Regions in theZ5 mating gene ofSchizophyllum commune involved in Y-Z binding and recognition

The A mating locus of the woodrotting fungusSchizophyllum commune encodes two multiallelic genes,Y andZ, which regulate the A-pathway of development. TheY alleles contain a homeobox, suggesting that the Y proteins may be DNA-binding regulatory proteins. During mating, development is induced when Y from one mating partner interacts with Z from the other mating partner; self combinations of Y and Z are inactive. Two-hybrid analyses indicate that nonself combinations of Y and Z form heteromultimers and self combinations do not. To understand Y-Z binding and self- nonself recognition further we used mutagenesis and chimeras to identify regions in one allele ofZ(Z5) that are involved in these processes. Here we report the results, which broadly define regions in Z5 that are essential for activity, Y-Z binding and Z5 allelic specificity.The sequence reported in this paper has been deposited in the Genbank database under accession number U22049     

Derepressible proteolytic activity in homokaryotic hyphae ofSchizophyllum commune

Proteolytic activity produced bySchizophyllum commune homokaryons was derepressed upon starvation of plate-grown cultures for nitrogen. Decreasing thel-asparagine concentration in the growth medium resulted in slower growth (as total protein), alteration of colonial morphology, and an increase in mycelial and extracellular protease specific activity against hide-powder azure. In comparisons between colonies grown on minimal medium (1 g/literl-Asn), 0.1 ×l-Asn, 0.01 ×l-Asn, and Nol-Asn medium, mycelial proteolytic specific activity increased 2- to 8-fold. Mycelial specific activity also generally increased as the colonies aged. In addition, substantial increases, up to 100-fold, in extracellular protease specific activity occurred under conditions of nitrogen deprivation. This derepression could result in increased mycelial protein turnover and, potentially, proteolysis of extracellular substrates.     

Mitosis in hyphae ofSchizophyllum commune Fr.

Summary In hyphae of the basidiomyceteSchizophyllum commune Fr. mitosis occurs through a longitudinal division of a strand of chromatin, which is followed by a parallel separation of the daughter strands.     

Light and electron microscope study of unilateral mating between a secondary mutant and a wild-type strain ofSchizophyllum commune

Summary After hyphal fusions between the secondary mutant and wild-type strains ofSchizophyllum commune some of the fused hyphae show several nuclei per cell and dissolved septa. These hyphae are designated migration hyphae because they are evidently the main routes of nuclear exchange between the two strains. On the wild-type side of the mating the nuclei spread gradually from the main part of the migration hyphae into the side branches, which develop into an extensive network with many anastomoses. The first cells with pseudoclamps or clamp connections are observed in this network.On the mutant side of the mating the branching is less developed and the number of anastomoses is smaller. The cross walls of the septa are poorly dissolved, and nuclear aggregations occur in the hyphae. No development of clamp connections or pseudoclamps is observed. It is suggested that the unilateral mating response of the secondary mutant strain might possibly be caused by the failure of the septa in the mutant hyphae to dissolve, which inhibits the distribution of the nuclei into the side branches of migration hyphae.     

Abnormal genesis of basidiospores in a mutant stock ofSchizophyllum commune FR

The Kniep stock subcultured for more than 45 years in the Centraal Bureau voor Schimmelcultures at Baarn, Netherlands, contains a burden of morphological and biochemical mutations. It is said to have been originally a monokaryon; something has obviously happened to it: either it has been mislabeled, or it has become contaminated during its long period of subculturing.Our results obtained from outcrossing, indicate that the Kniep stock is a dikaryon. Even mycelia derived from single spores behave as dikaryons and heterokaryons. An explanation of the abnormal behaviour of monosporous mycelia isolated from the Kniep stock is given in terms of impaired distribution of the nuclei from the basidia to the basidiospores, resulting in mono-, di-, and heterokaryotic basidiospores.     

Ultrastructural differences between wall apices of growing and non-growing hyphae ofSchizophyllum commune

Summary Newly synthesized chitin at the hyphal apex ofSchizophyllum commune was shown to be highly susceptible to chitinase degradation and solubilization by dilute mineral acid. With time this chitin became gradually more resistant to these treatments. With a combination of the shadow-cast technique and electron microscopic autoradiography it could be shown that this process occurred as the newly synthesized chitin moved into subapical parts of growing hyphae but also in non-growing apices which had ceased growth after incorporation of theN-acetyl[6-³H]glucosamine. These results are in agreement with a model which explains apical morphogenesis by assuming that the newly synthesized wall material at the apex is plastic due to the presence of individual polymer chains but becomes rigidified because of subsequent physical and chemical changes involving these polymers.Dedicated to Dr. A.Quispel, Professor of Botany at the University of Leiden, on occasion of his retirement.     

CHS5, a gene involved in chitin synthesis and mating in Saccharomyces cerevisiae.

The CHS5 locus of Saccharomyces cerevisiae is important for wild-type levels of chitin synthase III activity. chs5 cells have reduced levels of this activity. To further understand the role of CHS5 in yeast, the CHS5 gene was cloned by complementation of the Calcofluor resistance phenotype of a chs5 mutant. Transformation of the mutant with a plasmid carrying CHS5 restored Calcofluor sensitivity, wild-type cell wall chitin levels, and chitin synthase III activity levels. DNA sequence analysis reveals that CHS5 encodes a unique polypeptide of 671 amino acids with a molecular mass of 73,642 Da. The predicted sequence shows a heptapeptide repeated 10 times, a carboxy-terminal lysine-rich tail, and some similarity to neurofilament proteins. The effects of deletion of CHS5 indicate that it is not essential for yeast cell growth; however, it is important for mating. Deletion of CHS3, the presumptive structural gene for chitin synthase III activity, results in a modest decrease in mating efficiency, whereas chs5delta cells exhibit a much stronger mating defect. However, chs5 cells produce more chitin than chs3 mutants, indicating that CHS5 plays a role in other processes besides chitin synthesis. Analysis of mating mixtures of chs5 cells reveals that cells agglutinate and make contact but fail to undergo cell fusion. The chs5 mating defect can be partially rescued by FUS1 and/or FUS2, two genes which have been implicated previously in cell fusion, but not by FUS3. In addition, mating efficiency is much lower in fus1 fus2 x chs5 than in fus1 fus2 x wild type crosses. Our results indicate that Chs5p plays an important role in the cell fusion step of mating.     

Effect of adenosine 3′,5′-cyclic monophosphate on the morphogenesis of fruit bodies ofSchizophyllum commune

Adenosine 3′,5′-cyclic monophosphate has been found to affect the normal development of fruit bodies in the basidiomyceteSchizophyllum commune. At a concentration of 10^-3 M, cyclic AMP causes many fruit bodies to cease morphogenesis at an early stage. Those fruit bodies which continue development have either no gills or abnormal gills. A pronounced effect was also observed on the fruit bodies carrying a dominant mutant.     

Molecular cloning of RNAs differentially expressed in monokaryons and dikaryons ofSchizophyllum commune in relation to fruiting

A complementary DNA library cloned in pBR327 was prepared from RNA of a fruiting dikaryon of the basidiomyceteSchizophyllum commune. An improved colony-lysis method led to the isolation of complementary DNA clones hybridizing to nine different RNAs abundantly present in the fruiting dikaryon but present in very low or undetectable levels in the monokaryons. One of these RNAs, measuring 580 nucleotides, was exceptional in contributing more than 3% to the mRNA mass of the fruiting dikaryon. A role of the detected dikaryon-specific RNAs in fruiting was suggested by (i) their absence or low concentration in vegetatively growing monokaryons or the dikaryon, (ii) their steep increase in concentration during fruit-body formation in the dikaryon, (iii) a higher concentration of most of these RNAs in the fruit-body initials than in the supporting mycelium, and (iv) their prevalence in full-grown fruit bodies. The “fruiting-specific” RNAs were also present in a suspension-grown dikaryon, in the absence of fruiting, but in concentrations less than 10% of those in surface-grown fruiting dikaryon. The level of expression of these RNAs in the monokaryons was even lower or undetectable. Since the dikaryon and the monokaryons are otherwise coisogenic, it appears that the presence of two different incompatibility genes in the dikaryon allows for a low level of expression of the “fruiting genes” even in the absence of fruiting, whereas the genes are fully expressed under conditions permitting fruit-body formation.     

Griseofulvin-induced alterations in site of dividing nuclei and structure of septa in a dikaryon ofSchizophyllum commune

Summary Ultrastructural study of a dikaryon of the basidiomyceteSchizophyllum commune showed that treatment with griseofulvin affected the site of the dividing nuclei and the location and structure of the septa. The microtubules were considered to be the primary target of griseofulvin, since they participate in nuclear division and movement in the hyphae, and their assembly is known to be in other organisms than fungi inhibited by griseofulvin. It is pointed out that dikaryotic hyphae with two nuclei and a clamp connection per cell are more sensitive indicators of the effect of griseofulvin than homokaryotic hyphae, whose structure is less complex.     

Occurence of microtubules and microfilaments,and origin of septa in dikaryotic hyphae ofSchizophyllum commune

Summary In an electron microscopic study on the dikaryotic hyphae ofSchizophyllum commune, microtubules were observed during the nuclear division, and close to the non-dividing nuclei of apical cells and older cells. Microtubules of the spindle were connected with semicircular bodies at nuclear poles. Microfilaments were detected in the distal part of the apical cells. Vesicles similar to those in the tips of the hyphae occured also at the sites of septa formation. The occurrence of microtubules and the structure of semicircular bodies are compared with those in other basidiomycetes. It is suggested that vesicles are involved in the primary growth of the septal cross wall.     

Ultrastructure and localization of wall polymers during regeneration and reversion of protoplasts ofSchizophyllum commune

Summary Cell-wall regeneration and reversion of protoplasts ofSchizophyllum commune were investigated using electron microscopic methods and X-ray diffraction.After 3 hours of regeneration protoplasts have formed a loosely organized wall which does not react with Thiéry's stain for periodic acid sensitive carbohydrates. This wall largely consists of chitin microfibrils which are adpressed to the plasmalemma and which are covered by loose aggregates of alkali-soluble S-glucan (-1,3-glucan). Both components are microcrystalline, at least partly. Walls formed in the presence of polyoxin D only consist of thick loose fibers of S-glucan.From 3 hours onward the inner chitin microfibrils of the wall of the primary cells become embedded in alkali-insoluble material that stains heavily with the Thiéry reagent and probably is similar to the R-glucan of the mature wall (i.e., -1,3--1,6-glucan). The outer chitin microfibrils remain free of this matrix and are covered by S-glucan only.Bud-like structures that arise have the same wall architecture as the primary cells,i.e., only the inner chitin microfibrils are embedded in R-glucan and the S-glucan forms a fluffy coat. The walls of hyphal tubes that arise are distinct, however, in that all chitin microfibrils are embedded in R-glucan and the S-glucan forms a compact coat.Cytoplasmic vesicles are sparse in primary cells except at the sites of emergence of budlike structures and hyphae. They continue to be present in the apex of growing hyphae.     

Role of a cell-wall glucan-degrading enzyme in mating of Schizophyllum commune

Mycelial enzyme extracts of Schizophyllum commune were prepared during vegetative growth matings leading to common-A and common-B heterokaryons and the dikaryon, and were examined for hydrolytic activity against an alkaliinsoluble cell-wall glucan (R-glucan) isolated from this mushroom. In extracts from several individual homokaryotic mycelia the R-glucanase activity was low and did not increase when the cultures exhausted glucose in the medium. In common-A matings, a 30-fold increase in specific activity of intracellular R-glucanase was found even in the presence of glucose in the broth. An increase of this magnitude was not observed in the common-B mating nor in the fully compatible cross leading to the dikaryon. Extracts of the dikaryon did show elevated R-glucanase activity after exogenous glucose disappearance and subsequent fruiting. In none of these situations was an enzyme activity detected towards an alkali-soluble cell-wall glucan (S-glucan) prepared from S. commune. Changes in R-glucanase were not parallelled by identical changes in laminarinase, pustulanase, cellobiase, and p-nitrophenyl-beta-d-glucosidase, but comparable increases in specific activities were found for hydrolysis of glycogen and maltose. After interaction of the various mycelia in mating combinations, the S-glucan/R-glucan ratio of the cell wall of the dikaryon was found to be similar to that of the homokaryons, but increased in the common-B interaction and was elevated almost threefold in the common-A heterokaryon.     

Mating types and pheromone recognition in the Homobasidiomycete schizophyllum commune.

In the homobasidiomycete Schizophyllum commune the mating type genes of the B locus encode pheromones and pheromone receptors in multiple allelic specificities. Interaction of non-self pheromones and receptors leads to induction of B-regulated development easily scored in S. commune by the "flat" phenotype which lacks aerial mycelium formation and shows aberrant hyphal morphology. In contrast, self pheromones are not recognized and B-regulated development is not induced. Natural and mutant alleles of receptors have been analyzed for their specificity in transformation assays, and parts of the receptor involved in ligand discrimination can be described. The biological role of pheromone response in S. commune is assumed to be connected to nuclear migration based on the observation that wild-type cells with a receptor gene of different specificity lead to cells capable of nuclear uptake. Other possible roles for pheromone function are discussed.     

Integrin beta1-chain residues involved in substrate recognition and specificity of binding to invasin

A highly conserved 14-amino-acid region of the chicken beta1 integrin chain (beta1chk residues 151-168) hypothesized to be involved in divalent cation coordination was analysed to determine whether invasin uses the same structural determinants as fibronectin (Fn) to recognize receptors. For the most part, both proteins required similar beta1 chain residues for integrin recognition, although the relative preference of the integrin for the two substrates could be inverted mutationally. Substitution mutations in the amino terminal residues of this region resulted in defective binding to both substrates by the receptor, while substitutions at the carboxyl-terminal end of this region were better tolerated. A derivative carrying the double substitution (KDD160RDV) had the unique phenotype of maintaining Fn binding while abolishing invasin binding, indicating that this region of the receptor may determine substrate specificity. These data indicate that the integrin beta1 chain possesses a ligand binding site shared by invasin and Fn that can be altered by mutation to allow greater preference for the normally lower affinity substrate Fn than for invasin. It was also established that the region analysed has the ability to bind divalent cations.