Developmental regulation of a conidiation specific beta-tubulin in Aspergillus nidulans

Microtubules in Microorganisms: How Tubulin Isotypes Contribute to Diverse Cytoskeletal Functions

The cellular functions of the microtubule (MT) cytoskeleton range from relatively simple to amazingly complex. Assembled from tubulin, a heterodimeric protein with α- and β-tubulin subunits, microtubules are long, hollow cylindrical filaments with inherent polarity. They are intrinsically dynamic polymers that utilize GTP binding by tubulin, and subsequent hydrolysis, to drive spontaneous assembly and disassembly. Early studies indicated that cellular MTs are composed of multiple variants, or isotypes, of α- and β-tubulins, and that these multi-isotype polymers are further diversified by a range of posttranslational modifications (PTMs) to tubulin. These findings support the multi-tubulin hypothesis whereby individual, or combinations of tubulin isotypes possess unique properties needed to support diverse MT structures and/or cellular processes. Beginning 40 years ago researchers have sought to address this hypothesis, and the role of tubulin isotypes, by exploiting experimentally accessible, genetically tractable and functionally conserved model systems. Among these systems, important insights have been gained from eukaryotic microbial models. In this review, we illustrate how using microorganisms yielded among the earliest evidence that tubulin isotypes harbor distinct properties, as well as recent insights as to how they facilitate specific cellular processes. Ongoing and future research in microorganisms will likely continue to reveal basic mechanisms for how tubulin isotypes facilitate MT functions, along with valuable perspectives on how they mediate the range of conserved and diverse processes observed across eukaryotic microbes.

Tubulin isotypes - functional insights from model organisms

The microtubule cytoskeleton is assembled from the α- and β-tubulin subunits of the canonical tubulin heterodimer, which polymerizes into microtubules, and a small number of other family members, such as γ-tubulin, with specialized functions. Overall, microtubule function involves the collective action of multiple α- and β-tubulin isotypes. However, despite 40 years of awareness that most eukaryotes harbor multiple tubulin isotypes, their role in the microtubule cytoskeleton has remained relatively unclear. Various model organisms offer specific advantages for gaining insight into the role of tubulin isotypes. Whereas simple unicellular organisms such as yeast provide experimental tractability that can facilitate deeper access to mechanistic details, more complex organisms, such as the fruit fly, nematode and mouse, can be used to discern potential specialized functions of tissue- and structure-specific isotypes. Here, we review the role of α- and β-tubulin isotypes in microtubule function and in associated tubulinopathies with an emphasis on the advances gained using model organisms. Overall, we argue that studying tubulin isotypes in a range of organisms can reveal the fundamental mechanisms by which they mediate microtubule function. It will also provide valuable perspectives on how these mechanisms underlie the functional and biological diversity of the cytoskeleton.

Molecular basis of resistance to the microtubule-depolymerizing antitumor compound plocabulin

Plocabulin (PM060184) is a microtubule depolymerizing agent with potent antiproliferative activity undergoing phase II clinical trials for the treatment of solid tumors. Plocabulin shows antifungal activity virtually abolishing growth of the filamentous fungus Aspergillus nidulans. A. nidulans hyphae depend both on mitotic and interphase microtubules, as human cells. Here, we exploited the A. nidulans genetic amenability to gain insight into the mechanism of action of plocabulin. By combining mutations in the two A. nidulans β-tubulin isotypes we obtained a plocabulin-insensitive strain, showing that β-tubulin is the only molecular target of plocabulin in fungal cells. From a genetic screen, we recovered five mutants that show plocabulin resistance but do not carry mutations in β-tubulin. Resistance mutations resulted in amino acid substitutions in (1) two subunits of the eukaryotic translation initiation factor eIF2B activating the General Amino Acid Control, (2) TIM44, an essential component of the inner mitochondrial membrane translocase, (3) two transcription factors of the binuclear zinc cluster family potentially interfering with the uptake or efflux of plocabulin. Given the conservation of some of the identified proteins and their respective cellular functions in the tumor environment, our results pinpoint candidates to be tested as potential biomarkers for determination of drug efficiency.

RrmA regulates the stability of specific transcripts in response to both nitrogen source and oxidative stress

Differential regulation of transcript stability is an effective means by which an organism can modulate gene expression. A well-characterized example is glutamine signalled degradation of specific transcripts in Aspergillus nidulans. In the case of areA, which encodes a wide-domain transcription factor mediating nitrogen metabolite repression, the signal is mediated through a highly conserved region of the 3′ UTR. Utilizing this RNA sequence we isolated RrmA, an RNA recognition motif protein. Disruption of the respective gene led to loss of both glutamine signalled transcript degradation as well as nitrate signalled stabilization of niaD mRNA. However, nitrogen starvation was shown to act independently of RrmA in stabilizing certain transcripts. RrmA was also implicated in the regulation of arginine catabolism gene expression and the oxidative stress responses at the level of mRNA stability. ΔrrmA mutants are hypersensitive to oxidative stress. This phenotype correlates with destabilization of eifE and dhsA mRNA. eifE encodes eIF5A, a translation factor within which a conserved lysine is post-translationally modified to hypusine, a process requiring DhsA. Intriguingly, for specific transcripts RrmA mediates both stabilization and destabilization and the specificity of the signals transduced is transcript dependent, suggesting it acts in consort with other factors which differ between transcripts.

β-Tubulins in Gibberella zeae: their characterization and contribution to carbendazim resistance

BACKGROUND

Fusarium head blight caused by Gibberella zeae is an important disease of wheat and barley because it reduces grain yield and quality and results in the contamination of grain with mycotoxins. Recent studies have shown that carbendazim resistance in field strains of G. zeae is not caused by mutation of the β-tubulin gene (β₁ tub), which is the case with other filamentous fungi, but that fungicide resistance is greatly increased by deletion of β₁ tub. The aim of the present study was to clarify the function of β₁ tub and its role in carbendazim resistance in G. zeae by artificial gene operation.

RESULTS

Deletion of β₁ tub reduced vegetative growth and pathogenicity but increased asexual reproduction in G. zeae. All the mutants were more resistant to carbendazim than parent strains. A three-dimensional model of β₁ tub was constructed, and the possible carbendazim binding site was analysed.

CONCLUSION

β₁ tub is not an essential gene in G. zeae, but it affects the sensitivity of the fungus to carbendazim.

The Aspergillus nidulans cetA and calA genes are involved in conidial germination and cell wall morphogenesis

The Aspergillus nidulans genes cetA (AN3079.2) and calA (AN7619.2) encode a novel class of fungal thaumatin-like proteins of unknown function. Deletion of cetA does not result in an observable phenotype [Greenstein, S., Shadkchan, Y., Jadoun, J., Sharon, C., Markovich, S., Osherov, N., 2006. Analysis of the Aspergillus nidulans thaumatin-like cetA gene and evidence for transcriptional repression of pyr4 expression in the cetA-disrupted strain. Fungal Genet. Biol. 43, 42-53]. We prepared knockout calA and calA/cetA A. nidulans strains. The calA mutants were phenotypically identical to the wild-type. In contrast, the cetA/calA double mutant showed a synthetic lethal phenotype suggesting that the two genes affect a single function or pathway: most of its conidia were completely inhibited in germination. Many collapsed and underwent lysis. A few showed abnormal germination characterized by short swollen hyphae and abnormal hyphal branching. Nongerminated conidia contained a single condensed nucleus suggesting a block in early germination. This is the first functional analysis of the novel cetA/calA family of thaumatin-like genes and their role in A. nidulans conidial germination. We show that CETA and CALA are secreted proteins that together play an essential role in early conidial germination.

Coding tandem repeats generate diversity in Aspergillus fumigatus genes

Genes containing multiple coding mini- and microsatellite repeats are highly dynamic components of genomes. Frequent recombination events within these tandem repeats lead to changes in repeat numbers, which in turn alters the amino acid sequence of the corresponding protein. In bacteria and yeasts, the expansion of such coding repeats in cell wall proteins is associated with alterations in immunogenicity, adhesion, and pathogenesis. We hypothesized that identification of repeat-containing putative cell wall proteins in the human pathogen Aspergillus fumigatus may reveal novel pathogenesis-related elements. Here, we report that the genome of A. fumigatus contains as many as 292 genes with internal repeats. Fourteen of 30 selected genes showed size variation of their repeat-containing regions among 11 clinical A. fumigatus isolates. Four of these genes, Afu3g08990, Afu2g05150 (MP-2), Afu4g09600, and Afu6g14090, encode putative cell wall proteins containing a leader sequence and a glycosylphosphatidylinositol anchor motif. All four genes are expressed and produce variable-size mRNA encoding a discrete number of repeat amino acid units. Their expression was altered during development and in response to cell wall-disrupting agents. Deletion of one of these genes, Afu3g08990, resulted in a phenotype characterized by rapid conidial germination and reduced adherence to extracellular matrix suggestive of an alteration in cell wall characteristics. The Afu3g08990 protein was localized to the cell walls of dormant and germinating conidia. Our findings suggest that a subset of the A. fumigatus cell surface proteins may be hypervariable due to recombination events in their internal tandem repeats. This variation may provide the functional diversity in cell surface antigens which allows rapid adaptation to the environment and/or elusion of the host immune system.

The Aspergillus nidulans pkcA gene is involved in polarized growth, morphogenesis and maintenance of cell wall integrity

The protein kinase C (PKC) family participates in maintaining integrity and growth of fungal cell walls. However, the precise molecular role of these proteins in the filamentous fungi remains unknown. In this work, pkcA, the gene encoding the PKC homolog in the filamentous fungus Aspergillus nidulans, was cloned and its function analyzed using a conditional alcA-PKC mutant strain. Repression of pkcA expression resulted in increased conidial swelling, decreased rates of hyphal growth, changes in the ultrastructure of the cell wall and increased sensitivity to antifungal agents. These results suggest that the protein encoded by pkcA is involved in key aspects of cell morphogenesis and cell wall integrity.

Disruption of the Aspergillus fumigatus ECM33 homologue results in rapid conidial germination, antifungal resistance and hypervirulence

The ECM33/SPS2 family of glycosylphosphatidylinositol-anchored proteins plays an important role in maintaining fungal cell wall integrity and virulence. However, the precise molecular role of these proteins is unknown. In this work, AfuEcm33, the gene encoding the ECM33 homologue in the important pathogenic fungus Aspergillus fumigatus, has been cloned and its function analysed. It is shown that disruption of AfuEcm33 results in rapid conidial germination, increased cell-cell adhesion, resistance to the antifungal agent caspofungin and increased virulence in an immunocompromised mouse model for disseminated aspergillosis. These results suggest that the protein encoded by AfuEcm33 is involved in key aspects of cell wall morphogenesis and plays an important role in A. fumigatus virulence.

Analysis of the Aspergillus nidulans thaumatin-like cetA gene and evidence for transcriptional repression of pyr4 expression in the cetA-disrupted strain

The asexual spore or conidium plays a critical role in the life cycle of many filamentous fungi. However, the process of conidial germination remains surprisingly obscure. To better understand this process at the molecular level we characterized the Aspergillus nidulans cetA gene which is uniquely transcribed in conidiating cultures and whose transcript is significantly enriched in mature conidia. CetA is a member of a novel family of fungal genes of unknown function with homology to plant thaumatin-like (PR-5) defense proteins. We demonstrate by Northern analysis that cetA is a glucose-repressible gene. Transcriptional repression is dependent on the presence of protein kinase A. Western analysis indicates that the CETA protein is absent from conidia but is highly expressed during the first 6h of germination and is secreted into the medium. Disruption of the cetA gene seemingly results in delayed germination, slow growth, abnormal hyphal branching, and cell-wall defects. However, further analysis shows that the mutant phenotype is the result of glucose-dependent transcriptional repression of the pyr4 selectable marker used to disrupt the cetA gene. This is the first time that repression of a selectable marker ("position effect") has been reported in A. nidulans, a finding that may well be of significance in the analysis and interpretation of mutant phenotypes in this organism.

Two phylogenetically highly distinct ?-tubulin genes of the basidiomycete Suillus bovinus

Genes tubb1 and tubb2 which encode beta-tubulins 1 and 2, respectively, were characterised from the ectomycorrhizal basidiomycete Suillus bovinus. The two beta-tubulins are surprisingly divergent, with the lowest known sequence identity (60%) in any single fungal species. Comparative analysis showed that beta-tubulin 1 and the intron distribution within the tubb1 gene resemble the other beta-tubulins. beta-Tubulin 2, in contrast, is the most divergent fully described fungal beta-tubulin and the gene contains at least 21 introns, which is the largest amount known for any beta-tubulin gene. Despite this divergence, both genes are constitutively expressed in the functional compartments of the mycorrhizosphere and in pure cultures. Transcription of tubb1 is about 2.4 times higher than that of tubb2; and this difference is also seen at the translation level. Evidence suggested that phosphorylation may be the main post-translational modification of both beta-tubulins. The putative GTP-binding site residues of beta-tubulin 1 match crystallised pig beta-tubulin residues, while five of the nine differences in beta-tubulin 2 match the pig alpha-tubulin GTP-site, suggesting the presence of adaptive sequence evolution. In a Bayesian analysis, beta-tubulin 1 joins the other basidiomycete sequences, while beta-tubulin 2 loosely associates with the group of divergent ascomycete sequences without any clear relative among the known full-length fungal beta-tubulin sequences.

Tubulins in Aspergillus nidulans

The discovery and characterization of the tubulin superfamily in Aspergillus nidulans is described. Remarkably, the genes that encode alpha-, beta-, and gamma-tubulins were all identified first in A. nidulans. There are two alpha-tubulin genes, tubA and tubB, two beta-tubulin genes, benA and tubC, and one gamma-tubulin gene, mipA. Hyphal tubulin is encoded mainly by the essential genes tubA and benA. TubC is expressed during conidiation and tubB is required for the sexual cycle. Promoter swapping experiments indicate that the alpha-tubulins encoded by tubA and tubB are functionally interchangeable as are the beta-tubulins encoded by benA and tubC. BenA mutations that alter resistance to benzimidazole antimicrotubule agents are clustered and define a putative binding region for these compounds. gamma-Tubulin localizes to the spindle pole body and is essential for mitotic spindle formation. The phenotypes of mipA mutants suggest, moreover, that gamma-tubulin has essential functions in addition to microtubule nucleation.

Identification of conidial-enriched transcripts in Aspergillus nidulans using suppression subtractive hybridization

We have isolated and sequence-identified 12 genes whose transcripts are significantly enriched in Aspergillus nidulans conidia. To identify these genes, we used the method of suppressive subtraction hybridization (SSH). One of the 12 genes is similar to plant thaumatin-like proteins that have antifungal properties. Four genes encode metabolic enzymes crucial in the synthesis of glucose, carbohydrates, nucleic acid, and amino acid precursors. The rest are of unknown function. We have analyzed the pattern of expression of the 12 conidial-enriched transcripts in wild-type and mutant strains of A. nidulans blocked at different stages of conidial development. Our results indicate that the conidial-enriched transcripts can be divided into four classes based on their expression pattern in the wild-type and mutant strains. Study of the genes identified in this report may enhance our understanding of the process of conidial formation and germination.

A nucleotide substitution in one of the beta-tubulin genes of Trichoderma viride confers resistance to the antimitotic drug methyl benzimidazole-2-yl-carbamate

We characterized a Trichoderma viride strain that is resistant to the antimitotic drug methyl benzimidazole-2-yl-carbamate (MBC). This species has two beta-tubulin genes (tub1 and tub2) and by reverse genetics we showed that a mutation in the tub2 gene confers MBC resistance in this strain. Comparison of the tub2 sequence of the mutant strain with that of the wild type revealed that a single amino acid substitution of tyrosine for histidine at a position 6 is responsible for the MBC tolerance. Furthermore, we showed that this gene can be used as a homologous dominant selectable marker in T. viride transformation. Both tubulin genes were completely sequenced. They differ by 48 residues and the degree of identity between their deduced amino acid sequences is 86.3%.

Perspectives on tubulin isotype function and evolution based on the observation that Tetrahymena thermophila microtubules contain a single alpha- and beta-tubulin

We have cloned and sequenced the two beta-tubulin genes of the ciliated protozoan Tetrahymena thermophila. The two genes encode identical 443 amino acid peptides which are 99.7% identical to the beta-tubulin proteins of T. pyriformis and 95% identical to human beta 1 tubulin. T. thermophila contains only one alpha-tubulin gene (Callahan et al., 1984: Cell 36:441-445). Thus, all of the extremely diverse microtubule structures in this unicellular organism can be formed from a single alpha- and a single beta-tubulin peptide. We have also carried out a phylogenetic analysis of 84 complete beta-tubulin peptide sequences. This analysis supports two hypotheses regarding beta-tubulin evolution and function: 1) Multifunctional beta-tubulins are under greater evolutionary constraint than beta-tubulins present in specialized cells or in cells with very few microtubule related functions, which can evolve rapidly; and 2) Cells which form axonemes maintain a homogeneous population of tubulins.

Mitotic gold in a mold: Aspergillus genetics and the biology of mitosis

The analysis of fungal mutants has had an extraordinary impact on our understanding of the biochemistry and regulation of mitosis. In this article we review the contribution of work on the filamentous fungus Aspergillus nidulans to the molecular genetics of mitosis.

The tubB alpha-tubulin gene is essential for sexual development in Aspergillus nidulans

The filamentous fungus Aspergillus nidulans has two genes encoding alpha-tubulin, tubA and tubB. Mutational analysis of tubA has demonstrated that the tubA gene is essential for mitosis and nuclear migration. In this study we have deleted the tubB gene by replacing it with a selectable marker and have named this new allele tubB delta. The results demonstrate that the tubB gene is not required for vegetative growth or asexual reproduction, nor is it required for the initiation or early stages of sexual differentiation. Deletion of tubB, however, completely prevents ascosporogenesis, because tubB delta strains produce no sexual spores when self-crossed. These strains produce viable ascospores when outcrossed to tubB+ strains, indicating that the tubB delta mutation is recessive. We have studied the cytology of sexual development in wild-type strains and in the tubB mutant and have observed that tubB delta. strains develop normally to the stage of ascus formation. However, only a single nuclear mass is observed in the tubB delta ascus, indicating that either the two zygotic haploid nuclei are blocked in karyogamy or that karyogamy occurs but the resulting diploid nucleus is subsequently blocked in meiosis I.

Characterization of two divergent beta-tubulin genes from Colletotrichum graminicola

We have cloned and sequenced two beta-tubulin genes, TUB1 and TUB2, from the phytopathogenic fungus, Colletotrichum graminicola. The nucleotide sequences of the coding regions of the two genes are only 72.8% homologous. This divergence is reflected in the deduced amino acid (aa) sequences which differ at 94 aa residues. Comparison with the aa sequences of other fungal beta-tubulins indicates that the C. graminicola TUB2 gene encodes a conserved isotype, whereas the C. graminicola TUB1 product is highly divergent. Both genes contain six identically placed introns and the position of each intron is conserved in other fungal beta-tubulin genes. Also typical of other fungal beta-tubulin genes, there is a pronounced bias in codon usage in the C. graminicola TUB2 gene; there is a lesser codon bias in TUB1 from C. graminicola. Both C. graminicola beta-tubulin genes are transcribed and yield similar sized messages.

Increasing tubC beta-tubulin synthesis by placing it under the control of a benA beta-tubulin upstream sequence causes a reduction in benA beta-tubulin level but has no effect on microtubule function

We have constructed a chimeric beta-tubulin gene that places the structural gene for the tubC beta-tubulin of Aspergillus nidulans under the control of the benA beta-tubulin promoter. Introduction of either this chimeric gene or a second wild-type benA gene into a benomyl-resistant benA22 strain causes it to become benomyl sensitive, indicating that the introduced genes are functional. Analysis of the tubulin proteins synthesized in benA22 strains into which a second wild-type benA beta-tubulin gene was transformed showed that the total amount of beta-tubulin protein was the same as in the parental strain with a single benA gene. Thus the level of beta-tubulin must be regulated. This was also true of transformants carrying an extra copy of the chimeric beta-tubulin gene. The total amount of beta-tubulin was the same as in the parental strain. Two-dimensional gel analysis showed that the endogenous benA22 and the introduced chimeric tubC gene contributed equally to the total beta-tubulin pool. The fact that one-half of the benA beta-tubulin could be replaced by tubC beta-tubulin with no effect on the growth of the cells suggests that the benA and tubC beta-tubulins are functionally interchangeable.

The highly divergent beta-tubulins of Aspergillus nidulans are functionally interchangeable

An internal 1.4-kb Bst EII fragment was used to disrupt the benA gene and establish heterokaryons. The heterokaryons demonstrated that the molecular disruption of benA results in a recessive benA null mutation. Conidia from a heterokaryon swell and germinate but cannot undergo nuclear division and are thus inviable. A chimeric beta-tubulin gene was constructed with the benA promoter driving the tubC structural gene. This chimeric gene construction was placed on a plasmid containing a selectable marker for Aspergillus transformation and the gene disrupting fragment of benA. Integration of this plasmid at benA by the internal gene disrupting fragment of benA simultaneously disrupts the benA gene and replaces it with the chimeric beta-tubulin gene, rescuing the benA null generated by the integration. Strains generated by this procedure contain only tubC beta-tubulin for all beta-tubulin functions. Strains having only tubC beta-tubulin are viable and exhibit no detectable microtubule dysfunction though they are more sensitive than wild-type strains to the antimicrotubule drug benomyl. It is concluded that the two beta-tubulin genes of Aspergillus nidulans, though highly divergent, are interchangeable.

Characterization of an inducible expression system in Aspergillus nidulans using alcA and tubulin-coding genes

Plasmids have been constructed in which expression of a gene can be placed under the control of the inducible promoter of the alcA gene encoding alcohol dehydrogenase I in Aspergillus nidulans. Simplified shuttle vectors carrying pyr4 which complements pyrG89 mutations have also been constructed. These are based on pUC19 and retain alpha-peptide expression. The beta-tubulin genes, tubC and benA, have been placed under the control of alcA and their expression studied. Levels of expression can be assayed phenotypically because increased synthesis of beta-tubulin inhibits vegetative growth. Sensitivity of asexual spore formation to the anti-microtubule drug benomyl provides a means of detecting very low levels of expression of the chimeric genes. Glucose almost completely represses the chimeric genes. Induction is rapid and is maximal within an hour. When a strain carrying seven copies of an alcA::tubC gene fusion was grown under inducing conditions, 6.5% of total sulfate labelled protein consisted of tubC product. Cyclopentanone was the most potent inducer of the chimeric genes on solid media but it also partially inhibited growth. Chimeric alcA::tubC and alcA::benA genes were expressed to very similar levels despite the fact that tubC utilizes many rare codons.