Natural Variation of the Circadian Clock in Neurospora

Most living organisms on earth experience daily and expected changes from the rotation of the earth. For an organism, the ability to predict and prepare for incoming stresses or resources is a very important skill for survival. This cellular process of measuring daily time of the day is collectively called the circadian clock. Because of its fundamental role in survival in nature, there is a great interest in studying the natural variation of the circadian clock. However, characterizing the genetic and molecular mechanisms underlying natural variation of circadian clocks remains a challenging task. In this chapter, we will summarize the progress in studying natural variation of the circadian clock in the successful eukaryotic model Neurospora, which led to discovering many design principles of the molecular mechanisms of the eukaryotic circadian clock. Despite the success of the system in revealing the molecular mechanisms of the circadian clock, Neurospora has not been utilized to extensively study natural variation. We will review the challenges that hindered the natural variation studies in Neurospora, and how they were overcome. We will also review the advantages of Neurospora for natural variation studies. Since Neurospora is the model fungal species for circadian study, it represents over 5 million species of fungi on earth. These fungi play important roles in ecosystems on earth, and as such Neurospora could serve as an important model for understanding the ecological role of natural variation in fungal circadian clocks.

RANDOM-FRAGMENT HYBRIDIZATION ANALYSIS OF EVOLUTION IN THE GENUS NEUROSPORA: THE STATUS OF FOUR-SPORED STRAINS

A random-fragment hybridization method employing nuclear DNA has been developed to explore phylogenetic relationships in the genus Neurospora. Four cloned fragments and repetitive rDNA sequences were examined for restriction-fragment polymorphisms among 14 strains representing four species. The findings demonstrate that variation among randomly selected nuclear fragments can be employed to group related taxa with a higher degree of resolution than has been obtained with other DNA hybridization methods, isozyme electrophoresis, or restriction analysis of repetitive DNA. Based on our analysis of cloned fragments, we conclude that four-spored, secondarily-homothallic strains collected worldwide represent a monophyletic group. Trees constructed on the basis of restriction-fragment cataloging and coarse-structure restriction-site maps are for the most part consistent with the present mating-based species concept. We are encouraged that this method will provide an additional important experimental tool for evolutionary studies.

VARIATION IN RIBOSOMAL DNA AMONG BIOLOGICAL SPECIES OF ARMILLARIA, A GENUS OF ROOT-INFECTING FUNGI

Armillaria is a genus of root-infecting fungi composed of several biological species in North America and Europe. To examine relatedness among biological species, ribosomal DNA (rDNA) from one isolate was cloned and rDNAs from 30 isolates were mapped for eight restriction enzymes. The positions of the large (26S) and small (18S) rRNA cistrons were found by Northern hybridizations of total cellular RNA with rDNA subclones and by alignment of maps with conserved restriction sites present in rRNA genes of other fungi. Nine restriction-site and two length polymorphisms were observed. Eight North American (Roman numerals) and five European (species epithets) biological species could be placed in six classes with respect to rDNA maps (rDNA class 1: I and A. ostoyae; class 2: II; class 3: A. borealis; class 4: V, IX, and X; class 5: III, VII, A. lutea, and A. cepistipes; and class 6: VI and A. mellea). Most, but not all, polymorphisms were in intergenic regions.

mtDNA recombination in a natural population

Variation in mtDNA has been used extensively to draw inferences in phylogenetics and population biology. In the majority of eukaryotes investigated, transmission of mtDNA is uniparental and clonal, with genotypic diversity arising from mutation alone. In other eukaryotes, the transmission of mtDNA is biparental or primarily uniparental with the possibility of "leakage" from the minority parent. In these cases, heteroplasmy carries the potential for recombination between mtDNAs of different descent. In fungi, such mtDNA recombination has long been documented but only in laboratory experiments and only under conditions in which heteroplasmy is ensured. Despite this experimental evidence, mtDNA recombination has not been to our knowledge documented in a natural population. Because evidence from natural populations is prerequisite to understanding the evolutionary impact of mtDNA recombination, we investigated the possibility of mtDNA recombination in an organism with the demonstrated potential for heteroplasmy in laboratory matings. Using nucleotide sequence data, we report here that the genotypic structure of mtDNA in a natural population of the basidiomycete fungus Armillaria gallica is inconsistent with purely clonal mtDNA evolution and is fully consistent with mtDNA recombination.

Mitochondrial inheritance in Aspergillus nidulans

Mitochondrial chloramphenicol and oligomycin resistance mutations were used to investigate mitochondrial inheritance in A. nidulans. Mitochondrial RFLPs could not be used to distinguish between paternal and maternal mitochondria because none were detected in the 54 isolates investigated. Several thousand ascospores from each of 111 hybrid cleistothecia from 21 different crosses between 7 heterokaryon incompatible isolates were tested for biparental inheritance. All mitochondrial inheritance was strictly uniparental. Not one instance of paternal inheritance of mitochondria was observed. The implications of our results for the theory that uniparental inheritance evolved to avoid cytoplasmic conflict are discussed. Possible explanations for the maintenance of strict uniparental inheritance of mitochondria in an inbreeding homothallic organism are suggested. The chloramphenicol resistance marker was inherited preferentially to the oligomycin resistance marker probably due to the inhibited energy production of mitochondria with the oligomycin resistance mutation. The maternal parent was determined for 93 hybrid cleistothecia from 17 crosses between 7 different strains. Contrary to previous reports A. nidulans strains functioned as both maternal and paternal parent in most crosses.

Wide Distribution of Mitochondrial Genome Rearrangements in Wild Strains of the Cultivated Basidiomycete Agrocybe aegerita

We used restriction fragment length polymorphisms to examine mitochondrial genome rearrangements in 36 wild strains of the cultivated basidiomycete Agrocybe aegerita, collected from widely distributed locations in Europe. We identified two polymorphic regions within the mitochondrial DNA which varied independently: one carrying the Cox II coding sequence and the other carrying the Cox I, ATP6, and ATP8 coding sequences. Two types of mutations were responsible for the restriction fragment length polymorphisms that we observed and, accordingly, were involved in the A. aegerita mitochondrial genome evolution: (i) point mutations, which resulted in strain-specific mitochondrial markers, and (ii) length mutations due to genome rearrangements, such as deletions, insertions, or duplications. Within each polymorphic region, the length differences defined only two mitochondrial types, suggesting that these length mutations were not randomly generated but resulted from a precise rearrangement mechanism. For each of the two polymorphic regions, the two molecular types were distributed among the 36 strains without obvious correlation with their geographic origin. On the basis of these two polymorphisms, it is possible to define four mitochondrial haplotypes. The four mitochondrial haplotypes could be the result of intermolecular recombination between allelic forms present in the population long enough to reach linkage equilibrium. All of the 36 dikaryotic strains contained only a single mitochondrial type, confirming the previously described mitochondrial sorting out after cytoplasmic mixing in basidiomycetes.

Distribution of seven homology groups of mitochondrial plasmids in Neurospora: evidence for widespread mobility between species in nature

A survey of mitochondrial DNAs from over 225 Neurospora and related fungal isolates from around the world uncovered three new homology groups of mitochondrial plasmids, two divergent subgroups of the Fiji plasmid family, and extended previous data about plasmid distribution patterns. Newly-discovered circular plasmids, Java and MB1, and the linear Moorea plasmids, were found in relatively-few isolates. A large proportion of isolates (51%) were found to have these or previously-discovered plasmids in the Varkud, kalilo, LaBelle, or Fiji families. Plasmids in most families were found in isolates worldwide and distributed nearly randomly with respect to species. As many as three types of plasmids were found in single isolates, and plasmids typically were found alone or in pairs in a random, independent pattern. The regional clustering of some plasmids was independent of species, providing a strong argument that horizontal transfer of plasmids occurs frequently in nature. Some plasmid families were much more diverse than others. The Fiji plasmids are a superfamily composed of distinct subgroups defined by degrees of cross-hybridization. Between some subgroups there were large regions of non-homology.

Mitochondrial DNAs of the fungus Armillaria ostoyae: restriction map and length variation

A restriction-enzyme-site map is presented for the 147-kb mtDNA of North American Armillaria ostoyae. The locations of five structural genes, atp6, atp8, coxI, coxIII, and cob, along with the location and orientation of the large and small ribosomal RNA genes, were determined through Southern hybridizations with cloned genes from other fungal mtDNAs. Based on this map, the variation in mtDNA suggested geographic structure at two different levels. On a large geographic scale, 17 mtDNA types from North America were distinct, with respect to both size and restriction maps, from three mtDNA types from Europe. At the local scale, identical mtDNA types were evident among several different genetic individuals located no more than 1 km apart at a site in Michigan. No mtDNA type occurred more than once among genetic individuals from different regions of North America, although the occurrence of similar mtDNAs in isolates from distant regions suggested that this may occur at a low frequency with large sample sizes. Among the North American mtDNA types, analysis of discrete length variants was inconsistent with the hypothesis that the mtDNA of A. ostoyae evolves as a clonal lineage in which each length mutation represents a unique event. The two remaining hypotheses, that similar mutational events have occurred independently and that genetic exchange and recombination occurs among mtDNAs in natural populations of this species, remain to be tested.

Transmission of mitochondrial DNA in Ustilago violacea

Mitochondrial DNA (mtDNA) restriction fragment length polymorphisms (RFLPs) were used as genetic markers for following mitochondrial transmission in the basidiomycete Ustilago violacea. Yeast-like cells of opposite mating types (a1 and a2) were mated on 2% water agar and were treated with alpha-tocopherol to induce formation of dikaryotic hyphae. Upon depletion of the alpha-tocopherol, the hyphae budded off haploid cells with parental nuclear genotypes. These cells were examined for mitochondrial RFLP phenotype. In progeny expressing the a1 mating type, mitochondria from either parent were observed equally frequently. In progeny with the a2 mating type, mitochondria were almost exclusively (94%) from the a2 parent.

Mitochondrial DNAs and plasmids as taxonomic characteristics in Trichoderma viride

Mitochondrial DNA (mtDNA) was purified from 12 isolates of the Trichoderma viride aggregate and found to be, on the average, 32.7 kb in size. Plasmids were present in the mtDNA preparations from 8 of 12 strains of T. viride examined. Plasmids in four of the strains produced ladderlike banding patterns on gels, and these plasmids were studied in detail. The ladderlike patterns were produced by single molecules that were supercoiled to various degrees. Plasmids from two of the strains do not have homology with the mtDNA but do have a limited amount of homology with each other. No phenotype could be associated with the presence of a plasmid. Restriction endonuclease digestion of the mtDNAs produced patterns in which the presence or absence of certain fragments correlated with the classification of the strains into T. viride group I or II. Phenetic cluster analysis and parsimony analysis of the fragment patterns produced groups that corresponded to T. viride groups I and II. The fragment patterns were very diverse, with nearly all strains having a unique pattern. However, two strains of T. viride group I from widely different geographical locations did have identical restriction patterns for all the enzymes used in this study. This result indicates that it may not be possible to use mtDNA restriction patterns alone to identify Trichoderma strains.

Independent transfer of mitochondrial plasmids in Neurospora crassa

In the ascomycete fungus Neurospora, the distribution of homologous mitochondrial plasmid DNAs in different species and among mitochondrial types of N. crassa suggests that these molecules have moved between lineages of clonally propagated mtDNA. Here we report direct evidence for independent inheritance of mitochondrial plasmids by sexual reproduction which may help explain the distribution of these molecules among mitochondrial lineages.

Evolution of mushroom mitochondrial DNA: Suillus and related genera

Mapping studies were performed with 18 cloned probes on mitochondrial DNA (mtDNA) from 15 species of Suillus and four species from three related genera of fleshy pore mushrooms (Boletaceae). Within Suillus, mtDNAs vary in size from 36 to 121 kb, differ in gene order by only one major rearrangement, and have diverged in nucleotide sequence within the large subunit ribosomal RNA gene region by up to 2.9%. Three additional gene orders exist in related genera. Two of the three can be transformed into the predominant Suillus order by either one or two rearrangements. The fourth requires two to three rearrangements to be converted to any of the others. The minimum estimates of nucleotide divergence within the large subunit ribosomal RNA gene region vary from 8.3% to 11% in comparisons between Suillus and these related species. Trees based on restriction-site and size differences within the mitochondrial ribosomal RNA genes were consistent with the hypothesized sequence of genome rearrangements and provide suggestive evidence for a major expansion of the mitochondrial genome within Suillus. Structural and sequence changes in mtDNA provided information about phylogenetic relationships within the Boletaceae.

Mitochondrial DNAs of Suillus: three fold size change in molecules that share a common gene order

We constructed restriction-site and gene maps for mitochondrial DNAs from seven isolates of five species of Suillus (Boletaceae, Basidiomycotina). Each mitochondrial genome exists as a single circular chromosome, ranging in size from 36 to 121 kb. Comparisons within species and between two closely related species revealed that insertions and deletions are the major form of genome change, whereas most restriction sites are conserved. Among more distantly related species, size and restriction-site differences were too great to allow precise alignments of maps, but small clusters of putatively homologous restriction sites were found. Two mitochondrial gene orders exist in the five species. These orders differ only by the relative positions of the genes for ATPase subunit 9 and the small ribosomal RNA and are interconvertible by a single transposition. One of the two gene arrangements is shared by four species whose mitochondrial DNAs span the entire size range of 36 to 121 kb. The conservation of gene order in molecules that vary over three-fold in size and share few restriction sites demonstrates a low frequency of rearrangements relative to insertions, deletions, and base substitutions.