Aspergillus Fabm Encodes an Essential Product That Is Related to Poly(a)-Binding Proteins and Activates Development When Overexpressed

Overexpression of several different Aspergillus nidulans developmental regulatory genes has been shown to cause inappropriate developmental activation and growth inhibition. We previously exploited this observation that induced development caused growth inhibition in designing a screen to identify other genes that could activate development when overexpressed. We identified 16 mutants in which induced expression of different random genomic DNA sequences caused growth inhibition, accumulation of mRNA corresponding to the brlA developmental regulatory locus, and in several cases sporulation. This phenotype was designated FAB for Forced expression Activation of brlA and the genes were called fabA through fabP. Here we describe one of these genes, fabM, which is predicted to encode a poly(A)-binding protein (PABP) that is constitutively expressed and is essential for viability. While it is unclear why overexpression of the fabM caused sporulation, we showed that this activity required other known early developmental regulators including brlAβ, flbA, flbB, flbC, and fluG. We propose that fabM is an example of a gene that is not only required for growth, but also has specific functions early in development that assist developmental induction, presumably by allowing translation of specific mRNAs like brlA.     

Isolation of Aspergillus nidulans Mutants That Overcome brlA-Induced Growth Arrest

The Aspergillus nidulans brlA gene is a primary regulator of development-specific gene expression during conidiation. Forced activation of brlA in vegetative cells leads to inappropriate induction of conidiophore formation and causes growth to stop. In fact, when conidia containing a nutritionally inducible brlA gene fusion are placed on inducing medium, they fail to germinate. We used this phenotype to select 174 mutants that continue growing following such forced brlA activation. Forty-six of these mutants also produced abnormal developmental structures during air-induced conidiation as expected if the mutations resulted in an altered response to BrlA (designated sbr mutants for suppressors of brlA response). The predominant mutant class identified was defective in a known developmental regulatory gene, abaA. We also identified mutants with defects in the previously characterized early acting developmental regulatory genes flbB and flbD and in four previously undescribed loci designated sbrA-D. sbrA mutants represent the second largest group and are characterized by production of conidiophore stalks that lack a normal vesicle and form branching sterigmata that rarely make spores. Because abaA expression could not be detected in sbrA mutants following brlA activation we propose that sbrA functions as a developmental modifier, participating in brlA-dependent activation of other developmental regulators.     

RcoA has pleiotropic effects on Aspergillus nidulans cellular development

Aspergillus nidulans rcoA encodes a member of the WD repeat family of proteins. The RcoA protein shares sequence similarity with other members of this protein family, including the Saccharomyces cerevisiae Tup1p and Neurospora crassa RCO1. Tup1p is involved in negative regulation of an array of functions including carbon catabolite repression. RCO1 functions in regulating pleiotropic developmental processes, but not carbon catabolite repression. In A. nidulans, deletion of rcoA (DeltarcoA), a recessive mutation, resulted in gross defects in vegetative growth, asexual spore production and sterigmatocystin (ST) biosynthesis. Expression of the asexual and ST pathway-specific regulatory genes, brlA and aflR, respectively, but not the signal transduction genes (i.e. flbA, fluG or fadA) regulating brlA and aflR expression was delayed (brlA) or eliminated (aflR) in a DeltarcoA strain. Overexpression of aflR in a DeltarcoA strain could not rescue normal expression of downstream targets of AflR. CreA-dependent carbon catabolite repression of starch and ethanol utilization was only weakly affected in a DeltarcoA strain. The strong role of RcoA in development, vegetative growth and ST production, compared with a relatively weak role in carbon catabolite repression, is similar to the role of RCO1 in N. crassa.     

A protein kinase C-encoding gene, pkcA, is essential to the viability of the filamentous fungus Aspergillus nidulans

A protein kinase C (PKC)-encoding gene (pkcA) was isolated from the filamentous fungus Aspergillus nidulans. Although we attempted to isolate pkcA deletion mutants, we obtained only heterokaryons that had both DeltapkcA and pkcA(+) nuclei. Conidia produced by the heterokaryon germinated. The germ tubes, however, lysed frequently and no colony formation was observed, indicating that the pkcA gene is essential to the viability of A. nidulans. We constructed conditional mutants (alcA(p)-pkcA mutants) that expressed pkcA under the control of the alcA promoter (alcA(p)). Under alcA(p)-repressing conditions, their colonies were smaller than those of the wild-type strains and their hyphae lysed frequently. These phenotypes were not remedied under moderate- or high-osmolarity conditions; the growth defect deteriorated further under the latter. Under alcA(p)-inducing conditions, the alcA(p)-pkcA mutants also showed growth-sensitivity to cell wall destabilizing agents. These results indicate that pkcA plays an important role in the maintenance of cell integrity.     

Regulation of conidiation by light in Aspergillus nidulans

Light regulates several aspects of the biology of many organisms, including the balance between asexual and sexual development in some fungi. To understand how light regulates fungal development at the molecular level we have used Aspergillus nidulans as a model. We have performed a genome-wide expression analysis that has allowed us to identify >400 genes upregulated and >100 genes downregulated by light in developmentally competent mycelium. Among the upregulated genes were genes required for the regulation of asexual development, one of the major biological responses to light in A. nidulans, which is a pathway controlled by the master regulatory gene brlA. The expression of brlA, like conidiation, is induced by light. A detailed analysis of brlA light regulation revealed increased expression after short exposures with a maximum after 60 min of light followed by photoadaptation with longer light exposures. In addition to brlA, genes flbA-C and fluG are also light regulated, and flbA-C are required for the correct light-dependent regulation of the upstream regulator fluG. We have found that light induction of brlA required the photoreceptor complex composed of a phytochrome FphA, and the white-collar homologs LreA and LreB, and the fluffy genes flbA-C. We propose that the activation of regulatory genes by light is the key event in the activation of asexual development by light in A. nidulans.     

FluG-BrlA途径参与构巢曲霉无性发育机制的研究进展

构巢曲霉是丝状真菌的模式生物,已对其无性发育机制进行了比较充分的研究。本文以FluG-BrlA途径参与构巢曲霉无性发育机制的研究为切入点,综述了构巢曲霉无性发育中心调控路径中各主要成员如brlA、abaA、wetA,中心调控路径修饰基因如stuA、medA及中心调控路径激活因子fluG、flbA-E的研究进展,绘制出构巢曲霉无性发育相关基因遗传位置模式图。研究将为其它丝状真菌无性发育机制的研究提供参考。     

Interactions of three sequentially expressed genes control temporal and spatial specificity in Aspergillus development

Aspergillus nidulans brlA, abaA, and wetA form a dependent pathway that regulates asexual reproductive development. The order in which these genes are expressed determines the outcome of development. Expression of brlA in vegetative cells leads to activation of abaA and wetA, cessation of vegetative growth, cellular vacuolization, and spore formation. By contrast, expression of abaA in vegetative cells does not result in conidial differentiation but does lead to activation of brlA and wetA, cessation of vegetative growth, and accentuated cellular vacuolization. brlA, abaA, and wetA act individually and together to regulate their own expression and that of numerous other sporulation-specific genes. We propose that the central pathway controlling development is largely autoregulatory. The timing and extent of expression of the regulatory genes and their targets are determined as development proceeds by intrinsically controlled changes in the relative concentrations of regulatory gene products in the various conidiophore cell types.     

brlA requires both zinc fingers to induce development.

Expression of the Aspergillus nidulans brlA gene induces a developmental pathway leading to the production of asexual spores. We have introduced mutations into brlA that are expected to disrupt either or both Cys2-His2 Zn(II) coordination sites postulated to exist in the BrlA polypeptide. The resultant brlA alleles fail to induce either the asexual reproductive pathway or the expression of development-specific genes. These data support the hypothesis that brlA encodes a nucleic acid-binding protein whose activity requires each of two zinc fingers.     

Differential Esterase Expression in Developmental Mutants of Aspergillus nidulans

Esterase isozymes were used to detect substrate-preference polymorphism in five strains of Aspergillus nidulans, and to show differential gene expression in developmental mutants in response to 5-azacytidine treatment. The medusa mutants B116, SM23, and M25 were selected in the presence of 5-azacytidine (5AC); also the G839 bristle mutant obtained in the absence of 5AC as well as the UT196 master strain and the normal segregant SM24 were used for the esterase studies. The esterase isozyme patterns of the A. nidulans strains observed with 4-methylumbelliferyl esters and alpha- and beta-naphthyl esters indicated a total of 18 isoesterases. Substrate preference for either 4-methylumbelliferyl esters and alpha- or beta-naphthyl esters was observed. Similarity between the different A. nidulans genotypes was 84.4-100%. The genomic similarity of the B116, SM23, and M25 mutant strains (100%) supports previous observations that specific DNA sequences might be targets for 5AC action in this filamentous fungus, and the differential expression of the Est-4 isozyme in the medusa developmental mutant and the Est-2 isozyme specifically detected in the bristle mutant G839 seems to indicate esterase isozymes as possible markers of biochemical differences among different developmental mutants of A. nidulans.