Protoplasmic Incompatibility in PODOSPORA ANSERINA: a Possible Function for Incompatibility Genes

The suppression of protoplasmic incompatibility resulting from nonallelic gene interactions has been obtained by the coupled effect of mutations in the modA and modB genes (Bernet 1971). Due to their female sterility, modA modB strains provide an experimental tool to determine whether or not the mod and incompatibility loci are involved in a function other than protoplasmic incompatibility. Present results show that modA modB female sterility is a nonautonomous trait since heterokaryotic mycelia that include a modA modB nucleus and a female fertile nucleus (wild-type, modA or modB) produce modA modB protoperithecia, which are also formed by culture on medium supplemented with specific amino acids. Using modA modB strains, which are sterile at 32 degrees and fertile at 26 degrees , we have shown that the mod genes have no specific sequential timing. Indeed, the mod mutations may prevent the achievement of the female sexual cycle at any developmental stage from before early differentiation of protoperithecia until ascospore maturation. Employing different modA and modB mutations, we have shown that protoperithecia in modA modB cultures are generally distributed in female fertile rings; this result indicates that protoperithecia occur only in mycelial areas that have a restricted range of age at the time that modA modB thalli complete growth. Furthermore, nonsense mutations of incompatibility genes suppress the modA modB female fertile rings or restrict their width, suggesting that incompatibility loci, like the mod loci, are involved in protoperithecium formation. Taken together, these results lead to the postulate that mod and incompatibility genes do not determine, sensu stricto, protoperithecial function, as previously supposed (Boucherie and Bernet 1974), but may be involved in the homeostatic control of stationary cell functions essential for the complete development of the female sexual cycle.     

A constitutive mutation in a posttranscriptional regulator gene for a phenoloxidase and proteases in Podospora anserina

A recessive mutation in the gene mod-2 results in the synthesis at low temperatures of a phenoloxidase and an arrest of growth, reversible by beta-phenyl-pyruvic acid, a protease inhibitor. Phenoloxidase synthesis is 5-fluorouracil resistant and cycloheximade sensitive. Suppression of both cold sensitivity and phenoloxidase synthesis by common factors (higher NH4+ concentrations or mutations) suggests that the protease, suspected to be responsible for cold sensitivity, also arises from preexisting mRNA molecules. Instead of being recessive and constitutive, the mod-2 mutations is suppressive and dominant when cold sensitivity and phenoloxidases synthesis are induced as the consequence of the nonallelic gene interactions C/D, C/E, or R/V responsible for protoplasmic incompatibility. Combinations of nonallelic incompatibility systems and several mod-2 mutations lead us to hypothesize that the translational control of the above proteins depends on conformational relationships between incompatibility gene products and mod-2.     

The molecular mechanism of protoplasmic incompatibility and its relationship to the formation of protoperithecia in Podospora anserina.

In Podospora anserina, protoplasmic incompatibility due to interactions between non-allelic genes was suppressed by the effect of mutations in two modifier genes, mod-I and mod-2. It is shown that mod-I and mod-2 are involved in the production of three specific proteins, a phenoloxidase and two previously identified proteases (Bégueret & Bernet 1973 a) which are associated with the phenomenon of protoplasmic disintegration. These enzymes, whose messengers are normallly latent during vegetative growth, appear at this stage of the life cycle only as a consequence of incompatible gene interactions. The mode-I and mod-2 genes and each of the five incompatibility loci involved in non-allelic incompatibility systems also participate in the formation of the protoperithecia. This pleiotropic effect suggests that protoplasmic incompatibility is a deviation in the normal physiological processes of protoperithecial formation.     

Proteolytic activities during growth and aging in the fungus Podospora anserina: Effect of specific mutations

In Podospora anserina five proteolytic enzymes were characterized by chromatographic procedures. Three of these (proteases A, B and C) were found in the cell extracts of growing cultures and the other two (proteases III and IV) were revealed by studies on protoplasmic incompatibility. During growth, only protease C, an acidic enzyme, was active in crude extracts. From the stationary and the poststationary stages this activity decreased and finally disappeared, whereas a neutral serine protease (activity B) became active in crude extracts. A close relationship was observed between the proteolytic activity of the culture filtrates and the intracellular protease(s) concomitantly active in the crude extracts. None of the proteases associated with protoplasmic incompatibility was detected, both in the extra- and intracellular spaces. Qualitative variations in the proteolytic activities during stationary and post-stationary stages depended on the presence of specific genes and mutations: the mod C mutation suppressing protoplasmic incompatibility, inhibits the progressive decrease of protease C and, furthermore, the presence of non allelic incompatibility genes have for consequence the substitution of serine protease B by serine protease A during the poststationary stage.     

Molybdate and regulation of mod (molybdate transport), fdhF, and hyc (formate hydrogenlyase) operons in Escherichia coli.

Escherichia coli mutants with defined mutations in specific mod genes that affect molybdate transport were isolated and analyzed for the effects of particular mutations on the regulation of the mod operon as well as the fdhF and hyc operons which code for the components of the formate hydrogenlyase (FHL) complex. phi (hyc'-'lacZ+) mod double mutants produced beta-galactosidase activity only when they were cultured in medium supplemented with molybdate. This requirement was specific for molybdate and was independent of the moa, mob, and moe gene products needed for molybdopterin guanine dinucleotide (MGD) synthesis, as well as Mog protein. The concentration of molybdate required for FHL production by mod mutants was dependent on medium composition. In low-sulfur medium, the amount of molybdate needed by mod mutants for the production of half-maximal FHL activity was increased approximately 20 times by the addition of 40 mM of sulfate, mod mutants growing in low-sulfur medium transported molybdate through the sulfate transport system, as seen by the requirement of the cysA gene product for this transport. In wild-type E. coli, the mod operon is expressed at very low levels, and a mod+ merodiploid E. coli carrying a modA-lacZ fusion produced less than 20 units of beta-galactosidase activity. This level was increased by over 175 times by a mutation in the modA, modB, or modC gene. The addition of molybdate to the growth medium of a mod mutant lowered phi (modA'-'lacZ+) expression. Repression of the mod operon was sensitive to molybdate but was insensitive to mutations in the MGD synthetic pathway. These physiological and genetic experiments show that molybdate can be transported by one of the following three anion transport system in E. coli: the native system, the sulfate transport system (cysTWA gene products), and an undefined transporter. Upon entering the cytoplasm, molybdate branches out to mod regulation, fdhF and hyc activation, and metabolic conversion, leading to MGD synthesis and active molybdoenzyme synthesis.     

Mutational analysis of genes of the mod locus involved in molybdenum transport, homeostasis, and processing in Azotobacter vinelandii.

DNA sequencing of the region upstream from the Azotobacter vinelandii operon (modEABC) that contains genes for the molybdenum transport system revealed an open reading frame (modG) encoding a hypothetical 14-kDa protein. It consists of a tandem repeat of an approximately 65-amino-acid sequence that is homologous to Mop, a 7-kDa molybdopterin-binding protein of Clostridium pasteurianum. The tandem repeat is similar to the C-terminal half of the product of modE. The effects of mutations in the mod genes provide evidence for distinct high- and low-affinity Mo transport systems and for the involvement of the products of modE and modG in the processing of molybdate. modA, modB, and modC, which encode the component proteins of the high-affinity Mo transporter, are required for 99Mo accumulation and for the nitrate reductase activity of cells growing in medium with less than 10 microM Mo. The exchange of accumulated 99Mo with nonradioactive Mo depends on the presence of modA, which encodes the periplasmic molybdate-binding protein. 99Mo also exchanges with tungstate but not with vanadate or sulfate. modA, modB, and modC mutants exhibit nitrate reductase activity and 99Mo accumulation only when grown in more than 10 microM Mo, indicating that A. vinelandii also has a low-affinity Mo uptake system. The low-affinity system is not expressed in a modE mutant that synthesizes the high-affinity Mo transporter constitutively or in a spontaneous tungstate-tolerant mutant. Like the wild type, modG mutants only show nitrate reductase activity when grown in > 10 nM Mo. However, a modE modG double mutant exhibits maximal nitrate reductase activity at a 100-fold lower Mo concentration. This indicates that the products of both genes affect the supply of Mo but are not essential for nitrate reductase cofactor synthesis. However, nitrogenase-dependent growth in the presence or absence of Mo is severely impaired in the double mutant, indicating that the products of modE and modG may be involved in the early steps of nitrogenase cofactor biosynthesis in A. vinelandii.     

Characterization and genetic mapping of modA. A mutation in the post-translational modification of the glycosidases of Dictyostelium discoideum.

We have isolated a mutant of Dictyostelium discoideum, M31, which produces a reduced number of alpha-mannosidase-1 molecules per cell during the developmental program of the organism. We find that several of the glycosidases, a group of lysosomal proteins produced by D. discoideum, are altered in strain M31 and that this strain produces a reduced level of at least three of these activities. These enzymes do not share a common protein subunit but are known to share a common antigenic determinant which is, in part, carbohydrate in nature. In the wild type parent of M31, alpha-mannosidase-1 is modified by the addition of mannose and glucosamine (probably as N-acetylglucosamine) in the molar ratio of 5:2. alpha-Mannosidase-1 was also found to contain phosphoserine/phosphothreonine residues. alpha-Mannosidase-1 and other glycosidases are electrophoretically less negative when isolated from strain M31 than when isolated from wild type cells. The mutation present in M31, modA, appears to affect posttranslational modification, modA is a recessive mutation which we map onto linkage group I.     

Polymer-level synthesis of oxopyrimidine deoxynucleotides by Bacillus subtilis phage SP10: characterization of modification-defective mutants.

Bacillus subtilis phage SP10 DNA has two oxopyrimidines, thymidine 5'-monophosphate (dTMP) and its hypermodified analog (YdTMP). Published data suggest that both are synthesized by postreplicational modification of 5-hydroxymethyldeoxyuridylate (HOMedUMP) in nascent DNA by the following pathway: HOMedUMP----PPOMedUMP----dTMP (85%) or YdTMP (15%); PPOMedUMP is 5-(hydroxymethyl-O-pyrophosphoryl)deoxyuridylate, the pyrophosphoric acid ester of the C5CH2OH function of HOMedUMP. This paper describes aberrant DNAs synthesized at nonpermissive temperatures by a complementary series of heat-sensitive, modification-defective (mod) mutants. Collectively, these mutants encompass the major steps in the complete modification of nascent SP10 DNA. DNA produced by modA phage retains HOMedUMP as its sole oxopyrimidine, implying that (i) this mutant is defective in the pyrophosphorylation step and (ii) formation of PPOMedUMP is required for any further modification. Furthermore, studies with double mutants indicated that modA is epistatic for all other mod mutants, which supports the hypothesis that modA controls the earliest step in the modification pathway. Since their DNAs contain no YdTMP, modC and modD are defective in hypermodification (i.e., PPOMedUMP----YdTMP). However, dTMP occupies the entire oxopyrimidine fraction of modC DNA, whereas modD DNA has a normal dTMP content, but the now-missing YdTMP is replaced by either PPOMedUMP or a byproduct of abortive hypermodification. It is proposed that the modD mutants are defective in the catalytic aspects of hypermodification and that modC are defective in some regulatory function that promotes hypermodification at the expense of reductive modification (i.e., PPOMedUMP----dTMP). Reductive modification is defective in modB phage, as evidenced by the absence of dTMP. In contrast to the others, modB DNA has a complex oxopyrimidine content: HOMedUMP, ca. 30%; PPOMedUMP, ca. 40%; and YdTMP, ca. 30%. The expanded level of YdTMP suggests that at certain sites, reductive modification and hypermodification are competing reactions. Interestingly, the PPOMedUMP content of modB DNA seemingly reflects the maximum degree to which phage DNA can be pyrophosphorylated, since the loss of YdTMP from modBmodC and modBmodD DNAs results in a unilateral increase in HOMedUMP content.     

Characterization of Rhodobacter capsulatus genes encoding a molybdenum transport system and putative molybdenum-pterin-binding proteins.

The alternative, heterometal-free nitrogenase of Rhodobacter capsulatus is repressed by traces of molybdenum in the medium. Strains carrying mutations located downstream of nifB copy II were able to express the alternative nitrogenase even in the presence of high molybdate concentrations. DNA sequence analysis of a 5.5-kb fragment of this region revealed six open reading frames, designated modABCD, mopA, and mopB. The gene products of modB and modC are homologous to ChlJ and ChlD of Escherichia coli and represent an integral membrane protein and an ATP-binding protein typical of high-affinity transport systems, respectively. ModA and ModD exhibited no homology to known proteins, but a leader peptide characteristic of proteins cleaved during export to the periplasm is present in ModA, indicating that ModA might be a periplasmic molybdate-binding protein. The MopA and MopB proteins showed a high degree of amino acid sequence homology to each other. Both proteins contained a tandem repeat of a domain encompassing 70 amino acid residues, which had significant sequence similarity to low-molecular-weight molybdenum-pterin-binding proteins from Clostridium pasteurianum. Compared with that for the parental nifHDK deletion strain, the molybdenum concentrations necessary to repress the alternative nitrogenase were increased 4-fold in a modD mutant and 500-fold in modA, modB, and modC mutants. No significant inhibition of the heterometal-free nitrogenase by molybdate was observed for mopA mopB double mutants. The uptake of molybdenum by mod and mop mutants was estimated by measuring the activity of the conventional molybdenum-containing nitrogenase. Molybdenum transport was not affected in a mopA mopB double mutant, whereas strains carrying lesions in the binding-protein-dependent transport system were impaired in molybdenum uptake.     

Protoplasmic Incompatibility in PODOSPORA ANSERINA: A Possible Role for Its Associated Proteolytic Activity

A mutation (modD) was selected in a gene involved in the control of protoplasmic incompatibility. Previous results (Labarere and Bernet 1979) showed that modD decreased the density of protoperithecia and caused a defect in ascospore germination. In addition, modD has a third defect: when modD stationary cells were isolated in order to obtain further development, renewal of growth rarely ensued. Instead, the modD cells lysed or produced microthalli from which normal growth never occurred. These defects were suppressed by beta-phenyl pyruvic acid, a protease inhibitor, and by the presence of a mutation (modC) that suppresses the proteases associated with protoplasmic incompatibility. The stationary wild-type cells' regeneration was inhibited by beta-phenyl pyruvic acid at levels that maintained modD cells' regeneration. These results suggest a biological role for the proteases associated with protoplasmic incompatibility.     

Effects of a post-translational modification mutation on different developmentally regulated glycosidases in Dictyostelium discoideum.

We have studied the effect of a post-translational modification mutation upon four developmentally regulated glycosidases of Dictyostelium discoideum. The presence of the modA mutation affects the intracellular level of these multimeric enzymes differently. The level of alpha-glucosidase is unaffected in the modA mutant. The mutant cell contains only a very small fraction of the wild type beta-glucosidase-1 activity. The alteration in modification renders beta-glucosidase-1 holoenzyme thermolabile and susceptible to degradation in vivo. alpha-Mannosidase-1 and N-acetylglucosaminidase are found at approximately 1/3 of the wild type level in the modA mutant. Degradation of holoenzyme does not appear to be responsible for the low level of these activities. We propose that alpha-mannosidase-1 and N-acetylglucosaminidase subunits are being degraded prior to subunit assembly. We conclude the modification bestows different properties upon the various glycosidases.     

A New Method for the Screening of Mutations Related to Protoplasmic Incompatibility, Differentiation and Plasma Membrane in the Fungus PODOSPORA ANSERINA

In Podospora anserina previous investigations showed that mutations in genes involved in the control of protoplasmic incompatibility cause defects at various stages of differentiation during the life cycle and also modify properties of the plasma membrane. To establish these relationships in another way, a new method for screening mutations has been developed as a first step. Eighty-five new mutants were selected for resistance to toxic products (sorbose or thiourea); in a second step these mutants were tested for modifications of protoplasmic incompatibility and cellular differentiation. Seven of the sorbose or thiourea resistant-mutants (i.e., 8%) exhibited new patterns of protoplasmic incompatibility. Genetic analyses were carried out with three mutants. Mutation X25 suppresses protoplasmic incompatibility resulting from all allelic interactions and restores the fertility of the crosses ♀ V x ♂ V1 and ♀ Z1 x ♂ Z2. Mutation V41 is an allele of the v locus with new properties. Mutation X61 totally suppresses the V/V'1 interaction and weakens all of the other allelic incompatibility systems; X61 strains are defective in protoperithecia differentiation. Electrophoresis of plasma membrane proteins showed that X61 strains lack two polypeptides whose apparent molecular weights are 41,000 and 44,000. This new screening method is especially efficient for obtaining new mutants and identifying additional genes involved in incompatibility. These results provide further support demonstrating the relationships between protoplasmic incompatibility, cellular differentiation and plasma membrane.     

Molybdate transport and its effect on nitrogen utilization in the cyanobacterium Anabaena variabilis ATCC 29413

Molybdenum is an essential component of the cofactors of many metalloenzymes including nitrate reductase and Mo-nitrogenase. The cyanobacterium Anabaena variabilis ATCC 29413 uses nitrate and atmospheric N2 as sources of nitrogen for growth. Two of the three nitrogenases in this strain are Mo-dependent enzymes, as is nitrate reductase; thus, transport of molybdate is important for growth of this strain. High-affinity transport of molybdate in A. variabilis was mediated by an ABC-type transport system encoded by the products of modA and modBC. The modBC gene comprised a fused orf including components corresponding to modB and modC of Escherichia coli. The deduced ModC part of the fused gene lacked a recognizable molybdate-binding domain. Expression of modA and modBC was induced by starvation for molybdate. Mutants in modA or modBC were unable to grow using nitrate or Mo-nitrogenase. Growth using the alternative V-nitrogenase was not impaired in the mutants. A high concentration of molybdate (10 microM) supported normal growth of the modBC mutant using the Nif1 Mo-nitrogenase, indicating that there was a low-affinity molybdate transport system in this strain. The modBC mutant did not detectably transport low concentrations of 99Mo (molybdate), but did transport high concentrations. However, such transport was observed only after cells were starved for sulphate, suggesting that an inducible sulphate transport system might also serve as a low-affinity molybdate transport system in this strain.     

Unlinked Noncomplementation: Isolation of New Conditional-Lethal Mutations in Each of the Tubulin Genes of Saccharomyces Cerevisiae

Mutations in genes of Saccharomyces cerevisiae that code for proteins that interact with beta-tubulin were sought by screening for unlinked mutations that fail to complement mutations in the single beta-tubulin-encoding gene (TUB2). Among the first three noncomplementing mutations examined, two are linked to TUB2 while one is unlinked. The unlinked mutation was shown to be a conditional-lethal allele of the major alpha-tubulin-encoding gene (TUB1) and represents the first such mutation in that gene. The tub1-1 mutation itself causes a cold-sensitive cell-cycle arrest, and confers supersensitivity to the antimicrotubule drug benomyl. These phenotypes occur in the presence of a wild-type copy of the minor alpha-tubulin-encoding gene, TUB3; the combination of tub1-1 and a tub3 null mutation is inviable in haploids. Through further application of this method, new mutations in TUB2 and TUB3 were isolated as unlinked noncomplementers of tub1-1. The noncomplementation between tub1 and tub2 mutations is gene specific and allele specific, suggesting that the phenotype is due to an interaction at the protein level. We conclude that isolation of unlinked noncomplementing mutations is likely to be a generally useful method for isolating mutations in interacting gene products.     

Cloning and characterization of the polC region of Bacillus subtilis.

The polC gene of Bacillus subtilis is defined by five temperature-sensitive mutations and the 6-(p-hydroxyphenylazo)-uracil (HPUra) resistance mutation azp-12. Biochemical evidence suggests that polC codes for the 160-kilodalton DNA polymerase III. A recombinant plasmid, p154t, was isolated and found to contain the azp-12 marker and one end of the polC gene (N. C. Brown and M. H. Barnes, J. Cell. Biochem. 78 [Suppl.]: 116, 1983). The azp-12 marker was localized to a 1-kilobase DNA segment which was used as a probe to isolate recombinant lambda phages containing polC region sequences. A complete polC gene was constructed by in vitro ligation of DNA segments derived from two of the recombinant phages. The resulting plasmid, pRO10, directed the synthesis of four proteins of 160, 76, 39, and 32 kilodaltons in Escherichia coli maxicells. Recombination-deficient (recE) B. subtilis PSL1 containing pRO10 produced an HPUra-resistant polymerase III activity which was lost when the strain was cured of pRO10. In vivo, the HPUra resistance of the plasmid-encoded polymerase III appeared to be recessive to the resident HPUra-sensitive polymerase III enzyme.     

napts, a mutation affecting sodium channel activity in Drosophila, is an allele of mle, a regulator of X chromosome transcription.

napts is a recessive mutation that affects the level of sodium channel activity and, at high temperature, causes paralysis associated with a loss of action potentials. We show, by genetic complementation tests, germline transformation, and analysis of mutations, that napts is a gain-of-function mutation of mle, a gene required for X chromosome dosage compensation and male viability. Molecular analyses of nap and mle mutations indicate that mle+, nap+, and napts activities are encoded by the same open reading frame and suggest that napts is due to a single amino acid substitution. Although napts is known to act via para+, an X-linked sodium channel structural gene, its effect is not due to a simple defect in para+ dosage compensation.     

Isolation and characterization of temperature-sensitive RNA polymerase II mutants of Saccharomyces cerevisiae.

Three independent, recessive, temperature-sensitive (Ts-) conditional lethal mutations in the largest subunit of Saccharomyces cerevisiae RNA polymerase II (RNAP II) have been isolated after replacement of a portion of the wild-type gene (RPO21) by a mutagenized fragment of the cloned gene. Measurements of cell growth, viability, and total RNA and protein synthesis showed that rpo21-1, rpo21-2, and rpo21-3 mutations caused a slow shutoff of RNAP II activity in cells shifted to the nonpermissive temperature (39 degrees C). Each mutant displayed a distinct phenotype, and one of the mutant enzymes (rpo21-1) was completely deficient in RNAP II activity in vitro. RNAP I and RNAP III in vitro activities were not affected. These results were consistent with the notion that the genetic lesions affect RNAP II assembly or holoenzyme stability. DNA sequencing revealed that in each case the mutations involved nonconservative amino acid substitutions, resulting in charge changes. The lesions harbored by all three rpo21 Ts- alleles lie in DNA sequence domains that are highly conserved among genes that encode the largest subunits of RNAP from a variety of eucaryotes; one mutation lies in a possible Zn2+ binding domain.     

Mutations affecting a surface glycoprotein, gp80, of Dictyostelium discoideum.

We isolated two independent mutations in Dictyostelium discoideum that result in the absence of the antigenic determinant recognized by monoclonal antibody E28D8. This antibody reacts with a post-translational modification on the surface glycoprotein gp80 and several other proteins. Both of the mutations occur in the same locus, modB, which was mapped to linkage group VI. The modB mutations result in sufficient alteration of gp80 that it is absent or unrecognizable by two-dimensional gel electrophoresis. Strains carrying modB mutations exhibit "contact sites A"-mediated cell-cell adhesion although more weakly than do wild-type strains and develop to fruiting bodies carrying viable spores. Although gp80 has been implicated in the mechanism of cell-cell adhesion in D. discoideum, it is clear from the behavior of these mutant strains that the determinant on gp80 recognized by E28D8 is not necessary for either morphogenesis or reduced EDTA-resistant adhesion.