Crassa DNA Research Articles

Endogenous Small RNA Mediates Meiotic Silencing of a Novel DNA Transposon.

Genome defense likely evolved to curtail the spread of transposable elements and invading viruses. A combination of effective defense mechanisms has been shown to limit colonization of the Neurospora crassa genome by transposable elements. A novel DNA transposon named Sly1-1 was discovered in the genome of the most widely used laboratory “wild-type” strain FGSC 2489 (OR74A). Meiotic silencing by unpaired DNA, also simply called meiotic silencing, prevents the expression of regions of the genome that are unpaired during karyogamy. This mechanism is posttranscriptional and is proposed to involve the production of small RNA, so-called masiRNAs, by proteins homologous to those involved in RNA interference−silencing pathways in animals, fungi, and plants. Here, we demonstrate production of small RNAs when Sly1-1 was unpaired in a cross between two wild-type strains. These small RNAs are dependent on SAD-1, an RNA-dependent RNA polymerase necessary for meiotic silencing. We present the first case of endogenously produced masiRNA from a novel N. crassa DNA transposable element.

Efficient gene targeting in ligase IV-deficient Monascus ruber M7 by perturbing the non-homologous end joining pathway

Inactivating the non-homologous end joining (NHEJ) pathway is a well established method to increase gene replacement frequency (GRF) in filamentous fungi because NHEJ is predominant for the repair of DNA double strand breaks (DSBs), while gene targeting is based on homologous recombination (HR). DNA ligase IV, a component of the NHEJ system, is strictly required for the NHEJ in Saccharomyces cerevisiae and Neurospora crassa. To enhance the GRF in Monascus ruber M7, we deleted the Mrlig4 gene encoding a homolog of N. crassa DNA ligase IV. The obtained mutant (MrΔlig4) showed no apparent defects in vegetative growth, colony phenotype, microscopic morphology, spore yield, and production of Monascus pigments and citrinin compared with the wild-type strain (M. ruber M7). Gene targeting of ku70 and triA genes revealed that GRF in the MrΔlig4 strain increased four-fold compared with that in the wild-type strain, reached 68 % and 85 %, respectively. Thus, the MrΔlig4 strain is a promising host for efficient genetic manipulation. In addition, the MrΔlig4 strain is more sensitive than M. ruber M7 to a DNA-damaging agent, methyl methanesulfonate.

MgLig4, a homolog of Neurospora crassa Mus-53 (DNA ligase IV), is involved in, but not essential for, non-homologous end-joining events in Magnaporthe grisea

In many eukaryotic organisms, the non-homologous end-joining (NHEJ) system is a major pathway for the repair of DNA double-strand breaks (DSBs). DNA ligase IV is a component of the NHEJ system and is strictly required for the NHEJ system in Saccharomyces cerevisiae and in Neurospora crassa. To investigate the functions of DNA Ligase IV in Magnaporthe grisea, we generated deletion mutants of MGLIG4, which encodes a homolog of N. crassa DNA Ligase IV. Mutants ( mglig4) showed no defects in asexual or sexual growth, and were fully pathogenic. Compared to the wild-type, mglig4 exhibited weak sensitivity to a DNA-damaging agent, camptothecin. In addition, the frequency of targeted-gene replacement was relatively elevated in mglig4, although this varied in a gene-dependent manner. Surprisingly, non-homologous integration of DNA was frequently observed in mglig4 transformants. Our results demonstrate that MgLig4 is involved in, but not essential for, the NHEJ system in M. grisea.

The involvement of photoregulated DNA methylation into a choice between sexual and asexual developmental pathways in Neurospora crassa.

The mechanism of the alternative choice by a fungal organism between the sexual and asexual developmental pathways remains unclear despite intense study of gene expression in ontogeny. A possibility to control the life cycle of Neurospora crassa by varying the cultivation condition makes this ascomycete fungus a convenient model for experimental analysis of ontogenetic processes. The development of mycelial cells to form sexual or asexual reproductive structures can be determined by depriving the organism of certain nutritive substrates. Carbon starvation leads to formation of asexual spores, conidia, whereas a lack of nitrogen induces the development of female reproductive structures, protoperithecia. In the latter case, the orientation of an organism to the sexual cycle is not absolute, and some conidia are formed, too [1]. The realization of the ontogenetic program in N. crassa also depends on illumination [2]. The DNA methylation is known to protect the genome against foreign genetic elements [3] and control some developmental processes [4, 5]. The N. crassa genome is mostly unmethylated [6]. Nevertheless, the 5-methylcytosine content in the N. crassa DNA has been shown to vary during the development from the germinating conidia to a mature vegetative mycelium [7]. The DNA methylation is also involved into the appearance, during meiosis, of the so-called RIP (repeat-induced point) mutations [8], as well as with “quelling,” i.e., a suppressed gene expression in vegetative development [9]. We obtained the data indicating a participation of DNA methylation in a choice between the sexual and asexual development of N. crassa. To reveal the role of methylation, an inhibitor (5-azacytidine (4-amino- 1- β - D -ribofuranoside-5-triazine-2[1H]-one)) was used, which makes the DNA molecule inaccessible to methyl transferases through substituting the cytosine residues. The conidia suspension of N. crassa (FGSC wt 3834) was evenly spread on the surface of a cellophane film (2 〈 10 5 spores per 100 cm 2 ); placed in a Petri dish with a modified Vogel agar medium [10] containing 1% sorbose, 0.1% glucose and 4 mM NH 4 Cl ; and cultivated for three days in the dark at 23 ° C. Then, the film with the mycelium was transferred to a fresh medium of the same composition, except for a complete absence of the nitrogen source. Before the transfer, 5-azacytidine had been added to this medium. After 24 h, some of the plates were irradiated with a 2-min pulse of blue light ( λ = 300‐500 nm, 1 W m —2 ), and the others were used as a dark control. All plates were incubated in the dark for another two days, when the number of protoperithecia on the plates was counted using a binocular microscope with a dim red light illumination. After two more days in dark, the conidia were harvested from the mycelium and plated to the Vogel agar medium to determine their yield.

Molecular cloning and expression in Saccharomyces cerevisiae and Neurospora crassa of the invertase gene from Neurospora crassa

A plasmid (named pCN2) carrying a 7.6 kb BamHI DNA insert was isolated from a Neurospora crassa genomic library raised in the yeast vector YRp7. Saccharomyces cerevisiae suco and N. crassa inv strains transformed with pNC2 were able to grow on sucrose-based media and expressed invertase activity. Saccharomyces cerevisiae suco (pNC2) expressed a product which immunoreacted with antibody raised against purified invertase from wild type N. crassa, although S. cerevisiae suc+ did not. The cloned DNA hybridized with a 7.6 kb DNA fragment from BamHI-restricted wild type N. crassa DNA. Plasmid pNC2 transformed N. crassa Inv- to Inv+ by integration either near to the endogenous inv locus (40% events) or at other genomic sites (60% events). It appears therefore that the cloned DNA piece encodes the N. crassa invertase enzyme. A 3.8 kb XhoI DNA fragment, derived from pNC2, inserted in YRp7, in both orientation, was able to express invertase activity in yeast, suggesting that it contains an intact invertase gene which is not expressed from a vector promoter.

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.

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.

The use of a nonradioactive probe in RFLP analysis of Neurospora crassa DNA

The use of a nonradioactive probe in RFLP analysis of Neurospora crassa DNA

Binding of a 30-kDa protein to the pyruvate kinase gene of Neurospora crassa

Extracts of a wild-type strain of Neurospora crassa, electrophoresed on SDS-polyacrylamide gels and electroblotted onto nitrocellulose sheets, were hybridized to an end-labelled pyruvate kinase (PK) gene fragment containing the 5' noncoding sequence and a large part of the coding region. A 30-kDa protein was found to bind strongly to the PK gene DNA, while binding weakly to plasmid pUC12 DNA and to total N. crassa DNA. Probing of blots with individual restriction fragments derived from the PK gene showed that the protein binding occurred primarily to the 5' noncoding region. Nonspecific DNA from pUC12, PK gene DNA from the recombinant plasmid pNP460 (pUC12 containing a 1.8-kilobase EcoRI insert of the PK gene DNA), along with a 0.7-kilobase EcoRI-AccI restriction fragment containing the 5' flanking region, were used in filter-binding experiments to analyze the kinetics of binding. Formation of protein-DNA complexes was demonstrated by monitoring the electrophoretic mobility of this fragment on nondenaturing gels.

Molecular cloning and analysis of the regulation of cys-14+, a structural gene of the sulfur regulatory circuit of Neurospora crassa.

The cys-14+ gene encodes sulfate permease II, which is primarily expressed in mycelia. cys-14+ is one of a set of sulfur-related structural genes under the control of cys-3+ and scon+, the regulatory genes of the sulfur control circuit. We have cloned cys-14+ from a cosmid library of Neurospora crassa DNA. A restriction fragment length polymorphism analysis showed that this clone maps to the region of chromosome IV corresponding to the cys-14+ locus. Northern blot analyses were used to examine the regulated expression of the cys-14+ gene. In the wild type, a 3-kilobase cys-14+ transcript was highly expressed under sulfur-derepressing conditions but completely absent during sulfur repression. A cys-3 mutant, which cannot synthesize any of the sulfur-controlled enzymes, including sulfate permease II, did not possess any cys-14+ transcript under either condition. A cys-3 temperature-sensitive revertant completely lacked any cys-14+ mRNA at the conditional temperature but expressed the cys-14+ transcript upon derepression at the permissive temperature. Mutation of a second sulfur regulatory gene, scon(c), causes the expression of sulfur-related enzymes in a constitutive fashion; the scon(c) mutant showed a corresponding constitutive expression of cys-14+ mRNA, such that it was present even in cells subjected to sulfur repression conditions. These results show that the cys-14+ gene is regulated through the modulation of message content by the cys-3+ and scon(c) control genes in response to the sulfur levels of the cells.

Molecular cloning and analysis of the regulation of cys-14+, a structural gene of the sulfur regulatory circuit of Neurospora crassa.

The cys-14+ gene encodes sulfate permease II, which is primarily expressed in mycelia. cys-14+ is one of a set of sulfur-related structural genes under the control of cys-3+ and scon+, the regulatory genes of the sulfur control circuit. We have cloned cys-14+ from a cosmid library of Neurospora crassa DNA. A restriction fragment length polymorphism analysis showed that this clone maps to the region of chromosome IV corresponding to the cys-14+ locus. Northern blot analyses were used to examine the regulated expression of the cys-14+ gene. In the wild type, a 3-kilobase cys-14+ transcript was highly expressed under sulfur-derepressing conditions but completely absent during sulfur repression. A cys-3 mutant, which cannot synthesize any of the sulfur-controlled enzymes, including sulfate permease II, did not possess any cys-14+ transcript under either condition. A cys-3 temperature-sensitive revertant completely lacked any cys-14+ mRNA at the conditional temperature but expressed the cys-14+ transcript upon derepression at the permissive temperature. Mutation of a second sulfur regulatory gene, scon(c), causes the expression of sulfur-related enzymes in a constitutive fashion; the scon(c) mutant showed a corresponding constitutive expression of cys-14+ mRNA, such that it was present even in cells subjected to sulfur repression conditions. These results show that the cys-14+ gene is regulated through the modulation of message content by the cys-3+ and scon(c) control genes in response to the sulfur levels of the cells.

Molecular cloning and analysis of the regulation of nit-3, the structural gene for nitrate reductase in Neurospora crassa.

The nit-3 gene of Neurospora crassa encodes the enzyme nitrate reductase and is regulated by nitrogen catabolite repression and by specific induction with nitrate. The nit-3 gene was isolated from a cosmid-based genomic library by dual selection for benomyl resistance and for the ability to complement a nit-3 mutant strain using the sibling-selection procedure. The nit-3 gene was subcloned as a 3.8-kilobase DNA fragment from a cosmid that carried an approximately 40-kilobase N. crassa DNA insert. A restriction fragment length polymorphism analysis revealed that the cloned segment displayed tight linkage to two linkage-group-4 markers that flank the genomic location of nit-3. RNA gel blot analyses of RNA from wild-type and various mutant strains were carried out to examine the molecular mechanism for regulation of nit-3 gene expression. The nit-3 gene was transcribed to give a large mRNA of approximately 3.4 kilobases, the expected size to encode nitrate reductase. The nit-3 gene was only expressed in wild-type cells subject to simultaneous nitrogen derepression and nitrate induction. A mutant of nit-2, the major nitrogen regulatory gene of Neurospora, did not have detectable levels of nit-3 gene transcripts under the exact conditions in which these transcripts were highly expressed in wild type. Similarly, a mutant of nit-4, which defines a minor positive-acting nitrogen control gene, failed to express detectable levels of the nit-3 transcript. Nitrate reductase gene expression was partially resistant to nitrogen repression in a mutant of the nmr gene, which appears to be a regulatory gene with a direct role in nitrogen catabolite repression. Results are presented that suggest that the enzyme glutamine synthetase does not serve any regulatory role in controlling nitrate reductase gene expression.

A portable signal causing faithful DNA methylation de novo in Neurospora crassa.

Methylation of cytosine residues in eukaryotic DNA is common, but poorly understood. Typically several percent of the cytosines are methylated; however, it is unclear what governs which sequences eventually become modified. Neurospora crassa DNA containing the "zeta-eta" (zeta-eta) region, which is a region of unusually heavy methylation, was tested for its ability to direct DNA methylation de novo. DNA stripped of its methylation by propagation in Escherichia coli was reintroduced into Neurospora crassa by transformation. The zeta-eta region reproducibly became "properly" methylated whether inserted at its native chromosomal position or at ectopic sites. Adjacent Neurospora and bacterial sequences in the transforming DNA rarely became methylated. A model is presented that accounts for position-independent faithful methylation as observed in the zeta-eta region, as well as position-dependent methylation, as occasionally observed, especially with sequences not native to Neurospora.

Characterization of nit-2, the major nitrogen regulatory gene of Neurospora crassa.

The nit-2 gene is the major nitrogen-regulatory gene of Neurospora crassa, and under conditions of nitrogen limitations, it turns on the expression of various unlinked structural genes which specify nitrogen-catabolic enzymes. The nit-2 gene was subcloned as a 6-kilobase (kb) DNA fragment from a cosmid that carried approximately a 40-kb N. crassa DNA insert. The nit-2 gene was localized in a DNA segment of approximately 3.5 kb and was shown to correspond to a unique DNA sequence located on linkage group 1. Several N. crassa nit-2 transformants were characterized and were found to possess significantly different levels of the regulated enzyme nitrate reductase. Northern blot analysis of RNA from various strains was carried out to determine whether the nit-2 gene was expressed constitutively or was itself subject to regulation. The results revealed that the nit-2 gene is transcribed to give a single large mRNA of approximately 3.5 kb. Expression of the nit-2 gene is regulated such that its transcript is present at a substantially higher level in cells which are limited for nitrogen than in cells growing under nitrogen-repressed conditions. However, the nit-2 gene is not controlled by autogenous regulation. The nit-2 gene was transcribed only at a low level in nmr-1 and in gln-1b, under both nitrogen-repressed and derepressed conditions, suggesting that these unlinked loci may exert a positive regulatory effect on nit-2.

Characterization of nit-2, the major nitrogen regulatory gene of Neurospora crassa.

The nit-2 gene is the major nitrogen-regulatory gene of Neurospora crassa, and under conditions of nitrogen limitations, it turns on the expression of various unlinked structural genes which specify nitrogen-catabolic enzymes. The nit-2 gene was subcloned as a 6-kilobase (kb) DNA fragment from a cosmid that carried approximately a 40-kb N. crassa DNA insert. The nit-2 gene was localized in a DNA segment of approximately 3.5 kb and was shown to correspond to a unique DNA sequence located on linkage group 1. Several N. crassa nit-2 transformants were characterized and were found to possess significantly different levels of the regulated enzyme nitrate reductase. Northern blot analysis of RNA from various strains was carried out to determine whether the nit-2 gene was expressed constitutively or was itself subject to regulation. The results revealed that the nit-2 gene is transcribed to give a single large mRNA of approximately 3.5 kb. Expression of the nit-2 gene is regulated such that its transcript is present at a substantially higher level in cells which are limited for nitrogen than in cells growing under nitrogen-repressed conditions. However, the nit-2 gene is not controlled by autogenous regulation. The nit-2 gene was transcribed only at a low level in nmr-1 and in gln-1b, under both nitrogen-repressed and derepressed conditions, suggesting that these unlinked loci may exert a positive regulatory effect on nit-2.

Cloning and preliminary characterization of a molybdenum cofactor gene of Neurospora crassa

A Neurospora crassa library, constructed in a derivative of the plasmid pBR322 (pRK9), was used to transform two E. coli ch1D molybdenum cofactor mutants (ch1D, ch1D::Mu). Subsequently, one transformant from each of three independent transformation experiments was restriction mapped. All three transformants had an identical N. crassa DNA insert (4.2 kb). Southern Blot analysis with one of the plasmids (pMoCo, 1:4) showed hybridization to a single band of N. crassa genomic DNA. When pMoCo plasmid (1:4) was used to transform various E. coli nitrate reductase mutants (ch1A, ch1B, ch1C, ch1D, ch1E, ch1G and ch1M), the pMoCo plasmid was capable of restoring E. coli nitrate reductase activity to only the ch1D mutant. In vitro reconstitution experiments using wild-type, ch1D and ch1D; pMoCo cell-free extracts as a source of molybdenum cofactor (MoCo) were performed with the N. crassa MoCo mutants nit-1, nit-7 and nit-8. MoCo from wild-type E. coli cell-free extracts was capable of reconstituting NADPH : nitrate reductase activity to all three N. crassa mutants. MoCo from ch1D; pMoCo cell-free extracts was capable of reconstituting more NADPH : nitrate reductase activity to the N. crassa mutants than cell-free extracts from the original ch1D mutant.

Transformation of Aspergillus nidulans by the orotidine-5′-phosphate decarboxylase gene of Neurospora crassa

Relief of an auxotrophic requirement for uridine in Aspergillus nidulans strain G191 has been achieved by transformation with a segment of Neurospora crassa DNA containing the corresponding gene coding for orotidine-5′-phosphate decarboxylase. The mitotic stability of such transformants suggests that the DNA has integrated into the genome. Southern hybridisation analysis of DNA isolated from transformants revealed the presence of pBR322 sequences which have integrated into the host genome along with the N. crassa DNA.

Cloning of the trp-1 gene from neurospora crassa by complementation of a trpC mutation in Escherichia coli.

Studies with a hybrid plasmid containing 4.0 kilobase pairs of Neurospora crassa DNA cloned into plasmid pBR322 indicated that the plasmid restored to prototrophy a trpC mutant of Escherichia coli which lacked phosphoribosyl anthranilate isomerase but not a trpC mutant which lacked indole glycerol phosphate synthetase, that the relevant transcription was initiated at a promoter within the N. crassa DNA, and that the phosphoribosyl anthranilate isomerase could be specified by a subcloned segment of the original DNA.

Highly conserved GC-rich palindromic DNA sequences flank tRNA genes in Neurospora crassa mitochondria

In sequencing a 2200 bp region of the Neurospora crassa mitochondrial DNA encoding the 3′ end of the large rRNA gene and a cluster of six tRNA genes, we have found that the tRNA genes are flanked by highly conserved GC-rich palindromic DNA sequences. An 18 bp long core sequence, 5′-CC CTGCAG TA CTGCAG GG-3′, containing two closely spaced Pst I sites, is common to all these palindromic sequences. Each of the eight Pst I sites mapped in the 2200 bp region consists of two closely spaced Pst I sites; thus this 2200 bp long segment actually contains 16 Pst I sites. Between 5–10% of the N. crassa DNA may consist of these GC-rich palindromic sequences that include the 18 base long core sequence. The same core sequence is present within both the 5′ and 3′ side of the intervening sequence of the large rRNA gene, close to, but not at, the intron-exon boundaries. We discuss probable roles for these sequences in N. crassa mitochondrial function, including their role as signals either in the synthesis or processing (or both) of RNA in the mitochondria.

Identification and characterization of recombinant plasmids carrying the complete qa gene cluster from Neurospora crassa including the qa-1+ regulatory gene.

The early reactions in the catabolism of quinic acid in Neurospora crassa are controlled by at least four genes which are clustered on linkage group VII. Three of the loci (qa-2, qa-4, and qa-3) encode enzymes that convert quinic acid to protocatechuic acid. The fourth gene (qa-1) encodes a positive regulatory protein which, in the presence of quinic acid, leads to the de novo synthesis of the other proteins in the qa cluster. This communication describes a series of recombinant plasmids that span 36.5 kilobases of linkage group VII and contain the coding sequences for qa-2, qa-4, qa-3, and the qa-1 regulatory protein. The plasmids were obtained by partial digestion of wild-type N. crassa DNA with EcoRI and ligation into the cosmid cloning vehicle pHC79. Two independently derived plasmids (pMSK331 and pMSK335), each containing 36.5-kilobase inserts, were shown by transformation back into N. crassa to contain the entire qa gene cluster. A preliminary physical organization of the gene cluster is presented. An improved procedure for the transformation of N. crassa with plasmid DNA is also described.