Abstract: Due to technical difficulties, the genetic transformation of mitochondria in mammalian cells is still a challenge. In this report, we describe our attempts to transform mammalian mitochondria with an engineered mitochondrial genome based on selection using a drug resistance gene. Because the standard drug-resistant neomycin phosphotransferase confers resistance to high concentrations of G418 when targeted to the mitochondria, we generated a recoded neomycin resistance gene that uses the mammalian mitochondrial genetic code to direct the synthesis of this protein in the mitochondria, but not in the nucleus (mitochondrial version). We also generated a universal version of the recoded neomycin resistance gene that allows synthesis of the drug-resistant proteins both in the mitochondria and nucleus. When we transfected these recoded neomycin resistance genes that were incorporated into the mouse mitochondrial genome clones into mouse tissue culture cells by electroporation, no DNA constructs were delivered into the mitochondria. We found that the universal version of the recoded neomycin resistance gene was expressed in the nucleus and thus conferred drug resistance to G418 selection, while the synthetic mitochondrial version of the gene produced no background drug-resistant cells from nuclear transformation. These recoded synthetic drug-resistant genes could be a useful tool for selecting mitochondrial genetic transformants as a precise technology for mitochondrial transformation is developed.
Abstract: We have devised a method for cloning an entire mammalian mitochondrial genome (mtDNA) in Escherichia coli using PCR-based amplification and sequential ligation. Here we test this approach by cloning the complete mouse mtDNA. The mtDNA was divided into four to five fragments based on unique restriction enzyme sites and amplified by high-fidelity long-range DNA polymerase. The synthesized fragments were cloned individually to test their toxicity in the E. coli host and then combined sequentially into a vector containing the E. coli R6K origin of DNA replication. The synthetic complete mouse mtDNA clones were replicated stably and faithfully in E. coli when maintained at moderately low copy numbers per cell. The sequence integrity of the synthetic mouse mtDNA clones was confirmed by nucleotide sequencing; no mutations or rearrangements in the genome were found. This approach can facilitate the cloning of entire mammalian mitochondrial genomes in E. coli and assist in the introduction of desired modifications into the mitochondrial genome.
Abstract: Transformation of mitochondria in mammalian cells is now a technical challenge. In this report, we demonstrate that the standard drug resistant genes encoding neomycin and hygromycin phosphotransferases can potentially be used as selectable markers for mammalian mitochondrial transformation. We re-engineered the drug resistance genes to express proteins targeted to the mitochondrial matrix and confirmed the location of the proteins in the cells by fusing them with GFP and by Western blot and mitochondrial content mixing analyses. We found that the mitochondrially targeted-drug resistance proteins confer resistance to high levels of G418 and hygromycin without affecting the viability of cells.
Abstract: A detailed molecular understanding of mitochondrial fusion and fission in mammalian cells is rapidly emerging. In this report, we demonstrate for the first time cross-species mitochondrial fusion between distantly related species using green and red fluorescent proteins targeted to the mitochondrial matrix. We found that mouse mitochondria were able to efficiently fuse to unmodified mitochondria of human cells and that the contents of the mitochondrial matrix were completely mixed in less than 4h. We also observed that mitochondria from the mtDNA-less (rho(0)) mouse cells can homogeneously fuse to the mitochondria of human cells. We were, however, unable to maintain human mitochondrial DNA in the mouse cells. These results indicate that mitochondrial fusion proteins in mouse and human cells have enough functional homology to mediate efficient cross-species mitochondrial fusion, but mouse nuclear and human mitochondrial genomes have not retained functional compatibility with one another.
Abstract: We have developed a method for transferring exogenous DNA molecules into isolated mammalian mitochondria using bacterial conjugation. In general, we accomplish this by (i) inserting an origin of DNA transfer (oriT) sequence into a DNA construct, (ii) transforming the construct into an appropriate Escherichia coli strain and then (iii) introducing the mobilizable DNA into mitochondria through conjugation. We tested this approach by transferring plasmid DNA containing a T7 promoter sequence into mitochondria that we had engineered to contain T7 RNA polymerase. After conjugation between E.coli and mitochondria, we detected robust levels of T7 transcription from the DNA constructs that had been transferred into the mitochondria. This approach for engineering DNA constructs in vitro and subsequent transfer into mitochondria by conjugation offers an attractive experimental system for studying many aspects of vertebrate mitochondrial gene expression and is a potential route for transforming mitochondrial networks within mammalian cells.
Abstract: We have devised an efficient method for replicating and stably maintaining entire mitochondrial genomes in Escherichia coli and have shown that we can engineer these mitochondrial DNA (mtDNA) genome clones using standard molecular biological techniques. In general, we accomplish this by inserting an E.coli replication origin and selectable marker into isolated, circular mtDNA at random locations using an in vitro transposition reaction and then transforming the modified genomes into E.coli. We tested this approach by cloning the 16.3 kb mouse mitochondrial genome and found that the resulting clones could be engineered and faithfully maintained when we used E.coli hosts that replicated them at moderately low copy numbers. When these recombinant mtDNAs were replicated at high copy numbers, however, mtDNA sequences were partially or fully deleted from the original clone. We successfully electroporated recombinant mouse mitochondrial genomes into isolated mouse mitochondria devoid of their own DNA and detected robust in organello RNA synthesis by RT-PCR. This approach for modifying mtDNA and subsequent in organello analysis of the recombinant genomes offers an attractive experimental system for studying many aspects of vertebrate mitochondrial gene expression and is a first step towards true in vivo engineering of mammalian mitochondrial genomes.
Abstract: Excision and amplification of pre-determined, large genomic segments (taken directly from the genome of a natural host, which provides an alternative to conventional cloning in foreign vectors and hosts) was explored in human cells. In this approach, we devised a procedure for excising a large segment of human genomic DNA, the iNOS gene, by using the Cre/loxP system of bacteriophage P1 and amplifying the excised circles with the EBNA-1/ oriP system of the Epstein-Barr virus. Two loxP sequences, each of which serves as a recognition site for recombinase Cre, were integrated unidirectionally into the 5'-UTR and 3'-UTR regions of the iNOS gene, together with an oriP sequence for conditional replication. The trans-acting genes cre and EBNA-1, which were under the control of a tetracycline responsive Phcmv*-1 promoter, were also inserted into the 5’-UTR and 3’-UTR regions of the iNOS gene, respectively, by homologous recombination. The strain carrying the inserted elements was stably maintained until the excision and amplification functions were triggered by the induction of cre and EBNA-1. Upon induction by doxycycline, Cre excised the iNOS gene that was flanked by two loxP sites and circularized it. The circularized iNOS gene was then amplified by the EBNA-1/oriP-system. With this procedure, approximately a 45.8-kb iNOS genomic fragment of human chromosome 17 was excised and successfully amplified in human cells. Our procedure can be used effectively for the sequencing of unclonable genes, the functional analysis of unknown genes, and gene therapy.
Abstract: In vivo excision and amplification of pre-determined, large genomic segments, directly from the genome of a natural host, provides an alternative to conventional cloning in foreign vectors. Using this approach, we have devised an in vivo procedure for excising large segments of Saccharomyces cerevisiae genome using Cre/loxP system of bacteriophage P1, followed by amplification of excised circles, as based on the yeast 2microm plasmid-derived ori and Flp/FRT machinery. To provide the excision and replication enzymes, trans-acting genes cre and FLP, which were under a very tight control of GAL1 and GAL10 promoters, respectively, were inserted by homologous recombination into the URA3 gene on chromosome V. Two parallel loxP sequences, which serve as the recognition sites for the Cre recombinase, were also integrated into the genome at pre-determined sites that are 50-100kb apart. Moreover, 2microm ori, REP3 and two inverted FRTs, which serve as a conditional replication system, were also integrated between the loxP sites. The strain carrying all these inserted elements was perfectly stable. Only after the induction by galactose of the Cre excision function, the genomic segment flanked by two loxP sites was excised and circularized. Applying this procedure, the 50-kb LEU2-YCR011c and 100-kb LEU2-YCR035c regions of chromosome III were successfully excised from the S. cerevisiae genome, whereas the 2microm ori, as aided by FRT/Flp, provided the amplification function. Such excised and amplified genomic segments can be used for the sequencing and functional analysis of any yeast genes.
Abstract: The isolation and amplification of large, predetermined segments of a genome from its host have been explored. The prototype of our approach was the excisional replication of some viruses such as the lambda-lysogen. Similar machinery was used to excise and amplify large genomic segments of Escherichia coli in its host. Two loxP sequences for a site-specific recombinase Cre, together with a conditional replication origin (pi-dependent gamma-ori), were inserted into the genome by homologous recombination at predetermined sites, 50-100 kb apart. Cre and pir200 which encodes the site-specific recombinase Cre and an ori-specific replication protein pi, respectively, were also introduced into the genome. The predetermined genomic segments flanked by the loxP sequences were excised and amplified upon induction of the cre and pir200 genes which were under the control of the tet promoter. This excised and amplified DNA could be easily purified as a large plasmid. This procedure can provide an alternative to conventional cloning methods by obtaining predetermined large genomic segments directly from the original organisms. In this study, using the Cre/loxP site-specific recombination and pi/gamma-ori replication system of plasmid R6K, a procedure was devised that could isolate a large segment of the E. coli genome and demonstrated the feasibility of the procedure by excising and amplifying the 50-kb trg-narZ and 100-kb trg-hipA regions of the E. coli W3110 genome.
Abstract: A novel antimicrobial peptide was isolated and characterized from the earthworm, Lumbricus rubellus. The antimicrobial peptide was purified to homogeneity by a heparin-affinity column and C18 reverse-phase HPLC, and named lumbricin I. Lumbricin I was a proline-rich antimicrobial peptide of 62 amino acids (15% proline in molar ratio; molecular mass, 7231 Da), whose complete sequence was determined by a combination of peptide sequence and cDNA analysis. The peptide and cDNA sequence analysis revealed that lumbricin I was produced as a precursor form consisting of 76 amino acids, with 14 residues in a presegment and 62 residues in mature lumbricin I. Lumbricin I showed antimicrobial activity in vitro against a broad spectrum of microorganisms without hemolytic activity. In addition, a 29-amino acid peptide, named lumbricin I(6-34), which was derived from residues 6-34 of lumbricin I, showed marginally stronger antimicrobial activity than lumbricin I. Northern blot analysis on total RNA revealed that expression of lumbricin I gene was not induced by bacterial infection, but was constitutively expressed. Furthermore, the expression of lumbricin I gene was specific in adult L. rubellus: Lumbricin I mRNA was detected only in adult L. rubellus, but not in eggs and young L. rubellus.
