Actin and myosin contribute to mammalian mitochondrial DNA maintenance

Mitochondrial DNA maintenance and segregation are dependent on the actin cytoskeleton in budding yeast. We found two cytoskeletal proteins among six proteins tightly associated with rat liver mitochondrial DNA: non-muscle myosin heavy chain IIA and β-actin. In human cells, transient gene silencing of MYH9 (encoding non-muscle myosin heavy chain IIA), or the closely related MYH10 gene (encoding non-muscle myosin heavy chain IIB), altered the topology and increased the copy number of mitochondrial DNA; and the latter effect was enhanced when both genes were targeted simultaneously. In contrast, genetic ablation of non-muscle myosin IIB was associated with a 60% decrease in mitochondrial DNA copy number in mouse embryonic fibroblasts, compared to control cells. Gene silencing of β-actin also affected mitochondrial DNA copy number and organization. Protease-protection experiments and iodixanol gradient analysis suggest some β-actin and non-muscle myosin heavy chain IIA reside within human mitochondria and confirm that they are associated with mitochondrial DNA. Collectively, these results strongly implicate the actomyosin cytoskeleton in mammalian mitochondrial DNA maintenance.

Sorting of mannose 6-phosphate receptors mediated by the GGAs

The delivery of soluble hydrolases to lysosomes is mediated by the cation-independent and cation-dependent mannose 6-phosphate receptors. The cytosolic tails of both receptors contain acidic-cluster-dileucine signals that direct sorting from the trans-Golgi network to the endosomal-lysosomal system. We found that these signals bind to the VHS domain of the Golgi-localized, gamma-ear-containing, ARF-binding proteins (GGAs). The receptors and the GGAs left the trans-Golgi network on the same tubulo-vesicular carriers. A dominant-negative GGA mutant blocked exit of the receptors from the trans-Golgi network. Thus, the GGAs appear to mediate sorting of the mannose 6-phosphate receptors at the trans-Golgi network.

Signal-binding specificity of the mu4 subunit of the adaptor protein complex AP-4

The medium (mu) chains of the adaptor protein (AP) complexes AP-1, AP-2, and AP-3 recognize distinct subsets of tyrosine-based (YXXphi) sorting signals found within the cytoplasmic domains of integral membrane proteins. Here, we describe the signal-binding specificity and affinity of the medium subunit mu4 of the recently described adaptor protein complex AP-4. To elucidate the determinants of specificity, we screened a two-hybrid combinatorial peptide library using mu4 as a selector protein. Statistical analyses of the results revealed that mu4 prefers aspartic acid at position Y+1, proline or arginine at Y+2, and phenylalanine at Y-1 and Y+3 (phi). In addition, we examined the interaction of mu4 with naturally occurring YXXphi signals by both two-hybrid and in vitro binding analyses. These experiments showed that mu4 recognized the tyrosine signal from the human lysosomal protein LAMP-2, HTGYEQF. Using surface plasmon resonance measurements, we determined the apparent dissociation constant for the mu4-YXXphi interaction to be in the micromolar range. To gain insight into a possible role of AP-4 in intracellular trafficking, we constructed a Tac chimera bearing a mu4-specific YXXphi signal. This chimera was targeted to the endosomal-lysosomal system without being internalized from the plasma membrane.

HIV-1 reverse transcriptase interaction with model RNA-DNA duplexes

HIV-1 reverse transcriptase (HIV-1 RT) is a multifunctional enzyme responsible for converting viral RNA into preintegrative DNA during the early stages of viral infection. DNA polymerase and RNase H activities are required, and several conformationally distinct primer-templates must be accommodated by the enzyme during the process. Parameters of interaction between model substrates (ligands) and HIV-1 RT (wild type p66/p51 and the RNase H-deficient mutant p66(E478Q)/p51) (analytes) were estimated by surface plasmon resonance at 25 degrees C, pH 8.0. Binding of RT to the ligands is specific and can be analyzed using a conventional 1:1 binding algorithm. RNA-DNA hybrids with 5'-template overhangs of 6 and 12 nucleotides bind to RT approximately one order of magnitude stronger than the corresponding 36-mer with blunt ends due to slower dissociation. Immobilization of the latter through either the 5'-end of RNA or DNA strand does not change the equilibrium constant (K(D)) for wild-type RT but the values of kinetic constants of association and dissociation differ significantly. For the p66(E478Q)/p51 enzyme, orientation effects are notable even altering the K(D) value. Binding of the p66(E478Q)/p51 to any RNA-DNA hybrids is slightly stronger compared with wild type. Data can be interpreted in terms of the mechanism of reverse transcription.

The absence of ribonuclease H1 or H2 alters the sensitivity of Saccharomyces cerevisiae to hydroxyurea, caffeine and ethyl methanesulphonate: implications for roles of RNases H in DNA replication and repair

BACKGROUND

RNA of RNA-DNA hybrids can be degraded by ribonucleases H present in all organisms including the eukaryote Saccharomyces cerevisiae. Determination of the number and roles of the RNases H in eukaryotes is quite feasible in S. cerevisiae.

RESULTS

Two S. cerevisiae RNases H, related to Escherichia coli RNase HI and HII, are not required for growth under normal conditions, yet, compared with wild-type cells, a double-deletion strain has an increased sensitivity to hydroxyurea (HU) and is hypersensitive to caffeine and ethyl methanesulphonate (EMS). In the absence of RNase H1, RNase H2 activity increases, and cells are sensitive to EMS but not HU and are more tolerant of caffeine; the latter requires RNase H2 activity. Cells missing only RNase H2 exhibit increased sensitive to HU and EMS but not caffeine

CONCLUSIONS

Mutant phenotypes infer that some RNA-DNA hybrids are recognized by both RNases H1 and H2, while other hybrids appear to be recognized only by RNase H2. Undegraded RNA-DNA hybrids have an effect when DNA synthesis is impaired, DNA damage occurs or the cell cycle is perturbed by exposure to caffeine suggesting a role in DNA replication/repair that can be either beneficial or detrimental to cell viability.

Isolation of RNase H genes that are essential for growth of Bacillus subtilis 168

Two genes encoding functional RNase H (EC 3.1.26.4) were isolated from a gram-positive bacterium, Bacillus subtilis 168. Two DNA clones exhibiting RNase H activities both in vivo and in vitro were obtained from a B. subtilis DNA library. One (28.2 kDa) revealed high similarity to Escherichia coli RNase HII, encoded by the rnhB gene. The other (33.9 kDa) was designated rnhC and encodes B. subtilis RNase HIII. The B. subtilis genome has an rnhA homologue, the product of which has not yet shown RNase H activity. Analyses of all three B. subtilis genes revealed that rnhB and rnhC cannot be simultaneously inactivated. This observation indicated that in B. subtilis both the rnhB and rnhC products are involved in certain essential cellular processes that are different from those suggested by E. coli rnh mutation studies. Sequence conservation between the rnhB and rnhC genes implies that both originated from a single ancestral RNase H gene. The roles of bacterial RNase H may be indicated by the single rnhC homologue in the small genome of Mycoplasma species.

Identification of the genes encoding Mn2+-dependent RNase HII and Mg2+-dependent RNase HIII from Bacillus subtilis: classification of RNases H into three families

Database searches indicated that the genome of Bacillus subtilis contains three different genes encoding RNase H homologues. The ypdQ gene encodes an RNase HI homologue with 132 amino acid residues, whereas the rnh and ysgB genes encode RNase HII homologues with 255 and 313 amino acid residues, respectively. RNases HI and HII show no significant sequence similarity. These genes were individually expressed in Escherichia coli; the recombinant proteins were purified, and their enzymatic properties were compared with those of E. coli RNases HI and HII. We found that the ypdQ gene product showed no RNase H activity. The 2.2 kb pair genomic DNA containing this gene did not suppress the RNase H deficiency of an E. coli rnhA mutant, indicating that this gene product shows no RNase H activity in vivo as well. In contrast, the rnh (rnhB) gene product (RNase HII) showed a preference for Mn2+, as did E. coli RNase HII, whereas the ysgB (rnhC) gene product (RNase HIII) exhibited a Mg2+-dependent RNase H activity. Oligomeric substrates digested with these enzymes indicate similar recognition of these substrates by B. subtilis and E. coli RNases HII. Likewise, B. subtilis RNase HIII and E. coli RNase HI have generated similar products. These results suggest that B. subtilis RNases HII and HIII may be functionally similar to E. coli RNases HII and HI, respectively. We propose that Mn2+-dependent RNase HII is universally present in various organisms and Mg2+-dependent RNase HIII, which may have evolved from RNase HII, functions as a substitute for RNase HI.

Cloning, expression, and mapping of ribonucleases H of human and mouse related to bacterial RNase HI

We identified two human sequences and one mouse sequence in the database of expressed sequence tags that are highly homologous to the N-terminal sequence of eukaryotic RNases H1. The cDNAs for human RNASEH1 and mouse Rnaseh1 were obtained, their nucleotide sequences determined, and the proteins expressed in Escherichia coli and partially purified. Both proteins have RNase H activity in vitro and they bind to dsRNA and RNA-DNA hybrids through the N-terminal conserved motif present in eukaryotic RNases H1. The RNASEH1 gene is expressed in all human tissues at similar levels, indicating that RNase H1 may be a housekeeping protein. The human RNASEH1 and mouse Rnaseh1 cDNAs were used to isolate BAC genomic clones that were used as probes for fluorescence in situ hybridization. The human gene was localized to chromosome 17p11.2 and the mouse gene to a nonsyntenic region on chromosome 12A3. The chromosomal location and possible disease association of the human RNASEH1 gene are discussed.

A common 40 amino acid motif in eukaryotic RNases H1 and caulimovirus ORF VI proteins binds to duplex RNAs

Eukaryotic RNases H from Saccharomyces cerevisiae , Schizosaccharomyces pombe and Crithidia fasciculata , unlike the related Escherichia coli RNase HI, contain a non-RNase H domain with a common motif. Previously we showed that S.cerevisiae RNase H1 binds to duplex RNAs (either RNA-DNA hybrids or double-stranded RNA) through a region related to the double-stranded RNA binding motif. A very similar amino acid sequence is present in caulimovirus ORF VI proteins. The hallmark of the RNase H/caulimovirus nucleic acid binding motif is a stretch of 40 amino acids with 11 highly conserved residues, seven of which are aromatic. Point mutations, insertions and deletions indicated that integrity of the motif is important for binding. However, additional amino acids are required because a minimal peptide containing the motif was disordered in solution and failed to bind to duplex RNAs, whereas a longer protein bound well. Schizosaccharomyces pombe RNase H1 also bound to duplex RNAs, as did proteins in which the S.cerevisiae RNase H1 binding motif was replaced by either the C.fasciculata or by the cauliflower mosaic virus ORF VI sequence. The similarity between the RNase H and the caulimovirus domain suggest a common interaction with duplex RNAs of these two different groups of proteins.

Ribonuclease H renaturation gel assay using a fluorescent-labeled substrate

Ribonucleases H (RNases H) are enzymes that specifically degrade the RNA of RNA-DNA hybrids. These enzymes are involved in DNA replication, reverse transcription (RT) and antisense oligodeoxyribonucleotide-mediated arrest of translation. One of the most valuable tools for assaying RNase H activity is the renaturation gel assay with which such activities can be detected using purified protein preparations or crude extracts. Radioactive substrates [32P labeled poly(rA)-poly(dT) hybrid] are commonly used with exposure of the gel to X-ray film; this is possible at any time without disturbing the renaturation-degradation process. Here, we describe a method using fluorescent-labeled substrates. RNA-DNA substrates are synthesized by first transcribing DNA with T7 RNA polymerase using Bodipy-TR-14-UTP and the four normal nucleoside triphosphates. The run-off transcript is annealed to a short oligomeric DNA complementary to the 3'-end of the transcript, and the DNA portion of the hybrid is formed by RT. This RNA-DNA is added to the polyacrylamide mixture before polymerization, and SDS-PAGE is performed as usual. After various periods of renaturation, the gel is scanned to detect fluorescent substrate using the red-excited laser of a fluorescence scanner. This fluorescence method has all of the advantages of using radio-labeled substrates and none of its disadvantages, and the sensitivities of the two methods are comparable. In addition, we show that the sensitivity of this procedure can be increased if damaging chemicals remaining in the gel after polymerization are eliminated by simultaneous electrophoresis of the RNase H and a protein with higher mobility.

Kinetic and stoichiometric analysis for the binding of Escherichia coli ribonuclease HI to RNA-DNA hybrids using surface plasmon resonance

To understand how ribonucleases H recognize RNA-DNA hybrid substrates, we analyzed kinetic parameters of binding of Escherichia coli RNase HI to RNA-DNA hybrids ranging in length from 18 to 36 base pairs (bp) using surface plasmon resonance (BIAcoreTM). The kon and koff values for the binding of the enzyme to the 36-bp substrate were 1.5 x 10(6) M-1 s-1 and 3.2 x 10(-2) s-1, respectively. Similar values were obtained with the shorter substrates. Using uncleavable 2'-O-methylated RNA-DNA substrates, values for kon and koff were 2.1 x 10(5) M-1 s-1 and 1.3 x 10(-1) s-1 in the absence of Mg2+ that were further reduced in the presence of Mg2+ to 7.4 x 10(3) M-1 s-1 and 2.6 x 10(-2) s-1. Kinetic parameters similar to the wild-type enzyme were obtained using an active-site mutant enzyme, Asp134 replaced by Ala, whereas a greatly reduced on-rate was observed for another inactive mutant enzyme, in which the basic protrusion is eliminated, thereby distinguishing between poor catalysis and inability to bind to the substrate. Stoichiometric analyses of RNase HI binding to substrates of 18, 24, 30, and 36 bp are consistent with previous reports suggesting that RNase HI binds to 9-10 bp of RNA-DNA hybrid.

The isolated RNase H domain of murine leukemia virus reverse transcriptase. Retention of activity with concomitant loss of specificity

Retroviral RNases H are similar in sequence and structure to Escherichia coli RNase HI and yet have differences in substrate specificities, metal ion requirements, and specific activities. Separation of reverse transcriptase (RT) into polymerase and RNase H domains yields an active RNase H from murine leukemia virus (MuLV) but an inactive human immunodeficiency virus (HIV) RNase H. The "handle region" present in E. coli RNase HI but absent in HIV RNase H contributes to the binding to its substrate and when inserted into HIV RNase H results in an active enzyme retaining some degree of specificity. Here, we show MuLV protein containing the C-terminal 175 amino acids with its own handle region or that of E. coli RNase HI has the same specific activity as the RNase H of RT, retains a preference for Mn2+ as the cation required for activity, and has association rate (KA) 10% that of E. coli RNase HI. However, with model substrates, specificities for removal of the tRNAPro primer and polypurine tract stability are lost, indicating specificity of RNase H of MuLV requires the remainder of the RT. Differences in KA, while significant, appear insufficient to account for the differences in specific activities of the bacterial and viral RNases H.

Antiretroviral effect of a gag-RNase HI fusion gene

We have previously shown that a molecule consisting of a fusion of a Ca(2+)-dependent nuclease (from Staphylococcus aureus) to a retroviral coat protein specifies a potent antiviral specific for that retrovirus. Genes specifying such fusion proteins can be delivered to virus-susceptible cells, providing an antiviral gene therapy aimed at limiting virus spread. We report here the results of experiments to vary the nuclease moiety of such fusion proteins. We found that one nuclease. Serratia marcescens nuclease, was extremely toxic to host cells and hence not likely to be useful for therapeutic purposes. A second nuclease, Escherichia coli RNase Hl was found to be nontoxic and highly effective against a murine leukemia virus when it was fused to the leukemia virus coat protein. The fusion protein was enzymatically active and stably expressed, without apparent toxicity to host cells. Reduction in infectious virus output was as high as 97-99%. These studies provide a model system for the development of gene therapeutic agents aimed at combating retroviral infections in vivo.

Escherichia coli RNase HI inhibits murine leukaemia virus reverse transcription in vitro and yeast retrotransposon Ty1 transposition in vivo

BACKGROUND

Reverse transcription, which converts an RNA genome into double-stranded DNA, requires both the polymerase and RNase H activities of reverse transcriptase (RT). In vitro, poorly processive RT dissociates from partially copied RNA-DNA hybrids, that are usually extended by a second RT molecule. Despite similar structures, RNase HI of Escherichia coli can degrade RNA-DNA hybrids that are resistant to RNase H of RT. E. coli RNase HI is used to determine the accessibility to and requirement for RNA-DNA hybrids in reverse transcription in vivo and in vitro.

RESULTS

In the presence of E. coli RNase HI, reverse transcription yields incomplete cDNA molecules due to degradation of RNA-DNA hybrids. Delivery of E. coli RNase HI to Ty1 particles via fusion to the capsid protein can reduce retrotransposition by more than 99%, also indicating inhibition of DNA synthesis in vivo.

CONCLUSION

Inhibition of both reverse transcription in vitro and retrotransposition in vivo by E. coli RNase HI indicates that the poor processivity of RT exposes RNA-DNA hybrids critical for reverse transcription to degradation. Targeting a cellular RNase H to HIV may help define the site(s) of RNA-DNA hybrids that are susceptible to nonretroviral RNase H and may be useful for gene therapy to inhibit retroviral replication.

Cloning, sequence analysis, overproduction in Escherichia coli and enzymatic characterization of the RNase HI from Mycobacterium smegmatis

Activity gel analysis of cell extracts from slow- and fast-growing mycobacteria confirmed the presence of several RNase H activities in both classes of organism. The rnhA gene from Mycobacterium smegmatis (Ms) was subsequently cloned using an internal gene segment probe [Mizrahi et al., Gene 136 (1993) 287-290]. The gene encodes a polypeptide of 159 amino acids that shares 50% identity with the RNase HI from Escherichia coli (Ec). However, unlike its counterparts from Gram- bacteria, Ms rnhA does not form an overlapping divergent transcriptional unit with dnaQ (encoding the epsilon (proofreading) subunit of DNA polymerase III). Ms RNase HI was overproduced in Ec as an enzymatically active maltose-binding protein (MBP) fusion protein which cleaved the RNA strand of an RNA.DNA hybrid with a similar site selectivity to that of its Ec homologue.

The non-RNase H domain of Saccharomyces cerevisiae RNase H1 binds double-stranded RNA: magnesium modulates the switch between double-stranded RNA binding and RNase H activity

Eukaryotic ribonucleases H of known sequence are composed of an RNase H domain similar in size and sequence to that of Escherichia coli RNase HI and additional domains of unknown function. The RNase H1 of Saccharomyces cerevisiae has such an RNase H domain at its C-terminus. Here we show that the N-terminal non-RNase H portion of the yeast RNase H1 binds tightly to double-stranded RNA (dsRNA) and RNA-DNA hybrids even in the absence of the RNase H domain. Two copies of a sequence with limited similarity to the dsRNA-binding motif are present in this N-terminus. When the first of these sequences is altered, the protein no longer binds tightly to dsRNA and exhibits an increase in RNase H activity. Unlike other dsRNA-binding proteins, increasing the Mg2+ concentration from 0.5 mM to 5 mM inhibits binding of RNase H1 to dsRNA; yet a protein missing the RNase H domain binds strongly to dsRNA even at the higher Mg2+ concentration. These results suggest that binding to dsRNA and RNase H activity are mutually exclusive, and the Mg2+ concentration is critical for switching between the activities. Changes in the Mg2+ concentration or proteolytic severing of the dsRNA-binding domain could alter the activity or location of the RNase H and may govern access of the enzyme to the substrate. Sequences similar to the dsRNA-binding motif are present in other eukaryotic RNases H and the transactivating protein of cauliflower mosaic virus, suggesting that these proteins may also bind to dsRNA.

Defects in primer-template binding, processive DNA synthesis, and RNase H activity associated with chimeric reverse transcriptases having the murine leukemia virus polymerase domain joined to Escherichia coli RNase H

The RNase H domain of murine leukemia virus (MuLV) reverse transcriptase (RT) was replaced with Escherichia coli RNase H, and the effect on RNase H activity and processive DNA synthesis was studied, using RNA-DNA hybrids containing sequences from the MuLV polypurine tract (PPT). Two chimeric RTs, having the entire polymerase domain or all but the last 19 amino acids, were expressed. In both cases, these RTs made multiple cuts in PPT-containing substrates, whereas wild-type cleavages occurred primarily at sites consistent with the distance between the polymerase and RNase H active sites. Primer extension assays performed with the chimeric RTs, an RNase H-minus RT, and wild-type showed that the presence of a wild-type viral RNase H domain facilitates processive DNA synthesis. When wild-type RT was bound to primer-template, two retarded bands could be detected in band-shift assays. In the absence of primer extension, a high proportion of enzyme-bound primer-template was associated with the faster-migrating band, whereas with DNA synthesis, more of the bound radioactivity was in the super-shifted complex. This suggests that the super-shifted complex contains the active form of RT. The mutant RTs were deficient in formation of this complex, but the chimeric RTs were somewhat less defective than the RNase H-minus mutant. Our results demonstrate that in the wild-type enzyme, the RNase H domain is required to stabilize the interaction between RT and primer-template.

Overexpression of RNase H partially complements the growth defect of an Escherichia coli delta topA mutant: R-loop formation is a major problem in the absence of DNA topoisomerase I

Previous biochemical studies have suggested a role for bacterial DNA topoisomerase (TOPO) I in the suppression of R-loop formation during transcription. In this report, we present several pieces of genetic evidence to support a model in which R-loop formation is dynamically regulated during transcription by activities of multiple DNA TOPOs and RNase H. In addition, our results suggest that events leading to the serious growth problems in the absence of DNA TOPO I are linked to R-loop formation. We show that the overexpression of RNase H, an enzyme that degrades the RNA moiety of an R loop, can partially compensate for the absence of DNA TOPO I. We also note that a defect in DNA gyrase can correct several phenotypes associated with a mutation in the rnhA gene, which encodes the major RNase H activity. In addition, we found that a combination of topA and rnhA mutations is lethal.

Construction of an enzymatically active ribonuclease H domain of human immunodeficiency virus type 1 reverse transcriptase

The isolated ribonuclease (RNase) H domain of human immunodeficiency virus type 1 (HIV-1) is enzymatically inactive. The incorporation of the putative substrate binding site of Escherichia coli RNase HI (amino acid residues 76-102, the alpha c-helix and adjacent loop region) into the equivalent position of the RNase H domain of HIV-1 resulted in a highly active hybrid protein dependent on Mn2+. Similar restoration of RNase H activity has been observed when histidine residues are added to either the N- or C-terminus of the HIV-1 RNase H domain. The hybrid HIV-1/E. coli RNase H protein is approximately 10-fold more active than HIV-1 reverse transcriptase and 30-fold more active than the histidine-tagged proteins, indicating that the alpha c-helix and adjacent loop region of E. coli RNase HI is an excellent substrate binding region because of its sequence and/or location. The RNase H hybrid produced the same specific cleavage in the model tRNA(Lys3) primer removal assay as HIV-1 reverse transcriptase, showing that substrate binding and specificity are separable and that the specificity determinants are at least partially, if not totally, contained in the amino acid sequence of the hybrid protein derived from HIV-1 reverse transcriptase.

A large deletion in the connection subdomain of murine leukemia virus reverse transcriptase or replacement of the RNase H domain with Escherichia coli RNase H results in altered polymerase and RNase H activities

The functional relationship between the polymerase and RNase H domains of reverse transcriptase (RT) was investigated by studying the activities of AKR murine leukemia virus (MuLV) enzymes. In addition to the wild type, an RNase H-minus RT missing the entire RNase H domain and two other mutants having abnormal polymerase:RNase H ratios were expressed. These mutants include (i) a chimeric protein in which the MuLV RNase H domain was replaced by the entire Escherichia coli RNase H sequence and (ii) an RT with a 126 amino acid deletion in a region analogous to the "connection" subdomain in the p66 subunit of human immunodeficiency virus type 1 RT (Kohlstaedt, L. A., Wang, J., Friedman, J. M., Rice, P. A., & Steitz, T. A. (1992) Science 256, 1783-1790). With the wild-type RT, the major RNase H cleavage reaction was coordinated with DNA synthesis and occurred at a position corresponding to 15 nucleotides from the 3'-terminus of the DNA primer. Additional cleavages closer to the 5'-end of the RNA were explained in terms of a model relating binding of the RNA.DNA hybrid substrate and enzyme structure. The chimeric RT behaved like E. coli RNase H, exhibited 300-fold higher RNase H activity than wild-type RT, and was limited in its ability to synthesize DNA. Qualitative and quantitative changes in the polymerase and RNase H activities of the deletion mutant were also observed. The RNase H domain appeared to function independently of the polymerase domain, supporting the idea that the proper spatial relationship between the two active centers was disrupted by the mutation. Taken together, our results indicate that alteration of the normal polymerase:RNase H ratio can have profound effects on both polymerase and RNase H cleavage activities, as expected for an enzyme with two interdependent domains.

Analysis of mutagenesis induced by expression of retroviral reverse transcriptase in Escherichia coli

We showed that expression of reverse transcriptase from HIV or MuLV resulted in exceptionally high levels of mutagenesis in E coli. We observed high rates of mutagenesis in plasmid genes when reverse transcriptase was expressed off that plasmid. Although very high rates were observed in cis, our experiments could not detect mutagenic events in markers in other replicons (ie in trans). These results suggest mutagenic events occur preferentially on the same replicon in which the reverse transcriptase is encoded.

Proteolysis of Saccharomyces cerevisiae RNase H1 in E coli

Expression of S cerevisiae RNase H1 in E coli leads to the formation of a proteolytic product with a molecular mass of 30 kDa that is derived from the 39-kDa full length protein. The 30-kDa form retains RNase H1 activity, as determined by renaturation gel assay. The amount of proteolysis observed depends on the procedure used in preparing the cell extracts for protein analysis. The cleavage site on the amino acid sequence of the 39-kDa RNase H1 was determined by N-terminal sequence analysis of the 30-kDa proteolytic form. The cut occurs between two arginines located at the amino terminus region of the protein. The pattern of proteolysis was examined for both the wild-type RNase H1 and a mutant RNase H1 that was constructed in this work. In the mutant the second arginine of the cleavage site was changed to a lysine. Comparisons of the expression of the wild-type and altered protein in two different E coli strains demonstrate that the protease responsible for the degradation has a specificity very similar to that of the OmpT protease. However, the proteolysis observed in an OmpT background in extracts, prepared by boiling the cells in SDS containing buffer, indicates that the protease may, unlike OH108.

Correlation of activity with phenotypes of Escherichia coli partial function mutants of rnh, the gene encoding RNase H

The rnh gene of Escherichia coli encodes RNase H. rnh mutants display at least two phenotypes: (1) they require functional RecBCD enzyme for growth; thus rnh-339::cat recB270 (Ts) and rnh-339::cat recC271 (Ts) strains are temperature sensitive for growth; (2) rnh mutants permit replication that is independent of the chromosomal origin, presumably by failing to remove RNA-DNA hybrids from which extra-original replication can be primed. We report here that manifestation of these two phenotypes occurs at different levels of RNase H function; we have examined partially functional rnh mutants for their in vitro RNase H activity, their ability to rescue viability in recB or recC cells and their ability to permit growth of mutants incapable of using oriC [dnaA (Ts)].

A combination of RNase H (rnh) and recBCD or sbcB mutations in Escherichia coli K12 adversely affects growth

Colony forming ability of Escherichia coli strains carrying the rnh-339::cat mutant allele is strongly dependent on the recBCD and sbcB genes. A mutation inactivating either the RecBCD nuclease or exonuclease I (sbcB) is sufficient to restrict severely the efficiency of plating of strains carrying the rnh-339::cat mutation. Combining a non-lethal temperature-sensitive mutation in the RecBCD nuclease, recB270 (Ts) or recC271 (Ts), with rnh-339::cat renders strains temperature sensitive for growth, even though rnh+ strains with the recB270 (Ts) or recC271 (Ts) alleles are viable at 42 degrees C. The recombinational functions of the RecBCD nuclease can be excluded as the source of lethality on the basis of the following observations. Introduction of a recombination proficient, exonuclease defective recD1009 allele or production of the phage lambda GamS protein (an inhibitor of the RecBCD exonuclease activity) in an rnh-339::cat strain dramatically delays or impairs the ability of such strains to form colonies. Restoration of recombination proficiency by inclusion of an sbcB15 mutation with recB21 recC22 mutations does not restore the ability of the rnh-339::cat mutant strains to plate normally. A recBCD+ strain bearing the rnh-339::cat and sbcB15 mutations forms very few visible colonies after 24 h but forms colonies at normal frequencies after 48 h of incubation. Finally, plating efficiencies of strains are unaffected when the RecBCD recombination pathway is inactivated by introduction of recA56 into an rnh-339::cat strain. These results imply that the defective growth of rnh-339::cat recBCD strains is due to a defect in repair and not recombination mediated by either the RecBCD or the RecF pathway.

Selective cloning of genes encoding RNase H from Salmonella typhimurium, Saccharomyces cerevisiae and Escherichia coli rnh mutant

We have cloned genes encoding RNase H from Escherichia coli rnh mutants, Salmonella typhimurium and Saccharomyces cerevisiae. Selection was accomplished by suppression of the temperature-sensitive growth phenotype of Escherichia coli strains containing the rnh-339::cat and either recB270 (Ts) or recC271 (Ts) mutations. RNases H from E. coli and S. typhimurium contained 155 amino acid residues and differed at only 11 positions. The S. cerevisiae and E. coli RNases H were about 30% homologous. A comparison of the amino acid sequences of several RNases H from cellular and retroviral sources revealed some strongly conserved regions as well as variable regions; the carboxyl-terminus was particularly variable. The overlapping, divergent promoter gene organization found in E. coli was observed to be present in S. typhimurium.

Structure of ribonuclease H phased at 2 A resolution by MAD analysis of the selenomethionyl protein

Ribonuclease H digests the RNA strand of duplex RNA.DNA hybrids into oligonucleotides. This activity is indispensable for retroviral infection and is involved in bacterial replication. The ribonuclease H from Escherichia coli is homologous with the retroviral proteins. The crystal structure of the E. coli enzyme reveals a distinctive alpha-beta tertiary fold. Analysis of the molecular model implicates a carboxyl triad in the catalytic mechanism and suggests a likely mode for the binding of RNA.DNA substrates. The structure was determined by the method of multiwavelength anomalous diffraction (MAD) with the use of synchrotron data from a crystal of the recombinant selenomethionyl protein.

Ribonuclease H: from discovery to 3D structure

Ribonucleases H (RNases H) from Escherichia coli and retroviruses share common features at the primary amino acid sequence and activity levels. RNase H is involved in selection of the origins of replication in E. coli and in DNA synthesis of the positive strand of retroviruses. Crystallographic studies of E. coli RNase H indicate that several amino acids, conserved in both cellular and retroviral RNases H, form an active site for hydrolysis of the RNA of RNA-DNA hybrids. Multiple forms of RNase H are present in both prokaryotes and eukaryotes. It is suggested that these RNases H may be part of larger polypeptides and, as has been shown for reverse transcriptase RNase H derived from retroviruses, that the location and/or activity of the RNase H may be influenced by other regions of the polypeptides.

Expression, purification, and crystallization of natural and selenomethionyl recombinant ribonuclease H from Escherichia coli

Ribonuclease H (RNase H) from Escherichia coli is an endonuclease that specifically degrades the RNAs of RNA:DNA hybrids. The enzyme is a single polypeptide chain of 155 amino acid residues, of which 4 are methionines. To solve the crystallographic three-dimensional structure of E. coli RNase H by the multi-wavelength anomalous diffraction technique, we have constructed methionine auxotrophic strains of E. coli that overexpress selenomethionyl RNase H. MIC88 yields about 10 mg of selenomethionyl RNase H per liter of culture, which is comparable to the overexpression of the natural recombinant protein. We have purified both proteins to homogeneity and crystallized them isomorphously in the presence of sulfate. These are Type I crystals of space group P2(1)2(1)2(1) with the cell parameters a = 41.8 A, b = 86.4 A, c = 36.4 A, one monomer per asymmetric unit, and approximately 36% (v/v) solvent. Crystals of both proteins diffract to beyond 2-A Bragg spacings and are relatively durable in an x-ray beam. On replacement of sulfate with NaCl, crystals of natural RNase H grow as Type I' (very similar to Type I) at pH between 7.0 and 8.0; at pH 8.8, crystals of Type II are obtained in space group P2(1)2(1)2(1) with a = 44.3 A, b = 87.3 A, and c = 35.7 A. Type II crystals can be converted to Type I by soaking in phosphate buffer. RNase H crystals of Type II have also been reported by Kanaya et al. (Kanaya, S., Kohara, A., Miyakawa, M., Matsuzaki, T., Morikawa, K., and Ikehara, M. (1989) J. Biol. Chem. 264, 11546-11549).

Intrinsic properties of reverse transcriptase in reverse transcription. Associated RNase H is essentially regarded as an endonuclease

The intrinsic properties of reverse transcriptase in reverse transcription were studied using a synthetic, partial ovalbumin mRNA with a synthetic DNA oligonucleotide annealed to the 3'-end of the RNA as a model substrate. With or without concomitant cDNA synthesis, the RNase H activity of avian myeloblastosis virus (AMV)-reverse transcriptase cleaved the substrate at a site which would leave a hybrid of between 7 and 14 base pairs between the 3' termini of the RNA and DNA oligonucleotide. Variability in the exact size of the hybrid probably reflects some weak base preference for cleavage by the enzyme. These short hybrids can be recognized as substrates by Escherichia coli RNase H and can be utilized by reverse transcriptase as sites for continuation of cDNA synthesis. Substrates with 5'-triphosphorylated termini, 3'-OH, 3'-phosphate, 3'-end hairpin structures and 20 base pair hybrids on the middle region of long RNA more than 300 bases or on circular RNA were all cleaved by AMV-reverse transcriptase-associated RNase H, indicating that the RNase H activity is essentially regarded as an endonuclease degrading RNA moiety in RNA-DNA hybrid. The modes of action of reverse transcriptase from murine leukemia virus and Rous-associated virus 2 were the same as that of AMV-reverse transcriptase, except that the size of the remaining hybrid and the specificity for cleavage depended on the reverse transcriptase. We propose a possible model to explain the mode of action of RNase H and RNA-dependent DNA polymerase activities in reverse transcription.

Functional organization of the murine leukemia virus reverse transcriptase: characterization of a bacterially expressed AKR DNA polymerase deficient in RNase H activity

The functional organization of the murine leukemia virus reverse transcriptase was investigated by expressing a molecular clone containing AKR MuLV reverse transcriptase-coding sequences in Escherichia coli. A purified preparation of the expressed enzyme (pRT250 reverse transcriptase) consisted primarily of a 69-kilodalton protein that has normal levels of murine leukemia virus polymerase activity but 10-fold-reduced levels of RNase H compared with the viral enzyme. The deficit in RNase H activity was correlated with the absence of 60 to 65 amino acids normally present at the carboxyl end of murine leukemia virus reverse transcriptase. The results provide additional experimental evidence for the localization of polymerase and RNase H domains to the N- and C-terminal regions of reverse transcriptase, respectively.

Amplified RNase H activity in Escherichia coli B/r increases sensitivity to ultraviolet radiation

Strains of E. coli B/r transformed with the plasmid pSK760 were found to be sensitized to inactivation by ultraviolet radiation (UV) and to have elevated levels of RNase H activity. Strains transformed with the carrier vector pBR322 or the plasmid pSK762C derived from pSK760 but with an inactivated rnh gene were not sensitized. UV-inactivation data for strains having known defects in DNA repair and transformed with pSK760 suggested an interference by RNase H of postreplication repair: uvrA cells were strongly sensitized, wild-type and uvrA recF cells were moderately sensitized and recA cells were not sensitized; and minimal medium recovery was no longer apparent in sensitized uvrA cells. Biochemical studies showed that post-UV DNA synthesis was sensitized and that the smaller amounts of DNA synthesized after irradiation, while of normal reduced size as indicated by sedimentation position in alkaline sucrose gradients, did not shift to a larger size (more rapidly sedimenting) upon additional incubation. We suggest an excess level of RNase H interferes with reinitiation of DNA synthesis on damaged templates to disturb the normal pattern of daughter strand gaps and thereby to inhibit postreplication repair.

DNA Colony Hybridization Method Using Synthetic Oligonucleotides to Detect Enterotoxigenic Escherichia coli: Collaborative Study

The genes that encode several of the enterotoxins produced by Escherichia coli have been cloned by recombinant DNA techniques. When the nucleotide sequence of these genes is determined, defined sequence oligonucleotides that include a part of these genes may be synthesized. A 22-base DNA hybridization probe was produced for each of 2 heatstable E. coli enterotoxin (ST) genes: STH, from strains originally isolated from humans; and STP, from strains first found in pigs. For this study, 32P end-labeled DNA probes, sonicated calf thymus DNA, and 3 known and 20 unknown (10 ST-positive and 10 ST-negative) strains were sent to each of 23 collaborators. Cultures were spotted onto an agar-based medium and grown into colonies, which were transferred by blotting to cellulose filters, lysed by alkali and steam, and used for DNA colony hybridization with the ST DNA probes. Strains containing an ST gene were recognized as dark spots on an autoradiogram. Of the 460 samples analyzed, 440 (95.7%) were correctly classified by the collaborators. The method has been adopted official first action.

Neurospora crassa ribosomal DNA: sequence of internal transcribed spacer and comparison with N. intermedia and N. sitophila

Using [32P]DNA probes from a clone containing 17S, 5.8S and 26S rRNA of Neurospora crassa, the remainder of the repeat unit (RU) for ribosomal DNA (rDNA) has been cloned. Combining restriction analysis of the cloned DNA and restriction digests of genomic DNA, the RU was found to be 8.7 kb. The nucleotide sequence was determined for the internal transcribed spacer (ITS) regions one and two, for 5.8S rRNA and for portions of 17S and 26S rRNAs immediately flanking the ITS regions, and compared to the corresponding region of Saccharomyces carlsbergensis. In addition, a comparative restriction analysis of two other Neurospora species was performed using twelve restriction endonucleases. Genomic DNA blots of rDNA from N. intermedia and N. sitophila revealed rDNA RUs of 8.4 kb. The majority of differences in restriction patterns were confined to sequences outside the mature rRNA regions. However, one SmaI recognition site was found in 26S rRNA of N. crassa and N. sitophila but not in N. intermedia.

Genetic methods for the detection of microbial pathogens. Identification of enterotoxigenic Escherichia coli by DNA colony hybridization: collaborative study

Enteropathogenic Escherichia coli strains may produce a cholera-like, heat-labile enterotoxin (LT) as a virulence factor. The gene that codes for LT can be purified by recombinant DNA techniques and used as a genetic probe for DNA hybridization. These probes detect enterotoxigenic strains as well as strains that may not manifest toxin production but carry the genetic information to do so. In this study, 13 laboratories tested 3 known and 25 unknown (10 positive and 15 negative) cultures of E. coli for the presence of the LT gene. The isolates had been tested and classified by the mouse Y-1 adrenal cell test and an enzyme-linked immunosorbent assay. Cultures were spotted on nitrocellulose filters on MacConkey agar and incubated. Colonies were lysed in situ and their DNA was hybridized to 32P-labeled, purified LT gene DNA (provided to the collaborators). Positive colonies were identified by autoradiography. Of 325 samples, 315 (96.9%) were identified correctly and 10 were misclassified; there were 6 false negative and 4 false positive identifications. Chi-square values indicated that the method agreed with the previous classification and was equally efficient in distinguishing positive and negative samples (95.7 and 98.1%, respectively). The method has been adopted official first action.

Genetic Methods for the Detection of Microbial Pathogens. Identification of Enterotoxigenic Escherichia coli by DNA Colony Hybridization: Collaborative Study

Enteropathogenic Escherichia coli strains may produce a cholera-like, heat-labile enterotoxin (LT) as a virulence factor. The gene that codes for LT can be purified by recombinant DNA techniques and used as a genetic probe for DNA hybridization. These probes detect enterotoxigenic strains as well as strains that may not manifest toxin production but carry the genetic information to do so. In this study, 13 laboratories tested 3 known and 25 unknown (10 positive and 15 negative) cultures off. coli for the presence of the LT gene. The isolates had been tested and classified by the mouse Y-l adrenal cell test and an enzyme-linked immunosorbent assay. Cultures were spotted on nitrocellulose filters on MacConkey agar and incubated. Colonies were lysed in situ and their DNA was hybridized to 32P-labeled, purified LT gene DNA (provided to the collaborators). Positive colonies were identified by autoradiography. Of 325 samples, 315 (96.9%) were identified correctly and 10 were misclassified; there were 6 false negative and 4 false positive identifications. Chi-square values indicated that the method agreed with the previous classification and was equally efficient in distinguishing positive and negative samples (95.7 and 98.1%, respectively). The method has been adopted official first action.

The rnh gene is essential for growth of Escherichia coli

We have determined that a functional gene coding for ribonuclease H seems to be essential for cell growth in Escherichia coli. A strain was made with two copies of the rnh gene by lysogenizing an E. coli strain with a lambda phage bearing a copy of the rnh gene. Inactivation of one of the two copies of the rnh gene was accomplished by transformation with a linear DNA molecule that had the gene for chloramphenicol acetyltransferase inserted near the middle of the rnh gene. In recombinants that had an inactive gene replacing the normal chromosomal rnh gene, the lambda rnh prophage supplies an intact functional copy of the rnh gene. Curing the cells of the lambda rnh prophage left the cell with an inactive rnh gene and resulted in cell death. An intact functional rnh gene provided on a plasmid permits normal curing, and cured survivors were readily obtained. The technique described is probably generally applicable for assessing the requirement for other E. coli genes.

A model for the involvement of the small nucleolar RNA (U3) in processing eukaryotic ribosomal RNA

The nucleotide sequence of chick pre-rRNA between 5.8S and 28S rRNAs is 85% G + C and has the potential to form many different secondary structures. A model is presented in which a small nucleolar RNA, U3, and its associated proteins act as an RNA isomerase to position the pre-rRNA for processing. Cleavage could be performed either by a nuclease present in the U3RNP or by a ribonuclease directed to the proper form of the pre-rRNA.

Low levels of RNase H activity in Escherichia coli FB2 rnh result from a single-base change in the structural gene of RNase H

The DNA coding for RNase H from a mutant strain of Escherichia coli (FB2) was cloned into plasmid pBR322. DNA sequence analysis and the exchange of a portion of the mutant and wild-type genes revealed that a single-base alteration (C-->T) in the coding region of the structural gene for RNase H is responsible for the difference in RNase H activity of the wild-type and mutant cells.

DNA sequence of the gene coding for Escherichia coli ribonuclease H

The gene for Escherichia coli ribonuclease H has been studied by use of a plasmid which contains a segment of the E. coli chromosome. The genomic DNA was subcloned from pLC28-22 to pBR322 by use of various restriction enzymes. Such subcloning limited the RNase H gene to a piece of DNA no longer than 760 base pairs. Cells bearing plasmids containing the RNase H gene produce as much as 10-15 times the normal amount of RNase H without any drastic effect on maintenance of the plasmid or cell growth. DNA sequence analysis has permitted the prediction of a protein whose molecular weight is 17,559 (155 amino acid residues). The predicted sequence was confirmed by amino acid analysis, NH2-terminal amino acid sequence, and size determination of highly purified RNase H.

Selective inhibition of RNase H by dextran

Ordinarily, ribonuclease H hydrolyzes poly(rA) . poly(dT) and phiX174DNA-RNA at equal rates. Here we show that in the presence of dextran, the degradation of poly(rA) . poly(dT) is inhibited, while that of phi 174DNA-RNA is not. A similar inhibition by sucrose is found to be due to trace contamination of dextran in the sucrose. Ribose, deoxyribose, and a number of other saccharides fail to inhibit RNase H. In experiments where the two substrates are presented in the presence of the inhibitor, the kinetics indicates that both molecules are recognized by the enzyme, but only the phi X174DNA-RNA is degraded. That is, dextran does not interfere with the recognition site, but rather blocks hydrolysis. It is proposed that the ability of dextran to confer selectivity toward different substrates reveals a potential regulatory mechanism for RNase H activity which may represent a control step in the initiation of DNA synthesis.

Isolation and mapping of a mutation in Escherichia coli with altered levels of ribonuclease H

A mutant of Escherichia coli with altered levels of ribonuclease (RNase) H was isolated after mutagenesis with ethyl methane sulfonate. A procedure for assaying RNase H in partially purified extracts was used to screen approximately 1,500 colonies for variations in RNase H activity. Confirmation of a lower level of RNase H in the mutant was accomplished by analysis of RNase H in sodium dodecyl sulfate-polyacrylamide gels. By Hfr, F', and P1 transduction mapping, the genetic locus responsible for the lower levels of RNase H was located at 5.1 min on the E. coli chromosome. This mutation (rnh) represents a new locus on the E. coli chromosome. The only phenotypic characteristic of this mutation which has been observed to date is the lower level of RNase H (30% of parental values).

Localisation of an endonuclease specific for double-stranded RNA within the nucleolus and its implication in processing ribosomal transcripts

Nucleoli of both chick embryos and mouse Ehrlich ascites cells contain an enzymatic activity that is very similar to RNase DII, an enzyme isolated from total chick embryos for its ability to degrade double-stranded RNA. The enzyme can be extracted by low salt/EDTA from nucleoli and is associated with pre-ribosomal 80-S and 55-S particles. Under ionic conditions which are inhibitory for the nucleolytic activity the transcript in vitro of nucleoli is not processed and sediments around 45 S. Under salt conditions which are optimal for the nucleolar enzyme the nucleolar transcripts are cleaved to distinct intermediate-sized molecules. Addition of the chicken RNase DII or RNase III to the nucleolar transcription system results in a similar shift of the chain length of the RNA molecules. It is concluded that a nucleolar RNase recognizing double-stranded regions in the pre-ribosomal RNA is involved in the maturation of ribosomal RNA.