白念珠菌CaPPEl的克隆及其在酿酒酵母形态发生中的功能研究

白念珠菌的致病性与其形态转变相关,白念珠菌的形态转换受各种外界信号和细胞内信号转导途径的调控。转录因子Flo8在酿酒酵母形态发生中起重要作用,我们将白念珠菌基因组文库导入flo8缺失株中,筛选能够校正flo8缺失株侵入生长缺陷的基因,分离得到一个与酿酒酵母蛋白磷酸酯酶甲基酯酶PPEl同源的基因,命名为CaPPEl。CaPPEl的基因编码区全长1083bp,推测编码一个361氨基酸的蛋白。在单倍体酿酒酵母中,CaPPEl基因的表达可以部分回复flo8缺失株的侵入生长缺陷,但是在MAPK途径缺失株中不能进行侵入生长。在双倍体酿酒酵母中,CaPPEl基因的表达可以部分激活MAPK途径成员缺失株的菌丝生长缺陷,但却只能在flo8缺失株中产生微弱的激活作用。结果表明CaPpel在酿酒酵母的假菌丝生长和侵入生长中参与的信号转导途径不同。     

白念珠菌CaPPE1的克隆及其在酿酒酵母形态发生中的功能研究

白念珠茵的致病性与其形态转变相关,白念珠茵的形态转换受各种外界信号和细胞内信号转导途径的调控。转录因子Flo8在酿酒酵母形态发生中起重要作用,我们将白念珠茵基因组文库导入flo8缺失株中,筛选能够校正flo8缺失株侵入生长缺陷的基因,分离得到一个与酿酒酵母蛋白磷酸酯酶甲基酯酶PPEI同源的基因,命名为CaPPEl。CaPPEl的基因编码区全长1083bp,推测编码一个361氨基酸的蛋白。在单倍体酿酒酵母中,CaPPE1基因的表达可以部分回复flo8缺失株的侵入生长缺陷,但是在MAPK途径缺失株中不能进行侵入生长。在双倍体酿酒酵母中,CaPPEl基因的表达可以部分激活MAPK途径成员缺失株的茵丝生长缺陷,但却只能在flo8缺失株中产生微弱的激活作用。结果表明CaPpel在酿酒酵母的假茵丝生长和侵入生长中参与的信号转导途径不同。     

CaSRB9基因的克隆及其在酿酒酵母形态发生中的作用

白色念珠菌是一种重要的人体致病真菌 ,致病机制与其形态发生紧密相关。酿酒酵母Flo8因子在其形态发生中起重要作用 ,我们把白色念珠菌基因组DNA导入酿酒酵母flo8基因缺失株中 ,筛选能够互补 flo8侵入生长缺陷的基因 ,分离到了一个与酿酒酵母SRB9同源的新基因 ,命名为CaSRB9。该基因全长 4998bp ,编码一种16 6 5个氨基酸的蛋白质。在双倍体酿酒酵母中CaSRB9可以部分互补MAPK途径基因缺失株以及 flo8缺失株的菌丝生长缺陷 ;在单倍体酿酒酵母中表达能够互补 flo8缺失株的侵入生长缺陷 ,但在MAPK途径基因缺失株中不能形成侵入生长     

白色念珠菌CaBEM1基因的克隆及其在酿酒酵母丝状生长中的作用

白色念珠菌在不同的生长条件下能发生显著的形态变化 ,这种变化由多种调控因子与信号转导途径所调控。酿酒酵母的G1期细胞周期蛋白Cln1和Cln2参与其形态发生 ,cln1/cln1、cln2 /cln2双缺失株不能形成菌丝。把白色念珠菌基因组文库导入cln1/cln1、cln2 /cln2缺失株 ,筛选能校正菌丝形成缺陷的基因 ,分离得到白色念珠菌中的CaBEM 1基因。从核苷酸序列推导 ,CaBEM1编码一种 6 32个氨基酸的蛋白质 ,氨基酸序列分析表明在其N端有 2个SH3结构域 ,中部有 1个PX结构域 ,C端有 1个PB1结构域 ;CaBem1的氨基酸序列与酿酒酵母的Bem1同源性达 38% ,与裂殖酵母的Scd2同源性达 32 %。在酿酒酵母的缺失株中异源表达CaBEM1,能够部分校正它们在氮源缺乏条件下的菌丝形成缺陷。这种菌丝形成的校正作用绕过MAPK途径和cAMP/PKA途径 ,表明CaBem1在菌丝形成中的作用可能位于这两条信号转导途径的下游     

A novel functional link between MAP kinase cascades and the Ras/cAMP pathway that regulates survival

In mammalian cells, Ras regulates multiple effectors, including activators of mitogen-activated protein kinase (MAPK) cascades, phosphatidylinositol-3-kinase, and guanine nucleotide exchange factors (GEFs) for RalGTPases. In S. cerevisiae, Ras regulates the Kss1 MAPK cascade that promotes filamentous growth and cell integrity, but its major function is to activate adenylyl cyclase and control proliferation and survival ([; see Figure S1 in the Supplemental Data available with this article online). Previous work hints that the mating Fus3/Kss1 MAPK cascade cross-regulates the Ras/cAMP pathway during growth and mating, but direct evidence is lacking. Here, we report that Kss1 and Fus3 act upstream of the Ras/cAMP pathway to regulate survival. Loss of Fus3 increases cAMP and causes poor long-term survival and resistance to stress. These effects are dependent on Kss1 and Ras2. Activation of Kss1 by a hyperactive Ste11 MAPKKK also increases cAMP, but mating receptor/scaffold activation has little effect and may therefore insulate the MAPKs from cross-regulation. Catalytically inactive Fus3 represses cAMP by blocking accumulation of active Kss1 and by another function also shared by Kss1. The conserved RasGEF Cdc25 is a likely control point, because Kss1 and Fus3 complexes associate with and phosphorylate Cdc25. Cross-regulation of Cdc25 may be a general way that MAPKs control Ras signaling networks.     

A catalytic subunit of cyclic AMP-dependent protein kinase, PKAC-1, regulates asexual differentiation in Neurospora crassa

A cyclic AMP (cAMP)-dependent protein kinase pathway has been shown to regulate growth, morphogenesis and virulence in filamentous fungi. However, the precise mechanisms of regulation through the pathway remain poorly understood. In Neurospora crassa, the cr-1 adenylate cyclase mutant exhibits colonial growth with short aerial hyphae bearing conidia, and the mcb mutant, a mutant of the regulatory subunit of cAMP-dependent protein kinase (PKA), shows the loss of growth polarity at the restrictive temperature. In the present study, we isolated mutants of the catalytic subunit of the PKA gene pkac-1 through the process of repeat-induced point mutation (RIP). PKA activity of the mutants obtained through RIP was undetectable. The genome sequence predicts two distinct catalytic subunit genes of PKA, named pkac-1 (NCU06240.1, AAF75276) and pkac-2 (NCU00682.1), as is the case in most filamentous fungi. The results suggest that PKAC-1 works as the major PKA in N. crassa. The phenotype of the pkac-1 mutants included colonial growth, short aerial hyphae, premature conidiation on solid medium, inappropriate conidiation in submerged culture, and increased thermotolerance. This phenotype of pkac-1 mutants resembled to that of cr-1 mutants, except that the addition of cAMP did not rescue the abnormal morphology of pkac-1 mutants. The loss of growth polarity at the restrictive temperature in the mcb mutant was suppressed by pkac-1 mutation. These results suggest that the signal transduction pathway mediated by PKAC-1 plays an important role in regulation of aerial hyphae formation, conidiation, and hyphal growth with polarity.     

The nuclear Dbf2-related kinase COT1 and the mitogen-activated protein kinases MAK1 and MAK2 genetically interact to regulate filamentous growth, hyphal fusion and sexual development in Neurospora crassa

Ndr kinases, such as Neurospora crassa COT1, are important for cell differentiation and polar morphogenesis, yet their input signals as well as their integration into a cellular signaling context are still elusive. Here, we identify the cot-1 suppressor gul-4 as mak-2 and show that mutants of the gul-4/mak-2 mitogen-activated protein (MAP) kinase pathway suppress cot-1 phenotypes along with a concomitant reduction in protein kinase A (PKA) activity. Furthermore, mak-2 pathway defects are partially overcome in a cot-1 background and are associated with increased MAK1 MAPK signaling. A comparative characterization of N. crassa MAPKs revealed that they act as three distinct modules during vegetative growth and asexual development. In addition, common functions of MAK1 and MAK2 signaling during maintenance of cell-wall integrity distinguished the two ERK-type pathways from the p38-type OS2 osmosensing pathway. In contrast to separate functions during vegetative growth, the concerted activity of the three MAPK pathways is essential for cell fusion and for the subsequent formation of multicellular structures that are required for sexual development. Taken together, our data indicate a functional link between COT1 and MAPK signaling in regulating filamentous growth, hyphal fusion, and sexual development.     

Candida albicans INT1-induced filamentation in Saccharomyces cerevisiae depends on Sla2p

The Candida albicans INT1 gene is important for hyphal morphogenesis, adherence, and virulence (C. Gale, C. Bendel, M. McClellan, M. Hauser, J. M. Becker, J. Berman, and M. Hostetter, Science 279:1355-1358, 1998). The ability to switch between yeast and hyphal morphologies is an important virulence factor in this fungal pathogen. When INT1 is expressed in Saccharomyces cerevisiae, cells grow with a filamentous morphology that we exploited to gain insights into how C. albicans regulates hyphal growth. In S. cerevisiae, INT1-induced filamentous growth was affected by a small subset of actin mutations and a limited set of actin-interacting proteins including Sla2p, an S. cerevisiae protein with similarity in its C terminus to mouse talin. Interestingly, while SLA2 was required for INT1-induced filamentous growth, it was not required for polarized growth in response to several other conditions, suggesting that Sla2p is not required for polarized growth per se. The morphogenesis checkpoint, mediated by Swe1p, contributes to INT1-induced filamentous growth; however, epistasis analysis suggests that Sla2p and Swe1p contribute to INT1-induced filamentous growth through independent pathways. The C. albicans SLA2 homolog (CaSLA2) complements S. cerevisiae sla2Delta mutants for growth at 37 degrees C and INT1-induced filamentous growth. Furthermore, in a C. albicans Casla2/Casla2 strain, hyphal growth did not occur in response to either nutrient deprivation or to potent stimuli, such as mammalian serum. Thus, through analysis of INT1-induced filamentous growth in S. cerevisiae, we have identified a C. albicans gene, SLA2, that is required for hyphal growth in C. albicans.     

Rom2p, the Rho1 GTP/GDP exchange factor of Saccharomyces cerevisiae, can mediate stress responses via the Ras-cAMP pathway

The Ras-cyclic AMP pathway is connected to other nutrient-regulated signaling pathways and mediates the global stress responses of Saccharomyces cerevisiae. Here, we show that Rom2p, the Rho1 GTP/GDP exchange factor, can mediate stress responses and cell growth via the Ras-cAMP pathways. ROM2 was isolated as a suppresser of heat and NaCl sensitivity caused by the lack of the Ras-GTPase activator Ira2p or of cAMP phosphodiesterases. Subsequent analysis of strains with a rom2 deletion showed that Rom2p is essential for resistance to a variety of stresses caused by freeze-thawing, oxidants, cycloheximide, NaCl, or cobalt ions. Stress sensitivity and the growth defect caused by the rom2 deletion could be suppressed by depleting Ras or protein kinase A (PKA) activity or by overexpressing the high affinity cAMP phosphodiesterase Pde2p. In addition, overexpression of ROM2 could not rescue cells lacking the regulatory subunit of PKA, indicating that the Ras-adenylate, cyclase-PKA cascade is essential for Rom2p-mediated stress responses and cell growth. Deletion of IRA2 exacerbated the freeze-thaw sensitivity and growth defect of the rom2 mutant, indicating that Rom2p signaling may control Ras independently of IRA2. Increases in cAMP levels were detected in the rom2 deletion mutants, and these were comparable with the effects of an ira2 mutation. The effects of the deletion of ROM2 on sensitivity to hydrogen peroxide, paraquat, and cobalt ions, but not to caffeine, were reduced when a constitutive allele of RHO1 was introduced on a single copy plasmid. However, the effects of the deletion of ROM2 on sensitivity to diamide and NaCl were exacerbated. Taken together, our data indicate that Rom2p can regulate PKA activity by controlling cAMP levels via the Ras-cAMP pathway and that for those stresses related to oxidative stress, this cross-talk is probably mediated via the Rho1p-activated MAPK pathway.     

The control of morphogenesis in Saccharomyces cerevisiae by Elm1 kinase is responsive to RAS/cAMP pathway activity and tryptophan availability

Many fungi undergo a morphological transition to filamentous growth in response to limiting nutrient conditions. Constitutively elongated Saccharomyces cerevisiae mutants ( elm ) have been isolated; the ELM1 gene encodes a putative serine/threonine protein kinase. A novel allele, elm1-15 , has been isolated in an S288C-derived strain, which causes a pleiotropic phenotype, including media-specific growth effects, abnormal morphology and altered stress response, in cells that are auxotrophic for tryptophan. elm1-15 trp1 cells cannot use many nitrogen sources, are sensitive to amino acid analogues, have very low general amino acid permease activity and do not accumulate trehalose. In contrast, haploid elm1-15 TRP1 cells grow well in budding form on all media, are stress resistant and overaccumulate trehalose. Several lines of evidence suggest that Elm1 acts on functions related to the RAS /cAMP pathway. Overexpression of Elm1 partially rescues the ts phenotype of cdc25 and cyr1 mutants. Deletion of ELM1 in low PKA activity mutants increased the severity of their phenotypes, and activation of Ras2 decreases the cell elongation phenotype of elm1 mutants. A 'signal integration' model for the complex relationship of Elm1 and the RAS/ cAMP pathway in controlling morphogenesis in response to nutrients is proposed.     

Dynamic control of yeast MAP kinase network by induced association and dissociation between the Ste50 scaffold and the Opy2 membrane anchor

Membrane localization of the Ste11 MAPKKK is essential for activation of both the filamentous growth/invasive growth (FG/IG) MAP kinase (MAPK) pathway and the SHO1 branch of the osmoregulatory HOG MAPK pathway, and is mediated by binding of the Ste50 scaffold protein to the Opy2 membrane anchor. We found that Opy2 has two major (CR-A and CR-B), and one minor (CR-D), binding sites for Ste50. CR-A binds Ste50 constitutively and can transmit signals to both the Hog1 and Fus3/Kss1 MAPKs. CR-B, in contrast, binds Ste50 only when Opy2 is phosphorylated by Yck1/Yck2 under glucose-rich conditions and transmits the signal preferentially to the Hog1 MAPK. Ste50 phosphorylation by activated Hog1/Fus3/Kss1 MAPKs downregulates the HOG MAPK pathway by dissociating Ste50 from Opy2. Furthermore, Ste50 phosphorylation, together with MAPK-specific protein phosphatases, reduces the basal activity of the HOG and the mating MAPK pathways. Thus, dynamic regulation of Ste50-Opy2 interaction fine-tunes the MAPK signaling network.     

Glycosylation defects activate filamentous growth Kss1 MAPK and inhibit osmoregulatory Hog1 MAPK

The yeast filamentous growth (FG) MAP kinase (MAPK) pathway is activated under poor nutritional conditions. We found that the FG‐specific Kss1 MAPK is activated by a combination of an O‐glycosylation defect caused by disruption of the gene encoding the protein O‐mannosyltransferase Pmt4, and an N‐glycosylation defect induced by tunicamycin. The O‐glycosylated membrane proteins Msb2 and Opy2 are both essential for activating the FG MAPK pathway, but only defective glycosylation of Msb2 activates the FG MAPK pathway. Although the osmoregulatory HOG (high osmolarity glycerol) MAPK pathway and the FG MAPK pathway share almost the entire upstream signalling machinery, osmostress activates only the HOG‐specific Hog1 MAPK. Conversely, we now show that glycosylation defects activate only Kss1, while activated Kss1 and the Ptp2 tyrosine phosphatase inhibit Hog1. In the absence of Kss1 or Ptp2, however, glycosylation defects activate Hog1. When Hog1 is activated by glycosylation defects in ptp2 mutant, Kss1 activation is suppressed by Hog1. Thus, the reciprocal inhibitory loop between Kss1 and Hog1 allows only one or the other of these MAPKs to be stably activated under various stress conditions.