Isolation and characterization of a new gene, sre , which encodes a GATA-type regulatory protein that controls iron transport in Neurospora crassa

Multiple GATA factors – regulatory proteins with consensus zinc finger motifs that bind to DNA elements containing a GATA core sequence – exist in the filamentous fungus Neurospora crassa. One GATA factor, NIT2, controls nitrogen metabolism, whereas two others, WC-1 and WC-2, regulate genes responsive to blue light induction. A gene encoding a new GATA factor, named SRE, was isolated from Neurospora using a PCR-mediated method. Sequence analysis of the new GATA factor gene revealed an ORF specifying 587 amino acids, which is interrupted by two small introns. Unlike all previously known Neurospora GATA factors, which possess a single zinc-finger DNA-binding motif, SRE contains two GATA-type zinc fingers. The deduced amino acid sequence of SRE shows significant similarity to URBS1 of Ustilago and SREP of Penicillium. A loss-of-function mutation was created by the RIP procedure. Analysis of sre ⁺ and sre ⁻ strains revealed that SRE acts as a negative regulator of iron uptake in Neurospora by controlling the synthesis of siderophores. Siderophore biosynthesis is repressed by high iron concentrations in the wild-type strain but not in sre ⁻ mutant cells. The sre promoter contains a number of GATA sequences; however, expression of sre mRNA occurs in a constitutive fashion and is not regulated by the concentration of iron available to the cells. Received: 20 January 1998 / Accepted: 23 April 1998     

Functional analysis of the two zinc fingers of SRE, a GATA-type factor that negatively regulates siderophore synthesis in Neurospora crassa

Multiple GATA factors, zinc finger DNA binding proteins that recognize consensus GATA elements, exist in Neurospora crassa. One of them, SRE, is involved in controlling the iron metabolic pathway of N. crassa. In N. crassa, iron transport is mediated by a number of small cyclic peptides, known as siderophores. The siderophore synthesis pathway is negatively regulated by SRE; a loss-of-function sre mutant strain showed partial constitutive synthesis of siderophore. In the research presented here, the negative function of SRE was further confirmed by a heterokaryon test and by gene complementation. SRE was expressed as a GST fusion protein. In vitro EMSA revealed that SRE binds specifically to DNA molecules containing GATA sequence elements. Autoregulation of sre gene expression appears possible because the sre gene promoter itself contains GATA sequences. Mutations were introduced into sre that lead to amino acid substitutions in each of the zinc fingers that will disrupt their function. In vitro EMSA revealed that both N-terminal and C-terminal zinc fingers of SRE are involved in DNA binding. This feature is different from that found with the vertebrate two zinc finger GATA factors. Invivo tests, accomplished by transforming the mutant sre genes into sre rip mutant, showed that SRE with mutations in either or both zinc fingers still maintained its function under low-iron conditions. In contrast, these mutant SRE proteins fail to function under high-iron conditions. Our results predict the presence of other positive or negative regulators of the siderophore synthetic pathway.     

Factor X activator from Vipera lebetina snake venom,molecular characterization and substrate specificity

Our studies of the venom from the Levantine viper Vipera lebetina have demonstrated the existence of both coagulants and anticoagulants of the hemostatic system in the same venom. We showed that V. lebetina venom contains factor X activator (VLFXA) and factor V activator, fibrinolytic enzymes. VLFXA was separated by gel filtration on Sephadex G-100 superfine and ion exchange chromatography on CM-cellulose and on TSK-DEAE (for HPLC) columns. VLFXA is a glycoprotein composed of a heavy chain (57.5 kDa) and two light chains (17.4 kDa and 14.5 kDa) linked by disulfide bonds. VLFXA has multiple molecular forms distinguished by their isoelectric points. The differences in their pI values may be caused by dissimilarities in the respective charged carbohydrate content or in the primary sequence of amino acids. We synthesized 6–9 amino acid residues containing peptides according to physiological cleavage regions of human factor X and human factor IX. The peptides (Asn-Asn-Leu-Thr-Arg-Ile-Val-Gly-Gly – factor X fragment, and Asn-Asp-Phe-Thr-Arg-Val-Val-Gly-Gly – factor IX fragment) were used as substrates for direct assay of VLFXA. Cleavage products of peptide hydrolysis and the molecular masses of cleavage products of human factor X were determined by MALDI-TOF MS. The MALDI-TOF MS was highly efficient for the recovery and identification of peptides released by VLFXA hydrolysis. We can conclude that VLFXA cleaves the Arg⁵²-Ile⁵³ bond in the heavy chain of human factor X and the Arg²²⁶-Val²²⁷ bond in human factor IX precursor. VLFXA could not activate prothrombin nor had any effect on fibrinogen, and it had no arginine esterase activity toward benzoylarginine ethyl ester.     

Purification and characterization of uricase,a nitrogen-regulated enzyme,from Neurospora crassa

Uricase, a purine catabolic enzyme, is controlled by induction and by nitrogen catabolite repression in Neurospora. Uricase was purified nearly 1000-fold to homogeneity. Only a single protein band could be detected in analytical gels of the pure enzyme, and the protein band in each case corresponded exactly to the position of in situ staining for enzyme activity. The molecular weight of native uricase was estimated to be 123,000 ± 7000. The enzyme is a tetramer composed of identical or similar-sized subunits. The K_m value of uricase for uric acid was estimated to be 4.2 × 10^?5, m. Oxonic acid was shown to be a competitive inhibitor of uricase, with a K_i value of 6.7 × 10^?7, m. Uricase is a stable enzyme and is not subject to feedback inhibition by ammonia, glutamate, or glutamine in Neurospora. The regulation of uricase appears to occur primarily at the biosynthesis level. Uricase appears to be a metalloenzyme with no essential sulfhydryl groups.     

The basidiomycetous mushroom Lentinula edodes white collar-2 homolog PHRB,a partner of putative blue-light photoreceptor PHRA,binds to a specific site in the promoter region of the L. edodes tyrosinase gene

We isolated a cDNA homolog of Neurospora crassa wc-2 from the basidiomycetous mushroom Lentinula edodes and termed it phrB cDNA. The deduced PHRB (313 amino acid residues) contained a PAS domain and a zinc-finger motif. Random binding-site selection analysis of the PHRB produced in Escherichia coli revealed that it bound to a 7-bp sequence with the consensus sequence 5′GATA/TTG/T/AC3′. Electrophoretic mobility-shift assay showed that it also bound to the consensus sequence 5′GATATTC3′ in the promoter region of the L. edodes tyrosinase gene (Le.tyr). In vitro GST-pulldown immunoblot analysis disclosed that PHRB interacts with a putative blue-light photoreceptor of L. edodes (PHRA), the homolog of N. crassa WC-1, through the PAS B- and/or PAS C domain of PHRA. The expression of phrB and Le.tyr genes in pre-primordial mycelia of L. edodes is induced by light exposure, suggesting that PHRB can regulate the expression of the Le.tyr gene in a light-dependent manner.     

模式生物粗糙脉孢菌光受体的研究进展

粗糙脉孢菌是一种重要的模式生物,在遗传调节机制、昼夜节律运行以及真菌光应答反应研究中起重要的作用.本综述主要介绍粗糙脉孢菌光受体WC-1和VVD的结构与功能,以及它们参与调节昼夜节律和光适应机制方面的研究进展.在该真菌中,所有已知的光应答反应都受蓝光调节,由光受体WC-1和VVD介导.WC-1是该真菌的转录因子,介导最初的光反应过程,产生VVD等多种光反应蛋白,而VVD通过负反馈机制抑制WC-1的转录作用.此外,vvd基因已经用于构建在哺乳动物中表达的光调节基因元件.