Chitinases are thought to be involved in the morphogenesis and autolysis of filamentous fungi. We cloned a gene (chiB) encoding a class V chitinase from Aspergillus nidulans. ChiB expressed in Escherichia coli had chitin-hydrolyzing activity, indicating that chiB encoded a chitinase. Deletion of chiB affected neither germination efficiency nor hyphal growth rate, but considerably reduced the intracellular and extracellular chitinase activities. The decrease in hyphal dry weight during autolytic phase was slower in the mutant than in the wild-type strain. Western blot analysis indicated that the quantity of ChiB significantly increased when the wild-type mycelia were starved for carbon sources, a condition that induced hyphal autolysis. These results suggest that chiB plays an important role in the autolytic process in A. nidulans.

Two 3-phosphoglycerate kinase genes (pgk1 and pgk2) were cloned from Rhizopus niveus. It was deduced that both pgk genes have two introns. They have open reading frames of 1355 bp and 1356 bp, and code for proteins of 417 and 416 amino acids, respectively. The first introns of both genes are located at similar positions as those of pgk genes from other fungi based on the deduced amino-acid sequences of PGK proteins. The position of their second introns was similar to that of the seventh intron of the human pgk gene. The deduced amino-acid sequences of PGK proteins show high identity (64.8–72.2%) to those of PGKs of other filamentous fungi. When the promoters of each of the pgk genes were fused to the E. coli β-glucuronidase (GUS) gene and introduced into R. niveus, significant GUS activities were detected in the cell lysates of the transformants, suggesting that GUS protein was expressed under the control of both pgk gene promoters in R. niveus. GUS activity was induced by glucose but not by glycerol, indicating that expression of R. niveus pgk genes was regulated by the carbon source.

The chsA and chsC encode classes II and I chitin synthases, respectively, of the filamentous fungus Aspergillus nidulans. The ΔchsA ΔchsC double mutants (ΔAC mutants) show defects in asexual development: a striking reduction in the number of conidiophores and aberrant conidiophore morphology. Here, we examined the involvement of regulatory genes for asexual development (brlA, abaA, and medA) in the conidiation defects of the ΔAC mutants. Spatial expression patterns of brlA,abaA, and medA in conidiophores of the wild-type strains and ΔAC mutants were examined by in-situ staining using a reporter gene; expression of either gene was detected at abnormal sterigmata in the ΔAC mutants as well as at normal ones in the wild-type strain. However, abaA expression was not prominent at a subset of conidiophores developing long chains of aberrant sterigmata, suggesting that induction of the abaA expression was retarded in the ΔAC mutants. Based on these results and those previously presented, possible mechanisms involved in the conidiation defects are discussed.

Summary

Rhizopus niveus has been transformed to blasticidin S resistance by vectors containing the bacterial blasticidin S resistance gene under the control of a Rhizopus promoter. Southern analysis of the total DNA from transformants indicated that the introduced DNA was rearranged, and that one of the transformants harbored extrachromosomal plasmids with rearranged DNA. Using this transformation system, the introduction of pUBSR101, a plasmid carrying the Escherichia coli lacZ gene fused to the promoter and the N-terminal region of the R. niveus aspartic proteinase-II (RNAP-II) gene, resulted in an increase of β-galactosidase activity in the cell extract, indicating expression of the lacZ fusion gene in R. niveus. This is the first report of a transformation system for filamentous fungi using the blasticidin S resistance gene as a dominant selectable marker.

The filamentous fungus, Aspergillus nidulans, genome contains at least five chitin synthase-encoding genes. chsB is essential for normal hyphal growth. chsA and chsC are likely to be cooperatively required for hyphal wall integrity. In this study, we constructed chsA chsB and chsC chsB double mutants, in which chsB expression was under a repressible promoter [alcA(p)]. While chsA or chsC single mutants did not show obvious growth defects, the chsA chsB and chsC chsB double mutants showed different phenotypes from the chsB single mutant and from each other under alcA(p)-repressing conditions. The chsA chsB double mutant produced fewer aerial hyphae and the chsC chsB double mutant showed reduced cell mass. These observations support the idea that chsA and chsC each play a different role in hyphal morphogenesis. In addition, the chitin contents of these double mutants were higher than those of the chsB single mutant. When chsA was expressed ectopically under the chsB promoter in the chsB mutant, the growth defects caused by chsB repression were not remedied at all, although an increased level of chsA mRNA was observed. Thus, it is suggested that the gene products of chsA and chsB themselves have different functions in hyphal morphogenesis.