Structural and functional analyses of Saccharomyces cerevisiae wild-type and mutant RNA1 genes.

The yeast gene RNA1 has been defined by the thermosensitive rna1-1 lesion. This lesion interferes with the processing and production of all major classes of RNA. Each class of RNA is affected at a distinct and presumably unrelated step. Furthermore, RNA does not appear to exit the nucleus. To investigate how the RNA1 gene product can pleiotropically affect disparate processes, we undertook a structural analysis of wild-type and mutant RNA1 genes. The wild-type gene was found to contain a 407-amino-acid open reading frame that encodes a hydrophilic protein. No clue regarding the function of the RNA1 protein was obtained by searching banks for similarity to other known gene products. Surprisingly, the rna1-1 lesion was found to code for two amino acid differences from wild type. We found that neither single-amino-acid change alone resulted in temperature sensitivity. The carboxy-terminal region of the RNA1 open reading frame contains a highly acidic domain extending from amino acids 334 to 400. We generated genomic deletions that removed C-terminal regions of this protein. Deletion of amino acids 397 to 407 did not appear to affect cell growth. Removal of amino acids 359 to 397, a region containing 24 acidic residues, caused temperature-sensitive growth. This allele, rna1-delta 359-397, defines a second conditional lesion of the RNA1 locus. We found that strains possessing the rna1-delta 359-397 allele did not show thermosensitive defects in pre-rRNA or pre-tRNA processing. Removal of amino acids 330 to 407 resulted in loss of viability.     

Increased expression of the bifunctional protein PrlF suppresses overproduction lethality associated with exported beta-galactosidase hybrid proteins in Escherichia coli.

We have cloned and determined the nucleotide sequence of the prlF gene. An open reading frame predicting a 111-amino-acid protein (Mr 12,351) with an acidic carboxy terminus was identified. The DNA sequence preceding this open reading frame revealed a putative promoter and a ribosome-binding site. The nucleotide sequence of the prlF1 mutation revealed a 7-base-pair duplication resulting in a slightly smaller predicted gene product of Mr 12,009 that lacked the acidic carboxy terminus. Maxicell analysis of prlF and prlF1 subclones identified peptides of sizes similar to those predicted by the nucleotide sequences. The prlF sequence was shown to be expressed in vivo by both maxicell analysis and construction of a prlF-lacZ fusion. Two kanamycin resistance insertions within the prlF open reading frame were introduced into the chromosome, replacing the wild-type gene. In contrast to the prlF1 mutation, these insertions had no detectable effect on cell growth or on the beta-galactosidase activity or maltose sensitivity (two sensitive indicators of hybrid protein export) conferred by the lamB-lacZ42-1 gene fusion. Overproduction of the wild-type prlF gene product from a plasmid carrying an active hybrid promoter, however, conferred a prlF1 phenotype. In addition, both the prlF1 mutation and both kanamycin resistance insertions increased the beta-galactosidase activity of a prlF-lacZ fusion. These results suggest that prlF is autoregulated and that overproduction of the prlF gene product increases the export efficiency of beta-galactosidase hybrid proteins from the cytoplasm.     

Cloning and molecular characterization of a novel lectin gene from Pinellia ternata

The full-length cDNA of Pinellia ternata agglutinin (PTA) was cloned from inflorescences using RACE-PCR. Through comparative analysis of PTA gene (pta) and its deduced amino acid sequence with those of other Araceae species, pta was found to encode a precursor lectin with signal peptide and to have extensive homology with those of other Araceae species. PTA was a heterotetrameric mannose-binding lectin with three mannose-binding boxes like lectins from other Araceae and Amaryllidaceae species. Southern blot analysis of the genomic DNA revealed that pta belonged to a low-copy gene family. Northern blot analysis demonstrated that pta constitutively expressed in various plant tissues including root, leaf, stem and inflorescence. The pta cDNA sequence encoding for mature PTA protein was cloned into pET-32a plasmid and the resulting plasmid, pET-32a-PTA containing Trx-PTA fusion protein, was investigated for the expression in E. coli BL21. SDS-PAGE gel analysis showed that the Trx-PTA fusion protein was successfully expressed in E. coli BL21 when induced by IPTG. Artificial diet assay revealed that PTA fusion protein had significant levels of resistance against peach potato aphids when incorporated into artificial diet at 0.1% (w/v). The cloning of the pta gene will enable us to further test its effect in depth on aphids by transferring the gene into crop plants.     

osmY, a new hyperosmotically inducible gene, encodes a periplasmic protein in Escherichia coli.

A new osmotically inducible gene in Escherichia coli, osmY, was induced 8- to 10-fold by hyperosmotic stress and 2- to 3-fold by growth in complex medium. The osmY gene product is a periplasmic protein which migrates with an apparent molecular mass of 22 kDa on sodium dodecyl sulfate-polyacrylamide gels. A genetic fusion to osmY was mapped to 99.3 min on the E. coli chromosome. The gene was cloned and sequenced, and an open reading frame was identified. The open reading frame encoded a precursor protein with a calculated molecular weight of 21,090 and a mature protein of 18,150 following signal peptide cleavage. Sequencing of the periplasmic OsmY protein confirmed the open reading frame and defined the signal peptide cleavage site as Ala-Glu. A mutation caused by the osmY::TnphoA genetic fusion resulted in slightly increased sensitivity to hyperosmotic stress.     

Cloning, mapping, and characterization of the Escherichia coli prc gene, which is involved in C-terminal processing of penicillin-binding protein 3.

The prc gene, which is involved in cleavage of the C-terminal peptide from the precursor form of penicillin-binding protein 3 (PBP 3) of Escherichia coli, was cloned and mapped at 40.4 min on the chromosome. The gene product was identified as a protein of about 80 kDa in maxicell and in vitro systems. Fractionation of the maxicells producing the product suggested that the product was associated with the periplasmic side of the cytoplasmic membrane. This was consistent with the notion that the C-terminal processing of PBP 3 probably occurs outside the cytoplasmic membrane: the processing was found to be dependent on the secY and secA functions, indicating that the prc product or PBP 3 or both share the translocation machinery with other extracytoplasmic proteins. DNA sequencing analysis of the prc gene region identified an open reading frame, with two possible translational starts 6 bp apart from each other, that could code for a product with a calculated molecular weight of 76,667 or 76,432. The prc mutant was sensitive to thermal and osmotic stresses. Southern analysis of the chromosomal DNA of the mutant unexpectedly revealed that the mutation was a deletion of the entire prc gene and thus that the prc gene is conditionally dispensable. The mutation resulted in greatly reduced heat shock response at low osmolarity and in leakage of periplasmic proteins.     

Isolation of a yeast gene involved in species-specific pre-tRNA processing.

To identify genes involved in pre-tRNA processing, we searched for yeast DNA sequences that specifically enhanced the expression of the SUP4(G37) gene. The SUP4(G37) gene possesses a point mutation at position 37 of suppressor tRNA(Tyr). This lesion results in a reduced rate of pre-tRNA splicing and a decreased level of nonsense suppression. A SUP4(G37) strain was transformed with a yeast genomic library, and the transformants were screened for increased suppressor activity. One transformant contained a plasmid that encoded an unessential gene, STP1, that in multiple copies enhanced the suppression of SUP4(G37) and caused increased production of mature SUP4(G37) product. Disruption of the genomic copy of STP1 resulted in a reduced efficiency of SUP4-mediated suppression and the accumulation of pre-tRNAs. Not all intron-containing pre-tRNAs were affected by the stp1-disruption. At least five of the nine families of pre-tRNAs were affected. Two other species, pre-tRNA(Ile) and pre-tRNA(3Leu), were not. We propose that STP1 encodes a tRNA species-specific product that functions as a helper for pre-tRNA splicing. The STP1 product may interact with pre-tRNAs to generate a structure that is efficiently recognized by splicing machinery.     

SEN1, a positive effector of tRNA-splicing endonuclease in Saccharomyces cerevisiae.

The SEN1 gene, which is essential for growth in the yeast Saccharomyces cerevisiae, is required for endonucleolytic cleavage of introns from all 10 families of precursor tRNAs. A mutation in SEN1 conferring temperature-sensitive lethality also causes in vivo accumulation of pre-tRNAs and a deficiency of in vitro endonuclease activity. Biochemical evidence suggests that the gene product may be one of several components of a nuclear-localized splicing complex. We have cloned the SEN1 gene and characterized the SEN1 mRNA, the SEN1 gene product, the temperature-sensitive sen1-1 mutation, and three SEN1 null alleles. The SEN1 gene corresponds to a 6,336-bp open reading frame coding for a 2,112-amino-acid protein (molecular mass, 239 kDa). Using antisera directed against the C-terminal end of SEN1, we detect a protein corresponding to the predicted molecular weight of SEN1. The SEN1 protein contains a leucine zipper motif, consensus elements for nucleoside triphosphate binding, and a potential nuclear localization signal sequence. The carboxy-terminal 1,214 amino acids of the SEN1 protein are essential for growth, whereas the amino-terminal 898 amino acids are dispensable. A sequence of approximately 500 amino acids located in the essential region of SEN1 has significant similarity to the yeast UPF1 gene product, which is involved in mRNA turnover, and the mouse Mov-10 gene product, whose function is unknown. The mutation that creates the temperature-sensitive sen1-1 allele is located within this 500-amino-acid region, and it causes a substitution for an amino acid that is conserved in all three proteins.     

Gene encoding the 37,000-dalton minor sigma factor of Bacillus subtilis RNA polymerase: isolation, nucleotide sequence, chromosomal locus, and cryptic function.

We began an analysis of rpoF, the gene encoding the cryptic, 37,000-dalton minor sigma factor (sigma-37) of Bacillus subtilis RNA polymerase. Using antibody raised against sigma-37 holoenzyme to probe a lambda gt11 expression vector library, we isolated a 901-base-pair EcoRI fragment that expressed the COOH-terminal half of sigma-37 fused to lacZ. We used this fragment as a hybridization probe to isolate the entire rpoF gene and additional flanking sequences. Identity of the cloned gene was confirmed by the size and immunological reaction of its product expressed in Escherichia coli and, after DNA sequencing, by the homology of its predicted product (264 residues; 30,143 daltons) with other sigma factors. The DNA sequence also suggested that rpoF may lie in a gene cluster. Upstream of rpoF was an open reading frame that would encode a protein of 17,992 daltons; this frame overlapped the rpoF-coding sequence by 41 base pairs. Immediately following rpoF was a reading frame that would encode a protein of at least 20,000 daltons; expression of this region may be translationally coupled to that of rpoF. By plasmid integration and PBS1 transduction, we found the chromosomal locus of rpoF linked to ddl and dal at 40 degrees on the B. subtilis map and near no known lesions affecting growth regulation or development. Further, an rpoF null mutation resulting from gene disruption had no effect on cell growth or sporulation in rich medium, suggesting that sigma-37 may partly control a regulon not directly involved in the sporulation process.     

Cloning and characterization of ftsN, an essential cell division gene in Escherichia coli isolated as a multicopy suppressor of ftsA12(Ts).

A new cell division gene, ftsN, was identified in Escherichia coli as a multicopy suppressor of the ftsA12(Ts) mutation. Remarkably, multicopy ftsN suppressed ftsI23(Ts) and to a lesser extent ftsQ1(Ts); however, no suppression of the ftsZ84(Ts) mutation was observed. The suppression of ftsA12(Ts), ftsI23(Ts), and ftsQ1(Ts) suggests that FtsN may interact with these gene products during cell division. The ftsN gene was located at 88.5 min on the E. coli genetic map just downstream of the cytR gene. ftsN was essential for cell division, since expression of a conditional null allele led to filamentation and cell death. DNA sequence analysis of the ftsN gene revealed an open reading frame of 319 codons which would encode a protein of 35,725 Da. The predicted gene product had a hydrophobic sequence near its amino terminus similar to the noncleavable signal sequences found in several other Fts proteins. The presumed extracellular domain was unusual in that it was rich in glutamine residues. A 36-kDa protein that was localized to the membrane fraction was detected in minicells containing plasmids with the ftsN gene, confirming that FtsN was a membrane protein.     

Yeast CAL1 is a structural and functional homologue to the DPR1 (RAM) gene involved in ras processing

A 2.3-kilobase pair DNA fragment of the yeast CAL1 gene was cloned by complementation of the cal1-1 mutation, which causes a defect in nuclear division and bud formation (Ohya, Y., Ohsumi, Y., and Anraku, Y. (1984) Mol. & Gen. Genet. 193, 389-394). Nucleotide sequencing of this fragment revealed a single open reading frame (ORF) encoding a polypeptide of 376 amino acids. Comparative analysis of the predicted amino acid sequence has shown that the CAL1 product has similarity to two yeast proteins: the DPR1 (RAM) gene product that is involved in processing of ras protein at the farnesylation step, and the essential ORF2 protein whose structural gene has a head-to-head arrangement with PRP4, which is involved in mRNA processing. Functional homology between CAL1 and DPR1 has also been suggested from genetic evidence that multiple copies of the CAL1 gene suppress the growth defects of a dpr1 null mutant at high temperature. This suppression is Ca(2+)-dependent, since it was not observed in complete medium containing 200 microM CaCl2 but was apparent in medium containing 100 mM CaCl2. From sequence analysis of the cal1-1 mutation, together with the alignment of the three gene products, we have concluded that the conserved Gly328 in the C terminus is important for activity. We suggest that the CAL1 protein participates in a ras-like C-terminal modification of proteins involved in nuclear division and bud growth.     

一个中国Gilbert综合征家系的遗传学分析

对一个中国汉族Gilbert综合征遗传家系致病基因突变位点进行鉴定,以期了解该病的分子遗传学基础。首先提取先证者基因组DNA,PCR扩增尿苷二磷酸葡萄糖醛酸转移酶UGT1A1基因的5个外显子,以琼脂糖电泳鉴定PCR产物,纯化后直接测序鉴定。基因扫描显示,与血清胆红素水平密切相关的UGT1A1基因在第1和第5外显子存在纯合突变,而 UGT1A1基因启动子区域和内含子/外显子剪接边界位点序列未检测到突变。进一步对其他家系成员该基因的相应位点进行突变检测,结果显示他们在第1和第5外显子也存在杂合突变,其中还有两个成员在启动子区域检测到(TA)插入突变。对家系成员未抗凝新鲜血液进行生化检测证实了基因突变分析的结果。综合以上结果发现该家系三种突变并存,致病因素为第1和/或第5外显子突变,为显性遗传,两种突变位点纯合导致先证者出现严重胆红素代谢功能障碍。该家系因此成为Gilbert综合征突变位点及其致病机理研究的一个典型临床病例。     

A novel protein shared by RNase MRP and RNase P.

We have isolated suppressors of the temperature-sensitive rRNA processing mutation rrp2-2 in Saccharomyces cerevisiae. A class of extragenic suppressors was mapped to the YBR257w reading frame in the right arm of Chromosome II. Characterization of this gene, renamed POP4, shows that the gene product is necessary both for normal 5.8S rRNA processing and for processing of tRNA. Immunoprecipitation studies indicate that Pop4p is associated with both RNase MRP and RNase P. The protein is also required for accumulation of RNA from each of the two ribonucleoprotein particles.     

Cloning and characterization of GNS1: a Saccharomyces cerevisiae gene involved in synthesis of 1,3-beta-glucan in vitro.

The GNS1 gene product is required for the synthesis of 1,3-beta-glucan in vitro, since mutations in this gene result in exhibit an 80 to 90% reduction in 1,3-beta-glucan synthase specific activity. gns1 mutant strains display a pleiotropic phenotype including resistance to a pneumocandin B0 analog (L-733,560), slow growth, and mating and sporulation defects. The gns1-1 mutation was genetically mapped to within 1.35 centimorgans from the MAT locus on chromosome III. The wild-type GNS1 gene was isolated by complementing the pneumocandin resistance phenotype of the gns1-1 mutation and by hybridization with a chromosome III-derived sequence being used as a probe. The nucleotide sequence of GNS1 was determined and compared with the homologous region of the chromosome. The genetic and nucleotide sequence analyzes revealed that GNS1 and the open reading frame, YCR34 [S. Oliver, Q. van der Aart, M. Agostoni-Carbone, and the Chromosome III Sequencing Group, Nature (London) 357:38-46, 1992], represent identical loci in the genome. Cells deleted for GNS1 are viable but exhibit slow growth as well as the pleiotropic phenotype of the gns1 mutants. The putative protein product is predicted to be an integral membrane protein with five transmembrane helices displaying an exoplasmic orientation for the N terminus and a cytoplasmic orientation for the C terminus. This protein may be a subunit of 1,3-beta-glucan synthase.     

The MAK11 protein is essential for cell growth and replication of M double-stranded RNA and is apparently a membrane-associated protein

MAK11 is a gene necessary for the maintenance of killer M1 double-stranded RNA, but not for other cellular double-stranded RNAs (L-A, L-BC, T, W). The DNA sequence of this gene revealed a 1407-base pair open reading frame, which corresponds to a 54-kDa protein. The C-terminal region is lysine-rich and is necessary for mak11-complementing activity. The N-terminal 24 amino acids of the open reading frame include 16 hydrophobic amino acids, 4 basic residues, and 4 neutral amino acids; this sequence could span a membrane. We constructed a MAK11-lacZ fusion that includes the entire MAK11 protein and complements the mak11-1 mutation. The fusion protein was localized in a membrane fraction as shown by centrifugation in Percoll gradients. The fusion protein could be released from the membrane fraction by salt washing. Western blotting of protein, isolated from the membrane fraction and purified by p-aminophenyl-beta-D-thiogalactoside-agarose column chromatography, revealed a fusion protein monomer of 170 kDa which agrees with the predicted molecular weight. While the mak11-1 mutation results in specific loss of M1 double-stranded RNA without any apparent growth defect, replacing a 792-base pair internal EcoRV fragment of MAK11 with the URA3 gene (gene disruption) resulted in a lethal mutation.