The properties and localization of Saprolegnia monoica chitin synthase differ from those of other fungi.

The presence of non-fibrillar alpha-chitin in cellulosic fungi (class Oomycetes) poses intriguing questions as to its role, subcellular localization and evolutionary significance. Previous studies reported on the similarity of chitin synthase from Saprolegnia monoica with that of other fungi. The present work describes important dissimilarities. There was no evidence that the chitin synthase of S. monoica was present in small low-density vesicles (chitosomes). Chitin synthase sedimented with membranous components of high specific gravity (sp. gr. 1.177) that could be partially but distinctly separated from membranes harbouring most of the 1,3-beta-glucan synthase in the cell (sp. gr. 1.158). In contrast to other fungi, the chitin synthase from S. monoica was greatly stimulated by digitonin: both membrane-bound and dissociated chitin synthase showed little activity in the absence of digitonin. As in other fungi, the chitin synthase from S. monoica was solubilized by digitonin and remained zymogenic after dissociation. However, unlike the enzyme from other fungi, the solubilized chitin synthase of S. monoica had a lower sedimentation coefficient, was not stimulated by phospholipids and was not inhibited by high concentrations of digitonin. Unlike the enzyme from Mucor rouxii, the solubilized chitin synthase from S. monoica did not bind to a cation exchanger. The enzyme was partially purified by four-step scheme that included sucrose density-gradient centrifugation, a single passage through a strong anion exchanger and two consecutive passages through a weak anion exchanger. The final preparation contained five to seven polypeptide bands that cochromatographed with the chitin synthase activity, some of which may be part of a presumed chitin synthase macromolecular complex.

CHS2, a chitin synthase gene from the oomycete Saprolegnia monoica.

PCR was used to amplify fragments corresponding to the chitin synthase (CHS) genes from the Oomycetes Saprolegnia monoica, Phytophthora capsici and Achlya ambisexualis, utilizing as primers, oligonucleotides designed from the conserved region of CHS genes of chitinous fungi. Chitin synthase homologues were found in the three cellulosic fungi. The chitin synthase 2 gene (CHS2) from S. monoica was cloned, sequenced and characterized. The amino acid sequence deduced from the CHS2 genomic DNA revealed several domains, corresponding to the catalytic domains and polypeptide signatures, of high identity with CHS genes from chitinous fungi. Existence of a CHS gene family in S. monoica was supported by the identification of two CHS sequences among the PCR products, the localization of CHS homologues on two chromosomes, and the detection of two transcripts in mycelia and protoplasts. Polyclonal anti-chitin synthase antibodies raised against the N-terminal and the neutral fragments of the CHS2 products revealed, respectively, two and four proteins in membrane fractions and a truncated active form in entrapped product. The overall comparison of the structure and organization of CHS genes indicates that in spite of their divergent evolution, Oomycetes and chitinous fungi have evolved with conserved chitin synthase systems.

A novel 1,3-ß-glucan synthase from the oomycete Saprolegnia monoica.

An apparently novel 1,3-ß-glucan synthase from the oomycete Saprolegnia monoica has been characterized. The enzyme exhibits properties that differ markedly from those of the enzyme previously described [Fèvre, M. & Dumas, C. (1977). J Gen Microbiol 103, 297-306] as it is active at alkaline pH, stimulated by the divalent cations Ca2+, Mg2+ and Mn2+, and appears to be located mainly in the apical part of the hypha. Taking into consideration the differences in pH optimum and effect of divalent ions, each enzyme activity could be assayed in the presence of the other. The insoluble polymeric product of the enzyme with alkaline pH optimum was characterized as a linear 1,3-ß-glucan. Comparisons of the general properties of 1,3-ß-glucan synthases suggest that enzymes from the oomycetes are more closely related to enzymes from higher plants than to those of true fungi, reflecting the fact that the oomycetes are highly divergent from chitinous fungi.