Circadian Rhythms in Neurospora crassa: Effects of Saturated Fatty Acids

To assess their effects on the conidiation rhythm in Neurospora, 14 saturated fatty acids from 6 to 24 carbons long were used to supplement the bd csp and bd csp cel strains. Both strains express a circadian spore-forming rhythm when grown on solid media; the cel mutation confers a partial fatty acid requirement. Fatty acid supplements from 8 to 13 carbons long lengthened the free-running period of bd csp cel compared with the control value of 21 h; the maximal effect (33 h) was obtained with nonanoic acid (9:0) at a concentration of 5 x 10(-4) M. In contrast, the period of bd csp remained unchanged under all experimental conditions. The short-chain fatty acids (<14 carbons) reduced the rate of advance of the growth front in both strains, compared with unsupplemented controls. However, this inhibition did not appear to be responsible for the lengthened periods in bd csp cel. Nor was direct incorporation of the short-chain (period-lengthening) fatty acids into mycelial total lipids responsible, since such incorporation was not observed. In fact, extensive metabolic conversion of these supplements by both strains was indicated by the disappearance of short-chain fatty acids from the agar media coupled with their absence in mycelial lipids, and by the liberation of (14)CO(2) from cultures supplemented with [1-(14)C]lauric acid (12:0).     

Altered Fatty Acid Distribution in Mutants of Neurospora crassa

Morphological mutants of Neurospora with decreased levels of reduced nicotinamide adenine dinucleotide phosphate (NADPH) and reduced nicotinamide ad enine dinucleotide (NADH) contained only 20% as much of a polyunsaturated fatty acid (linolenic acid) as the wild type in both the phospholipid and neutral lipid fractions. There was an excellent correlation between linolenic acid levels and morphological appearance as a function of total NADPH content, but no correlation with NADH content. The linolenic acid deficiency was balanced by a relative increase in the amounts of the less unsaturated fatty acids (oleic and linoleic acids), but the level of three other fatty acids did not appear to be changed. This accumulation of these two precursors suggests that the NADPH deficiency preferentially affected the final desaturation step, i.e., the conversion of linoleic to linolenic acid. The NADPH needed for this reaction in vivo was probably generated by the pentose phosphate shunt, since mutations affecting the shunt lead to the decreased levels of linolenic acid. It is not clear whether the changes in fatty acid distribution affect the morphogenesis of Neurospora, or if these changes are just part of the NADPH-deficiency syndrome.     

Circadian Rhythms of Nucleic Acid Metabolism in Neurospora crassa

Wild-type, band, and fluffy strains of Neurospora crassa exhibit circadian rhythms of ribonucleic acid and deoxyribonucleic acid content in the growth-front hyphae of cultures grown on a solid medium. There is also a rhythm of (3)H-uridine incorporation into the nucleic acids of the band strain. Maximum incorporation precedes the peaks of nucleic acid content which occur during conidiation. As cultures age, ribonucleic acid content decreases rapidly and deoxyribonucleic acid content decreases gradually in standing, shake, and bubble cultures. A reduction of ribonuclease activity with age is also noted in standing and shake cultures. The nucleic acid content, nuclease activity, and changes associated with age vary with the culture conditions.     

Peptide Utilization by Amino Acid Auxotrophs of Neurospora crassa

The ability of auxotrophs of Neurospora crassa to grow on certain tripeptides, despite the presence of excess competing amino acids, suggests it has an oligopeptide transport system. In general, dipeptides did not support growth except in those instances where extracellular hydrolysis occurred, or where the dipeptide appeared to be accumulated by an uptake system which is sensitive to inhibition by free amino acids. Considerable intracellular peptidase activity toward a large number of peptides was demonstrated, including a number of peptides which could not be utilized for growth. The intracellular peptidase activity was shown to be selective for amino acid composition and sequence (N-terminal or C-terminal) within the peptide; glycine-containing peptides were particularly poor substrates for peptidase activity. Only a small amount of extracellular peptidase activity could be detected.     

Saturated Fatty Acid Mutant of Saccharomyces cerevisiae with an Intact Fatty Acid Synthetase

To determine directly the effects of streptomycin on translational fidelity in intact cells, we studied the synthesis of beta-galactosidase and of the coat protein of bacteriophage R17 in an Escherichia coli mutant in which the bactericidal effects of streptomycin are delayed. After the addition of streptomycin to exponentially growing mutant cells, protein synthesis continues at an undiminished rate for approximately an hour; however, as measured by enzyme assays, little functional protein is produced. Serological assays designed to detect beta-galactosidase and bacteriophage R17 coat protein show that substantial amounts of the protein synthesized can react with antisera prepared against active beta-galactosidase and phage R17, indicating the aberrance of the protein produced in the presence of the antibiotic. The polypeptides synthesized in the presence of streptomycin are degraded in the cell to a much greater extent than protein synthesized in the absence of the antibiotic. The proteolytic attack on this protein is not affected by inhibitors of serine proteases, suggesting that enzymes other than those involved in "normal turnover" of cellular protein are responsible. In this strain, certain of the multiple effects of streptomycin are separated in time and the production of abnormal protein (enzymatically inactive and susceptible to proteolytic attack) could be studied in the absence of the lethal effect of the drug.     

End-Product Regulation of the Tryptophan-Nicotinic Acid Pathway in Neurospora crassa

The regulation of the tryptophan-nicotinic acid pathway in Neurospora crassa was examined with mutants (nic-2, nic-3) which require nicotinamide for growth. The accumulation of N-acetylkynurenin and 3-hydroxyanthranilic acid by these mutants served to estimate the level of function of the early reactions in the pathway. In still cultures, maximal accumulation occurred with media containing growth-limiting amounts of nicotinamide; the accumulation of intermediates was almost negligible with nicotinamide in excess. Only nicotinamide and closely related compounds which also supported the growth of these mutants inhibited the accumulation of intermediates. The site of inhibition was assessed to be between tryptophan and kynurenin (or N-acetylkynurenin). The synthesis of N-acetylkynurenin was examined in washed germinated conidia suspended in buffer; the level of N-acetylkynurenin-synthesizing activity was inversely related to the concentration of nicotinamide in the germination medium. The addition of large amounts of nicotinamide to suspensions of germinated conidia did not affect their N-acetylkynurenin-synthesizing activity. Formamidase activity, kynurenin-acetylating activity, and gross tryptophan metabolism in germinated conidia was not influenced by the concentration of nicotinamide in the germination medium. The results obtained indicate that the site of inhibition by nicotinamide is the first step in the pathway, the tryptophan pyrrolase reaction. The data are interpreted as nicotinamide or a product thereof, such as nicotinamide adenine dinucleotide, acting as a repressor of the formation of tryptophan pyrrolase in N. crassa.     

Transfer Ribonucleic Acid Methylases During the Germination of Neurospora crassa

Transfer ribonucleic acid (tRNA) methylases were studied during the germination of spores in Neurospora crassa. The total methylase capacity and base specific tRNA methylase activities were determined in extracts from cells harvested at various stages of germination. Germinated conidia have a 65% higher methylase capacity than ungerminated conidia. Three predominant methylase activities were found in the extracts, and the relative amount of each activity was different at the various stages. Enzymes from vegetative cells catalyzed significant hypermethylation of tRNA from conidia, whereas conidial enzymes were much less active on tRNA from vegetative cells. The results indicate differences in the tRNA methylase content and tRNA species of conidia and vegetative cells.     

Microconidia of Neurospora crassa

Neurospora crassa produces two types of vegetative spores-relatively small numbers of uninucleate microconidia and very large numbers of multinucleate macroconidia (blastoconidia and arthroconidia). The microconidia can function either as spermatia (male gametes) or as asexual reproductive structures or both. In nature they probably function exclusively in fertilization of protoperithecia. The environmental conditions favoring their formation and the pattern of their development are quite distinct from those of macroconidia. Mutants of N. crassa have been isolated in which macroconidiation is selectively blocked without affecting microconidiation, showing that these two types of conidial differentiation involve distinct developmental pathways. Unlike microconidia of some related ascomycetes, those of Neurospora are capable of germination, providing viable uninucleate haploid cells which are desired in several types of investigations. A technique of selectively removing macroconidia from culture initiated on cellophane overlying agar medium allows pure microconidia to be obtained even from the wild-type strains of Neurospora. The conditional microcyclic strain, mcm, allows either macroconidia or microconidia to be obtained at will, depending on the conditions of culture. The new methods of obtaining pure microconidia from normal laboratory strains will make it quick and easy to purify heterokaryotic transformants following introduction of DNA into multinucleate protoplasts. Moreover, these methods allow the detection of genetic variability that remains hidden within an individual fungus and the estimation of the frequency of nuclear types in laboratory-constructed heterokaryons. The discovery, function, and development of microconidia are described and their research applications are discussed in this review.     

Conidiation in Neurospora crassa

Summary Conidiation in Neurospora crassa has been studied in vivo by time-lapse microphotography and shown to be most generally (in aerial, dry conditions) a budding-fission process. Such a two-phase process is characterized by an initial basifugal budding of proconidial elements which are then secondarily separated as maturing conidia by interconidial septa. Dry macroconidia of Neurospora are thus blasto-arthrospores, i.e. blastospores basifugally budded on conidiophores and secondarily disarticulated from the proconidial chain as arthrosporal elements. Inception and median splitting of the interconidial septum have been electron microphotographed.In the vegetative hyphae, ethanol dehydrogenase has been cytochemically detected by oxidative assay and demonstrates a dense, uniform distribution of activity except at the hyphal tips. In the conidiating hyphae, the ethanol dehydro-genase becomes less dense in distribution, especially in the budding apices. Cytochrome oxidase activity, localized in the mitochondria, is confined in the subapical zone of vegetative hyphae while at the initiation of conidiation it becomes dispersed throughout the proconidial buds.     

Photoperiodism in Neurospora crassa

Plants and animals use day or night length for seasonal control of reproduction and other biological functions. Overwhelming evidence suggests that this photoperiodic mechanism relies on a functional circadian system. Recent progress has defined how flowering time in plants is regulated by photoperiodic control of output pathways, but the underlying mechanisms of photoperiodism remain to be described. The authors investigate photoperiodism in a genetic model system for circadian rhythms research, Neurospora crassa. They find that both propagation and reproduction respond systematically to photoperiod. Furthermore, a nonreproductive light-regulated function is also enhanced under certain photoperiodic conditions. All of these photoperiodic responses require a functional circadian clock, in that they are absent in a clock mutant. Night break experiments show that measuring night length is one of the mechanisms used for photoperiod assessment. This represents the first formal report of photoperiodism in the fungi.     

Disruption of an Amino Acid Transport Mutant of Neurospora crassa by KCl

A double amino acid transport-deficient mutant (Pm (-)NB) of Neurospora crassa is shown to be altered in the molecular structure of its cell wall or membrane. This alteration was revealed by a high degree of cellular disruption and cell-cell interaction following extraction by a high molar concentration of KCl.     

Cold-sensitive Mutants of Neurospora crassa

Cold-sensitive mutants of the eucaryote Neurospora crassa have been isolated by a modification of the filtration-enrichment technique of Catcheside. The mutants include osmotic remedial, auxotrophic, transport, and incorporation deficient isolates.     

Metal transportome of Neurospora crassa

Neurospora crassa has been the model filamentous fungus for the study of many fundamental cellular mechanisms of transport and metabolism. The recently completed genome sequence of N. crassa has over 10,000 genes without significant matches for a large number of genes (41%) in the sequence databases, indeed presents many challenges for new discoveries. Using transporter database and BLAST searches a total of 65 open reading frames for putative cation transporter genes have been identified in N. crassa. These were further confirmed by characteristic features of the family like transmembrane domains (TOPPRED 2), conserved motifs (Clustal W) and phylogenetic analysis (TREETOP). In Neurospora cation transporter genes constitute nearly 18.3% of the total membrane transport systems, which is higher than E. coli (8.8%), S. cerevisiae (13.7%), S. pombe (17.2%), A. fumigatus (10.1%), A. thaliana (16.8%) and H. sapiens (15.6%). We refer to the complete complement of metal ion transporter genes as "Metal Transportome". There are a total of 33 putative transporters for alkali and alkaline earth metals constituting 18 for calcium (P-ATPase, VIC, CaCA, Mid1), 7 for sodium (P-ATPase, CPA1, CPA2), 4 for potassium (Trk, VIC, KUP), and 4 for magnesium (MIT). Transition metal ion transporters account for 32 transporters including 7 for zinc (ZIP), 6 for copper (Ctr2, Ctr1), 2 each for manganese (Nramp), iron (OFeT), arsenite (ArsAB, ACR3) and other metal ions (ABC and P-ATPase) and 1 each for nickel (NiCoT) and chromate (CHR). N. crassa has 7 linkage groups of which LGI harbors 21 of metal ion transporters and in contrast LGVII has only 2. Studies on metal transportomes of different organisms will help to unravel the role of metal ion transporters in homeostasis.     

Redundant DNA of Neurospora crassa

Approximately 20% of the DNA of Neurospora crassa consists of redundant sequences. This is calculated from the reassociation rate of fragmented, denatured DNA as measured by hydroxyapatite column chromatography. The redundant DNA has a complexity of 10⁵ base pairs and a repetition frequency of up to 60 copies per genome. Its buoyant density in CsCl is 1.720 g/ml and its hypochromicity 20–24%. Base composition determination shows 54% GC content like Neurospora nuclear DNA. DNA-RNA hybridization studies indicate that rRNA and tRNA cistrons make up 2.3 and 1.2%, respectively, of the redundant fraction. Pulse-labeled RNA is shown to hybridize with both redundant and unique DNA fractions, suggesting that both fractions are transcribed.This work is supported by a grant from National Science Foundation (GB 8058) and National Institute of Health Research Career Development Award (K3GM31-238).     

大豆饱和脂肪酸组分改良研究进展

为了更好地满足消费者的需要,遗传改良豆油中脂肪酸含量已经取得很大进展,并有3个油分改良的大豆品种已经商品化,其油分中亚麻酸的含量已经从原来的8%降到了1%,油酸含量也已从25%增加到80%,棕榈酸从11%降到小于4%。传统育种和基因工程育种都是遗传改良大豆油的手段。阐述了遗传改良、基因型和表现型的选择等多方法对脂肪酸的影响,总结了大豆饱和脂肪酸组翻改良的主要进展。     

Histones of Neurospora crassa.

Neurospora crassa chromatin isolated by a rapid method minimizing proteolytic degradation contains approximately one weight of acid-extractable basic protein per weight of DNA. This basic protein consists of five major polypeptide species which are similar in size to the histone proteins of higher eukaryotes and are present in approximately the same molar ratios. These five polypeptides have been purified by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. Their electrophoretic mobilities in polyacrylamide gels and their amino acid compositions indicate that they are histones homologous, although not identical, to the H1, H2A, H2B, H3, and H4 histones of mammals. The first 3 residues in the amino acid sequence of Neurospora H3 histone are identical to the first 3 residues in calf and pea H3; Neurospora H1, H2A, and H4 histones have blocked NH2 termini, like their mammalian counterparts. The finding of recognizable H1, H2A, H2B, H3, and H4 histones in Neurospora extends the range of eukaryotes now shown to contain a full complement of these strongly conserved chromosomal proteins, and supports the view that histones became involved in chromosome structure at a very early point in the evolution of eukaryotes.