Isolation of a sexual sporulation hormone from Aspergillus nidulans.

Psi factor is a substance produced by Aspergillus nidulans that induces premature sexual sporulation. Chromatographic analysis of psi-active extracts showed that psi activity resides in several different forms. Two of the forms, psiA1 and psiB1, have been isolated and have been shown to have closely similar compositions. The most abundant form, psiA1, reacts with alcohols in acidic solution by the addition of one entire molecule of the alcohol. This reaction, which is reversible, suggests that psiA1 may be a lactone whose ring is opened by alcohol addition. At high concentration, psiA1 is antagonistic to the response exhibited by the other forms of psi, but this antagonism is lost by the alcoholic derivatives. At least one unpurified psi species can be converted to psiA1 by acid catalysis. We suggest that psiA1 may be the metabolic precursor of at least some of the other more active psi components and that this conversion during Aspergillus development may be part of the process that triggers sexual sporulation.

An endogenous inducer of sexual development in Aspergillus nidulans.

During development of the homothallic ascomycete Aspergillus nidulans, asexual sporulation is followed by sexual sporulation. We report here the detection of a solvent-extractable activity which inhibits asexual sporulation and stimulates premature sexual sporulation. This activity, called precocious sexual inducer (psi), is overproduced by certain mutants that are blocked in both modes of sporulation. Using partially purified preparations of psi, biological response could be elicited with as little as 50 ng of material. We suggest that psi is a hormone-precursor which is converted to a hormone by normal sporulating strains that respond to psi, but not by the asporogenous mutants that overproduce psi. The stability of psi activity gives promise that the compound can be purified and identified.

Mutants of Aspergillus nidulans blocked at an early stage of sporulation secrete an unusual metabolite.

Mutants of Aspergillus nidulans defective in conidiation (asexual sporulation) can be classified according to whether they are blocked before or after induction of conidiation. Mutants blocked before induction (preinduction mutants) appear to be unable to respond to the inducing stimulus and thus are defective in one of the earliest events in the sporulation process. Three preinduction mutants have been isolated and characterized. Each was found to exhibit the same pleiotropic phenotype: they also were defective in sexual sporulation and secreted a set of phenolic metabolites at a level much higher than did wild type or mutants blocked at later stages of conidiation. One of the metabolites has been identified as the antibiotic diorcinal (3,3'-dihydroxy-5,5'-dimethyldiphenyl ether) which is known to be involved in the synthesis of certain farnesyl phenols of unknown function. These results suggest that preinduction mutants are blocked in a phenolic metabolic pathway, one or more product of which participates in the initiation of sporulation.

Genetic analysis of mutants of Aspergillus nidulans blocked at an early stage of sporulation.

Three mutants of Aspergillus nidulans, selected to have a block at an early stage of conidiation (asexual sporulation), exhibit similar pleiotropic phenotypes. Each of these mutants, termed preinduction mutants, also are blocked in sexual sporulation and secrete a set of phenolic metabolites at level much higher than wild type or mutants blocked at later stages of conidiation. Backcrosses of these mutants to wild type showed that the three phenotypes always cosegregated. Diploids containing the mutant alleles in all pairwise combinations were normal for all phenotypes, showing that the three mutations are nonallelic. This conclusion was confirmed by the finding that the mutations map at three unlinked or distantly linked loci. Ten revertants of the two least leaky preinduction mutants, selected for ability to conidiate, were found in each case to arise by a second-site suppressor mutation. All of the revertants still showed accumulation of some of the phenolic metabolites but differed from each other in certain components. Three of the revertants retained the block in sexual sporulation. In these cases the suppressor has thus uncoupled the block in asexual sporulation from the block in sexual sporulation. These results are understandable in terms of a model in which preinduction mutations and their suppressors affect steps in a single metabolic pathway whose intermediates include an effector specific for asexual sporulation and a second effector specific for sexual sporulation.

Developmental defects resulting from arginine auxotrophy in Aspergillus nidulans.

A mutant of Aspergillus nidulans, isolated for inability to form asexual spores (conidia) on complete medium, was found to regain the ability to conidiate if the medium was supplemented with arginine. On minimal medium the mutant required arginine for growth but at a much lower concentration than that required for conidiation. This mutant, designated argB12, thus defines a phase-critical gene, i.e. a gene whose function is in greater demand for development than for growth. In addition to its aconidial phenotype, the mutant also exhibited (depending on the medium) aberrant sexual development and a low efficiency of conidial germination. In crosses, each of these developmental phenotypes segregated with arginine auxotrophy. Genetic and biochemical analyses showed the argB12 mutation to be an allele of the previously described argB locus, mutants of which lack ornithine transcarbamylase. Arginine-requiring mutants at at least two other loci were also found to be defective in asexual sporulation, but the germination defect appears to be specific to argB mutants.

Laccase localized in hulle cells and cleistothecial primordia of Aspergillus nidulans.

Several species of the genus Aspergillus form sexual spores within minute (approximately 0.2 mm) spherical shells (cleisthothecia) which are woven from specialized hyphae. Aspergillus nidulans cleistothecia are uniquely characterized by their dark red coloration and an envelope of thick-walled globose cells (hulle cells). By use of a new chromogenic substrate, we have shown that the constitutent hyphae of young cleistothecia and the hulle cells which surround the cleistothecia of A. nidulans exhibit a strong phenoloxidase activity which has the substrate specificity of a laccase. This enzyme (laccase II) is distinct from the previously described phenoloxidase (laccase I) that participates in the synthesis of the conidial pigment of A. nidulans: the two enzymes differ electrophoretically, do not cross-react immunologically, appear at different times during colonial development, and are under different genetic control. Examination of seven additional species of Aspergillus showed that the hulle cells of three acleistothecial species were also laccase positive, whereas the pale or unpigmented cleistothecia of four species (which lack hulle cells) were laccase negative. The relevance of these findings to the role of hulle cells in cleistothecial development is discussed. The presence of histologically detectable laccase in cleistothecial primordia provides a valuable tool, previously unavailable, for quantitating the early stages of sexual development in A. nidulans.

Purification and characterization of the conidial laccase of Aspergillus nidulans.

Conidial laccase of Aspergillus nidulans was purified by standard protein purification methods. Although the purified material showed a cluster of several protein bands on a nondenaturing gel, each of these protein bands had laccase activity. All bands of activity, however, were absent in a strain carrying a mutation in the structural gene for laccase. Concentrated solutions (greater than 1 mg/ml) were bright blue, suggesting that, like other laccases, this enzyme contains copper. The enzyme contained asparagine-linked carbohydrate (12% by weight) which could be removed by digestion with endo-beta-N-acetylglucosaminidase H. The molecular weight of native enzyme as determined by gel filtration was 110,000, but the largest component in a sodium dodecyl sulfate gel was 80,000. Several smaller components (55,000 and 36,000 molecular weight) were also visible. We present evidence which suggests that the smaller components are in vivo cleavage products tightly associated with enzymatically active molecules. Comparison of the laccase from a white-spore (wA) and a green-spore (wA+) strain showed, surprisingly, that the enzymes differed in electrophoretic pattern, in vitro heat stability, and in vivo metabolic stability. The difference was manifested for enzymes isolated from cultures after conidial pigmentation of the wA+ strain had occurred. If examined earlier, before pigmentation, the enzymes were indistinguishable. Since wA strains lack the precursor of the wild-type green pigment, i.e., the laccase substrate, we suggest that the transformation of the enzyme of the wA strain is due to its failure to interact with its normal substrate.

Dominant spore color mutants of Aspergillus nidulans defective in germination and sexual development.

The ascomycete Aspergillus nidulans produces green conidia (asexual spores). Recessive mutants which produce yellow conidia have been previously isolated from haploid strains and have been shown to be deficient in laccase (diphenol oxidase), an enzyme that requires copper for activity. Using a diploid parent strain, we isolated dominant yellow conidial mutants which, in the haploid state, produced even less laccase activity than a recessive mutant. Three isolates of such mutants behaved similarly and define a single complementation group (yB) on chromosome VIII distinct from the yA locus on chromosome I defined by recessive mutants. Unlike yA mutants, whose only discernable phenotype is their conidial color, yB mutants are pleiotropic: conidial germination was delayed relative to the wild type, and sexual development was blocked at an early stage. The three phenotypes of yB mutants were expressed on yeast extract-glucose medium containing 1.6 microM of added copper. When copper was added to above 5 microM, all three phenotypes were remediated, and near wild-type levels of laccase were produced. We conclude that yB mutants have a reduced availability of copper. The dominance of yB mutants could result, for example, from an alteration in transport or storage of copper. Using an immunological assay, we detected no laccase antigenic cross-reacting material in yB mutants grown on medium of low copper content. We conclude that either the synthesis or the stability of laccase is copper dependent.

Precursors of the T4 internal peptides.

The precursors of the two T4 internal peptides have been identified by in vitro cleavage of individual phage proteins eluted from sodium dodecyl sulfate-acrylamide gels. The precursor of internal peptide VII is p22, the product of T4 gene 22 and an essential component of the morphogenic core. The precursor of peptide II is a protein with a molecular weight of approximately 13,000, whose gene has yet to be defined by mutation. A newly detected protein of approximately 15,000 molecular weight is found to be cleaved and is, therefore, likely to be a component of precursor head structures.

Role and location of "protease I" from Escherichia coli.

Pacaud and Uriel described an enzyme from Escherichia coli ("protease I") that hydrolyzes acetyl phenylalanine naphthyl ester (APNE). We examined the possible involvement of this enzyme in intracellular protein degradation, its subcellular distribution, and its proteolytic activity. Although the APNE-hydrolyzing activity is localized primarily in the periplasm, proteolytic activity against casein was found in the periplasm, membrane, and cytoplasm with similar specific activities. The APNE-hydrolyzing enzyme did not appear to contribute to the proteolytic activity of the periplasm. A mutant deficient in APNE-hydrolyzing activity lacked all activity in the periplasm but showed a slight percentage of residual activity in the cytoplasm. Extracts of such cells were normal in their ability to hydrolyze casein. The mutant was indistinguishable from wild-type cells in its rate of protein degradation during growth or glucose starvation and in the ability to rapidly degrade puromycin-containing polypeptides. Nitrogen starvation, which increased protein breakdown severalfold, affected neither the total amount nor the distribution of APNE-hydrolyzing activity. The mutant showed no defect in its ability to cleave small phenylalanine-containing peptides released during protein degradation. The mutant and wild-type cells are equally able to hydrolyze exogenously supplied phenylalanyl peptides. These experiments suggest that the APNE-hydrolyzing enzyme is not required for protein degradation and that "protease I" is probably not a protease.

Identification of gene products required for in vitro formation of the internal peptides of bacteriophage T4.

In vitro formation of both bacteriophage T4 internal peptides (II and VII) from preexisting precursor protein was shown to require the product of T4 gene 21. The proteolytic factor was detectable in extracts of cells infected with certain phage mutants blocked in early steps of head assembly but could not be demonstrated in extracts of T4 wild-type infected cells. This finding suggests that the proteolytic factor is inactivated during normal phage assembly. The product of T4 gene 22 appears to be the precursor of peptide VII but not of peptide II.

T4-induced activity required for specific cleavage of a bacteriophage protein in vitro.

We have examined the acid-soluble products formed during incubation of labeled substrate protein from T4-infected cells with unlabeled phage-infected cell extracts. If the substrate protein is prepared from cells infected with a T4 mutant blocked in cleavage of phage head precursor proteins, the products formed in vitro include a peptide indistinguishable by several criteria from one of the T4 internal peptides. Denatured as well as undenatured protein can serve as the substrate for the formation of this peptide. As expected, this peptide is not formed if protein from either uninfected cells or cells infected with wild-type T4 is used as substrate. The formation of this peptide in vitro is dependent on a factor present in extracts of phage-infected cells but absent from extracts of uninfected cells.