Molecular cloning of a Neurospora crassa carotenoid biosynthetic gene (albino-3) regulated by blue light and the products of the white collar genes.

The albino-3 (al-3) gene of Neurospora crassa, which probably encodes the carotenoid biosynthetic enzyme geranylgeranyl pyrophosphate synthetase, was cloned. The N. crassa triple mutant al-3 qa-2 aro-9 was transformed to qa-2+ with mixtures of plasmids bearing N. crassa DNA inserts, and the transformants were screened for the al-3+ phenotype. One al-3+ qa-2+ transformant (AL3-1) was examined in detail and shown to contain intact vector sequences integrated into the N. crassa genome. The vector and some flanking sequences were recovered from AL3-1 after restriction, ligation, and selection of chloramphenicol-resistant transformants of Escherichia coli. The flanking sequences were subsequently used to detect the al-3-containing plasmid in the mixture of about 1,800 plasmids. Restriction fragment length polymorphism mapping was carried out to confirm the identity of the cloned fragment. The level of the al-3 mRNA was shown to be increased 15-fold in light-induced (compared with that in dark-grown) wild-type mycelia. The light-dependent increase in al-3 mRNA levels was not observed in presumed regulatory mutant (white collar) strains.     

Nucleotide sequence of the Neurospora crassa trp-3 gene encoding tryptophan synthetase and comparison of the trp-3 polypeptide with its homologs in Saccharomyces cerevisiae and Escherichia coli

The complete nucleotide sequence of the Neurospora crassa trp-3 gene-encoding tryptophan synthetase has been determined; we present an analysis of its structure. A comparison of the deduced amino acid sequence of the trp-3 polypeptide with its homologs in Saccharomyces cerevisiae (encoded by the TRP5 gene) and Escherichia coli (encoded by the trpA and trpB genes) shows that the A and B domains (amino acid segments homologous to the trpA and trpB polypeptides, respectively) of the N. crassa and yeast polypeptides are in the same order (NH2-A-B-COOH). This arrangement is the reverse of the gene order characteristic of all prokaryotes that have been examined. N. crassa tryptophan synthetase has strong homology to the yeast TRP5 polypeptide (A domains have 54% identity; B domains have 75% identity), and somewhat weaker homology to the E. coli trpA and trpB polypeptides (A domains have 31% identity; B domains have 50% identity). The two domains of the N. crassa polypeptide are linked by a connector of 54-amino acid residues that has less than 25% identity to the 45-residue connector of the yeast polypeptide, although secondary structure analysis predicts both connectors would be alpha-helical. In contrast to the yeast TRP5 gene, which has no introns, the trp-3 coding region is interrupted by two introns 77 and 71 nucleotides in length. Both introns are located near the 5'-end of the gene and therefore not near the segment encoding the connector.     

Complete nucleotide sequence of the Escherichia coli gdhA gene

The DNA sequence of the gdhA gene of Escherichia coli K12, which encodes the 447 amino acid polypeptide subunit of NADP-specific glutamate dehydrogenase, is presented. The deduced protein sequence is strongly homologous to the corresponding enzyme of the eukaryotic fungus Neurospora crassa. The upstream DNA sequence includes several overlapping promoter consensus sequences. The downstream DNA sequence contains inverted repeats, predicted as forming long stable stem-loop structures in RNA, homologous to those found in several enterobacterial intergenic regions.     

Amino acid sequence of Escherichia coli glutamine synthetase deduced from the DNA nucleotide sequence

Glutamine synthetase is encoded by the glnA gene of Escherichia coli and catalyzes the formation of glutamine from ATP, glutamate, and ammonia. A 1922-base pair fragment from a cDNA containing the glnA structural gene for E. coli glutamine synthetase has been sequenced. An open reading frame of 1404 base pairs encodes a protein of 468 amino acid residues with a calculated molecular weight of 51,814. With few exceptions, the amino acid sequence deduced from the DNA sequence agreed very well with the amino acid sequences of several peptides reported previously. The secondary structure predicted for the E. coli enzyme has approximately 36% of the residues in alpha-helices which is in agreement with calculations of approximately 39% based on optical rotatory dispersion data. Comparison of the amino acid sequences of glutamine synthetase from E. coli (468 amino acids) and Anabaena (473 amino acids) (Turner, N. E., Robinson, S. T., and Haselkorn, R. (1983) Nature 306, 337-342) indicates that 260 amino acids are identical and 80 are of the same type (polar or nonpolar) when aligned for maximum homology. Several homologous regions of these two enzymes exist, including the sites of adenylylation and oxidative modification, but the regulation of each enzyme is different.     

Primary structure of the Neurospora plasma membrane H+-ATPase deduced from the gene sequence. Homology to Na+/K+-, Ca2+-, and K+-ATPase

The gene for the Neurospora crassa plasma membrane H+-ATPase has been cloned and sequenced. The gene encodes for a protein of 920 amino acids with a molecular weight of 100,002. The coding region is interrupted by four introns: three near the amino terminus and one near the carboxyl terminus. The deduced amino acid sequence of the N. crassa plasma membrane H+-ATPase exhibits 75% homology to the amino acid sequence of the Saccharomyces cerevisiae plasma membrane H+-ATPase. Also, an amino acid comparison with the Na+/K+-ATPase from sheep kidney, Ca2+-ATPase from rabbit muscle, and K+-ATPase from Escherichia coli reveals that certain regions are highly conserved and suggest that these regions may serve essential functions which are common to the various cation-motive ATPases. This observation suggests that the phosphorylatable, cation-motive ATPases may function via a similar energy transduction mechanism.     

Molecular comparison of the negative-acting nitrogen control gene,nmr, inNeurospora crassa and otherNeurospora and fungal species

In Neurospora crassa, the expression of unlinked structural genes which encode nitrogen catabolic enzymes is subject to genetic and metabolic regulation. The negative-acting nmr regulatory gene appears to play a role in nitrogen catabolite repression. Using the N. crassa nmr gene as a probe, homologous sequences were identified in a variety of other filamentous fungi. The polymerase chain reaction was used to isolate the nmr-like gene from the exotic Mauriceville strain of N. crassa and from the two related species, N. intermedia and N. sitophila. Sequence comparisons were carried out with a 1.7-kb DNA segment which includes the entire coding region of nmr plus 5' and 3' noncoding sequences. The size of the nmr coding region was identical in all three Neurospora species. Approximately 30 nucleotide base substitutions were found in the coding region of the nmr gene of each of the sister species when compared to the standard N. crassa sequence. However, most of the base changes occurred in third codon positions and were silent. The NMR proteins of N. sitophila and of N. intermedia display only three and four amino acid substitutions, respectively, from the N. crassa protein. Two regions of high variability, which include deletions and insertions of bases, were found in the 5' and 3' noncoding regions of the gene.     

Phylogenetic Analysis of Heterothallic Neurospora Species

We examined the phylogenetic relationships among five heterothallic species of Neurospora using restriction fragment polymorphisms derived from cosmid probes and sequence data from the upstream regions of two genes, al-1 and frq. Distance, maximum likelihood, and parsimony trees derived from the data support the hypothesis that strains assigned to N. sitophila, N. discreta, and N. tetrasperma form respective monophyletic groups. Strains assigned to N. intermedia and N. crassa, however, did not form two respective monophyletic groups, consistent with a previous suggestion based on analysis of mitochondrial DNAs that N. crassa and N. intermedia may be incompletely resolved sister taxa. Trees derived from restriction fragments and the al-1 sequence position N. tetrasperma as the sister species of N. sitophila. None of the trees produced by our data supported a previous analysis of sequences in the region of the mating type idiomorph that grouped N. crassa and N. sitophila as sister taxa, as well as N. intermedia and N. tetrasperma as sister taxa. Moreover, sequences from al-1, frq, and the mating-type region produced different trees when analyzed separately. The lack of consensus obtained with different sequences could result from the sorting of ancestral polymorphism during speciation or gene flow across species boundaries, or both.     

Isolation of a class IV chitin synthase gene from a zygomycete fungus, Rhizopus oligosporus

We found the presence of DNA sequence which shows sequence similarity to the class IV chitin synthase gene (CHS3) of Saccharomyces cerevisiae in the genome of 14 Rhizopus species which belong to zygomycetes. We cloned a gene (chs3), which might correspond to one of these homologous sequences, from Rhizopus oligosporus by low stringency plaque hybridization probed with CHS3. The deduced amino acid sequence of this gene showed highest similarity to the class IV chitin synthase of Neurospora crassa (46.7% identity over 1087 amino acids), showing that this gene encodes a class IV chitin synthase. Northern analysis revealed the differential expression pattern of this gene in the asexual life cycle with highest expression in the early stage of asexual spore formation. This is the first report of the isolation and analysis of a class IV chitin synthase gene from zygomycete fungi.     

The Intriguing Evolution of the “b” and “G” Subunits in F-type and V-type ATPases: Isolation of the vma-10 Gene from Neurospora crassa

We have characterized the vma-10 gene which encodes the G subunit of the vacuolar ATPase in Neurospora crassa. The gene is somewhat unusual in filamentous fungi because it contains five introns, comprising 71% of the region between the translation start and stop codons. The 5 untranslated region of the gene contains several elements that have been identified in other genes that encode subunits of the vacuolar ATPase in N. crassa. A comparison of G subunits from N. crassa, S. cerevisiae, and animal cells showed that the N-terminal half of the polypeptide shows the highest degree of sequence conservation. Most striking is the observation that this region could form an alpha helix in which all of the conserved residues are clustered on one face. Subunit G appears to be homologous to the b subunit found in F-type ATPases. The major difference between the b and G subunits is the lack of a membrane-spanning region in the G subunit. We have also identified homologous subunits in the operons which encode V-type ATPases in a eubacterium, Enterrococcus hirae, and an archaebacterium, Methanococcus jannaschii. As in eukaryotic vacuolar ATPases the G subunit homologs lack a membrane-spanning region. Although the b and G subunits appear to be derived from a common ancestor, significant changes have evolved. In F-type and V-type ATPases these subunits can have zero, one, or two membrane-spanning regions and can also differ significantly in the number of copies per enzyme.     

Developmental regulation of the gene for formate dehydrogenase in Neurospora crassa.

We have isolated and characterized a gene, fdh, from Neurospora crassa which is developmentally regulated and which produces formate dehydrogenase activity when expressed in Escherichia coli. The gene is closely linked (less than 0.6 kb apart) to the leu-5 gene encoding mitochondrial leucyl-tRNA synthetase; the two genes are transcribed convergently from opposite strands. The expression patterns of these genes differ: fdh mRNA is found only during conidiation and early germination and is not detectable during mycelial growth, while leu-5 mRNA appears during germination and mycelial growth. The structure of the fdh gene was determined from the sequence of cDNA and genomic DNA clones and from mRNA mapping studies. The gene encodes a 375-amino-acid-long protein with sequence similarity to NAD-dependent dehydrogenases of the E. coli 3-phosphoglycerate dehydrogenase (serA gene product) subfamily. In particular, there is striking sequence similarity (52% identity) to formate dehydrogenase from Pseudomonas sp. strain 101. All of the residues thought to interact with NAD in the crystal structure of the Pseudomonas enzyme are conserved in the N. crassa enzyme. We have further shown that expression of the N. crassa gene in E. coli leads to the production of formate dehydrogenase activity, indicating that the N. crassa gene specifies a functional polypeptide.     

Eth-1, the Neurospora Crassa Locus Encoding S-Adenosylmethionine Synthetase: Molecular Cloning, Sequence Analysis and in Vivo Overexpression

Intense biochemical and genetic research on the eth-1(r) mutant of Neurospora crassa suggested that this locus might encode S-adenosylmethionine synthetase (S-Adomet synthetase). We have used protoplast transformation and phenotypic rescue of a thermosensitive phenotype associated with the eth-1(r) mutation to clone the locus. Nucleotide sequence analysis demonstrated that it encodes S-Adomet synthetase. Homology analyses of prokaryotic, fungal and higher eukaryotic S-Adomet synthetase polypeptide sequences show a remarkable evolutionary conservation of the enzyme. N. crassa strains carrying S-Adomet synthetase coding sequences fused to a strong heterologous promoter were constructed to assess the phenotypic consequences of in vivo S-Adomet synthetase overexpression. Studies of growth rates and microscopic examination of vegetative development revealed that normal growth and morphogenesis take place in N. crassa even at abnormally high levels of cellular S-Adomet. The degree of cytosine methylation of a naturally methylated genomic region was dependent on the cellular levels of S-Adomet. We conclude that variation in S-Adomet levels in N. crassa cells, which in addition to the status of genomic DNA methylation could modify the flux of other S-Adomet-dependent metabolic pathways, does not affect growth rate or morphogenesis.     

Isolation of genes encoding the Neurospora vacuolar ATPase. Analysis of vma-2 encoding the 57-kDa polypeptide and comparison to vma-1

In partially purified preparations of the vacuolar ATPase from Neurospora crassa, the two most prominent components are polypeptides of Mr = 70,000 and 60,000. We previously reported the isolation of the gene vma-1, which encodes the Mr = 70,000 polypeptide, and presented evidence that the polypeptide contains the site of ATP hydrolysis (Bowman, E. J., Tenney, K., and Bowman, B. J. (1988) J. Biol. Chem. 263, 13994-14001). We now report the isolation of a gene (designated vma-2), that encodes the Mr = 60,000 polypeptide. Analysis of the DNA sequence shows that the polypeptide has 513 amino acids and a molecular mass of 56,808 daltons (and will thus be referred to as the 57-kDa polypeptide). It is fairly rich in polar amino acids and has no apparent membrane-spanning domains. The vma-2 gene contains five short introns (55-71 bases), all clustered in the 5' end of the coding region. The gene maps to the right arm of linkage group II, near 5 S RNA gene 3. Thus, it is unlinked to vma-1 and to other known ATPase genes in N. crassa. The 57-kDa polypeptide shows 25% amino acid sequence identity with the vma-1 gene product. It shows essentially the same degree of similarity (25-28%) to both the alpha and beta subunits of F0F1 ATPases. Analysis of specific regions of the 57-kDa polypeptide, however, suggests it may have a function like that of the alpha subunit in F0F1 ATPases. The data indicate that all four types of ATPase polypeptides have evolved from a common ancestor and that the vacuolar-type ATPases have a structure surprisingly similar to that of the F0F1 ATPases.     

Genes expressed during conidiation in Neurospora crassa: molecular characterization of con-13

Asexual development in Neurospora crassa proceeds through a series of discrete morphological stages that culminate in the production of dormant spores called conidia. Changes in the pattern of gene expression parallel the morphological transformations associated with conidiation. As a prerequisite to the analysis of developmental gene expression in N. crassa, several genes of unknown function that are preferentially expressed during conidiation were isolated [Berlin and Yanofsky, Mol. Cell. Biol. 5 (1985) 849-855]. The molecular structure and nucleotide sequence of one of these genes, designated con-13, is presented. The con-13 gene specifies a relatively rare 1.35-kb message which is first detected about 8 h following the induction of conidiation. Sequence analysis of both cDNA and genomic clones indicates that the con-13 gene consists of three exons divided by two small introns. It encodes a polypeptide of 340 amino acid residues (37.1 kDa). The Con-13 protein is weakly acidic and hydrophilic. A comparison of the regions upstream from the con-8, con-10, and con-13 genes revealed several short sequence motifs which may be important in developmental gene regulation.