Isolation and characterization of a second RNase H (RNase HII) of Escherichia coli K-12 encoded by the rnhB gene.

An additional RNase H (EC 3.1.26.4), RNase HII, has been isolated from Escherichia coli K-12. By screening a library of E. coli DNA for clones that suppressed RNase H deficiency of an E. coli rnh mutant, a clone was obtained that produced a protein with RNase H activity. The overexpressed RNase HIII protein in E. coli was purified to near homogeneity and exhibited a strong preference for the ribonucleotide moiety of RNA-DNA hybrid as substrate. The terminal 11 amino acids were determined and were identical to those predicted from the nucleotide sequence. The rnhB gene, which encodes RNase HII, was distinct from rnhA by its map position (4.5 min on E. coli genetic map, between lpxB and dnaE) and by the lack of significant amino acid sequence similarity. The presence of a second RNase H in E. coli indicates that multiple RNase H genes per genome is a general feature of a general feature of a wide variety of organisms.     

Site-specific excision from RNA by RNase H and mixed-phosphate-backbone oligodeoxynucleotides.

Oligodeoxynucleotides containing phosphodiester or modified internucleoside linkages were investigated with respect to their ability to be acted on by ribonuclease H activities present in a HeLa cell nuclear extract after hybridization with complementary sequences in RNA. Oligodeoxynucleotides complementary to nucleotides 2-14 of human U1 small nuclear RNA were investigated. Extensive cleavage of U1 RNA was observed with the unmodified oligodeoxynucleotide and with the phosphorothioate analogue but not with U1-complementary oligodeoxynucleotides containing methylphosphonate, phosphoro-N-morpholidate, or phosphoro-N-butylamidate internucleoside linkages. Additional experiments using a 514-nucleotide-long RNA substrate demonstrated the capacity of complementary phosphodiester- and phosphorothioate-linked oligodeoxynucleotides (but not ones containing methylphosphonate, phosphoro-N-morpholidate, or phosphoro-N-butylamidate linkages) to serve as RNase H targets when hybridized to an internal RNA site. Detailed comparisons revealed phosphodiester-linked oligodeoxynucleotides to be more efficient than the comparable phosphorothioate-linked oligomers with respect to RNase H action. Various pentadecamer oligodeoxynucleotides complementary to the 514-nucleotide-long test RNA and containing 2-6 consecutive phosphodiester- or phosphorothioate-linked nucleotides flanked by RNase H-resistant methylphosphonate linkages afforded precise "site-directed" RNase H excision within the DNA.RNA hybrid. These results serve to assort modified oligodeoxynucleotide-containing hybrids into RNase H-sensitive and -resistant classes and also provide clues as to how RNase H makes contact with the DNA strand in a DNA.RNA hybrid.     

Excision of misincorporated ribonucleotides in DNA by RNase H (type 2) and FEN-1 in cell-free extracts

Misincorporated ribonucleotides in DNA will cause DNA backbone distortion and may be targeted by DNA repair enzymes. Using double-stranded oligonucleotide probes containing a single ribose, we demonstrate a robust activity in human, yeast, and Escherichia coli cell-free extracts that nicks 5' of the ribose. The human and yeast extracts also make a subsequent cut 3' of the ribonucleotide releasing a ribonucleotide monophosphate. The resulting 1-nt gap is an ideal substrate for polymerase and ligase to complete a proposed repair sequence that effectively replaces the ribose with deoxyribose. Screening of yeast deletion mutant cells reveals that the initial nick is made by RNase H(35), a RNase H type 2 enzyme, and the second cut is made by Rad27p, the yeast homologue of human FEN-1 protein. RNase H type 2 enzymes are present in all kingdoms of life and are evolutionarily well conserved. We knocked out the corresponding rnhb gene in E. coli and show that extracts from this strain lack the nicking activity. Conversely, a highly purified archaeal RNase HII type 2 protein has a pronounced activity. To study substrate specificity, extracts were made from a yeast double mutant lacking the other main RNase H enzymes [RNase H1 and RNase H(70)], while maintaining RNase H(35). It was found that a single ribose is preferred as substrate over a stretch of riboses, further strengthening a proposed role of this enzyme in the repair of misincorporated ribonucleotides rather than (or in addition to) processing RNADNA hybrid molecules.     

How does RNase H recognize a DNA.RNA hybrid?

The mechanism of RNase H substrate recognition is proposed from a model of a chemically modified DNA.RNA hybrid Escherichia coli RNase H complex. Site-directed mutagenesis of the enzyme and substrate titration observed by heteronuclear two-dimensional NMR spectra have been carried out. A model complex has been built, based on free structures of the enzyme and the substrate independently determined by x-ray crystallography and NMR distance geometry, respectively. In addition to steric and electrostatic complementarities between the molecular surfaces of the enzyme and the minor groove of the hybrid in the model, putative hydrogen bonds between the polar groups in the enzyme and 2'-oxygens of the RNA strand of the hybrid fix the hybrid close to the active site of the enzyme. The enzymatic activities of the mutant proteins and the changes in NMR spectra during the course of substrate titration are consistent with the present model. Moreover, the specific cleavage of the RNA strand in DNA.RNA hybrids can be explained as well as cleavage modes in modified heteroduplexes. A mechanism of enzymatic action is proposed.     

Discovery of a minimal form of RNase P in Pyrobaculum

RNase P RNA is an ancient, nearly universal feature of life. As part of the ribonucleoprotein RNase P complex, the RNA component catalyzes essential removal of 5' leaders in pre-tRNAs. In 2004, Li and Altman computationally identified the RNase P RNA gene in all but three sequenced microbes: Nanoarchaeum equitans, Pyrobaculum aerophilum, and Aquifex aeolicus (all hyperthermophiles) [Li Y, Altman S (2004) RNA 10:1533-1540]. A recent study concluded that N. equitans does not have or require RNase P activity because it lacks 5' tRNA leaders. The "missing" RNase P RNAs in the other two species is perplexing given evidence or predictions that tRNAs are trimmed in both, prompting speculation that they may have developed novel alternatives to 5' pre-tRNA processing. Using comparative genomics and improved computational methods, we have now identified a radically minimized form of the RNase P RNA in five Pyrobaculum species and the related crenarchaea Caldivirga maquilingensis and Vulcanisaeta distributa, all retaining a conventional catalytic domain, but lacking a recognizable specificity domain. We confirmed 5' tRNA processing activity by high-throughput RNA sequencing and in vitro biochemical assays. The Pyrobaculum and Caldivirga RNase P RNAs are the smallest naturally occurring form yet discovered to function as trans-acting precursor tRNA-processing ribozymes. Loss of the specificity domain in these RNAs suggests altered substrate specificity and could be a useful model for finding other potential roles of RNase P. This study illustrates an effective combination of next-generation RNA sequencing, computational genomics, and biochemistry to identify a divergent, formerly undetectable variant of an essential noncoding RNA gene.