Behavior of restriction-modification systems as selfish mobile elements and their impact on genome evolution

Restriction–modification (RM) systems are composed of genes that encode a restriction enzyme and a modification methylase. RM systems sometimes behave as discrete units of life, like viruses and transposons. RM complexes attack invading DNA that has not been properly modified and thus may serve as a tool of defense for bacterial cells. However, any threat to their maintenance, such as a challenge by a competing genetic element (an incompatible plasmid or an allelic homologous stretch of DNA, for example) can lead to cell death through restriction breakage in the genome. This post-segregational or post-disturbance cell killing may provide the RM complexes (and any DNA linked with them) with a competitive advantage. There is evidence that they have undergone extensive horizontal transfer between genomes, as inferred from their sequence homology, codon usage bias and GC content difference. They are often linked with mobile genetic elements such as plasmids, viruses, transposons and integrons. The comparison of closely related bacterial genomes also suggests that, at times, RM genes themselves behave as mobile elements and cause genome rearrangements. Indeed some bacterial genomes that survived post-disturbance attack by an RM gene complex in the laboratory have experienced genome rearrangements. The avoidance of some restriction sites by bacterial genomes may result from selection by past restriction attacks. Both bacteriophages and bacteria also appear to use homologous recombination to cope with the selfish behavior of RM systems. RM systems compete with each other in several ways. One is competition for recognition sequences in post-segregational killing. Another is super-infection exclusion, that is, the killing of the cell carrying an RM system when it is infected with another RM system of the same regulatory specificity but of a different sequence specificity. The capacity of RM systems to act as selfish, mobile genetic elements may underlie the structure and function of RM enzymes.     

Shaping the genome--restriction-modification systems as mobile genetic elements

A restriction enzyme gene is often linked to a modification methylase gene the role of which is to protect a recognition site on DNA from breakage by the former. Loss of some restriction-modification gene complexes leads to cell death through restriction breakage in the genome. Their behavior as genomic parasites/symbionts may explain the distribution of restriction sites and clarify certain aspects of bacterial recombination repair and mutagenesis. A comparison of bacterial genomes supports the hypothesis that restriction-modification gene complexes are mobile elements involved in various genome rearrangements and evolution.     

酵母pac—1基因的克隆、序列分析和在大肠杆菌中的高效表达及活性测定

粟酒裂殖酵母菌 (Ｓｃｈｉｚｏｓａｃｃｈａｒｍｙｃｅｓｐｏｍｂｅ)的 ｐａｃ 1基因于 1991年Ｙｕｉｃｈｉｌｉｎｏ等首次报道。在温度敏感型的酵母突变体中 ,ｐａｃ 1基因是一个多拷贝阻遏子 ,它使酵母在限制温度培养条件下的减数分裂不受调控 ,对酵母的生长过程起着重要的调节作用。该基因有一个编码 36 4个氨基酸的开放阅读框 ,编码产物的羧基端与大肠杆菌核糖核酸酶Ⅲ有2 5 %的同源性。通过酶活性测定 ,已经确定它是一类依赖ｄｓＲＮＡ的核糖核酸酶 ,具有降解ｄｓＲＮＡ的功能[1,2 ] 。由于大多数植物病毒为ＲＮＡ病毒 ,因此无论它的基…     

DNA methylation of mobile genetic elements in human cancers

Mobile genetic elements are responsible for half of the human genome, creating the host genomic instability or variability through several mechanisms. Two types of abnormal DNA methylation in the genome, hypomethylation and hypermethylation, are associated with cancer progression. Genomic hypermethylation has been most often observed on the CpG islands around gene promoter regions in cancer cells. In contrast, hypomethylation has been observed on mobile genetic elements in the cancer cells. It is recently considered that the hypomethylation of mobile genetic elements may play a biological role in cancer cells along with the DNA hypermethylation on CpG islands. Growing evidence has indicated that mobile genetic elements could be associated with the cancer initiation and progression through the hypomethylation. Here we review the recent progress on the relationship between DNA methylation and mobile genetic elements, focusing on the hypomethylation of LINE-1 and HERV elements in various human cancers and suggest that DNA hypomethylation of mobile genetic elements could have potential to be a new cancer therapy target in the future.     

Comparison between Pyrococcus horikoshii and Pyrococcus abyssi genome sequences reveals linkage of restriction-modification genes with large genome polymorphisms

Recent work suggests that restriction-modification gene complexes are mobile genetic elements that insert themselves into the genome and cause various genome rearrangements. In the present work, the complete genome sequences of Pyrococcus horikoshii and Pyrococcus abyssi, two species in a genus of hyperthermophilic archaeon (archaebacterium), were compared to detect large genome polymorphisms linked with restriction-modification gene homologs. Sequence alignments, GC content analysis, and codon usage analysis demonstrated the diversity of these homologs and revealed a possible case of relatively recent acquisition (horizontal transfer). In two cases out of the six large polymorphisms identified, there was insertion of a DNA segment with a modification gene homolog, accompanied by target deletion (simple substitution). In two other cases, homologous DNA segments carrying a modification gene homolog were present at different locations in the two genomes (transposition). In both cases, substitution (insertion/deletion) in one of the two loci was accompanied by inversion of adjacent chromosomal segment. In the fifth case, substitution by a DNA segment carrying type I restriction, modification, and specificity gene homologs was likewise accompanied by adjacent inversion. In the last case, two homologous DNA segments, were found at different loci in the two genomes (transposition), but only one of them had insertion of a modification homolog and an unknown ORF. The possible relationship of these polymorphisms to attack by restriction enzymes on the chromosome will be discussed.     

Control of photosynthetic membrane assembly in Rhodobacter sphaeroides mediated by puhA and flanking sequences.

A reaction center H- strain (RCH-) of Rhodobacter sphaeroides, PUHA1, was made by in vitro deletion of an XhoI restriction endonuclease fragment from the puhA gene coupled with insertion of a kanamycin resistance gene cartridge. The resulting construct was delivered to R. sphaeroides wild-type 2.4.1, with the defective puhA gene replacing the wild-type copy by recombination, followed by selection for kanamycin resistance. When grown under conditions known to induce intracytoplasmic membrane development, PUHA1 synthesized a pigmented intracytoplasmic membrane. Spectral analysis of this membrane showed that it was deficient in B875 spectral complexes as well as functional reaction centers and that the level of B800-850 spectral complexes was greater than in the wild type. The RCH- strain was photosythetically incompetent, but photosynthetic growth was restored by complementation with a 1.45-kilobase (kb) BamHI restriction endonuclease fragment containing the puhA gene carried in trans on plasmid pRK404. B875 spectral complexes were not restored by complementation with the 1.45-kb BamHI restriction endonuclease fragment containing the puhA gene but were restored along with photosynthetic competence by complementation with DNA from a cosmid carrying the puhA gene, as well as a flanking DNA sequence. Interestingly, B875 spectral complexes, but not photosynthetic competence, were restored to PUHA1 by introduction in trans of a 13-kb BamHI restriction endonuclease fragment carrying genes encoding the puf operon region of the DNA. The effect of the puhA deletion was further investigated by an examination of the levels of specific mRNA species derived from the puf and puc operons, as well as by determinations of the relative abundances of polypeptides associated with various spectral complexes by immunological methods. The roles of puhA and other genetic components in photosynthetic gene expression and membrane assembly are discussed.     

Movement of DNA sequence recognition domains between non-orthologous proteins

Comparisons of proteins show that they evolve through the movement of domains. However, in many cases, the underlying mechanisms remain unclear. Here, we observed the movements of DNA recognition domains between non-orthologous proteins within a prokaryote genome. Restriction–modification (RM) systems, consisting of a sequence-specific DNA methyltransferase and a restriction enzyme, contribute to maintenance/evolution of genomes/epigenomes. RM systems limit horizontal gene transfer but are themselves mobile. We compared Type III RM systems in Helicobacter pylori genomes and found that target recognition domain (TRD) sequences are mobile, moving between different orthologous groups that occupy unique chromosomal locations. Sequence comparisons suggested that a likely underlying mechanism is movement through homologous recombination of similar DNA sequences that encode amino acid sequence motifs that are conserved among Type III DNA methyltransferases. Consistent with this movement, incongruence was observed between the phylogenetic trees of TRD regions and other regions in proteins. Horizontal acquisition of diverse TRD sequences was suggested by detection of homologs in other Helicobacter species and distantly related bacterial species. One of these RM systems in H. pylori was inactivated by insertion of another RM system that likely transferred from an oral bacterium. TRD movement represents a novel route for diversification of DNA-interacting proteins.     

A functional bacteria-derived restriction modification system in the mitochondrion of a heterotrophic protist

The overarching trend in mitochondrial genome evolution is functional streamlining coupled with gene loss. Therefore, gene acquisition by mitochondria is considered to be exceedingly rare. Selfish elements in the form of self-splicing introns occur in many organellar genomes, but the wider diversity of selfish elements, and how they persist in the DNA of organelles, has not been explored. In the mitochondrial genome of a marine heterotrophic katablepharid protist, we identify a functional type II restriction modification (RM) system originating from a horizontal gene transfer (HGT) event involving bacteria related to flavobacteria. This RM system consists of an HpaII-like endonuclease and a cognate cytosine methyltransferase (CM). We demonstrate that these proteins are functional by heterologous expression in both bacterial and eukaryotic cells. These results suggest that a mitochondrion-encoded RM system can function as a toxin–antitoxin selfish element, and that such elements could be co-opted by eukaryotic genomes to drive biased organellar inheritance.

This study reveals that a functional type II restriction modification system of flavobacterial ancestry has been horizontally transferred into the mitochondrion of a marine protist and is capable of encoding potent function, perhaps allowing it to play a role in inter-organellar warfare or protection against further integration of foreign DNA.     

A mobile restriction–modification system provides phage defence and resolves an epigenetic conflict with an antagonistic endonuclease

Epigenetic DNA methylation plays an important role in bacteria by influencing gene expression and allowing discrimination between self-DNA and intruders such as phages and plasmids. Restriction–modification (RM) systems use a methyltransferase (MTase) to modify a specific sequence motif, thus protecting host DNA from cleavage by a cognate restriction endonuclease (REase) while leaving invading DNA vulnerable. Other REases occur solitarily and cleave methylated DNA. REases and RM systems are frequently mobile, influencing horizontal gene transfer by altering the compatibility of the host for foreign DNA uptake. However, whether mobile defence systems affect pre-existing host defences remains obscure. Here, we reveal an epigenetic conflict between an RM system (PcaRCI) and a methylation-dependent REase (PcaRCII) in the plant pathogen Pectobacterium carotovorum RC5297. The PcaRCI RM system provides potent protection against unmethylated plasmids and phages, but its methylation motif is targeted by the methylation-dependent PcaRCII. This potentially lethal co-existence is enabled through epigenetic silencing of the PcaRCII-encoding gene via promoter methylation by the PcaRCI MTase. Comparative genome analyses suggest that the PcaRCII-encoding gene was already present and was silenced upon establishment of the PcaRCI system. These findings provide a striking example for selfishness of RM systems and intracellular competition between different defences.     

Post-segregational killing by restriction modification gene complexes: observations of individual cell deaths

Through a mechanism known as post-segregational killing, several plasmids mediate their stable maintenance by carrying genes that kill plasmid-free segregant cells. We demonstrated earlier that loss of plasmids carrying type II restriction modification (RM) gene complexes inhibits the propagation of a cell population and causes chromosome breakage. We now show the morphology of individual cells changes following loss of thermosensitive plasmids carrying EcoRI RM or PaeR7I RM after a shift to a non-permissive temperature. After a lag, many cells formed long filaments containing multiple nuclei as detected by DAPI staining. Several hours after the shift, many of these long filaments lacked nuclei. Fragmentation of chromosomal DNA down to 5 kb was detected by electrophoresis. These observations lend strong support to the concept of post-segregational cell killing by type II restriction modification gene complexes.     

Isolation of a repeated DNA sequence from Bordetella pertussis

A repeated DNA sequence in the genome of Bordetella pertussis has been demonstrated. At least 20 copies of this sequence could be observed in either BamHI or EcoRI restriction enzyme digests of chromosomal DNA; fragments carrying the repeated DNA sequence ranged in size from about 1.5 to 20 kbp. The repeated DNA sequence was cloned from two separate regions of the B. pertussis genome, as shown by restriction enzyme site maps of the two clones and by hybridization studies. A small number of differences in the pattern of hybridization of the repeated DNA sequence to chromosomal DNA from several strains of B. pertussis was observed. No repeated DNA sequences were observed in one strain each of B. parapertussis and B. bronchiseptica, and there was no hybridization of B. pertussis DNA to Escherichia coli chromosomal DNA. The repeated DNA sequence was subcloned on a 2.54 kbp BamHI fragment from one of the two original clones. Restriction enzyme digests and hybridization studies showed that the repeated DNA sequence was about 1 kbp in size and had a single, internal ClaI site.     

PsasM2I,a Type II Restriction–Modification System in Pseudomonas savastanoi pv. savastanoi: Differential Distribution of Carrier Strains in the Environment and the Evolutionary History of Homologous RM Systems in the Pseudomonas syringae Complex

A type II restriction–modification system was found in a native plasmid of Pseudomonas savastanoi pv. savastanoi MLLI2. Functional analysis of the methyltransferase showed that the enzyme acts by protecting the DNA sequence CTGCAG from cleavage. Restriction endonuclease expression in recombinant Escherichia coli cells resulted in mutations in the REase sequence or transposition of insertion sequence 1A in the coding sequence, preventing lethal gene expression. Population screening detected homologous RM systems in other P. savastanoi strains and in the Pseudomonas syringae complex. An epidemiological survey carried out by sampling olive and oleander knots in two Italian regions showed an uneven diffusion of carrier strains, whose presence could be related to a selective advantage in maintaining the RM system in particular environments or subpopulations. Moreover, carrier strains can coexist in the same orchards, plants, and knot tissues with non-carriers, revealing unexpected genetic variability on a very small spatial scale. Phylogenetic analysis of the RM system and housekeeping gene sequences in the P. syringae complex demonstrated the ancient acquisition of the RM systems. However, the evolutionary history of the gene complex also showed the involvement of horizontal gene transfer between related strains and recombination events.     

Epstein-Barr virus intrastrain recombination in oral hairy leukoplakia.

In laboratory lymphoblastoid cell lines and in natural human infections, Epstein-Barr virus (EBV) strains have been identified by DNA restriction fragment length polymorphisms of the BamHI H fragment. Multiple, heterogeneous BamHI H fragments have been detected in oral hairy leukoplakia (HLP), raising the question of EBV coinfection with multiple strains. To investigate whether the heterogeneous BamHI H fragments represent different EBV strains or recombinant variants of the same strain, EBV DNA from HLP lesions was analyzed to characterize the viral strains and determine the source of possible recombinant variants. Clones of heterogeneous BamHI H fragments from a single HLP lesion were determined to have strain identity on the basis of sequence identity of the EBNA-2 genes. Intrastrain homologous recombination within the IR2 internal repeat region and nonhomologous recombination of other sequences accounted for the heterogeneity of the BamHI H fragments. PCR amplification from additional HLP specimens detected similar recombinant variants. A possible example of site-specific recombination joining the BamHI Y portion of the EBNA-2 gene to sequences within the BamHI S fragment was also detected in multiple HLP specimens. These data indicate that intrastrain recombination during productive replication confounds the use of restriction fragment length polymorphism analysis of the BamHI Y and H fragments to identify EBV strains in HLP. In patients with permissive epithelial EBV infections, EBV strains could be more accurately distinguished by sequence identity or divergence within known regions of genetic strain variation.     

Detection and mapping of homologous, repeated and amplified DNA sequences by DNA renaturation in agarose gels.

A new molecular hybridization approach to the analysis of complex genomes has been developed. Tracer and driver DNAs were digested with the same restriction enzyme(s), and tracer DNA was labeled with 32P using T4 DNA polymerase. Tracer DNA was mixed with an excess amount of driver, and the mixture was electrophoresed in an agarose gel. Following electrophoresis, DNA was alkali-denatured in situ and allowed to reanneal in the gel, so that tracer DNA fragments could hybridize to the driver only when homologous driver DNA sequences were present at the same place in the gel, i.e. within a restriction fragment of the same size. After reannealing, unhybridized single-stranded DNA was digested in situ with S1 nuclease. The hybridized tracer DNA was detected by autoradiography. The general applicability of this technique was demonstrated in the following experiments. The common EcoRI restriction fragments were identified in the genomes of E. coli and four other species of bacteria. Two of these fragments are conserved in all Enterobacteriaceae. In other experiments, repeated EcoRI fragments of eukaryotic DNA were visualized as bands of various intensity after reassociation of a total genomic restriction digest in the gel. The situation of gene amplification was modeled by the addition of varying amounts of lambda phage DNA to eukaryotic DNA prior to restriction enzyme digestion. Restriction fragments of lambda DNA were detectable at a ratio of 15 copies per chicken genome and 30 copies per human genome. This approach was used to detect amplified DNA fragments in methotrexate (MTX)-resistant mouse cells and to identify commonly amplified fragments in two independently derived MTX-resistant lines.     

Identification of the gene encoding Marek''s disease herpesvirus A antigen.

The gene encoding the glycoprotein Marek's disease herpesvirus A antigen (MDHV-A) precursor polypeptide pr47 was delineated by using Northern blot (RNA blot) analysis and hybrid selection of its mRNA with cloned MDHV DNA, cell-free translation of the mRNA, and immunoprecipitation of the polypeptide. The resulting piece of DNA with strongly positive hybrid selection results was a 2.2-kilobase-pair (kbp) PvuII-EcoRI restriction fragment localized to the center of the 18.3-kbp MDHV BamHI B fragment of the total virus genome. The localization was specific since no other small restriction subfragment of the larger BamHI B fragment was able to hybrid select significant MDHV-A mRNA and the gene mapped only in the BamHI B fragment of the total virus genome. Northern blot analysis confirmed the localization of the MDHV-A gene on the 2.2-kbp fragment and detected its mRNA as a 1.8-kilobase species, a size consistent with encoding a 47-kilodalton polypeptide. This is the first report of an MDHV gene being mapped to the MDHV viral genome. This opens the way for the use of recombinant DNA technology to study the nature of the gene encoding a secreted virus-specific glycoprotein that could possibly be involved in immunoprevention, immunosuppression, or immunoevasion, immune phenomena known or speculated to be involved in this oncogenic herpesvirus system.     

Polymorphism and complexity of the human DC and murine I-A alpha chain genes

A cDNA clone encoding the human B cell alloantigen DC alpha chain (pDCH1) has been used to analyse the structure of the human and murine major histocompatibility complexes by the DNA filter hybridization technique. The pDCH1 probe hybridizes to a single DNA sequence present on chromosome 17 in the mouse genome. A restriction enzyme polymorphism enables us to map this sequence to the I-A subregion. Extensive restriction enzyme polymorphism detected in HLA-DR homozygous typing cells is reminiscent of the DR/MT linkage disequilibrium groups, suggesting that the pDCH1 probe could be useful for haplotype typing in the human population. The HLA-DR region appears more complex than the I region since a second DC-like hybridizing sequence is detected in the human genome in these experiments.