Charles A. Specht

A multigene family related to chitin synthase genes of yeast in the opportunistic pathogen Aspergillus fumigatus

Two approaches were used to isolate fragments of chitin synthase genes from the opportunistic human pathogen Aspergillus fumigatus. Firstly, regions of amino acid conservation in chitin synthases of Saccharomyces cerevisiae were used to design degenerate primers for amplification of portions of related genes, and secondly, a segment of the S. cerevisiae CSD2 gene was used to screen an A. fumigatus λ genomic DNA library. The polymerase chain reaction (PCR)-based approach led to the identification of five different genes, designated chsA, chsB, chsC, chsD and chsE. chsA, chsB, and chsC fall into Classes I, II and III of the ‘zymogen type’ chitin synthases, respectively. The chsD fragment has approximately 35% amino acid sequence identity to both the zymogen type genes and the non-zymogen type CSD2 gene. chsF appears to be a homologue of CSD2, being 80% identical to CSD2 over 100 amino acids. An unexpected finding was the isolation by heterologous hybridization of another gene (chsE), which also has strong sequence similarity (54% identity at the amino acid level over the same region as chsF) to CSD2. Reverse transcriptase-PCR was used to show that each gene is expressed during hyphal growth in submerged cultures.

CHS-4, A CLASS IV CHITIN SYNTHASE GENE FROM NEUROSPORA CRASSA

InSaccharomyces cerevisiae, most of the cellular chitin is produced by chitin synthase III, which requires the product encoded by theCSD2/CAL1/DIT101/KT12 gene. We have identified, isolated and structurally characterized aCSD2/CAL1/DIT101/KT12 homologue in the filamentous ascomyceteNeurospora crassa and have used a “reverse genetics” approach to determine its role in vivo. The yeast gene was used as a heterologous probe for the isolation of aN. crassa gene (designatedchs-4) encoding a polypeptide belonging to a class of chitin synthases which we have designated class IV. The predicted polypeptide encoded by this gene is highly similar to those ofS. cerevisiae andCandida albicans. N. crassa strains in whichchs-4 had been inactivated by the Repeat-Induced Point mutation (RIP) process grew and developed in a normal manner under standard growth conditions. However, when grown in the presence of sorbose (a carbon source which induces morphological changes accompanied by elevated chitin content), chitin levels in thechs-4RIP strain were significantly lower than those observed in the wild type. We suggest that CHS4 may serve as an auxiliary enzyme inN. crassa and that, in contrast to yeasts, it is possible that filamentous fungi may have more than one class IV chitin synthase.

Cloning and expression of chitinases of Entamoebae

Entamoeba histolytica (Eh) and Entamoeba dispar (Ed) are protozoan parasites that infect hundreds of millions of persons. In the colonic lumen, amebae form chitin-walled cysts, the infectious stage of the parasite. Entamoeba invadens (Ei), which infects reptiles and is a model for amebic encystation, produces chitin synthase and chitinase during encystation. Ei cysts formation is blocked by the chitinase-inhibitor allosamidin. Here molecular cloning techniques were used to identify homologous genes of Eh, Ed, and Ei that encode chitinases (EC 3.2.1.14). The Eh gene (Eh cht1) predicts a 507-amino acid (aa) enzyme, which has 93 and 74% positional identities with Ed and Ei chitinases, respectively. The Entamoeba chitinases have signal sequences, followed by acidic and hydrophilic sequences composed of multiple tandemly arranged 7-aa repeats (Eh and Ed) or repeats varying in length (Ei). The aa compositions of the chitinase repeats are similar to those of the repeats of the Eh and Ed Ser-rich proteins. The COOH-terminus of each chitinase has a catalytic domain, which resembles those of Brugia malayi (33% positional identity) and Manduca sexta (29%). Recombinant entamoeba chitinases are precipitated by chitin and show chitinase activity with chitooligosacharide substrates. Consistent with previous biochemical data, chitinase mRNAs are absent in Ei trophozoites and accumulate to maximal levels in Ei encysting for 48 h.

CLONING AND EXPRESSION OF TWO CHITIN DEACETYLASE GENES OF SACCHAROMYCES CEREVISIAE

Chitin deacetylase (EC 3.5.1.41), which hydrolyses the N‐acetamido groups of N‐acetyl‐d‐glucosamine residues in chitin, has been demonstrated in crude extracts from sporulating Saccharomyces cerevisiae. Two S. cerevisiae open reading frames (ORFs), identified by the Yeast Genome Project, have protein sequence homology to a chitin deacetylase from Mucor rouxii. Northern blot hybridizations show each ORF was transcribed in diploid cells after transfer to sporulation medium and prior to formation of asci. Each ORF was cloned in a vector under transcriptional control of the GAL 1, 10 promoter and introduced back into haploid strains of S. cerevisiae. Chitin deacetylase activity was detected by in vitro assays from vegetative cells grown in galactose. Chemical analysis of these cells also demonstrated the synthesis of chitosam in vivo. Both recombinant chitin deacetylases showed similar qualitative and quantitative activities toward chitooligosaccharides in vitro. A diploid strain deleted of both ORFs, when sporulated, did not show deacetylase activity. The mutant spores were hypersensitive to lytic enzymes (Glusulase or Zymolyase).

Chitinases are a multi-gene family in Aedes, Anopheles and Drosophila.

Degenerate primers were used to amplify by the polymerase chain reaction (PCR) DNA fragments from the chitinase genes of five insect species: Aedes aegypti, Anopheles freeborni, Anopheles gambiae, Anopheles stephensi and Drosophila melanogaster. As many as four different products were found for each species; each deduced protein sequence having greatest homology to chitinase sequences from other species of insects and the crustacean, Penaeus japonicus. The four PCR products of A. aegypti hybridize to two loci, with three of the products derived from either three tightly linked genes or a single gene with three catalytic domains. Southern blot hybridizations of the PCR products from the species of Anopheles suggest a similar arrangement.

The isolation of a dol-P-man synthase from Ustilago maydis that functions in Saccharomyces cerevisiae

Genomic DNAs from several fungi were screened for a homologous sequence to Saccharomyces cerevisiae DPM1, an essential gene which encodes dolichyl phosphoryl mannose synthase. The fungi examined included Aspergillus nidulans, Neurospora crassa, Schizophyllum commune and Ustilago maydis. Only U. maydis gave a significant signal after Southern hybridization using DPM1 as a probe. The Ustilago homolog was subsequently cloned and sequenced. The predicted protein of 294 amino acids has 60% identity to the S. cerevisiae protein, but lacks the putative ‘dolichol recognition sequence’. RNA of ca. 900 bp is transcribed in both yeast and filamentous cells of Ustilago. In Escherichia coli, the U. maydis sequence expressed a 35 kDa protein exhibiting dolichyl phosphoryl mannose synthase activity. The sequence was also shown to complement a haploid strain of S. cerevisiae containing a deletion of the DPM1 gene. The U. maydis sequence therefore, encodes a dolichyl phosphoryl mannose synthase that can support normal vegetative growth in S. cerevisiae. The GenBank accession number is U54797.

Molecular cloning of a third chitinase gene (CHT1) from Candida albicans

Here we report the complete nucleotide sequence of a third chitinase gene (CHT1) from the dimorphic human pathogen Candida albicans. The deduced amino acid (aa) sequence of Cht1 consists of 416 aa and displays 36% protein sequence similarity to chitinases Cht2 and Cht3, from C. albicans. Interestingly the domain structure of Cht1 is truncated when compared to the other chitinases of C. albicans and lacks a Ser/Thr‐rich region. The sequence data will appear in the GenBank Nucleotide Sequence Data Library under the accession number U36490.

Isolation of the Bα and Bβ mating-type loci of Schizophyllum commune

The B mating type of the basidiomycete fungus, Schizophyllum commune is determined by two, tightly linked, multi-specificity (also called multi-allelic) loci: Bα and Bβ. A plasmid library was used in DNA-mediated transformation to obtain transformants that displayed B-directed development. Plasmids that conferred Bα1 and Bβ1 mating-type specificities were rescued from the transformants. Fragments of DNA from each plasmid hybridized to genomic DNA from the strain used to make the plasmid library; however, they did not hybridize, or hybridized only weakly, to genomic DNA from strains with mating-type specificities different from Bα1 or Bβ1. The cloned fragments are presumed to correspond to active regions of each B mating-type locus.