Sequence Analysis of 203 Kilobases from Saccharomyces cerevisiae Chromosome VII

The nucleotide sequences of five major regions from chromosome VII of Saccharomyces cerevisiae have been determined and analysed. These regions represent 203 kilobases corresponding to approximately one-fifth of the complete yeast chromosome VII. Two fragments originate from the left arm of this chromosome. The first one of about 15·8 kb starts approximately 75 kb from the left telomere and is bordered by the SKI8 chromosomal marker. The second fragment covers the 72·6 kb region between the chromosomal markers CYH2 and ALG2. On the right chromosomal arm three regions, a 70·6 kb region between the MSB2 and the KSS1 chromosomal markers and two smaller regions dominated by the KRE11 marker and another one in the vicinity of the SER2 marker were sequenced. We found a total of 114 open reading frames (ORFs), 13 of which were completely overlapping with larger ORFs running in the opposite direction. A total of 44 yeast genes, the physiological functions of which are known, could be precisely mapped on this chromosome. Of the remaining 57 ORFs, 26 shared sequence homologies with known genes, among which were 13 other S. cerevisiae genes and five genes from other organisms. No homology with any sequence in the databases could be found for 31 ORFs. Furthermore, five Ty elements were found, one of which may not be functional due to a frame shift in its Ty1B amino acid sequence. The five chromosomal regions harboured five potential ARS elements and one sigma element together with eight tRNA genes and two snRNAs, one of which is encoded by an intron of a protein-coding gene. © 1997 by John Wiley & Sons, Ltd.     

A single-copy suppressor of the Saccharomyces cerevisae late-mitotic mutants cdc15 and dbf2 is encoded by the Candida albicans CDC14 gene.

The Saccharomyces cerevisiae CDC15, DBF2, TEM1 and CDC14 genes encode regulatory proteins that play a crucial role in the latest stages of the M phase of the cell cycle. By complementation of a S. cerevisiae cdc15-lyt1 mutant with a Candida albicans centromeric-based genomic library, we have isolated a homologue of the protein phosphatase-encoding gene CDC14. The sequence analysis of the C. albicans CDC14 gene reveals a putative open reading frame of 1626 base pairs interrupted by an intron located close to the 5' region. Analysis of C. albicans cDNA proved that the intron is processed in vivo. The CaCDC14 gene shares 49% of amino acid sequence identity with the S. cerevisiae CDC14 gene, 46% with Schizosaccharomyces pombe homologue, 35% with Caenorhabditis elegans and 37% and 38% with human CDC14A and CDC14B genes, respectively. As expected, the C. albicans CDC14 gene complemented a S. cerevisiae cdc14-1 mutant. We found that this gene was able to efficiently suppress not only a S.cerevisiae cdc15-lyt1 mutant but also a dbf2-2 mutant in a low number of copies and allowed growth, although very slightly, of a tem1 deletant. Overexpression of the human CDC14A and CDC14B genes complemented, although very poorly, S. cerevisiae cdc15-lyt1 and dbf2-2 mutants, suggesting a conserved function of these genes throughout phylogeny. The sequence of CaCDC14 was deposited in the EMBL database under Accession No. AJ243449.     

黑芥ANS基因的克隆和在芸薹属B基因组的PCR鉴别

利用同源克隆方法克隆黑芥ANS基因,获得2个ANS基因拷贝BnANS1和BnANS2,长度分别为1 366bp和1 367bp.这2个基因都有1个76bp的内含子.比较BnAⅣS1和BnANS2基因序列,发现在编码区、5＇与3＇非编码区和内含子区域都有多态性,5＇非编码区有3个碱基的多态性和4个碱基的缺失,编码区有26个碱基的多态性;内含子有2个碱基的多态性;3＇非编码区有18个碱基的多态性和3个碱基的插入.这2个ANS拷贝都编码356个氨基酸的蛋白,具有其他物种同样的ANS蛋白保守结构域,属于2OG-Fe（Ⅱ）加氧酶超家族.BnANS1编码的蛋白质理论分子量为40 448.58Da,等电点为5.05;BnANS2编码的蛋白质理论分子量为40 468.52Da,等电点为5.04.比较这2个ANS基因拷贝编码的蛋白质序列,发现有9个多态性位点.这2个ANS拷贝在黑芥的种皮和胚中均检测到表达.获得了1对ANS引物,能从白菜、黑芥、甘蓝、芥菜型油菜、甘蓝型油菜和埃塞俄比亚芥中,用等位特异PCR方法特异识别来自芸薹属B基因组的ANS基因.     

Sequence,map position and genome organization of the RPL17B gene,encoding ribosomal protein L17b in Saccharomyces cerevisiae

Sequence analysis of the newly defined SSU81 gene revealed an adjacent open reading frame (ORF) encoding a protein whose deduced amino acid sequence is identical to that of ribosomal protein L17. The DNA sequence of this region is different from that of the RPL17A gene and therefore represents a duplicate gene encoding L17. We have designated this gene RPL17B. The RPL17B coding region is split by an intron that occurs in the same position (codons 14/15) as the intron in RPL17A. The RPL17B promoter region includes two TATA boxes, a canonical UAS_RPG motif, and several pyrimidine-rich tracts. RPL17B was mapped by CHEF and lambda clone grid hybridization blots to the right arm of chromosome V, linked to the TRP2 and RAD51 genes. A partial ORF was identified adjacent to RPL17B and SSU81 that is homologous to an ORF (designated A509) physically linked to RPL17A. This observation, and the identical position of the introns within the RPL17 genes, suggest that one RPL17 locus arose by duplication and translocation of the other. The complete 3·8 kbp DNA sequence encompassing RPL17B has been entered in the GenBank data library under Accession Number U15653.     

Three Major Nucleotide Polymorphisms in the Waxy Gene Correlated with the Amounts of Extra-long Chains of Amylopectin in Rice Cultivars with S or L-type Amylopectin

Extra-long chains (ELC) of amylopectin in rice endosperm are synthesized by granule-bound starch synthase I encoded by the Waxy (Wx) gene, which primarily synthesizes amylose. Previous studies showed that single nucleotide polymorphisms (SNP) in intron 1 and exon 6 of the Wx gene influences ELC amount. However, whether these SNPs are conserved among rice cultivars and if any other SNPs are present in the Wx gene remained unknown. Here, we sequenced the Wx gene from 17 rice cultivars with S or L-type amylopectin, including those with known ELC content and those originating in China with unique starch properties, as well as typical japonica and indica cultivars. In addition to the two SNPs described above, an additional SNP correlating with ELC content was found in exon 10. Low ELC cultivars (<3.0 %) had thymine at the splicing donor site of intron 1, Tyr224 in exon 6, and Pro415 in exon 10. Cultivars with moderate ELC content (4.1–6.9 %) had guanine at the splicing donor site of intron 1, Ser224 in exon 6, and Pro415 in exon 10. Cultivars with high ELC content (7.7–13.9 %) had guanine at the splicing donor site of intron 1, Tyr224 in exon 6, and Ser415 in exon 10. The chain length distribution pattern of amylopectin was correlated with the amounts of SSIIa found in starch granules and gelatinization temperature, but not with ELC content. The combinations of SNPs in the Wx gene found in this study may provide useful information for screening specific cultivars with different ELC content.     

Analysis of a 26 756 bp segment from the left arm of yeast chromosome IV

The nucleotide sequence of a 26·7 kb DNA segment from the left arm of Saccharomyces cerevisiae chromosome IV is presented. An analysis of this segment revealed 11 open reading frames (ORFs) longer than 300 bp and one split gene. These ORFs include the genes encoding the large subunit of RNA polymerase II, the biotin apo-protein ligase, an ADP-ribosylation factor (ARF 2), the ‘L35’-ribosomal protein, a rho GDP dissociation factor, and the sequence encoding the protein phosphatase 2A. Further sequence analysis revealed a short ORF encoding the ribosomal protein YL41B, an intron in a 5′ untranslated region and an extended homology with another cosmid (X83276) located on the same chromosome. The potential biological relevance of these findings is discussed. The sequence was submitted to the EMBL database under Accession Number X96876.     

Cloning the genomic sequence and identification of promoter regions of bovine pyruvate carboxylase

Pyruvate carboxylase (PC) catalyzes a pivotal reaction in gluconeogenesis and lipid metabolism in liver. In bovine the PC gene is expressed as six 5′ untranslated region (UTR) mRNA variants. The objectives for this study were to clone and sequence the bovine PC gene, determine the intron and exon organization and identify PC promoter region(s). Oligonucleotide sequences that corresponded to the 5′ UTR mRNA variants and coding sequence of bovine PC were used to isolate 2 clones from the RPCI-42 bovine bacterial artificial chromosome (BAC) library. Sequencing data confirmed the presence of regions for the 5′ UTR for bovine PC mRNA. The exon arrangement from 5′ to 3′ is 48 (exon I), 41 (exon II), 178 (exon IIIA and IIIB), and 185 (exon IV) bp. Three promoter regions, P3, P2, and P1, adjacent to exon I, II, and IIIA, respectively, were identified based on computer analysis of sequence data. Putative promoters were cloned into a firefly luciferase vector and transiently transfected into H4IIE rat hepatoma cells. All PC promoters demonstrated luciferase activity comparable with the minimal promoter luciferase vector and higher than the promoterless luciferase vector. In addition, PC promoter 1 exhibited greater luciferase activity compared with PC promoter 2 or 3. These data provide information about the arrangement of the 4 bovine PC 5′ UTR exons, the identity of the promoter regions for the bovine PC gene, and indicate differences in relative basal activity of the promoter regions.     

The mei3 region of the Schizosaccharomyces pombe genome

Expression of the mei3 gene is sufficient to induce meiosis in the fission yeast Schizosaccharomyces pombe. The mei3 gene is located 0.64 Mb from the telomere of the left arm of Sz. pombe chromosome II. We have sequenced and analysed 107 kb of DNA from the mei3 genomic region. The sequence includes 14 known genes (bag1-B, csh3, dps1, gpt1, mei3, mfm3, pac1, prp31, rpl38-1, rpn3, rti1, spa1, spm1 and ubc4) and 26 other open reading frames (ORFs) longer than 100 codons: a density of one protein-coding gene per 2.7 kb. Twenty-one of the 40 ORFs (53%) have introns. In addition there is one lone Tf1 transposon long terminal repeat (LTR), tRNA(Trp) and tRNA(Ser) genes and a 5S rRNA gene. 14 of the novel ORFs show sequence similarities which suggest functions of their products, including a coatomer alpha-subunit, a catechol O-methyltransferase, protein kinase, asparagine synthetase, zinc metalloprotease, acetyltransferase, phosphatidylinositol 4-kinase, inositol polyphosphate phosphatase, GTPase-activating protein, permease, pre-mRNA splicing factor, 20S proteasome component and a thioredoxin-like protein. One predicted protein has similarity to the human Cockayne syndrome protein CSA and one with human GTPase XPA binding protein XAB1. Three ORFs are likely to code for proteins because they have sequence similarity with hypothetical proteins, three encode predicted coiled-coil proteins and four are sequence orphans.     

Molecular cloning and analysis of autonomous replicating sequence of Candida maltosa.

A Candida maltosa chromosomal DNA fragment which confers high frequency transformation of C. maltosa and autonomous replication of recombinant plasmids was cloned and sequenced. Analysis of the nucleotide sequence of the cloned DNA revealed a sequence homologous for C. maltosa autonomously replicating sequence (ARS) elements. Vector pRJ1 for C. maltosa was constructed, which contained a 1.3 kb ARS sequence, pICEM-19H and the ADE1 gene of C. maltosa. Southern blot analysis suggested that the copy number of pRJ1 in C. maltosa was approximately 20 per genome. The sequence analysis also revealed an open reading frame, encoding a polypeptide with high homology (70%) to the RS15 protein of Brugia pagangi. This open reading frame has an intron with canonical sites for correct splicing in Saccharomyces cerevisiae.     

烟草钾离子通道基因NKT5的克隆和序列分析

本研究运用已经获得的1条490bp的普通烟草钾离子(K~+)通道基因的中间片段来设计特异性引物,应用RACE方法获得其3'和5'末端cDNA序列。通过三段cDNA序列拼接结合全长克隆测序验证,获得一个未报道的普通烟草K~+通道基因,并将其命名为NKT5(NCBI登录号为HM010922)。NKT5的cDNA全长为2365bp,其中5'端非编码区190bp、3'端非编码区249bp、编码区1926bp,编码641AA。对该基因进行了序列分析及功能预测,为进一步阐明其在烟草吸钾及抗逆过程中的功能及分子机制奠定了基础。     

Identification of a Candida albicans homologue of the PHO85 gene, a negative regulator of the PHO system in Saccharomyces cerevisiae

In a screen for the protein kinase genes of the human pathogenic yeast Candida albicans, a putative homologue (CaPHO85) of PHO85, a negative regulator of the PHO system of Saccharomyces cerevisiae, which is one of the cyclin-dependent protein kinases (CDKs), was isolated. An open reading frame (ORF) of this gene was identified encoding a predicted protein of 326 amino acids with a calculated molecular weight of 37.6 kDa. The amino acid sequence is highly homologous to S. cerevisiae Pho85 (62% identity) and its Aspergillus nidulans homologue (70% identity), but less homologous to Cdc28 (50% identity) of S. cerevisiae and to its C. albicans homologue CaCdc28 (49% identity), both of which are also CDK. The coding region for the C. albicans gene was interrupted by an intron of 81 nucleotides near the sequence encoding the N-terminal region, similarly to the case of the S. cerevisiae PHO85 gene. Alignment of CaPho85 with various yeast CDKs revealed that most of the domains for ATP-binding and protein kinase activity are conserved among fungal species. Southern blot analysis indicated that CaPHO85 is most likely present as a single copy gene. This gene complemented the pho85 mutation of S. cerevisiae by transformation.     

Genetic variation in the αS1-casein of Chinese yak (Bos grunniens)

The aim of this study was to investigate diversity of the αS1-casein gene in Maiwa yak. A polymorphism of αS1-casein gene has been identified in Chinese Maiwa yak by PCR single-strand conformation polymorphism protocol. Comparing the X59856 sequence, some non-coding and coding DNA variants of yak CSN1S1 gene were detected in this present study, including KJ397913 (promoter region, 9969A/G, 9984 A/G, 10153 C/T, 10175 A/C, 10261 G/C), KJ397914 (promoter region 10261 G/C), KJ397896 (intron III, 14862 T/C), KJ397897 (intron III, 14862 T/C, and deleted 14944-14946 CTT), KJ397899 (intron IV, 15297 A/C), KJ397901 (intron VIII, 17503 A/C, 17666 A/C), KJ397902 (exon IX, 18901C/A, intron IX, 18970 T/G, 19088 add A, 19120 add A, 19202 add T, 19296 G/T), KJ397903 (intron IX, 18970 T/G, 19088 add A, 19120 add A, 19202 add T, 19296 G/T), KJ397904 (intron IX, 19537 T/G, 19539T/G, 19599G/A, 19638 C/T), KJ397905 (intron XIV, 23402 T/G, 23417 C/T, 23480 T/C, 23511 G/A), and KJ397907 (intron XVI, 25976 G/T; exon XVII, 26181A/G). The polymorphism of αS1-casein gene may be helpful for future studies on genetic variation within and between yak populations or on associated traits.     

Identification of an UDP-Glc:glycoprotein glucosyltransferase in the yeast Yarrowia lipolytica

The UDP-Glc:glycoprotein glucosyltransferase (UGT) is a soluble protein of the endoplasmic reticulum (ER) that plays a determining part in the mechanism by which unfolded, partially folded or misfolded glycoproteins are retained into the ER. We have identified an UGT in the yeast Yarrowia lipolytica. This protein, of a predicted molecular weight of 165.7 kDa, is encoded by a 5054 bp coding sequence containing a 643 bp intron at position 682-1323. The N-terminal part of the protein displays a signal sequence whereas its C-terminal part carries an ER retrieval signal HDEL. An interruption of the gene that removes the 1075 last nucleotides of its sequence did not lead to any evident phenotype except for a slight increased sensitivity to tunicamycin. YlUGT1 mRNA levels respond to tunicamycin treatment by an induction factor of 2-4, which indicates that the gene product participates in the quality control mechanism in this yeast. Finally, an immunofluorescence study of the protein localization, shows that the protein distribution is different from that of previously studied ER resident proteins. This could indicate that UGT distribution in the secretory pathway is not confined to the ER.     

Mutations in the large subunit of U2AF disrupt pre-mRNA splicing, cell cycle progression and nuclear structure

The prp2 gene of fission yeast has previously been shown to encode the large subunit of the splicing factor spU2AF. SpU2AF(59) is an evolutionarily conserved protein that has an arginine/serine-rich region and three RNA recognition motifs (RRMs). We have sequenced three temperature-sensitive alleles of prp2 and determined that the mutations result in single amino acid changes within one of the RRMs or between RRMs. All mutant alleles of prp2 have pre-mRNA splicing defects at the non-permissive temperature. Although the mutant strains are growth-arrested at 37 degrees C, they do not elongate like typical fission yeast cell cycle mutants. The DNA of the prp2(-) strains stains more intensely than a wild-type strain, suggesting that the chromatin may be condensed. Ultrastructural studies show differences in the mutant nuclei including a prominent distinction between the chromatin- and non-chromatin-enriched regions compared to the more homogenous wild-type nucleus. Two-hybrid assays indicate that some of the wild-type protein interactions are altered in the mutant strains. These results suggest that normal functioning of spU2AF(59) may be essential not only for pre-mRNA splicing but also for the maintenance of proper nuclear structure and normal cell cycle progression.     

CaALK8, an alkane assimilating cytochrome P450, confers multidrug resistance when expressed in a hypersensitive strain of Candida albicans

We report the isolation of a novel C. albicans gene designated CaALK8, by its ability to complement drug hypersensitivity of a pdr5 (ABC: ATP-binding cassette drug extrusion pump) null mutant of S. cerevisiae (JG436). CaALK8 in JG436 conferred resistance to drugs such as cycloheximide (CYH), fluconazole (FCZ), O-phenanthroline (PHE) and 4-nitroquinoline oxide (NQO). The gene was so designated because its sequence was identical to a partial sequence entry named as ALK8 in the Candida database (http://alces.med.umn.edu/candida.html). CaALK8 encodes for a putative 515 amino acid protein highly homologous to alkane-inducible cytochromes P450 (CYP52 gene family) of C. maltosa and C. tropicalis. The ability of CaALK8 to confer drug resistance was also established by its expression in another drug-hypersensitive strain of S. cerevisiae (AD 1234568), which was deleted in seven ABC efflux pumps. The homozygous disruption of CaALK8 in a wild-type C. albicans strain (CAI4) did not result in altered drug susceptibilities. The overexpression of CaALK8 in CAI4 resulted in only FCZ resistance. However, a distinct MDR phenotype was evident when CaALK8 was overexpressed in a drug-hypersensitive C. albicans strain disrupted in both CDR1 and CDR2 (ABC drug extrusion pumps of C. albicans). Alk8p, similar to other Alk proteins from C. maltosa and C. tropicalis, could hydroxylate alkanes and fatty acids. In this study we demonstrate that several drugs could compete with the hydroxylation activity by directly interacting with CaAlk8p. Taken together, our results suggest that a member of the CYP52 gene family could mediate MDR in C. albicans, although it does not seem to be involved in the development of azole resistance in clinical isolates. The nucleotide sequence reported in this paper has been submitted to GenBank under Accession No. Y14766.