Vegetative incompatibility in filamentous fungi: het genes begin to talk.

Somatic or vegetative incompatibility is widespread in filamentous fungi. It prevents the coexistence of genetically different nuclei within a common cytoplasm. Cloning the het genes that control this process has been achieved in several species. This has provided essential information on the function of the genes in the biology of fungi and has also led to the formulation of models that may explain similar phenomena in other organisms.

Nonintegrative transformation in the filamentous fungus Podospora anserina: stabilization of a linear vector by the chromosomal ends of Tetrahymena thermophila.

The effect of the chromosomal ends of Tetrahymena thermophila on the stability of linear transforming molecules in the filamentous fungus Podospora anserina was tested. A derivative of an integrative vector for this fungus has been constructed, so that after linearization, the ends of the plasmid are the telomeric sequences of T. thermophila. After transformation, this linear molecule was maintained as an extrachromosomal plasmid with no integrated copies in about 50% of the transformants. Under selective conditions, there was approximately one linear molecule per 5 to 10 nuclei, and these extrachromosomal molecules were rapidly lost under nonselective conditions. The circular plasmid carrying an inverted repeat of T. thermophila telomeres could be linearized and processed in vivo.

Vegetative incompatibility in filamentous fungi: Podospora and Neurospora provide some clues.

In filamentous fungi, vegetative cell fusion between genotypically distinct individuals leads to a cell-death reaction known as vegetative or heterokaryon incompatibility. Genes involved in this reaction have been characterised molecularly. We can now begin to get a better understanding of the mechanism and the biological significance of this intriguing phenomenon.

A single amino acid difference is sufficient to elicit vegetative incompatibility in the fungus Podospora anserina.

Vegetative incompatibility is known to limit heterokaryosis in filamentous fungi. It results from genetic differences between incompatible strains at specific loci. The proteins encoded by the two incompatible alleles het-s and het-S of the fungus Podospora anserina differ from each other by 14 amino acids. Two approaches have been used to identify how many and which of these differences are necessary to elicit incompatibility. Twelve alleles of the het-s locus of wild-type isolates of P. anserina and of the related species Podospora comata have been sequenced to determine the extent of the variability of genes controlling s and S specificities. Expression of hybrid het-s/het-S genes and site-specific mutagenesis revealed that the specificities of het-s and het-S are under the control of a limited number of amino acid differences. The results show that vegetative incompatibility between s and S strains can be attributed to a single amino acid difference in the proteins encoded by the het-s locus.

A mutation in an HSP90 gene affects the sexual cycle and suppresses vegetative incompatibility in the fungus Podospora anserina.

Vegetative incompatibility is widespread in fungi but its molecular mechanism and biological function are still poorly understood. A way to study vegetative incompatibility is to investigate the function of genes whose mutations suppress this phenomenon. In Podospora anserina, these genes are known as mod genes. In addition to suppressing vegetative incompatibility, mod mutations cause some developmental defects. This suggests that the molecular mechanisms of vegetative incompatibility and development pathway are interconnected. The mod-E1 mutation was isolated as a suppressor of the developmental defects of the mod-D2 strain. We show here that mod-E1 also partially suppresses vegetative incompatibility, strengthening the link between development and vegetative incompatibility. mod-E1 is the first suppressor of vegetative incompatibility characterized at the molecular level. It encodes a member of the Hsp90 family, suggesting that development and vegetative incompatibility use common steps of a signal transduction pathway. The involvement of mod-E in the sexual cycle has also been further investigated.

MOD-D, a Galpha subunit of the fungus Podospora anserina, is involved in both regulation of development and vegetative incompatibility.

Cell death via vegetative incompatibility is widespread in fungi but molecular mechanism and biological function of the process are poorly understood. One way to investigate this phenomenon was to study genes named mod that modified incompatibility reaction. In this study, we cloned the mod-D gene that encodes a Galpha protein. The mod-D mutant strains present developmental defects. Previously, we showed that the mod-E gene encodes an HSP90. The mod-E1 mutation suppresses both vegetative incompatibility and developmental defects due to the mod-D mutation. Moreover, we isolated the PaAC gene, which encodes an adenylate cyclase, as a partial suppressor of the mod-D1 mutation. Our previous results showed that the molecular mechanisms involved in vegetative incompatibility and developmental pathways are connected, suggesting that vegetative incompatibility may result from disorders in some developmental steps. Our new result corroborates the involvement of mod genes in signal transduction pathways. As expected, we showed that an increase in the cAMP level is able to suppress the defects in vegetative growth due to the mod-D1 mutation. However, cAMP increase has no influence on the suppressor effect of the mod-D1 mutation on vegetative incompatibility, suggesting that this suppressor effect is independent of the cAMP pathway.

Regulation of gene expression during the vegetative incompatibility reaction in Podospora anserina. Characterization of three induced genes.

Vegetative incompatibility in fungi limits the formation of viable heterokaryons. It results from the coexpression of incompatible genes in the heterokaryotic cells and leads to a cell death reaction. In Podospora anserina, a modification of gene expression takes place during this reaction, including a strong decrease of total RNA synthesis and the appearance of a new set of proteins. Using in vitro translation of mRNA and separation of protein products by two-dimensional gel electrophoresis, we have shown that the mRNA content of cells is qualitatively modified during the progress of the incompatibility reaction. Thus, gene expression during vegetative incompatibility is regulated, at least in part, by variation of the mRNA content of specific genes. A subtractive cDNA library enriched in sequences preferentially expressed during incompatibility was constructed. This library was used to identify genomic loci corresponding to genes whose mRNA is induced during incompatibility. Three such genes were characterized and named idi genes for genes induced during incompatibility. Their expression profiles suggest that they may be involved in different steps of the incompatibility reaction. The putative IDI proteins encoded by these genes are small proteins with signal peptides. IDI-2 protein is a cysteine-rich protein. IDI-2 and IDI-3 proteins display some similarity in a tryptophan-rich region.

The mod-A suppressor of nonallelic heterokaryon incompatibility in Podospora anserina encodes a proline-rich polypeptide involved in female organ formation.

Vegetative incompatibility in fungi results from the control of heterokaryon formation by the genes present at het loci. Coexpression of antagonistic het genes in the same hyphae leads to a lethal process. In Podospora anserina, self-incompatible strains containing nonallelic incompatible genes in the same nucleus are inviable as the result of a growth arrest and a lytic process. Mutations in suppressor genes (mod genes) can restore the viability. These mod mutations also interfere with developmental processes, which suggests common steps between the incompatibility reaction and cellular differentiation. The mod-A locus, responsible for growth arrest in the self-incompatible strains, is also involved in the control of the development of female organs. The mod-A gene was isolated. An open reading frame 687 amino acids long was identified. The MOD-A-encoded polypeptide is rich in proline residues, which are clustered in a domain containing a motif that displays similarity to SH3-binding motifs, which are known to be involved in protein-protein interactions. Construction of a strain deleted for mod-A confirmed that the product of this gene involved in differentiation is a key regulator of growth arrest associated with vegetative incompatibility.

Mutational analysis of the [Het-s] prion analog of Podospora anserina. A short N-terminal peptide allows prion propagation.

The het-s locus is one of nine known het (heterokaryon incompatibility) loci of the fungus Podospora anserina. This locus exists as two wild-type alleles, het-s and het-S, which encode 289 amino acid proteins differing at 13 amino acid positions. The het-s and het-S alleles are incompatible as their coexpression in the same cytoplasm causes a characteristic cell death reaction. We have proposed that the HET-s protein is a prion analog. Strains of the het-s genotype exist in two phenotypic states, the neutral [Het-s*] and the active [Het-s] phenotype. The [Het-s] phenotype is infectious and is transmitted to [Het-s*] strains through cytoplasmic contact. het-s and het-S were associated in a single haploid nucleus to generate a self-incompatible strain that displays a restricted and abnormal growth. In the present article we report the molecular characterization of a collection of mutants that restore the ability of this self-incompatible strain to grow. We also describe the functional analysis of a series of deletion constructs and site-directed mutants. Together, these analyses define positions critical for reactivity and allele specificity. We show that a 112-amino-acid-long N-terminal peptide of HET-s retains [Het-s] activity. Moreover, expression of a mutant het-s allele truncated at position 26 is sufficient to allow propagation of the [Het-s] prion analog.

The ura5 gene of the filamentous fungus Podospora anserina: nucleotide sequence and expression in transformed strains.

We have sequenced the ura5 gene of the filamentous fungus Podospora anserina. The deduced sequence for the orotidylic acid pyrophosphorylase (OMPppase) has been compared with the Escherichia coli enzyme which is the only known sequence for this enzyme. This comparison shows extensive blocks of homology. The expression of the ura5 gene has been studied in a ura5 mutant which has been transformed by a recombinant plasmid carrying the ura5 gene. We observed that strains carrying integrated multicopies of the transforming vector exhibit higher specific activity for OMPppase than wild type (wt). By recombination we have constructed a strain in which the level of this enzyme is 32 times higher than in the wt strain.

Non-homologous integration of transforming vectors in the fungus Podospora anserina: sequences of junctions at the integration sites.

Transformation of the ura5-6 mutant strain of Podospora anserina with a recombinant vector carrying the ura5+ gene often results in the integration of the transforming plasmid by non-homologous recombination outside of the genomic ura5 locus. To investigate the mechanism of such integration, we rescued the integrated plasmid from three transformants. In two cases, the rescued plasmid was highly altered compared with the original transforming vector. We cloned the junctions between plasmidic DNA and genomic DNA of the transformants and determined their nucleotide sequences. It was found that there was little homology between plasmidic and genomic DNA sequences. Moreover, in all cases deletions of plasmid sequences at the integration site had occurred. These rearrangements can be explained by the formation of multimeric plasmids prior to integration.

An additional copy of the adenylate cyclase-encoding gene relieves developmental defects produced by a mutation in a vegetative incompatibility-controlling gene in Podospora anserina.

To identify cellular functions involved in vegetative incompatibility in filamentous fungi, we have initiated the cloning of Podospora anserina (Pa) mod genes. These genes interfere with the lethal reaction triggered by interaction between incompatible het genes. A gene (Pa AC) has been cloned by complementation of developmental defects caused by a mutation in the mod-D gene. This gene encodes a protein of 2145 amino acids (aa)that exhibits strong similarities with many adenylate cyclases (AC). About 65% aa identity has been found between the sequence of the polypeptide encoded by this Pa AC gene and the AC of Neurospora crassa. The organization of peptidic domains in the polypeptide encoded by Pa AC is closely related to that of Saccharomyces cerevisiae CYR1. Restriction-fragment-length polymorphism (RFLP) and genetic analysis have shown that Pa AC and mod-D are distinct genes.

A gene responsible for vegetative incompatibility in the fungus Podospora anserina encodes a protein with a GTP-binding motif and G beta homologous domain.

The het-e-1 gene of the fungus Podospora anserina is responsible for vegetative incompatibility through specific interactions with different alleles of the unlinked gene, het-c. Coexpression of two incompatible genes triggers a cell death reaction that prevents heterokaryon formation. The het-e1 allele has been cloned to get information on the function of the locus. It encodes a putative 1356-amino-acid polypeptide that displays two sequence motifs that have not yet been reported to be present on a single polypeptide. They are a GTP-binding domain and a repeated region that shares similarity with that of the beta-transducin. Contrary to other members of the beta-transducin family, sequence conservation between the repeated units is very strong and the number of repeats is different in wild-type het-e alleles.

Characterization of a gene from the filamentous fungus Podospora anserina encoding an aspartyl protease induced upon carbon starvation.

In an attempt to characterize proteases associated with vegetative incompatibility, a Podospora anserina gene (papA) encoding an aspartyl protease (podosporapepsin) was cloned using a heterologous probe. The deduced papA coding region was 1278 nucleotides long, interrupted by a single 71bp intron. The corresponding amino acid sequence presented a high degree of similarity to other aspartyl proteases. Sequence analysis and proteolytic activity measurement suggested that the podosporapepsin could be intracellular rather than secreted. The papA gene was expressed under carbon starvation, but not under nitrogen starvation conditions. Its disruption led to a slight decrease in the growth rate of the mutant strain when bovine serum albumin was the sole carbon source in the medium. Disruption or overexpression of papA gene had no obvious consequence on vegetative incompatibility. Transcription of papA induced by carbon starvation was strongly reduced in the presence of a suppressor of vegetative incompatibility. This result suggests a relationship between adaptation for starvation and vegetative incompatibility.

Cloning gene ura5 for the orotidylic acid pyrophosphorylase of the filamentous fungus Podospora anserina: transformation of protoplasts.

From a genomic library of the filamentous fungus Podospora anserina, we have cloned a 4.9-kb fragment which complements an Escherichia coli mutant strain deficient for orotidylic acid pyrophosphorylase (pyrE gene). The recombinant plasmid pPAura5 also transforms to prototrophy a mutant strain of P. anserina carrying a mutation in the ura5 gene and lacking OMPppase activity.

c-erb-A mRNA content and triiodothyronine nuclear receptor binding capacity in rat liver according to vitamin A status.

Vitamin A is required for normal growth and development and synergistically acts with thyroid hormones in these processes. Effects of retinol dietary intake (0, 5, 50 U retinol/g food) on the triiodothyronine (T3) nuclear receptor were examined in rat liver. Properties of this receptor have been investigated by an in vitro binding method. The amount of c-erb-A mRNA has been deduced by reverse transcription and amplification methods (PCR). Results show that both retinol deficiency and excess leads to a reduced amount of c-erb-A mRNA and to a decreased T3 binding capacity, suggesting that retinol, or retinoic acid which is its natural metabolite, contributes to the regulation of the T3 nuclear receptor properties.

Retinoic acid decreases retinoic acid and triiodothyronine nuclear receptor expression in the liver of hyperthyroidic rats.

Retinoic acid (RA) and triiodothyronine (T3) exert many of their actions by binding to specific nuclear receptors (respectively, RA receptor (RAR) and T3) receptor (TR) belonging to a 'superfamily' of receptors. Some heterologous regulation of these receptors has been shown, and in particular regulation of the maximum binding capacity of TR by either retinol or RA. Now, using hyperthyroidic rats as a model, the effect of RA on binding capacity and on the mRNA levels of TR and RAR was investigated. The results show that the benefit of vitamin A treatment for the hyperthyroidic state, which has been described for a long time, could be the result of a down-heteroregulation of TR by RA, the active metabolite of retinol.

Detection of circulating cells expressing chromogranin A gene transcripts in patients with lung neuroendocrine carcinoma.

High grade lung neuroendocrine carcinomas, like small and large cell neuroendocrine carcinomas, pose therapeutic problems. Most initially respond to chemotherapeutic agents, but early relapses are frequent and are resistant to the presently available treatments. Our study reports for the first time the development and evaluation of a test for detecting the presence of circulating tumour cells by measuring chromogranin A gene transcripts with reverse transcriptase-polymerase chain reaction (RT-PCR) and Southern blotting. The test is specific and sensitive (detection of 10 cancer cells/ml blood), and only minimally invasive. Positivity is statistically correlated to high grade neuroendocrine carcinomas and to a poor prognosis with a 3-fold higher lethal risk. The test now needs to be assessed for its usefulness as a tool in the initial staging procedures and follow-up by comparison with the recent immunoradiometric assay (RIA) for detection of chromogranin A in the serum.

Quantitative variation of a 60S ribosomal protein during growth of the fungus Podospora anserina.

During the growth phase, in the fungus Podospora anserina, a variation is observed in the composition of the ribosomal proteins. A protein of the 60S subunit which is absent in the ribosomes from 2 days old cultures becomes gradully more abundant as the culture time is prolonged.

Self-cloning in filamentous fungi: application to the construction of endothiapepsin overproducers in Cryphonectria parasitica.

The filamentous ascomycete fungus Cryphonectria parasitica naturally secretes endothiapepsin, an aspartic proteinase. It is cultured on a commercial scale as a source of the milk-clotting enzyme for cheese making. Our objective was to increase enzyme production of an industrial C. parasitica strain by a new technique of self-cloning; it consisted in the screening for transformants producing higher levels of endothiapepsin and having integrated only the DNA fragment of interest. Such genetically improved strains that are devoid of any foreign genes should be more readily acceptable for the production of food-grade enzymes.