Helmut Bertrand

An extrachromosomal plasmid is the etiological precursor of kalDNA insertion sequences in the mitochrondrial chromosome of senescent neurospora

In the kalilo strains of N. intermedia, senescence is initiated by insertion of a 9.0 kb foreign nucleotide sequence, kalDNA, into mitochondrial DNA. A 9.0 kb linear DNA plasmid that is structurally homologous to the mitochondrial kalDNA insertion sequences exists in high copy numbers in close association with the nuclei of presenescent and senescent kalilo cells, but is not present in cells of long-lived normal strains. The free kalilo plasmid has not been detected in mitochondria, suggesting that the element does not contain a mitochondrial origin of replication. Unexpectedly, the nuclear plasmid, like the mitochondrial insertion element, follows a strict pattern of maternal inheritance. We surmise that the extramitochondrial plasmid is the etiological precursor of the kalDNA insertion sequences that appear in the mtDNAs of senescent cell lines and conclude that the kalilo element induces senescence because it is a mutator of mitochondrial genes.

Unstable cytoplasms in Hawaiian strains of Neurospora intermedia

SummaryBy subjecting a large sample of natural isolates of N. intermedia to prolonged serial subculturing, 26 cytoplasmic variants have been identified. These variants show senescence, and finally death at some strain-specific point in the subculture series. All senescent strains are from the Hawaiian archipelago, where their incidence in natural populations is high. Senescent cultures can be female-fertile. Random ascospore analyses show that (i) senescence is maternally inherited; (ii) different stages of senescence give different proportions of senescent progeny; and (iii) ascospores from one cross show different degrees of senescence. These results indicate that senescence is determined by a genetic factor which re sides in the cytoplasm. This factor promotes instability of the cytoplasm, resulting initially in cytoplasmic heterogeneity shown by ascus and conidium sampling, and finally in death. Molecular studies to be published elsewhere show that the progression through senescence to death is correlated with the occurence of abnormalities in cytochrome content and mitochondrial DNA. The Hawaiian word kalilo (dying), symbolised [kal], is proposed to denote these cytoplasms.

RNA splicing in neurospora mitochondria. Characterization of new nuclear mutants with defects in splicing the mitochondrial large rrna

In Neurospora, the gene encoding the mitochondrial large (25S) ribosomal RNA contains an intervening sequence of 2.3 kb. We have identified eight nuclear mutants that are defective in splicing the mitochondrial large ribosomal RNA and that accumulate unspliced precursor RNA. These mutants identify three different nuclear genes required for the same mitochondrial RNA splicing reaction. Some of the mutants have unique phenotypic characteristics (for example, accumulation of an unusual intron RNA) that may provide insight into specific aspects of mitochondrial RNA splicing. Mutations at one locus, cyt4, are subject to partial phenotypic suppression by the electron-transport inhibitor antimycin. This phenomenon suggests that at least one component required for mitochondrial RNA splicing is regulated such that its synthesis or activity is increased in response to impairment of electron transport.

A circular mitochondrial plasmid incites hypovirulence in some strains of Cryphonectria parasitica.

Abstract In the chestnut-blight fungus Cryphonectria parasitica, a plasmid, pCRY1, occurs in the mitochondria of several strains isolated at various locations in the northeastern United States and Canada. The monomer of this plasmid is a 4.2-kb circular double-stranded DNA that has no detectable sequence homology with the 160–kb mitochondrial DNA of Ep155, a standard virulent laboratory strain of C. parasitica. The circular nature and oligomeric characteristics of the plasmid were deduced from the heterogeneous size of plasmid DNA molecules as detected by one- and two-dimensional gel-electrophoresis, the nature and alignment of restriction fragments, and the lack of detectable termini in the nucleotide sequence. The cytoplasmic location of the plasmid was deduced from its co-purification with mitochondria, uniparental (maternal) transmission in sexual crosses, dissociation from the nuclei of the donor strain during its horizontal transfer between vegetatively compatible strains through hyphal anastomoses, and mitochondrial codon usage (UGA=Try). The pCRY1 plasmid contains a long open reading frame that is transcribed and potentially encodes a unique 1214 amino-acid, B-family DNA polymerase similar to those encoded by the LaBelle and Fiji circular mitochondrial plasmids of Neurospora. In this subgroup of proteins, the DTD motif characteristic of B-family DNA polymerases is replaced by TTD. Amino-acid motifs related to those that are characteristic of the 3′→5′ exonuclease domains of B-family DNA polymerases have been located in the amino-terminal portion of the proteins. A comparison of isogenic plasmid-free and plasmid-containing cultures indicates that pCRY1 is an infectious agent that effects a reduction in the pathogenicity of some, but not all, strains of C. parasitica.

Nuclear cytochrome-deficient mutants of neurospora crassa: Isolation, characterization, and genetic mapping

SummaryWe have isolated twenty-six nuclear, singlegene cytochrome-deficient mutants of Neurospora crassa as an initial step toward the study of the structural components and regulatory mechanisms involved in the biogenesis of the mitochondrial cytochrome system. These mutants, together with two previously described mutants, cyt-1 and cyt-2, have been classified into six distinct groups on the basis of cytochrome phenotype: a) cytochrome aa3 deficiency (due to mutations affecting loci designated cya); b) cytochrome b deficiency (cyb-1 locus); c) cytochrome b deficiency with a partial deficiency of cytochrome aa3 (cyb-2 locus); d) deficiency of both cytochromes aa3 and b (cyt loci); e) deficiency of both cytochromes aa3 and c (cyt-2 locus); and f) partial deficiency of cytochromes aa3 and c (cyt-12 locus).Four of seven mutations affecting cya loci have been mapped and are located on linkage groups I, II, V, and VI. It is not yet known whether these genes code for structural components of cytochrome oxidase or have a regulatory function that affects synthesis or assembly of the enzyme. The cyb-1 and cyb-2 genes are located on linkage groups V and VI, respectively, and appear to code for regulatory elements that control the biogenesis of cytochromes b and aa3. The positions of the cyt mutations that cause a simultaneous deficiency of cytochromes aa3 and b are dispersed throughout the genome, except for two gene clusters on the left arm of linkage group I. Some of these mutants may be deficient in mitochondrial protein synthesis. Two mutations, cyt-2 and cyt-12, are located on linkage groups VI and II, respectively, and appear to affect genes that code for components of a regulatory system that controls the biogenesis of cytochromes aa3 and c.

Phosphate Starvation in Fungi Induces the Replacement of Phosphatidylcholine with the Phosphorus-Free Betaine Lipid Diacylglyceryl-N,N,N-Trimethylhomoserine

ABSTRACT Diacylglyceryl-N,N,N-trimethylhomoserine (DGTS) is a phosphorus-free betaine-lipid analog of phosphatidylcholine (PtdCho) synthesized by many soil bacteria, algae, and nonvascular plants. Synthesis of DGTS and other phosphorus-free lipids in bacteria occurs in response to phosphorus (P) deprivation and results in the replacement of phospholipids by nonphosphorous lipids. The genes encoding DGTS biosynthetic enzymes have previously been identified and characterized in bacteria and the alga Chlamydomonas reinhardtii. We now report that many fungal genomes, including those of plant and animal pathogens, encode the enzymatic machinery for DGTS biosynthesis, and that fungi synthesize DGTS during P limitation. This finding demonstrates that replacement of phospholipids by nonphosphorous lipids is a strategy used in divergent eukaryotic lineages for the conservation of P under P-limiting conditions. Mutants of Neurospora crassa were used to show that DGTS synthase encoded by the BTA1 gene is solely responsible for DGTS biosynthesis and is under the control of the fungal phosphorus deprivation regulon, mediated by the NUC-1/Pho4p transcription factor. Furthermore, we describe the rational reengineering of lipid metabolism in the yeast Saccharomyces cerevisiae, such that PtdCho is completely replaced by DGTS, and demonstrate that essential processes of membrane biogenesis and organelle assembly are functional and support growth in the engineered strain.

Dynamics of asexual transmission of a mitochondrial plasmid in Cryphonectria parasitica.

Abstract In the chestnut blight fungus Cryphonectria parasitica, as in most fungi, little is known about the efficiency of the asexual transmission of optional mitochondrial plasmids, vertically through conidia, and horizontally through hyphal anastomoses. In this paper, we show that pCRY1, a circular mitochondrial plasmid, is transmitted vertically with 100%-efficiency through conidia. Moreover, the plasmid is transmitted horizontally through hyphal contact from donor strains to vegetatively compatible and most incompatible strains. An allelic difference between the donor and recipient strain, at only one of the five nuclear incompatibility genes that were tested strongly inhibited, but did not absolutely prevent, the transfer of pCRY1 through hyphal fusions. In contrast, allelic differences in any one or several of the other four heterokaryon-compatibility loci suppressed the transmission of the plasmid only partially or not at all. The plasmid was also transmitted among incompatible strains by protoplast fusion without the concomitant transfer of mitochondrial DNA (mtDNA). A comparison of plasmid-bearing with plasmid-free isogenic strains revealed that pCRY1 significantly diminishes the pathogenic potency of some strains of the fungus, but does not affect the virulence of others. Collectively, the observations indicate that the introduction of deleterious mitochondrial genetic elements into natural populations may be a means for managing fungal pathogens.

The Cryphonectria parasitica mitochondrial rns gene: Plasmid-like elements, introns and homing endonucleases

The mt-rns gene of Cryphonectria parasitica is 9872bp long and includes two group I and two group II introns. An analysis of intronic protein-encoding sequences revealed that LAGLIDADG ORFs, which usually are associated with group I introns, were transferred at least twice into group II introns. A plasmid-like mitochondrial element (plME) that appears in high amounts in previously mutagen-induced mit1 and mit2 hypovirulent mutants of the Ep155 standard virulent strain of C. parasitica was found to be derived from a short region of the mt-rns gene, including the exon 1 and most of the first intron. The plME is a 4.2-kb circular, multimeric DNA and an autonomously-replicating mtDNA fragment. Although sexual transmission experiments indicate that the plME does not directly cause hypovirulence, its emergence is one manifestation of the many complex molecular and genetic events that appear to underlie this phenotype.

Transmissible mitochondrial hypovirulence in a natural population of Cryphonectria parasitica.

A cytoplasmically transmissible hypovirulence syndrome has been identified in virus-free strains of the chestnut blight fungus Cryphonectria parasitica isolated from healing cankers on American chestnut trees in southwestern Michigan. The syndrome is associated with symptoms of fungal senescence, including a progressive decline in the growth potential and abundance of conidia, and elevated levels of respiration through the cyanide-insensitive alternative oxidase pathway. Conidia from senescing mycelia exhibited varying degrees of senescence ranging from normal growth to death soon after germination. Cytoplasmic transmission of hypovirulence between mycelia occurred by hyphal contact and coincided with the transfer of a specific restriction fragment length polymorphism from the mitochondrial DNA (mtDNA) of the donor strains into the mtDNA of virulent recipients. The transmission of the senescence phenotype was observed not only among vegetatively compatible strains but also among incompatible strains. Hypovirulence was present in isolates from the same location with different nuclear genotypes as identified by DNA fingerprinting. This study confirms that mitochondrial hypovirulence can occur spontaneously and spread within a natural population of a phytopathogenic fungus.

Physical and genetic map of the mitochondrial genome of Cryphonectria parasitica Ep155

Abstract In the chestnut-blight fungus, Cryphonectria parasitica, a cytoplasmically transmissible (infectious) form of hypovirulence is associated with mitochondrial DNA (mtDNA) mutations that cause respiratory deficiencies. To facilitate the characterization of such mutations, a restriction map including the probable location of 13 genes was constructed for a relatively well-characterized virulent strain of the fungus, Ep155. The physical map is based on the order of all fragments generated by cleavage of the mtDNA by the PstI restriction endonuclease and includes some of the cleavage sites for HindIII, EcoRI, and XbaI. It was constructed from hybridization patterns of cloned mtDNA fragments with Southern blots of mtDNA digested with the four restriction enzymes. On this map, the probable locations of genes commonly found in the mitochondrial genomes of ascomycetes were determined by low-stringency hybridization of cloned Neurospora crassa mitochondrial gene probes to Southern blots of C. parasitica mtDNA. The data indicate that the mtDNA of strain Ep155 is a circular molecule of approximately 157 kbp and ranks among the largest mitochondrial chromosomes observed so far in fungi. The mtDNAs of 11 different C. parasitica isolates range in size from 135 to 157 kbp and in relatedness from 68 to 100 percent, as estimated from restriction-fragment polymorphisms. In addition to the typical mtDNA, the mitochondria of some isolates of the fungus contain double-stranded DNA plasmids consisting of nucleotide sequences not represented in the mtDNA of Ep155.