Regulation of hsp90 and hsp70 genes during antheridiol-induced hyphal branching in the oomycete Achlya ambisexualis.

When mycelia of Achlya ambisexualis J. Raper strain E87 were undergoing antheridial branching, a marked increase was observed in the levels of transcript populations encoding the heat shock protein chaperone Hsp90 and transcript populations encoding three different Hsp70-family heat shock protein chaperones, respectively. Although up to 90% of hyphae in the hormone-treated thalli were undergoing antheridial branching, no similar increase in the level of transcripts encoding actin was observed. Nuclear run-on assays demonstrated that the observed antheridiol-induced increases in the levels of the chaperone RNAs resulted from increased transcription. Although not tested for function, the nucleotide sequence of the 5' flanking region of each of the two A. ambisexualis hsp90 genes revealed a diversity of sequences and motifs similar or identical to the sequences of known transcription factor response elements. Among these potential response element sequences observed in the A. ambisexualis genes were motifs observed also in animal steroid hormone response elements. Surrounding the primer-extension determined transcription start site of each A. ambisexualis hsp90 gene was a 16-nucleotide sequence that matched in 14 out of 16 nucleotides a sequence found in the transcription initiation region of many different oomycete genes.

Hsp90-containing multiprotein complexes in the eukaryotic microbe Achlya.

In the oomycete fungus Achlya ambisexualis, hyphae of the male strain undergo sexual differentiation in the presence of the steroid hormone antheridiol. Earlier studies demonstrated that antheridiol binds with high affinity to a 9S multiprotein complex from A. ambisexualis cytosols. Although these complexes were found to contain the heat shock protein Hsp90, the other components were not known. It was of interest to determine if any of the other protein components in the Achlya Hsp90-heterocomplexes would be homologous to those found in the steroid receptor-Hsp90-heterocomplexes of vertebrates. Cytosolic proteins of 110 kDa, 74 kDa, 64 kDa, 61 kDa, 56 kDa, 47 kDa, 27 kDa and 23 kDa, were found in repeated trials, to co-immunoprecipitate with Achlya Hsp90. The 74 kDa protein was identified as the heat shock protein Hsp70, the 23 kDa protein was found to be related to the vertebrate protein p23 and the 56 kDa protein was found to be related to immunophilin FKBP51. All three of these proteins are components of the vertebrate receptor heterocomplexes. The 110 kDa, 61 kDa and 27 kDa proteins appeared to be unique to the Achlya complexes. Unlike the seven other proteins co-immunoprecipitating with Hsp90, the 61 kDa protein was observed only in the co-immunoprecipitates produced from in vitro translates of RNA isolated from antheridiol-treated mycelia.

Regulation of two different hsp70 transcript populations in steroid hormone-induced fungal development.

In the filamentous oomycete fungus Achlya, the differentiation of gamete bearing structures on vegetative hyphae of the male mating type, is induced by the Achlya steroid hormone, antheridiol. Among the several metabolically labeled intracellular proteins whose synthesis or accumulation is altered by hormone treatment are steroid-induced 85-kDa and 68- to 78-kDa proteins. The 85-kDa protein was previously shown to be the Achlya heat shock protein hsp85 [Brunt et al., 1990; Brunt and Silver, 1991], a component of the putative Achlya steroid hormone receptor. It was of interest to determine if the antheridiol-induced "70-kDa" proteins were hsp70-family heat shock proteins and if hormone treatment-induced changes in the level of hsp70 transcripts. Two different Achlya hsp70 genomic sequences were cloned and used to investigate these questions. The two hsp70 sequences recognized two different mycelial transcript populations, one of which was regulated also by decreased glucose. Of note, both of the two hsp70 transcript populations were found to be regulated by antheridiol. The hormone-induced changes in hsp70 transcript levels were temporally correlated with the onset of massive lateral hyphal branching and alterations in the pattern of secreted N-linked glycoproteins which occur in hormone-treated mycelia. To our knowledge, this represents one of the first reports on changes in hsp70 proteins and transcripts during fungal differentiation. Our results may have implications for the role of heat shock proteins in hyphal branching and secretion in filamentous fungi and perhaps other cell types.

Molecular cloning and characterization of two distinct hsp85 sequences from the steroid responsive fungus Achlya ambisexualis.

In Achlya ambisexualis, hsp85 is one of the characteristic mycelial heat shock proteins induced in response to a rapid elevation in temperature (Silver et al. 1983). This heat shock protein has the same electrophoretic mobility on two-dimensional gels and is antigenically related to an 85 kDa steroid hormone-regulated protein which constitutes a component of the putative Achlya steroid hormone-receptor complex. We report here the isolation of two distinct, yet highly related, hsp85 gene sequences from Achlya genomic libraries. Northern analyses, using these two Achlya genomic sequences as probes, suggest that there are two hsp85 message population in Achlya and that at least one of these is regulated by the steroid hormone antheridiol.

Steroid hormone regulation of the Achlya ambisexualis 85-kilodalton heat shock protein, a component of the Achlya steroid receptor complex.

The steroid hormone antheridiol regulates sexual development in the fungus Achlya ambisexualis. Analyses of in vivo-labeled proteins from hormone-treated cells revealed that one of the characteristic antheridiol-induced proteins appeared to be very similar to the Achyla 85-kilodalton (kDa) heat shock protein. Analysis of in vitro translation products of RNA isolated from control, heat-shocked, or hormone-treated cells demonstrated an increased accumulation of mRNA encoding a similar 85-kDa protein in both the heat-shocked and hormone-treated cells. Northern (RNA) blot analyses with a Drosophila melanogaster hsp83 probe indicated that a mRNA species of approximately 2.8 kilobases was substantially enriched in both heat-shocked and hormone-treated cells. The monoclonal antibody AC88, which recognizes the non-hormone-binding component of the Achyla steroid receptor, cross-reacted with Achlya hsp85 in cytosols from heat-shocked cells. This monoclonal antibody also recognized both the hormone-induced and heat shock-induced 85-kDa in vitro translation products. Taken together, these data suggest that similar or identical 85-kDa proteins are independently regulated by the steroid hormone antheridiol and by heat shock and that this protein is part of the Achyla steroid receptor complex. Our results demonstrate that the association of hsp90 family proteins with steroid receptors observed in mammals and birds extends also to the eucaryotic microbes and suggest that this association may have evolved early in steroid-responsive systems.

Cellular localization of steroid hormone-regulated proteins during sexual development in Achlya.

In the fungus Achlya ambisexualis sexual development in the male strain E87 is controlled by the steroid hormone antheridiol. To investigate the effects of antheridiol on the synthesis and/or accumulation of specific cellular proteins we have analysed [35S]methionine-labeled proteins from control and hormone-treated cells using both one-dimensional (1D) and two-dimensional (2D) PAGE. Since in a total cell extract, hormone-induced changes in specific proteins might not be apparent against a background of more abundant proteins, cells were fractionated prior to protein isolation. It was also necessary to establish a concentration of hormone carrier, in this case methanol, which by itself did not alter the pattern of protein synthesis. Using these approaches the addition of the hormone antheridiol to vegetatively growing cells of Achlya E87 was found to result in changes in the synthesis and/or accumulation of at least 16 specific proteins, which could be localized to the cytoplasmic, nuclear or cell wall/cell membrane fractions. The most prominent changes observed in the hormone-treated cells included the appearance in the cytoplasmic fraction of labeled proteins at 28.4 and 24.3 kD which were not detectable in control cells, and a significant enrichment in the labeling of a 24.3 kD protein in the cell wall/cell membrane fraction. A marked increase in the labeling of 85, 63 and 47 kD proteins in the nuclear fraction from hormone-treated cells was also noted. The molecular weight (MW) and the behavior on 2D gels of the 85 kD hormone-induced protein appeared very similar to that of the 85 kD heat-shock protein reported in Achlya. Quantitive changes in the [35S]methionine labeling of several other proteins were noted in all three cell fractions.

Steroid hormone-induced changes in secreted proteins in the filamentous fungus Achlya.

In the fungus Achlya, sexual development in the male strain E87 is mediated by the steroid hormone antheridiol. Treatment of vegetatively growing cells of E87 with antheridiol resulted in changes in the [35S]methionine labeling of several secreted proteins. The most heavily labeled group of proteins observed in the secreted fraction from control cells appeared on one-dimensional gels as a prominent wide band which could be resolved into three closely spaced components with relative molecular weights (MWs) of 57, 54, and 50 kD, respectively. After hormone treatment the two lower MW proteins of the group were barely detectable. Concomitant with the observed reductions in the labeling of the 54 and 50 kD proteins was the increased labeling of a doublet of very prominent proteins with relative MWs of 44.4 and 43 kD, respectively. The results of experiments with Endoglycosidase H suggested that the 44.4 and 43 kD proteins seen in hormone-treated cultures, might result from the removal or reduced synthesis of high mannose oligosaccharide groups found on the 54 and 50 kD proteins normally seen in control cultures. Additional support for this suggestion was provided by the observation that the 54 and 50 kD proteins from control cultures appeared to bind to conA columns and to be eluted with alpha-methylmannoside, while there was little or no binding of the 44.4 and 43 kD proteins from hormone-treated cells. Although other possibilities are not excluded, the results are suggestive of a steroid hormone-induced alteration in glycoprotein processing. The functions of the observed hormonally-responsive secreted proteins as well as those of the secreted proteins in non-hormone-treated cultures, are not known at this time.