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.     

New findings of Neurospora in Europe and comparisons of diversity in temperate climates on continental scales

The life cycles of the conidiating species of Neurospora are adapted to respond to fire, which is reflected in their natural history. Neurospora is found commonly on burned vegetation from the tropic and subtropical regions around the world and through the temperate regions of western North America. In temperate Europe it was unknown whether Neurospora would be as common as it is in North America because it has been reported only occasionally. In 2003 and 2004 a multinational effort surveyed wildfire sites in southern Europe. Neurospora was found commonly from southern Portugal and Spain (37 degrees N) to Switzerland (46 degrees N). Species collected included N. crassa, N. discreta, N. sitophila and N. tetrasperma. The species distribution and spatial dynamics of Neurospora populations showed both similarities and differences when compared between temperate Europe and western North America, both regions of similar latitude, climate and vegetation. For example the predominant species in western North America, N. discreta phylogenetic species 4B, is common but not predominant in Europe, whereas species rare in western North America, N. crassa NcB and N. sitophila, are much more common in Europe. The meiotic drive element Spore killer was also common in European populations of N. sitophila and at a higher proportion than anywhere else in the world. The methods by which organisms spread and adapt to new environments are fundamental ecosystem properties, yet they are little understood. The differences in regional diversity, reported here, can form the basis of testable hypotheses. Questions of phylogeography and adaptations can be addressed specifically by studying Neurospora in nature.     

A relationship between carotenoid accumulation and the distribution of species of the fungus Neurospora in Spain

The ascomycete fungus Neurospora is present in many parts of the world, in particular in tropical and subtropical areas, where it is found growing on recently burned vegetation. We have sampled the Neurospora population across Spain. The sampling sites were located in the region of Galicia (northwestern corner of the Iberian peninsula), the province of Cáceres, the city of Seville, and the two major islands of the Canary Islands archipelago (Tenerife and Gran Canaria, west coast of Africa). The sites covered a latitude interval between 27.88° and 42.74°. We have identified wild-type strains of N. discreta, N. tetrasperma, N. crassa, and N. sitophila and the frequency of each species varied from site to site. It has been shown that after exposure to light Neurospora accumulates the orange carotenoid neurosporaxanthin, presumably for protection from UV radiation. We have found that each Neurospora species accumulates a different amount of carotenoids after exposure to light, but these differences did not correlate with the expression of the carotenogenic genes al-1 or al-2. The accumulation of carotenoids in Neurospora shows a correlation with latitude, as Neurospora strains isolated from lower latitudes accumulate more carotenoids than strains isolated from higher latitudes. Since regions of low latitude receive high UV irradiation we propose that the increased carotenoid accumulation may protect Neurospora from high UV exposure. In support of this hypothesis, we have found that N. crassa, the species that accumulates more carotenoids, is more resistant to UV radiation than N. discreta or N. tetrasperma. The photoprotection provided by carotenoids and the capability to accumulate different amounts of carotenoids may be responsible, at least in part, for the distribution of Neurospora species that we have observed across a range of latitudes.     

Species-Specific and Mating Type-Specific DNA Regions Adjacent to Mating Type Idiomorphs in the Genus Neurospora

Mating type idiomorphs control mating and subsequent sexual development in Neurospora crassa and were previously shown to be well conserved in other Neurospora species. The centromere-proximal flanks of the A and a idiomorphs, but not the distal flanks from representative heterothallic, pseudohomothallic, and homothallic Neurospora species contain apparent species-specific and/or mating type-specific sequences adjacent to the well-conserved idiomorphs. The variable flank is bordered by regions that are highly homologous in all species. The sequence of ~1 kb immediately flanking the conserved idiomorphs of each species was determined. Sequence identity between species ranged from 20% (essentially unrelated) to >90%. By contrast, the mt-A1 gene shows 88-98% identity. Sequence and hybridization data also show that the centromere-proximal flanks are very different between the two mating types for N. intermedia, N. discreta, and N. tetrasperma, but not for N. sitophila and N. crassa. The data suggest a close evolutionary relationship between several of the species; this is supported by phylogenetic analysis of their respective mt-A1 genes. The origin of the variable regions adjacent to the evolutionarily conserved mating type idiomorphs is unknown.     

Evidence for the Differentiation of Wild-Type Alleles in Different Species of Neurospora

Wild-type alleles at the peak locus of Neurospora have been transferred by backcrossing from N. sitophila and N. tetrasperma to N. crassa. In the genomic background of N. crassa the different wild-type alleles show strikingly different dominance relations with Pk-4, a dominant peak mutation in N. crassa.     

Neurospora species in bakeries

S. YASSIN AND A. WHEALS. 1992. Neurospora species may occur as spoilage organisms in bakeries and bakery products. A survey of two bakeries over a 4 month period produced 315 individually isolated strains which were characterized with respect to six features: conidial colour, protoperitheciality, mating type and percentage dark-coloured (fertile) ascospores in crosses with type specimens of Neurospora crassa, N. sitophila and N. intermedia. We concluded that (i) N: crassa of both mating types was by far the most abundant but N. sitophila and N. intermedia were also represented; (ii) conidial colour was not a good species criterion; (iii) the percentage of fertile ascospores produced in crosses with several type specimens provided a reliable and simple species indicator; (iv) identification of individuals based on these six characteristics suggested that a large number of genetically different organisms were present in the collection; and (v) bakery infection was not due to endemic contamination in the bakery or in raw materials but from repeated external infection, perhaps on contaminated returned goods.     

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.     

Control of mating type heterokaryon incompatibility by the tol gene in Neurospora crassa and N. tetrasperma.

The mating-type of Neurospora crassa (A and a) have a dual function: A and a individuals are required for sexual reproduction, but only strains of the same mating type will form a stable vegetative heterokaryon. Neurospora tetrasperma, in contrast, is a naturally occurring A+a heterokaryon. It was shown previously that the mating-type genes of both species are functionally the same and are not responsible for this difference in heterokaryon incompatibility. This suggests that a separate genetic system determines the heterokaryon incompatibility function of mating type. The mutant tolerant (tol) in N. crassa, unlinked to mating type, acts as a specific suppressor of A+a heterokaryon incompatibility. In the present study, the wild-type alleles at the tol locus were introgressed reciprocally, from N. crassa into N. tetrasperma and from N. tetrasperma into N. crassa, to investigate the action of these alleles in the A+a heterokaryon incompatibility systems of these species. The wild-type allele from N. tetrasperma (tolT) acts as a recessive suppressor of A+a heterokaryon incompatibility in N. crassa. Furthermore, the wild-type allele from N. crassa (tolC) causes A and a to become heterokaryon incompatible in N. tetrasperma, while having no effect on the sexual reproduction. Therefore, the tol gene plays a major role in determining the heterokaryon compatibility of mating type in these species: tolC is an active allele that causes incompatibility and tolT an inactive allele that suppresses incompatibility by its inactivity.     

Signal for DNA methylation associated with tandem duplication in Neurospora crassa.

Most cytosine residues are subject to methylation in the zeta-eta (zeta-eta) region of Neurospora crassa. The region consists of a tandem direct duplication of a 0.8-kilobase-pair element including a 5S rRNA gene. The repeated elements have diverged about 15% by the occurrence of numerous CG to TA mutations, which probably resulted from deamination of methylated cytosines. Most but not all common laboratory strains of N. crassa have methylated duplicated DNA at the zeta-eta locus. However, many strains of N. crassa and strains of N. tetrasperma, N. sitophila, and N. intermedia have one instead of two copies of the homologous DNA and it is not methylated. A cross of strains differing at the zeta-eta locus produced progeny which all had duplicated, methylated, or unique, unmethylated DNA, like the parental strains. We conclude that a signal causing unprecedented heavy DNA methylation is present in the zeta-eta region.     

Ancestral polymorphism and linkage disequilibrium at the het-6 region in pseudohomothallic Neurospora tetrasperma

In species of Neurospora, non-self recognition is mediated by at least 11 heterokaryon (het) incompatibility loci. Previously, we identified ancient allelic variation at het-c in pseudohomothallic N. tetrasperma, which confirmed outcrossing in this species. Here, we report distinct ancestral alleles at het-6 and un-24, two closely linked genes with het incompatibility function in N. crassa. The pattern of variation at het-6 and un-24 in N. tetrasperma is similar to that observed for N. crassa, where two ancestral allele specificities exist for each locus, Oak Ridge (het-6(OR), un-24(OR)) and Panama (het-6(PA), un-24(PA)). Only het-6(OR)/un-24(OR) and het-6(PA)/un-24(PA) allele combinations have been observed. The absence of recombinant haplotypes (e.g., het-6(OR)/un-24(PA)) appears to derive from an ancestral chromosomal rearrangement that limits recombination. Allelic variation at het-6 and un-24 in N. tetrasperma provides further evidence of outcrossing in this predominantly selfing species and indicates that selection maintains ancient allelic diversity at het loci.     

Structural variations and optional introns in the mitochondrial DNAs of Neurospora strains isolated from nature

Mitochondrial DNAs from ten wild-type Neurospora crassa, Neurospora intermedia, and Neurospora sitophila strains collected from different geographical areas were screened for structural variations by restriction enzyme analysis. The different mtDNAs show much greater structural diversity, both within and among species, than had been apparent from previous studies of mtDNA from laboratory N. crassa strains. The mtDNAs range in size from 60 to 73 kb, and both the smallest and largest mtDNAs are found in N. crassa strains. In addition, four strains contain intramitochondrial plasmid DNAs that do not hybridize with the standard mtDNA. All of the mtDNA species have a basically similar organization. A 25-kb region that includes the rRNA genes and most tRNA genes shows very strong conservation of restriction sites in all strains. The 2.3-kb intron found in the large rRNA gene in standard N. crassa mtDNAs is present in all strains examined, including N. intermedia and N. sitophila strains. The size differences between the different mtDNAs are due to insertions or deletions that occur outside of the rRNA-tRNA region. Restriction enzyme and heteroduplex mapping suggest that four of these insertions are optional introns in the gene encoding cytochrome oxidase subunit I. Mitochondrial DNAs from different wild-type strains contain zero, one, three, or four of these introns.     

Blocked recombination along the mating-type chromosomes of Neurospora tetrasperma involves both structural heterozygosity and autosomal genes

The Neurospora tetrasperma mating-type chromosomes have been shown to be structurally heterozygous by reciprocal introgression of these chromosomes between N. tetrasperma and N. crassa. This structural heterozygosity correlates with both a previously described recombination block and cytologically visible unpaired chromosomes at pachytene. Genes on the autosomes are also implicated in blocking recombination.     

Neurospora crassa ribosomal DNA: sequence of internal transcribed spacer and comparison with N. intermedia and N. sitophila

Using [32P]DNA probes from a clone containing 17S, 5.8S and 26S rRNA of Neurospora crassa, the remainder of the repeat unit (RU) for ribosomal DNA (rDNA) has been cloned. Combining restriction analysis of the cloned DNA and restriction digests of genomic DNA, the RU was found to be 8.7 kb. The nucleotide sequence was determined for the internal transcribed spacer (ITS) regions one and two, for 5.8S rRNA and for portions of 17S and 26S rRNAs immediately flanking the ITS regions, and compared to the corresponding region of Saccharomyces carlsbergensis. In addition, a comparative restriction analysis of two other Neurospora species was performed using twelve restriction endonucleases. Genomic DNA blots of rDNA from N. intermedia and N. sitophila revealed rDNA RUs of 8.4 kb. The majority of differences in restriction patterns were confined to sequences outside the mature rRNA regions. However, one SmaI recognition site was found in 26S rRNA of N. crassa and N. sitophila but not in N. intermedia.     

脉孢菌lca-1基因调控无性产孢及类胡萝卜素的合成

类胡萝卜素是很多生物细胞内重要的抗氧化剂,具有保护细胞免受紫外线伤害的功能。粗糙脉孢菌是少数几个类胡萝卜素合成基因比较清楚的真菌之一,为了深入了解该菌类胡萝卜素合成调控机制,通过对粗糙脉孢菌基因突变体库中6,087株突变体进行筛选,新发现6个基因敲除突变体营养生长正常,但类胡萝卜素的合成降低,其中表型较好的1个突变体,其无性产孢量与类胡萝卜素合成量均明显降低。鉴定发现该突变体所缺失的基因编码一种依赖ATP的染色体重建复合体的ATP酶链ISW1,将该基因命名为lca-1。进一步测定发现lca-1基因的突变导     

Expression of Meiotic Drive Elements Spore Killer-2 and Spore Killer-3 in Asci of Neurospora Tetrasperma

It was shown previously that when a chromosomal Spore killer factor is heterozygous in Neurospora species with eight-spored asci, the four sensitive ascospores in each ascus die and the four survivors are all killers. Sk-2K and Sk-3K are nonrecombining haplotypes that segregate with the centromere of linkage group III. No killing occurs when either one of these killers is homozygous, but each is sensitive to killing by the other in crosses of Sk-2K x Sk-3K. In the present study, Sk-2K and Sk-3K were transferred by recurrent backcrosses from the eight-spored species Neurospora crassa into Neurospora tetrasperma, a pseudohomothallic species which normally makes asci with four large spores, each heterokaryotic for mating type and for any other centromere-linked genes that are heterozygous in the cross. The action of Sk-2K and Sk-3K in N. tetrasperma is that predicted from their behavior in eight-spored species. A sensitive nucleus is protected from killing if it is enclosed in the same ascospore with a killer nucleus. Crosses of Sk-2K x Sk-2S, Sk-3K x Sk-3S, and Sk-sK x Sk-3K all produce four-spored asci that are wild type in appearance, with the ascospores heterokaryotic and viable. The Eight-spore gene E, which shows variable penetrance, was used to obtain N. tetrasperma asci in which two to eight spores are small and homokaryotic. When killer and sensitive alleles are segregating in the presence of E, only those ascospores that contain a killer allele survive. Half of the small ascospores are killed. In crosses of Sk-2K x Sk-3K (with E heterozygous), effectively all small ascospores are killed. The ability of N. tetrasperma to carry killer elements in cryptic condition suggests a possible role for Spore killers in the origin of pseudohomothallism, with adoption of the four-spored mode restoring ascospore viability of crosses in which killing would otherwise occur.     

Neurospora in temperate forests of western North America

The fungal genus Neurospora has a distinguished history as a laboratory model in genetics and biochemistry. The most recent milestone in this history has been the sequencing of the genome of the best known species, N. crassa. The hope and promise of a complete genome sequence is a full understanding of the biology of the organism. Full understanding cannot be achieved, however, in the absence of fundamental knowledge of natural history. We report that species of Neurospora, heretofore thought to occur mainly in moist tropical and subtropical regions, are common primary colonizers of trees and shrubs killed by forest fires in western North America, in regions that are often cold and dry. Surveys in 36 forest-fire sites from New Mexico to Alaska yielded more than 500 cultures, 95% of which were the rarely collected N. discreta. Initial characterization of genotypes both within a site and on a single tree showed diversity consistent with sexual reproduction of N. discreta. These discoveries fill important gaps in knowledge of the distribution of members of the genus on both large and small spatial scales and provide the framework for future studies in new regions and microhabitats. The overall result is that population biology and genetics now can be combined, placing the genus Neurospora in a unique position to expand its role in experimental biology as a useful model organism for ecology, population genetics and evolution.