The chitinase C gene PsChiC from Pseudomonas sp. and its synergistic effects on larvicidal activity

Pseudomonas sp. strain TXG6-1, a chitinolytic gram-negative bacterium, was isolated from a vegetable field in Taixing city, Jiangsu Province, China. In this study, a Pseudomonas chitinase C gene (PsChiC) was isolated from the chromosomal DNA of this bacterium using a pair of specific primers. The PsChiC gene consisted of an open reading frame of 1443 nucleotides and encoded 480 amino acid residues with a calculated molecular mass of 51.66 kDa. The deduced PsChiC amino acid sequence lacked a signal sequence and consisted of a glycoside hydrolase family 18 catalytic domain responsible for chitinase activity, a fibronectin type III-like domain (FLD) and a C-terminal chitin-binding domain (ChBD). The amino acid sequence of PsChiCshowed high sequence homology (> 95%) with chitinase C from Serratia marcescens. SDS-PAGE showed that the molecular mass of chitinase PsChiC was 52 kDa. Chitinase assays revealed that the chitobiosidase and endochitinase activities of PsChiCwere 51.6- and 84.1-fold higher than those of pET30a, respectively. Although PsChiC showed little insecticidal activity towards Spodoptera litura larvae, an insecticidal assay indicated that PsChiC increased the insecticidal toxicity of SpltNPV by 1.78-fold at 192 h and hastened death. These results suggest that PsChiC from Pseudomonas sp. could be useful in improving the pathogenicity of baculoviruses.     

Bioinformatic comparison of structures and homology-models of matrix metalloproteinases

The entire family of human matrix metalloproteinases (MMPs) was investigated using phylogenetic trees and homology modeling. The phylogenetic analysis indicates that individual domains of each MMP have evolved in a correlated manner. Despite their high sequence similarity, the phylogenetic tree of the catalytic domains already allows functional (e.g., linked to regulation and substrate recognition) homologies between different MMPs to be identified. The same pattern of functional homologies is confirmed by the phylogenetic analysis of the mature proteins. Structural models were built for the catalytic domains of the entire MMP family, for twelve hemopexin domains and for twelve mature proteins. The surface properties around the active site cleft of the modeled and experimental structures are quite conserved, whereas the hemopexin domains are more differentiated, possibly indicating a role in determining substrate specificity. The analysis of mature MMPs showed that the area of the interface between the catalytic and hemopexin domains is essentially conserved, with both hydrophobic and hydrophilic amino acids at the interface. The absence of specific conserved interdomain contacts suggests that the interface is tolerant to amino acid replacements, and that there may be a certain degree of plasticity with respect to the reciprocal orientation of the two domains.     

Molecular analysis of the major cellulase (CelV) of Erwinia carotovora: evidence for an evolutionary “mix-and-match” of enzyme domains

The structural gene for the major cellulase of Erwinia carotovora subspecies carotovora (Ecc) was isolated and expressed in Escherichia coli. Sequencing of the gene (celV) revealed a typical signal sequence and two functional domains in the enzyme; a catalytic domain linked by a short proline/threonine-rich linker to a cellulose-binding domain (CBD). The deduced amino acid sequence of the catalytic domain showed homology with cellulases of Family A, including enzymes from Bacillus spp. and Erwinia chrysanthemi CelZ, whereas the CBD showed homology with cellulases from several diverse families, supporting a “mix-and-match” hypothesis for evolution of this domain. Analysis of the substrate specificity of CelV showed it to be an endoglucanase with some exoglucanase activity. The pH optimum is about 7.0 and the temperature optimum about 42°C. CelV is secreted by Ecc and by the taxonomically related Erwinia carotovora subspecies atroseptica (Eca) but not by E. coli. Overproduction of the enzyme from multicopy plasmids in Ecc appears to overload the secretory mechanism.     

Identification and sequence analysis of a rap gene from the true slime mold Physarum polycephalum

A member of the ras gene superfamily, belonging to the rap family and designated Pprap1, was isolated from a cDNA library from the true slime mold Physarum polycephalum by plaque hybridization in combination with 5′-RACE. The assembled nucleotide sequence of Pprap1 (1062 bp) has an open reading frame coding for a protein of 188 amino acids of a calculated M_r of 21035. This protein exhibits: (i) a highly conserved GTP binding domain containing a putative effector domain, with the threonine-for-glutamine substitution characteristic of rap proteins, (ii) a hypervariable domain, and (iii) the CAAX motif. Analysis of the C-terminal amino acid sequence of Pprap1 shows that it presumably undergoes geranylgeranylation but is not palmitoylated; however, it contains a lysine-rich domain which might serve as the second membrane localization signal. Pprap1 exhibits significantly high amino acid homology within the GTP binding domain with its homologues: Ddrap1 from Dictyostelium discoideum (92%) and human Rap1A (83%), and relatively low homology (59%) with the Saccharomyces cerevisiae homologue, RSR1. It has also 59% and 61% homology with the P. polycephalum Ppras1 and Ppras2 proteins, respectively. This gene is the third member of the ras gene superfamily identified in P. polycephalum so far.     

A gene expression fingerprint of C. elegans embryonic motor neurons

Background

ADP-ribosylation is an enzyme-catalyzed posttranslational protein modification in which mono(ADP-ribosyl)transferases (mARTs) and poly(ADP-ribosyl)transferases (pARTs) transfer the ADP-ribose moiety from NAD onto specific amino acid side chains and/or ADP-ribose units on target proteins.

Results

Using a combination of database search tools we identified the genes encoding recognizable pART domains in the public genome databases. In humans, the pART family encompasses 17 members. For 16 of these genes, an orthologue exists also in the mouse, rat, and pufferfish. Based on the degree of amino acid sequence similarity in the catalytic domain, conserved intron positions, and fused protein domains, pARTs can be divided into five major subgroups. All six members of groups 1 and 2 contain the H-Y-E trias of amino acid residues found also in the active sites of Diphtheria toxin and Pseudomonas exotoxin A, while the eleven members of groups 3 - 5 carry variations of this motif. The pART catalytic domain is found associated in Lego-like fashion with a variety of domains, including nucleic acid-binding, protein-protein interaction, and ubiquitylation domains. Some of these domain associations appear to be very ancient since they are observed also in insects, fungi, amoebae, and plants. The recently completed genome of the pufferfish T. nigroviridis contains recognizable orthologues for all pARTs except for pART7. The nearly completed albeit still fragmentary chicken genome contains recognizable orthologues for twelve pARTs. Simpler eucaryotes generally contain fewer pARTs: two in the fly D. melanogaster, three each in the mosquito A. gambiae, the nematode C. elegans, and the ascomycete microfungus G. zeae, six in the amoeba E. histolytica, nine in the slime mold D. discoideum, and ten in the cress plant A. thaliana. GenBank contains two pART homologues from the large double stranded DNA viruses Chilo iridescent virus and Bacteriophage Aeh1 and only a single entry (from V. cholerae) showing recognizable homology to the pART-like catalytic domains of Diphtheria toxin and Pseudomonas exotoxin A.

Conclusion

The pART family, which encompasses 17 members in the human and 16 members in the mouse, can be divided into five subgroups on the basis of sequence similarity, phylogeny, conserved intron positions, and patterns of genetically fused protein domains.     

Molecular and Biochemical Characterization of Two Xylanase-Encoding Genes from Cellulomonas pachnodae

Two xylanase-encoding genes, named xyn11A and xyn10B, were isolated from a genomic library of Cellulomonas pachnodae by expression in Escherichia coli. The deduced polypeptide, Xyn11A, consists of 335 amino acids with a calculated molecular mass of 34,383 Da. Different domains could be identified in the Xyn11A protein on the basis of homology searches. Xyn11A contains a catalytic domain belonging to family 11 glycosyl hydrolases and a C-terminal xylan binding domain, which are separated from the catalytic domain by a typical linker sequence. Binding studies with native Xyn11A and a truncated derivative of Xyn11A, lacking the putative binding domain, confirmed the function of the two domains. The second xylanase, designated Xyn10B, consists of 1,183 amino acids with a calculated molecular mass of 124,136 Da. Xyn10B also appears to be a modular protein, but typical linker sequences that separate the different domains were not identified. It comprises a N-terminal signal peptide followed by a stretch of amino acids that shows homology to thermostabilizing domains. Downstream of the latter domain, a catalytic domain specific for family 10 glycosyl hydrolases was identified. A truncated derivative of Xyn10B bound tightly to Avicel, which was in accordance with the identified cellulose binding domain at the C terminus of Xyn10B on the basis of homology. C. pachnodae, a (hemi)cellulolytic bacterium that was isolated from the hindgut of herbivorous Pachnoda marginata larvae, secretes at least two xylanases in the culture fluid. Although both Xyn11A and Xyn10B had the highest homology to xylanases from Cellulomonas fimi, distinct differences in the molecular organizations of the xylanases from the two Cellulomonas species were identified.     

Identification and characterization of novel mouse and human ADAM33s with potential metalloprotease activity

The ADAM family of membrane-anchored proteins has a unique domain structure, with each containing a disintegrin and metalloprotease (ADAM) domain. We have isolated mouse and human cDNAs encoding a novel member of the ADAM family. The mouse and human predicted proteins consisted of 797 and 813 amino acids, respectively, and they shared 70% homology of the entire amino acid sequence. The mouse ADAM gene exists at a single gene locus. The human gene was ubiquitously expressed in tissues other than liver, was mapped to human chromosome 20p13, and was found to consist of 22 exons. Both proteins have domain organization identical to that of previously reported members of the ADAM family, and contain the typical zinc-binding consensus sequence (HEXGHXXGXXHD) in their metalloprotease domain and a pattern of cysteine localization (C(x)(3)C(x)(5)C(x)(5)CxC(x)(8)C) in their EGF-like domain that is typical of an EGF-like motif. The human protein shows homology with Xenopus ADAM13 (44%), human ADAM19 (40%), and human ADAM12 (39%). From the results of phylogenic analysis based on primary amino acid sequence and distribution of the mRNA, these novel ADAM genes were thus named ADAM33.     

Characterization of Chitinase C from a Marine Bacterium, Alteromonas sp. Strain O-7, and Its Corresponding Gene and Domain Structure

One of the chitinase genes of Alteromonas sp. strain O-7, the chitinase C-encoding gene (chiC), was cloned, and the nucleotide sequence was determined. An open reading frame coded for a protein of 430 amino acids with a predicted molecular mass of 46,680 Da. Alignment of the deduced amino acid sequence demonstrated that ChiC contained three functional domains, the N-terminal domain, a fibronectin type III-like domain, and a catalytic domain. The N-terminal domain (59 amino acids) was similar to that found in the C-terminal extension of ChiA (50 amino acids) of this strain and furthermore showed significant sequence homology to the regions found in several chitinases and cellulases. Thus, to evaluate the role of the domain, we constructed the hybrid gene that directs the synthesis of the fusion protein with glutathione S-transferase activity. Both the fusion protein and the N-terminal domain itself bound to chitin, indicating that the N-terminal domain of ChiC constitutes an independent chitin-binding domain.     

Cloning of the human serotonin 5-HT2 and 5-HT1C receptor subtypes.

We report the cloning and the deduced amino acid sequence of cDNAs encoding both the human serotonin 5-HT2 and 5-HT1C receptors. The human 5-HT2 and 5-HT1C receptors shared 87% and 90% amino acid homology, respectively, with their rat counterparts. The most divergent regions of the 5-HT2 receptor between human and rat were the N-terminal extracellular domain (75% homology) and the C-terminal intracellular domain (67% homology between amino acids 426-474). The greatest variability between the human and rat 5-HT1C receptors were at the N-terminal extracellular domain (78% homology) and the third cytoplasmic loop (71% homology). The availability of the cloned human 5-HT2 and 5-HT1C receptors will help facilitate the further understanding of the molecular pharmacology and physiology of these receptors.     

cDNA cloning and genomic structure of the duck (<Emphasis Type="Italic">Anas platyrhynchos</Emphasis>) MHC class I gene

In order to provide data for studies on disease resistance, duck MHC class I cDNA (Anpl-MHC I) was cloned from a duck cDNA library and the genome structure was investigated. Anpl-MHC I genes encoded 344-355 amino acids. The genomic organization is composed of eight exons and seven introns. Based on the genetic distance, Anpl-MHC I cDNA from six individuals can be classified into four lineages (from Anpl-UAA to Anpl-UDA). A total of 28 amino acid positions in the peptide-binding domain (PBD) showed high scores by Wu-kabat index analysis. The Anpl-MHC amino acid sequence displayed seven critical HLA-A2amino acids that bind with antigen polypeptides, and have an 83.6–88.5% amino acid homology with each lineage, a 55.2–64.6% amino-acid homology with chicken MHC class I (B-FIV21, B-FIV2, Rfp-Y), and a 40.3–42.8% homology with mammalian MHC class I. Nested PCR detected that Anpl-MHC I can be expressed in the brain, heart, kidney, intestines and bursa. Compared with the human HLA-A2 tertiary structure of the PBD, Anpl-MHC I had an insertion or deletion variation in four domains (A–D). The phlyogenetic tree appears to branch in an order consistent with accepted evolutionary pathways.C. Xia and C.Y. Lin contributed equally to this work     

Analyses of the gene and amino acid sequence of thePrevotella (bacteroides) ruminicola 23 xylanase reveals unexpected homology with endoglucanases from other genera of bacteria

The DNA sequence for the xylanase gene fromPrevotella (Bacteroides) ruminicola 23 was determined. The xylanase gene encoded for a protein with a molecular weight of 65,740. An apparent leader sequence of 22 amino acids was observed. The promoter region for expression of the xylanase gene inBacteroides species was identified with a promoterless chloramphenicol acetyltransferase gene. A region of high amino acid homology was found with the proposed catalytic domain of endoglucanases from several organisms, includingButyrivibrio fibrisolvens, Ruminococcus flavefaciens, andClostridium thermocellum. The cloned xylanase was found to exhibit endoglucanase activity against carboxymethyl cellulose. Analysis of the codon usage for the xylanase gene found a bias towards G and C in the third position in 16 of 18 amino acids with degenerate codons.     

Bioinformatic and biochemical studies point to AAGR-1 as the ortholog of human acid α-glucosidase in Caenorhabditis elegans

Human acid α-glucosidase (GAA, EC 3.2.1.20) is a lysosomal enzyme that belongs to the glycoside hydrolase family 31 (GH31) and catalyses the hydrolysis of α-1,4- and α-1,6-glucosidic linkages at acid pH. Hereditary deficiency of GAA results in lysosomal glycogen storage disease type II (GSDII, Pompe disease). The aim of this study was to assess GH31 proteins in Caenorhabditis elegans (C. elegans) to identify the ortholog of human GAA. Bioinformatic searches for GAA ortholog in C. elegans genome revealed four acid alpha-glucosidase-related (aagr-1–4) genes. Multiple sequence alignment of AAGRs with other GH31 proteins demonstrated their evolutionary conservation. Phylogenetic analyses suggested clustering of AAGR-1 and -2 with acid-active and AAGR-3 and -4 with neutral-active GH31 enzymes. In order to prove the AAGRs’ predicted α-glucosidase activity, we performed RNA interference of all four aagr genes. The impact on the α-glucosidase activity was evaluated at pH 4.0 (acid) and pH 6.5 (neutral), with or without the inhibitor acarbose. AAGR-1 and -2 expressed acidic α-glucosidase activity; on the contrary, AAGR-3 not -4 represented the predominant neutral α-glucosidase activity in C. elegans. Similar results were obtained in each of aagr-1 and -4 deletion mutants. Moreover, based on our structural models of AAGRs and these biochemical experiments, we hypothesize that the enzymatic sensitivity of AAGR-2 and human maltase-glucoamylase to the inhibitor acarbose is associated with a tyrosine residue in the GH31 active site, whereas acarbose resistance of AAGR-1 and human GAA is associated with the corresponding tryptophane in the active site. Acid-active AAGR-1 may thus represent the ortholog of human GAA in C. elegans.     

A pore-forming protein,perforin, from a non-mammalian organism,Japanese flounder,<Emphasis Type="Italic"> Paralichthys olivaceus</Emphasis>

A perforin cDNA of Japanese flounder, Paralichthys olivaceus, was cloned from a cDNA library of kidney stimulated with ConA/PMA. The full-length cDNA is 2,157 bp, which encodes 587 amino acids. The Japanese flounder perforin gene consists of five exons and four introns, with a length of approximately 3 kb. The amino acid sequence of the Japanese flounder perforin is 36% identical to that of rat perforin and 37% identical to amino acid sequences of mouse and human perforin. The Japanese flounder perforin also showed low homology to human and mouse complement components (C6, C7, C8 and C9), ranging from 19% to 24%. However, the membrane attack complex/perforin domain is conserved. A phylogenetic analysis placed the Japanese flounder perforin in the same cluster with other known mammalian perforins. RT-PCR analysis revealed that the perforin gene was expressed in the peripheral blood leukocytes, head kidney, trunk kidney, spleen, heart, gill and intestine of healthy fish. Recombinant perforin produced in insect cells using the baculovirus expression system showed calcium-dependent hemolytic activity.     

Cloning of a cluster of chitinase genes from Aeromonas sp. No. 10S-24

A gene encoding chitinases from Aeromonas sp. No. 10S-24 was cloned into Escherichia coli DH5α using pUC19, and its nucleotides were sequenced. The chitinase gene was clustered in ORFs (open reading frame) 1 to 4, in a 8-kb fragment of DNA. ORF-1 consisted of 1608 bp encoding 535 amino acid residues, and ORF-2 consisted of 1425 bp encoding 474 amino acid residues. ORF-3 was 1617 bp long and encodes a protein consisting of 538 amino acids. ORF-4 encodes 287 amino acids of the N-terminal region. The amino acid sequences of ORF-1 and ORF-3 share sequence homology with chitinase D from Bacillus circulans, and chitinase A and B from Streptomyces lividans. The amino acid sequence of ORF-2 shared sequence homology with chitinase II from Aeromonas sp. No. 10S-24, and chitinase from Saccharopolyspora erythraea. A region of the sequence starting from Ala-28 of the amino acid sequence of ORF-3 coincided with the N-terminal amino acid sequence of chitinase III from Aeromonas sp. No. 10S-24.     

Amplification of ribulose bisphosphate carboxylase/oxygenase large subunit (RuBisCO LSU) gene fragments from Thiobacillus ferrooxidans and a moderate thermophile using polymerase chain reaction

Southern blot analysis of DNA from an iron-oxidising moderate thermophile NMW-6 and from Thiobacillus ferrooxidans strain TF1–35 demonstrated sequences homologous to the RuBisCO LSU gene of Synechococcus. DNA fragments (457 bp) encoding part of the RuBisCO LSU gene (amino acids 73–200) were amplified from the genomic DNA of Thiobacillus ferrooxidans and the moderate thermophile NMW-6 using the polymerase chain reaction (PCR) technique (Saiki et al. (1985) Science 233, 1350–1354). A comparison with the LSU sequences from T. ferrooxidans, Alcaligenes eutrophus, Chromatium vinosum, Synechococcus and Spinacea oleracea, which all have RuBisCOs with a hexadecameric structure, showed that the RuBisCO LSU gene sequence from NMW-6 appeared to be most closely related to that of the hydrogen bacterium A. eutrophus which showed 71.9% homology at the amino acid level. Despite its physiological similarity, T. ferrooxidans showed only 64.1% homology to the amino acid sequence from NMW-6 and had the lowest DNA homology (60.9%) of the hexadecameric type RuBisCOs. In the region sequenced, T. ferrooxidans and the RuBisCOs of the phototrophs C. vinosum, Synechococcus and S. oleracea, had 17 residues that were completely conserved which were substituted in both NMW-6 and A. eutrophus, 11 of these being identical substitutions. Comparison of the nucleotide and derived amino acid sequences of the RuBisCO LSU fragment from T. ferrooxidans with other RuBisCO sequences indicated a closer relationship to the hexadecameric type LSU genes of photosynthetic origin than to that of A. eutrophus. The T. ferrooxidans amino acid sequence showed 93.8%, 78.9% and 77.3% homology, respectively, to the C. vinosum, Synechococcus and S. oleracea (spinach) sequences but only 56.2% to A. eutrophus. The DNA sequence from Rhodospirillum rubrum, which has the atypical large subunit dimer RuBisCO structure with no small subunit, showed 39.2% and 42.7% homology, respectively, with the sequences of NMW-6 and T. ferrooxidans, and 25.0% and 29.7% amino acid homology, indicating that the DNA homology was substantially random in nature. PCR fragments (126 bp) that overlaped the last 15 codons of the fragments above were also amplified and sequenced. They showed incomplete homology with the larger fragments, supporting evidence obtained from Southern hybridizations that T. ferrooxidans and the moderate thermophile NMW-6 have multiple copies of RuBisCO LSU genes.     

Conservation of protein kinase a catalytic subunit sequences in the schistosome pathogens of humans

cAMP-dependent protein kinases (PKAs) are central mediators of cAMP signaling in eukaryotic cells. Previously we identified a cDNA which encodes for a PKA catalytic subunit (PKA-C) in Schistosoma mansoni (SmPKA-C) that is required for adult schistosome viability in vitro. As such, SmPKA-C could potentially represent a novel schistosome chemotherapeutic target. Here we sought to identify PKA-C subunit orthologues in the other medically important schistosome species, Schistosoma haematobium and Schistosoma japonicum, to determine the degree to which this potential target is conserved and could therefore be exploited for the treatment of all forms of schistosomiasis. We report the identification of PKA-C subunit orthologues in S. haematobium and S. japonicum (ShPKA-C and SjPKA-C, respectively) and show that PKA-C orthologues are highly conserved in the Schistosoma, with over 99% amino acid sequence identity shared among the three human pathogens we examined. Furthermore, we show that the recently published Schistosoma mansoni and S. japonicum genomes contain sequences encoding for several putative PKA substrates with homology to those found in Homo sapiens, Caenorhabditis elegans, and Saccharomyces cerevisiae.     

斑茅δ-OAT基因克隆及其序列分析

利用RT-PCR和RACE技术从斑茅（Erianthus arundinaceus）中分离出编码鸟氨酸-δ-氨基转氨酶基因的全长cDNA序列,序列全长1 680 bp,编码454个氨基酸。通过对哺乳动物、高等植物、微生物的δ-OAT基因编码的氨基酸序列进行同源比对,发现斑茅δ-OAT基因同其近缘属植物甘蔗的同源性最高（87%）,同其他高等植物的同源性次之（约为70%）,而同动物的同源性最低（约为60%）。在斑茅δ-OAT基因编码的氨基酸序列的5′端未发现线粒体定位序列,同甘蔗δ-OAT基因一样。斑茅δ-OAT基因具有完整的鸟氨酸转氨酶功能区rocD。利用定量RCR（real-time PCR）对30%PEG胁迫下的斑茅δ-OAT基因表达量进行研究,结果表明δ-OAT基因在胁迫12 h表达量达到最高,约为对照的4.1倍;胁迫2 h δ-OAT基因表达量反而有所降低。