Gene activation at a distance and telomeric silencing are not affected by yeast histone H1

Until recently, it was believed that the budding yeast Saccharomyces cerevisiae has no histone H1 gene. However, a search of the yeast genome database revealed a possible H1 homologue of 258 amino acids, termed yeast histone H1 (HHO1). The protein shows 36% identity to the human H1 core domain over a stretch of 93 amino acids. Unlike other H1 proteins, Hho1p has a second possible core domain which shows 43% identity to the first core domain. Since vertebrate H1 histone had been implied in gene repression as well as gene activation at a distance, we tested the effect of deleting the yeast H1-like gene on remote activation of a modified GAL1 promoter, which contains a synthetic GAL4 binding site close to the TATA box, and the natural UAS_G, consisting of four GAL4 binding sites. Different spacing up to 1.8 kb between the proximal binding site and the distal UAS_G enhancer revealed no differences in gene activation between wild-type and knockout strains. Overexpression of a heterologous histone H1 from sea urchin showed an overall inhibition of gene activation by the GAL1 promoter, whereas overexpression of the yeast histone H1 had no effect. Also, the expression of A1, ALPHA2 or SUC2 genes, all of which are known to be responsive to an altered chromatin structure, was unchanged in HHO1 knockout or HHO1-overexpressing strains when compared to wild-type cells. We also considered the possibility that HHO1 was involved in forming the heterochromatin at telomeres. On testing for telomeric silencing of a URA reporter gene introduced 1.3 kb away from the chromosomal end, we again observed no differences between wild-type and knockout strains. Thus, the yeast histone H1-like gene appears to have no role in gene activation at a distance or in silencing under the conditions tested. It remains to be seen whether the yeast H1 histone is a gene-specific regulator rather than a general chromatin-associated protein. Received: 16 April 1997 / Accepted: 4 July 1997     

Characterization of the lys2 gene of Penicillium chrysogenum encoding α -aminoadipic acid reductase

A DNA fragment containing a gene homologous to LYS2 gene of Saccharomyces cerevisiae was cloned from a genomic DNA library of Penicillium chrysogenum AS-P-78. It encodes a protein of 1409 amino acids (Mr^ 154 859) with strong similarity to the S. cerevisiae (49.9% identity) Schizosaccharomycespombe (51.3% identity) and Candida albicans (48.12% identity) α-aminoadipate reductases and a lesser degree of identity to the amino acid-activating domains of the non-ribosomal peptide synthetases, including the α-aminoadipate-activating domain of the α-aminoadipyl-cysteinyl-valine synthetase of P. chrysogenum (12.4% identical amino acids). The lys2 gene contained one intron in the 5′-region and other in the 3′-region, as shown by comparing the nucleotide sequences of the cDNA and genomic DNA, and was transcribed as a 4.7-kb monocistronic mRNA. The lys2 gene was localized on chromosome III (7.5 Mb) in P. chrysogenum AS-P-78 and on chromosome IV (5.6 Mb) in strain P2, whereas the penicillin gene cluster is known to be located in chromosome I in both strains. The lys2-encoded protein is a member of the aminoacyladenylate-forming enzyme family with a reductase domain in its C-terminal region. Received: 26 January 1998 / Accepted: 4 May 1998     

Yeast Srp1, a nuclear protein related toDrosophila and mouse pendulin, is required for normal migration, division, and integrity of nuclei during mitosis

This paper describes genes from yeast and mouse with significant sequence similarities to aDrosophila gene that encodes the blood cell tumor suppressor pendulin. The protein encoded by the yeast gene, Srp1p, and mouse pendulin share 42% and 51% amino acid identity withDrosophila pendulin, respectively. All three proteins consist of 10.5 degenerate tandem repeats of 42 amino acids each. Similar repeats occur in a superfamily of proteins that includes theDrosophila Armadillo protein. All three proteins contain a consensus sequence for a bipartite nuclear localization signal (NLS) in the N-terminal domain, which is not part of the repeat structure. Confocal microscopic analysis of yeast cells stained with antibodies against Srp1p reveals that this protein is intranuclear throughout the cell cycle. Targeted gene disruption shows thatSRP1 is an essential gene. Despite their sequence similarities,Drosophila and mouse pendulin are unable to rescue the lethality of anSRP1 disruption. We demonstrate that yeast cells depleted of Srp1p arrest in mitosis with a G2 content of DNA. Arrested cells display abnormal structures and orientations of the mitotic spindles, aberrant segregation of the chromatin and the nuclei, and threads of chromatin emanating from the bulk of nuclear DNA. This phenotype suggests that Srplp is required for the normal function of microtubules and the spindle pole bodies, as well as for nuclear integrity. We suggest that Srp1p interacts with multiple components of the cell nucleus that are required for mitosis and discuss its functional similarities to, and differences fromDrosophila pendulin.     

MSl3, a multicopy suppressor of mutants hyperactivated in the RAS-CAMP pathway, encodes a novel HSP70 protein of Saccharomyces cerevisiae

The MSI3 gene was isolated as a multicopy suppressor of the heat shock-sensitive phenotype of the iral mutation, which causes hyperactivation of the RAS-cAMP pathway. Overexpression of MSI3 also suppresses the heat shock-sensitive phenotype of the bcyl mutant. Determination of the DNA sequence of MSI3 revealed that MSI3 can encode a 77.4 kDa protein related to the HSP70 family. The amino acid sequence of Msi3p is about 30% identical to that of the Ssalp of Saccharomyces cerevisiae. This contrasts with the finding that members of the HSP70 family generally show at least 50% amino acid identity. The consensus nucleotide sequence of the heat shock element (HSE) was found in the upstream region of MSI3. Moreover, the steady-state levels of the MSI3 mRNA and protein were increased upon heat shock. These results indicate that the MSI3 gene encodes a novel HSP70-like heat shock protein. Disruption of the MSI3 gene was associated with a temperature sensitive growth phenotype but unexpectedly, thermotolerance was enhanced in the disruptant.     

Efficient production of intact human parathyroid hormone in a Saccharomyces cerevisiae mutant deficient in yeast aspartic protease 3 (YAP3)

When human parathyroid hormone (hPTH) is expressed as a secretory product in yeast, the main problem is the aberrant proteolytic cleavage that reduces the yield of intact protein. To overcome this problem, we developed an hPTH expression system using a host strain in which the YAP3 gene encoding yeast aspartic protease 3 (YAP3) was disrupted. After 48 h of culture, most of the hPTH secreted by the yap3 disruptant remained intact, whereas more than 90% of the hPTH secreted by the wild-type strain was cleaved. When the authentic hPTH was incubated in each of the culture supernatants of untransformed yap3 disruptant and wild-type strain, the proteolysis proceeded much more slowly in the culture supernatant of yap3 disruptant than in that of the wild type. The extent of hPTH proteolysis was also significantly reduced by the addition of pepstatin A, a specific aspartic protease inhibitor. The results suggest that YAP3 is involved in the internal cleavage of hPTH expressed in yeast. The correct processing of the intact hPTH secreted in the yap3 disruptant demonstrates that the yeast mutant lacking the YAP3 activity is a suitable host for the high-level expression of intact hPTH. Received: 8 December 1997 / Received last revision: 3 March 1998 / Accepted: 19 April 1998     

The Human Lamin B Receptor/Sterol Reductase Multigene Family

LBR (lamin B receptor) is an integral protein of the inner nuclear membrane encoded by a gene on human chromosome 1q42.1. LBR has a nucleoplasmic, amino-terminal domain of approximately 200 amino acids followed by a carboxyl-terminal domain similar in sequence to yeast and plant sterol reductases. We have determined the primary structures of two human proteins with strong sequence similarity to the carboxyl-terminal domain of LBR and sterol reductases. Their genes have recently been assigned the symbols TM7SF2 and DHCR7. TM7SF2 mRNA is most predominantly expressed in heart and DHCR7 mRNA mostly in liver and brain. Whereas LBR is localized to the inner nuclear membrane, these two related proteins are in the endoplasmic reticulum. TheTM7SF2gene contains 10 coding exons, and its intron positions are exactly conserved in the part of theLBRgene encoding its carboxyl-terminal domain. Intron positions in theDHCR7gene are also similar. Both of these new LBR-like genes are on chromosome 11q13. These results describe a human gene family encoding proteins of the inner nuclear membrane and endoplasmic reticulum that function in nuclear organization and/or sterol metabolism.     

Multiple hydrophobic motifs in Arabidopsis CBF1 COOH-terminus provide functional redundancy in trans-activation

The Arabidopsis CBF proteins activate expression of a set of genes whose upstream regulatory sequences typically harbor one or more copies of the CRT/DRE low temperature cis-acting DNA regulatory element. Using domain swap experiments in both yeast and Arabidopsis we show that the NH₃-terminal 115 amino acids direct CBF1 to target genes and the COOH-terminal 98 amino acids function in trans-activation. Mutational analysis through the COOH-terminus using truncation and alanine-substitution mutants in yeast revealed four motifs that contribute positively towards activation. Overexpression of mutants in plants support this conclusion and also indicated that disruption of a single motif did not seriously compromise activity unless combined with the disruption of a second. These motifs consist of clusters of hydrophobic residues which are delimited from one another by short stretches of Asp, Glu, Pro and other residues favoring the formation of loops. This structural pattern is conserved across plant taxa as revealed through alignment of Arabidopsis CBF1 with homologous sequences from a diverse array of plant species. Overexpression in plants of the CBF1 COOH-terminus as a fusion with the yeast GAL4 DNA binding domain also resulted in severe stunting of growth, a phenotype which was alleviated if the activation domain was rendered ineffective. Taken together these results suggest that high level overexpression of an active, CBF activation domain compromises plant growth.     

Isolation and characterization of gmsti,a stress-inducible gene from soybean (Glycine max) coding for a protein belonging to the TPR (tetratricopeptide repeats) family

In close vicinity of two fus nuclear genes (chloroplast-specific translation elongation factor cEF-G) of soybean (Glycine max) we localized a split nuclear gene coding for a protein with tetratricopeptide repeats (TPR). A full-length cDNA was sequenced (1871 nucleotides). It encodes a protein (569 amino acids) with high sequence identity to the yeast STI1 stress-inducible and the human transformation-sensitive IEF SSP 3521 protein which both carry TPR elements. The soybean gene is heat-inducible. This is the first evidence for the existence of plant genes coding for proteins which belong to the TPR family. We call the gene gmsti and the protein GMSTI in analogy to the yeast counterpart.     

大豆GeBP转录因子基因家族的生物信息学分析

GeBP转录因子调控植物表皮毛的生长发育,并且参与控制植物叶片的发育。该文利用生物信息学方法,在大豆全基因组范围内搜索GeBP基因家族,并从氨基酸理化性质、基因结构、染色体的物理分布、系统进化、序列比对、功能结构域、组织表达情况等基本特征方面对GmGeBP基因家族进行分析。结果表明:(1)共获得9个GmGeBP转录因子基因家族成员,其中仅2个基因含有内含子,且都只有1个内含子,表明该家族成员基因构造比较简单但稳定。(2)GmGeBP编码的蛋白分子量为39.65~49.24 kD,理论等电点为4.65~9.08;这些成员基本上都是酸性氨基酸,属于亲水性、不稳定蛋白。(3)这9个基因不均匀的分布于7条染色体上,10和20号染色体上分别分布2个GeBP基因,3、5、13、15、19号染色体上各分布1个基因。(4)系统进化分析表明,大豆与拟南芥对应的GeBP成员亲缘关系较近,分别聚类到4个分支,而与水稻的距离较远。(5)结构域分析表明,9个GmGeBP成员都包含DUF573结构域,推测该部分在GeBP转录因子中很可能是与靶标基因顺式作用元件互作的结构域。(6)通过分析大豆GmGeBP转录因子基因家族的组织表达,发现不同基因在大豆不同组织的表达量不同,具有一定的特异性。该文对大豆GeBP转录因子基因家族的分析和鉴定为进一步研究大豆表皮毛发育的分子作用提供了理论基础。     

Rap1‐mediated nucleosome displacement can regulate gene expression in senescent cells without impacting the pace of senescence

Cell senescence is accompanied, and in part mediated, by changes in chromatin, including histone losses, but underlying mechanisms are not well understood. We reported previously that during yeast cell senescence driven by telomere shortening, the telomeric protein Rap1 plays a major role in reprogramming gene expression by relocalizing hundreds of new target genes (called NRTS, for n ew R ap1 t argets at s enescence) to the promoters. This leads to two types of histone loss: Rap1 lowers histone level globally by repressing histone gene expression, and it also causes local nucleosome displacement at the promoters of upregulated NRTS. Here, we present evidence of direct binding between Rap1 and histone H3/H4 heterotetramers, and map amino acids involved in the interaction within the Rap1 SANT domain to amino acids 392–394 (SHY). Introduction of a point mutation within the native RAP1 locus that converts these residues to alanines (RAP1^SHY), and thus disrupts Rap1‐H3/H4 interaction, does not interfere with Rap1 relocalization to NRTS at senescence, but prevents full nucleosome displacement and gene upregulation, indicating direct Rap1‐H3/H4 contacts are involved in nucleosome displacement. Consistent with this, the histone H3/H4 chaperone Asf1 is similarly unnecessary for Rap1 localization to NRTS but is required for full Rap1‐mediated nucleosome displacement and gene activation. Remarkably, RAP1^SHY does not affect the pace of senescence‐related cell cycle arrest, indicating that some changes in gene expression at senescence are not coupled to this arrest.     

In vitro binding to the leucine tRNA gene identifies a novel yeast homeobox gene

In a search for gene products of Saccharomyces cerevisiae interacting with the internal promoter of yeast tRNA genes two genes encoding a homeodomain protein of the Drosophila Antennapedia type were isolated. One of them codes for Pho2, and the second codes for a previously unknown protein (Yox1). The corresponding gene, termed YOX1, maps to chromosome 16. The amino acid sequence of Yox1 shows a remarkable similarity within the homeobox domain to many proteins from a wide variety of sources. Fusion proteins that contain sequences encoded by these genes demonstrate that the genes encode DNA-binding proteins that are capable of binding to the DNA of the leucine tRNA gene in vitro. However, deletion of YOX1 gene activity does not give rise to a scorable mutant phenotype. This result leaves open whether Yox1 binding to the leucine tRNA gene is necessary for the in vivo regulaiton of the gene and its suggests that the YOX1 gene codes for a nonessential product.by H. JäckleThe sequence data reported here will appear in the EMBL, Gen-Bank and DDBJ Nucleotide Sequence Databases under the accession number X62392     

A human homologue of the Drosophila melanogaster sluggish-A (proline oxidase) gene maps to 22q11.2, and is a candidate gene for type-I hyperprolinaemia

We have cloned the complete coding region for a human homologue of the Drosophila melanogaster sluggish-A and yeast PUT1 genes, previously shown to encode proline oxidase activity in these organisms. The predicted 516-residue human protein shows strong homology (51% amino acid sequence identity) to the D. melanogaster protein, indicating that this new human gene may encode proline oxidase. Northern analysis shows that the gene is expressed in human lung, skeletal muscle and brain, to a lesser extent in heart and kidney, and weakly in liver, placenta and pancreas. The gene was mapped by fluorescence in situ hybridization and by in situ hybridization with a [³H]-labelled DNA probe to chromosome 22q11.2, a region previously implicated in type-I hyperprolinaemia in a case of CATCH 22 syndrome, a contiguous gene deletion syndrome involving 22q11. Taken together, the evidence indicates that this new human gene is a good candidate gene for type-I hyperprolinaemia. In view of the neurological phenotype of the D. melanogaster sluggish-A mutant, it is of interest that schizophrenia and bipolar disorder susceptibility genes also map in this region. Received: 14 April 1997 / Accepted: 17 June 1997     

The Tsc/Rheb signaling pathway controls basic amino acid uptake via the Cat1 permease in fission yeast

The Tsc/Rheb signaling pathway plays critical roles in the control of growth and cell cycle. Studies in fission yeast have also implicated its importance in the regulation of amino acid uptake. Disruption of tsc2 ⁺, one of the tsc ⁺ genes, has been shown to result in decreased arginine uptake and resistance to canavanine. A similar effect is also seen with other basic amino acids. We have identified a permease responsible for the uptake of basic amino acids by genetic complementation and disruption. SPAC869.11 (termed Cat1 for cationic amino acid transporter) contains 12 predicted transmembrane domains and its overexpression in wild type fission yeast leads to the increased uptake of basic amino acids and sensitivity to canavanine. Disruption of cat1 ⁺ in the Δtsc2 background interfered with the suppression of the canavanine-resistant phenotype of Δtsc2 mutants by a dominant negative Rheb. In Δtsc2 mutant strains, the amount of Cat1 was not altered, but instead was mislocalized. This mislocalization was suppressed by the expression of dominant negative Rheb. In addition, we found that the loss of the E3 ubiquitin ligase, Pub1, also restores proper localization. These results provide a crucial link between Tsc/Rheb signaling and the regulation of the basic amino acid permease in fission yeast.     

Isolation and characterization of OsDMC1, the rice homologue of the yeast DMC1 gene essential for meiosis

Yeast DMC1 is a meiosis-specific gene required for homologous chromosome pairing in meiosis. Using degenerate primers designed according to amino acid motifs conserved in yeast Dmc1 and Arabidopsis AtDmc1, we obtained full-length cDNA of a rice homologue of the DMC1 gene (OsDMC1) by RT-PCR and rapid amplification of cDNA ends (RACEs). OsDmc1 exhibited 53% amino acid sequence identity to yeast Dmc1 and 81% to AtDmc1. OsDMC1 was expressed at high-levels in reproductive organs, low-levels in roots, and undetectable levels in leaves and seedlings. Southern blot analyses revealed that OsDMC1 is one of two DMC1 homologues present in rice. Received: 18 December 2000 / Accepted: 22 December 2000     

Cloning and mutational analysis of the gene encoding subunit C of yeast vacuolar H(+)-ATPase.

A DNA fragment containing the gene encoding subunit C of vaculor H(+)-ATPase (V-ATPase) was cloned from a yeast library. The predicted amino acid sequence indicated that the C subunit consists of 373 amino acids with a calculated molecular mass of 42,287 Da. The protein from yeast is 37% identical in its amino acid sequence to the C subunit of bovine V-ATPase. The DNA fragment that was cloned in this study contained two additional reading frames. At the 5' end an amino acid sequence that is homologous to Artemia elongation factor 1 was detected. At the 3' end the N-terminal part of a kinesin-like protein was observed. The gene encoding subunit C of the V-ATPase was interrupted, and the resulting mutant could not grow at high pH and was sensitive to low and high Ca2+ concentrations in the growth medium. Transformation of the mutant by a plasmid containing the gene encoding subunit C repaired the phenotype of the mutant. Substitution of more than half of the coding region by a corresponding DNA fragment encoding the bovine subunit C resulted in a phenotype indistinguishable from wild type. Immunological studies with the disruptant mutant revealed that subunit C is necessary for the assembly of the catalytic sector of the enzyme.