Abstract: Neuroblastoma arises from precursor cells of the sympathetic nervous system and presently accounts for 15% of all childhood cancer deaths. These tumors display remarkable heterogeneity in clinical behavior, ranging from spontaneous regression to rapid progression and resistance to therapy. The clinical behavior of these tumors is associated with many factors, including patient age, histopathology and genetic abnormalities such as MYCN amplification. More recently, the dysregulation of some miRNAs, including the miR-17-5p-92 cluster and miR-34a, has been implicated in the pathobiology of neuroblastoma. MiR-17-5p-92 family members act in an oncogenic manner while miR-34a has tumor suppressor functions. The evidence for the contribution of miRNAs in the aggressive neuroblastoma phenotype is reviewed in this article, along with exciting possibilities for miRNA mediated therapeutics.

Abstract: In this single centre study of childhood acute lymphoblastic leukaemia (ALL) patients treated on the Medical Research Council UKALL 97/99 protocols, it was determined that minimal residual disease (MRD) detected by real time quantitative polymerase chain reaction (RQ-PCR) and 3-colour flow cytometry (FC) displayed high levels of qualitative concordance when evaluated at multiple time-points during treatment (93.38%), and a combined use of both approaches allowed a multi time-point evaluation of MRD kinetics for 90% (53/59) of the initial cohort. At diagnosis, MRD markers with sensitivity of at least 0.01% were identified by RQ-PCR detection of fusion gene transcripts, IGH/TRG rearrangements, and FC. Using a combined RQ-PCR and FC approach, the evaluation of 367 follow-up BM samples revealed that the detection of MRD >1% at Day 15 (P = 0.04), >0.01% at the end of induction (P = 0.02), >0.01% at the end of consolidation (P = 0.01), >0.01% prior to the first delayed intensification (P = 0.01), and >0.1% prior to the second delayed intensification and continued maintenance (P = 0.001) were all associated with relapse and, based on early time-points (end of induction and consolidation) a significant log-rank trend (P = 0.0091) was noted between survival curves for patients stratified into high, intermediate and low-risk MRD groups.

Abstract: Neuroblastoma (NBL), a pediatric tumor arising from precursor cells of the sympathetic nervous system, is characterized by numerous recurrent large-scale chromosomal imbalances. High resolution oligonucleotide array CGH analysis of NBL has previously identified microdeletions that are confined to the 5' UTR of the protein tyrosine phosphatase receptor D (PTPRD) gene, implicating this gene in the pathogenesis of these tumors. Here, we demonstrate that the 5' UTR of this gene, consisting of 11 noncoding exons, is also aberrantly spliced in >50% of NBL primary tumors and cell lines. The loss of exons from the 5' UTR region through aberrant splicing results in aberrant mRNA isoforms that are similar to those generated through microdeletions. The aberrant splicing or microdeletion of 5' UTR exons in such a high proportion of tumors indicates that loss of these exons dys-regulates the mRNA sequence. To further validate the role of PTPRD in NBL, we have examined the expression of this gene in normal fetal adrenal neuroblasts (the cell of origin of NBL) and in tumors from patients with either low stage or high stage disease. This gene is expressed at lower levels in high stage NBL tumors, particularly those with amplification of MYCN, relative to low stage tumors or normal fetal adrenal neuroblasts, consistent with the possibility that loss of the 5' UTR exons have destabilized the mRNA.

Abstract: Tumor-specific patterns of large-scale chromosomal imbalances characterize most forms of cancer. Based on evidence primarily from neuroblastomas, it can be argued that large-scale chromosomal imbalances are crucial for tumor pathogenesis and have an impact on the global transcriptional profile of cancer cells, and that some imbalances even initiate cancer. The genes and genetic pathways that have been dysregulated by such imbalances remain surprisingly elusive. Many genes are affected by the regions of gain and loss, and there are complex interactions and relationships that occur between these genes, hindering their identification. The study of untranslated RNA sequences, such as microRNAs, is in its infancy, and it is likely that such sequences are also dysregulated by chromosomal imbalance, contributing to pathogenesis.

Abstract: Neuroblastoma (NB) is one of the most common forms of cancer in children, accounting for 15% of pediatric cancer deaths. The clinical course of these tumors is highly variable and is dependent on such factors as age at presentation, stage, ploidy and genomic abnormalities. Hemizygous deletion of chromosome 1p occurs in approximately 30% of advanced stage tumors, is associated with a poor prognosis, and likely leads to the loss of one or more tumor suppressor genes. We show here that microRNA (miRNA)-34a (1p36.23) is generally expressed at lower levels in unfavorable primary NB tumors and cell lines relative to normal adrenal tissue and that reintroduction of this miRNA into three different NB cell lines causes a dramatic reduction in cell proliferation through the induction of a caspase-dependent apoptotic pathway. As a potential mechanistic explanation for this observation, we demonstrate that miR-34a directly targets the messenger ribonucleic acid (mRNA) encoding E2F3 and significantly reduces the levels of E2F3 protein, a potent transcriptional inducer of cell-cycle progression. Furthermore, miR-34a expression increases during retinoic acid-induced differentiation of the SK-N-BE cell line, whereas E2F3 protein levels decrease. Thus, adding to the increasing role of miRNAs in cancer, miR-34a may act as a suppressor of NB tumorgenesis.

Abstract: Large-scale hemizygous loss of chromosome 3p is a common event in neuroblastoma, occurring preferentially in tumors that exhibit loss of chromosome 11q and lack MYCN amplification. Although numerous tumor suppressor genes (TSG) have been mapped to the 3p region, the gene or genes contributing to neuroblastoma pathogenesis have remained elusive. High-resolution oligonucleotide array CGH mapping of chromosome 3p breakpoints relative to the positions of known TSGs indicates that more than one gene may contribute to neuroblastoma pathogenesis. We evaluated the methylation status of semaphorin 3B (SEMA3B), one of the chromosome 3p TSGs, in neuroblastoma tumors with (n = 12) and without (n = 32) 3p deletions. A significantly higher percentage of methylated CpG sites in the SEMA3B promoter was detected in tumors exhibiting 3p loss (95%), relative to tumors without loss (52%), suggestive of a two-hit mechanism of allele inactivation. The involvement of methylation in the control of SEMA3B expression was confirmed by treatment of neuroblastoma cell lines with the demethylating agent 5-aza-2-deoxycytidine. Transcriptional regulation of this locus is complex, however; low levels of SEMA3B expression were also seen in tumors with unmethylated SEMA3B promoters (n = 4). SEMA3B is known to play an important role in the development of normal sympathetic neurons, and interestingly, we found higher levels of SEMA3B expression in differentiated tumors with favorable histopathology (n = 19) than in tumors with unfavorable histology (n = 22). Furthermore, SEMA3B was upregulated in the SK-N-BE neuroblastoma cell line following induction of differentiation with retinoic acid. The association of SEMA3B expression with neuroblastoma differentiation suggests that this TSG may play a role in neuroblastoma pathobiology.

Abstract: Neuroblastoma accounts for 15% of pediatric cancer deaths, and although a few protein-coding genes, such as MYCN, are involved with aggressive pathogenicity, the identification of novel biological targets for therapeutic intervention is still a necessary prerequisite for improving patient survival. Expression profiling of 157 microRNA (miRNA) loci in 35 primary neuroblastoma tumors indicates that 32 loci are differentially expressed in favorable and unfavorable tumor subtypes, indicating a potential role of miRNAs in neuroblastoma pathogenesis. Many of these loci are significantly underexpressed in tumors with MYCN amplification, which have particularly poor prognoses. Interestingly, we found that miRNA expression levels substantially change in a MYCN-amplified cell line following exposure to retinoic acid, a compound which is well known for causing reductions in MYCN expression and for inducing neuroblastoma cell lines to undergo neuronal differentiation. We also show that small interfering RNA inhibition of MYCN by itself causes similar alterations in the expression of miRNA loci. In vitro functional studies of one locus, miR-184, indicate that it plays a significant role in apoptosis. The association of experimentally induced alterations of miRNA expression in neuroblastoma cell lines with differentiation or apoptosis leads us to conclude that these loci play important roles in neuroblastoma pathogenesis. We further suggest that MYCN may mediate a tumorigenic effect, in part, through directly or indirectly regulating the expression of miRNAs that are involved with neural cell differentiation and/or apoptosis, warranting substantial further studies of miRNAs as potential therapeutic targets.

Abstract: Many recurrent large-scale chromosome abnormalities associated with poor clinical outcomes have been identified in neuroblastoma, a pediatric tumor that accounts for 15% of childhood cancer deaths. We have previously used high-resolution oligonucleotide array comparative genomic hybridization to map 461 chromosome breakpoints leading to large-scale chromosome imbalances in 56 primary neuroblastoma tumors and cell lines. Here, we analyze the distribution of DNA sequence elements and genomic landmarks found within these breakpoint intervals and in 15,800 randomly generated intervals of similar size. The most consistent finding was that neuroblastoma chromosome breakpoints occur preferentially in GC-rich regions of the genome. It is not unsurprising that these regions have fewer (AT)(n) microsatellite repeat sequences. In addition, chromosome breakpoints occurring in neuroblastoma also appeared to be preferentially associated with ancestral chromosome breakpoint regions on several chromosomes, suggesting that such sites also act as hotspots for chromosome rearrangement in somatic cells. Very little evidence for the enrichment of Alu and other types of repeats in breakpoint intervals was obtained. Overall, our results are consistent with a mechanistic model involving nonhomologous end joining of DNA double-strand breaks that have been generated in a nonrandom manner.

Abstract: Neuroblastoma is characterized by numerous recurrent large-scale chromosomal imbalances and gene amplifications which are associated with poor clinical outcome. The most common include MYCN amplification, loss of 1p, 3p and 11q, and gain of 17q genomic regions. Two of these abnormalities, MYCN amplification and loss of 11q, define different genetic subtypes of the disease with vastly different global gene expression profiles. The progress towards the identification of the genes and genetic pathways that have been affected by these abnormalities is reviewed and high resolution mapping of the chromosomal breakpoint regions using oligonucleotide array CGH (oaCGH) is discussed. oaCGH analysis is proving useful for both defining minimal regions of overlap of imbalances, as well as providing information on the molecular mechanisms that generate the chromosomal imbalances. These high resolution analyses have also permitted the detection of micro-deletions in the tumors that further assist in identifying genes important for neuroblastoma pathogenesis.

Abstract: High-resolution array comparative genomic hybridization (arrayCGH) profiling was performed on 75 primary tumors and 29 cell lines to gain further insight into the genetic heterogeneity of neuroblastoma and to refine genomic subclassification. Using a novel data-mining strategy, three major and two minor genomic subclasses were delineated. Eighty-three percent of tumors could be assigned to the three major genomic subclasses, corresponding to the three known clinically and biologically relevant subsets in neuroblastoma. The remaining subclasses represented (1) tumors with no/few copy number alterations or an atypical pattern of aberrations and (2) tumors with 11q13 amplification. Inspection of individual arrayCGH profiles showed that recurrent genomic imbalances were not exclusively associated with a specific subclass. Of particular notice were tumors with numerical imbalances typically observed in subtype 1 neuroblastoma, in association with genomic features of subtype 2A or 2B. A search for prognostically relevant genomic alterations disclosed 1q gain as a predictive marker for therapy failure within the group of subtype 2A and 2B tumors. In cell lines, a high incidence of 6q loss was observed, with a 3.87-5.32 Mb region of common loss within 6q25.1-6q25.2. Our study clearly illustrates the importance of genomic profiling in relation to tumor behavior in neuroblastoma. We propose that genome-wide assessment of copy number alterations should ideally be included in the genetic workup of neuroblastoma. Further multicentric studies on large tumor series are warranted in order to improve therapeutic stratification in conjunction with other features such as age at diagnosis, tumor stage, and gene expression signatures.

Abstract: The HYDIN gene located in human chromosome band 16q22.2 is a large gene encompassing 423 kb of genomic DNA that has been suggested as a candidate for an autosomal recessive form of congenital hydrocephalus. We have found that the human HYDIN locus has been very recently duplicated, with a nearly identical 360-kb paralogous segment inserted on chromosome 1q21.1. The duplication, among the largest interchromosomal segmental duplications described in humans, is not accounted for in the current human genome assembly and appears to be part of a greater than 550-kb contig that must lie within 1 of the 11 sequence gaps currently remaining in 1q21.1. Both copies of the HYDIN gene are expressed in alternatively spliced transcripts. Elucidation of the role of HYDIN in human disease susceptibility will require careful discrimination among the paralogous copies.

Abstract: BACKGROUND : Neuroblastoma tumor cells are assumed to originate from primitive neuroblasts giving rise to the sympathetic nervous system. Because these precursor cells are not detectable in postnatal life, their transcription profile has remained inaccessible for comparative data mining strategies in neuroblastoma. This study provides the first genome-wide mRNA expression profile of these human fetal sympathetic neuroblasts. To this purpose, small islets of normal neuroblasts were isolated by laser microdissection from human fetal adrenal glands. RESULTS : Expression of catecholamine metabolism genes, and neuronal and neuroendocrine markers in the neuroblasts indicated that the proper cells were microdissected. The similarities in expression profile between normal neuroblasts and malignant neuroblastomas provided strong evidence for the neuroblast origin hypothesis of neuroblastoma. Next, supervised feature selection was used to identify the genes that are differentially expressed in normal neuroblasts versus neuroblastoma tumors. This approach efficiently sifted out genes previously reported in neuroblastoma expression profiling studies; most importantly, it also highlighted a series of genes and pathways previously not mentioned in neuroblastoma biology but that were assumed to be involved in neuroblastoma pathogenesis. CONCLUSION : This unique dataset adds power to ongoing and future gene expression studies in neuroblastoma and will facilitate the identification of molecular targets for novel therapies. In addition, this neuroblast transcriptome resource could prove useful for the further study of human sympathoadrenal biogenesis.

Abstract: Although neuroblastoma is characterized by numerous recurrent, large-scale chromosomal imbalances, the genes targeted by such imbalances have remained elusive. We have applied whole-genome oligonucleotide array comparative genomic hybridization (median probe spacing 6 kb) to 56 neuroblastoma tumors and cell lines to identify genes involved with disease pathogenesis. This set of tumors was selected for having either 11q loss or MYCN amplification, abnormalities that define the two most common genetic subtypes of metastatic neuroblastoma. Our analyses have permitted us to map large-scale chromosomal imbalances and high-level amplifications at exon-level resolution and to identify novel microdeletions and duplications. Chromosomal breakpoints (n = 467) generating imbalances >2 Mb were mapped to intervals ranging between 6 and 50 kb in size, providing substantial information on each abnormality. For example, breakpoints leading to large-scale hemizygous loss of chromosome 11q were highly clustered and preferentially associated with segmental duplications. High-level amplifications of MYCN were extremely complex, often resulting in a series of discontinuous regions of amplification. Imbalances (n = 540) <2 Mb long were also detected. Although the majority (78%) of these imbalances mapped to segmentally duplicated regions and primarily reflect constitutional copy number polymorphisms, many subtle imbalances were detected that are likely somatically acquired alterations and include genes involved with tumorigenesis, apoptosis, or neural cell differentiation. The most frequent microdeletion involved the PTPRD locus, indicating a possible tumor suppressor function for this gene.

Abstract: Primary effusion lymphomas (PEL) form a subset of AIDS-related lymphomas and usually have a poor prognosis. Although Kaposi's sarcoma-associated herpes virus (KSHV) is often associated with PEL, very little is known about the exact mechanisms or causative effects of these associations. We investigated the chromosomal imbalances in six KSHV-positive PEL cell lines using comparative genomic hybridization analysis. We defined the shortest regions of overlaps for genomic gains on six chromosomes: 1q31, 4q31 approximately q33, 7q10 approximately q21, 8q21.1, 12q0 approximately q23, and Xp11 approximately q21. The recurrent nature of the gains found in these chromosomal regions suggests that these imbalances play roles in the pathogenesis of PEL.

Abstract: PURPOSE: Neuroblastoma is a genetically heterogeneous pediatric tumor with a remarkably variable clinical behavior ranging from widely disseminated disease to spontaneous regression. In this study, we aimed for comprehensive genetic subgroup discovery and assessment of independent prognostic markers based on genome-wide aberrations detected by comparative genomic hybridization (CGH). MATERIALS AND METHODS: Published CGH data from 231 primary untreated neuroblastomas were converted to a digitized format suitable for global data mining, subgroup discovery, and multivariate survival analyses. RESULTS: In contrast to previous reports, which included only a few genetic parameters, we present here for the first time a strategy that allows unbiased evaluation of all genetic imbalances detected by CGH. The presented approach firmly established the existence of three different clinicogenetic subgroups and indicated that chromosome 17 status and tumor stage were the only independent significant predictors for patient outcome. Important new findings were: (1) a normal chromosome 17 status as a delineator of a subgroup of presumed favorable-stage tumors with highly increased risk; (2) the recognition of a survivor signature conferring 100% 5-year survival for stage 1, 2, and 4S tumors presenting with whole chromosome 17 gain; and (3) the identification of 3p deletion as a hallmark of older age at diagnosis. CONCLUSION: We propose a new regression model for improved patient outcome prediction, incorporating tumor stage, chromosome 17, and amplification/deletion status. These findings may prove highly valuable with respect to more reliable risk assessment, evaluation of clinical results, and optimization of current treatment protocols.

Abstract: We report a case of desmoplastic small round cell tumor occurring in the right ilium of a 13-year-old boy. Morphologically, the neoplasm consisted of small round cells of primitive appearance with a diffuse growth pattern replacing marrow space and eroding bone. Immunohistochemical staining was positive for vimentin, synapsin, CD99 (MIC2 protein), and FLI-1, prompting an initial diagnosis of Ewing sarcoma/primitive neuroectodermal tumor. However, a diagnosis of desmoplastic small round cell tumor was rendered after the detection by cytogenetic analysis of the reciprocal chromosomal translocation, t(11;22)(p13;q12), which is uniquely associated with this tumor. This is the first documented instance of desmoplastic small round cell tumor arising in bone.

Abstract:

Abstract: The incidence of melanoma is increasing rapidly, with advanced lesions generally failing to respond to conventional chemotherapy. Here, we utilized DNA microarray-based gene expression profiling techniques to identify molecular determinants of melanoma progression within a unique panel of isogenic human melanoma cell lines. When a poorly tumorigenic cell line, derived from an early melanoma, was compared with two increasingly aggressive derivative cell lines, the expression of 66 genes was significantly changed. A similar pattern of differential gene expression was found with an independently derived metastatic cell line. We further examined these melanoma progression-associated genes via use of a tailored TaqMan Low Density Array (LDA), representing the majority of genes within our cohort of interest. Considerable concordance was seen between the transcriptomic profiles determined by DNA microarray and TaqMan LDA approaches. A range of novel markers were identified that correlated here with melanoma progression. Most notable was TSPY, a Y chromosome-specific gene that displayed extensive down-regulation in expression between the parental and derivative cell lines. Examination of a putative CpG island within the TSPY gene demonstrated that this region was hypermethylated in the derivative cell lines, as well as metastatic melanomas from male patients. Moreover, treatment of the derivative cell lines with the DNA methyltransferase inhibitor, 2'-deoxy-5-azacytidine (DAC), restored expression of the TSPY gene to levels comparable with that found in the parental cells. Additional DNA microarray studies uncovered a subset of 13 genes from the above-mentioned 66 gene cohort that displayed re-activation of expression following DAC treatment, including TSPY, CYBA and MT2A. DAC suppressed tumor cell growth in vitro. Moreover, systemic treatment of mice with DAC attenuated growth of melanoma xenografts, with consequent re-expression of TSPY mRNA. Overall, our data support the hypothesis that multiple genes are targeted, either directly or indirectly, by DNA hypermethylation during melanoma progression.

Abstract: Understanding the genes and genetic pathways targeted by recurrent chromosomal imbalances in malignancy, along with the molecular mechanisms that generate the imbalances, are important problems in cancer biology. In this report, we demonstrate that oligonucleotide array CGH (oaCGH) analysis can routinely map chromosomal imbalance breakpoints at exon-level resolution, including imbalances that are single copy number genomic alterations. Different tiling-path array designs were used in this study: a whole-genome array with a 6-kb median probe spacing and fine-tiling arrays for selected genomic regions with either 50- or 140-bp median probe spacing. In both array formats, oligonucleotide probes were of isothermal design and were tiled through genic and inter-genic regions. Whole-genome oaCGH analysis of two neuroblastoma cell lines and three primary tumors led to the identification of 58 chromosomal breakpoints that generated 45 large-scale partial chromosomal imbalances (> 2 Mb). An unexpectedly high proportion (34%) of these breakpoint intervals mapped to regions containing segmental duplications. In addition, 88 smaller-sized regions (< 2 Mb) of imbalance were detected, the majority of which mapped to segmentally duplicated regions and may reflect constitutional copy number polymorphisms. The chromosomal breakpoints for 12 recurrent abnormalities exhibited in neuroblastoma tumors and cell lines, including MYCN amplicon boundaries, loss of 3p, loss of 11q, and gain of 17q, could be mapped to intervals ranging from 50 bp to 10 kb in size using high-density fine-tiling oligonucleotide microarrays. Fine-tiling oaCGH analysis provides an unprecedented level of resolution, allowing detailed mapping of recurrent unbalanced chromosomal abnormalities. Supplementary material for this article can be found on the Genes, Chromosomes, and Cancer website at http://www.interscience.wiley.com/jpages/1045-2257/suppmat/index.html.

Abstract: Neuroblastoma, one of the most common tumors of childhood, presents at diagnosis with a vast number of recurrent chromosomal imbalances that include hyperdiploidy for whole chromosomes, partial loss of 1p, 3p, 4p, 11q, 14q, partial gain of 1q, 7q, 17q and amplification of MYCN. These abnormalities are nonrandomly distributed in neuroblastoma as loss of 3p and 11q rarely occur in MYCN amplified neuroblastomas. Here, we report on a patient who had a non-MYCN amplified 3p-/11q- neuroblastoma at diagnosis who subsequently developed a high level of MYCN amplification in bone marrow metastases 41 months after induction of complete remission. The tumor at diagnosis had low level unbalanced gain of distal 2p. In order to assess the frequency of low level gain of distal 2p in neuroblastoma, we examined the comparative genomic hybridization results from 60 neuroblastomas. Among non-MYCN amplified neuroblastomas, 8/45 (18%) had low level gain of distal 2p. Low level gain for a segment of 2p (i.e. a region larger than the 2p23-->p24 undergoing amplification) was also detected in five of the 15 tumors that had high level MYCN amplification. The possibility that low level gain of distal 2p is a risk factor for high level MYCN amplification is discussed.

Abstract: We report identical twins with supernumerary ring chromosome 19 mosaicism, who had severe refractory epilepsy at an early age. The epilepsy was dominated largely by severe life-threatening tonic seizures. Both twins died, likely as a consequence of their severe epilepsy. They displayed no dysmorphic features. Eight cases of ring chromosome 19 have been reported in the literature, all to our knowledge without epilepsy. The clinical picture of these twins emphasizes the importance of carrying out a karyotype study on patients with early-onset epilepsy even in the absence of dysmorphic features.

Abstract: A number of distinct subtypes of neuroblastoma exist with different genetic abnormalities that are predicative of outcome. Whole chromosome gains are usually associated with low stage disease and favourable outcome, whereas loss of 1p, 3p and 11q, unbalanced gain of 17q and MYCN amplification (MNA) are indicative of high stage disease and unfavourable prognosis. Although MNA and loss of 11q appear to represent two distinct genetic subtypes of advanced stage neuroblastoma, a detailed understanding of how these subtypes differ in terms of global gene expression is still lacking. We have used metaphase comparative genomic hybridization (CGH) analysis in combination with oligonucleotide technology to identify patterns of gene expression that correlate with specific genomic imbalances found in primary neuroblastic tumours and cell lines. The tumours analysed in this manner included a ganglioneuroma, along with various ganglioneuroblastoma and neuroblastoma of different stages and histopathological classifications. Oligonucleotide microarray-based gene expression profile analysis was performed with Affymetrix HU133A arrays representing approximately 14 500 unique genes. The oligonucleotide microarray results were subsequently validated by quantitative real-time PCR, immunohistochemical staining, and by comparison of specific gene expression patterns with published results. Hierarchical clustering of gene expression data distinguished tumours on the basis of stage, differentiation and genetic abnormalities. A number of genes were identified whose patterns of expression were highly correlated with 11q loss; supporting the concept that loss of 11q represents a distinct genetic subtype of neuroblastoma. The implications of these results in the process of neuroblastoma development and progression are discussed.

Abstract: Loss of 11q material occurs in approximately 30% of advanced stage neuroblastoma and defines a distinct genetic subtype of this disease. These tumors almost always possess unbalanced gain of the 17q, along with many additional recurrent chromosomal imbalances. Loss of 11q and gain of 17q is often the consequence of an unbalanced translocation between the long arms of both chromosomes, but because of the involvement of other chromosomal mechanisms, the actual frequency of t(11;17) is unknown. In addition, chromosomal breakpoint positions for the t(11;17) are variable in different tumors, with breakpoints on neither the 11q nor 17q being well defined. We have used interphase fluorescence in situ hybridization analysis to detect a der(11)t(11;17) in a series of neuroblastomas with 11q loss/17q gain using a statistical approach which could be applicable to the detection of translocations in other solid tumors. The frequency of der(11)t(11;17) was approximately 90% in our neuroblastoma series. A balanced t(11;17) was also detected in a MYCN amplified tumor, which is a distinctly different genetic subtype from the 11q- tumors. Breakpoint positions on 11q were determined to be variable, whereas all breakpoints on 17q appeared to cluster proximal to position 43.1 Mb on the DNA sequence map. The majority of tumors had large numbers of nuclei with 2 or more copies of der(11)t(11;17), which led to unbalanced gain of 11p, and further increases in 17q imbalance. The prevalence of t(11;17) in neuroblastoma warrants additional studies to further define the range in variation in breakpoint positions on both chromosomes and to elucidate the molecular mechanisms that lead to this important and interesting recurrent genetic abnormality.

Abstract: In a search for potential infertility loci, which might be revealed by clustering of chromosomal breakpoints, we compiled 464 infertile males with a balanced rearrangement from Mendelian Cytogenetics Network database (MCNdb) and compared their karyotypes with those of a Danish nation-wide cohort. We excluded Robertsonian translocations, rearrangements involving sex chromosomes and common variants. We identified 10 autosomal bands, five of which were on chromosome 1, with a large excess of breakpoints in the infertility group. Some of these could potentially harbour a male-specific infertility locus. However, a general excess of breakpoints almost everywhere on chromosome 1 was observed among the infertile males: 26.5 versus 14.5% in the cohort. This excess was observed both for translocation and inversion carriers, especially pericentric inversions, both for published and unpublished cases, and was significantly associated with azoospermia. The largest number of breakpoints was reported in 1q21; FISH mapping of four of these breakpoints revealed that they did not involve the same region at the molecular level. We suggest that chromosome 1 harbours a critical domain whose integrity is essential for male fertility.

Abstract: Human chromosome 16 features one of the highest levels of segmentally duplicated sequence among the human autosomes. We report here the 78,884,754 base pairs of finished chromosome 16 sequence, representing over 99.9% of its euchromatin. Manual annotation revealed 880 protein-coding genes confirmed by 1,670 aligned transcripts, 19 transfer RNA genes, 341 pseudogenes and three RNA pseudogenes. These genes include metallothionein, cadherin and iroquois gene families, as well as the disease genes for polycystic kidney disease and acute myelomonocytic leukaemia. Several large-scale structural polymorphisms spanning hundreds of kilobase pairs were identified and result in gene content differences among humans. Whereas the segmental duplications of chromosome 16 are enriched in the relatively gene-poor pericentromere of the p arm, some are involved in recent gene duplication and conversion events that are likely to have had an impact on the evolution of primates and human disease susceptibility.

Abstract: Neuroblastoma exhibiting deletion of a segment of the long arm of chromosome 11 represents a genetic subtype of tumor that is distinct from those exhibiting MYCN amplification or 1p deletion. The 11q- genetic subtype is further characterized by gain of 17q and loss of distal 3p material. Gain of 11p material has also been reported in neuroblastoma with 11q loss, but at a considerably lower frequency than gain of 17q or loss of the distal 3p region. Our results, however, indicate that gain of 11p may occur more frequently in 11q- neuroblastoma than what was previously realized. Comparative genomic hybridization analyses of neuroblastoma tissue from eleven patients indicated that six of 11 tumors (55%) with loss of 11q also possessed gain of 11p. The shortest region of 11p gain was 11p11.2-->p14. G-banding and fluorescence in situ hybridization analysis performed on tumor cells from primary and metastatic sites from one patient allowed us to infer that gain of 11p arose secondarily to the abnormality that led to the loss of 11q material. Gain of an entire chromosome 7 was detected in 17 of 43 (40%) tumors, whereas gain of 7q was detected in 5 of 43 (12%) tumors. Unlike gain of 11p, gain of an entire chromosome 7 appears to be prevalent in all tumor stages and is not limited to the 11q- tumor subtype. Gain of 7q, however, is more prevalent in higher stage tumors. G-band cytogenetic analysis indicated that an unbalanced t(3;7) was responsible for the gain of 7q and loss of 3p material in one case. We discuss the possibility that gain of 7/7q, and 11p material may contribute to either tumorigenesis or progression.

Abstract: Autism is a neurodevelopmental disorder presenting in the first 3 years of life. Deficits occur in the three core areas of communication, social interaction, and behavior. The causes of autism are unknown, but clinical genetic studies show strong evidence in favor of a genetic etiology. Molecular genetic studies report some association with candidate genes, and candidate regions have emerged from several genome-wide linkage studies. Here we report a clinical case of autism with a deletion on chromosome 2 in a young male with high-functioning autism. The deletion seems to correspond with regions emerging from linkage studies. We propose this as a possible candidate region in the search for autism genes.

Abstract: We describe a 19-year-old girl who has clinical features of microphthalmia with linear skin defects (MLS) syndrome caused by a microdeletion of Xp22.3. In addition to the classical ocular abnormalities and linear skin defects she has other features not previously described. She was previously reported in this journal in 1990 as poikiloderma congenitale, but her true diagnosis of an Xp22.3 microdeletion was clarified when fluorescent in situ hybridization (FISH) analysis indicated that one of her X chromosomes had a microdeletion including the KAL gene. We describe this patient with an Xp22.3 microdeletion to heighten awareness among dermatologists of this syndrome and to underscore the difficulties in diagnosing MLS syndrome.

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Abstract: We report on nine children with Shwachman-Diamond syndrome (SDS), eight of whom had clonal abnormalities of chromosome 7. Seven children had an isochromosome 7 [i(7)(q10)] and one a derivative chromosome 7, all with an apparently identical (centromeric) breakpoint. Children with SDS are predisposed to myelodysplasia (MDS) and acute myeloid leukaemia (AML) often with chromosome 7 abnormalities. Allogeneic transplants have been used to treat these children, however, they are a high-risk transplant group and require careful evaluation. Three of the children were transplanted but only one survived, who to our knowledge remains the longest surviving SDS transplant patient (4.5 years +). The six non-transplanted children are well. In classic MDS, chromosome 7 abnormalities are associated with rapid progression to acute leukaemia; however, we present evidence to suggest that isochromosome 7q may represent a separate disease entity in SDS children. This is a particularly interesting finding given that the SDS gene has recently been mapped to the centromeric region of chromosome 7. Our studies indicate that i(7)(q10) is a relatively benign rearrangement and that it is not advisable to offer allogeneic transplants to SDS children with i(7)(q10) alone in the absence of other clinical signs of disease progression.

Abstract: We describe an adult male with severe learning disability, epilepsy, and dysmorphic features. Cytogenetic studies demonstrated a terminal duplication of the long arm of chromosome 17, resulting in partial trisomy 17q24-q25. Our patient shows some of the characteristic features of the distal 17q phenotype, but in addition has more unusual features such as epilepsy, sensorineural hearing loss, and long fingers and overlapping toes. We suggest that these features occur with terminal duplications of 17q.

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Abstract: Comparative genomic hybridization (CGH) analysis was performed on both a pre- and post-chemotherapy hepatoblastoma from a 24-month-old female patient. The diagnostic sample obtained from a tru-cut biopsy was a mixed epithelial-mesenchymal tumor with both fetal and embryonal patterns present. In contrast, the post-chemotherapy tumor exhibited a prominent anaplastic large cell population focally reminiscent of pleomorphic hepatocellular carcinoma (HCC). CGH analysis indicated that there were similarities as well as differences in the gains and losses of genetic material in each tumor. The diagnostic sample had gains of chromosome 1q, 2, 2(q31q33), 7, 8q, 12(q15q22), 17q and 20 material, while the post-chemotherapy tumor had gains of 1q, 2, 7, 8q, 10, 17q and 20 material. In addition, the pre- and post-chemotherapy samples may have incurred loss of chromosome 17p material. The main differences between the two samples involved localized gain of 2(q31q33) and 12(q15q22) in the pre-chemotherapy sample, and gain of chromosome 10 material in the post-chemotherapy tumor. The patient subsequently developed metastatic nodules in her lungs, the histology of which was identical in pattern to the diagnostic pattern, and appeared to have localized gain of 2(q31q33) and 12(q15q22). These results are consistent with published results that gain of chromosome 8q and 20 are associated with an unfavorable prognosis.

Abstract: Comparative genomic hybridization (CGH) was used to clarify the chromosomal status of 15 patients diagnosed with childhood acute lymphoblastic leukemia (ALL). Bone marrow samples from 10 of the 15 patients were selected because no metaphases were obtained for cytogenetic analysis. Three patients with normal trypsin and giemsa banding (GTG) karyotypes were also studied by CGH to determine whether significant abnormalities might have been missed by banding analysis, and samples from an additional 2 patients with hyperdiploidy were also included. Seven of the 10 patients with failed GTG banding analysis were found to be chromosomally abnormal by CGH; 2 out of 3 patients with normal GTG band karyotypes were abnormal, indicating that the metaphases available for karyotyping were not malignant cells, and that CGH analysis of hyperdiploid samples provided more accurate resolution than karyotyping alone. The prognostic value of chromosomal aberrations detected by CGII and the efficiency of the technique suggest a central role for CGH in routine clinical cytogenetics.

Abstract: Neuroblastoma, the most common extracranial solid tumor of childhood, is associated with a number of genetic abnormalities that are prognostically significant. The most common abnormalities are associated with aggressive clinical behavior and include deletion of distal chromosome 1p, NMYC amplification, and unbalanced gain of the long arm of chromosome 17. There are also other recurrent, but less frequent abnormalities, the clinical significance of which is uncertain. These less common abnormalities include deletion 3p, 11q, and 14q. To gain further clinical insight into some of the less commonly observed abnormalities in neuroblastoma, we performed comparative genomic hybridization (CGH) analysis on 24 primary and metastatic neuroblastomas (6 stage 2, 5 stage 3, 11 stage 4, and 2 stage 4). Nineteen of these tumors were prechemotherapy. A total of 190 abnormalities were detected from these tumors. Four of the 24 tumors studied showed loss of 11q material, with 3 of these tumors also possessing distal chromosome 3p deletions. Our results provide confirmation that deletion of chromosome 3p is nonrandomly associated with deletion of chromosome 11q in neuroblastoma. However, analysis of our results, along with other results reported in the literature, indicate that there is no statistically significant association between 3p and 11q loss and more clinically aggressive tumors.

Abstract: G band cytogenetic analysis often leads to the discovery of unbalanced karyotypes that require further characterisation by molecular cytogenetic studies. In particular, G band analysis usually does not show the chromosomal origin of small marker chromosomes or of a small amount of extra material detected on otherwise normal chromosomes. Comparative genomic hybridisation (CGH) is one of several molecular approaches that can be applied to ascertain the origin of extra chromosomal material. CGH is also capable of detecting loss of material and thus is also applicable to confirming or further characterising subtle deletions. We have used comparative genomic hybridisation to analyse 19 constitutional chromosome abnormalities detected by G band analysis, including seven deletions, five supernumerary marker chromosomes, two interstitial duplications, and five chromosomes presenting with abnormal terminal banding patterns. CGH was successful in elucidating the origin of extra chromosomal material in 10 out of 11 non-mosaic cases, and permitted further characterisation of all of the deletions that could be detected by GTG banding. CGH appears to be a useful adjunct tool for either confirming deletions or defining their breakpoints and for determining the origin of extra chromosomal material, even in cases where abnormalities are judged to be subtle. We discuss internal quality control measures, such as the mismatching of test and reference DNA in order to assess the quality of the competitive hybridisation effect on the X chromosome.

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Abstract: We report on a 2 1/2 year old girl who is dysmorphic, developmentally delayed, and mosaic for an unbalanced, de novo translocation between chromosomes 3 and 15. The karyotype from peripheral blood lymphocytes is 46,XX (50) and the karyotype from skin fibroblasts is 46,XX (28)/46,XX,der(15)t(3;15)(q11;p11) (23). The mechanism for the generation of this unbalanced, de novo translocation is discussed.

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Abstract: The distribution and evolution of (CT)n microsatellites were examined in GenBank mammalian DNA sequences because these microsatellites are known to play important roles in the regulation of some genes in Drosophila melanogaster. A total of 236 (CT)n microsatellite loci were found in GenBank mammalian gene sequences. To determine whether (CT)n microsatellite arrays were conserved at orthologous positions in distantly related mammalian sequences, we determined whether orthologous sequences existed in GenBank for each of the 236 loci. A total of 47 sequence alignments could be made. For rodent x rodent comparisons, 7 of 8 (CT)n arrays were conserved at identical positions in each pair of orthologous sequences. Comparisons of orthologous sequences between different orders of mammals indicated that 11 of 39 (CT)n arrays occurred at orthologous positions or within 1 kb of orthologous positions in each pair of sequences. It appears that there is some level of conservation of (CT)n repeats in distantly related mammals. However, this level of conservation may not be greater than what might be expected to occur by chance. In 13 cases where (CT)n arrays were not conserved at orthologous positions, the lack of a (CT)n array in one sequence resulted from either nucleotide substitution within an array or nonexpansion of a shorter (CT)n element. In these cases, significant sequence identity could be detected throughout the entire region even though the repeat array was not detected in one of the sequences. In contrast, there was a disruption of sequence identity in the (CT)n microsatellite region that ranged from 24 to 1600 bp in 21 cases.(ABSTRACT TRUNCATED AT 250 WORDS)

Abstract: We describe efficient methods for screening clone libraries, based on pooling schemes that we call "random k-sets designs." In these designs, the pools in which any clone occurs are equally likely to be any possible selection of k from the v pools. The values of k and v can be chosen to optimize desirable properties. Random k-sets designs have substantial advantages over alternative pooling schemes: they are efficient, flexible, and easy to specify, require fewer pools, and have error-correcting and error-detecting capabilities. In addition, screening can often be achieved in only one pass, thus facilitating automation. For design comparison, we assume a binomial distribution for the number of "positive" clones, with parameters n, the number of clones, and c, the coverage. We propose the expected number of resolved positive clones--clones that are definitely positive based upon the pool assays--as a criterion for the efficiency of a pooling design. We determine the value of k that is optimal, with respect to this criterion, as a function of v, n, and c. We also describe superior k-sets designs called k-sets packing designs. As an illustration, we discuss a robotically implemented design for a 2.5-fold-coverage, human chromosome 16 YAC library of n = 1298 clones. We also estimate the probability that each clone is positive, given the pool-assay data and a model for experimental errors.

Abstract: A human corneal fibroblast cDNA library was screened with a bovine lumican cDNA probe to obtain three clones. Sequencing of the longest clone (1.75 kb) yielded an open reading frame of 1014 bp coding for a 338-amino-acid core protein. Amino acid sequencing of a tryptic peptide resulted in a 9-amino-acid match with the derived primary structure, confirming the identity of these clones. Human lumican displays all of the features of small interstitial proteoglycans: N- and C-terminal domains with highly conserved cysteines and a central domain containing nine repeats of slight variations of the leucine motif LXXLXLXXNXL. Like bovine lumican, the human core protein contains four possible N-glycosylation sites in the central domains, all or some of which are substituted with keratan sulfate side chains. At the amino acid level, it is 90% identical with bovine and 72% identical with the chicken core protein. The gene (LUM) was localized to human chromosome 12 by hybridizing a cDNA probe to a Southern blot containing a human/hamster monochromosomal mapping panel DNA. Further sublocalization to 12q21.3-q22 was performed by the fluorescence in situ hybridization technique using a lumican P1 genomic clone. By immunohistochemical staining, we show lumican's presence, not only in the corneal stroma as shown previously, but also in the dermal area of the skin, indicating a wider distribution of this proteoglycan.

Abstract: Forty-one Spanish families with polycystic kidney disease 1 (PKD1) were studied for evidence of linkage disequilibrium between the disease locus and six closely linked markers. Four of these loci--three highly polymorphic microsatellites (SM6, CW3, and CW2) and an RFLP marker (BLu24)--are described for the first time in this report. Overall the results reveal many different haplotypes on the disease-carrying chromosome, suggesting a variety of independent PKD1 mutations. However, linkage disequilibrium was found between BLu24 and PKD1, and this was corroborated by haplotype analysis including the microsatellite polymorphisms. From this analysis a group of closely related haplotypes, consisting of four markers, was found on 40% of PKD1 chromosomes, although markers flanking this homogeneous region showed greater variability. This study has highlighted an interesting subpopulation of Spanish PKD1 chromosomes, many of which have a common origin, that may be useful for localizing the PKD1 locus more precisely.

Abstract: Fluorescence in situ hybridization (FISH) provides a rapid approach to regional localization of overlapping clone sets (contigs) developed by various fingerprinting approaches. We have used 70 cosmid clones derived from 48 different contigs, part of the developing contig map of chromosome 16 (Stallings et al., 1990, 1992a), to cytogenetically map an estimated 8.6 million base pairs (Mbp) of chromosome 16 DNA (approximately 8-9% total coverage). Although the majority of cosmid contigs hybridized to single sites on chromosome 16, a significant fraction (23%) hybridized to multiple regions on chromosome 16; a subset of these also hybridized to other human chromosomes. In most instances, clones that mapped to multiple locations were found to contain low-abundance repetitive DNA sequences. The FISH data presented here, coupled with published mapping data from somatic cell hybrids (Callen et al., 1992), permits independent verification of the integrity of chromosome 16 cosmid contigs. The order of clones derived by FISH agrees closely with the cell hybrid mapping data and can be correlated with chromosome bands and specific chromosomal translocation breakpoints.

Abstract: The distribution of all trinucleotide microsatellite sequences in the GenBank database was surveyed to provide insight into human genetic disease syndromes that result from expansion of microsatellites. The microsatellite motif (CAG)n is one of the most abundant microsatellite motifs in human GenBank DNA sequences and is the most abundant microsatellites found in exons. This fact may explain why (CAG)n repeats are thus far the predominant microsatellites expanded in human genetic diseases. Surprisingly, (CAG)n microsatellites are excluded from intronic regions in a strand-specific fashion, possibly because of similarity to the 3' consensus splice site, CAGG. A comparison of the positions of microsatellites in human vs rodent homologous sequences indicates that some arrays are not extensively conserved for long periods of time, even when they form parts of protein coding sequences. The general lack of conservation of trinucleotide repeat loci in diverse mammals indicates that animal models for some human microsatellite expansion syndromes may be difficult to find.

Abstract: Fluorescence in situ hybridization analysis (FISH) was used to map the constitutional chromosome 16 pericentric inversion breakpoints inv(16)(p13q22) detected in one individual (II-2) from a large kindred [Bianchi et al., 1992: Am J Med Genet 43:791-795]. The breakpoints found in individual II-2 mapped to distinctly different locations than the chromosome 16 pericentric inversion breakpoints commonly acquired in acute nonlymphocytic leukemia. The constitutional pericentric inversion breakpoints also do not map to regions where low abundance repetitive DNA sequences found in bands 16p13 and q22 are located. The results indicate that low abundance, chromosome 16-specific repetitive DNA sequences in bands p13 and q22 are probably not causally related to the inversion that is found in many members of a large kindred [Bianchi et al., 1992].

Abstract: An area of 500 kb at the proximal end of the polycystic kidney disease 1 (PKD1) region has been mapped in detail, with 260 kb cloned in cosmids. The area cloned from normal individuals contains two homologous but divergent regions each of 75 kb, including the previously described marker 26-6. Pulsed-field gel electrophoresis identified a duplication of 75 kb of this region, referred to as the OX duplication (OXdup), in three patients with PKD1. The OXdup probably arose by an unequal exchange promoted by misalignment of partially homologous areas. Study of the OXdup in a large PKD1 family showed that it segregated with PKD1 in just one-half of the family, indicating that a recent crossover had occurred between the OXdup and PKD1 and showing that it was not a PKD1 mutation. Further analysis identified an OXdup breakpoint fragment: the OXdup was subsequently identified in 2 normal individuals of 110 assayed. The finding of the OXdup and in other individuals an 11-kb deletion (OXdel) at a similar point within this duplicated area indicates that this is an unusually unstable genomic region.

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Abstract: Repetitive DNA sequences have been implicated in the origin of several disease phenotypes, including fragile X syndrome, myotonic dystrophy, and spinal bulbar atrophy. In addition, a complex family of chromosome 16-specific low-abundance repetitive (CH16LAR) DNA sequences have been mapped by fluorescence in situ hybridization to regions of chromosome 16 that undergo breakage/rearrangement in acute nonlymphocytic leukemia (ANLL) cells. It has been hypothesized that these repetitive sequences are causally related to the chromosome rearrangements found in ANLL. Here, we further refine the mapping of CH16LAR sequences with respect to the ANLL inversion breakpoints, using a panel of somatic cell hybrids containing 51 different chromosome 16 breakpoints. These studies indicate that CH16LAR sequences at 16p13 are in close proximity to the ANLL short-arm breakpoint region. However, the region containing the highest density of CH16LAR sequences on the long arm appears to be distal to the region where the ANLL long-arm breakpoint has been mapped. These studies further show that CH16LAR sequences map in close proximity to FRA16D and FRA16A.

Abstract:

Abstract: The Rubinstein-Taybi syndrome (RTS) is a well-defined complex of congenital malformations characterized by facial abnormalities, broad thumbs and big toes, and mental retardation. The breakpoint of two distinct reciprocal translocations occurring in patients with a clinical diagnosis of RTS was located to the same interval on chromosome 16, between the cosmids N2 and RT1, in band 16p13.3. By using two-color fluorescence in situ hybridization, the signal from RT1 was found to be missing from one chromosome 16 in 6 of 24 patients with RTS. The parents of five of these patients did not show a deletion of RT1, indicating a de novo rearrangement. RTS is caused by submicroscopic interstitial deletions within 16p13.3 in approximately 25% of the patients. The detection of microdeletions will allow the objective conformation of the clinical diagnosis in new patients and provides an excellent tool for the isolation of the gene causally related to the syndrome.

Abstract: Batten disease, juvenile onset neuronal ceroid lipofuscinosis, is an autosomal recessive neurodegenerative disorder characterized by accumulation of autofluorescent lipopigment in neurons and other cell types. The disease locus (CLN3) has previously been assigned to chromosome 16p. The genetic localization of CLN3 has been refined by analyzing 70 families using a high-resolution map of 15 marker loci encompassing the CLN3 region on 16p. Crossovers in three maternal meioses allowed localization of CLN3 to the interval between D16S297 and D16S57. Within that interval alleles at three highly polymorphic dinucleotide repeat loci (D16S288, D16S298, D16S299) were found to be in strong linkage disequilibrium with CLN3. Analysis of haplotypes suggests that a majority of CLN3 chromosomes have arisen from a single founder mutation.

Abstract: Sequence-tagged sites (STSs) are versatile chromosomal markers for a variety of genome mapping efforts. In this report, we describe a randomly generated STS (323F4) from human chromosome 16 genomic DNA that has 90.0% sequence identity to the type I human inosine-5'-monophosphate dehydrogenase (IMPDH1) gene and 72% identity to the type II human inosine-5'-monophosphate dehydrogenase (IMPDH2) gene. Additional sequencing by primer walking has provided a total of 1380 bp of the human chromosome 16 sequence. The IMPDH-like sequence 323F4 was regionally localized by PCR analysis of a panel of somatic cell hybrids containing different portions of human chromosome 16 to 16p13.3-13.12, between the breakpoints found in hybrids CY196/CY197 and CY198. This regional mapping assignment was further refined to subband 16p13.13 by high-resolution fluorescence in situ hybridization using cosmid 323F4 as a probe. We conclude that a third, previously undescribed IMPDH locus, termed IMPDHL1, exists at human chromosome 16p13.13.

Abstract: We report the cloning of the chromosome 16 p-arm breakpoint involved in inversion 16(p13;q22) associated with subtype of acute myelomonocytic leukemia (AMML) M4Eo. Inter-Alu polymerase chain reaction (PCR) products from a series of interspecific somatic cell hybrids that contain only small portions of the human chromosome 16 p-arm were generated for use as fluorescent in-situ hybridization (FISH) probes. When applied to patient cells, rapid and unambiguous identification of the inversion resulted. Using FISH analysis, cosmid clones associated with the hybrids were identified that bracketed the p-arm breakpoint. A repeat-free fragment of one of these cosmids (35B11) when used as probe on Southern blots from pulsed-field gels identified rearranged macrorestriction fragments in patient DNA. Yeast artificial chromosomes (YACs) were isolated using sequences derived from cosmids flanking 35B11 in a cosmid contig. Of 4 YACs so identified, 3 were shown by FISH to cross the inversion-16 p-arm breakpoint. Therefore, the breakpoint has been molecularly cloned, and identified as being within these 3 YACs. These clones will facilitate the unraveling of the genetic events associated with inversion-16 and are available tools with immediate clinical application.

Abstract: Simple microsatellite repetitive sequences are widely distributed in eukaryotic genomes. Using the GCG Find program, the distribution of each type of mono- and dinucleotide repetitive sequence has been examined in GenBank sequences. Examples of each type of simple satellite sequence could be found, although the frequency of (CpG)n greater than or equal to 8 repeats was extremely low. The suppression of CpG dinucleotides in vertebrates does not adequately explain the rarity of this repeat since (CpG)n repeats are also extremely infrequent in species genomes where CpG dinucleotides are not suppressed. Instead, it is proposed that (CpG)n repeats must possess a DNA conformation that has a deleterious structural effect.

Abstract: Human chromosome 16-specific low-abundance repetitive (CH16LAR) DNA sequences have been identified during the course of constructing a physical map of this chromosome. At least three CH16LAR sequences exist and they are interspersed, in small clusters, over four regions that constitute more than 5% of the chromosome. CH16LAR sequences were observed in one unusually large cosmid contig (number 55), where the ordering of clones was difficult because these sequences led to false overlaps between noncontiguous clones. Contig 55 contains 78 clones, or approximately 2% of all the clones contained within the present cosmid contig physical map. Fluorescent in situ hybridization of multiple clones, including cosmid and YAC contig 55 clones, mapped the four CH16LAR-rich regions to bands p13, p12, p11, and q22. These regions are of biological interest since the pericentric inversion and the interhomologue translocation breakpoints commonly found in acute nonlymphocytic leukemia (ANLL) subtype M4 fall within these bands. Sequence analysis of a 2.2-kb HindIII fragment from a cosmid containing a CH16LAR sequence indicated that one of the CH16LAR elements is similar to a minisatellite sequence in that the core repeat is only 40 bp in length. Additional characterization of other repetitive elements is in progress.

Abstract: A cosmid contig physical map of human chromosome 16 has been developed by repetitive sequence finger-printing of approximately 4000 cosmid clones obtained from a chromosome 16-specific cosmid library. The arrangement of clones in contigs is determined by (1) estimating cosmid length and determining the likelihoods for all possible pairwise clone overlaps, using the fingerprint data, and (2) using an optimization technique to fit contig maps to these estimates. Two important questions concerning this contig map are how much of chromosome 16 is covered and how accurate are the assembled contigs. Both questions can be addressed by hybridization of single-copy sequence probes to gridded arrays of the cosmids. All of the fingerprinted clones have been arrayed on nylon membranes so that any region of interest can be identified by hybridization. The hybridization experiments indicate that approximately 84% of the euchromatic arms of chromosome 16 are covered by contigs and singleton cosmids. Both grid hybridization (26 contigs) and pulsed-field gel electrophoresis experiments (11 contigs) confirmed the assembled contigs, indicating that false positive overlaps occur infrequently in the present map. Furthermore, regional localization of 93 contigs and singleton cosmids to a somatic cell hybrid mapping panel indicates that there is no bias in the coverage of the euchromatic arms.

Abstract: A panel of 54 mouse/human somatic cell hybrids, each possessing various portions of chromosome 16, was constructed; 46 were constructed from naturally occurring rearrangements of this chromosome, which were ascertained in clinical cytogenetics laboratories, and a further 8 from rearrangements spontaneously arising during tissue culture. By mapping 235 DNA markers to this panel of hybrids, and in relation to four fragile sites and the centromere, a cytogenetic-based physical map of chromosome 16 with an average resolution of 1.6 Mb was generated. Included are 66 DNA markers that have been typed in the CEPH pedigrees, and these will allow the construction of a detailed correlation of the cytogenetic-based physical map and the genetic map of this chromosome. Cosmids from chromosome 16 that have been assembled into contigs by use of repetitive sequence fingerprinting have been mapped to the hybrid panel. Approximately 11% of the euchromatin is now both represented in such contigs and located on the cytogenetic-based physical map. This high-resolution cytogenetic-based physical map of chromosome 16 will provide the basis for the cloning of genetically mapped disease genes, genes disrupted in cytogenetic rearrangements that have produced abnormal phenotypes, and cancer breakpoints.

Abstract: SCORE, a program for computer-assisted scoring of Southern blots of clone DNA, retains the use of expert human judgment while taking over much of the drudgery of the scoring task. The primary functions of the program are to help make an aligned overlay of the fluorescence gel image and the autoradiogram blot image, to keep track of band and lane locations and to store the resulting data directly into a database. Use of SCORE has resulted in greatly increased efficiency and accuracy.

Abstract: Mapping of 33 anonymous DNA probes and 12 genes to the long arm of chromosome 16 was achieved by the use of 14 mouse/human hybrid cell lines and the fragile site FRA16B. Two of the hybrid cell lines contained overlapping interstitial deletions in bands q21 and q22.1. The localization of the 12 genes has been refined. The breakpoints present in the hybrids, in conjunction with the fragile site, can potentially divide the long arm of chromosome 16 into 16 regions. However, this was reduced to 14 regions because in two instances there were no probes or genes that mapped between pairs of breakpoints.

Abstract: The dinucleotide repetitive sequence, (GT)n, is highly interspersed in eukaryotic genomes and may have functional roles in genetic recombination or the modulation of transcriptional activity. We have examined the distribution and conservation of position of GT repetitive sequences in several mammalian genomes. The distribution of GT repetitive sequences in the human genome was determined by the analysis of over 3700 cosmid clones containing human insert DNA. On average, a GT repetitive sequence occurs every 30 kb in DNA from euchromatic regions. GT repetitive sequences are significantly underrepresented in centric heterochromatin. The density of GT repetitive sequences in the human genome could also be estimated by analyzing GenBank genomic sequences that include introns and flanking sequences. The frequency of GT repetitive sequences found in GenBank human DNA sequences was in close agreement with that obtained by experimental methods. GenBank genomic sequences also revealed that (GT)n repetitive sequences (n greater than 6) occur every 18 and 21 kb, on average, in mouse and rat genomes. Comparative analysis of 31 homologous sequences containing (GT)n repetitive sequences from several mammals representing four orders revealed that the positions of these repeats have been conserved between closely related species, such as humans and other primates. To a lesser extent, positions of GT repetitive sequences have been conserved between species in distantly related groups such as primates and rodents. The distribution and conservation of GT repetitive sequences is discussed with respect to possible functional roles of the repetitive sequence.

Abstract: The hypothesis that trans-acting factors affect chromosome stability was explored using human X Chinese hamster somatic cell hybrids. Two types of hybrids were examined. In either case, the human parent consisted of human diploid fibroblasts, the chromosomes of which tended to be lost from the hybrid cell. Comparisons were made between hybrid clones in which the hamster parent had a very stable karyotype (line CHO) and clones from a hamster parent with an unusual ongoing unstable karyotype (line CHX). Chinese hamster-human hybrid cell clones were expanded, and metaphase spreads were analyzed with an in situ hybridization procedure that uses biotin-labeled human genomic DNA as probe. Analyses of chromosome numbers and interspecies translocations were made after 20, 60, and 100 population doublings. Throughout the experiments, the generation of human-hamster-translocated chromosomes was more frequent in the hybrid cells with the CHX background. In addition, these cells also generated human acentric fragments, which were rare in cells with the CHO background. These results favor explanations for the instability of the CHX line that involve ongoing production of a diffusible clastogenic factor.

Abstract: We have developed an approach for identifying overlapping cosmid clones by exploiting the high density of repetitive sequences in complex genomes. Individual clones are fingerprinted, using a combination of restriction enzyme digestions followed by hybridization with selected classes of repetitive sequences. This "repeat fingerprinting" technique allows small regions of clone overlap (10-20%) to be unambiguously assigned. We demonstrate the utility of this approach, using the fingerprinting of 3145 cosmid clones (1.25 x coverage), containing one or more (GT)n repeats, from human chromosome 16. A statistical analysis was used to link these clones into 460 contiguous sequences (contigs), averaging 106 kilobases (kb) in length and representing approximately 54% (48.7 Mb) of the euchromatic arms of this chromosome. These values are consistent with theoretical calculations and indicate that 150- to 200-kb contigs can be generated with 1.5 x coverage. This strategy requires the fingerprinting of approximately one-fourth as many cosmids as random strategies requiring 50% minimum overlap for overlap detection. By "nucleating" at specific regions in the human genome, and exploiting the high density of interspersed sequences, this approach allows (i) the rapid generation of large (greater than 100-kb) contigs in the early stages of contig mapping and (ii) the production of a contig map with useful landmarks for rapid integration of the genetic and physical maps.

Abstract: The functional human metallothionein (MT) genes are located on chromosome 16q13. We have physically mapped the functional human MT locus by isolation and restriction digest mapping of cloned DNA. The mapped region contains all sequences on chromosome 16 that hybridize to metallothionein gene probes and comprises 14 tightly linked MT genes, 6 of which have not been previously described. This analysis defines the genetic limits of metallothionein functional diversity in the human genome.

Abstract: Myogenin is a member of a family of muscle-specific regulatory factors which includes MyoD1, Myf-5, and Myf-6 (also called MRF4 and herculin). Extensive regions of sequence homology in genes for these three factors suggest duplication events associated with their evolution. In the present study, the chromosomal location of the myogenin gene in humans (MYOG), mice (Myog), and Chinese hamsters (MYOG) was determined using in situ hybridization to human metaphase chromosomes as well as segregation analysis among interspecific somatic cell hybrid panels and interspecific backcrossed mice. We localize the gene encoding myogenin to human chromosome 1q31-q41 within a linkage group homologous with a region on mouse chromosome 1 and Chinese hamster chromosome 5. The results verify the nonlinkage of MYOG to MYOD1, MYF5, and MYF6 genes and indicate that events associated with the duplication of MYOG with respect to MYOD1, MYF5, or MYF6 loci were not chromosome-wide.

Abstract: The adenosine deaminase (ADA) locus appears to be under complex transcriptional control since levels of ADA enzyme activity vary greatly between different tissues and stages of development. Evidence that a trans-acting factor may be involved with the regulation of this locus came from previous experiments where fusion of ADA-negative human JEG cells and mouse ADA-positive cells led to the trans-activation of human ADA in a hybrid nucleus. Here, we demonstrate that the near euploid mouse embryo fibroblast cell line, CAK, also lacks detectable ADA enzyme activity due to altered gene regulation. We further demonstrate that ADA in CAK cells is not amenable to activation by somatic cell fusion. Following treatment with 5-azacytidine and Xyl-A selection (for ADA), however, CAK clones were obtained that stably express the ADA gene. Molecular analysis of the parental CAK cells and the ADA-positive derivative clones demonstrated that both 5' and 3' regions of the ADA gene had become hypomethylated in the ADA+ clones. We conclude that methylation is another element involved with the transcriptional control of the ADA gene and that ADA might serve as a useful model for studying the interaction of cis- and trans-acting regulational elements.

Abstract: The mouse downless (dl) gene is a morphogenetic gene that plays a role in dermal-epidermal interaction and regulation of hair follicle induction during fetal development. We report here the identification of a transgenic mouse line with an insertional mutation in the dl gene. The genomic sequences flanking the transgenic insert have been cloned and used as hybridization probes to confirm that the mutant transgenic mice are homozygous for the transgenic insert and that the site of integration lies on mouse chromosome 10. Genomic probes that are close to or within the downless gene are now available and should permit the characterization of a gene that is involved in induction of a specific type of epithelial morphogenesis.

Abstract: A human DNA repair gene, ERCC2 (Excision Repair Cross Complementing 2), was assigned to human chromosome 19 using hybrid clone panels in two different procedures. One set of cell hybrids was constructed by selecting for functional complementation of the DNA repair defect in mutant CHO UV5 after fusion with human lymphocytes. In the second analysis, DNAs from an independent hybrid panel were digested with restriction enzymes and analyzed by Southern blot hybridization using DNA probes for the three DNA repair genes that are located on human chromosome 19: ERCC1, ERCC2, and X-Ray Repair Cross Complementing 1 (XRCC1). The results from hybrids retaining different portions of this chromosome showed that ERCC2 is distal to XRCC1 and in the same region of the chromosome 19 long arm (q13.2-q13.3) as ERCC1, but on different MluI macrorestriction fragments. Similar experiments using a hybrid clone panel containing segregating Chinese hamster chromosomes revealed the hamster homologs of the three repair genes to be part of a highly conserved linkage group on Chinese hamster chromosome number 9. The known hemizygosity of hamster chromosome 9 in CHO cells can account for the high frequency at which genetically recessive mutations are recovered in these three genes in CHO cells. Thus, the conservation of linkage of the repair genes explains the seemingly disproportionate number of repair genes identified on human chromosome 19.

Abstract: The genes for the M2 subunit of ribonucleotide reductase (RRM2), ornithine decarboxylase (ODC1), and 55,000-Daltons protein (P5), are amplified in hydroxyurea-resistant hamster and human cell lines. These genomic sequences have been mapped to hamster chromosome 7 and to human chromosome 2p24-25 near the cytogenetic location of the N-myc gene. We now report that genomic sequences homologous to N-myc are amplified in hydroxyurea-resistant hamster lung cell line, 600H, and the N-myc gene segregates with hamster chromosome 7 in mouse-hamster somatic cell hybrids. The conserved linkage group consisting of the RRM2, ODC1, P5, and N-myc in the hamster and human genomes prompted our investigation of human neuroblastomas. We report here that genomic DNA from 1 of 6 primary neuroblastoma tumors containing amplified N-myc also contains amplified sequences homologous to a hamster ODC cDNA.

Abstract: The human chromosomal assignments of genes of the creatine kinase (CK) family--loci for brain (CKBB), muscle (CKMM), and mitochondrial (CKMT) forms--were studied by Southern filter hybridization analysis of DNAs isolated from a human x rodent somatic cell hybrid clone panel. Probes for the 3'-noncoding sequences of human CKBB and CKMM hybridized concordantly only to DNAs from somatic cell hybrids containing chromosomes 14 and 19, respectively. Thus the earlier assignment of the gene coding for the CKBB isozyme to chromosome 14 was confirmed by molecular means, as was the provisional assignment of CKMM to the long arm of chromosome 19. A probe containing canine sequences for CKMM cross-hybridized with human sequences on chromosomes 14 and 19, a result consistent with the assignments of CKBB and CKMM. A probe containing human sequences for CKMT enabled the provisional assignment of CKMT to human chromosome 15. Independent hybrids with portions of the long arm of chromosome 19 missing indicated the order of genes on the long arm of chromosome 19 as being cen-GPI-(TGFB, CYP1)-[CKMM, (APOC2-ERCC1)]-(CGB, FTL). The unexpectedly more distal location of APOC2 among the genes on the long arm--and APOC2's close association with CKMM--is discussed with respect to the close linkage relationship of APOC2 to myotonic muscular dystrophy.

Abstract: We have shown previously that cDNAs for the M1 and M2 subunits of ribonucleotide reductase, ornithine decarboxylase (ODC), and p5-8, a 55,000-Dalton protein, hybridize to amplified genomic sequences in a highly hydroxyurea-resistant hamster cell line. We have extended these observations to include two additional, independently isolated, hydroxyurea-resistant cell lines: SC8, a single-step hamster ovary cell line, and KH450, a multistep human myeloid leukemic cell line, have also undergone genomic amplification for sequences homologous to ODC and p5-8 cDNAs. However, neither SC8 nor KH450 contains amplified genomic sequences homologous to an M1 cDNA probe. A panel of mouse-hamster somatic cell hybrids was used to map sequences homologous to M1, M2, ODC, and 5-8 cDNAs in the hamster genome. The M2, ODC, and p5-8 cDNAs hybridized to DNA fragments that segregated with hamster chromosome 7. In contrast, M1 cDNA hybridized to DNA fragments that segregated with hamster chromosome 3. These data suggest that the genes RRM2, (M2), ODC, and p5-8, but not RRMI (M1), are linked and may have been co-amplified in the selection of the hydroxyurea-resistant hamster and human cell lines.

Abstract: HRAS and KRAS are the cellular homologs of the oncogenic transforming genes found in the Harvey strain of murine sarcoma virus and the Kirsten murine sarcoma virus, respectively. Phyla as diverse as insects, birds, and mammals possess distinct HRAS and KRAS sequences, suggesting that these genes are essential to metazoa. In this report, we used a clone panel of Chinese hamster X mouse C11D somatic cell hybrids segregating hamster chromosomes to map those genes. Southern filter hybridization analyses of the hybrids revealed that hamster HRAS and KRAS gene sequences are on chromosomes 3 and 8, respectively. These gene assignments are consistent with the conservation of autosomal gene linkage groups observed among hamsters, humans, and mice and may provide insight into specific chromosomal alterations that have been observed during the spontaneous neoplastic transformation of Chinese hamster fibroblasts in vitro.

Abstract: Previous studies have shown both hypermethylation and late replication of DNA sequences to be associated with gene inactivity. To determine whether there is a causal relationship between patterns of DNA methylation and replication timing during S phase, we have examined the timing of replication of the inactive, hypermethylated metallothionein (MT) I and II genes in synchronized, cadmium-sensitive (Cds) CHO cells. The time of S-phase replication of the MT genes was ascertained by determining the period of S phase wherein cadmium-resistant (Cdr) cells could be induced with highest frequency by pulse treatment of synchronized Cds cells with the hypomethylating drug 5-azacytidine (5-aza-CR), and by analyzing Southern blots of density fractionated DNAs isolated from synchronized cells pulse-labeled with BrdU during different intervals after release from hydroxyurea blockade. Southern filter hybridization analyses demonstrated replication of both MTI and II gene sequences within the first half of S phase. Consistent with this result, phenotypic conversion of Cds to Cdr was maximal immediately after hydroxyurea release and decreased abruptly within three hours. The replication of inactive hypermethylated MT genes in early S phase argues that transcriptional inactivity and gene-specific hypermethylation are not sufficient conditions for late DNA replication.

Abstract: Gene amplification has been associated with multidrug resistance (MDR) in several drug-resistant Chinese hamster ovary (CHO) cell lines which exhibit cross-resistance to other unrelated, cytotoxic drugs. In situ hybridization studies (Teeter et al., J. Cell Biol., in press) suggested the presence of an amplified gene associated with the MDR phenotype on the long arm of either of the largest CHO chromosomes (1 or Z1) in vincristine-resistant cells. In this study, somatic cell hybrids were constructed between these vincristine-resistant CHO cells and drug-sensitive murine cells to determine the functional relationship between the chromosome bearing the amplified sequences and the MDR phenotype. Hybrids exhibited primary drug resistance and MDR in an incomplete dominant fashion. Hybrid clones and subclones segregated CHO chromosomes. Concordant segregation between vincristine resistance, the MDR phenotype, the presence of the MDR-associated amplified sequences, overexpression of the gene located in those sequences, and CHO chromosome Z1 was consistent with the hypothesis that there is an amplified gene on chromosome Z1 of the vincristine-resistant CHO cells which is responsible for the MDR in these cells. A low level of discordance between CHO chromosomes Z8 and 2 and the drug resistance phenotype suggests that these chromosomes may contain genes involved with the MDR phenotype.

Abstract: Proto-oncogenes, which represent the cellular progenitors of the transforming genes harbored by acute transforming oncogenic retroviruses, have been highly conserved during vertebrate evolution. In this report, we have assigned experimentally a subset of proto-oncogenes (SRC, ABL, FES, and FMS-all related to the SRC family) to Chinese hamster chromosomes by Southern filter hybridization analyses of DNAs isolated from both somatic cell hybrids and flow-sorted hamster chromosomes. These results demonstrate that several autosomal linkage groups containing proto-oncogenes originated prior to the radiation and speciation of mammals and have remained remarkably stable for nearly 80 million years.

Abstract: We describe here the derivation, characterization, and use of clonal cadmium-resistant (Cdr) strains of the Chinese hamster cell line CHO which differ in their metallothionein (MT) induction capacity. By nondenaturing polyacrylamide gel electrophoresis, we showed that the stable Cdr phenotype is correlated with the augmented expression of both isometallothioneins (MTI and MTII). In cells resistant to concentrations of CdCl2 exceeding 20 microM, coordinate amplification of genes encoding both isometallothioneins was demonstrated by using cDNA MT-coding sequence probes and probes specific for 3'-noncoding regions of Chinese hamster MTI and MTII genes. Molecular and in situ hybridization analyses supported close linkage of Chinese hamster MTI and MTII genes, which we have mapped previously to Chinese hamster chromosome 3. This suggests the existence of a functionally related MT gene cluster in this species. Amplified Cdr variants expressing abundant MT and their corresponding Cds parental CHO cells should be useful for future studies directed toward elucidating the mechanisms that regulate expression of the isometallothioneins.

Abstract: The 2,3,7,8-tetrachlorodibenzo-p-dioxin-inducible cytochrome P-450 gene family (P1-450 and P3-450 in the C57BL/6N mouse) has recently been localized to mouse chromosome 9. In the present study, HindIII-digested DNA from Chinese hamster, mouse, and 20 Chinese hamster X mouse somatic cell hybrids and subclones segregating hamster chromosomes was probed with the mouse P1-450 and P3-450 full-length cDNA clones. Hamster P-450 gene fragments (6.0 and 7.4 kb) were assigned to Chinese hamster chromosome 4. These data are consistent with linkage conservation among these two P-450 sequences and four other loci on mouse chromosome 9 that map to hamster chromosome 4.

Abstract: The Chinese hamster genes ADK, NP, ESD, PGM2, PEPS, PEPB, GLO, and GSR, all of which are on Chinese hamster chromosome 1, were assigned to CHO-LA chromosomes by analysis of the segregation of CHO isozymes and chromosomes from interspecific somatic cell hybrids made with CHO cells and mouse C11D cells. One allele of each of these eight loci remained linked on the normal chromosome 1 homolog. For seven loci, the other allele remained linked on chromosome Z1, but ESD was shown to have been translocated to chromosome Z6 (Chinese hamster chromosome 5q +). Ag-NOR staining of CHO chromosomes indicated that the (1;5) translocation was very likely reciprocal, since the Chinese hamster chromosome 5, which gave rise to the CHO Z6, lacks an NOR and the Z1 now has one. These data allowed regional assignment of ESD to the distal portion of Chinese hamster chromosome 1p and provided genetic evidence for the origin of CHO chromosomes Z1 and Z6 from Chinese hamster chromosomes 1 and 5. Induced electrophoretic shift mutations of ESD and positive Ag-NOR staining for the rRNA genes on the Z1 showed that the activities of the genes lying close to the translocation breakpoints were maintained.

Abstract: Concordant segregation analysis of Chinese hamster (Cricetulus griseus) isozymes and chromosomes segregating from hamster X mouse interspecific somatic cell hybrids revealed that loci for ME1, PGM3, MPI, and PKM2 are located on Chinese hamster chromosome 4. Synteny of these loci in hamsters provides additional evidence for the conservation of mammalian autosomal linkage groups.

Abstract: Analysis of CHO electrophoretic mobility shift mutants for six enzyme loci ( LDHA , GAA, IDH2 , ME1, PGM3, and MPI) that have been previously mapped to Chinese hamsters chromosomes 3 and 4 indicated that each of these loci, with the exception of IDH2 , are functionally dizygous in CHO. Segregation analysis of CHO X mouse somatic cell hybrids allowed regional gene mapping assignments for a total of eight Chinese hamster chromosome 3- or 4-derived marker loci (the above six, plus APRT and PKM2) to CHO chromosomes Z3 , Z4 , Z5 , and Z7 . For seven of these enzyme loci (all but IDH2 ), two alleles are expressed in CHO cells, each segregating with a different Z-group chromosome. These gene mapping assignments confirm genetically that CHO chromosomes Z3 , Z4 , Z5 , and Z7 are, in fact, derived from Chinese hamster chromosomes 3 and 4, and provide insight into the effects of chromosomal rearrangements on gene expression and hemizygosity in CHO cells.

Abstract: Similarity of G-band patterns between the long arm of Chinese hamster chromosome 6 and mouse chromosome 2, combined with the assignments of AK1, ADA, and ITPA to hamster chromosome 6 and AK1 to mouse chromosome 2, suggested mouse chromosome 2 also might contain ADA and ITPA. Here, concordant segregation analysis of enzyme loci and chromosomes in mouse spleen X CHO as well as mouse microcell X CHO somatic cell hybrids established the assignments of ADA and ITPA onto mouse chromosome 2 in the region between the first G-band and the terminus (C1----ter). This assignment presents a demonstration of the conservation and evolution of enzyme and proto-oncogene loci linkage since two cellular homologs of viral oncogenes--c-src and c-abl--also map to mouse chromosome 2. In humans c-src, ADA, and ITPA remain conserved on chromosome 20, whereas AK1 and c-abl are together on chromosome 9. These observations and concepts are discussed with respect to the role of proto-oncogenes in chromosomal evolution and suggest the long arm of chromosome 6 as a fruitful place to look for c-src and c-abl in the Chinese hamster.

Abstract: Cadmium resistant (Cdr) variants with coordinately amplified metallothionein I and II (MTI and MTII) genes have been derived from both Chinese hamster ovary and near-euploid Chinese hamster cell lines. Cytogenetic analyses of Cdr variants consistently revealed breakage and rearrangement involving chromosome 3p. In situ hybridization with a Chinese hamster MT-encoding cDNA probe localized amplified MT gene sequences near the translocation breakpoint involving chromosome 3p. These observations suggested that both functionally related, isometallothionein loci are linked on Chinese hamster chromosome 3. Southern blot analyses of DNAs isolated from a panel of Chinese hamster X mouse somatic cell hybrids which segregate hamster chromosomes confirmed that both MTI and MTII are located on chromosome 3. We speculate that rearrangement of chromosome 3p could be causally involved with the amplification of MT genes in Cdr hamster cell lines.

Abstract: Interspecific somatic cell hybrids were generated by fusion of Chinese hamster spleen cells or primary fibroblasts with cells from an adenine phosphoribosyltransferase (APRT)-deficient mouse subline derived from LMTK- Cl.1D. Subclones which had been selected for either retention or loss of APRT were subjected to combined isozyme and chromosome segregation analysis. Concordant expression or segregation of Chinese hamster APRT, lactate dehydrogenase A (LDHA), isocitrate dehydrogenase 2 (IDH2), and alpha-glucosidase (GAA) with Chinese hamster chromosome 3 allowed provisional assignment of all four loci to that chromosome. Exceptional subclones, in which coordinate segregation of these syntenic markers was disrupted by chromosome breakage or deletions, allowed further localization of these genes to specific regions of the 3 chromosome.

Abstract: The effects of chromosomal rearrangements on gene function and mutation are poorly understood. Although the extensive conservation of autosomal linkage among diverse mammals may indicate physiological significance for some gene arrangements, the majority of linkages have probably been conserved by chance. The establishment of a Chinese hamster gene map has provided further evidence for the conservation of mammalian autosomal linkage and the study of gene rearrangements in cultured Chinese hamster cell lines is beginning to provide information on the genetic consequences of chromosomal rearrangements.

Abstract: Concordant segregation analysis of Chinese hamster (Cricetulus griseus) isozymes and chromosomes segregating from interspecific somatic cell hybrids made with mouse C11D cells revealed the locations of GPI and PEPD on chromosome 9 and TPI on chromosome 8 in both euploid Chinese hamster and CHO cells. The patterns of electrophoretically detectable shift mutants of these loci in CHO cells were consistent with the observed presence of two normally banded chromosome 8's and monosomy for chromosome 9. These findings and the isolation of three independent, null PEPD mutants in only 527 ethyl methansulfonate-exposed clones indicate that the high frequency of recovery of recessive drug resistant mutants in CHO cells may be due not only to haploidy caused by deletions and monosomy but also by great sensitivity of certain loci to particular mutagens.

Abstract: The CHO-AT3-2 Chinese hamster ovary cell line is functionally hemizygous for the adenine phosphoribosyltransferase (APRT; EC 2.4.2.7) locus. Class 1 APRT +/- heterozygotes, such as CHO-AT3-2, can be isolated at high spontaneous frequencies from wild-type CHO cell populations. Simon et al. [Simon, A. E., Taylor, M. W., Bradley, W. E. C. & Thompson, L. (1982) Mol. Cell. Biol. 2, 1126-1133] have proposed that a high-frequency event that inactivates one APRT allele might be responsible for both the spontaneous generation of class 1 APRT +/- heterozygotes and the high-frequency occurrence of APRT- mutants in class 2 APRT +/- heterozygote populations. This event appears to occur at only one of the two APRT alleles. To investigate the nature of this high-frequency event, and to determine the genetic basis for functional hemizygosity of the APRT locus in CHO-AT3-2 cells, we have mapped the APRT locus by using CHO-AT3-2-mouse somatic cell hybrids. Our data confirm that CHO-AT3-2 cells have a single functional APRT allele, which is located on the Z7 chromosome. Karyotypic analysis of CHO-AT3-2 revealed an interstitial deletion on the long arm of the Z4 chromosome, in the very region where the other APRT allele should be located. To determine whether the Z4q interstitial deletion had resulted in physical loss of the APRT gene, DNA from CHO-AT3-2-mouse cell hybrids that had either lost or retained the Z4q- chromosome was analyzed for the presence of CHO APRT coding sequences. Our data suggest that allele-specific high-frequency structural gene deletion events involving the long arm of chromosome Z4 are responsible for the spontaneous generation of functional hemizygosity at the APRT locus in CHO cells.

Abstract: Polyethylene glycol-mediated fusion of Chinese hamster ovary (CHO) cells with mouse Cl1D cells produced interspecific somatic cell hybrids which slowly segregated CHO chromosomes. Cytogenetic and isozyme analysis of HAT- and bromodeoxyuridine-selected hybrid subclones and of members of a hybrid clone panel retaining different combinations of CHO chromosomes enabled provisional assignments of the following enzyme loci to CHO chromosomes: TK, GALK, and ACP1 to chromosome 7; TK and GALK to chromosome Z13; ACP1, ADA, and ITPA to chromosome Z8; and ADA and ITPA to chromosome Z9. These genetic markers reflect the origin of each of these Z group chromosomes and indicate the functional activity of alleles located on rearranged chromosomes. Identification of diploid electrophoretic shift mutations for ADA and ITPA was consistent with those observations. Assignment of the functional TK locus in TK+/- CHO-AT3-2 cells indicated that gene deletion may be responsible for TK hemizygosity in this subline.

Abstract: Fourteen independent somatic cell hybrid clones made between diphtheria toxin (DT)-resistant mouse Cl1D cells and DT-sensitive Chinese hamster ovary (CHO) cells slowly segregated CHO chromosome. Concordant segregation analysis of electrophoretically resolvable Chinese hamster chromosome 2 gene products and CHO chromosomes 2 and Z2 (having q1-q24 deletion) in DT-selected and control hybrid subclones was conducted. Analysis revealed that loci for DT sensitivity and galactose-1-phosphate uridyltransferase could be regionally assigned to Chinese hamster chromosome 2q1-24 and were physically hemizygous in CHO cells. Enolase (ENO1), 6 phosphogluconate dehydrogenase (PGD), and phosphoglucomutase 1 (PGM1) were located outside the q1-24 region on Chinese hamster chromosome 2 and were dizygous in CHO cells. Functional dizygosity of ENO1, PGD, and PGM1 in CHO cells, as determined by the isolation of diploid heterozygous electrophoretic shift mutants following UV and EMS exposure, confirmed their location outside the Z2 deletion and indicated that the deletion did not result in the inactivation of adjacent loci. These results are discussed in relation to current theories on the basis for high frequency of drug-resistant autosomal recessive mutants in CHO cells and conservation of mammalian autosomal linkage groups.

Abstract: Interspecific somatic cell hybrids formed by fusion of mouse Cl1D cells with Chinese hamster primary spleen or fibroblast cells were used to form a clone panel with members retaining different combinations of Chinese hamster chromosomes and isozyme markers. Concordant segregation analysis of isozymes and chromosomes among clone panel members enabled the provisional assignment of ADA, ITPA, and AK1 to Chinese hamster chromosome 6. Diphtheria toxin selection for Chinese hamster chromosome 2 segregants in Dede cell X Cl1D somatic cell hybrids indicated AK2 is located on chromosome 2. These assignments extend observations of autosomal linkage group conservation in mammals--a concept further supported by similarity of G-band patterns in certain chromosomal regions bearing homologous loci in Chinese hamsters, humans, and mice.

Abstract: PEG-mediated fusion between mouse Cl1d cells and primary Chinese hamster spleen cells produced interspecific hybrids which slowly and nonrandomly segregated Chinese hamster chromosomes. Cytogenetic and isozyme analysis (31 loci) of HAT and BrdU selected hybrid clones and subclones and of members of a hybrid clone panel retaining different combinations of Chinese hamster chromosomes enabled provisional assignment of the following enzyme loci on Chinese hamster chromosomes: thymidine kinase, galactokinase, and acid phosphatase-1 to chromosome 7; galactose-1-phosphate uridyltransferase to chromosome 2; and adenosine kinase, esterase D, glutathione reductase, glyoxalase, nucleoside phosphorylase, peptidases B and S, and phosphoglucomutase (PGM) 2 to chromosome 1. Assignments of PGM1, 6-phosphogluconate dehydrogenase, and enolase 1 to chromosome 2 were confirmed, and a chromosome 2 deletion (q23-q33) enabled the provisional assignment of PGM1 to that region. The assignments provide markers for the study of the genetic consequences of chromosomal rearrangements in Chinese hamster cell lines and support the concept of conservation of mammalian autosomal linkage groups.

Abstract: A series of Chinese hamster cell lines commonly used in somatic cell genetics research was examined for variations in either expression or electrophoretic mobility of 43 enzyme gene products by starch gel electrophoresis followed by histochemical staining. Stable variations in the qualitative expressions of the creatine kinase B and adenylate kinase 1 (AK1) loci were detected among the cell lines and verified in subclones. All ten cell lines examined were deficient in the expression of the lactate dehydrogenase B locus. Polymorphisms were detected for the adenosine deaminase (ADA) and AK2 loci among the cell lines and shown to exist in a series of Chinese hamsters. Electrophoretic banding patterns from tissues, sublines, and subclones of the same genetic source and Hardy-Weinberg distribution of phenotypes from different genetic sources confirmed that the polymorphisms were based on its inheritance of two codominant autosomal ADA and AK2 alleles that specified electrophoretically variant enzymes.