Mutants Of Neurospora Research Articles

Fungal senescence induced by the Neurospora sen mutation and mitochondrial plasmids - the contributions of Ramesh Maheshwari.

This article describes some of the research contributions made by Prof. Ramesh Maheshwari and his colleagues at the Indian Institute of Science, Bangalore. These include (1) the understanding of the Neurospora life cycle in agricultural (sugarcane) fields, (2) identification of Neurospora mutants that trigger vegetative spore development via microcycle conidiation, and (3) isolation of wild Neurospora strains in which the essential immortality of the fungal mycelia is subverted.

Phosphate starvation in fungi induces the replacement of phosphatidylcholine with the phosphorus-free betaine lipid diacylglyceryl-N,N,N-trimethylhomoserine.

Diacylglyceryl-N,N,N-trimethylhomoserine (DGTS) is a phosphorus-free betaine-lipid analog of phosphatidylcholine (PtdCho) synthesized by many soil bacteria, algae, and nonvascular plants. Synthesis of DGTS and other phosphorus-free lipids in bacteria occurs in response to phosphorus (P) deprivation and results in the replacement of phospholipids by nonphosphorous lipids. The genes encoding DGTS biosynthetic enzymes have previously been identified and characterized in bacteria and the alga Chlamydomonas reinhardtii. We now report that many fungal genomes, including those of plant and animal pathogens, encode the enzymatic machinery for DGTS biosynthesis, and that fungi synthesize DGTS during P limitation. This finding demonstrates that replacement of phospholipids by nonphosphorous lipids is a strategy used in divergent eukaryotic lineages for the conservation of P under P-limiting conditions. Mutants of Neurospora crassa were used to show that DGTS synthase encoded by the BTA1 gene is solely responsible for DGTS biosynthesis and is under the control of the fungal phosphorus deprivation regulon, mediated by the NUC-1/Pho4p transcription factor. Furthermore, we describe the rational reengineering of lipid metabolism in the yeast Saccharomyces cerevisiae, such that PtdCho is completely replaced by DGTS, and demonstrate that essential processes of membrane biogenesis and organelle assembly are functional and support growth in the engineered strain.

Rediscovery by Whole Genome Sequencing: Classical Mutations and Genome Polymorphisms inNeurospora crassa

Classical forward genetics has been foundational to modern biology, and has been the paradigm for characterizing the role of genes in shaping phenotypes for decades. In recent years, reverse genetics has been used to identify the functions of genes, via the intentional introduction of variation and subsequent evaluation in physiological, molecular, and even population contexts. These approaches are complementary and whole genome analysis serves as a bridge between the two. We report in this article the whole genome sequencing of eighteen classical mutant strains of Neurospora crassa and the putative identification of the mutations associated with corresponding mutant phenotypes. Although some strains carry multiple unique nonsynonymous, nonsense, or frameshift mutations, the combined power of limiting the scope of the search based on genetic markers and of using a comparative analysis among the eighteen genomes provides strong support for the association between mutation and phenotype. For ten of the mutants, the mutant phenotype is recapitulated in classical or gene deletion mutants in Neurospora or other filamentous fungi. From thirteen to 137 nonsense mutations are present in each strain and indel sizes are shown to be highly skewed in gene coding sequence. Significant additional genetic variation was found in the eighteen mutant strains, and this variability defines multiple alleles of many genes. These alleles may be useful in further genetic and molecular analysis of known and yet-to-be-discovered functions and they invite new interpretations of molecular and genetic interactions in classical mutant strains.

Activation and localization of protein kinase C in Neurospora crassa

The Neurospora crassa protein kinase C (NPKC) is reported to be a regulator of light responsive genes. It phosphorylates the light receptor WC-1 and regulates the levels of the circadian clock protein FRQ and transcription of the light-induced albino-2 gene. In mammals, the conventional and novel isoforms of PKC are activated by diacylglycerol (DAG), which induces PKC translocation from the cytoplasm to membranes. To investigate the interaction of NPKC and DAG in Neurospora, we constructed a strain that expresses a PKC-GFP fusion protein. We found that NPKC localizes to growing tips and sub-apical plasma membrane in actively growing hyphae, and actively participates in septum development. NPKC is activated by exogenous DAG and phorbol esters, and translocates to the plasma membrane from the cytoplasm. We have previously reported that choline depletion of the chol-1 mutant of Neurospora increases DAG levels and lengthens the period of the circadian rhythm of conidiation. We have found that the activity of NPKC is rhythmic, and that NPKC levels are increased on choline depletion. However, over-expression of NPKC did not lengthen the conidiation period, indicating that PKC in Neurospora may not be responsible for the lengthened period in low choline cultures.

Characterization of the Temperature-Sensitive Mutations un-7 and png-1 in Neurospora crassa

The model filamentous fungus Neurospora crassa has been studied for over fifty years and many temperature-sensitive mutants have been generated. While most of these have been mapped genetically, many remain anonymous. The mutation in the N. crassa temperature-sensitive lethal mutant un-7 was identified by a complementation based approach as being in the open reading frame designated NCU00651 on linkage group I. Other mutations in this gene have been identified that lead to a temperature-sensitive morphological phenotype called png-1. The mutations underlying un-7 result in a serine to phenylalanine change at position 273 and an isoleucine to valine change at position 390, while the mutation in png-1 was found to result in a serine to leucine change at position 279 although there were other conservative changes in this allele. The overall morphology of the strain carrying the un-7 mutation is compared to strains carrying the png-1 mutation and these mutations are evaluated in the context of other temperature-sensitive mutants in Neurospora.

Hydroxylamine-induced purple mutants (ad-3) in Neurospora crassa. II. Identification of genetic alteration at the molecular level.

There is evidence that most hydroxylamine (HA)-induced mutants in Neurospora arise from a GC-to-AT base-pair transition. Evidence supporting this hypothesis was obtained by a study of the revertibility of HA-induced mutants after treatment with specific chemical mutagens. Hydroxylamine-induced ad-3 mutants of Neurospora crassa were tested for revertibility after treatment with nitrous acid (NA), ethyl methanesulfonate (EMS), O-methyl-hydroxylamine (OMHA), and 2-methoxy-6-chloro-9- [3-(ethyl-2-chloraethyl) amino propyl-amino] acridine dihydrochloride (ICR-170). Mutants not reverting after treatment with these mutagens were tested for revertibility after treatment with N-methyl-N'-nitro-N-nitroso-guanidine (MNNG). An analysis was made of mutants induced in a 2-component heterokaryon. Of this material 78.2% reverted by an AT-to-GC transition; 10% by a GC-to-AT transition, 4.5% by base-pair insertion or deletion; and 7.3% reverted spontaneously but not after treatment with any of the 5 mutagens. Thus, HA produces mainly GC-to-AT transitions when the treatment is carried out under conditions promoting this specificity. This means that HA has a mutagenic specificity in higher organisms similar to that observed in phage and transforming DNA from B. subtilis. HA can be used as an analytical tool for mutagenesis in higher organisms to characterize the mutagenic activity of agents with an unknown mutation mechanism. HA can also be used to produce mutants with AT at the mutant site. The spectra of genetic alterations among the ad-3B mutants with nonpolarized or polarized complementation patterns and among noncomplementing mutants do not differ from each other, because the majority of HA-induced mutants result from the same genetic alteration.

The Neurospora crassa UVS-3 epistasis group encodes homologues of the ATR/ATRIP checkpoint control system

The mutagen sensitive uvs-3 and mus-9 mutants of Neurospora show mutagen and hydroxyurea sensitivity, mutator effects and duplication instability typical of recombination repair and DNA damage checkpoint defective mutants. To determine the nature of these genes we used cosmids from a genomic library to clone the uvs-3 gene by complementation for MMS sensitivity. Mutation induction by transposon insertion and RIP defined the coding sequence. RFLP analysis confirmed that this sequence maps in the area of uvs-3 at the left telomere of LG IV. Analysis of the cDNA showed that the UVS-3 protein contains an ORF of 969 amino acids with one intron. It is homologous to UvsD of Aspergillus nidulans, a member of the ATRIP family of checkpoint proteins. It retains the N′ terminal coiled-coil motif followed by four basic amino acids typical of these proteins and shows the highest homology in this region. The uvsD cDNA partially complements the defects of the uvs-3 mutation. The uvs-3 mutant shows a higher level of micronuclei in conidia and failure to halt germination and nuclear division in the presence of hydroxyurea than wild type, suggesting checkpoint defects. ATRIP proteins bind tightly to ATR PI-3 kinase (phosphatidylinositol 3-kinase) proteins. Therefore, we searched the Neurospora genome sequence for homologues of the Aspergillus nidulans ATR, UvsB. A uvsB homologous sequence was present in the right arm of chromosome I where the mus-9 gene maps. A cosmid containing this genomic DNA complemented the mus-9 mutation. The putative MUS-9 protein is 2484 amino acids long with eight introns. Homology is especially high in the C-terminal 350 amino acids that correspond to the PI-3 kinase domain. In wild type a low level of constitutive mRNA is present for both genes. It is transiently induced upon UV exposure.

Beadle’s progeny: Innocence rewarded, innocence lost

Beadle’s progeny: Innocence rewarded, innocence lost Perspectives Beadle’s progeny: Innocence rewarded, innocence lost* R OWLAND H D AVIS Department of Molecular Biology and Biochemistry, University of California, Irvine, Irvine, CA 92697-3900, USA (Email, rhdavis@uci.edu) Introduction In the history of various sciences, we fi nd periods of static tradition punctuated by discoveries that ignite rapid reorientations and novel lines of investigation. The dinosaurs die off and the shrews take over, beady-eyed and ignorant of the past as they spread into new, habitable niches. So it was in the early 1940s when Beadle and Tatum (1941) announced the isolation of their fi rst metabolic mutants of the fungus Neurospora, followed by papers that elaborately bore out the promise of the “one gene, one enzyme” hypothesis. The promise of fi nding the actual role of genes in the structure of proteins and enzymes, and how mutations might be used to dissect metabolic and other complex sequences was clear. Neurospora workers, small in numbers, sensed that a new day had come, a day in which the undiscovered country between the molecule and the cell surface might soon be revealed. When we were young, things were simple, and for some time thereafter, we retained our innocence. Creative innocence Two paths lie before a new graduate student. One is to discover something new; the other is to refi ne doggedly what is known, usually on someone else’s grant money. I was forced to do the former, inasmuch as grant funds were not the way my mentor, Paul Levine, supported his students. Moreover, my fascination with Neurospora would contribute nothing whatever to his studies of Drosophila population genetics or his later work on recombination in Chlamydomonas. I had discovered early on that a student without purpose could acquire one simply by relaxing and waiting for mutations to appear. Such accidents, as Pasteur had said, favour the prepared mind, even if the mind was Keywords. prepared only with a need to discover something, however trivial. I entered graduate school in 1954, a year after Watson and Crick’s discovery of DNA structure (1953) condensed the gene’s abstract properties into a molecular model. It took some years for me to appreciate its signifi cance, because my interests favoured the use of microorganisms to illuminate the genetics of haploid organisms and the workings of simple cells. But work on DNA developed in parallel with microbial and biochemical genetics, the three areas probing the fundamental structures and activities of living cells. Genetics would give us the means to dismantle the cell and to teach us, like Vesalius, to ignore the ancient texts. My graduate work had begun with a mutation affecting heterokaryons in Neurospora. My innocent delight in demonstrating its 1:1 segregation in a cross with wild-type confi rmed my faith in genetics. After all, Beadle and Tatum had done this with somewhat more interesting mutations in 1941 and published it to wide acclaim. In 1958 I went to Caltech as a postdoctoral fellow, knowing that I must have a passing acquaintance with biochemistry, of which I was then wholly ignorant. My motives were base: I wanted to do biochemistry by mutational techniques rather than having to follow the demanding, fussy chemical approaches that characterized the fi eld. Perhaps I too could become, as Chargaff later remarked, an unlicensed biochemist, using clumsy, random mutations to explore the china shop of metabolism. At Caltech, I joined the seminal group that had adumbrated the one gene, one enzyme motto. Apparent counterevidence had been assimilated into the theory. For instance, a mutation affecting the isoleucine and valine pathways was found to affect a single enzyme common to both. A problem remained, however: Max Delbruck insisted that the theory Arginine; Beadle; metabolic organization; Neurospora; pyrimidine *This article is dedicated to the memory of two mentors: Herschel K Mitchell, who gave me opportunity and independence, and Norman H Horowitz, who gave me background and insight into Neurospora biochemical genetics. http://www.ias.ac.in/jbiosci J. Biosci. 32(2), March 2007, 197–205, © Indian J. Academy of Sciences Biosci. 32(2), March 2007

Structural and kinetic alterations of constitutive conidial alkaline phosphatase from the osmotically-sensitive mutant ofNeurospora crassa

The osmotically-sensitive os-1 mutant of Neurospora crassa overproduced conidial alkaline phosphatase. The enzyme was purified by Phenyl-Sepharose CL-4B chromatography and Sephadex G-200 gel filtration. PAGE analysis of the purified enzyme suggested the occurrence of aggregation and/or disaggregation phenomena. The enzyme is a glycoprotein containing 16% saccharide, with apparent molar mass of 137 kDa. Two protein bands (36 and 62 kDa) were observed in SDS-PAGE, suggesting that the native enzyme was a trimer. The pI was estimated to be 2.7, and optima of pH and temperature were 9.5 and 65 degrees C, respectively. The enzyme showed broad substrate specificity, hydrolyzing preferentially 4-nitrophenyl phosphate, O-phosphoamino-acids and 2-phosphoglycerate. The hydrolysis of 4-nitrophenyl phosphate was stimulated by Co(II) (26%), Ni(II) (23%) and Mg(II) ions (80%). The enzyme was stable for up to 6 months at 4 degrees C in 5 mmol/L Tris-HCl buffer and also upon storage at 25 degrees C for 10 d. The kinetic and structural properties of the conidial enzyme purified from the os-1 mutant were quite different from those of the wild type strain. The enzyme overproduction observed in the mutant may be related to cell wall alterations that affect the process of enzyme secretion.

Mannosyltransferase is required for cell wall biosynthesis, morphology and control of asexual development in Neurospora crassa

Two Neurospora mutants with a phenotype that includes a tight colonial growth pattern, an inability to form conidia and an inability to form pro-toperithecia have been isolated and characterized. The relevant mutations were mapped to the same locus on the sequenced Neurospora genome. The mutations responsible for the mutant phenotype then were identified by examining likely candidate genes from the mutant genomes at the mapped locus with PCR amplification and a sequencing assay. The results demonstrate that a map and sequence strategy is a feasible way to identify mutant genes in Neurospora. The gene responsible for the phenotype is a putative alpha-1,2-mannosyltransferase gene. The mutant cell wall has an altered composition demonstrating that the gene functions in cell wall biosynthesis. The results demonstrate that the mnt-1 gene is required for normal cell wall biosynthesis, morphology and for the regulation of asexual development.

Conidial anastomosis tubes in filamentous fungi

Conidial anastomosis tubes (CATs) can be recognized in 73 species of filamentous fungi covering 21 genera, and develop in culture and in host-pathogen systems. They have been shown to be morphologically and physiologically distinct from germ tubes in Colletotrichum and Neurospora, and under separate genetic control in Neurospora. CATs are short, thin, usually unbranched and arise from conidia or germ tubes. Their formation is conidium-density dependent, and CATs grow towards each other. MAP kinase mutants of Neurospora are blocked in CAT induction. Nuclei pass through fused CATs and are potential agents of gene exchange between individuals of the same and different species. CAT fusion may also serve to improve the chances of colony establishment.

Mannosyltransferase is required for cell wall biosynthesis, morphology and control of asexual development in Neurospora crassa

Two Neurospora mutants with a phenotype that includes a tight colonial growth pattern, an inability to form conidia and an inability to form protoperithecia have been isolated and characterized. The relevant mutations were mapped to the same locus on the sequenced Neurospora genome. The mutations responsible for the mutant phenotype then were identified by examining likely candidate genes from the mutant genomes at the mapped locus with PCR amplification and a sequencing assay. The results demonstrate that a map and sequence strategy is a feasible way to identify mutant genes in Neurospora. The gene responsible for the phenotype is a putative alpha-1,2-mannosyltransferase gene. The mutant cell wall has an altered composition demonstrating that the gene functions in cell wall biosynthesis. The results demonstrate that the mnt-1 gene is required for normal cell wall biosynthesis, morphology and for the regulation of asexual development.

Circadian period lengths of lipid synthesis mutants (cel, chol-1) of Neurospora show defective temperature, but intact pH-compensation

The influence of extracellular pH on the circadian sporulation rhythm of Neurospora crassa has been investigated for the mutants chol-1 and cel. Both mutants have a defect in the lipid synthesis pathway and require either choline or palmitate, respectively, as supplements for normal growth. The chol-1 and cel mutants also show an impaired temperature-compensation when growing on minimal medium. We investigated the possible correlation between loss of temperature- and pH-compensation in cel and chol-1 similar to the correlation found earlier for the frq7 mutant. Our results show that the cel and the chol-1 mutants, although defective in temperature-compensation have an intact pH-compensation of their circadian rhythms. At present, the products of the frq-locus are the only components of the clock that affect the sporulation rhythm of Neurospora both through pH- and temperature-compensation.

Meiotic Silencing by Unpaired DNA

The silencing of gene expression by segments of DNA present in excess of the normal number is called cosuppression in plants and quelling in fungi. We describe a related process, meiotic silencing by unpaired DNA (MSUD). DNA unpaired in meiosis causes silencing of all DNA homologous to it, including genes that are themselves paired. A semidominant Neurospora mutant, Sad-1, fails to perform MSUD. Sad-1 suppresses the sexual phenotypes of many ascus-dominant mutants. MSUD may provide insights into the function of genes necessary for meiosis, including genes for which ablation in vegetative life would be lethal. It may also contribute to reproductive isolation of species within the genus Neurospora. The wild-type allele, sad-1 + , encodes a putative RNA-directed RNA polymerase.

Blue light adaptation and desensitization of light signal transduction in Neurospora crassa.

The ascomycete Neurospora crassa has the capacity of adapting to a given light quantity, leading to transient blue light responses under continuous light conditions. Here, we present an investigation of this photoadaptation phenomenon. We demonstrated previously that two proteins of the Neurospora blue light signal transduction chain, WC1 and WC2, are subject to light-dependent phosphorylation. WC1 was phosphorylated in parallel with the transient increase in transcript levels of light-regulated genes. Using the light-dependent phosphorylation of WC1 as a marker for an active signalling state of WC1, we show that the transiency of Neurospora blue light responses results from desensitization of the photoreceptor and/or the signalling cascade. Furthermore, a Neurospora mutant was characterized that revealed a specific defect in photoadaptation. In this mutant, the transient expression of light-regulated genes under continuous light, the temporary insensitivity after a light pulse and the capability of differentiating between and adapting to low and high light intensities were abolished. The corresponding protein seems to represent a central component of a negative feedback desensitization mechanism. This negative feedback regulation requires continuous and light-dependent protein de novo biosynthesis.

Senescent: A New Neurospora crassa Nuclear Gene Mutant Derived from Nature Exhibits Mitochondrial Abnormalities and a “Death” Phenotype

Navaraj, A., Pandit, A., and Maheshwari, R. 2000. senescent: A new Neurospora crassa nuclear gene mutant derived from nature exhibits mitochondrial abnormalities and a “death” phenotype. Fungi are capable of potentially unlimited growth. We resolved nuclear types from multinuclear mycelium of a phenotypically normal wild isolate of the fungus Neurospora intermedia by plating its uninucleate microconidia and obtained a strain which, unlike the “parent” strain, exhibited clonal senescence in subcultures. The mutant gene, senescent, was introgressed into N. crassa and mapped four map units to the right of the his-1 locus on linkage group VR. senescent is the first nuclear gene mutant of Neurospora derived from nature that shows the death phenotype. Death of the sen mutant occurred faster at 34°C than at 22 or 26°C. Measurements of oxygen uptake of conidia using respiratory inhibitors and the spectrophotometric analyses of mitochondrial cytochromes showed that in sen cultures grown at 34°C, cytochromes b and aa3 were present but cytochrome c was absent. By contrast at 26°C, cytochromes b and c were present but cytochrome aa3 was diminished in the late subcultures. This suggested that the sen mutation does not affect the potential to produce functional cytochromes. The deficiency of the respiratory chain cytochromes may not be the cause of death of the sen mutant because the cytochrome c and aa3 mutants of N. crassa are capable of sustained growth whereas sen is not. Possible explanations for the observations are discussed.

Role of a white collar-1-white collar-2 complex in blue-light signal transduction

Mutations in either white collar-1 (wc-1) or white collar-2 (wc-2) lead to a loss of most blue-light-induced phenomena in Neurospora crassa. Sequence analysis and in vitro experiments show that WC-1 and WC-2 are transcription factors regulating the expression of light-induced genes. The WC proteins form homo- and heterodimers in vitro; this interaction could represent a fundamental step in the control of their activity. We demonstrate in vivo that the WC proteins are assembled in a white collar complex (WCC) and that WC-1 undergoes a change in mobility due to light-induced phosphorylation events. The phosphorylation level increases progressively upon light exposure, producing a hyperphosphorylated form that is degraded and apparently replaced in the complex by a newly synthesized WC-1. WC-2 is unmodified and also does not change quantitatively in the time frame examined. Light-dependent phosphorylation of WC-1 also occurs in a wc-2 mutant, suggesting that a functional WC-2 is dispensable for this light-specific event. These results suggest that light-induced phosphorylation and degradation of WC-1 could play a role in the transient expression of blue-light-regulated genes. Our findings suggest a mechanism by which WC-1 and WC-2 mediate light responses in Neurospora.

Functional anatomy of the kinesin molecule in vivo

We have developed an assay that allows the functional efficiency of mutant kinesins to be probed in vivo. We show here that the growth rate of the filamentous fungus Neurospora crassa can be used as a sensitive reporter for the ability of mutant kinesins to suppress the phenotype of the kinesin null mutant of Neurospora. Truncation mutants, internal deletion mutants and chimeras, in which homologous domains were exchanged between different fungal kinesins, were generated and transformed into the kinesin-deficient strain. None of the mutations affect motor velocity in vitro, but even minor alterations in the tail domain severely compromise kinesin's performance in vivo. The analysis of these mutants has identified subdomains in the stalk and tail likely to be involved in cargo binding and/or regulation of motor activity. The phenotypes of several mutants strongly suggest that kinesin requires a folded conformation to achieve full functionality in vivo. Folding critically depends on two flexible domains in the stalk that allow an interaction of the tail with the neck/hinge region near the catalytic motor domain. The assay has proven to be a valuable tool in the analysis of kinesin function in vivo and should help to characterize the sites involved in intra- and intermolecular interactions.

Mutants of Neurospora crassa defective in regulation of blue light perception.

A new selection system was used to isolate mutants deficient in regulation of blue light perception in Neurospora crassa. This selection system has two possible applications and was used for the isolation of either blind or constitutive mutants. We isolated 17 UV-induced mutants that showed the pleiotropic white collar (wc) phenotype and were completely blocked in transduction of the light signal. From the segregation pattern in sexual crosses, we tentatively assigned the 17 mutants to either the wc-1 or wc-2 gene. Furthermore, two Neurospora mutants, ccb-1 and ccb-2, were isolated that showed constitutive carotenoid biosynthesis in the dark. Analysis of these mutants for transcripts of the carotenoid biosynthesis genes al-3 and al-1 revealed no higher steady-state levels in the dark than in the control strain. The mutant cch-2 showed major differences in mRNA levels only for conidiation and developmental genes. The lack of a specific change in mRNA levels in response to light, and the mutant phenotype, which seems to reflect a step in conidiation, indicate a role for the cch-2 product in a developmental process, such as conidiation. In contrast, the mutant cch-1 showed a threefold overinduction of carotenoid biosynthesis genes in response to light. This effect was not observed for the conidiation genes examined. The recessive nature of the ccb-1 mutation, together with its specific effect on light induction of the carotenoid biosynthesis genes, indicate that the gene product of ccb-1 acts as a repressor of transcription in some light-regulated processes, but not others.

Loss of growth polarity and mislocalization of septa in a Neurospora mutant altered in the regulatory subunit of cAMP-dependent protein kinase.

In filamentous fungi, growth polarity (i.e. hyphal extension) and formation of septa require polarized deposition of new cell wall material. To explore this process, we analyzed a conditional Neurospora crassa mutant, mcb, which showed a complete loss of growth polarity when incubated at the restrictive temperature. Cloning and DNA sequence analysis of the mcb gene revealed that it encodes a regulatory subunit of cAMP-dependent protein kinase (PKA). Unexpectedly, the mcb mutant still formed septa when grown at the restrictive temperature, indicating that polarized deposition of wall material during septation is a process that is, at least in part, independent of polarized deposition during hyphal tip extension. However, septa formed in the mcb mutant growing at the restrictive temperature are mislocalized. Both polarized growth and septation are actin-dependent processes, and a concentration of actin patches is observed at growing hyphal tips and sites where septa are being formed. In the mcb mutant growing at the restrictive temperature, actin patches are uniformly distributed over the cell cortex; however, actin patches are still concentrated at sites of septation. Our results suggest that the PKA pathway regulates hyphal growth polarity, possibly through organizing actin patches at the cell cortex.