Characterization of human MRP/Th RNA and its nuclear gene: full length MRP/Th RNA is an active endoribonuclease when assembled as an RNP.

Vertebrate cells contain a site-specific endoribonuclease (RNase MRP) that cleaves mitochondrial RNA transcribed from the origin of leading-strand mitochondrial DNA replication. This report presents the characterization of the human enzyme and its essential RNA component. Human RNase MRP is a ribonucleoprotein with a nucleus-encoded RNA of 265 nucleotides. As expected, the single-copy RNA coding region is homologous (84%) to the corresponding mouse gene; surprisingly, at least 700 nucleotides of the immediate 5'-flanking region are conserved. The 265-nucleotide MRP RNA and an MRP RNA cleavage product representing the 3'-terminal 108 nucleotides exist in nuclear and mitochondrial RNA isolates; the larger MRP RNA is present in greatest abundance in the nucleus. The putative processing site within the 265-nucleotide MRP RNA is offset from that of mouse MRP RNA, but in each case cleavage is precise and occurs at the sequence ANCCCGC. Oligonucleotide-mediated inhibition experiments reveal that both the 5' and 3' portions of the MRP RNA are involved in cleavage by RNase MRP; this implies that full length MRP RNA complexed with proteins is an active species in vertebrate cells.     

Differential expression of the mouse mitochondrial genes and the mitochondrial RNA-processing endoribonuclease RNA by androgens.

Using subtractive hybridization to identify genes that are androgen regulated in the mouse epididymis, a number of cDNAs were identified that represented mitochondrial genes including cytochrome oxidase c subunits I, II, and III, cytochrome b, NADH dehydrogenase subunit 5, a region of the displacement loop, and the 16S rRNA. Northern blot analysis of RNA from intact, castrate, or testosterone-replaced epididymides confirmed that these mitochondrial mRNAs as well as the rRNA were androgen regulated with a 2- to 5-fold reduction in expression observed after 4 weeks castration with partial to full recovery to precastrate levels upon 4 weeks of testosterone replacement. In contrast to the mitochondrial genes, the expression of the RNA component of the mitochondrial RNA-processing endoribonuclease (RNAase MRP), a nuclear factor which is thought to be involved in the regulation of mitochondrial DNA synthesis, increased in the epididymis upon castration and then returned to precastrate levels after testosterone replacement. An examination of other androgen-responsive tissues showed that mitochondrial gene expression was also regulated by androgens in the kidney. The RNAase MRP RNA levels, however, showed an increase after castration only in the reproductive tissues (epididymis, vas deferens, and seminal vesicle) and not in the kidney. No correlative increase in mitochondrial DNA levels was observed for any of the tissues. Finally, an analysis of various mouse tissues as well as the different regions of the epididymis revealed large differences in mitochondrial mRNA levels. While for most tissues the mRNA levels correlated with the mitochondrial DNA content, the levels of the RNAase MRP RNA did not. Taken together, these findings not only show the large variations in mitochondrial gene expression between tissues but also demonstrate that the expression of mitochondrial genes and ultimately mitochondrial function are androgen regulated in the epididymis and kidney.     

Bovine RNase MRP cleaves the divergent bovine mitochondrial RNA sequence at the displacement-loop region

RNase MRP is a site-specific ribonucleoprotein endoribonuclease that cleaves mitochondrial RNA from the origin of leading-strand DNA synthesis contained within the displacement-loop region. Bovine mitochondrial DNA maintains the typical gene content and order of mammalian mitochondrial DNAs but differs in the nature of sequence conservation within this displacement-loop regulatory region. This markedly different sequence arrangement raises the issue of the degree to which a bovine RNase MRP would reflect the physical and functional properties ascribed to the enzymes previously characterized from mouse and human. We find that bovine RNase MRP exists as a ribonucleoprotein, with an RNA component of 279 nucleotides that is homologous to that of mouse or human RNase MRP RNA. Characterization of the nuclear gene for bovine RNase MRP RNA showed conservation of sequence extending 5 of the RNase MRP RNA coding sequence, including the presence of a cis-acting element known to be important for the expression of some mitochondrial protein-coding nuclear genes. Bovine or mouse RNase MRP cleaves a standard mouse mitochondrial RNA substrate in the same manner; each also cleaves a bovine mitochondrial RNA substrate identically. Since bovine and mouse RNase MRPs process both bovine and mouse substrates, we conclude that the structural features of the mitochondrial RNA substrate required for enzymatic cleavage have been well conserved despite significant overall primary sequence divergence. Inspection of the bovine RNA substrate reveals conservation of only the most critical portion of the primary sequence as indicated by earlier studies with mouse and human RNase MRPs. Interestingly, a principal cleavage site in the bovine mitochondrial RNA substrate is downstream of the promoter located at the leading-strand mitochondrial DNA replication origin. Correspondence to: D.J. Dairaghi     

Insect small nuclear RNA gene promoters evolve rapidly yet retain conserved features involved in determining promoter activity and RNA polymerase specificity

In animals, most small nuclear RNAs (snRNAs) are synthesized by RNA polymerase II (Pol II), but U6 snRNA is synthesized by RNA polymerase III (Pol III). In Drosophila melanogaster, the promoters for the Pol II-transcribed snRNA genes consist of approximately 21 bp PSEA and approximately 8 bp PSEB. U6 genes utilize a PSEA but have a TATA box instead of the PSEB. The PSEAs of the two classes of genes bind the same protein complex, DmSNAPc. However, the PSEAs that recruit Pol II and Pol III differ in sequence at a few nucleotide positions that play an important role in determining RNA polymerase specificity. We have now performed a bioinformatic analysis to examine the conservation and divergence of the snRNA gene promoter elements in other species of insects. The 5' half of the PSEA is well-conserved, but the 3' half is divergent. Moreover, within each species positions exist where the PSEAs of the Pol III-transcribed genes differ from those of the Pol II-transcribed genes. Interestingly, the specific positions vary among species. Nevertheless, we speculate that these nucleotide differences within the 3' half of the PSEA act similarly to induce conformational alterations in DNA-bound SNAPc that result in RNA polymerase specificity.     

Glutamate tRNA genes are adjacent to 5S RNA genes in Drosophila and reveal a conserved upstream sequence (the ACT-TA box).

In Drosophila melanogaster at least six transfer RNA genes are located adjacent to the 3' end of the 5S RNA gene cluster. Three of these have been sequenced and identified as coding for glutamate tRNA4. In the chromosome they are arranged as tandem repeats on the same DNA strand and transcribed in the same direction as is 5S DNA, towards the centromere. We have also identified a sequence, the ACT-TA box, that is highly conserved among the polymerase III transcribed genes. Usually the sequence is located at 37 +/- 8 base pairs upstream from the first nucleotide of the structural gene. A similar sequence is also observed upstream of yeast and silkworm tRNA genes and the mitochondrial tRNA genes of mouse and humans.