Role of cysteine residues and disulfide bonds in the activity of a legume root nodule-specific, cysteine-rich peptide

The root nodules of certain legumes including Medicago truncatula produce >300 different nodule-specific cysteine-rich (NCR) peptides. Medicago NCR antimicrobial peptides (AMPs) mediate the differentiation of the bacterium, Sinorhizobium meliloti into a nitrogen-fixing bacteroid within the legume root nodules. In vitro, NCR AMPs such as NCR247 induced bacteroid features and exhibited antimicrobial activity against S. meliloti. The bacterial BacA protein is critical to prevent S. meliloti from being hypersensitive toward NCR AMPs. NCR AMPs are cationic and have conserved cysteine residues, which form disulfide (S-S) bridges. However, the natural configuration of NCR AMP S-S bridges and the role of these in the activity of the peptide are unknown. In this study, we found that either cysteine replacements or S-S bond modifications influenced the activity of NCR247 against S. meliloti. Specifically, either substitution of cysteines for serines, changing the S-S bridges from cysteines 1-2, 3-4 to 1-3, 2-4 or oxidation of NCR247 lowered its activity against S. meliloti. We also determined that BacA specifically protected S. meliloti against oxidized NCR247. Due to the large number of different NCRs synthesized by legume root nodules and the importance of bacterial BacA proteins for prolonged host infections, these findings have important implications for analyzing the function of these novel peptides and the protective role of BacA in the bacterial response toward these peptides.     

Novel paralogous gene families with potential function in legume nodules and seeds

Within the plant kingdom, legumes are unusual in their ability to form nitrogen-fixing nodules in symbiosis with certain bacteria in the family Rhizobiaceae (rhizhobia). Genes that are required for signaling between plant and symbiont, and for the development and maintenance of the nodule, were either created de novo or adopted from other plant pathways. Only in recent years have genome-scale sequence data from legumes made it possible to identify large, novel families of genes probably evolved to function in nodulation. Members of these novel families are expressed in seeds or nodules, and are homologous to defense-related proteins. Perhaps the most striking example is a large family (of more than 340 members) of cysteine cluster proteins that have homology to plant defensins.     

The involvement of Medicago truncatula non-specific lipid transfer protein N5 in the control of rhizobial infection

Cysteine-rich proteins seem to play important regulatory roles in Medicago truncatula/Sinorhizobium meliloti symbiosis. In particular, a large family of nodule-specific cysteine-rich (NCR) peptides is crucial for the differentiation of nitrogen-fixing bacteroids. The Medicago truncatula N5 protein (MtN5) is currently the only reported non-specific lipid transfer protein necessary for successful rhizobial symbiosis; in addition, MtN5 shares several characteristics with NCR peptides: a small size, a conserved cysteine-rich motif, an N-terminal signal peptide for secretion and antimicrobial activity. Unlike NCR peptides, MtN5 expression is not restricted to the root nodules and is induced during the early phases of symbiosis in root hairs and nodule primordia. Recently, MtN5 was determined to be involved in the regulation of root tissue invasion; while, it was dispensable for nodule primordia formation. Here, we discuss the hypothesis that MtN5 participates in linking the progression of bacterial invasion with restricting the competence of root hairs for infection.     

Trypanosoma cruzi: a gene family encoding chitin-binding-like proteins is posttranscriptionally regulated during metacyclogenesis.

The development of the representation of differential expression method has lead to the cloning of Trypanosoma cruzi stage-specific genes. We used this method to characterize a multicopy gene family differentially expressed during metacyclogenesis. The genomic and cDNA clones sequenced encoded three short cysteine-rich polypeptides, of two types, with predicted molecular masses of 7.1, 10.4, and 10.8 kDa. We searched GenBank for similar sequences and found that the sequences of these clones were similar to that encoding the wheat germ agglutinin protein. The region of similarity corresponds to the chitin-binding domain, with eight similarly positioned half-cysteines and conserved aromatic residues involved in chitin recognition. Multiple copies of the genes of this family are present on a high- molecular-mass chromosome. We studied the expression of genes of this family during metacyclogenesis by determining messenger RNA (mRNA) levels. The mRNAs for the members of this gene family were present in the total RNA fraction but were mobilized to the polysomal fraction of adhered (differentiating) epimastigotes during metacyclogenesis, with a peak of accumulation at 24 of differentiation. Polyclonal antisera were raised against a recombinant protein and a synthetic peptide. The specific sera obtained detected 7- and 11-kDa proteins in T. cruzi total protein extracts. The 11-kDa protein was present in similar amounts in the various cell populations, whereas the 7-kDa protein displayed differential synthesis during metacyclogenesis, with maximal levels in 24-h-adhered (differentiating) epimastigotes.     

银鲫精巢特异的Ly-6/uPAR相关蛋白的分子克隆及其特征分析

Ly-6/uPAR基因超家族(Ly-6 SF)成员广泛地存在于后生动物中, 开展该家族相关功能基因研究具有重要的意义。研究从银鲫(Carassius auratus gibelio)中鉴定到一个该家族新成员, cDNA全长为570 bp, 其中开放阅读框长度为300 bp, 编码99个氨基酸, 生物软件预测该蛋白含有一个LU结构域, 不含GPI锚信号序列, N端含有信号肽, 表明其可能为Ly-6基因超家族中分泌型蛋白。组织表达分析显示, 该基因只在银鲫精巢中特异表达, 且又是Ly-6基因超家族中一员, 因此将其命名为银鲫精巢特异的Ly-6/uPAR相关蛋白(Carassius auratus gibelio testis-specific Ly-6/uPAR related protein, 简称CagTslurp)。原位杂交结果显示, 该基因在银鲫精巢的精原细胞, 初级精母细胞以及次级精母细胞中表达, 精子细胞中存在少量的表达, 而在体细胞中不表达。这种精巢特异的表达模式, 暗示CagTslurp在银鲫精子发生中可能发挥了作用。       

Symbiotic and nonsymbiotic hemoglobin genes of Casuarina glauca.

Casuarina glauca has a gene encoding hemoglobin (cashb-nonsym). This gene is expressed in a number of plant tissues. Casuarina also has a second family of hemoglobin genes (cashb-sym) expressed at a high level in the nodules that Casuarina forms in a nitrogen-fixing symbiosis with the actinomycete Frankia. Both the nonsymbiotic and symbiotic genes retained their specific patterns of expression when introduced into the legume Lotus corniculatus. We interpret this finding to mean that the controls of expression of the symbiotic gene in Casuarina must be similar to the controls of expression of the leghemoglobin genes that operate in nodules formed during the interaction between rhizobia and legumes. Deletion analyses of the promoters of the Casuarina symbiotic genes delineated a region that contains nodulin motifs identified in legumes; this region is critical for the controlled expression of the Casuarina gene. The finding that the nonsymbiotic Casuarina gene is also correctly expressed in L. corniculatus suggests to us that a comparable non-symbiotic hemoglobin gene will be found in legume species.     

GASA4, one of the 14-member Arabidopsis GASA family of small polypeptides, regulates flowering and seed development

Members of the plant-specific gibberellic acid-stimulated Arabidopsis (GASA) gene family play roles in hormone response, defense and development. We have identified six new Arabidopsis GASA genes, bringing the total number of family members to 14. Here we show that these genes all encode small polypeptides that share the common structural features of an N-terminal putative signal sequence, a highly divergent intermediate region and a conserved 60 amino acid C-terminal domain containing 12 conserved cysteine residues. Analysis of promoter::GUS (beta-glucuronidase) transgenic plants representing six different GASA loci reveals that the promoters are activated in a variety of stage- and tissue-specific patterns during development, indicating that the GASA genes are involved in diverse processes. Characterization of GASA4 shows that the promoter is active in the shoot apex region, developing flowers and developing embryos. Phenotypic analyses of GASA4 loss-of-function and gain-of-function lines indicate that GASA4 regulates floral meristem identity and also positively affects both seed size and total seed yield.     

Identification and characterization of a novel peritrophic matrix protein, Ae-Aper50, and the microvillar membrane protein, AEG12, from the mosquito, Aedes aegypti

Immuno-screening of an adult Aedes aegypti midgut cDNA expression library with anti-peritrophic matrix antibodies identified cDNAs encoding a novel peritrophic matrix protein, termed Ae. aegypti Adult Peritrophin 50 (Ae-Aper50), and the epithelial cell-surface membrane protein, AEG12. Both genes are expressed exclusively in the midguts of adult female mosquitoes and their expression is strongly induced by blood feeding. Ae-Aper50 has a predicted secretory signal peptide and five chitin-binding domains with intervening mucin-like domains. Localization of Ae-Aper50 to the peritrophic matrix was demonstrated by immuno-electron microscopy. Recombinant Ae-Aper50 expressed in baculovirus-infected insect cells binds chitin in vitro. Site-directed mutagenesis was used to study the role that cysteine residues from a single chitin-binding domain play in the binding to a chitin substrate. Most of the cysteine residues proved to be critical for binding. AEG12 has a putative secretory signal peptide at the amino-terminus and a putative glycosyl-phosphatidylinositol (GPI) anchor signal at its carboxyl-terminus and the protein was localized by immuno-electron microscopy to the midgut epithelial cell microvilli.     

The ubiquitin-specific protease family from Arabidopsis. AtUBP1 and 2 are required for the resistance to the amino acid analog canavanine

Ubiquitin-specific proteases (UBPs) are a family of unique hydrolases that specifically remove polypeptides covalently linked via peptide or isopeptide bonds to the C-terminal glycine of ubiquitin. UBPs help regulate the ubiquitin/26S proteolytic pathway by generating free ubiquitin monomers from their initial translational products, recycling ubiquitins during the breakdown of ubiquitin-protein conjugates, and/or by removing ubiquitin from specific targets and thus presumably preventing target degradation. Here, we describe a family of 27 UBP genes from Arabidopsis that contain both the conserved cysteine (Cys) and histidine boxes essential for catalysis. They can be clustered into 14 subfamilies based on sequence similarity, genomic organization, and alignments with their closest relatives from other organisms, with seven subfamilies having two or more members. Recombinant AtUBP2 functions as a bona fide UBP: It can release polypeptides attached to ubiquitins via either alpha- or epsilon-amino linkages by an activity that requires the predicted active-site Cys within the Cys box. From the analysis of T-DNA insertion mutants, we demonstrate that the AtUBP1 and 2 subfamily helps confer resistance to the arginine analog canavanine. This phenotype suggests that the AtUBP1 and 2 enzymes are needed for abnormal protein turnover in Arabidopsis.     

Identification of extracytoplasmic proteins in Bradyrhizobium japonicum using phage display

A novel gene bank of Bradyrhizobium japonicum USDA110spc4 was constructed using pG3DSS, a phagemid vector designed for detecting genes encoding secreted proteins. In this phagemid, the phage protein III lacks its indigenous signal peptide required for protein secretion, thus recombinant fusion proteins are displayed on the phage surface only if a functional signal peptide is provided by an inserted DNA fragment. In addition, the N-terminal half of protein III has been replaced by a short linker region (the E-tag) that is recognized by a monoclonal antibody, which enables isolation of phages displaying a fusion protein. The expression library described here, therefore, provides a powerful means to affinity select for B. japonicum genes encoding extracytoplasmic proteins. In total, 182 DNA sequences were analyzed, among which 132 different putative extracytoplasmic proteins could be identified. The function of most proteins could be predicted and support an extracytoplasmic localization. In addition, genes encoding novel extracytoplasmic proteins were found. In particular, a novel family of small proteins has been identified that is characterized by a conserved pattern of four cysteine residues.