tRNA核酸内切酶的研究进展

tRNA在蛋白质合成过程中起着极其重要的作用。在所有的生物体内,tRNA首先以前体形式转录,然后必需经过一系列的加工后才能成为有功能的tRNA分子。tRNaseZ、RNaseP和tRNA剪接内切酶是参与tRNA前体加工的三种主要的核酸内切酶,分别参与tRNA前体3′末端、tRNA前体5′末端和内含子剪接的加工。这三种酶具有不同的结构特征,并且利用完全不同的催化机制水解磷酸二酯键。tRNaseZ和RNaseP都是金属酶,活性中心分别需要Zn^2＋和Mg^2＋的参与;而tRNA剪接内切酶活性中心不需要金属离子,是一个由不同催化亚基上的关键氨基酸残基构成的组合式活性中心。     

PTA1, an essential gene of Saccharomyces cerevisiae affecting pre-tRNA processing.

We have identified an essential Saccharomyces cerevisiae gene, PTA1, that affects pre-tRNA processing. PTA1 was initially defined by a UV-induced mutation, pta1-1, that causes the accumulation of all 10 end-trimmed, intron-containing pre-tRNAs and temperature-sensitive but osmotic-remedial growth. pta1-1 does not appear to be an allele of any other known gene affecting pre-tRNA processing. Extracts prepared from pta1-1 strains had normal pre-tRNA splicing endonuclease activity. pta1-1 was suppressed by the ochre suppressor tRNA gene SUP11, indicating that the pta1-1 mutation creates a termination codon within a protein reading frame. The PTA1 gene was isolated from a genomic library by complementation of the pta1-1 growth defect. Episome-borne PTA1 directs recombination to the pta1-1 locus. PTA1 has been mapped to the left arm of chromosome I near CDC24; the gene was sequenced and could encode a protein of 785 amino acids with a molecular weight of 88,417. No other protein sequences similar to that of the predicted PTA1 gene product have been identified within the EMBL or GenBank data base. Disruption of PTA1 near the carboxy terminus of the putative open reading frame was lethal. Possible functions of the PTA1 gene product are discussed.     

Characterization of the yeast KEX1 gene product: a carboxypeptidase involved in processing secreted precursor proteins.

We have identified and partially characterized the Saccharomyces cerevisiae KEX1 gene product, Kex1p, to assess its role in processing secreted protein precursors. Anti-Kex1p antibodies identified a 113-kilodalton protein that was absent in cells in which the KEX1 gene has been disrupted and that was more abundant in cells overexpressing the KEX1 gene. Kex1p was found to be a membrane-associated glycoprotein with N-linked carbohydrate. The N-linked oligosaccharide(s) was modified in a progressive manner after synthesis, causing the glycoprotein to slowly increase in mass to 115 kilodaltons. After a Kex2p-mediated cleavage event at specific pairs of basic amino acids, alpha-factor and K1 killer toxin precursors have COOH-terminal dibasic residue extensions and require a carboxypeptidase B-like enzyme to process the precursors to maturity. A carboxypeptidase activity, with apparent specificity for basic amino acids, was detected in KEX1 cells. Disruption of the KEX1 gene abolished this activity, while overexpression of KEX1 increased it. Our results provide biochemical evidence consistent with earlier genetic work, that KEX1 encodes a serine carboxypeptidase involved in the processing of precursors to secreted mature proteins.     

Isolation and structure of a yeast initiator tRNAmet gene.

Sixteen bacterial clones containing yeast initiator tRNAmet genes have been isolated. The size of the BamHI fragments encoding these genes ranges from 4,000 to 23,000 base pairs. The nucleotide sequence of one member of this group has been determined. It has no intervening sequences.     

Preferential binding of yeast tRNA ligase to pre-tRNA substrates.

Joining of tRNA halves during splicing in extracts of Saccharomyces cerevisiae requires each of the three enzymatic activities associated with the tRNA ligase polypeptide. Joining is most efficient for tRNA as opposed to oligonucleotide substrates and is sensitive to single base changes at a distance from splice sites suggesting considerable specificity. To examine the basis for this specificity, binding of ligase to labeled RNA substrates was measured by native gel electrophoresis. Ligase bound tRNA halves with an association constant 1600-fold greater than that for a nonspecific RNA. Comparison of binding of a series of tRNA processing intermediates revealed that tRNA-structure, particularly in the region around the splice sites, contributes to specific binding. Finally, the ligase was shown to form multiple, discrete complexes with tRNA substrates. The basis for recognition by ligase and its role in a tRNA processing pathway are discussed.     

A synthetic intron in a naturally intronless yeast pre-tRNA is spliced efficiently in vivo.

Saccharomyces cerevisiae glutamine tRNA(CAG) is encoded by an intronless, single-copy gene, SUP60. We have imposed a requirement for splicing in the biosynthesis of this tRNA by inserting a synthetic intron in the SUP60 gene. Genetic analysis demonstrated that the interrupted gene produces a functional, mature tRNA product in vivo.     

Isolation and PCR amplification of a species-specific oxidoreductase-coding gene region in Listeria grayi

Listeria grayi is a nonpathogenic Gram-positive bacterium that demonstrates considerable similarities to other members in the genus Listeria, including the foodborne human pathogen Listeria monocytogenes and the animal pathogen Listeria ivanovii. A rapid diagnostic test to identify and diagnose listeriosis would be valuable, especially in cases where the presence of L. grayi may complicate diagnosis. This test would be based on a unique gene present in L. grayi. In this study, after comparative screening of a recombinant L. grayi DNA library by dot blot hybridization, an L. grayi specific clone (lgr20-246) with an insert of 722 bp was isolated. By applying PCR primers derived from a distinct region of the clone not shared by other bacteria, a specific band of 420 bp was amplified from the genomic DNA of L. grayi only and not of other Listeria species or common bacteria. These results suggest that the PCR assay employing primers lgr20-246F and lgr20-246R provides an independent and precise means of distinguishing L. grayi from other Listeria species and common bacteria. Therefore, it would be another useful technique for laboratory differentiation of Listeria bacteria.     

Assembly of the mitochondrial membrane system. Characterization of a yeast nuclear gene involved in the processing of the cytochrome b pre-mRNA

The cytochrome b gene of Saccharomyces cerevisiae D273-10B was previously shown to be composed of three exons and two introns (Nobrega, F.G., and Tzagoloff, A. (1980) J. Biol. Chem. 255, 9828-9837). In the present study nuclear respiratory deficient mutants of this strain have been screened for defects in processing of the cytochrome b pre-mRNA. Fifteen independently isolated mutants lacking cytochrome b have been assigned to a single genetic complementation group (G36). Members of this complementation group are blocked in the excision of the second intervening sequence of cytochrome b and consequently are unable to produce the mature mRNA. The wild type gene defined by this class of mutants has been named CBP2. A recombinant plasmid with the CBP2 gene has been selected from a library of wild type nuclear DNA and further subcloned by transformation of a cbp2 mutant to respiratory competency. The smallest plasmid (pG36/T5) capable of complementing cbp2 mutants and of restoring their ability to complete processing of the cytochrome b pre-mRNA has a nuclear DNA fragment of 2.6 kilobase pairs inserted at the BamHI site of the yeast vector YEp13. The sequence of the cloned DNA fragment has revealed an 1890-nucleotide-long reading frame encoding a basic protein with a molecular weight of 74,000. Deletion analysis confirms that the entire reading frame is required for complementation of cbp2 mutants. This reading frame is proposed to code for the CBP2 gene product.     

Differential distribution of factors involved in pre-mRNA processing in the yeast cell nucleus.

The yeast cell nucleus has previously been shown to be divided into two regions by a variety of microscopic approaches. We used antibodies specific for the 2,2,7-trimethylguanosine cap structure of small nuclear ribonucleic acids (snRNAs) and for a protein component of small nuclear ribonucleoprotein particles to identify the distribution of small nuclear ribonucleoprotein particles within the yeast cell nucleus. These studies were performed with the fission yeast Schizosaccharomyces pombe and the budding yeast Saccharomyces cerevisiae. By using immunofluorescence microscopy and immunoelectron microscopy, most of the abundant snRNAs were localized to the portion of the nucleus which has heretofore been referred to as the nucleolus. This distribution of snRNAs is different from that found in mammalian cells and suggests that the nucleolar portion of the yeast nucleus contains functional domains in addition to those associated with RNA polymerase I activity.     

Isolation of yeast tRNALeu genes. DNA sequence of a cloned tRNALeu3 gene.

A library of cloned yeast DNA fragments generated by digestion of yeast DNA with the restriction endonuclease Bam HI has been screened by colony hybridization to total yeast [32P]tRNA. Four hundred colonies carrying yeast tRNA genes were isolated. By hybridization to 125I-tRNALeu3, we have isolated from this collection 14 colonies carrying fragments containing yeast tRNALeu genes. The size of the yeast Bam HI inserts ranged from 2.45 x 10(6) to 14 x 10(6) daltons. One of these fragments was mapped in detail by restriction endonuclease digestion and hybridization to 125I-tRNALeu3. The presence of a tRNALeu3 gene was confirmed by DNA sequence. The results indicate that the tRNALeu3 coding region is not co-linear with the tRNALeu3. An intervening tract of 33 base pairs interrupts the coding sequences 1 base pair past the anticodon coding region. The putative structure of a tRNALeu3 precursor is deduced in which the anticodon base pairs with residues from the intervening sequence.     

Isolation of LUMINIDEPENDENS: a gene involved in the control of flowering time in Arabidopsis.

Plants have evolved the ability to regulate flowering in response to environmental signals such as temperature and photoperiod. The physiology and genetics of floral induction have been studied extensively, but the molecular mechanisms that underlie this process are poorly understood. To study this process, we isolated a gene, LUMINIDEPENDENS (LD), that is involved in the timing of flowering in Arabidopsis. Mutations in this gene render Arabidopsis late flowering and appear to affect light perception. The late-flowering phenotype of the ld mutation was partially suppressed by vernalization. Genomic and cDNA clones of the LD gene were characterized. The predicted amino acid sequence of the LD protein contains 953 residues and includes two putative bipartite nuclear localization signals and a glutamine-rich region.     

A potential membrane protein involved in pre-tRNA splicing of Schizosaccharomyces pombe

We had previously isolated six pre-tRNA splicing mutants of Schizosaccharomyces pombe named ptp1 to ptp6. To investigate the molecular mechanism of tRNA splicing, we cloned the ptp4(+) gene by complementation of the temperature-sensitive growth defect. The ptp4(+) gene consists of three exons and encodes a putative protein of 218 amino acids with a molecular mass of 24.4 kDa. Analysis of the amino acid sequence reveals that the protein is a potential membrane protein with four membrane-spanning regions. The ptp4(+) shows significant similarity to the Saccharomyces cerevisiae putative protein YOR311C. Expression of the ptp4(+) gene in the ptp4(-) mutant restores the ability to splice tRNA. Northern blot analysis showed that the ptp4(+) gene is expressed in both mating-type cells of S. pombe. These results suggest that the Ptp4(+) could be a component involved in tRNA splicing.