Extragenic Suppressors of Nudc3, a Mutation That Blocks Nuclear Migration in Aspergillus Nidulans

Nuclear migration plays an important role in the growth and development of many organisms including the filamentous fungus Aspergillus nidulans. We have cloned three genes from A. nidulans, nudA, nudC, and nudF, in which mutations affect nuclear migration. The nudA gene encodes the heavy chain of cytoplasmic dynein. The nudC gene encodes a 22-kD protein. The nudF gene was identified as an extracopy suppressor of the temperature sensitive (ts(-)) nudC3 mutation. The nudC3 mutation substantially decreases the intracellular concentration of the nudF protein at restrictive temperature. This is restored toward the normal level by an extra copy of nudF. To identify other genes whose products interact directly or indirectly with the NUDC protein, we have isolated a set of extragenic suppressors of the nudC3 temperature-sensitive mutation. Genetic analysis of 16 such extragenic suppressors showed them to represent nine different genes, designated sncA-sncI (for suppressor of nudC). sncA-sncH were either dominant or semidominant in diploids homozygous for nudC3 and heterozygous for the snc mutations. All of the suppressors reversed the ts(-) phenotype of nudC3 by restoring the intracellular concentration of the NUDF protein.     

An Alpha Tubulin Mutation Suppresses Nuclear Migration Mutations in Aspergillus Nidulans

Microtubules and cytoplasmic dynein, a microtubule-dependent motor, are required for nuclei to move along the hyphae of filamentous fungi. Nuclear migration in Aspergillus nidulans is blocked by heat-sensitive (hs(-)) mutations in the nudA gene, which encodes dynein heavy chain, and the nudF gene, which encodes a G protein β-subunit-like protein. Hs(-) mutations in the nudC and nudG genes also prevent nuclear migration. We have isolated extragenic suppressor mutations that reverse the hs(-) phenotypes caused by these mutations. Here we show that one nudF suppressor also suppresses hs(-) mutations in nudA, nudC, and nudG and deletions in nudA and nudF. This suppressor mutation is in the tubA alpha tubulin gene, and its characteristics suggest that it destabilizes microtubules. The mutation alters microtubule staining and confers sensitivity to cold and benomyl, two treatments that destabilize microtubules. Treatment with low concentrations of benomyl also suppresses the hs(-) nudA, nudC, nudF, and nudG mutations and the nudA and nudF deletions. Suppression of the hs(-) nudA mutation and the nudA deletion is especially interesting because these strains lack active dynein heavy chain. Together, these results suggest that microtubule destabilization allows nuclei to migrate even in the absence of cytoplasmic dynein motor function.     

Genetic and Molecular Analysis of a Trna(leu) Missense Suppressor of Nudc3, a Mutation That Blocks Nuclear Migration in Aspergillus Nidulans

NudC encodes a protein of unknown biochemical function that is required for nuclear migration. In an attempt to define its function by identifying interacting proteins, a screen for extragenic suppressors of the temperature-sensitive nudC3 mutation was undertaken that identified nine snc genes. Here we demonstrate that nudC3 has a missense mutation at amino acid 146 that causes leucine to be replaced by proline and that sncB69 encodes a mutant tRNA(Leu) that corrects the mutation. The sncB69 mutation deletes a single nucleotide in the anticodon of a tRNA(Leu) that changes its normal (5')CAG(3') leucine anticodon to the proline anticodon (5')CGG(3'), which presumably allows incorporation of leucine at the mutant nudC3 proline codon 146 and thereby causes suppression of the nudC3 mutant phenotype.     

Genetic Analysis of Suppressors of the Vea1 Mutation in Aspergillus Nidulans

Light-dependent conidiation in the filamentous ascomycete, Aspergillus nidulans, is contingent on the allelic state of the velvet (veA) gene. Light dependence is abolished by a mutation in this gene (veA1), which allows conidiation to occur in the absence of light. We have isolated and characterized six extragenic suppressors of veA1 that restore the light-dependent conidiation phenotype. Alleles of four genes, defined by complementation tests, were subjected to extensive genetic and phenotypic analysis. The results of light-dark shifting experiments and the phenotypes of double mutant combinations are consistent with the possibility that the expression of the light-dependent phenotype is regulated by specific interactions of the suppressor gene products with the velvet gene product and with each other.     

An Extragenic Suppressor of the Mitosis-Defective Bimd6 Mutation of Aspergillus Nidulans Codes for a Chromosome Scaffold Protein

We previously identified a gene, bimD, that functions in chromosome segregation and contains sequences suggesting that it may be a DNA-binding protein. Two conditionally lethal mutations in bimD arrest with aberrant mitotic spindles at restrictive temperature. These spindles have one-third the normal number of microtubules, and the chromosomes never attach to the remaining microtubules. For this reason, we hypothesized that BIMD functioned in chromosome segregation, possibly as a component of the kinetochore. To identify other components that function with bimD, we conducted a screen for extragenic suppressors of the bimD5 and bimD6 mutations. We have isolated seven cold-sensitive extragenic suppressors of bimD6 heat sensitivity that represent three or possibly four separate sud genes. We have cloned one of the suppressor genes by complementation of the cold-sensitive phenotype of the sudA3 mutation. SUDA belongs to the DA-box protein family. DA-box proteins have been shown to function in chromosome structure and segregation. Thus bimD and the sud genes cooperatively function in chromosome segregation in Aspergillus nidulans.     

Extragenic Suppressors of Growth Defects in msbB Salmonella

Lipid A, a potent endotoxin which can cause septic shock, anchors lipopolysaccharide (LPS) into the outer leaflet of the outer membrane of gram-negative bacteria. MsbB acylates (KDO)(2)-(lauroyl)-lipid IV-A with myristate during lipid A biosynthesis. Reports of knockouts of the msbB gene describe effects on virulence but describe no evidence of growth defects in Escherichia coli K-12 or Salmonella. Our data confirm the general lack of growth defects in msbB E. coli K-12. In contrast, msbB Salmonella enterica serovar Typhimurium exhibits marked sensitivity to galactose-MacConkey and 6 mM EGTA media. At 37 degrees C in Luria-Bertani (LB) broth, msbB Salmonella cells elongate, form bulges, and grow slowly. msbB Salmonella grow well on LB-no salt (LB-0) agar; however, under specific shaking conditions in LB-0 broth, many msbB Salmonella cells lyse during exponential growth and a fraction of the cells form filaments. msbB Salmonella grow with a near-wild-type growth rate in MSB (LB-0 containing Mg(2+) and Ca(2+)) broth (23 to 42 degrees C). Extragenic compensatory mutations, which partially suppress the growth defects, spontaneously occur at high frequency, and mutants can be isolated on media selective for faster growing derivatives. One of the suppressor mutations maps at 19.8 centisomes and is a recessive IS10 insertional mutation in somA, a gene of unknown function which corresponds to ybjX in E. coli. In addition, random Tn10 mutagenesis carried out in an unsuppressed msbB strain produced a set of Tn10 inserts, not in msbB or somA, that correlate with different suppressor phenotypes. Thus, insertional mutations, in somA and other genes, can suppress the msbB phenotype.     

The “8-kD” Cytoplasmic Dynein Light Chain Is Required for Nuclear Migration and for Dynein Heavy Chain Localization in Aspergillus nidulans

The heavy chain of cytoplasmic dynein is required for nuclear migration in Aspergillus nidulans and other fungi. Here we report on a new gene required for nuclear migration, nudG, which encodes a homologue of the “8-kD” cytoplasmic dynein light chain (CDLC). We demonstrate that the temperature sensitive nudG8 mutation inhibits nuclear migration and growth at restrictive temperature. This mutation also inhibits asexual and sexual sporulation, decreases the intracellular concentration of the nudG CDLC protein and causes the cytoplasmic dynein heavy chain to be absent from the mycelial tip, where it is normally located in wild-type mycelia. Coimmunoprecipitation experiments with antibodies against the cytoplasmic dynein heavy chain (CDHC) and the nudG CDLC demonstrated that some fraction of the cytoplasmic dynein light chain is in a protein complex with the CDHC. Sucrose gradient sedimentation analysis, however, showed that not all of the NUDG protein is complexed with the heavy chain. A double mutant carrying a cytoplasmic dynein heavy chain deletion plus a temperature-sensitive nudG mutation grew no more slowly at restrictive temperature than a strain with only the CDHC deletion. This result demonstrates that the effect of the nudG mutation on nuclear migration and growth is mediated through an interaction with the CDHC rather than with some other molecule (e.g., myosin-V) with which the 8-kD CDLC might theoretically interact.     

Enhancers of Conidiation Mutants in Aspergillus Nidulans

Mutants at a number of loci, designated sthenyo, have been isolated as enhancers of the oligoconidial mutations at the medA locus. Two loci have been mapped: sthA on linkage group I, and sthB on linkage group V. Two probable alleles have been identified at each locus but two further mutants were unlinked to either sthA or sthB. Neither sthA nor sthB mutants have conspicuous effects on morphology on their own, nor could the sthA1 sthB2 double mutant be distinguished from wild type. Mutants at both loci also interact with the temperature-sensitive brlA42 mutant at the permissive temperature to give a phenotype described as ``Abacoid.' sthA1 also induces a slight modification of the phenotype of an abaA mutant. We conclude that sthenyo genes act mainly at the phialide stage of conidiation. We also describe the isolation of new medA mutants arising spontaneously as outgrowths on brlA42 colonies.     

Extragenic Suppressors of Saccharomyces Cerevisiae Prp4 Mutations Identify a Negative Regulator of Prp Genes

The PRP4 gene encodes a protein that is a component of the U4/U6 small nuclear ribonucleoprotein particle and is necessary for both spliceosome assembly and pre-mRNA splicing. To identify genes whose products interact with the PRP4 gene or gene product, we isolated second-site suppressors of temperature-sensitive prp4 mutations. We limited ourselves to suppressors with a distinct phenotype, cold sensitivity, to facilitate analysis of mutants. Ten independent recessive suppressors were obtained that identified four complementation groups, spp41, spp42, spp43 and spp44 (suppressor of prp4, numbers 1-4). spp41-spp44 suppress the pre-mRNA splicing defect as well as the temperature-sensitive phenotype of prp4 strains. Each of these spp mutations also suppresses prp3; spp41 and spp42 suppress prp11 as well. Neither spp41 nor spp42 suppresses null alleles of prp3 or prp4, indicating that the suppression does not occur via a bypass mechanism. The spp41 and spp42 mutations are neither allele- nor gene-specific in their pattern of suppression and do not result in a defect in pre-mRNA splicing. Thus the SPP41 and SPP42 gene products are unlikely to participate directly in mRNA splicing or interact directly with Prp3p or Prp4p. Expression of PRP3-lacZ and PRP4-lacZ gene fusions is increased in spp41 strains, suggesting that wild-type Spp41p represses expression of PRP3 and PRP4. SPP41 was cloned and sequenced and found to be essential. spp43 is allelic to the previously identified suppressor srn1, which encodes a negative regulator of gene expression.     

Isolation of Two Apsa Suppressor Strains in Aspergillus Nidulans

Aspergillus nidulans reproduces asexually with single nucleated conidia. In apsA (anucleate primary sterigmata) strains, nuclear positioning is affected and conidiation is greatly reduced. To get further insights into the cellular functions of apsA, aconidial apsA strains were mutagenized and conidiating suppressor strains were isolated. The suppressors fell into two complementation groups, samA and samB (suppressor of anucleate metulae). samA mapped on linkage group I close to pyrG. The mutant allele was dominant in diploids homozygous for apsA. Viability of conidia of samA suppressor strains (samA(-); apsA(-)) was reduced to 50% in comparison to wild-type conidia. Eighty percent of viable spores produced small size colonies that were temperature- and benomyl-sensitive. samB mapped to chromosome VIII and was recessive. Viability of conidia from samB suppressor strains (apsA(-); samB(-)) was also affected but no small size colonies were observed. Both suppressors produced partial defects in sexual reproduction and both suppressed an apsA deletion mutation. In wild-type background the mutant loci affected hyphal growth rate (samA) or changed the colony morphology (samB) and inhibited sexual spore formation (samA and samB). Only subtle effects on conidiation were found. We conclude that both suppressor genes bypass the apsA function and are involved in microtubule-dependent processes.     

Identification and Characterization of Aspergillus Nidulans Mutants Defective in Cytokinesis

Filamentous fungi undergo cytokinesis by forming crosswalls termed septa. Here, we describe the genetic and physiological controls governing septation in Aspergillus nidulans. Germinating conidia do not form septa until the completion of their third nuclear division. The first septum is invariantly positioned at the basal end of the germ tube. Block-and-release experiments of nuclear division with benomyl or hydroxyurea, and analysis of various nuclear division mutants demonstrated that septum formation is dependent upon the third mitotic division. Block-and-release experiments with cytochalasin A and the localization of actin in germlings by indirect immunofluorescence showed that actin participated in septum formation. In addition to being concentrated at the growing hyphal tips, a band of actin was also apparent at the site of septum formation. Previous genetic analysis in A. nidulans identified four genes involved in septation (sepA-D). We have screened a new collection of temperature sensitive (ts) mutants of A. nidulans for strains that failed to form septa at the restrictive temperature but were able to complete early nuclear divisions. We identified five new genes designated sepE, G, H, I and J, along with one additional allele of a previously identified septation gene. On the basis of temperature shift experiments, nuclear counts and cell morphology, we sorted these cytokinesis mutants into three phenotypic classes. Interestingly, one class of mutants fails to form septa and fails to progress past the third nuclear division. This class of mutants suggests the existence of a regulatory mechanism in A. nidulans that ensures the continuation of nuclear division following the initiation of cytokinesis.     

Identification of Developmental Regulatory Genes in Aspergillus Nidulans by Overexpression

Overexpression of several Aspergillus nidulans developmental regulatory genes has been shown to cause growth inhibition and development at inappropriate times. We set out to identify previously unknown developmental regulators by constructing a nutritionally inducible A. nidulans expression library containing small, random genomic DNA fragments inserted next to the alcA promoter [ alcA (p) ] in an A. nidulans transformation vector. Among 20,000 transformants containing random alcA (p) genomic DNA fusion constructs, we identified 66 distinct mutant strains in which alcA (p) induction resulted in growth inhibition as well as causing other detectable phenotypic changes. These growth inhibited mutants were divided into 52 FIG (Forced expression Inhibition of Growth) and 14 FAB (Forced expression Activation of brlA) mutants based on whether or not alcA (p) induction resulted in accumulation of mRNA for the developmental regulatory gene brlA. In four FAB mutants, alcA (p) induction not only activated brlA expression but also caused hyphae to differentiate into reduced conidiophores that produced viable spores from the tips as is observed after alcA (p) :: brlA induction. Sequence analyses of the DNA fragments under alcA (p) control in three of these four sporulating strains showed that in two cases developmental activation resulted from overexpression of previously uncharacterized genes, whereas in the third strain, the alcA (p) was fused to brlA. The potential uses for this strategy in identifying genes whose overexpression results in specific phenotypic changes like developmental induction are discussed.