Cloning of the Aspergillus niger gene encoding α-l-arabinofuranosidase A

Using l-arabitol as an inducer, simple induction conditions were established that resulted in high-level expression of -l-arabinofuranosidase A by an Aspergillus niger d-xylulose kinase mutant strain. These conditions were adapted to construct a cDNA expression library from which an -l-arabinofuranosidase A cDNA clone was isolated using specific antiserum. The corresponding gene encoding -l-arabinpfuranosidase A (abfA) was isolated from a genomic library and cloned into a high copy plasmid vector. By co-transformation of uridine auxotrophic mutants lacking orotidine-5-phosphate decarboxylase activity, the afbA gene was introduced both in A. niger and A. nidulans, using the A. niger pyrA gene as selection marker. The identity of the abfA gene was confirmed by overexpression of the gene product by A. niger and A. nidulans transformants, upon growth using sugar beet pulp as the carbon source.     

Cross-complementation of Clostridium perfringens PLC and Clostridium septicum α-toxin mutants reveals PLC is sufficient to mediate gas gangrene

Clostridium perfringens and Clostridium septicum are the most common causes of clostridial myonecrosis or gas gangrene. Although they mediate a similar disease pathology, they elaborate functionally very different α-toxins. We used a reciprocal complementation approach to assess the contribution of the primary toxin of each species to disease and found that C. perfringens α-toxin (PLC) was able to mediate the gross pathology of myonecrosis even in a C. septicum background, although it could not induce vascular leukostasis. Conversely, while C. septicum α-toxin restored some virulence to a C. perfringens plc mutant, it was less active than in its native background.     

Molecular analysis of the gene encoding α-lytic protease: evidence for a preproenzyme

A 1.7-kb EcoRI fragment containing the structural gene for α-lytic protease has been cloned from Lysobacter enzymogenes 495 chromosomal DNA: the first example of a gene cloned from this organism. The protein sequence deduced from the nucleotide sequence encoding this serine protease matches the published amino acid sequence [Olson et al., Nature 228 (1970) 438–442] precisely. Sequence analysis and S 1 mapping indicate that, like subtilisin [e.g. Wells et al., Nucleic Acids Res. 11 (1983) 7911–7925] α-lytic protease is synthesized as a pre-pro protein (41 kDa) that is subsequently processed to its mature extracellular form (20 kDa). This first finding of a large N-terminal protease precursor in a Gram-negative bacterial protease strengthens the hypothesis that large precursors may be a general property of extracellular bacterial proteases, and suggests that the N- or C-terminal location of the precursor segment may be significant.     

Cloning and analysis of a gene from Streptomyces lividans 66 encoding a novel secreted protease exhibiting homology to subtilisin BPN′

 Amino-terminal degradation has been observed for many of the secreted heterologous proteins produced by S. lividans 66. We, therefore, set out to characterize the relevant proteinases and their genes. A tripeptide chromogenic substrate was used to identify a gene that was shown to encode a secreted protein which removed tripeptides from the amino terminus of extracellular proteins (tripeptidyl aminopeptidase, Tap; Butler et al. 1995). This activity was removed by a homologous gene deletion replacement and the ability of the S. lividans strain to remove N-terminal tripeptides was greatly reduced, but still significant. When the tap-deleted strain was used as a host for the rescreening of a S. lividans 66 genomic DNA library, a number of other genes encoding proteases with aminopeptidase activities were discovered. One clone (P5-4) produced a 45-kDa secreted protein (Ssp), which showed activity against Ala-Pro-Ala-β-naphthylamide (APA-βNH-Nap) substrate. Further analysis of the cloned DNA showed an open-reading frame encoding a protein larger than 45 kDa. Direct Edman degradation of the secreted protein confirmed that it was encoded within the cloned DNA and probably processed from a larger precursor. Protein sequence analysis revealed a striking homology to subtilisin BPN′ in three regions around the active-site residues suggesting that the protein is a serine protease. As expected, the protease activity was inhibited by phenylmethylsulphonyl fluoride. Mutant strains with most of the ssp gene deleted exhibited reduced activity against APA-βNH-Nap substrate compared to their non-deleted parental strains. Received: 15 May 1995/Received last revision: 2 October 1995/Accepted: 4 October 1995     

Phospholipid hydrolysis caused by Clostridium perfringens α-toxin facilitates the targeting of perfringolysin O to membrane bilayers

Clostridium perfringens causes gas gangrene and gastrointestinal disease in humans. These pathologies are mediated by potent extracellular protein toxins, particularly α-toxin and perfringolysin O (PFO). While α-toxin hydrolyzes phosphatidylcholine and sphingomyelin, PFO forms large transmembrane pores on cholesterol-containing membranes. It has been suggested that the ability of PFO to perforate the membrane of target cells is dictated by how much free cholesterol molecules are present. Given that C. perfringens α-toxin cleaves the phosphocholine headgroup of phosphatidylcholine, we reasoned that α-toxin may increase the number of free cholesterol molecules in the membrane. Our present studies reveal that α-toxin action on membrane bilayers facilitates the PFO?cholesterol interaction as evidenced by a reduction in the amount of cholesterol required in the membrane for PFO binding and pore formation. These studies suggest a mechanism for the concerted action of α-toxin and PFO during C. perfringens pathogenesis.     

Sequencing and characterization of the porcine α-galactosidase A gene: towards the generation of a porcine model for Fabry disease

Fabry disease is an inherited lysosomal disorder caused by a deficiency of alpha-galactosidase A (α-gal A). The systemic accumulation of substrate, mainly globotriaosylceramide (Gb3), results in organ failure. Although Gb3 accumulation has been observed in an α-gal A-deficient mouse model, important clinical manifestations were not seen. The pursuit of effective treatment for Fabry disease through gene therapy, for example, has been hampered by the lack of a relevant large animal model to assess the efficacy and safety of novel therapies. Towards assembling the tools to generate an alternative animal model, we have sequenced and characterized the porcine ortholog of the α-gal A gene. When compared to the human α-gal A, the porcine α-gal A showed a high level of homology in the coding regions and located at chromosome Xq22. Cell lysate and supernatants from Fabry patient-derived fibroblasts transduced with a lentiviral vector (LV) carrying the porcine α-gal A cDNA (LV/porcine α-gal A), showed high levels of α-gal A activity and its enzymological stability was similar to that of human α-gal A. Uptake of secreted porcine α-gal A was observed into non-transduced cells and was partially inhibited by soluble mannose-6-phosphate. Furthermore, Gb3 accumulation was reduced in Fabry patient-derived fibroblasts transduced with the LV/porcine α-gal A. In conclusion, we elucidated and characterized the porcine α-gal A gene and enzyme. Similarity in enzymatic profile and chromosomal location between α-gal A of porcine and human origins may be of great advantage for the development of a large animal model for Fabry disease.     

Structural organisation of the gene encoding the α-subunit of the human amiloride-sensitive epithelial sodium channel

The human amiloride-sensitive epithelial sodium channel (ENaC) is a member of the degenerin/ENaC family of ion channels and regulates fluid and electrolyte absorption across a number of epithelia, including kidney, colon and lung. Native ENaC has been shown to be a multimer made up of at least three homologous subunits (α, β, γ) and mutations affecting the channel complex have been identified in various human diseases. “Gain of function” mutations in one of the three ENaC subunits have been found to cause pseudoaldosteronism (Liddle’s syndrome) and ENaC “reduction of function” mutations are found in patients affected with the recessive form of pseudohypoaldosteronism (PHA) type 1. In this report, we describe the genomic organisation of the humanαENaC gene. Human αENaC consists of 13 exons spanning 17 kb on chromosome 12p13 and contains at least eight Alu sequences. In addition to the intron/exon boundaries, we have deciphered almost all the intron sequences and 475 bp of the CCAAT-less and TATA-less 5′ flanking region. Received: 23 December 1997 / Accepted: 5 March 1998     

Molecular cloning of the gene encoding α-acetolactate decarboxylase from Enterobacter aerogenes

Enterobacter aerogenes genomic library has been constructed using cosmid pJB8 in Escherichia coli. The gene encoding α-acetolactate decarboxylase (ALDC) has been isolated from this library by direct measurement of enzyme activity. The expression of the ALDC gene in E. coli appears to originate from the own promoter. Subsequent subcloning revealed that the ALDC gene locates within 1.7 kb BamHI-PstI fragment.     

Isolation and characterization of a gene encoding α-tubulin from Candida albicans

A gene encoding the α-tubulin of Candida albicans has been cloned and characterized. Nucleotide sequence analysis reveals the presence of an intron within the structural gene and predicts the synthesis of a polypeptide of 448 amino acid residues. Comparison of nucleotide and amino acid sequences with the Saccharomyces cerevisiae α-tubulin encoding genes shows a 75% homology and about 92% similarity respectively. In contrast to S. cerevisiae, C. albicans appears to possess only one gene for α-tubulin which is able to functionally complement a S. cerevisiae cold-sensitive tub1 mutant.     

A gene encoding Achlya bisexualis β-amylase and its expression in Saccharomyces cerevisiae

Part of a -amylase genomic DNA sequence from the oomycete, Achlya bisexualis was cloned by polymerase chain reaction (PCR) using degenerate oligonucleotide primers derived from the conserved regions of other known -amylase sequences. The 5- and 3-regions of the -amylase gene were amplified by genome walking method. The Ach. bisexualis -amylase gene consisted of a 1338bp open reading frame, encoding a protein of 446 amino acids with a molecular weight of 49 381Da, and was not interrupted by any intron. The deduced amino acid sequence of the -amylase gene had 67% similarity to the -amylase of Saprolegnia ferax, followed by 40% similarity to that ofArabidopsis thaliana. The -amylase gene was expressed in Saccharomyces cerevisiae placing it under the control of the alcohol dehydrogenase gene (ADC1) promoter.     

Evolution and expression analysis of the β-glucosidase (GLU) encoding gene subfamily in maize

The maize ??-glucosidase (ZmGLU1) hydrolyzes cytokinin-conjugates for releasing active cytokinins and thus plays important roles in cytokinin regulatory processes. ZmGLU1 belongs to glycosyl hydrolases 1 (GH1) gene family with a large number of members, and the gene function of other homologs remains to be investigated. In this study, 47 Arabidopsis, 34 rice, 31 brachypodium, 28 sorghum and 26 maize GH1 protein sequences were collected and subsequently used to construct a phylogenetic tree by Neighbor-Joining method. ZmGLU1 together with its 7 paralogs and 4 sorghum homologs were assigned into a distinct group (named GLU subfamily) with far evolutionary distance to other GH1 members. None of the Arabidopsis, rice and brachypodium gene falling into this group indicated a recent evolutionary emergence of GLU subfamily in some Poaceae plants after the divergence of Poaceae species. Phylogeny and comparative genome analysis revealed that GLU subfamily members of maize and sorghum evolved from a common ancestor, and expanded independently in each species by several duplications after maize-sorghum split. Ka/Ks analysis showed that purifying selection played important roles in maintenance of similar functions among the maize GLU paralogs. In addition, the similar protein properties and cytokinin-dependent gene expressions further suggested the similar functions of ZmGLUs in cytokinin activation. However, the organ-dependent expression of ZmGLUs exhibited diverse patterns, which might contribute to their diverse roles in cytokinin homeostasis. Taken together, this work put new insights into the evolution and expression of ZmGLU genes, and provided the foundation for future functional investigations.     

Characterization of the lys2 gene of Penicillium chrysogenum encoding α-aminoadipic acid reductase

A DNA fragment containing a gene homologous to LYS2 gene of Saccharomyces cerevisiae was cloned from a genomic DNA library of Penicillium chrysogenum AS-P-78. It encodes a protein of 1409 amino acids (Mr^ 154?859) with strong similarity to the S.?cerevisiae (49.9% identity) Schizosaccharomycespombe (51.3% identity) and Candida albicans (48.12% identity) α-aminoadipate reductases and a lesser degree of identity to the amino acid-activating domains of the non-ribosomal peptide synthetases, including the α-aminoadipate-activating domain of the α-aminoadipyl-cysteinyl-valine synthetase of P. chrysogenum (12.4% identical amino acids). The lys2 gene contained one intron in the 5′-region and other in the 3′-region, as shown by comparing the nucleotide sequences of the cDNA and genomic DNA, and was transcribed as a 4.7-kb monocistronic mRNA. The lys2 gene was localized on chromosome III (7.5?Mb) in P. chrysogenum AS-P-78 and on chromosome IV (5.6 Mb) in strain P2, whereas the penicillin gene cluster is known to be located in chromosome I in both strains. The lys2-encoded protein is a member of the aminoacyladenylate-forming enzyme family with a reductase domain in its C-terminal region.