Molecular cloning and expression of the beta-hydroxysteroid dehydrogenase gene from Pseudomonas testosteroni.

The structural gene (hsd) of the Pseudomonas testosteroni encoding the 17 beta-hydroxysteroid dehydrogenase has been cloned using the cosmid vector pVK102. Escherichia coli carrying recombinant clones of hsd, isolated by immunological screening, were able to express the biologically active enzyme, as measured by the conversion of testosterone into androstenedione. Subcloning experiments, restriction and deletion analysis, and site-directed insertion mutagenesis showed that the hsd gene is located within a 1.3-kb HindIII-PstI restriction fragment. A 26.5-kDa protein encoded by a recombinant plasmid containing this Ps. testosteroni DNA restriction fragment was detected by SDS-PAGE analysis of in vitro [35S]methionine-labeled polypeptides.     

Regulation of testosterone degradation in Comamonas testosteroni

Recently, we have identified a gene encoding a LuxR-type factor, TeiR (Testosterone-inducible Regulator), which positively regulates steroid degradation in Comamonas testosteroni. Herein, we demonstrate that TeiR interacts in vivo with steroid catabolic gene promoters. The presence of testosterone induces a significant TeiR protein increase at the early logarithmic phase of growth. Interestingly, it is not until the early stationary phase where the activation of a steroid-inducible gene promoter is observed, indicating that testosterone might not be the true inductor of the steroid degradation pathway. In addition, beta-galactosidase expression driven by a testosterone-inducible promoter is prematurely activated in cells cultured in medium supplemented with ethyl acetate extracts obtained from the early stationary phase cell-free supernatants of C. testosteroni grown in presence of testosterone. Complementation experiments of C. testosteroni wild type performed with teiR deletion constructs indicate that extra-copies of deleted-TeiR exert a dominant negative effect on the wild-type TeiR protein. While, when C. testosteroni teiR mutants were used to carry out complementation assays only the full length gene can overcome the teiR mutant phenotype. Altogether these findings indicate that TeiR regulates steroid catabolic genes interacting with their promoters and suggest that this interaction requires the presence of a testosterone-derived metabolite to induce the system.     

Discovery and characterization of Sip1A: a novel secreted protein from Bacillus thuringiensis with activity against coleopteran larvae

Bioassay screening of Bacillus thuringiensis culture supernatants identified strain EG2158 as having larvicidal activity against Colorado potato beetle (Leptinotarsa decemlineata) larvae. Ion-exchange fractionation of the EG2158 culture supernatant resulted in the identification of a protein designated Sip1A (secreted insecticidal protein) of approximately 38 kDa having activity against Colorado potato beetle (CPB). An oligonucleotide probe based on the N-terminal sequence of the purified Sip1A protein was used to isolate the sip1A gene. The sequence of the Sip1A protein, as deduced from the sequence of the cloned sip1A gene, contained 367 residues (41,492 Da). Recombinant B. thuringiensis and Escherichia coli harboring cloned sip1A produced Sip1A protein which had insecticidal activity against larvae of CPB, southern corn rootworm (Diabrotica undecimpunctata howardi), and western corn rootworm (Diabrotica virgifera virgifera).     

Functional analysis of the Streptomyces lividans type I signal peptidases

Type I signal peptidases are responsible for the proteolytic cleavage of the signal peptide of secreted proteins. In the gram-positive bacterium Streptomyces lividans, four adjacent genes (sipW, sipX, sipY and sipZ) were isolated encoding putative type I signal peptidases. In this work, the different sip genes were cloned and expressed. Subsequently, the Sip proteins were purified to raise antibodies. Although the four Sip proteins share a low degree of sequence similarity and differ significantly in size and pI, anti-Sip antibodies cross-reacted intensively. Functional signal peptidase processing activity for each of these Sip proteins was shown both in vitro and in vivo. The different Sip proteins did not exhibit the same cleavage efficiency on the Bacillus subtilis pre-chitosanase.     

Extraction of a steroid transport system from Pseudomonas testosteroni membranes and incorporation into synthetic liposomes

A steroid binding protein has been extracted from Pseudomonas testosteroni membranes with an organic solvent system. This protection binds some C19 and C21 steroids but not C18 steroids. When this protein is incorporated into synthetic lipid vesicles constructed from P. testosteroni phospholipids, the vesicles perform concentrative uptake of testosterone in the presence of the ionophore valinomycin. This steroid binding protein is thus believed to be the steroid permease of this organism.     

Sip1Ab gene from a native Bacillus thuringiensis strain QZL38 and its insecticidal activity against Colaphellus bowringi Baly

In this study, we collected 540 soil samples from northeast China and isolated the wild-type strain of Bacillus thuringiensis (Bt) by identifying and cloning 9 Bt strains that expressed the secreted insecticidal protein (Sip) gene. We selected the strain QZL38 for further study. The sip gene was identified from the Bt strain QZL38 using polymerase chain reaction (PCR). We sequenced a 1095-base pair fragment of DNA that encodes 364 amino acid residues of a 41.18?kDa pro-toxin and compared it with the registered Sip1Ab protein amino acid residue sequence. The sequence was submitted to GenBank with the accession no. KP231523, and the gene was named sip1Ab. The Sip1Ab protein expressed in Escherichia coli showed insecticidal activity against Colaphellus bowringi Baly, with an LC50 of 1.051?μg?mL^?1. To identify the active fragment of the Sip1Ab toxin, four pairs of primers with different truncation positions were designed, and the recombinant proteins were expressed in E. coli. The truncated Sip protein expressed in E. coli showed insecticidal activity against C. bowringi Baly. The insecticidal activity of the recombinant proteins against C. bowringi Baly from the Sip1Ab signal peptide after removal of 30 amino acid residues showed an LC50 of 1.078?μg?mL^?1. Sip proteins may play an important role in the prevention and control of the C. bowringi Baly.     

beta-subunits of Snf1 kinase are required for kinase function and substrate definition

The Snf1 kinase and its mammalian homolog, the AMP-activated protein kinase, are heterotrimeric enzymes composed of a catalytic alpha-subunit, a regulatory gamma-subunit and a beta-subunit that mediates heterotrimer formation. Saccharomyces cerevisiae encodes three beta-subunit genes, SIP1, SIP2 and GAL83. Earlier studies suggested that these subunits may not be required for Snf1 kinase function. We show here that complete and precise deletion of all three beta-subunit genes inactivates the Snf1 kinase. The sip1Delta sip2Delta gal83Delta strain is unable to derepress invertase, grows poorly on alternative carbon sources and fails to direct the phosphorylation of the Mig1 and Sip4 proteins in vivo. The SIP1 sip2Delta gal83Delta strain manifests a subset of Snf phenotypes (Raf(+), Gly(-)) observed in the snf1Delta 10 strain (Raf(-), Gly(-)), suggesting that individual beta-subunits direct the Snf1 kinase to a subset of its targets in vivo. Indeed, deletion of individual beta-subunit genes causes distinct differences in the induction and phosphorylation of Sip4, strongly suggesting that the beta-subunits play an important role in substrate definition.     

Sip1, an AP-1 Accessory Protein in Fission Yeast,Is Required for Localization of Rho3 GTPase

Rho family GTPases act as molecular switches to regulate a range of physiological functions, including the regulation of the actin-based cytoskeleton, membrane trafficking, cell morphology, nuclear gene expression, and cell growth. Rho function is regulated by its ability to bind GTP and by its localization. We previously demonstrated functional and physical interactions between Rho3 and the clathrin-associated adaptor protein-1 (AP-1) complex, which revealed a role of Rho3 in regulating Golgi/endosomal trafficking in fission yeast. Sip1, a conserved AP-1 accessory protein, recruits the AP-1 complex to the Golgi/endosomes through physical interaction. In this study, we showed that Sip1 is required for Rho3 localization. First, overexpression of rho3 ⁺ suppressed defective membrane trafficking associated with sip1-i4 mutant cells, including defects in vacuolar fusion, Golgi/endosomal trafficking and secretion. Notably, Sip1 interacted with Rho3, and GFP-Rho3, similar to Apm1-GFP, did not properly localize to the Golgi/endosomes in sip1-i4 mutant cells at 27°C. Interestingly, the C-terminal region of Sip1 is required for its localization to the Golgi/endosomes, because Sip1-i4-GFP protein failed to properly localize to Golgi/endosomes, whereas the fluorescence of Sip1ΔN mutant protein co-localized with that of FM4-64. Consistently, in the sip1-i4 mutant cells, which lack the C-terminal region of Sip1, binding between Apm1 and Rho3 was greatly impaired, presumably due to mislocalization of these proteins in the sip1-i4 mutant cells. Furthermore, the interaction between Apm1 and Rho3 as well as Rho3 localization to the Golgi/endosomes were significantly rescued in sip1-i4 mutant cells by the expression of Sip1ΔN. Taken together, these results suggest that Sip1 recruits Rho3 to the Golgi/endosomes through physical interaction and enhances the formation of the Golgi/endosome AP-1/Rho3 complex, thereby promoting crosstalk between AP-1 and Rho3 in the regulation of Golgi/endosomal trafficking in fission yeast.     

Sip1, a Conserved AP-1 Accessory Protein,Is Important for Golgi/Endosome Trafficking in Fission Yeast

We had previously identified the mutant allele of apm1⁺ that encodes a homolog of the mammalian μ 1A subunit of the clathrin-associated adaptor protein-1 (AP-1) complex and demonstrated that the AP-1 complex plays a role in Golgi/endosome trafficking, secretion, and vacuole fusion in fission yeast. Here, we isolated a mutant allele of its4⁺/sip1⁺, which encodes a conserved AP-1 accessory protein. The its4-1/sip1-i4 mutants and apm1 -deletion cells exhibited similar phenotypes, including sensitivity to the calcineurin inhibitor FK506, Cl⁻ and valproic acid as well as various defects in Golgi/endosomal trafficking and cytokinesis. Electron micrographs of sip1-i4 mutants revealed vacuole fragmentation and accumulation of abnormal Golgi-like structures and secretory vesicles. Overexpression of Apm1 suppressed defective membrane trafficking in sip1-i4 mutants. The Sip1-green fluorescent protein (GFP) co-localized with Apm1-mCherry at Golgi/endosomes, and Sip1 physically interacted with each subunit of the AP-1 complex. We found that Sip1 was a Golgi/endosomal protein and the sip1-i4 mutation affected AP-1 localization at Golgi/endosomes, thus indicating that Sip1 recruited the AP-1 complex to endosomal membranes by physically interacting with each subunit of this complex. Furthermore, Sip1 is required for the correct localization of Bgs1/Cps1, 1,3-β-D-glucan synthase to polarized growth sites. Consistently, the sip1-i4 mutants displayed a severe sensitivity to micafungin, a potent inhibitor of 1,3-β-D-glucan synthase. Taken together, our findings reveal a role for Sip1 in the regulation of Golgi/endosome trafficking in coordination with the AP-1 complex, and identified Bgs1, required for cell wall synthesis, as the new cargo of AP-1-dependent trafficking.     

The Snf1 protein kinase and its activating subunit, Snf4, interact with distinct domains of the Sip1/Sip2/Gal83 component in the kinase complex.

The Snf1 protein kinase plays a central role in the response to glucose starvation in the yeast Saccharomyces cerevisiae. Previously, we showed that two-hybrid interaction between Snf1 and its activating subunit, Snf4, is inhibited by high levels of glucose. These findings, together with biochemical evidence that Snf1 and Snf4 remain associated in cells grown in glucose, suggested that another protein (or proteins) anchors Snf1 and Snf4 into a complex. Here, we examine the possibility that a family of proteins, comprising Sip1, Sip2, and Gal83, serves this purpose. We first show that the fraction of cellular Snf4 protein that is complexed with Snf1 is reduced in a sip1delta sip2delta gal83delta triple mutant. We then present evidence that Sip1, Sip2, and Gal83 each interact independently with both Snf1 and Snf4 via distinct domains. A conserved internal region binds to the Snf1 regulatory domain, and the conserved C-terminal ASC domain binds to Snf4. Interactions were mapped by using the two-hybrid system and were confirmed by in vitro binding studies. These findings indicate that the Sip1/Sip2/Gal83 family anchors Snf1 and Snf4 into a complex. Finally, the interaction of the yeast Sip2 protein with a plant Snf1 homolog suggests that this function is conserved in plants.     

Isolation, characterization and molecular cloning of the bark lectins from Maackia amurensis

A detailed study was made of the bark lectins of the legume tree Maackia amurensis using a combination of protein purification and cDNA cloning. The lectins, which are the most abundant bark proteins, are a complex mixture of isoforms composed of two types of subunits of 32 and 37 kDa, respectively. Isolation and characterization of the homotetrameric isoforms indicated that the 32 kDa subunit exhibits a 100-fold stronger haemagglutinating activity than the 37 kDa subunit. Molecular cloning confirmed that the two lectin subunits are encoded by different genes. The 32 kDa subunit is apparently encoded by a single gene, whereas two highly homologous genes encode the 37 kDa subunit. A comparison of the deduced amino acid sequences of the bark lectin cDNAs and the previously described cDNA encoding the seed haemagglutinin demonstrated that they are encoded by different genes. Abbreviations: LECMAHb, cDNA clone encoding Maackia amurensis bark haemagglutinin; LECMALb, cDNA clone encoding Maackia amurensis bark leucoagglutinin; MALb, Maackia amurensis bark leucoagglutinin; MAHb, Maackia amurensis bark haemagglutinin This revised version was published online in November 2006 with corrections to the Cover Date.     

Structure of bacterial 3beta/17beta-hydroxysteroid dehydrogenase at 1.2 A resolution: a model for multiple steroid recognition

The enzyme 3beta/17beta-hydroxysteroid dehydrogenase (3beta/17beta-HSD) is a steroid-inducible component of the Gram-negative bacterium Comamonas testosteroni. It catalyzes the reversible reduction/dehydrogenation of the oxo/beta-hydroxy groups at positions 3 and 17 of steroid compounds, including hormones and isobile acids. Crystallographic analysis at 1.2 A resolution reveals the enzyme to have nearly identical subunits that form a tetramer with 222 symmetry. This is one of the largest oligomeric structures refined at this resolution. The subunit consists of a monomer with a single-domain structure built around a seven-stranded beta-sheet flanked by six alpha-helices. The active site contains a Ser-Tyr-Lys triad, typical for short-chain dehydrogenases/reductases (SDR). Despite their highly diverse substrate specificities, SDR members show a close to identical folding pattern architectures and a common catalytic mechanism. In contrast to other SDR apostructures determined, the substrate binding loop is well-defined. Analysis of structure-activity relationships of catalytic cleft residues, docking analysis of substrates and inhibitors, and accessible surface analysis explains how 3beta/17beta-HSD accommodates steroid substrates of different conformations.     

Functional expression, purification, and characterization of 3alpha-hydroxysteroid dehydrogenase/carbonyl reductase from Comamonas testosteroni

3alpha-Hydroxysteroid dehydrogenase (3alpha-HSD) catalyzes the oxidoreduction at carbon 3 of steroid hormones and is postulated to initiate the complete mineralization of the steroid nucleus to CO(2) and H(2)O in Comamonas testosteroni. By this activity, 3alpha-HSD provides the basis for C. testosteroni to grow on steroids as sole carbon and energy source. 3alpha-HSD was cloned and overexpressed in E. coli and purified to homogeneity by an affinity chromatography system as His-tagged protein. The recombinant enzyme was found to be functional as oxidoreductase toward a variety of steroid substrates, including androstanedione, 5alpha-dihydrotestosterone, androsterone, cholic acid, and the steroid antibiotic fusidic acid. The enzyme also catalyzes the carbonyl reduction of nonsteroidal aldehydes and ketones such as metyrapone, p-nitrobenzaldehyde and a novel insecticide (NKI 42255), and, based on this pluripotent substrate specificity, was named 3alpha-hydroxysteroid dehydrogenase/carbonyl reductase (3alpha-HSD/CR). It is suggested that 3alpha-HSD/CR contributes to important defense strategies of C. testosteroni against natural and synthetic toxicants. Antibodies were generated in rabbits against the entire 3alpha-HSD/CR protein, and may now be used for evaluating the pattern of steroid induction in C. testosteroni on the protein level. Upon gel permeation chromatography the purified enzyme elutes as a 49.4 kDa protein revealing for the first time the dimeric nature of 3alpha-HSD/CR of C. testosteroni.     

Molecular cloning and partial characterization of the pathway for aniline degradation inPseudomonas sp. strain CIT1

The genes encoding aniline utilization inPseudomonas sp. strain CIT1 have been cloned inEscherichia coli and partially characterized. Molecular cloning of the genes was achieved by construction of a cosmid library, followed by mobilization of the library into mutants ofPs. sp. CIT1 impaired in a number of functions necessary for growth on aniline. A 42-kbSau3A fragment was found to encode the ability to utilize aniline and contained the catechol 2,3-dioxygenase (C230) gene. The regions encoding these activities were subcloned and further characterized. Plasmids containing the aniline oxidase gene encoded a 260-kDa protein complex, which was putatively shown to be composed of 72 kDa and possibly 36 kDa subunits. The fragment required for C230 activity encodes a 35 kDa protein, similar in size to C230 gene products previously characterized.