Abstract: A strategy for the selective in vivo activation of prodrugs by proteases is presented. The approach is based on the design of polythiol peptides able to neutralize the toxicity of As(III) through chelation, and contemporarily to be recognized as substrates of a disease-linked specific protease. Enzyme digestion implies conversion of such polythiol peptides into monothiol fragments with irreversible loss of the ability to chelate the metalloid, thus triggering the release in its free and pharmacologically effective form. The proteases whose activity appears dramatically up-regulated in various pathologies, ranging from cancer to infectious diseases, can be conveniently employed as prodrug activators in the disease microenvironment. The design of the representative peptide shown here has been assisted by molecular modeling in order to fulfill the dual characteristic to be an efficient As(III) chelator and simultaneously a substrate of the matrix metalloproteinase-9 (MMP-9) whose activity results dramatically increased at the surface of cells affected by several pathologies.

Abstract: One strategy in the development of anticancer therapeutics has been to arrest malignant proliferation through inhibition of the enzymatic activity of cyclin-dependent kinases (cdks), which are key regulatory molecules of the cell cycle. Over the past few years, numerous compounds with remarkable cdk inhibitory activity have been studied in cancer therapy, although it is very difficult to point out the best cdk to target. An excellent candidate appears to be cdk2, whose alteration is a pathogenic hallmark of tumorigenesis. The small molecule described in our study showed an inhibitory effect on the kinase activity of cdk2, a significant growth arrest observed in a colony formation assay and a reduction in the size of the tumor in nude mice, thus suggesting its potential role as a promising new type of mechanism-based antitumor drug, also for the treatment of hyperproliferative disorders.

Abstract: We investigated several phenotypic and functional parameters of T cell-mediated immunity in a large series of common variable immunodeficiency (CVID) patients. We demonstrated that the vast majority of CVID patients presented multiple T cell abnormalities intimately related among them, the severity of which was reflected in a parallel loss of CD4+ naive T cells. A strong correlation between the number of CD4+ naive T cells and clinical features was observed, supporting the subgrouping of patients according to their number of naive CD4+ T lymphocytes. A reduced thymic output and disrupted CD4+ and CD8+ TCR repertoires paralleled the contraction of CD4+ naive T cell pools. The evaluation of activation markers and cytokine production indicated a strong T cell activation that was significantly related to the increased levels of T cell turnover and apoptosis. Finally, discrete genetic profiles could be demonstrated in groups of patients showing extremely diverse T cell subset composition and function. Naive CD4+ T cell levels were significantly associated with the switched memory B cell-based classification, although the concordance between the respective subgroups did not exceed 58.8%. In conclusion, our data highlight the key role played by the T cell compartment in the pathogenesis of CVID, pointing to the need to consider this aspect for classification of this disease.

Abstract: The viral factor E7 plays a key role in the well-established association between "high-risk" Human Papillomavirus (HPV) infection and the development of epithelial malignant tumors, as uterine cervix and ano-genital cancer. To delve into the molecular mechanisms of HPV-mediated cell transformation, we searched for novel potential cellular targets of the HPV-16 E7 oncoprotein, by means of the yeast two-hybrid technique, identifying a protein-protein interaction between HPV-16 E7 and the pro-apoptotic cellular factor Siva-1. Using co-precipitation assays and the "PepSets" technique, we confirmed this physical interaction and mapped accurately, for both proteins, the amino acid residues involved. Additionally, we found that HPV-16 E7 competed in vitro with the binding of the Bcl-X(L) anti-apoptotic factor to Siva-1, an interaction that has a major inference in UV radiation-induced apoptosis. In HaCaT immortalized human keratinocytes, forced HPV-16 E7 expression by retroviral infection caused Siva-1 transcript up-regulation, detected by cDNA macroarray hybridization and real-time quantitative PCR, paralleled by an increased amount of protein. Confirming the anti-apoptotic role of HPV-16 E7 in the HaCaT cellular model, evaluated by nuclear morphology, we also found that Siva-1 expression produced a significant increase of the apoptotic rate in UV radiation-exposed HaCaT cells, and that this effect resulted explicitly counteracted by HPV-16 E7. Being apoptosis a key physiological process for the elimination of irreversibly injured cells, the anti-apoptotic role of HPV-16 E7, performed at least by its interference with Siva-1, can be considered an additional mechanism for the survival of damaged, potentially transforming, cell clones.

Abstract: Retinoblastoma (RB) family proteins pRb, p107 and pRb2/p130 are important cellular factors which play a well-recognized role as tumor and growth suppressors. These proteins are actively involved in the negative control of the cell cycle and their function is modulated via complex homeostatic processes, most of them involving post-translational regulation of their phosphorylation status. Interestingly, the family members p107 and pRb2/p130 share the ability to physically interact and inhibit the kinase activity of the Cdk2/Cyclin A and Cdk2/Cyclin E complexes. Regarding pRb2/p130, its inhibitory effect on Cdk2/Cyclin A activity has been attributed to the "spacer" region. Recently, a 39 aa-long pRb2/p130 spacer-derived peptide (Spa310, aa 641-679) was selected as the sequence responsible for Cdk2/Cyclin A inhibition. Following the identification of this active sequence, here we propose a computer-generated three-dimensional model of the interaction between the Cdk2/Cyclin A complex and the N-terminal nine-amino acid sequence of the Spa310 peptide. We believe this model to be useful for the rational development of peptide or peptidomimetic kinase inhibitors for negative cell cycle modulation in cancer cells.

Abstract: The amount of information on tumor biology has expanded enormously, essentially due to the completion of the human genome sequencing and to the application of new technologies that represent an exciting breakthrough in molecular analysis. Often these data spring from experimental procedures, such as a serial analysis of gene expression (SAGE) and DNA microarrays, which cannot be defined as hypothesis-driven: it may appear to be a "brute force" approach through which no information can be directly generated concerning the specific functions of selected genes in a definite context. However, interesting results are fruitfully generated, and thus it is important to consider the enormous potential these new technologies possess and to learn how to apply this novel form of knowledge in the emerging field of molecular medicine. This review, after a limited outline regarding several classic aspects of human cutaneous melanoma biology, genetics, and clinical approaches, will focus on the proficient use of up-to-date technologies in the study of the neoplastic disease and on their capability to provide effective support to conventional approaches in melanoma diagnosis, prognosis, and treatment.

Abstract: Recently, after the identification of ferritin light chain (L-ferritin) gene and protein over-expression in human metastatic melanoma cells, we engineered, starting from the LM metastatic melanoma cell line, clones in which L-ferritin gene expression was down-regulated by the stable expression of a specific antisense construct. The present investigation started from the observation that L-ferritin down-regulated LM cells displayed a less pigmented phenotype, confirmed by a major decrease of total melanin, when compared to control LM cells. This finding was accompanied by a dramatic decrease in tyrosinase activity, which was not paralleled by a concomitant reduction of the amount of tyrosinase specific mRNA. Western blot analysis of tyrosinase in control LM cells displayed a pattern, which corresponds to the progressive glycosylation of the native protein up to the 80 kDa form, considered the functional one. Tyrosinase pattern assayed in L-ferritin down-regulated LM cells showed the remarkable absence of the 80 kDa form and a prevalence of endoglycosidase H (endo H)-sensitive immature (70 kDa) tyrosinase, accumulated in the endoplasmic reticulum (ER), as confirmed by confocal microscopy analysis. These results demonstrate that, in a human metastatic melanoma cell line, the stress condition promoted by L-ferritin down-modulation, can substantially influence proper maturation of tyrosinase.

Abstract: With the aim to find novel partners of human Cyclin T2a, we performed a two-hybrid screening in yeast using the full-length cDNA of this cyclin as bait, and a human heart cDNA library as preys source. Upon several interesting genes selected, our attention has been focused on the cDNA coding for PKNalpha, a fatty acid- and Rho-activated serine/threonine protein kinase, having a catalytic domain homologous to protein kinase C family. Co-immunoprecipitation and in vitro pull-down assays independently confirmed the interaction between the two proteins. Luciferase assays, performed on NIH3T3 cell extracts after transfection with a MyoD-responsive promoter, pointed out that PKNalpha was able to enhance MyoD-dependent transcription, and that this effect was further increased when cyclin T2a was co-overexpressed. Finally, overexpression of both Cyclin T2a and PKNalpha in C2C12 cells strongly enhanced the expression of myogenic differentiation markers, such as Myogenin and Myosin Heavy Chain, during starvation-induced differentiation. Taken together, our data strengthen the hypothesis that Cyclin T2a plays a role in muscle differentiation, and propose PKNalpha as a novel partner of Cyclin T2a in this process.

Abstract: High-risk human papillomaviruses (HPV) are linked to human cervical and other ano-genital cancers. Integration of the viral genome in the transformed epithelial cells is restricted to the coding regions for the E6 and E7 oncoproteins. Nevertheless, E7 plays the major role in cell transformation. We report a novel interaction between HPV-16 E7 and the Nm23-H1 and Nm23-H2 proteins identified in yeast by the two-hybrid system and confirmed by co-immunoprecipitation in the human keratinocyte HaCaT cell line. Expression of the E7 oncoprotein in HaCaT cells induces modified keratinocyte proliferation and differentiation patterns, and leads to down-modulation and functional inactivation of the metastasis suppressor Nm23-H1 protein. Both transcriptional down-regulation and protein degradation contribute to reduce Nm23-H1 intracellular content. Besides metastasis suppression, Nm23-H1 displays multiple functions in cell cycle regulation and differentiation, development, DNA regulation and caspase-independent apoptosis. As a consequence of Nm23-H1 inhibition, HPV-16 E7 expressing HaCaT cells, acquire invasiveness capabilities and resistance to granzyme A-induced apoptosis. We propose that impairment of the multifunctional role of Nm23-H1 is an important feature consistent with the complex strategy carried out by HPV-16 E7 to promote cell transformation and tumor progression.

Abstract: RB, the most investigated tumor suppressor gene, is the founder of the RB family of growth/tumor suppressors, which comprises also p107 (RBL1) and Rb2/p130 (RBL2). The protein products of these genes, pRb, p107 and pRb2/p130, respectively, are also known as 'pocket proteins', because they share a 'pocket' domain responsible for most of the functional interactions characterizing the activity of this family of cellular factors. The interest in these genes and proteins springs essentially from their ability to regulate negatively cell cycle processes and for their ability to slow down or abrogate neoplastic growth. The pocket domain of the RB family proteins is dramatically hampered in its functions by the interference of a number of proteins produced by the small DNA viruses. In the last two decades, the 'viral hypothesis' of cancer has received a considerable renewed impulse from the notion that small DNA viruses, such as Adenovirus, Human papillomavirus (HPV) and Polyomavirus, produce factors that can physically interact with major cellular regulators and alter their function. These viral proteins (oncoproteins) act as multifaceted molecular devices that have evolved to perform very specific tasks. Owing to these features, viral oncoproteins have been widely employed as invaluable experimental tools for the identification of several key families of regulators, particularly of the cell cycle homeostasis. Adenovirus early-region 1A (E1A) is the most widely investigated small DNA tumor virus oncoprotein, but relevant interest in human oncology is raised by the E1A-related E7 protein from transforming HPV strains and by Polyomavirus oncoproteins, particularly large and small T antigens from Simian virus 40, JC virus and BK virus.

Abstract: The cell cycle regulatory pathway responsible for the control of the late-G1 checkpoint is found recurrently altered in human malignant melanoma, often due to lack of functional p16 or pRb (pRb-1) proteins. Here we examined the ability of p16-derived peptides to mimic p16 function in two exemplary human melanoma cell lines: the p16-defective, pRb-positive A375M cells and p16-positive, pRb-defective A2058 cells. The synthetic p16-mimicking peptides strongly induced apoptosis in p16-, pRb+ A375M cells in vitro, while they had significantly less activity on p16+, pRb- A2058 cells. The most active p16-mimicking peptide, p16-AP9, also potently inhibited in vivo growth of the A375M melanoma. Treated tumors showed a threefold smaller volume (P < 0.025) and a significant reduction of the mitotic index and of PCNA expression. Growth of A2058 cells in vivo was not affected by treatment with the p16-mimicking peptide. Our results demonstrate that p16-mimicking peptides can induce apoptosis in vitro and that can inhibit tumor growth in vivo in p16-defective, pRb-expressing human melanoma cells, suggesting that p16-mimicking peptides can represent a promising tool for targeted therapy in selected cancer phenotypes.

Abstract: PURPOSE: Employing an in vitro model system of human melanoma progression, we previously reported ferritin light chain (L-ferritin) gene overexpression in the metastatic phenotype. Here, we attempted to characterize the role of ferritin in the biology of human melanoma and in the progression of this disease. EXPERIMENTAL DESIGN: Starting from the LM human metastatic melanoma cell line, we engineered cell clones in which L-ferritin gene expression was down-regulated by the stable expression of a specific antisense construct. These cells were then assayed for their growth capabilities, chemoinvasive properties, and sensitivity to oxidative stress. Additionally, ferritin protein content in primary and metastatic human melanomas was determined by immunohistochemistry. RESULTS: Artificial L-ferritin down-regulation in the LM cells strongly inhibited proliferation and chemoinvasion in vitro and cell growth in vivo. In addition, L-ferritin down-regulated cells displayed enhanced sensitivity to oxidative stress and to apoptosis. Concurrently, immunohistochemical analysis of a human melanoma tissue array revealed that ferritin expression level in metastatic lesions was significantly higher (P < 0.0001) than in primary melanomas. Furthermore, ferritin expression was constantly up-regulated in autologous lymph node melanoma metastases when compared with the respective primary tumors in a cohort of 11 patients. CONCLUSIONS: These data suggest that high ferritin expression can enhance cell growth and improve resistance to oxidative stress in metastatic melanoma cells by interfering with their cellular antioxidant system. The potential significance of these findings deserves to be validated in a clinical setting.

Abstract: The human HtrA family of proteases consists of four members: HtrA1, HtrA2, HtrA3, and HtrA4. In humans the four HtrA homologues appear to be involved in several important functions such as cell growth, apoptosis, and inflammatory reactions, and they control cell fate via regulated protein metabolism. In previous studies it was shown that the expression of HtrA1 was ubiquitous in normal adult human tissues. Here we examined the expression of HtrA1 protein and its corresponding mRNA during mouse embryogenesis using Northern blotting hybridization, RT-PCR, and immunohistochemical staining analyses. Our results indicate that HtrA1 is expressed in a variety of tissues in mouse embryos. Furthermore, this expression is regulated in a spatial and temporal manner. Relatively low levels of HtrA1 mRNA are detected in embryos at the beginning of organogenesis (E8), and the levels of expression increase during late organogenesis (E14-E19). Our results show that HtrA1 was expressed during embryonic development in specific areas where signaling by TGFbeta family proteins plays important regulatory roles. The expression of HtrA1, documented both at mRNA and protein levels by RT-PCR and immunohistochemistry in the developing nervous system, is consistent with a possible role of this protein both in dividing and postmitotic neurons, possibly via its documented inhibitory effects on TGFbeta proteins. An exhaustive knowledge of the different cell- and tissue-specific patterns of expression of HtrA1 in normal mouse embryos is essential for a critical evaluation of the exact role played by this protein during development.

Abstract: APAF-1 plays a pivotal role in mitochondria-dependent apoptosis, binding to cytochrome c and favoring activation of caspase-9. It has been shown that epigenetic silencing of the APAF-1 gene is a common event in several metastatic melanoma cells in vitro. We determined, by Western blot, variation in the level of expression of APAF-1 in several human melanoma cell lines and, by immunohistochemistry, in a group of 106 histological samples including benign and malignant melanocytic lesions. We observed APAF-1 down-regulation or loss of expression in two metastatic melanoma cell lines, compared to primary melanoma cell lines. The immunohistochemical analysis revealed a significant difference in APAF-1 staining between nevi and melanomas. In addition, we found a significant negative correlation between APAF-1 expression level and tumor thickness and between primary melanomas and metastases. We conclude that loss of APAF-1 expression can be considered as an indicator of malignant transformation in melanoma.

Abstract: The adenoviral E1A proteins have been implicated in promotion of proliferation and transformation, inhibition of differentiation, induction of apoptosis, regulation of transcription, and suppression of tumor growth. The ability of E1A to override the fundamental controls of host cells is based on its ability to physically interact with several cellular proteins. We recently characterized RACK1 as a new E1A-interacting protein. In this report, we show that the extreme N-terminal region of E1A, spanning from aminoacids 1-36, and the conserved WD regions of RACK1 are responsible for this interaction. We also demonstrate that E1A and RACK1 colocalize at the perinuclear membrane in the cells. Furthermore, we provide evidence that E1A is able to antagonize the inhibitory effects of RACK1 on Src activity. These results suggest that RACK1 signaling pathway may be a functional target of E1A, contributing to E1A oncogenic effect in the host cells.

Abstract: Signaling through the Notch cell surface receptors is a highly conserved mechanism of cell fate specification. Notch signaling regulates proliferation, differentiation and cell death. In vertebrates, putative gene duplication has originated four Notch genes, Notch-1, -2, -3 and -4. They have been implicated in neurogenesis, hematopoiesis, T-cell development, vasculogenesis and brain cortical growth. We have investigated Notch-1 distribution in normal human tissues by immunohistochemistry and immunoblot. We detected widespread expression of Notch-1 cytoplasmatic staining, with different tissue distributions in the different organs examined. In particular, high expression of Notch-1 was detected in the intermediate suprabasal layers, but not in the dead cells at the extreme periphery of stratified epithelia. Moreover, a low/intermediate level of Notch-1 was observed in lymphocytes in several peripheral lymphoid tissues; in particular the germinal centers of lymph nodes showed the most abundant number of positive cells, which appeared to be centroblasts/immunoblasts based on nuclear morphology. Notch-1 participates in keratinocytes differentiation. We showed by Western blot analysis that Notch-1 level was clearly increased in HaCaT cells after Ca(++) addition and remained substantially elevated until late differentiation stages. These results suggest that Notch-1 may function in numerous cell types in processes beyond cell fate determination, such as neuronal plasticity, muscle hypertrophy, liver regeneration, and germinal center lymphopoiesis during the immune response.

Abstract: The placenta has a dynamic and continuous capacity for self-renewal. The molecular mechanisms responsible for controlling trophoblast proliferation are still unclear. It is generally accepted that the simultaneous activity of proteins involved in cell proliferation, apoptosis, and extracellular matrix degradation plays an important role in correct placental development. We investigated in depth the expression of the serine protease HtrA1 during pregnancy in human placenta by in situ hybridization and immunohistochemistry, we demonstrated that HtrA1 displayed a low level of expression in the first trimester of gestation and a strong increase of HtrA1 expression in the third trimester. Finally, by electron microscopy, we demonstrated that HtrA1 was localized either in the cytoplasm of placental cells, especially close to microvilli that characterized the plasma membrane of syncytiotrophoblast cells, or in the extracytoplasmic space of the stroma of placental villi, particularly in the spaces between collagen fibers and on collagen fibers themselves. The expression pattern of HtrA1 in human placentas strongly suggests a role for this protein in placental development and function. Moreover, on the basis of its subcellular distribution it can be postulated that HtrA1 acts on different targets, such as intracellular growth factors or extracellular matrix proteins, to favor the correct formation/function of the placenta.

Abstract: In order to identify genes relevant for melanoma development, we carried out cDNA array experiments employing an in vitro model of human melanoma progression, consisting of two cell lines: one, LP, derived from a primary melanoma and the other, LM, from its metastatic supraclavicular lymph node. Basic cDNA array data identified 26 genes as down-regulated in the LM cell line. Northern blot analysis confirmed an effective transcriptional down-regulation for five out of 13 genes analyzed. The products of these five genes belong to different functional protein types, such as transcription and translation regulators (Edg-2, eIF-3 p110, and RNPL/RBM3), extracellular communicators (PRSS11) and members of the major histocompatibility complex (beta2-microglobulin). Some previously described differences in expression patterns, such as loss of HLA I, were confirmed by our array data. In addition, we identified and validated for the first time the reduced expression level of several genes during melanoma progression. In particular, reduced Edg-2 gene product expression was also confirmed in a group of 50 primary melanomas and unrelated metastases. In conclusion, comparative hybridization by means of cDNA arrays assisted in identifying a series of novel progression-associated changes in gene expression, confirming, at the same time, a number of previously described results.

Abstract:

Abstract: Cyclins are members of family of proteins involved in the cell cycle regulation. They are regulatory subunits of complexes with proteins called cyclin-dependent kinases (CDKs). There are three forms of cyclin T: cyclin T1, cyclin T2a, and T2b. All cyclin T contain an N-terminal "cyclin homology box," the most conserved region among different members of the cyclin family that serves to bind CDK9. In addition to the N-terminal cyclin domain, cyclin T contains a putative coiled-coil motif, a His-rich motif, and a C-terminal PEST sequence. The CDK9/cyclin T complex is able to activate gene expression in a catalytic-dependent manner, phosphorylating the carboxy-terminal domain (CTD) of RNA polymerase II. In addition, only cyclin T1 supports interactions between Tat and TAR. The interaction of Tat with cyclin T1 alters the conformation of Tat to enhance the affinity and specificity of the Tat:TAR interaction. On the other hand, CDK9/cyclin T2 complexes are involved in the regulation of terminal differentiation in muscle cells.

Abstract: By means of the yeast two-hybrid system, we have discovered a novel physical interaction between the adenovirus E1A oncoprotein and Ran, a small GTPase which regulates nucleocytoplasmic transport, cell cycle progression, and mitotic spindle organization. Expression of E1A elicits induction of S phase and centrosome amplification in a variety of rodent cell lines. The induction of supernumerary centrosomes requires functional RCC1, the nucleotide exchange factor for Ran and, hence, a functional Ran network. The E1A portion responsible for the interaction with Ran is the extreme NH(2)-terminal region (amino acids 1-36), which is also required for the induction of centrosome amplification. In an in vitro assay with recombinant proteins, wild-type E1A interferes with nucleotide exchange on Ran, whereas an E1A mutant, deleted from the extreme NH(2)-terminal region, does not. In addition, we detected an in vitro interaction between Ran and HPV-16 E7 and SV40 large T antigen, two oncoproteins functionally related to E1A. These findings suggest a common pathway of these oncoproteins in eliciting virus-induced genomic instability.

Abstract: Despite the clonal origin of most tumors, their tremendous heterogeneity suggests that cancer progression springs from the combined forces of both genetic and epigenetic events, which produce variant clonal populations, together with the selective pressures of the microenvironment, which promote growth and, perhaps, dissemination of variants with a specific set of characteristics. Although the importance of genetic mutations in cancer has long been recognized, the role of epigenetic events has been suggested more recently. This review focuses on the genetic and epigenetic molecular mechanisms involved in cancer onset and progression, and discusses the possibility of new strategies in the development of anticancer treatments.

Abstract: Genetic aberrations, mostly resulting in changes in gene expression, are critical events in cancer onset and progression. The advent of the cDNA array technology allows the screening and the efficient measurement of expression of thousands genes simultaneously in a wide spectrum of experimental and clinical models. This genomic scale approach is being currently used to obtain global views of human cancer gene expression and to identify genetic markers that might be important for diagnosis, prognosis, and therapy. This review discusses some recent findings obtained by means of cDNA arrays investigating the human melanoma.

Abstract: Adenocarcinoma of the stomach is the second most common cause of cancer mortality in the world. The purpose of this study was to evaluate the potential role in carcinogenesis of two secreted Helicobacter pylori's proteins, CagA and HspB, both shown to increase the risk of gastric carcinoma in patients infected with H. pylori-positive strain. The effects of these two proteins on cell kinetics and the ability to selectively affect the expression of cell cycle-related proteins by transfection of a human gastric epithelial cell line (AGS) were analyzed. Using a genomic library of H. pylori, we isolated and cloned CagA and HspB. The effects of the overexpression of these proteins on cell growth were analyzed in AGS cells by immunoblots, proliferation assay, and flow cytometry. Coexpression of CagA and HspB in AGS cells in the first 48 h caused an increase of the level of E2F transcription factor, cyclin D3, and phosphorylated retinoblastoma protein, all involved in the G(1)-S checkpoint of the cell cycle. Consistently, an increase of cell proliferation, corresponding to an augment of the fraction of the cells in the S-G(2)-M phase of the cell cycle, was also demonstrated. Moreover, an increase of c-jun protein levels, but not of c-fos, was also found after coexpression of CagA and HspB. All these data suggest that CagA and HspB, independently from the bacterial infection, have a direct effect on the cell growth of the gastric cells acting on the G(1)-S checkpoint of the cell cycle.

Abstract: The small DNA virus proteins E1A and E1B from human Adenovirus, E6 and E7 from human papillomavirus, and large T and small T antigens from SV40, are multifaceted molecular tools that can carry out an impressive number of tasks in the host cell. These viral factors, collectively termed 'oncoproteins' for their ability to induce cancer, can be viewed as paradigmatic oncogenic factors which can disrupt checkpoint controls at multiple levels--they interfere with both 'gatekeeper' cellular functions, including major control pathways of cell cycle and apoptosis, and with 'caretaker' functions, thereby inducing mitotic abnormalities and increasing genomic instability. Both E1A and E7 have been recently found to interact physically with the Ran GTPase. This interaction is key in uncoupling the centrosome cycle from the cell cycle, highlighting a direct link between viral infection and the induction of genomic instability. Further expanding our current knowledge in this field will be crucial to elucidate viral strategies leading to cellular transformation and cancer progression, as well as design novel preventive or therapeutic approaches to human cancer.

Abstract: The human HtrA family of proteases consists of three members: HtrA1, HtrA2, and HtrA3. In bacteria, the chief role of HtrA is recognition and degradation of misfolded proteins in the periplasm, combining a dual activity of chaperone and protease. In humans, the three HtrA homologues appear to be involved in diverse functions such as cell growth, apoptosis, allergic reactions, fertilization, control of blood pressure, and blood clotting. Previous studies using RNA blot hybridization have shown that the expression of HtrA1 is ubiquitous in normal human tissues. Here we show by immunohistochemistry (IHC) that HtrA1 is widely expressed, although different tissue distributions and/or levels of expression were detected in the different tissues examined. In particular, high to medium HtrA1 expression was detected in mature layers of epidermis, in secretory breast epithelium, in liver, and in kidney tubules of cortex, in concordance with its secretory properties. Furthermore, we show a higher protein expression level in the epithelium of proliferative endometrium, in contrast to epithelium of secretory endometrium, which is almost completely negative for this protein. This suggests a possible role for HtrA1 in the modulation of tissue activity in this organ. The various expression levels in human tissues indicate several possible roles for HtrA1 in different cell types.

Abstract: BACKGROUND: Mesothelioma is the most commonly occurring primary pleural neoplasm. Several studies have documented an increase in the incidence of this malignancy during the last decades. Although the association between asbestos exposure and development of mesothelioma is generally accepted, the exact mechanism of carcinogenesis is unknown. Recently, Simian virus 40 large T antigen (SV40 Tag) expression has been detected in pleural mesothelioma. The ability of SV40 oncoproteins to inactivate p53 and retinoblastoma tumour suppressor proteins has been proposed as an important step in the pathogenesis of human mesothelioma. METHODS: To obtain a better understanding of the molecular mechanisms of the pathogenesis of mesothelioma, the expression of the cell cycle inhibitor p21(WAF1/CIP1) (p21), a downstream target of p53, was evaluated immunohistochemically in a group of 29 mesothelioma specimens already characterised for the presence of SV40 Tag sequences. RESULTS: Statistical analysis did not reveal any correlation between p21 expression and histopathological type of mesothelioma using the kappa(2) test (p=0.577). A significant positive relationship was found between p21 expression level and the patients' overall survival according to the Kaplan-Meier survival curves and using a log rank test (median difference in survival 7 months, 95% CI 4.8 to 9.9; p<0.001). CONCLUSIONS: Determination of p21 expression bears a prognostic significance in patients affected with mesothelioma, further underlining the role of SV40 in the pathogenesis of malignant pleural mesothelioma.

Abstract: Differential gene expression of cell lines derived from a malignant melanoma or its autologous lymph node metastasis using cDNA arrays indicated down-regulation of PRSS11, a gene encoding the serine protease HtrA1, a homolog of the Escherichia coli protease HtrA, in the metastatic line. Stable PRSS11 overexpression in the metastatic cell line strongly inhibited proliferation, chemoinvasion and Nm23-H1 protein expression in vitro, as well as cell growth in vivo in nu/nu mice. A polyclonal anti-HtrA1 serum demonstrated a significantly higher expression in primary melanomas when compared to unrelated metastatic lesions in a human melanoma tissue array, and down-modulation of HtrA1 expression in autologous lymph node melanoma metastases in seven out of 11 cases examined. These results suggest that down-regulation of PRSS11 and HtrA1 expression may represent an indicator of melanoma progression.

Abstract: Cyclin T2a was recently identified as one of the regulatory subunits of the cdk-cyclin complex P-TEFb, the most studied positive factor in the regulation of transcription elongation. By fluorescent in situ hybridization (FISH), the gene codifying for cyclin T2a has been mapped on human chromosome 2q21. This locus also has been linked to different forms of myopathy. By use of a new specific antiserum raised against cyclin T2a, the immunohistochemical pattern of expression of cyclin T2a in human tissues has been examined and compared to that of cyclin T1, described in the previous report. The observation that immunohistochemical expression of cyclin T2a was high in skeletal muscle cells, whereas it was undetectable in two cases of centronuclear myopathy, together with its chromosomal location, suggests an involvement of the cdk9-cyclin T2a complex in this disease.

Abstract:

Abstract: Cyclin T1 was recently identified, together with cdk9 (previously named PITALRE), as part of the TAK multiprotein complex, a co-factor targeted by the human immunodeficiency virus Type 1 (HIV-1) protein named Tat, suggesting a role for this complex in transcription elongation. Although studies on mRNA and protein expression have shown that cyclin T1 is ubiquitous in adult human tissues, no data have yet been reported regarding the expression of this protein in different cell lineages. Using a polyclonal antiserum raised against cyclin T1, we investigated the pattern of expression of this protein in adult human tissues by immunohistochemistry. Cyclin T1 was expressed ubiquitously, although different levels of expression were found in various organs. Some specialized tissues, such as blood, lymphoid tissues, and cells of connective tissue origin, showed high cyclin T1 expression. These specific expression patterns are only partially justified by some well-known specialized functions of cyclin T1 in certain cell types, such as its involvement in peripheral blood lymphocytes and monocyte differentiation. The high expression level found in other tissues suggests new possible roles for cyclin T1 in cell types other than those of lymphoid tissue.

Abstract: The adenoviral E1A proteins are able to promote proliferation and transformation, inhibit differentiation, induce apoptosis, and suppress tumor growth. The extreme N terminus and conserved region one of E1A, which are indispensable for transcriptional regulation and for binding to p300/CBP, TBP, and pCAF, play essential roles in these abilities. These observations strongly suggest an intrinsic link between E1A-mediated transcriptional regulation and other effects. In this report, we show that E1A inhibits the normal growth of Saccharomyces cerevisiae HF7c, and this inhibition also depends on the domains required for transcriptional regulation. We demonstrate that E1A associates with histone acetyltransferase activity and represses the transactivation activity of transcription factor in S. cerevisiae, suggesting that E1A may suppress the expression of genes required for normal growth. Based on yeast growth rescue, we present a genetic screening strategy that identified RACK1 as an E1A antagonizing factor. Expression of human RACK1 efficiently relieves E1A-mediated growth inhibition in HF7c and protects human tumor cells from E1A-induced apoptosis. Finally, we show that RACK1 decreases E1A-associated histone acetyltransferase activity in yeast and mammalian cells, and physically interacts with E1A. Our data demonstrate that RACK1 is a repressor of E1A, possibly by antagonizing the effects of E1A on host gene transcription.

Abstract: Increasing evidence indicates that the nm23 genes, initially documented as suppressors of metastasis progression, are involved in normal development and differentiation. We have shown previously that the murine nm23 gene enhances pheochromocytoma PC12 cells responsiveness to NGF by accelerating cell growth arrest and neurite outgrowth. The present study was aimed at elucidating the mechanisms by which nm23 controls cell proliferation and promotes neuronal differentiation. We demonstrated that nm23 modulates the expression of the Rb2/p130 gene, a negative regulator of cell cycle progression also implicated in the maintenance of the differentiated state. Furthermore, we showed that nm23-H1 mutants, defective in inhibiting the invasive phenotype, downregulate Rb2/p130 expression and inhibit NGF-induced PC12 cell differentiation. In synthesis, our results provide first evidence of interplay between the nm23 and the Rb2/p130 genes in driving PC12 cells neuronal differentiation and suggest that the antimetastatic and the differentiative nm23 functions can have similar features.

Abstract: This review portrays an updated overview about the possible tumor suppressive properties of the Rb2/p130 gene, the third member of the retinoblastoma (RB) family of genes, including RB itself and p107. After a brief analysis of the established structural and functional similarities among the three genes, the main purpose is to critically analyze present evidence whether Rb2/p130 shares the role of a tumor suppressor. Taking into account the well-proven growth suppressive properties of Rb2/p130 and p107, we discuss the analysis of mutated or deleted forms of Rb2/p130 found in a number of human cancers. Finally, we take into consideration the data provided by the targeted disruption of each RB family gene, alone or in combination, in the mouse model.

Abstract: BACKGROUND: The expression of several genes is modulated during neuroblastoma differentiation. The retinoblastoma family proteins, pRb, p107 and pRb2/p130, act in the repression of proliferation genes, interacting mainly with the E2F transcription factors. PROCEDURE AND RESULTS: In this study, we found that, in neuroblastoma cell lines, pRb and p107 proteins decreased, undergoing progressive dephosphorylation, whereas pRb2/p130 increased at late stages of differentiation. B-myb expression was down-regulated in association with the up-regulation of pRb2/p130, the major partner of E2F on the E2F site of the B-myb promoter in differentiated cells. Transfection of each of the retinoblastoma family genes in neuroblastoma cells was able to induce neural differentiation, to inhibit 3H-thymidine incorporation, and to down-regulate B-myb promoter activity. CONCLUSIONS: In conclusion, our data suggest a major contribution of retinoblastoma proteins, and especially of pRb2/p130, in B-myb promoter regulation and demonstrate the induction of neural differentiation by p107 and pRb2/p130, suggesting a role of these proteins in triggering differentiation-specific genes.

Abstract: The AP-2 transcription factor plays a pivotal role in regulating the expression of several genes involved in tumor growth and progression of melanoma. We determined, by Western blot, variation in the level of expression of AP-2 and three of its downstream targets, c-kit, E-cadherin, and p21 in several human melanoma cell lines and, by immunohistochemistry, in a group of 99 histological samples including benign and malignant melanocytic lesions. A significant negative correlation between AP-2 expression level and tumor thickness was found. Moreover, AP-2 expression was positively associated with E-cadherin and c-kit expression. In contrast, there was a significant negative association between AP-2 and p21 expression levels. These findings suggest that p21 is independent of AP-2 transactivator function during the latest phases of melanoma progression. Finally, AP-2, c-kit, E-cadherin, and p21 expression levels did not show to be able to distinguish between dysplastic nevi and nevi without dysplasia. We conclude that changes in the expression of these proteins are involved in the later phases of melanoma progression, and may be responsible for the transition from local invasive melanoma to metastasis.

Abstract: Rb2/p130, a member of the Retinoblastoma family of growth and tumour suppressor genes, is extensively implicated in the control of cell cycle and differentiation. The minimal promoter region of Rb2/p130 in T98G human glioblastoma cells was identified and its analysis revealed the presence of a KER1 palindromic sequence able to bind the transcription factor AP-2, a regulatory protein that plays a crucial role in ectodermal differentiation. This KER1 site interacted in vitro with AP-2, and AP-2 overexpression increased Rb2/p130 transcription and translation. We also found that rat PC12 pheochromocytoma cells, when induced to differentiate by NGF, displayed an increase of AP-2 protein levels and of Rb2/p130 transcription and protein levels. AP-2-transfected PC12 cells displayed enhanced transcription and translation of Rb2/p130 and of the cdk inhibitor p21(WAF1/CIP1), a gene known to be under the control of AP-2, but unable by itself to elicit PC12 differentiation. Overexpression of either AP-2 or Rb2/p130 elicited per se cell differentiation in the absence of NGF, while coexpression of AP-2B, a negative regulator of AP-2 transcriptional activity, inhibited only AP-2-induced differentiation. Altogether, these results indicate that Rb2/p130 is a critical effector of AP-2 in sustaining ectodermal differentiation.

Abstract: Tumor suppressor genes have a pivotal role in normal cells regulating cell cycle processes negatively. Furthermore, the inhibition of cell proliferation is a crucial step in the achievement of cell differentiation. Increasing evidence suggests that the nm23 genes, initially documented as suppressors of the invasive phenotype in some cancer types, are involved in the control of normal development and differentiation. In this review, we summarize some data concerning the involvement of the nm23 genes in development and differentiation, attempting to delineate an overall view of many facets of their biological role.

Abstract: The p53 protein accumulates rapidly through post-transcriptional mechanisms following cellular exposure to DNA damaging agents and is also activated as a transcription factor leading to growth arrest or apoptosis. Phosphorylation of p53 occurs after DNA damage thereby modulating its activity and impeding the interaction of p53 with its negative regulator oncogene Mdm2. The serines 15 and 37 present in the amino terminal region of p53 are phosphorylated by the DNA-dependent protein kinase (DNA-PK) in response to DNA damage. In order to verify if specific p53 mutations occur in the multi-drug resistance phenotype, we analysed the p53 gene in two T-lymphoblastoid cell lines, CCRF-CEM and its multi-drug-resistant clone CCRF-CEM VLB100, selected for resistance to vinblastine sulfate and cross-resistant to other cytotoxic drugs. Both cell lines showed two heterozygous mutations in the DNA binding domain at codons 175 and 248. The multi-drug resistant cell line, CCRF-CEM VLB100, showed an additional mutation that involves the serine 37 whose phosphorylation is important to modulate the protein activity in response to DNA damage. The effects of these mutations on p53 transactivation capacity were evaluated. The activity of p53 on pro-apoptotic genes expression in response to DNA damage induced by (-irradiation, was affected in the vinblastine (VLB) resistant cell line but not in CCRF-CEM sensitive cell line resulting in a much reduced apoptotic cell death of the multi-drug resistant cells.

Abstract: An association between cyclin D3 and the C-terminal domain of pRb2/p130 was demonstrated using the yeast two-hybrid system. Further analysis restricted the epitope responsible for the binding within the 74 N-terminal amino acids of cyclin D3, independent of the LXCXE amino acid motif present in the D-type cyclin N-terminal region. In a coprecipitation assay in T98G cells, a human glioblastoma cell line, the C-terminal domain of pRb2/p130 was able to interact solely with cyclin D3, while the corresponding portion of pRb interacted with either cyclin D3 or cyclin D1. In T98G cells, endogenous cyclin D3-associated kinase activity showed a clear predisposition to phosphorylate preferentially the C-terminal domain of pRb2/p130, rather than that of pRb. This propensity was also confirmed in LAN-5 human neuroblastoma cells, where phosphorylation of the pRb2/p130 C-terminal domain and expression of cyclin D3 also decreased remarkably in the late neural differentiation stages.

Abstract: The effect of the antitumor drug lonidamine (LND) on respiration, aerobic glycolysis, adenylate pool, doxorubicin (DOX) uptake, and efflux in DOX-resistant and DOX-sensitive Ehrlich tumor cells was investigated. The results may be summarized as follows: 1) In both types of cells, LND inhibited both respiration and glycolysis in a dose-dependent manner and lowered the ATP concentration. The effect was more marked in cells incubated in glucose-free medium; 2) LND raised, to a remarkable extent, the intracellular content of DOX in resistant and sensitive cells respiring on endogenous substrates because of reduced ATP availability, whereas in glucose-supplemented medium, where both respiration and glycolysis contributed to ATP synthesis, the increase was lower; and 3) when LND was added to DOX-loaded cells, it failed to significantly inhibit DOX efflux because of time-dependent phenomena. These findings indicated that LND, a drug currently employed in tumor therapy, might also be useful in reducing or overcoming multidrug resistance (MDR) of those cells with a reduced ability to accumulate and retain antitumor drugs.

Abstract: The retinoblastoma family of nuclear factors is composed of RB, the prototype of the tumour suppressor genes and of the strictly related genes p107 and Rb2/p130. The three genes code for proteins, namely pRb, p107 and pRb2/p130, that share similar structures and functions. These proteins are expressed, often simultaneously, in many cell types and are involved in the regulation of proliferation and differentiation. We determined the expression and the phosphorylation of the RB family gene products during the DMSO-induced differentiation of the N1E-115 murine neuroblastoma cells. In this system, pRb2/p130 was strongly up-regulated during mid-late differentiation stages, while, on the contrary, pRb and p107 resulted markedly decreased at late stages. Differentiating N1E-115 cells also showed a progressive decrease in B-myb levels, a proliferation-related protein whose constitutive expression inhibits neuronal differentiation. Transfection of each of the RB family genes in these cells was able, at different degrees, to induce neuronal differentiation, to inhibit [3H]thymidine incorporation and to down-regulate the activity of the B-myb promoter.

Abstract: B-MYB expression is associated with cell proliferation and recent studies have suggested that it promotes the S phase of mammalian cells. Based on its homology to the transcription factors c-MYB and A-MYB, B-MYB is thought to be involved in transcriptional regulation; however, its activity is not detectable in several cell lines. It was postulated that B-MYB function may depend on the presence of a cofactor, and recent studies suggested that B-MYB is phosphorylated specifically during S phase in murine fibroblasts. In this report we provide evidence that the product of the human B-myb gene can be activated in vivo by coexpression with cyclin A or cyclin E. Transfection studies showed that B-MYB was a weak transcriptional activator in SAOS-2 cells and was unable to promote their proliferation. In contrast, overexpression of both B-MYB and cyclin A or cyclin E caused a drastic increase in the number of SAOS-2 cells in S phase. Also, overexpression of cyclin A and cyclin E in SAOS-2 cells enhanced the ability of B-MYB, but not c-MYB, to transactivate various promoters, including the cdc2 promoter, the HIV-1-LTR, and the simian virus 40 minimal promoter. A direct role for cyclin-dependent activation of B-MYB was demonstrated using an in vitro transcription assay. These observations suggest that one mechanism by which cyclin A and E may promote the S phase is through modification and activation of B-MYB.

Abstract: We studied the effect of phosphorothioate oligodeoxynucleotides ([S]ODNs) complementary to the bcr-abl junction on cells taken at diagnosis from 41 patients with Philadelphia-positive chronic myelogenous leukaemia (CML). Experiments included the evaluation of the anti-leukaemic effect of 16- and 26-mer antisense [S]ODNs on both mononuclear and CD34+ cells, evaluation of incubation time and correlation of colony growth inhibition with the down-regulation of p210(bcr-abl). At the same time, the uptake of [S]ODNs by mononuclear and purified CD34+ cell populations and the cross-hybridization of 26- and 16-mer [S]ODNs with the complementary sequences were evaluated. After incubation for 120 h with 26-mer antisense [S]ODNs on mononuclear cells, overall mean colony recovery was 41.9% of the untreated control samples; in particular, a significant reduction in colony formation was observed in 22 of the 35 cases tested. The effect of 26-mer ODNs on CD34+ cells was comparable to that observed on mononuclear cells in terms of colony inhibition; however, a higher proportion of cases showed a significant inhibition of colony formation. In comparison with the 26-mer antisense [S]ODNs, the anti-leukaemic effect of the 16-mer antisense [S]ODNs was less evident on mononuclear cells and comparable on CD34+ cells; however, a more specific effect was evident on both target cells. Hybridization experiments confirmed a partial cross-reactivity when the 26-mer ODNs were hybridized with their complementary sequence; this did not occur when 16-mer ODNs were similarly tested. Experiments aimed at evaluating the effect of the incubation time showed a significant increase in anti-leukaemic effect after a 120 h incubation period compared to that measured after a 24 h incubation period; this was parallelled by a progressive increase in the intracellular concentrations of [S]ODNs from day 1 to day 5. The accumulation of [S]ODNs correlated with a marked down-regulation of p210(bcr-abl) levels which was first detectable after 72 h of treatment. The down-regulation of p210(bcr-abl) levels following treatment with [S]ODNs showed a correlation between the effect of antisense [S]ODNs on leukaemic colony formation and protein expression. These studies confirm that, under optimal conditions of target cell culture and ODN size, antisense [S]ODNs complementary to the bcr-abl junction have specific anti-leukaemic effects.

Abstract: Neuroblastoma cells can undergo neural differentiation upon treatment with a variety of chemical inducers and growth factors. During this process, many cell cycle-related genes are downregulated while differentiation-specific genes are triggered. The retinoblastoma family proteins, pRb, p107, and pRb2/p130, are involved in transcriptional repression of proliferation genes, mainly through their interaction with the E2F transcription factors. We report that pRb2/p130 expression levels increased during differentiation of neuroblastoma cell line LAN-5. On the other hand, both pRb and p107 decreased and underwent progressive dephosphorylation at late differentiation times. The expression of B-myb and c-myb, two targets of the retinoblastoma family proteins, were downregulated in association with the increase of pRb2/p130, which was detected as the major component of the complex with E2F on the E2F site of the B-myb promoter in differentiated cells. Interestingly, E2F4, a preferential partner of p107 and pRb2/p130, was upregulated and underwent changes in cellular localization during differentiation. In conclusion, our data suggest a major role of pRb2/p130 in the regulation of B-myb promoter during neural differentiation despite the importance of cofactors in modulating the function of the retinoblastoma family proteins.

Abstract: Respiration, glycolysis, utilization of carbon from 14C-labeled glucose and the activities of some regulatory enzymes of the Krebs cycle and glycolysis in adriamycin-sensitive (EH-WT) and -resistant (EH-ADR) Ehrlich ascites tumor cells have been investigated. The following summarizes the results: 1. Compared with wild-type cells, EH-ADR cells exhibited an enhanced rate of oxygen consumption as well as of ATP production (2-fold). 2. When the cells were supplied with glucose as the only added energy source, the aerobic lactate production was 30% higher in EH-ADR cells. However, in spite of the enhanced glycolysis, 50% of total cell ATP was still supplied by oxidative phosphorylation, whereas in EH-WT cells 65% of ATP was derived from glycolysis. 3. The activities of the regulatory enzymes were remarkably more elevated in EH-ADR cells. 4. The amount of glucose carbon atoms metabolized through the Krebs cycle and pentose phosphate pathway in EH-ADR cells was significantly higher than in EH-WT cells. 5. These differences confirmed a modified energy metabolism in resistant cells and reflected metabolic adaptations associated with the development of multidrug resistance.

Abstract: The effect of the local anesthetic bupivacaine on transmembrane potential of mitochondria within Ehrlich ascites tumor cells has been investigated by the safranine method. The following summarizes the results. 1) When Ehrlich ascites tumor cells were added into a medium containing safranine, a differential spectrum with a decrease at 520 nm appeared. The addition of bupivacaine did not reverse the response but resulted in a spectrum similar to that observed with deenergized mitochondria, with a maximum at 550 nm and a minimum at 495 nm. 2) The addition of glucose to bupivacaine- or rotenone-treated cells also produced a shift in safranine spectrum similar to that observed upon energization of mitochondrial membranes by ATP, thus suggesting that glycolytically generated ATP was responsible for this spectral change. 3) The ability of bupivacaine to decrease the membrane potential in mitochondria within Ehrlich ascites tumor cells was due to two different effects: inhibition of the energy-conserving site 1 of the respiratory chain and uncoupling by a true protonophoretic mechanisma.

Abstract: The retinoblastoma gene (RB1) is frequently deleted or mutated in many tumor types and in all cases of retinoblastoma. Apart from its role in regulation of the cell cycle, the RB1 gene product (p110RB1) appears to be involved in control of differentiation. Malignant metastatic cells show many properties of poorly differentiated cells, and are highly invasive in vitro and in vivo. We have transfected the human RB1 cDNA in an expression vector under the control of the beta-actin promoter into B16F10 murine melanoma cells. These cells highly overexpress RB1 mRNA and the p110RB1 product, show reduced growth rate and increased melanogenesis in vitro. Vector control transfectants showed no alteration of invasiveness. The p110RB1 over-expressing cells also had a reduced capacity to migrate and invade through an artificial basement membrane, key characteristics of metastatic cells. When injected into nude mice, the p110RB1 over-expressing cells showed reduced tumor growth and reduced metastatic potential. The few metastasis observed were predominantly melanotic. These data indicate that RB1 gene expression is involved in melanoma cell differentiation and plays a role in downregulation of migration, invasion and metastatic potential of these cells.

Abstract: The retinoblastoma (Rb) family consists of the tumor suppressor pRb and related proteins p107 and pRb2/p130. Ectopic expression of pRb and p107 results in a growth arrest of sensitive cells in the G1 phase of the cell cycle. We demonstrated here that the growth-suppressive properties of pRb2/p130 were also specific for the G1 phase. The A-, E-, and D-type cyclins as well as transcription factor E2F1 and the E1A viral oncoprotein were able to rescue the pRb2/p130-mediated G1 growth arrest in SAOS-2 cells. The rescue with cyclins A and E correlated with their physical interaction with pRb2/p130, which surprisingly has been found to occur over all phases of the cell cycle. The phosphorylation status as well as the kinase activity associated with pRb2/p130 dramatically increased near the G1-S-phase transition. This suggests that, like the other Rb family members, pRb and p107, the phosphorylation of pRb2/p130 is controlled by the cell cycle machinery and that pRb2/p130 may indeed be another key G1-S-phase regulator.

Abstract: Two genes, p107 and Rb2/p130, are strictly related to RB, the most investigated tumor suppressor gene, responsible for susceptibility to retinoblastoma. The products of these three genes, namely pRb, p107, and pRb2/p130 are characterized by a peculiar steric conformation, called "pocket," responsible for most of the functional interactions characterizing the activity of these proteins in the homeostasis of the cell cycle. The interest in these genes and proteins springs from their ability to regulate cell cycle processes negatively, being able, for example, to dramatically slow down neoplastic growth. So far, among these genes, only RB is firmly established to act as a tumor suppressor, because its lack-of-function is clearly involved in tumor onset and progression. It has been found deleted or mutated in most retinoblastomas and sarcomas, but its inactivation is likely to play a crucial role in other types of human cancers. The two other members of the family have been discovered more recently and are currently under extensive investigation. We review analogies and differences among the pocket protein family members, in an attempt to understand their functions in normal and cancer cells.

Abstract: We have described previously three mouse multifinger coding genes (C. Passananti et al., Proc. Natl. Acad. Sci. USA, 86: 9417-9421, 1989). We have analyzed the expression of one of them, termed Mfg2 and renamed Zfp59, and demonstrated that Zfp59 mRNA and its translation product are present in specific stages of mouse spermatogenesis. The predicted amino acid sequence of the Zfp59 protein has been found to consist of 16 zinc-finger motifs clustered at the COOH terminus and subdivided into two groups by a degenerate finger motif. At its NH2 terminus, Zfp59 shares with other members of the zinc finger gene family two additional conserved amino acid modules A and B, described as either FAX, KRAB, or FPB domains. By means of Northern blot, Western blot analysis, and immunohistochemical localization, Zfp59 mRNA and its translation product were shown to be synthesized specifically during the postmeiotic phase of male germ line differentiation. By immunoelectron microscopy, the Zfp59 protein has been shown to accumulate in the nuclei of mature sperms in association with the nuclear matrix.

Abstract: The Rb2/p130 protein has been shown to have a high sequence homology with the retinoblastoma gene product (pRb), one of the most well-characterized tumor suppressor genes, and with pRB-related p107, especially in their conserved pocket domains, which display a primary role in the function of these proteins. In this study, we report on the biochemical and immunocytochemical characterization of the Rb2/p130 protein, using a polyclonal antibody developed against its "spacer" region included in the pocket domain of the whole protein. We show that pRb2/p130 is a phosphoprotein located at the nuclear level and that its phosphorylation pathway can be dramatically reduced by phosphatase treatment. Moreover pRb2/p130 with p107, is one of the major targets of the E1A viral oncoprotein-associated kinase activity, showing a phosphorylation pattern which is modulated during the cell cycle, reaching a peak of activation at the onset of S-phase.

Abstract: The retinoblastoma susceptibility gene in leukemia and lymphoma has been investigated using different approaches involving either gene or protein analysis. In this study, a novel method, which evaluates the functional status of the retinoblastoma gene product by a binding assay to an in vitro-translated viral oncoprotein, has been applied to leukemic cells from acute myeloid leukemia patients. One hundred twenty-two cases were considered, and 42 of them were also analyzed by Western blot. Results obtained with the two methods were comparable, with the exception of few cases, where the retinoblastoma protein appeared detectable but unable to bind to the viral oncoprotein. The retinoblastoma protein has been found defective mostly in the M3 promyelocytic subtype.

Abstract: The glycolytic enzyme hexokinase plays a key role in regulating cell energy metabolism. Its activity has been associated with cell growth rate and, notably, with neoplastic transformation. NIH-3T3 cells were transfected with a tumor hexokinase cDNA. The transfected cells showed increased hexokinase amount and activity, mainly located in the particulate cellular fraction, increased glycolytic rate evaluated as lactate production, and, finally, enhanced growth rate. These data may suggest that high hexokinase activity might be not merely the consequence of peculiar metabolic demands by actively replicating normal or cancer cells, but also a modification able per se to drive, at least partially, a more intense mitotic activity.

Abstract: Inactivating mutations of the retinoblastoma susceptibility gene (Rb) are involved in the pathogenesis of hereditary and sporadic retinoblastoma. Alterations in the Rb gene have also been found in several other human tumors occurring with epidemiological incidence higher than that of retinoblastoma. Four human malignant glioma cell lines were examined for abnormalities in the retinoblastoma gene product (pRb), using a procedure based on the interaction of pRb with an in vitro-translated adenovirus E1A oncoprotein. In the CRS-A2 cell line, derived from a glioblastoma multiforme, pRb did not bind with the in vitro-translated E1A protein. Restriction analysis of the CRS-A2 Rb gene and Rb mRNA expression provided patterns that could not be distinguished from the other glioma cell lines. Further investigation revealed the presence of a truncated pRb in the CRS-A2 cell line, due to a nucleotide insertion in the coding sequence at position 2550. In addition, this truncated Rb protein was undetectable in phosphorylated form. The binding assay with the in vitro-translated E1A was also used to study other cell lines with known mutations in the Rb gene. This method, which evaluates the interaction between in vitro-translated E1A and the pRb, is proposed as a rapid screening for detecting functional alterations in the retinoblastoma protein.

Abstract: The utilization of carbon from 14C-labeled glucose by adriamycin (ADM)-sensitive and -resistant LoVo human colon carcinoma cells has been investigated. The following summarizes the results: 1. Aerobic glycolysis is the main energy-yielding process in both cell lines, whereas only a small proportion of glucose carbon atoms are incorporated into CO2, lipids, nucleic acids, and supporting structures. 2. Basic alterations in glucose metabolism are associated with drug resistance in tumor cells. In fact, ADM-resistant LoVo cells show a significant increase in the oxidative pathway of glucose metabolism as well as in acetyl-CoA production. 3. In adriamycin-resistant LoVo cells, the amount of glucose carbon atoms metabolized through the pentose phosphate pathway is significantly higher than in adriamycin-sensitive cells. These findings confirm a modified glucose metabolism in cells with a resistant phenotype.

Abstract: Rhein (RH), 4,5 dihydroxyanthraquinone-2-carboxylic acid, is known to inhibit the glycolysis of neoplastic cells by impairing glucose uptake. In order to establish whether this might be due to a selective interaction of the carrier with the drug or to functional modifications of the cell membrane, the effect of RH on glucose uptake in Ehrlich ascites tumor cells has been investigated. RH strongly inhibits the uptake of both 2-deoxyglucose and 3-O-methylglucose, so the reduced influx therefore cannot be ascribed to an effect on glucose phosphorylation. The inhibition of glucose transport does not depend on a reduction of the number of the carriers as indicated by the inability of the drug to interfere with the synthesis of the transporter. Moreover, the extent of total binding of cytochalasin B, as well as the fact that glucose specificity is not altered, indicate that the intrinsic activity of the glucose carrier is not affected. We therefore conclude that the inhibition of glucose uptake must be ascribed to an interaction of the drug with cell membranes that results in an alteration of membrane-associated functions.

Abstract: The effect of hyperthermia and lonidamine, alone and in combination, on the clonogenic activity of a human glioma cell line was investigated. The time-temperature relationship of asynchronous, exponentially growing cells was defined in the range of 40-45 degrees C. All survival curves were exponential and an Arrhenius plot for heat killing was linear over the temperature range tested, with an activation energy of 192 Kcal/mol. The survival curve of lonidamine-treated cells was also exponential after an initial shoulder. The analysis of the interaction between lonidamine and hyperthermia, performed by the isobolar method, demonstrated an additivity of response so that the effectiveness of the combined treatment was the result of two independent effects. Lonidamine inhibits the neoplastic growth mainly through an ATP depletion, but the thermal killing was not mediated by the drug-induced changes in the energy status of the cell. The effectiveness of the combined treatment was strongly influenced by the schedule of administration. In fact, the sequence lonidamine-->hyperthermia made the cells less sensitive to heat so that the pre-established end-point, i.e. 30% survival, was never achieved whichever combination was used. This "drug-induced heat resistance" was not associated with the induction of heat shock proteins, but rather with modification of cell cycle. On the contrary, showing a purely additive effect, the sequence hyperthermia-->lonidamine allowed achievement of the pre-established cell killing (70%), with exposure times (1-2 hr) and with a temperature (42 degrees C) generally accepted as clinically achievable. Therefore, also considering its low systemic toxicity, lonidamine may be useful in reducing the side effects of hyperthermia.

Abstract: The effect of Rhein (RH) on the protein synthetic activity and adenylate energy charge in human glioma cells cultured in vitro has been investigated. The results demonstrate that in RH-treated cells, the protein synthesis is strongly decreased, but no modifications in the qualitative pattern occur. The extent of inhibition is a function of the drug concentration as well as of the time of exposure. Such an inhibition must be ascribed mainly to a reduction of adenylate energy charge brought about by RH because of its effect on respiration and glycolysis. The correlation between the adenylate energy charge and cell viability, as well as the possibility of using rhein as a biochemical modulator to reduce or to reverse multidrug resistance, are also discussed.

Abstract: The effect of the combination of adriamycin (ADM) with the anti-inflammatory drug rhein (RH) on the membrane redox activity in human glioma cells was investigated. RH, although less effective than ADM, inhibits ferricyanide reduction by human glioma cells in a dose-dependent manner as well as ferricyanide-induced proton release. The inhibition of the plasma membrane redox system might represent a further mechanism by which RH, other than ATP depletion, affects cell survival. The analysis of the interaction between ADM and RH, performed with the isobolar method, demonstrates a strong synergic response, probably due to an effect on different sites of action. The synergism of the ADM-RH association allows us to achieve a pre-established extent of inhibition with ADM concentrations much lower than with ADM alone. RH might, therefore, represent a very useful tool to improve the therapeutic index of ADM and to lower its general toxicity.

Abstract: The effect of association of 1,3-bis-(2-chloroethyl)-l-nitrosourea (BCNU)- Rhein (RH) and BCNU-Lonidamine (LND) on the clonogenic activity of human glioma cells was evaluated. Both RH and LND modulate the lethal effect of BCNU regardless of the schedule of treatment. The analysis of the interactions, performed with the isbolar method according to Berembaum, demonstrates an additivity of the effects. The possible mechanisms as well as the implications for the design of brain tumor schedule treatment are discussed.

Abstract: In Northern blot analysis of a series of tumor cell lines a single hexokinase mRNA species of 4.3 Kb was detected. Detailed examination of one such line, the rat AS-30D hepatoma, revealed that two mitochondrial species of hexokinase are present with a molecular mass of 115 and 107 KDa. The smaller of the two species is 4-fold more active than the larger. Only the larger, less active species is detected in the well differentiated H-35 rat hepatoma cell line which exhibits a lower glucose catabolic rate. These results suggest that a post-translational proteolytic event may play a central role in regulating the glucose utilization capacity of tumor cells by modulating the relative levels of high and low activity forms of hexokinase.

Abstract: Hexokinase is a key enzyme in carbohydrate metabolism. Its activity has been shown elevated in cells with high mitotic index. In particular, experimental cancer cells, due to their peculiar energy metabolism, display a hexokinase activity proportional to the degree of malignancy. This is the case also for human gliomas in which glucose metabolism, evaluated via positron emission tomography, has been shown to be predictive for patient prognosis. In order to better correlate these findings, specific reagents for tumor hexokinase (a polyclonal antibody and a full-length cDNA probe both specific for murine tumor hexokinase) have been successfully employed to quantitate the protein and its messenger in cultured cell lines; the antibody was also tested in four specimens obtained from human astrocytomas.

Abstract: Recent data from phase II trials have shown that lonidamine (LND) is effective in the treatment of tumors of various histogenesis, including gliomas. In the present work, we tested the antiproliferative effect of LND on a human glioblastoma cell line (LI) in different culture conditions. When LI are cultured in their standard conditions, a reduction of cell growth is seen after 3 days of treatment with 10(-4) M LND. It reaches 70% with respect to control after 6 days and is statistically significant. LND is ineffective at the other concentrations tested. In more stringent culture conditions, 10(-4) M LND determines a higher inhibition of cell proliferation both after 3 and 6 days of exposure, while other doses of LND are unable to affect cell growth.

Abstract: Lonidamine (LND) is a drug that interferes with energy metabolism of cancer cells, principally inhibiting aerobic glycolytic activity, by its effect on mitochondrially-bound hexokinase (HK). In such way LND could impair energy-requiring processes, as recovery from potentially lethal damage, induced by radiation treatment and by some cytotoxic drugs. A randomized study started in November 1983, to evaluate the efficacy of LND in association with radiotherapy as first line treatment in malignant gliomas, after surgical procedure. LND was also used in association with Lomustine (CCNU) at the moment of documented clinical and neuroradiological recurrence. At the present time 60 patients entered the study, and 47 are evaluable. Present preliminary results are not statistically significant, however indicate that LND tends to prolong the median survival time and the rate of one year survivors.

Abstract: The action of rhein, 4,5-dihydroxyanthraquinone-2-carboxylic acid, on protein synthesis of neoplastic cells has been investigated. Rhein decreases amino acid incorporation in all cells tested. The inhibition of incorporation of labeled precursors into acid-insoluble material cannot be ascribed to an impairment of amino acid uptake, which is unaffected by the drug. Tests on cell-free system showed that rhein does not inhibit the TMV-mRNA directed in vitro protein synthesis, thus indicating that the protein machinery per se is not affected. The inhibition of protein brought about by the drug must be ascribed to an effect on the energy-yielding processes with a remarkable decrease in ATP content. The mechanism is similar to that of other metabolic inhibitors, but rhein, for its capability to inhibit both respiration and glycolysis, is effective at much lower concentrations.

Abstract: Among the features of the reprogrammed neoplastic phenotype there is the metabolic property to display an increased glycolytic capacity and the ability to convert glucose to lactic acid in the presence of oxygen. Human gliomas in vivo and in vitro are capable to metabolize glucose in a way strictly related to the pathological degree of malignancy. The drug Lonidamine [1-(2,4-dichlorobenzyl)-1H-indazol-3 carboxylic acid)] (LND) is able to selectively block hexokinase (HK) activity and, consequently, lactate production only in highly glycolytic (highly malignant) gliomas, stimulating, on the contrary, that of low grade gliomas; this basically depends on the different HK patterns between low and high grade gliomas. LND is under clinical trial in order to evaluate its effectiveness in glioma therapy.

Abstract: Up-to-date unsatisfactory results obtained in multimodality treatments of malignant glioma have prompted the research of new therapeutic modalities with 'unconventional' modes of action. Lonidamine (LND) is a drug which reduces aerobic glycolytic activity in both human and experimental tumors. This effect mainly depends on the inhibition of mitochondrially-bound hexokinase (HK) which is present in large amounts in malignant cells. A Phase II study was conducted on patients with recurrent glioma; 12 patients were admitted to the study. Clinical side effects were moderate, necessitating a reduction of the dosage in only 1 case. The objective results were evaluated according to the indications of Levin. 2 responders and 3 cases of stable disease were observed out of 10 evaluable patients. The potential value of this new drug is discussed.

Abstract: Receptors for Insulin, Epidermal Growth Factor, Platelet-Derived Growth Factor and Insulin-like Growth Factor type 1 are tyrosine-specific protein kinases. This enzymatic activity may play a role in mediating the biological actions of these peptides. It has recently been identified a Mr 120 KDa glycoprotein in rat liver plasma membranes which can be phosphorylated by the insulin receptor and by the EGF receptor in a cell-free system and by the insulin receptor in intact cultured H-35 hepatoma cells. In the present report it is shown that the solubilized Insulin-like Growth Factor type 1 receptor can phosphorylate tyrosine residues in the same 120 KDa glycoprotein from the AS-30D rat hepatoma cells.

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Abstract: Recent studies from this laboratory have demonstrated that a form of hexokinase characteristic of rapidly growing, highly glycolytic tumor cells is bound to an outer mitochondrial membrane receptor complex containing a Mr 35,000 pore protein (D. M. Parry and P. L. Pedersen, J. Biol. Chem., 258: 10904-10912, 1983; R. A. Nakashima, et al., Biochemistry, 25: 1015-1021, 1986). In new studies reported here the specificity of this receptor complex for binding hexokinase is defined, and a purification scheme is described which leads to a homogeneous and bindable form of the tumor hexokinase. In the AS-30D hepatoma, hexokinase activity is elevated more than 100-fold relative to liver tissue. The relative increase in hexokinase activity is 8 times greater than that of any other glycolytic enzyme. Hexokinase is the only glycolytic enzyme of AS-30D cells to exhibit a mitochondrial/cytoplasmic specific activity ratio greater than 1, showing a 3.5-fold elevation in the mitochondrial fraction. Purification of hexokinase is accomplished by preferential solubilization of the mitochondrial bound enzyme with glucose-6-phosphate, followed by high-performance liquid chromatography on gel permeation and anion exchange columns. The final fraction has a specific activity of 144 units per mg of protein, with a Km for glucose of 0.13 mM and for ATP of 1.4 mM. The purified tumor enzyme migrates as a single species upon sodium dodecyl sulfate: polyacrylamide gel electrophoresis with an apparent molecular weight of 98,000. Significantly, the purified tumor enzyme retains its activity for mitochondrial binding. Additional results derived from chromatographic, polyclonal antibody, and amino acid analysis studies indicate that the predominant rat hepatoma hexokinase species is related most closely to isozymic form(s) of the enzyme commonly referred to as type II, and least related to the liver type IV isozyme (glucokinase).

Abstract: Lonidamine (LND) has been shown to inhibit tumor aerobic glycolysis. Its effect was evaluated on several human astrocytomas at different degrees of malignancy; a correlation was found between LDN effect on lactate production and tumor malignancy: in grade I and II astrocytomas LND stimulates lactate production, while in grade III, IV and glioblastoma multiforme lactate production is inhibited. In an attempt to explain this different behaviour, hexokinase content and compartmentation was evaluated in astrocytomas from fresh operatory specimens and from cultured cells as well, observing a significative correlation between malignancy, hexokinase activity, percent of mitochondrially-bound hexokinase and LND effect. The results justify from a biochemical point of view the role of LND as a 'non-conventional' agent in multimodality combined treatment for malignant gliomas.

Abstract: The effect of Lonidamine, 1-(2,4 dichlorobenzyl)-1-H-indazol-3-carboxylic acid, on the uptake of Adriamycin by Ehrlich ascites tumor cells has been investigated. The uptake of Adriamycin is greatly stimulated by Lonidamine and the increase depends on the energy sources of the cell. In the presence of glucose the intracellular drug content is remarkably lower than that in its absence. This difference lies in the mechanism by which Lonidamine enhances the uptake of Adriamycin. The Adriamycin efflux is via an active transport process and, in the presence of glucose, both aerobic glycolysis and oxidative phosphorylation contribute to ATP synthesis. Although Lonidamine inhibits both these pathways, there is still sufficient ATP to extrude a certain amount of Adriamycin. The elevated intracellular concentration of Adriamycin depends not only on the Lonidamine-inhibited outward transport but also on higher membrane permeability which allows a low concentration of Adriamycin (18 microM) to interfere also with the oxidative metabolism of Ehrlich ascites tumor cells.

Abstract: The effect of hyperthermia (1 hr, 41 degrees C) on the functional properties of Ehrlich ascites tumor mitochondria was investigated. Mitochondria isolated from Ehrlich ascites tumor after exposure of whole cells to 41 degrees C for 1 hr still phosphorylate and maintain a normal acceptor control ratio (ACR). The temperature decreases state 4 and ADP-and FCCP-stimulated respiration on various substrates entering at three energy-conserving sites of the respiratory chain. The inhibition of oxygen consumption by NAD- and FAD-linked substrates was 40% for state 4 and 70% for ADP- or FCCP-stimulated respiration. State 4 and FCCP-stimulated respiration of mitochondria on TMPD + ascorbate was affected 38% and 45%, respectively. ATPase activity was unaffected by hyperthermia, indicating that under these experimental conditions, the inhibition of ADP-stimulated respiration does not depend on an effect on either Fo F1-ATPase or adenine translocase, the activity of which is required for ATP entry prior to ATPase activity. Because of the inability to detect a specific site of action of temperature, it is conceivable that hyperthermia might inhibit substrate oxidation by altering some components of the inner mitochondrial membrane, which regulates the kinetic properties of the membrane-associated enzymes.

Abstract: The effect of Adriamycin on mitochondria of the rat heart, liver, and Ehrlich ascites tumor mitochondria has been evaluated. The results may be summarized as follows: Adriamycin reduces both ADP- and FCCP-stimulated respiration, inhibits oxidative phosphorylation, decreases mitochondrial ATP-ase activity, and affects the redox state of respiratory carriers. These alterations are common to all types of mitochondria tested with almost similar patterns. However, the severe cardiotoxicity of the drug cannot be ascribed only to an effect on mitochondrial energy-yielding processes. The addition of hexokinase to phosphorylating heart mitochondria does not increase the sensitivity of succinate oxidation to Adriamycin. Experiments to determine the site of action were not able to detect a specific point of attack. It is conceivable, therefore, that the modifications induced by Adriamycin on the functional parameters of mitochondria may be ascribed to alterations of the physical state of some components of the inner mitochondrial membrane, e.g., lipids, which regulate the kinetic properties of the membrane-associated enzymes.

Abstract: The effect of lonidamine (LND), 1-(2,4-dichlorobenzyl)-1H-indazol-3 carboxylic acid, on the utilization of carbon from 14C-labeled glucose by cell cultures of the permanent strain LI derived from a human glioblastoma multiforme (astrocytoma) has been investigated. The results may be summarized as follows. Aerobic glycolysis is the main energy-yielding process as shown by the fact that the greatest part of glucose carbon atoms is incorporated into lactate. Nevertheless, the amount of glucose converted accounts for only 63% of the lactate produced, indicating the presence of an elevated endogenous aerobic glycolysis. The amount of glucose carbon atoms incorporated into CO2, lipids, nucleic acid, and supporting structures is low. LND decreased the incorporation of 14C activity in all the above mentioned isolated compounds because of its ability to inhibit glucose phosphorylation. Consequently, there is a lower concentration of glucose-6-phosphate which, in turn, affects the rate of formation of several metabolites in glycolytic and pentose phosphate pathways. Experiments with [1-14C]-2-deoxy-D-glucose further substantiate the idea of glucose phosphorylation as a main target of LND and strongly suggest the presence of a mitochondrially bound hexokinase. The higher inhibition of glucose phosphorylation in exponentially growing cells indicates a further shift of the enzyme toward mitochondria-bound form and confirms the importance of the energy status of the cell in eliciting the response to LND. The reduced capacity of LND-treated cells to synthetize ATP and glucose-6-phosphate reflects the decreased synthesis of proteins and nucleic acids, which affects cell growth and duplication.

Abstract: Low concentrations of Adriamycin (ADM) do not inhibit the oxygen consumption of rat liver mitochondria because of the inability to cross the outer membrane. The involvement of this membrane as a permeability barrier is demonstrated by the results with exogenous ferrocytochrome c. ADM does not affect the basal rate of ferrocytochrome c oxidation, which, on the contrary, increases in Lonidamine (LND)-treated mitochondria. This difference lies in the capacity of LND to unmask the redox carriers in the inner membrane, i.e. cytochrome c:oxygen oxidoreductase which is also a marker of the outer membrane permeabilization. Therefore, the enhancement of ADM's effect on mitochondrial respiration by LND must be ascribed to its permeabilizing effect on the outer mitochondrial membrane.

Abstract: Lonidamine induces in murine and human tumor cells severe morphological damage of the mitochondria and other cytoplasmic structures both 'in vitro' and 'in vivo'. Biochemical studies have demonstrated that the drug decreases oxygen consumption and lactate production. The sensitivity of human tumor cells is not related to their histotype. Lonidamine's effects on mitochondria, glycolysis, pentose phosphate pathway, and aromatase activity are discussed.

Abstract: The effect of the association of gossypol and Lonidamine on the electron transport in Ehrlich ascites tumor mitochondria has been investigated by addition of drugs to isolated mitochondria. The results may be summarized as follows. (1) Low concentrations of gossypol increase the rate of oxygen consumption at the level of three energy-conserving sites of the respiratory chain. Higher concentrations result in an inhibition of oxygen consumption at (or near) both energy-conserving sites 1 and 2, while energy-conserving site 3 is unaffected. (2) Gossypol, at concentrations at which it exerts its uncoupling effect, stimulates ATPase activity. Higher concentrations inhibit the enzyme activity. (3) The addition of gossypol to mitochondria respiring on pyruvate plus malate or succinate induces a more oxidized state of NAD+ and cytochrome b, respectively. (4) Gossypol enhances the effect of Lonidamine on oxygen consumption. Lonidamine does not affect state 4 respiration, but in the presence of gossypol, it determines a marked decrease in the rate of oxygen consumption. The inhibition of oxidation of NAD-linked substrates is greater than that of FAD-linked substrates. (5) It may be concluded that gossypol is very effective in potentiating the effect of Lonidamine. Moreover, it may be suggested that the antitumor activity of Lonidamine is enhanced if it is used in combination with other drugs and/or treatments, such as hyperthermia, which modify the energy status of mitochondria.

Abstract: The AS-30D rat hepatoma cell line is characteristic of that class of rapidly growing tumors which exhibit high rates of aerobic glucose utilization and lactic acid production (Bustamante, E., Morris, H.P., and Pedersen, P.L., J. Biol. Chem., 256: 8699-8704, 1981). In this study, we have examined the coupling properties of the mitochondria in intact AS-30D hepatoma cells and the relative contributions of cytoplasmic (glycolytic) and mitochondrial compartments to total cellular ATP production in the presence of glucose and glutamine. All respiration in AS-30D cells was inhibited by inhibitors of mitochondrial electron transport, ruling out significant rates of respiration from other cellular components. Moreover, cellular respiration was found to be coupled to phosphorylation of ADP, as demonstrated by its inhibition by oligomycin and aurovertin, inhibitors of the mitochondrial ATP synthetase (F0F1-ATPase). When intact cells were supplied with glucose as the only added energy source, it was estimated that about 60% of the total cell ATP was derived from glycolysis and 40% from oxidative phosphorylation. Addition of physiological concentrations of glutamine in the presence of glucose had little effect on the relative contributions of glycolysis and oxidative phosphorylation to total cellular ATP production. In the absence of added glucose, glutamine alone could maintain the same ATP production rates by supporting mitochondrial oxidative phosphorylation. It is concluded that, in the AS-30D hepatoma cell line, glucose is the preferred energy source, with the larger portion of ATP production being supplied by glycolytic reactions. Although oxidative substrates such as glutamine can replace glucose in maintaining total cell ATP production, they do not appear to be the major fuel sources when hepatoma AS-30D cells are exposed to concentrations of substrates which occur in vivo.

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Abstract: The action of Lonidamine [1-(2,4-dichlorobenzyl)-1-H-indazol-3-carboxylic acid] on oxygen consumption and the rate of aerobic and anaerobic lactate production by Ehrlich ascites tumor cells has been investigated. The rate of oxygen consumption decreases exponentially with the increase of Lonidamine concentration, with maximal inhibition occurring at 0.40 mM Lonidamine. The rate of aerobic lactate production is inhibited to the same extent as is the oxygen consumption. However, the maximum effect is observed at 0.12 mM Lonidamine, and the decrease is linear with Lonidamine concentration. Anaerobic lactate production is more sensitive to Lonidamine, and complete inhibition can be observed by raising the concentration to 0.6 mM. The possibility that the decrease observed in lactate production was secondary to the inhibition of sodium- and potassium-containing adenosinetriphosphatase was excluded, because the drug has no effect on this enzyme. Mitochondrial adenosinetriphosphatase was not affected. Lonidamine was, however, shown to inhibit the activity of mitochondrially bound hexokinase to approximately the same extent as it inhibited aerobic glycolysis (approximately 70%). It is concluded that inhibition of the glycolysis of Ehrlich ascites tumor cells by Lonidamine results from an effect of the drug on the mitochondrially bound hexokinase.

Abstract: The action of Lonidamine [1-(2,4-chlorobenzyl)-1H-indazol-3-carboxylic acid] on respiration and aerobic lactate production of several murine tumor cells and normal differentiated murine cells was investigated. Lonidamine reduced the oxygen consumption in both normal and neoplastic cells. In contrast, it increased the aerobic glycolysis of normal cells but inhibited that of tumor cells. This selective action might be ascribed to the inhibition of mitochondrially bound hexokinase, which is usually absent in normal differentiated cells.