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.

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.

Repetitive sequences found in the chromosome of the myxobacterium Nannocystis exedens are similar to msDNA: a possible retrotransposition event in bacteria.

The first reverse transcriptase (RT) to be found in a prokaryotic cell is encoded by an element called a retron which resides in the chromosome of many different bacteria. In addition, all retrons code for a functionally obscure RNA-DNA satellite molecule called msDNA. msDNA is synthesized from an RNA template by the retron-encoded RT. An unusual retron element is described here from the myxobacterium Nannocystis exedens. This retron does not appear to have a typical RT gene in close proximity (1 kb) to the gene msd (which encodes the DNA strand of msDNA). The gene msr (which encodes the RNA strand of msDNA) appears to be duplicated and flanks both sides of the msd gene. Also discovered throughout the chromosome of this bacterium is a set of repeated sequences related to msDNA. These repeat sequences match only part of the sequences of msDNA and may have become incorporated into the chromosome of this bacterium by reverse transcription.

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.

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)

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

Reverse transcriptase required for the synthesis of msDNA.Ec67 in an Escherichia coli strain was purified as a large molecular weight complex with msDNA. The complex sedimented in a glycerol gradient at an s value greater than 19. The predominant protein species co-purifying with reverse transcriptase activity in the complex had a molecular weight estimated at 65,000 which is close to the expected size of 67,227 for the Ec67-reverse transcriptase. In addition, the large complex also contained msDNA.Ec67. The purified complex was able to synthesize cDNA using 5 S rRNA as a template (annealed to a synthetic DNA primer), and a double-stranded DNA using a synthetic DNA template (annealed to a synthetic DNA primer). When msDNA.Ec67 was used as a natural template:primer, the purified complex produced two major products: a 103-base single-stranded DNA by extending the 3' end of msDNA using msdRNA as a template, and a 60-base double-stranded DNA product resulting from the converse reaction in which the 3' end of msdRNA is extended using msDNA as a template. The results suggest that bacterial reverse transcriptase is capable of producing single-stranded cDNA and possibly double-stranded DNA as well. Possible implications of these findings on the biology of the msDNA-retron system are discussed.

Extensive diversity of branched-RNA-linked multicopy single-stranded DNAs in clinical strains of Escherichia coli.

Recently it was shown that a clinical strain of Escherichia coli contains a reverse transcriptase that is essential for the synthesis of a branched-RNA-linked multicopy single-stranded DNA (msDNA). We now have examined 113 independent clinical isolates of E. coli for the existence of msDNA and found that 7 strains contained msDNA. Four of them were further analyzed by hybridization analysis, which indicated that three of the msDNAs were different, having little sequence homology. When the reverse transcriptase gene associated with one of these msDNAs was used as a probe, it did not hybridize with chromosomal DNA from the other strains containing msDNA. These results indicate that some clinical E. coli strains carry their own unique msDNA-synthesizing systems; msDNAs produced by these systems have little, if any, sequence homology in their RNA and DNA molecules and the reverse transcriptases required for the production of msDNA also have little sequence similarity. Such extensive diversity of the msDNA-synthesizing systems supports the notion that they were acquired by the E. coli genome late during the evolution of E. coli.

Reverse transcriptase in a clinical strain of Escherichia coli: production of branched RNA-linked msDNA.

Branched RNA-linked multicopy single-stranded DNA (msDNA) originally detected in myxobacteria has now been found in a clinical isolate of Escherichia coli. Although lacking homology in the primary structure, the E. coli msDNA is similar in secondary structure to the myxobacterial msDNA's, including the 2',5'-phosphodiester linkage between RNA and DNA. A chromosomal DNA fragment responsible for the production of msDNA was cloned in an E. coli K12 strain; its DNA sequence revealed an open reading frame (ORF) of 586 amino acid residues. The ORF shows sequence similarity with retroviral reverse transcriptases and ribonuclease H. Disruption of the ORF blocked msDNA production, indicating that this gene is essential for msDNA synthesis.

Reverse transcriptase with concomitant ribonuclease H activity in the cell-free synthesis of branched RNA-linked msDNA of Myxococcus xanthus.

msDNA is a peculiar molecule consisting of a branched RNA linked to single-stranded DNA via a 2',5' phosphodiester bond. A cell-free system, utilizing cells permeabilized with phenethyl alcohol, was established to study the synthesis of msDNA in M. xanthus. Permeablized cells labeled with [alpha-32P]dCTP in the presence of ddGTP, ddATP, or ddTTP produce a band that migrates at the same position as the full-sized msDNA in an polyacrylamide gel. However, when this band is treated with ribonuclease A prior to gel electrophoresis, it results in many different-sized bands. This indicates that during the labeling, intermediates are produced in which single-stranded DNAs of various lengths are associated with a compensatory length of RNA such that the total length for each intermediate is identical. These results provide evidence for the previously proposed model in which msDNA is synthesized by reverse transcriptase using a folded RNA precursor as a primer as well as a template. Furthermore, we found that there is a precise coupling mechanism of reverse transcriptase and ribonuclease H.

Structure of msDNA from Myxococcus xanthus: evidence for a long, self-annealing RNA precursor for the covalently linked, branched RNA.

The branched RNA (msdRNA) of M. xanthus consists of 77 bases. The 20th rG residue is linked to the 5' end of msDNA, consisting of 162 bases, by a 2', 5' phosphodiester linkage. The msdRNA coding region is located on the chromosome in the opposite orientation to the msDNA coding region, with the 3' ends overlapping by eight bases. S1 nuclease mapping experiments indicate that the primary product of msdRNA is much longer at both the 5' and 3' ends (approximately 375 bases). Because of homologous sequences upstream of the msdRNA and msDNA coding regions, the precursor RNA molecule is considered to form an extremely stable stem-and-loop structure (delta G = -210 kcal). We propose a novel mechanism of DNA synthesis in which the stem-and-loop structure serves as a primer as well as a template to form the branched RNA-linked msDNA.

Novel mechanism for plasmid-mediated erythromycin resistance by pNE24 from Staphylococcus epidermidis.

We describe an unusual type of erythromycin resistance (Emr) mediated by a plasmid designated pNE24 from Staphylococcus epidermidis. This 26.5-kilobase plasmid encodes resistance strictly to 14-membered macrolide antibiotics, erythromycin, and oleandomycin. Resistance to other macrolide-lincosamide-streptogramin B (MLS) antibiotics was not observed even after a prior induction stimulus with various MLS antibiotics. Plasmid pNE24 was found to express resistance constitutively and manifested a low to intermediate MIC (62.5 micrograms/ml) for erythromycin. The resistance gene, designated erpA, appears to mediate resistance by altering the permeability of the host cell for erythromycin, because the measured uptake of 14C-labeled erythromycin by strain 958-2 (containing pNE24) was lower than for the erythromycin-susceptible, isogenic strain 958-1. No inactivation of erythromycin in overnight broth culture supernatants could be detected. In addition, no significant loss in binding affinity between [14C]erythromycin and ribosome could be detected for ribosomes isolated from strain 958-2 relative to 958-1, indicating that pNE24 probably does not produce a modification of the bacterial ribosome. No other selectable marker was found associated with pNE24; however, a 60,000-dalton protein was present only in the membrane fractions of cells (958-2) containing pNE24 and may play a role in mediating resistance to erythromycin.

Nucleotide sequence of the constitutive macrolide-lincosamide-streptogramin B resistance plasmid pNE131 from Staphylococcus epidermidis and homologies with Staphylococcus aureus plasmids pE194 and pSN2.

The complete nucleotide sequence of the Staphylococcus epidermidis plasmid pNE131 is presented. The plasmid is 2,355 base pairs long and contains two major open reading frames. A comparison of the pNE131 DNA sequence with the published DNA sequences of five Staphylococcus aureus plasmids revealed strong regional homologies with two of them, pE194 and pSN2. The region of pNE131 containing the reading frame which encodes the constitutive ermM gene is almost identical to the inducible ermC gene region of pE194, except for a 107-base-pair deletion which removes the mRNA leader sequence required for inducible expression. A second region of pNE131 contains an open reading frame with homology to the small cryptic plasmid pSN2 and potentially encodes a 162-amino-acid protein.

Comparison of epidemiologic markers for Staphylococcus epidermidis.

Cultures of Staphylococcus epidermidis from the eyes or nose of the same individual were compared by their antimicrobial phenotype, Staph-Ident (Analytab Products, Inc., Plainview, N.Y.) profile number, phage type, and plasmid profile to determine which parameters provide the most compelling data for their identity. None of the parameters alone provided this type of information. The most conclusive data for the identity of strains resulted when two cultures had the same long phage type and identical or similar plasmid profiles. The presence of a large, slowly migrating plasmid band(s) in a culture that agreed with its pair in all other parameters and, in all likelihood, was the same strain casts doubt in some instances on the reliability of the plasmid profile alone for strain identification in an epidemiologic study.

Naturally occurring Staphylococcus epidermidis plasmid expressing constitutive macrolide-lincosamide-streptogramin B resistance contains a deleted attenuator.

A naturally occurring constitutive macrolide-lincosamide-streptogramin B (MLS) resistance plasmid, pNE131, from Staphylococcus epidermidis was chosen to study the molecular basis of constitutive expression. Restriction and functional maps of pNE131 are presented along with the nucleotide sequence of ermM, the gene which mediates constitutive MLS resistance. Sharing 98% sequence homology within the 870-base-pair Sau3A-TaqI fragment, ermM appears to be almost identical to ermC, the inducible MLS resistance determinant from S. aureus (pE194). The two genes share nearly identical sequences, except in the 5' promoter region of ermM. Constitutive expression of ermM is due to the deletion of 107 base pairs relative to ermC; the deletion removes critical sequences for attenuation, resulting in constitutive methylase expression.

Characterization of a macrolide, lincosamide, and streptogramin resistance plasmid in Staphylococcus epidermidis.

A strain of Staphylococcus epidermidis was transduced to erythromycin resistance, and all of the transductants exhibited the macrolide, lincosamide, streptogramin B resistance phenotype. Curing and antibiotic disk studies also indicated that these resistances were controlled by a single plasmid determinant and were constitutive. Agarose gel electrophoresis of plasmid deoxyribonucleic acid (DNA) from donor, cured, and transduced strains showed that a single plasmid was responsible. This plasmid, designated pNE131, was examined for sequence homology to two other plasmids, pE194 and p1258, from Staphylococcus aureus, which also code for erythromycin resistance. DNA from plasmids pNE131 and pE194 hybridized with one another, but no extensive homology to pI258 with either pNE131 or pE194 was found. Restriction endonuclease digests of pNE131 and pE194 showed no common fragments. However, sequence homology was localized to the nucleotides in pE194 that code for the 29,000-dalton protein responsible for erythromycin resistance. pNE131 was calculated to have 2,220 base pairs and is the smallest naturally occurring plasmid with a known function yet reported in S. epidermidis.