Reverse transcriptase from Escherichia coli exists as a complex with msDNA and is able to synthesize double-stranded DNA

Bacterial retrons encode phage-defending tripartite toxin-antitoxin systems

Retrons are prokaryotic genetic retroelements encoding a reverse transcriptase that produces multi-copy single-stranded DNA1 (msDNA). Despite decades of research on the biosynthesis of msDNA2, the function and physiological roles of retrons have remained unknown. Here we show that Retron-Sen2 of Salmonella enterica serovar Typhimurium encodes an accessory toxin protein, STM14_4640, which we renamed as RcaT. RcaT is neutralized by the reverse transcriptase-msDNA antitoxin complex, and becomes active upon perturbation of msDNA biosynthesis. The reverse transcriptase is required for binding to RcaT, and the msDNA is required for the antitoxin activity. The highly prevalent RcaT-containing retron family constitutes a new type of tripartite DNA-containing toxin-antitoxin system. To understand the physiological roles of such toxin-antitoxin systems, we developed toxin activation-inhibition conjugation (TAC-TIC), a high-throughput reverse genetics approach that identifies the molecular triggers and blockers of toxin-antitoxin systems. By applying TAC-TIC to Retron-Sen2, we identified multiple trigger and blocker proteins of phage origin. We demonstrate that phage-related triggers directly modify the msDNA, thereby activating RcaT and inhibiting bacterial growth. By contrast, prophage proteins circumvent retrons by directly blocking RcaT. Consistently, retron toxin-antitoxin systems act as abortive infection anti-phage defence systems, in line with recent reports3,4. Thus, RcaT retrons are tripartite DNA-regulated toxin-antitoxin systems, which use the reverse transcriptase-msDNA complex both as an antitoxin and as a sensor of phage protein activities.

Cryo-EM structures of Escherichia coli Ec86 retron complexes reveal architecture and defence mechanism

First discovered in the 1980s, retrons are bacterial genetic elements consisting of a reverse transcriptase and a non-coding RNA (ncRNA). Retrons mediate antiphage defence in bacteria but their structure and defence mechanisms are unknown. Here, we investigate the Escherichia coli Ec86 retron and use cryo-electron microscopy to determine the structures of the Ec86 (3.1 Å) and cognate effector-bound Ec86 (2.5 Å) complexes. The Ec86 reverse transcriptase exhibits a characteristic right-hand-like fold consisting of finger, palm and thumb subdomains. Ec86 reverse transcriptase reverse-transcribes part of the ncRNA into satellite, multicopy single-stranded DNA (msDNA, a DNA-RNA hybrid) that we show wraps around the reverse transcriptase electropositive surface. In msDNA, both inverted repeats are present and the 3' sides of the DNA/RNA chains are close to the reverse transcriptase active site. The Ec86 effector adopts a two-lobe fold and directly binds reverse transcriptase and msDNA. These findings offer insights into the structure-function relationship of the retron-effector unit and provide a structural basis for the optimization of retron-based genome editing systems.

OUP accepted manuscript

Retrons are bacterial retroelements that produce single-stranded, reverse-transcribed DNA (RT-DNA) that is a critical part of a newly discovered phage defense system. Short retron RT-DNAs are produced from larger, structured RNAs via a unique 2′-5′ initiation and a mechanism for precise termination that is not yet understood. Interestingly, retron reverse transcriptases (RTs) typically lack an RNase H domain and, therefore, depend on endogenous RNase H1 to remove RNA templates from RT-DNA. We find evidence for an expanded role of RNase H1 in the mechanism of RT-DNA termination, beyond the mere removal of RNA from RT-DNA:RNA hybrids. We show that endogenous RNase H1 determines the termination point of the retron RT-DNA, with differing effects across retron subtypes, and that these effects can be recapitulated using a reduced, in vitro system. We exclude mechanisms of termination that rely on steric effects of RNase H1 or RNA secondary structure and, instead, propose a model in which the tertiary structure of the single-stranded RT-DNA and remaining RNA template results in termination. Finally, we show that this mechanism affects cellular function, as retron-based phage defense is weaker in the absence of RNase H1.

Retrons and their applications in genome engineering

Precision genome editing technologies have transformed modern biology. These technologies have arisen from the redirection of natural biological machinery, such as bacteriophage lambda proteins for recombineering and CRISPR nucleases for eliciting site-specific double-strand breaks. Less well-known is a widely distributed class of bacterial retroelements, retrons, that employ specialized reverse transcriptases to produce noncoding intracellular DNAs. Retrons' natural function and mechanism of genetic transmission have remained enigmatic. However, recent studies have harnessed their ability to produce DNA in situ for genome editing and evolution. This review describes retron biology and function in both natural and synthetic contexts. We also highlight areas that require further study to advance retron-based precision genome editing platforms.

Multi-copy single-stranded DNA in Escherichia coli

Multi-copy single-stranded DNA (msDNA) is composed of covalently bound single-stranded DNA and RNA, and synthesized by retron-encoded reverse transcriptase. msDNA-synthesizing systems are thought to be a recent acquisition by Escherichia coli because, to date, only seven types of msDNA, which differ markedly in their primary nucleotide sequences, have been found in a small subset of E. coli strains. The wide use of E. coli in molecular research means that it is important to understand more about these stable, covalently bound, single-stranded DNA or RNA compounds. The present review provides insights into the molecular biosynthesis, distribution and function of E. coli msDNA to raise awareness about these special molecules.

Retron Se72 utilizes a unique strategy of the self-priming initiation of reverse transcription

Unlike all of the other retrons, the bacterial retron reverse transcriptase RrtE is capable of synthesizing small double-stranded DNA (sdsDNA) from template RNA. In this study, we analyzed the biosynthesis of the sdsDNA by RrtE in detail. We found out that the initiation of reverse transcription was dependent on a novel self-priming mechanism utilizing a free 3'OH of RNA that is reverse-transcribed into sdsDNA. The priming of the sdsDNA synthesis was not dependent on any particular nucleotide being used as a donor of 3'OH (unlike all of the other retrons, which prime from 2'OH of a particular guanosine) or any particular nucleotide being introduced into the sdsDNA first. Due to the relaxed demands for the initiation of reverse transcription, RrtE has the potential to generate dsDNA from different RNA transcripts in vivo.

A reverse transcriptase-related protein mediates phage resistance and polymerizes untemplated DNA in vitro

Reverse transcriptases (RTs) are RNA-dependent DNA polymerases that usually function in the replication of selfish DNAs such as retrotransposons and retroviruses. Here, we have biochemically characterized a RT-related protein, AbiK, which is required for abortive phage infection in the Gram-positive bacterium Lactococcus lactis. In vitro, AbiK does not exhibit the properties expected for an RT, but polymerizes long DNAs of 'random' sequence, analogous to a terminal transferase. Moreover, the polymerized DNAs appear to be covalently attached to the AbiK protein, presumably because an amino acid serves as a primer. Mutagenesis experiments indicate that the polymerase activity resides in the RT motifs and is essential for phage resistance in vivo. These results establish a novel biochemical property and a non-replicative biological role for a polymerase.

Retrons, msDNA, and the bacterial genome

Retrons are distinct DNA sequences that code for a reverse transcriptase (RT) similar to the RTs produced by retroviruses and other types of retroelements. Retron DNAs are commonly associated with prophage DNA and are found in the genomes of a wide variety of different bacteria. The retron RT is used to synthesize a strange satellite DNA known as msDNA. msDNA is actually a complex of DNA, RNA, and probably protein. It is composed of a small, single-stranded DNA, linked to a small, single-stranded RNA molecule. The 5' end of the DNA molecule is joined to an internal guanosine residue of the RNA molecule by a unique 2'-5' phosphodiester bond. msDNA is produced in many hundreds of copies per cell, but its function remains unknown. Although retrons are absent from the genome of most members of a population of related bacteria, retrons may not be entirely benign DNAs. Evidence is beginning to suggest that retron elements may produce small but potentially significant effects on the host cell. This includes the generation of repeated copies of the msDNA sequence in the genome, and increasing the frequency of spontaneous mutations. Because these events involve the retron RT, this may represent a source of reverse transcription in the bacterial cell. Thus, the process of reverse transcription, a force that has profoundly affected the content and structure of most eukaryotic genomes, may likewise be responsible for changes in some prokaryotic genomes.

Avoidance of false PCR results with the integron-retron junction in multiple antibiotic resistant Salmonella enterica serotype Typhimurium

Salmonella infections continue to cause gastrointestinal and systemic disease throughout the world. Another concern with this pathogen is the ability to acquire integrons that confer resistance to multiple antibiotics. For multiresistant Salmonella enterica serotype Typhimurium, the most common multiresistant Salmonella serotype, an integron structure can be found between thdF and a retron. Our objective was to investigate the utility of a 450 bp thdF-retron amplicon as an indicator of an insertless thdF-retron junction thus indicating an integron-free strain. Surprisingly, we found that the 450 bp thdF-retron amplicon was present, and thus incorrectly suggesting an integron-free status, in some multiresistant S. enterica serotype Typhimurium isolates. However, this phenomenon was not observed if the isolate was enriched in the presence of two antibiotics. This demonstrates that, within some individual clinical isolates of multiresistant S. enterica serotype Typhimurium, there exists a small subpopulation of integron-free bacteria. Consequently, it appears that the thdF-retron amplicon is an inaccurate predictor of integron status in S. enterica serotype Typhimurium unless multiresistance is used as a selection tool during enrichment.

A partial copy of msDNA from a new retron element is likely a retrotransposed DNA found in the myxobacterium Nannocystis exedens

Retrons are reverse transcriptase (RT) encoding genetic elements usually located on the chromosome of a wide variety of mostly Gram-negative bacteria. Here we describe a new retron, designated Ne144, found in the chromosome of the myxobacterium Nannocystis exedens. This element codes for a 515-amino-acid RT that is most closely related to those found in other myxobacterial retrons. The RT is responsible for the production of a small satellite DNA called msDNA. This msDNA is composed of a 144 base, single-stranded DNA that is linked to a 72 base single-stranded RNA. The RNA strand is joined to the 5' end of the DNA chain via a 2'-5' linkage that occurs from the 2' position of an internal guanosine residue in the RNA. In addition to the retron element, the chromosome of N. exedens also contains several partial copies of the msDNA sequence as revealed by DNA hybridization experiments using msDNA as a probe. One of these partial copies was characterized from a chromosome restriction fragment and found to contain a sequence that matches the last 82 bases of the DNA strand and five bases of the RNA strand in msDNA-Ne144. This partial copy of msDNA is very likely a retrotransposed sequence that was generated by reverse transcription using an RNA (the primer-template RNA for msDNA) as a template and the 3' end of a nick in the chromosome as a primer, followed by incorporation into an open reading frame. The presence of this truncated copy of msDNA is strong evidence of retrotransposition in N. exedens causing an alteration in the bacterial genome.

The msDNAs of bacteria

msDNAs are small, structurally unique satellite DNAs found in a number of Gram-negative bacteria. Composed of hundreds of copies of single-stranded DNA--hence the name multicopy single-stranded DNA--msDNA is actually a complex of DNA, RNA, and probably protein. These peculiar molecules are synthesized by a reverse transcription mechanism catalyzed by a reverse transcriptase (RT) that is evolutionarily related to the polymerase found in the HIV virus. The genes, including the RT gene, responsible for the synthesis of msDNA are encoded in a retron, a genetic element that is carried on the bacterial chromosome. The retron is, in fact, the first such retroelement to be discovered in prokaryotic cells. This report is a comprehensive review of the many interesting questions raised by this unique DNA and the fascinating answers it has revealed. We have learned a great deal about the structure of msDNA: how it is synthesized, the structure and functions of the RT protein required to make it, its effects on the host cell, the retron element that encodes it, its possible origins and evolution, and even its potential usefulness as a practical genetic tool. Despite the impressive gains in our understanding of the msDNAs, however, the simple, fundamental question of its natural function remains an enduring mystery. Thus, we have much more to learn about the msDNAs of bacteria.

Low-molecular-weight plasmid of Salmonella enterica serovar Enteritidis codes for retron reverse transcriptase and influences phage resistance

Retron reverse transcriptases are unusual procaryotic enzymes capable of synthesis of low-molecular-weight DNA by reverse transcription. All of the so-far-described DNA species synthesized by retron reverse transcriptases have been identified as multicopy single-stranded DNA. We have shown that Salmonella enterica serovar Enteritidis is also capable of synthesis of the low-molecular-weight DNA by retron reverse transcriptase. Surprisingly, Salmonella serovar Enteritidis-produced low-molecular-weight DNA was shown to be a double-stranded DNA with single-stranded overhangs (sdsDNA). The sdsDNA was 72 nucleotides (nt) long, of which a 38-nt sequence was formed by double-stranded DNA with 19- and 15-nt single-stranded overhangs, respectively. Three open reading frames (ORFs), encoded by the 4,053-bp plasmid, were essential for the production of sdsDNA. These included an ORF with an unknown function, the retron reverse transcriptase, and an ORF encoding the cold shock protein homologue. This plasmid was also able to confer phage resistance onto the host cell by a mechanism which was independent of sdsDNA synthesis.

Efficient gap repair catalyzed in vitro by an intrinsic DNA polymerase activity of human immunodeficiency virus type 1 integrase

Cleavage and DNA joining reactions, carried out by human immunodeficiency virus type 1 (HIV-1) integrase, are necessary to effect the covalent insertion of HIV-1 DNA into the host genome. For the integration of HIV-1 DNA into the cellular genome to be completed, short gaps flanking the integrated proviral DNA must be repaired. It has been widely assumed that host cell DNA repair enzymes are involved. Here we report that HIV-1 integrase multimers possess an intrinsic DNA-dependent DNA polymerase activity. The activity was characterized by its dependence on Mg2+, resistance to N-ethylmaleimide, and inhibition by 3'-azido-2',3'-dideoxythymidine-5'-triphosphate, coumermycin A1, and pyridoxal 5'-phosphate. The enzyme efficiently utilized poly(dA)-oligo(dT) or self-annealing oligonucleotides as a template primer but displayed relatively low activity with gapped calf thymus DNA and no activity with poly(dA) or poly(rA)-oligo(dT). A monoclonal antibody binding specifically to an epitope comprised of amino acids 264 to 273 near the C terminus of HIV-1 integrase severely inhibited the DNA polymerase activity. A deletion of 50 amino acids at the C terminus of integrase drastically altered the gel filtration properties of the DNA polymerase, although the level of activity was unaffected by this mutation. The DNA polymerase efficiently extended a hairpin DNA primer up to 19 nucleotides on a T20 DNA template, although addition of the last nucleotide occurred infrequently or not at all. The ability of integrase to repair gaps in DNA was also investigated. We designed a series of gapped molecules containing a single-stranded region flanked by a duplex U5 viral arm on one side and by a duplex nonviral arm on the other side. Molecules varied structurally depending on the size of the gap (one, two, five, or seven nucleotides), their content of T's or C's in the single-stranded region, whether the CA dinucleotide in the viral arm had been replaced with a nonviral sequence, or whether they contained 5' AC dinucleotides as unpaired tails. The results indicated that the integrase DNA polymerase is specifically designed to repair gaps efficiently and completely, regardless of gap size, base composition, or structural features such as the internal CA dinucleotide or unpaired 5'-terminal AC dinucleotides. When the U5 arm of the gapped DNA substrate was removed, leaving a nongapped DNA template-primer, the integrase DNA polymerase failed to repair the last nucleotide in the DNA template effectively. A post-gap repair reaction did depend on the CA dinucleotide. This secondary reaction was highly regulated. Only two nucleotides beyond the gap were synthesized, and these were complementary to and dependent for their synthesis on the CA dinucleotide. We were also able to identify a specific requirement for the C terminus of integrase in the post-gap repair reaction. The results are consistent with a direct role for a heretofore unsuspected DNA polymerase function of HIV-1 integrase in the repair of short gaps flanking proviral DNA integration intermediates that arise during virus infection.

A mutational study of the site-specific cleavage of EC83, a multicopy single-stranded DNA (msDNA): nucleotides at the msDNA stem are important for its cleavage

Multicopy single-stranded DNA (msDNA) molecules consist of single-stranded DNA covalently linked to RNA. Such molecules are encoded by genetic elements called retrons. Unlike other retrons, retron EC83 isolated from Escherichia coli 161 produces RNA-free msDNA by site-specific cleavage of msDNA at 5'-TTGA/A-3', where the slash indicates the cleavage site. In order to investigate factors responsible for the msDNA cleavage, retron EC83 was treated with hydroxylamine and colonies were screened for cleavage-negative mutants. We isolated three mutants which were defective in msDNA cleavage and produced RNA-linked msDNA. They were all affected in msd, a gene for msDNA, with a base substitution at the bottom part of the msDNA stem. In contrast, base substitution at and around the cleavage site has no marked effect on msDNA synthesis or its cleavage. From these results, we concluded that the nucleotides at the bottom of the msDNA stem, but not the nucleotides at the cleavage site, play a major role in the recognition and cleavage of msDNA EC83.

Starvation-induced expression of retron-Ec107 and the role of ppGpp in multicopy single-stranded DNA production

Multicopy single-stranded DNA is found as a small single-stranded RNA-DNA complex in certain wild-type strains of Escherichia coli as well as in other gram-negative bacteria. Using the promoter region of the previously characterized retron-Ec107 from E. coli ECOR70, I constructed a chromosomally located lacZ operon fusion. Examination of expression from the PEc107 promoter showed that activity increased sharply when cells entered stationary phase in rich medium or when they were starved for phosphate. The nucleotide guanosine-3',5'-bispyrophosphate was found to be a positive regulator of retron-Ec107 expression. Its presence is required for starvation-induced transcription of retron-Ec107 and multicopy single-stranded DNA production. It was also found that expression from the retron promoter is independent of the sigma factor sigmaS.

Structure, function, and evolution of bacterial reverse transcriptase

The discovery of retroelements in the prokaryotes raises intriguing questions concerning their roles in bacteria and the origin and evolution of reverse transcriptases. We first discuss a possible structure of bacterial reverse transcriptases on the basis of the known three-dimensional structure of HIV-1 reverse transcriptase, and how such a putative three-dimensional structure is able to recognize a single primer-template RNA molecule to initiate DNA chain elongation from the 2'-OH group of an internal G residue. This reaction leads to the production of a unique RNA-DNA complex called msDNA (multicopy single-stranded DNA) in which a single-stranded DNA branches out from an RNA molecule via a 2',5'-phosphodiester linkage. Second, the mobility of the bacterial retroelements called retrons, responsible for the production of msDNA, are discussed and compared with the mobility of group I and group II introns. Third, the original and evolution of bacterial reverse transcriptases are discussed in light of the question of whether the bacterial reverse transcriptases are older than eukaryotic reverse transcriptases.

Bacterial reverse transcriptase and msDNA

Retrons are a new class of genetic elements found in the chromosome of a large number of different bacteria. These elements code for a reverse transcriptase (RT) that is structurally similar to the polymerases of retroviruses. The retron associated RT is responsible for the production of an unusual extrachromosomal satellite DNA, known as multicopy, single-stranded DNA (msDNA). Synthesis of msDNA is dependent on a novel self-priming mechanism, resulting in the formation of a 2',5'-phosphodiester bond. A comparison of bacterial RTs is presented, noting conserved and unique features of these polymerases. In addition, the origin, means of dissemination, and possible activities of these functionally obscure retroelements are discussed.

Phylogenetic comparison of retron elements among the myxobacteria: evidence for vertical inheritance

Twenty-eight myxobacterial strains, representing members from all three subgroups, were screened for the presence of retron elements, which are novel prokaryotic retroelements encoding reverse transcriptase. The presence of retrons was determined by assaying strains for a small satellite DNA produced by reverse transcription called multicopy, single-stranded DNA (msDNA). An msDNA-producing retron appeared to be absent from only one of the strains surveyed. DNA hybridization experiments revealed that retron elements similar to retron Mx162, first identified in Myxococcus xanthus, were found only among members of the Myxococcus subgroup; that is, each of the seven different genera which constitute this subgroup contained a Mx162 homolog. Another retron element also appeared to have a clustered distribution, being found exclusively within the Nannocystis subgroup of the myxobacteria. A retron element of the Mx162 type was cloned from Melittangium lichenicola, and its DNA sequence was compared with those of similar elements in M. xanthus and Stigmatella aurantiaca. Together, the degree of sequence diversity, the codon bias of the reverse transcriptase genes, and the clustered distribution of these retrons suggest a possible evolutionary scenario in which a common ancestor of the Myxococcus subgroup may have acquired this retroelement.

Diversity of retron elements in a population of rhizobia and other gram-negative bacteria

Genetic elements called retrons reside on the chromosome of Escherichia coli and the myxobacteria and represent the first reverse transcriptase-encoding element to be found in a prokaryotic cell. All known retrons produce a functionally obscure RNA-DNA satellite molecule called multicopy single-stranded DNA (msDNA). We report here the presence of msDNA-producing retron elements in a number of new bacterial groups, including strains of the genera Proteus, Klebsiella, Salmonella, Nannocystis, Rhizobium, and Bradyrhizobium. Among a population of 63 rhizobia strains, only 16% contain a retron element. The rhizobia retrons appear to be heterogeneous in nucleotide sequence and show little similarity to previously studied retrons of E. coli and the myxobacteria.

Survey of multicopy single-stranded DNAs and reverse transcriptase genes among natural isolates of Myxococcus xanthus

Twenty different isolates of the soil bacterium Myxococcus xanthus were examined for the presence of multicopy single-stranded DNA (msDNA)-producing retroelements, or retrons. Each strain was analyzed by ethidium bromide staining for msDNA, 32P labeling of the msDNA molecule by the reverse transcriptase (RT) extension method, and DNA hybridization experiments with probes derived from two retrons, Mx162 and Mx65, previously cloned from M. xanthus DZF1. These analyses revealed that all M. xanthus strains contain an msDNA very similar to Mx162 msDNA, and 13 strains also contain a second smaller msDNA very similar to Mx65 msDNA. In addition, the strains contained retron-encoded genes msr and msd, which code for msDNA, and a gene for RT responsible for the synthesis of msDNA. These genes show greater than 80% nucleotide sequence similarity to retrons Mx162 or Mx65. The near-ubiquitous occurrence of msDNA retrons among M. xanthus strains and their homogeneous nature are in marked contrast to the highly diverse but rarely occurring msDNA-producing elements of Escherichia coli. The possible origin and evolution of RT and retron elements is discussed in view of these findings.

Structure of two retrons of Escherichia coli and their common chromosomal insertion site

It has been shown that certain strains of myxobacteria and of Escherichia coli have a genetic element encoding a reverse transcriptase (RT). This element, called a 'retron', produces a covalently linked RNA-DNA compound (msDNA-RNA). Here, I report the complete nucleotide sequence of retron EC-86, the retron in E. coli B, together with its flanking regions. Retron EC-86 contains genes for msDNA-RNA (msd, and msr), a gene for RT (ret) and a gene for an open reading frame whose function is unknown. The upstream junction is composed of the sequence GCGCGCGC, but there are no direct or inverted repeats at the retron-host junctions. It is also shown that another retron of E. coli, EC-67, which was isolated originally from the clinical strain CL1 and was later found to be present also in a clinical E. coli isolate from Brazil, is inserted at the same chromosomal site as retron EC-86. Retron EC-67 contains only msd, msr, and ret. I suggest that these two retrons were independently inserted into the same site of their host strains via a novel mechanism of integration.

Retronphage phi R73: an E. coli phage that contains a retroelement and integrates into a tRNA gene

Some strains of Escherichia coli contain retroelements (retrons) that encode genes for reverse transcriptase and branched, multicopy, single-stranded DNA (msDNA) linked to RNA. However, the origin of retrons is unknown. A P4-like cryptic prophage was found that contains a retroelement (retron Ec73) for msDNA-Ec73 in an E. coli clinical strain. The entire genome of this prophage, named phi R73, is 12.7 kilobase pairs and is flanked by 29-base pair direct repeats derived from the 3' end of the selenocystyl transfer RNA gene (selC). P2 bacteriophage caused excision of the phi R73 prophage and acted as a helper to package phi R73 DNA into an infectious virion. The newly formed phi R73 closely resembled P4 as a virion and in its lytic growth. Retronphage phi R73 lysogenized a new host strain, reintegrating its genome into the selC gene of the host chromosome and enabling the newly formed lysogens to produce msDNA-Ec73. Hence, retron Ec73 can be transferred intercellularly as part of the genome of a helper-dependent retronphage.

Retroelements in bacteria

A peculiar type of satellite DNA, called msDNA, has been discovered in myxobacteria and some natural isolates of E. coli. These molecules are characterized by the presence of single-stranded DNA branching out from an internal guanosine residue of an RNA molecule by a unique 2',5'-phosphodiester linkage. Reverse transcriptase is required for the synthesis of msDNA. The discovery of retroelements in bacterial populations raises many intriguing questions concerning the evolutionary origin of reverse transcriptase, the function and the biosynthesis of msDNA, and the nature of the mechanisms generating the extensive diversity found in msDNA and reverse transcriptase genes among different bacterial strains.

msDNA of bacteria

The msDNA-retron element represents the first prokaryotic member of the large and diverse retroelement family found in many eukaryotic genomes (Table II). This prokaryotic retroelement exists as a single copy element in the chromosome of two different bacterial groups: the common soil microbe M. xanthus and the enteric bacterium E. coli. It encodes an RT similar to the polymerases found in retroviruses, containing most of the strictly conserved amino acids found in all RTs. The RT is responsible for the production of an unusual extrachromosomal RNA-DNA molecule known as msDNA. Each composed of a short single strand of RNA and a short single strand of DNA, msDNAs vary considerably in their primary nucleotide sequences, but all share certain secondary structural features, including the unique 2',5' branch linkage that joins the 5' end of the DNA chain to the 2' position of an internal guanosine residue of the RNA strand. It is proposed that msDNA is synthesized by reverse transcription of a precursor RNA transcribed from a region of the retron containing the genes msr (encoding the RNA portion) and msd (encoding the DNA portion) and the ORF (encoding the RT). The precursor RNA transcript folds into a stable secondary structure that serves as both the primer and the template for the synthesis of msDNA. The msDNA-retron elements of E. coli are found in less than 10% of all strains observed, are heterogeneous in nature, and have an atypical aminoacid codon usage for this species, suggesting that this element was transmitted to E. coli by some other source. The presence of directly repeated 26-base-pair sequences flanking the junctions of the Ec67-retron of E. coli also suggests that it may be a mobile element. However, the msDNA-retrons of M. xanthus appear to be as old as other genes native to this species, based on codon-usage data for the RT genes and the fact that every strain of M. xanthus appears to have the same type of msDNA. If the msDNA-retron element originated with the myxobacteria, it would place the existence of retrons before the appearance of eukaryotic cells, suggesting that the bacterial element is perhaps the ancestral gene from which eukaryotic retroviruses and other retroelements evolved.(ABSTRACT TRUNCATED AT 400 WORDS)