First Bacterial Endosymbionts Found in the Phylum Ascomycota

Fitzpatrick, Eileen Elizabeth

01 March 2013

Organisms belonging to the Kingdom Fungi are known to occupy a wide variety of ecological niches and are found globally in virtually all environments. Two members of the smallest of the fungal phylum, the Zygomycota, have also been found to harbor intercellular bacteria initially described as being from or closely related to organisms from the Genus Burkholderia. In this study two microaerophilic members of the species Verticilium from the phyla Ascomycota were characterized. Both appear to carry two bacterial endosymbionts. This is the first evidence of bacterial endosymbionts found within a member of the Ascomycota. Through the use of fluorescent stains, isolation of the intercellular bacteria, DNA analysis and fluorescent in situ hybridization (FISH) it appears that the newly isolated Verticilium sp. fungi contain not one but two bacterial endosymbionts from the family Proteobacteria. One putative symbiont is from the genus Bradyrhizobium, a member of the α-Proteobacteria, and one from the genus Burkholderia, a member of the β-Proteobacteria. This is the first evidence of a fungus containing not one, but two distinct endosymbionts from two separate bacterial families. Additionally the fungi were found to grow from spore across a large pH gradient (pH 1.2 to pH 13.5) and in conditions lacking given nutrient. They were tolerant of concentrations of Fe(II) up to 50mM and grew better with low oxygen levels (1.6%) than without.

Fungus-bacterium relationships

Endosymbiosis

Zygomycetes

Ascomycetes

Biology

Other Plant Sciences

A phytosociological study of Coprophilous ascomycete and Basidiomycete communities from Santaquin Canyon, Utah

Blauer, A. Clyde

01 August 1965

Numerous reports have been published on the taxonomy and distribution of the coprophilous Ascomycetes and Basidiomycetes. No known quantitative work has been done, however, on the succession and structure of the communities formed by these higher fungi. This research was undertaken to study those two phases of the ascomycete and basidiomycete communities which grow and fruit on cow dung collected from Santaquin Canyon, Utah.

Ascomycetes

Utah; Basidiomycetes

Utah

Life Sciences

Microbiology

Plant Sciences

A study of the Coprophilous Ascomycetes of Utah

Hanks, David L.

01 May 1963

Specimens of animal dung were collected from various areas of the state of Utah. These were cultured by placing a few small pieces in a culture dish over moistened sphagnum moss and filter paper. The cultures were observed periodically and specimens were studied as they matured upon the substratum. A total of eighty-four species representing three orders and fifteen genera are reported. Of these, nine species have not previously been described. Included is one species, Tripterospora erostrata, from the order Plectascales of the Series Plectomyceteae. Cited from the order Sphaeriales of the Series Pyrenomyceteae are forty-nine species as follow: Coniochaeta, two species; Delitschia, nine species; Hypocopra, two species; Pleophragmia, two unnamed species; Sordaria, thirteen species; and Zygospermella, one species. From the order Pezizles of the Series Discomyceteae are reported thirty-four species as follows: Ascobolus, five species, including one unnamed species; Ascophanus, thirteen species; Cheilymenia, four species; Peziza, three species; Lasiobols, two species, one unnamed species; and Saccobolus, five species, two of which are reported for the first time.

Coprophilous ascomycetes

Utah

Animal Sciences

Life Sciences

Microbiology

ROLE OF THE SEXUAL CYCLE IN DEVELOPMENT OF GENOTYPIC AND PHENOTYPIC DIVERSITY IN Gibberella zeae

Bec, Sladana

01 January 2011

Gibberella zeae (anamorph Fusarium graminearum) is a homothallic ascomycete pathogen that is responsible for causing Fusarium head blight (FHB) of wheat and small grains. In addition to causing a reduction in yield, harvested grain is frequently contaminated with trichothecene mycotoxins that are harmful for human and animal health. Use of wheat varieties with resistance to FHB is an important strategy to lower its impact. In order to produce varieties with durable resistance, we must understand the origin and degree of genetic diversity present in the pathogen population. In my research, I focused my efforts on an investigation of the role of mating and sexual development in the generation of genotypic and phenotypic variability in G. zeae. The goal of one part of my work was to develop new genetic markers that can be used to monitor out-crossing and genetic diversity in the population. I also optimized gene deletion protocols for G. zeae so that I could produce mutant and control strains to address my research hypothesis that MAT genes play a direct role in pathogenicity. Application of novel repetitive RFLP probes to a group of G. zeae isolates originating from and near Kentucky revealed a surprisingly high degree of diversity in these local populations. Diversity between locations was greater than that within locations, suggesting the relative importance of local inoculum sources. The probes were also useful as genetic markers for segregation analysis. I crossed two genetically closely related, and commonly used, laboratory strains of G. zeae and found that this resulted in transgressive segregation for both aggressiveness and toxigenicity. I showed that the very high and very low levels of aggressiveness and toxigenicity in transgressive segregants are heritable. I also showed that selfing produced a higher degree of diversity in these traits among the progeny than was observed among conidial progeny. This suggests the presence of epigenetic factors that impact pathogenicity. Sexual behavior in G. zeae is under the control of MATing type genes. I deleted the complete MAT1 locus, and the MAT1-1-1, and MAT1-2-1 genes separately. Deletion of each of the targeted sequences produced the expected shifts in fertility phenotype. The mat1KO strains became asexual, while mat1-1-1KO and mat1-2-1KO strains shifted to obligate heterothallism. Deletion of the MAT1-1-1 and MAT1-2-1 genes had a negative effect on aggressiveness and mycotoxin production in planta, but deletion of the complete MAT1 locus had no effect. The set of mutant and ectopic control strains that I generated will be a useful asset that will be made available to the research community.

Gibberella zeae

Fusarium Head Blight

MATing type genes

Ascomycetes

wheat

Plant Biology

Plant Pathology

Plant Sciences

Pendent Usnea (Lichens; Ascomycetes; Parmeliaceae) in Western Oregon : taxonomy; morphological characters; and geographical distribution

Pittam, Sherry K.

14 March 1995

Pendent Usnea species were collected in western Oregon and examined. Character states, such as cortex-medulla-axis ratio; fibril length; papilla diameter; branching patterns; and presence or absence of fibrils, papillae, soredia, isidia; plus chemistry, were recorded and analyzed by inspection for differences. Historical names were researched in the literature. A comparison was made between species concepts used in these accounts, with many conflicting concepts encountered. Selected morphological characters were examined by scanning electron microscope, or dissecting microscope, described, and illustrated. The characters reviewed included articulate fissures; isidia and soredia; cortex-medulla-axis ratio; papillae; and foveate pits. Species determinations were made for field collections. Names were found for all specimens inspected without introducing new names at this time. Eight pendent species were found in western Oregon; they are Usnea cavernosa, Usnea ceratina, Usnea fillpendula, Usnea hesperina subsp. liturata, Usnea inflata, Usnea leucosticta, Usnea longissima, and Usnea merrillii. A practical key to taxa with descriptions is provided and geographic distributions are recorded in tables and maps. / Graduation date: 1995

Lichens -- Oregon -- Classification

Ascomycetes -- Oregon -- Classification

Parmeliaceae -- Oregon -- Classification

Lichens -- Morphology

Lichens -- Geographical distribution

Study on fungal pellet morphology and its industrial applications

Ravula, Vamsi Krishna

January 2017

Mycelial pellet formation by filamentous fungi is one of the most researched topics in fungal biotechnology research. Pellets are generally formed as a result of a complex interaction process through the influence of many cultivation factors such as inoculum size, pH, dissolved oxygen level, agitation system, nucleating agents, additives, trace metals, CO2, temperature, reactor types, carbon substrate, rheology, culture modes, fermenter geometry, nitrogen and phosphate levels etc. Each factor has varying effects on the growth morphologies of different fungal species. Fungal growths in the form of pellets have several advantages and pose a potential solution to overcome the problems associated with the filamentous fungal growth in large scale industrial bioreactors. The aim of the present work was to study pellet formation of edible filamentous fungus Neurospora intermedia, focusing on the molecular aspects of the fungal pellets with special interest to investigate the role of cell signaling second messenger cyclic 3', 5’-adenosine mono- phosphate (cAMP). It was found that Neurospora intermedia stimulate cAMP in the pellet form than filamentous form. The industrial applications of fungal pellets for generating value added products were also studied and observed fermentation in individual and co fermented first and second-generation ethanol substrate, showed an ethanol yield maximum of 0.25 ± 0.05 g/g dry substrate. The growth of fungal pellets in presence of inhibitors (such as acetic acid, HMF and furfural) resulted in about 11% to 45% increase in ethanol production as compared to filamentous forms, at similar growth conditions in the liquid straw hydrolysate.

Filamentous fungi

Ascomycetes

Edible fungi

Pellet

Neurospora intermedia

Other Engineering and Technologies

Annan teknik

La RNase P mitochondriale chez Neurospora crassa

Minoiu, Ioana

12 1900

Résumé La Ribonucléase P (RNase P) est une enzyme principalement reconnue pour sa participation à la maturation en 5’des ARN de transfert (ARNt). Cependant, d’autres substrats sont reconnus par l’enzyme. En général, la RNase P est composée d’une sous-unité ARN (le P-ARN, codé par le gène rnpB) qui porte le centre actif de l’enzyme et d’une ou de plusieurs sous-unités protéiques (la P-protéine). Les P-ARN chez toutes les bactéries, la majorité des archéobactéries et dans le génome nucléaire de la plupart des eucaryotes, possèdent généralement une structure secondaire très conservée qui inclut le noyau (P1-P4); l’hélice P4 constitue le site catalytique de l’enzyme et l’hélice P1 apparie les extrémités du P-ARN en stabilisant sa structure globale. Les P-ARN mitochondriaux sont souvent moins conservés et difficiles à découvrir. Dans certains cas, les seules régions de structure primaire qui restent conservées sont celles qui définissent le P4 et le P1. Pour la détection des gènes rnpB, un outil de recherche bioinformatique, basé sur la séquence et le profil de structure secondaire, a été développé dans le laboratoire. Cet outil permet le dépistage de toutes les séquences eucaryotes (nucléaires et mitochondriales) du gène avec une très grande confiance (basée sur une valeur statistique, E-value). Chez les champignons, plusieurs ascomycètes encodent un gène rnpB dans leur génome mitochondrial y compris tous les membres du genre d’Aspergillus. Cependant, chez les espèces voisines, Neurospora crassa, Podospora anserina et Sordaria macrospora, une version mitochondriale de ce gène n’existe pas. Au lieu de cela, elles contiennent deux copies nucléaires du gène, légèrement différentes en taille et en contenu nucléotidique. Mon projet a été établi dans le but d’éclaircir l’évolution de la RNase P mitochondriale (mtRNase P) chez ces trois espèces voisines d’Aspergillus. En ce qui concerne les résultats, des modèles de structures secondaires pour les transcrits de ces gènes ont été construits en se basant sur la structure consensus universelle de la sous-unité ARN de la RNase P. Pour les trois espèces, par la comparaison de ces modèles, nous avons établi que les deux copies nucléaires du gène rnpB sont assez distinctes en séquence et en structure pour pouvoir y penser à une spécialisation de fonction de la RNase P. Chez N. crassa, les deux P-ARN sont modifiés probablement par une coiffe et les extrémités 5’, 3’ sont conformes à nos modèles, ayant un P1 allongé. Encore chez N. crassa, nous avons constaté que les deux copies sont transcrites au même niveau dans le cytoplasme et que la plus petite et la plus stable d’entre elles (Nc1) se retrouve dans l’extrait matriciel mitochondrial. Lors du suivi du P-ARN dans diverses sous-fractions provenant de la matrice mitochondriale soluble, Nc1 est associée avec l’activité de la RNase P. La caractérisation du complexe protéique, isolé à partir de la fraction active sur un gel non dénaturant, révèle qu’il contient au moins 87 protéines, 73 d’entre elles ayant déjà une localisation mitochondriale connue. Comme chez la levure, les protéines de ce complexe sont impliquées dans plusieurs fonctions cellulaires comme le processing de l’ADN/ARN, le métabolisme, dans la traduction et d’autres (par exemple : la protéolyse et le repliement des protéines, ainsi que la maintenance du génome mitochondrial). Pour trois protéines, leur fonction est non déterminée. / Abstract Ribonuclease P (RNase P) is an endonuclease that cleaves 5’- leader sequences from tRNA precursors and a few other small RNAs. In most cases, the enzyme is a ribonucleo-protein complex (ribozyme), containing an RNA subunit (P-RNA; encoded by the rnpB gene) that carries the active centre of the enzyme, plus one or more protein subunits. P-RNAs in Bacteria, Eukarya and Archaea have a highly conserved secondary structure including the core P1 and P4 helices. P4 forms the catalytic site of the ribozyme, and P1 pairs the RNA termini, stabilizing overall structure and protecting from nuclease degradation. For processing of mitochondrial (mt) tRNAs, certain eukaryotic species (e.g., Saccharomyces cerevisiae, Aspergillus nidulans) have separate mtDNA-encoded P-RNAs (of bacterial origin). Mt P-RNAs are often less conserved, and difficult to discover. To identify rnpB genes, we have developed a search tool based on sequence plus secondary structure profiles. It predicts all known eukaryotic (nuclear and organellar) rnpB genes with high confidence (based on E-values). In fungi, many ascomycetes encode a mitochondrial rnpB gene, including all members of Aspergillus. Yet, the closely related Neurospora crassa, Podospora anserina and Sordaria macrospora lack an mtDNA-encoded gene version. Instead, they contain two nuclear gene copies with slightly different sequences. My project aims to elucidate the evolution of mitochondrial RNase P in these three closely related species. We have established secondary structure models based on comparisons with the universal minimum consensus secondary structure for all nuclear gene mtP-RNAs copies in all three species. By comparison of these secondary structure models, we have established that the two nuclear copies of rnpB gene are quite distinct in sequence and structure, suggesting a specialization of function. In N. crassa, both P-RNAs are modified most likely by capping, and 5’- 3’ termini perfectly conform to P-RNA structure models that have an elongated P1 helical pairing. Furthermore, we find that the two nuclear copies of rnpB gene are present at about the same level in the cytoplasm, and that the shorter form of P-RNA (Nc1) translocates into the (soluble) mitochondrial matrix. When tracing P-RNA in different mitochondrial sub-fractions of a native gel, the presence of Nc1 and mitochondrial RNase P activity are associated. A proteomics characterization of a P-RNA complex isolated by native gel electrophoresis reveals that it contains at least 87 proteins, 73 of which are of known mitochondrial localization. Like in yeast, the complex contains proteins potentially involved in other DNA/RNA processing activities, but also in translation, in metabolism, and in protein folding. Only three proteins are of unknown function.

ribozyme

ribonucléoprotéine

ascomycètes

N. crassa

mtRNase P

processus mitochondriaux

maturation des précurseurs des ARNt

ribonucleoprotein

ascomycetes

mitochondrial processes

maturation of tRNA precursors

Charakteristika společenstva hub na opadu smrku ztepilého kultivací a analýzou T-RFLP / Characterization of fungal community in spruce (Picea abies) litter using cultivation and T-RFLP

Kolářová, Zuzana

January 2012

Fungi have a key role in the decomposition of coniferous litter and affect nutrient cycling in forest ecosystems. Therefore, great emphasis is placed on exploring the diversity of these organisms. The aim of this thesis was to describe fungal diversity in spruce litter and revealed temporal development of this community in a forest regenerating after bark beetle outbreak. Another objective was to compare sites with different length of bark beetle damage. The study area was located in the Bohemian Forest mountain range. Litter bags with spruce needles were placed on the forest soil and several samplings were performed in the course of three years. Diversity of fungi and changes in the fungal community were assessed by two methods: cultivation of needles on 2ř MEA and fingerprinting method T-RFLP. In total 71 fungal species were obtained from needles during a three-year succession by cultivation approach. Using T-RFLP 122 different fragments were generally recorded. The dominant species were Scleroconidioma sphagnicola, Thysanophora penicillioides, Hormonema dematiodes, Ceuthospora pinastri, species of genus Chalara, Trichoderma polysporum, Mycena galopus and unknown species Helotiales sp. 1. Primary saprotrophs occured in the community mainly in first 8 months and then were replaced by basidiomycetes....

Studies on the centromere-specific histone, CenH3, of Neurospora crassa and related ascomycetes

Phatale, Pallavi A.

10 December 2012

In eukaryotes, the defined loci on each chromosome, the centromeres, accomplish the critical task of correct cell division. In some organisms, centromeres are composed of a euchromatic central core region embedded in a stretch of heterochromatin and the inheritance and maintenance of centromeres are controlled by dynamic epigenetic phenomena. Although the size of centromeres differs between organisms, its organization, and the placement of euchromatic and heterochromatic regions is conserved from the fission yeast, Schizosaccharomyces pombe, to humans, Homo sapiens. However, relatively little is known about centromeres in the filamentous fungi from the Ascomycota, representing the largest group of fungi and fungal pathogens. Further, studies from humans, flies, yeast and plants have shown that the inheritance of centromeres is not strictly guided by centromeric DNA content, which is highly AT-rich, repetitive and constantly evolving. Therefore, it is difficult to align ans assemble the sequenced contigs of centromeric regions of higher eukaryotes, including most filamentous fungi. A genetic technique, tetrad (or octad) analysis has helped to map the centromeres of the filamentous fungus Neurospora crassa early on. The research presented in this dissertation used N. crassa as a model to focus on characterizing different features of centromeres with an emphasis on the centromere-specific histone H3 (CenH3) protein. Data included here represent the first study on centromere-specific proteins in Neurospora, and demonstrate that the central core of the centromeres are heterochromatic, showing enrichment of silent histone marks, which is in contrast to the centromere arrangement in fission yeast. The CenH3 protein, whose deposition on the genome licenses formation or maintenance of centromeres, shows highly divergent N-terminal regions and a conserved histone fold domain (HFD) in all eukaryotes. This bipartite nature of CenH3 is also observed in the Ascomycota, which provides an opportunity for functional complementation assays by replacing Neurospora CenH3 (NcCenH3) with CenH3 genes from other species within the Ascomycota. The results from this experimental approach provide good measures for (1) determining the specific regions of CenH3 required for the assembly of centromeres during meiotic and mitotic cell divisions and (2) analyzing the resistance to changes in the organization of centromeres in N. crassa. The genetic analysis showed that the divergent N-terminal region is essential for the proper assembly of centromeres, and that the conserved carboxy-terminus of CenH3 is important for the process of meiosis but not mitotic cell division. ChIP-seq analyses suggest that the observed loss of Podospora anserina CenH3 (PaCenH3- GFP) from certain N. crassa centromeres does not result in obvious phenotypic defects, e.g. diminished growth or evidence for aneuploidy. Further, the low enrichment of PaCenH3-GFP at certain centromeres is possibly predetermined during meiosis, which results in irreversible and progressive decreases in enrichment. It remains to be determined if this process is random as far as selection of centromeres is concerned. Together the results presented here suggest that during meiosis more stringent structural requirements for centromere assembly apply and that these are dependent on CenH3, and that depletion of CenH3 from centromeres does not critically affect mitosis in the asynchronously dividing nuclei of Neurospora hyphae. / Graduation date: 2013

histone

centromere

fungi

neurospora

heterochormatin

Neurospora crassa -- Molecular genetics

Histones

Heterochromatin

Centromere

La RNase P mitochondriale chez Neurospora crassa

Minoiu, Ioana

12 1900

Résumé La Ribonucléase P (RNase P) est une enzyme principalement reconnue pour sa participation à la maturation en 5’des ARN de transfert (ARNt). Cependant, d’autres substrats sont reconnus par l’enzyme. En général, la RNase P est composée d’une sous-unité ARN (le P-ARN, codé par le gène rnpB) qui porte le centre actif de l’enzyme et d’une ou de plusieurs sous-unités protéiques (la P-protéine). Les P-ARN chez toutes les bactéries, la majorité des archéobactéries et dans le génome nucléaire de la plupart des eucaryotes, possèdent généralement une structure secondaire très conservée qui inclut le noyau (P1-P4); l’hélice P4 constitue le site catalytique de l’enzyme et l’hélice P1 apparie les extrémités du P-ARN en stabilisant sa structure globale. Les P-ARN mitochondriaux sont souvent moins conservés et difficiles à découvrir. Dans certains cas, les seules régions de structure primaire qui restent conservées sont celles qui définissent le P4 et le P1. Pour la détection des gènes rnpB, un outil de recherche bioinformatique, basé sur la séquence et le profil de structure secondaire, a été développé dans le laboratoire. Cet outil permet le dépistage de toutes les séquences eucaryotes (nucléaires et mitochondriales) du gène avec une très grande confiance (basée sur une valeur statistique, E-value). Chez les champignons, plusieurs ascomycètes encodent un gène rnpB dans leur génome mitochondrial y compris tous les membres du genre d’Aspergillus. Cependant, chez les espèces voisines, Neurospora crassa, Podospora anserina et Sordaria macrospora, une version mitochondriale de ce gène n’existe pas. Au lieu de cela, elles contiennent deux copies nucléaires du gène, légèrement différentes en taille et en contenu nucléotidique. Mon projet a été établi dans le but d’éclaircir l’évolution de la RNase P mitochondriale (mtRNase P) chez ces trois espèces voisines d’Aspergillus. En ce qui concerne les résultats, des modèles de structures secondaires pour les transcrits de ces gènes ont été construits en se basant sur la structure consensus universelle de la sous-unité ARN de la RNase P. Pour les trois espèces, par la comparaison de ces modèles, nous avons établi que les deux copies nucléaires du gène rnpB sont assez distinctes en séquence et en structure pour pouvoir y penser à une spécialisation de fonction de la RNase P. Chez N. crassa, les deux P-ARN sont modifiés probablement par une coiffe et les extrémités 5’, 3’ sont conformes à nos modèles, ayant un P1 allongé. Encore chez N. crassa, nous avons constaté que les deux copies sont transcrites au même niveau dans le cytoplasme et que la plus petite et la plus stable d’entre elles (Nc1) se retrouve dans l’extrait matriciel mitochondrial. Lors du suivi du P-ARN dans diverses sous-fractions provenant de la matrice mitochondriale soluble, Nc1 est associée avec l’activité de la RNase P. La caractérisation du complexe protéique, isolé à partir de la fraction active sur un gel non dénaturant, révèle qu’il contient au moins 87 protéines, 73 d’entre elles ayant déjà une localisation mitochondriale connue. Comme chez la levure, les protéines de ce complexe sont impliquées dans plusieurs fonctions cellulaires comme le processing de l’ADN/ARN, le métabolisme, dans la traduction et d’autres (par exemple : la protéolyse et le repliement des protéines, ainsi que la maintenance du génome mitochondrial). Pour trois protéines, leur fonction est non déterminée. / Abstract Ribonuclease P (RNase P) is an endonuclease that cleaves 5’- leader sequences from tRNA precursors and a few other small RNAs. In most cases, the enzyme is a ribonucleo-protein complex (ribozyme), containing an RNA subunit (P-RNA; encoded by the rnpB gene) that carries the active centre of the enzyme, plus one or more protein subunits. P-RNAs in Bacteria, Eukarya and Archaea have a highly conserved secondary structure including the core P1 and P4 helices. P4 forms the catalytic site of the ribozyme, and P1 pairs the RNA termini, stabilizing overall structure and protecting from nuclease degradation. For processing of mitochondrial (mt) tRNAs, certain eukaryotic species (e.g., Saccharomyces cerevisiae, Aspergillus nidulans) have separate mtDNA-encoded P-RNAs (of bacterial origin). Mt P-RNAs are often less conserved, and difficult to discover. To identify rnpB genes, we have developed a search tool based on sequence plus secondary structure profiles. It predicts all known eukaryotic (nuclear and organellar) rnpB genes with high confidence (based on E-values). In fungi, many ascomycetes encode a mitochondrial rnpB gene, including all members of Aspergillus. Yet, the closely related Neurospora crassa, Podospora anserina and Sordaria macrospora lack an mtDNA-encoded gene version. Instead, they contain two nuclear gene copies with slightly different sequences. My project aims to elucidate the evolution of mitochondrial RNase P in these three closely related species. We have established secondary structure models based on comparisons with the universal minimum consensus secondary structure for all nuclear gene mtP-RNAs copies in all three species. By comparison of these secondary structure models, we have established that the two nuclear copies of rnpB gene are quite distinct in sequence and structure, suggesting a specialization of function. In N. crassa, both P-RNAs are modified most likely by capping, and 5’- 3’ termini perfectly conform to P-RNA structure models that have an elongated P1 helical pairing. Furthermore, we find that the two nuclear copies of rnpB gene are present at about the same level in the cytoplasm, and that the shorter form of P-RNA (Nc1) translocates into the (soluble) mitochondrial matrix. When tracing P-RNA in different mitochondrial sub-fractions of a native gel, the presence of Nc1 and mitochondrial RNase P activity are associated. A proteomics characterization of a P-RNA complex isolated by native gel electrophoresis reveals that it contains at least 87 proteins, 73 of which are of known mitochondrial localization. Like in yeast, the complex contains proteins potentially involved in other DNA/RNA processing activities, but also in translation, in metabolism, and in protein folding. Only three proteins are of unknown function.

ribozyme

ribonucléoprotéine

ascomycètes

N. crassa

mtRNase P

processus mitochondriaux

maturation des précurseurs des ARNt

ribonucleoprotein

ascomycetes

mitochondrial processes

maturation of tRNA precursors