The biosynthesis of many secreted peptides involves limited endoproteolysis of larger, usually inactive, precursors to release the bioactive fragments. A family of serine endoproteases (proprotein convertases) that perform this processing function within the secretory pathway has been defined (1-3). Two members, proprotein convertases 1 and 2 (PC1 and PC2), which show expression confined to the regulated secretory pathway of neuroendocrine tissue, have been particularly closely studied. Although ex vivo experiments indicate that their substrate specificities overlap, in vivo they appear We have previously described the only reported case of human proprotein convertase 1 (PC1) deficiency, in a female (Subject A) with obesity, hypogonadism, hypoadrenalism, and reactive hypoglycemia. We now report the second case of human PC1 deficiency (Subject B), also due to compound heterozygosity for novel missense and nonsense mutations. While both subjects shared the phenotypes of obesity, hypoadrenalism, reactive hypoglycemia, and elevated circulating levels of certain prohormones, the clinical presentation of Subject B was dominated by severe refractory neonatal diarrhea, malabsorptive in type. Subsequent investigation of Subject A revealed marked small-intestinal absorptive dysfunction, which was not previously clinically suspected. We postulate that PC1, presumably in the enteroendocrine cells, is essential for the normal absorptive function of the human small intestine. The differences in the nature and severity of presentation between the two cases cannot readily be explained on the basis of allelic heterogeneity, as the nonsense and missense mutations from both subjects had comparably severe effects on the catalytic activity of PC1. Despite Subject A's negligible PC1 activity, some mature ACTH and glucagonlike peptide 1 7-36amide were detectable in her plasma, suggesting that the production of these hormones, at least in humans, does not have an absolute dependence on PC1. The presence of severe obesity and the absence of growth retardation in both subjects contrast markedly with the phenotype of mice lacking PC1 and suggest that the precise physiological repertoire of this enzyme may vary between mammalian species.
Previous results from our laboratory have demonstrated that equine infectious anemia virus displays structural variations in its surface glycoproteins and RNA genome during passage and chronic infections in experimentally infected Shetland ponies (Montelaro et al., J. Biol. Chem. 259:10539-10544, 1984; Payne et al., J. Gen. Virol. 65:1395-1399, 1984). The present study was undertaken to obtain an antigenic and biochemical characterization of equine infectious anemia virus isolates recovered from an experimentally infected pony during sequential disease episodes, each separated by intervals of only 4 to 8 weeks. The virus isolates could be distinguished antigenically by neutralization assays with serum from the infected pony and by Western blot analysis with a monoclonal antibody against the major surface glycoprotein gp90, thus demonstrating that novel antigenic variants of equine infectious anemia virus predominate during each clinical episode. The respective virion glycoproteins displayed different electrophoretic mobilities on sodium dodecyl sulfate-polyacrylamide gels, indicating structural variation. Tryptic peptide and glycopeptide maps of the viral proteins of each virus isolate revealed biochemical alterations involving amino acid sequence and glycosylation patterns in the virion surface glycoproteins gp90 and gp45. In contrast, no structural variation was observed in the internal viral proteins pp15, p26, and p9 from any of the four virus isolates. Oligonucleotide mapping experiments revealed similar but unique RNase T1-resistant oligonucleotide fingerprints of the RNA genomes of each of the virus isolates. Localization of altered oligonucleotides for one virus isolate placed two of three unique oligonucleotides within the predicted env gene region of the genome, perhaps correlating with the structural variation observed in the envelope glycoproteins. Thus these results support the concept that equine infectious anemia virus is indeed capable of relatively rapid genomic variations during replication, some of which result in altered glycoprotein structures and antigenic variants which are responsible for the unique periodic disease nature observed in persistently infected animals. The findings of envelope specific differences in isolates of visna virus and of human T-cell lymphotropic virus III (acquired immune deficiency syndrome-related virus) suggest that this variation may be a common characteristic of the subfamily Lentivirinae.
The biosynthesis of many secreted peptides involves limited endoproteolysis of larger, usually inactive, precursors to release the bioactive fragments. A family of serine endoproteases (proprotein convertases) that perform this processing function within the secretory pathway has been defined (1-3). Two members, proprotein convertases 1 and 2 (PC1 and PC2), which show expression confined to the regulated secretory pathway of neuroendocrine tissue, have been particularly closely studied. Although ex vivo experiments indicate that their substrate specificities overlap, in vivo they appear We have previously described the only reported case of human proprotein convertase 1 (PC1) deficiency, in a female (Subject A) with obesity, hypogonadism, hypoadrenalism, and reactive hypoglycemia. We now report the second case of human PC1 deficiency (Subject B), also due to compound heterozygosity for novel missense and nonsense mutations. While both subjects shared the phenotypes of obesity, hypoadrenalism, reactive hypoglycemia, and elevated circulating levels of certain prohormones, the clinical presentation of Subject B was dominated by severe refractory neonatal diarrhea, malabsorptive in type. Subsequent investigation of Subject A revealed marked small-intestinal absorptive dysfunction, which was not previously clinically suspected. We postulate that PC1, presumably in the enteroendocrine cells, is essential for the normal absorptive function of the human small intestine. The differences in the nature and severity of presentation between the two cases cannot readily be explained on the basis of allelic heterogeneity, as the nonsense and missense mutations from both subjects had comparably severe effects on the catalytic activity of PC1. Despite Subject A's negligible PC1 activity, some mature ACTH and glucagonlike peptide 1 7-36amide were detectable in her plasma, suggesting that the production of these hormones, at least in humans, does not have an absolute dependence on PC1. The presence of severe obesity and the absence of growth retardation in both subjects contrast markedly with the phenotype of mice lacking PC1 and suggest that the precise physiological repertoire of this enzyme may vary between mammalian species.
Three ponies were inoculated with plasma containing 10(4.8) TCID50 of equine infectious anemia virus (EIAV) and observed for 165 to 440 days. Each pony developed a febrile response within 3 weeks of infection during which a plasma viremia greater than or equal to 10(3.5) TCID50/ml was observed. Analyses of four isolates from sequential febrile episodes in a single pony were conducted by two-dimensional tryptic peptide maps and with monoclonal antibodies in immunoblots. Structural and antigenic alterations were observed in the envelope glycoproteins gp90 and gp45, with greatest variation in gp90. Specific IgG to EIAV gp90, gp45, and p26 of homologous and heterologous isolates was detectable by immunoblots within one month after infection although IgG levels to gp45 at this time were relatively low. The group-specific determinants of gp90 and gp45 were more antigenic than those of p26; however, binding of IgG to these determinants did not correlate with neutralization of EIAV as assayed in fetal equine kidney cells. Neutralizing antibodies were first detectable within two months of infection and only neutralized viruses isolated prior to serum collection. Neutralizing activity of sera collected later in the infection was broadly reactive regardless of the number of clinical episodes the donor had suffered.
A neutralization escape mutant (A/1 E) of equine infectious anemia virus was isolated after 13 passages in cell culture in the presence of serum containing antibodies to type- and group-specific determinants of EIAV envelope glycoproteins. Loss of neutralization by the selecting serum correlated with loss of two epitopes in the major envelope glycoprotein gp90 of A/1 E which were present in a parallel variant isolated from a persistently infected pony.
Monoclonal antibodies (MAbs) against two major structural proteins of the cell-adapted Mebus strain of bovine coronavirus (BCV-L9) were produced and characterized. Seven MAbs reacted with the peplomeric glycoprotein, gp 100/S, while three MAbs reacted with the nucleoprotein p53/N in Western blot analysis of BCV polypeptides. MAbs to gp 100/S reacted with discontinuous epitopes of gp 100/S in Westerns under mild but not under standard denaturing conditions. In contrast, MAbs to p53/N reacted in both types of Westerns, and those epitopes were thus continuous. MAbs to p53/N failed to neutralize BCV infectivity, while 4 MAbs to gp 100/S neutralized BCV effectively. Cross reactivity of MAbs to gp 100/S specified by five virulent wild-type strains and two high passage, cell-culture-adapted strains in mildly denaturing Westerns and neutralization assays indicated that two epitopes were conserved in all seven strains, while two epitopes of the avirulent strains were not detected in the wild-type strains. Non-neutralizing MAbs of gp 100/S reacted with all seven strains in Westerns with the exception of one MAb that was specific for the highly cell-adapted strain BCV-L9.
Exploration with high throughput leaf metabolomics along with functional genomics in wild tomato unreveal potential role of steroidal glyco-alkaloids and phenylpropanoids during early blight resistance. Alternaria solani severely affects tomato (Solanum lycopersicum L.) yield causing early blight (EB) disease in tropical environment. Wild relative, Solanum arcanum Peralta could be a potential source of EB resistance; however, its underlying molecular mechanism largely remains unexplored. Hence, non-targeted metabolomics was applied on resistant and susceptible S. arcanum accessions upon A. solani inoculation to unravel metabolic dynamics during different stages of disease progression. Total 2047 potential metabolite peaks (mass signals) were detected of which 681 and 684 metabolites revealed significant modulation and clear differentiation in resistant and susceptible accessions, respectively. Majority of the EB-triggered metabolic changes were active from steroidal glycol-alkaloid (SGA), lignin and flavonoid biosynthetic pathways. Further, biochemical and gene expression analyses of key enzymes from these pathways positively correlated with phenotypic variation in the S. arcanum accessions indicating their potential role in EB. Additionally, transcription factors regulating lignin biosynthesis were also up-regulated in resistant plants and electrophoretic mobility shift assay revealed sequence-specific binding of rSaWRKY1 with MYB20 promoter. Moreover, transcript accumulation of key genes from phenylpropanoid and SGA pathways along with WRKY and MYB in WRKY1 transgenic tomato lines supported above findings. Overall, this study highlights vital roles of SGAs as phytoalexins and phenylpropanoids along with lignin accumulation unrevealing possible mechanistic basis of EB resistance in wild tomato.
The phenotype of a recently-described mutant (OV6), conditionally defective in chromosome partitioning and septal positioning, was originally thought to be due to a new gene (parD) mapping at 88.4 min. We have now shown that, in addition to the parD mutation, OV6 carries a gyrAam mutation and that this mutation is probably responsible for the gross phenotype of the mutant. We have cloned the gyrA gene, identified the GyrA protein, sequenced the gyrA gene and flanking genes, cloned and sequenced the gyrAam mutation, and identified its truncated product. In addition, we have identified the transcriptional start point of the gyrA gene. The E. coli GyrA protein has extensive homologies with Gyrase proteins of other organisms and weak sequence homologies with some eukaryotic cytoskeletal proteins.
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