Genetic and Physiological Characterization of met15 Mutants of SACCHAROMYCES CEREVISIAE: a Selective System for Forward and Reverse Mutations

One hundred and thirty-three spontaneous and induced mutants of the met15 locus in Saccharomyces cerevisiae were characterized with respect to temperature sensitivity, osmotic remediability, interallelic complementation, and suppressibility by amber and ochre suppressors. Forty mutants are osmotic remedial; 17 of these, and no others, are also temperature-sensitive. Seven of 133 mutations are suppressible by an amber suppressor and 11 are suppressible by an ochre suppressor. Seventy percent of the mutants exhibited interallelic complementation, suggesting that the functional gene product of the met15 gene is a multimeric protein. Relative map positions of 30 met15 were estimated from the frequencies of X-ray-induced mitotic reversion of various heteroallelic diploids. All complementing nonsense mutations are located near one end of the gene in contrast to other nonsense mutations which span most of the gene, thus relating the direction of translation of the mRNA with respect to the fine-structure map. Recombination studies indicated that two of 30 mutants contained deletions of the entire met15 locus.—It was established that a variety of mutational types, including missense, nonsense, and deletions, are recovered with this unique system in which both forward and reverse mutations can be selected on the basis of methyl mercury resistance and methionine requirement of the met15 mutants.     

Fine Structure Analysis of the ade3 Locus in SACCHAROMYCES CEREVISIAE

Twenty-six spontaneous mutants at the ade3 locus of Saccharomyces cerevisiae have been mapped and characterized with respect to revertibility, osmotic remediability and temperature sensitivity. Twelve of the twenty-six are temperature sensitive, 25 of 26 are osmotic remedial and 21 of 26 revert. Two of the mutants map as deletions. At least five of the 26 are nonsense mutations but are also, unexpectedly, osmotic remedial. Three nonsense mutations are also temperature sensitive, again an unexpected result. The two multisite mutations are both temperature sensitive and osmotic remedial. For mutants at this locus osmotic remediability and temperature sensitivity cannot be considered diagnostic criteria for missense mutations.     

Cyclic AMP-dependent protein kinase A negatively regulates conidia formation by the tangerine pathotype of Alternaria alternata

The necrotrophic fungal pathogen Alternaria alternata causes brown spot diseases in many citrus cultivars. The FUS3 and SLT2 mitogen-activated protein kinases (MAPK)-mediated signaling pathways have been shown to be required for conidiation. Exogenous application of cAMP to this fungal pathogen decreased conidia formation considerably. This study determined whether a cAMP-activated protein kinase A (PKA) is required for conidiation. Using loss-of-function mutations in PKA catalytic and regulatory subunit-coding genes, we demonstrated that PKA negatively regulates conidiation. Fungal mutants lacking PKA catalytic subunit gene (PKA ^cat ) reduced growth, lacked detectable PKA activity, and produced higher amounts of conidia compared to wild-type. Introduction of a functional copy of PKA ^cat into a null mutant partially restored PKA activity and produced wild-type level of conidia. In contrast, fungi lacking PKA regulatory subunit gene (PKA ^reg ) produced detectable PKA activity, exhibited severe growth reduction, formed swelling hyphal segments, and produced no mature conidia. Introduction of the PKA ^reg gene to a regulatory subunit mutant restored all phenotypes to wild type. PKA ^reg -null mutants induced fewer necrotic lesions on citrus compared to wild-type, whereas PKA ^cat mutant displayed wild-type virulence. Overall, our studies indicate that PKA and FUS3-mediated signaling pathways apparently have very different roles in the regulation of conidia production and A. alternata pathogenesis in citrus.     

Mapping of recognition sites for the restriction endonuclease from Escherichia coli K12 on bacteriophage PM2 DNA.

Several mutations in gene B of phage S13 appear to shorten the B protein by elimination of an N-terminal fragment, without destroying the B protein function. The shortened B protein resulting from each of these mutations can block the unique DNA-nicking properties of the S13 gene A protein. Because of the block in gene A function, normal gene B protein may have a function in phage DNA synthesis in addition to its known role in catalyzing capsid assembly.From gel electrophoresis the mutant B protein is estimated to be shorter than the normal S13 B protein by 1720 ± 70 daltons and is therefore believed to be an internal reinitiation fragment. The reinitiated fragments are functional and are made in about twice the amount of the normal B protein.The phage mutants which yield the reinitiation fragments are double mutants, each phage containing the same gene B nonsense mutation and each appearing to contain a different compensating gene B mutation. Various data support the assumption that the compensating mutations are frame-shifts, including the fact that suppression does not restore the normal-sized B protein. The reinitiation is assumed to occur at a pre-existing out-of-phase initiator codon, near the nonsense triplet; the correct reading frame would then be restored by each of the several different compensating mutations.The position of the normal S13 B protein in the gel electrophoresis pattern has been located both by elimination and shifting of the B peak, using appropriate amber mutants. The molecular weight of the S13 B protein is about 17,200, and is 2100 daltons less than the B protein of phage φX174; the S13 B protein can nevertheless substitute for the φX 174 B protein. Thus substantial portions of the B protein can be deleted without destroying its function.     

Genetic studies of the lac repressor. III. Additional correlation of mutational sites with specific amino acid residues

The complete results of the analysis of over 5300 independently derived nonsense mutations in the lacI gene are presented. These have been mapped and divided into specific sites. A total of 105 nonsense mutations derived from 90 different codons can be distinguished, of which several are the result of tandem double base changes induced by ultraviolet light. With the aid of results determined in a preceding paper (Miller et al., 1977), the majority of these mutations have been assigned to points in the gene coding for specific residues in the lac repressor. This allows a detailed correlation of the physical and genetic map.Recombination studies have been carried out using mutations at known sites. For crosses involving mutations separated by less than 30 nucleotides (the main object of this study), a significant lack of agreement between distance and recombination frequency has been found.     

Molecular analysis of mutation at the hprt locus of Chinese hamster V79 cells induced by ethyl methanesulphonate and mitomycin C

Mutation at the hprt locus of Chinese hamster V79 cells were induced by treatment with ethyl methanesulphonate (EMS), considered primarily a point mutagen and mitomycin C (MMC), a potent clastogen. EMS gave a dose-dependent induction of mutants while MMC induced a poor mutagenic response. Mutations were analysed using Southern and Northern blotting.Analysis of 9 EMS-induced and 4 spontaneous mutants yielded no detectable alterations in the hprt locus after digestion of DNA with 6 restriction enzymes. Mutants without detectable changes carried presumptive point mutations. In contrast, 4 out of 12 MMC-induced mutants had detectable alterations. 2 of these appeared to have lost the entire hprt gene while the other 2had prodable partial deletions. For these 4 deletion mutants no hprt mRNA was detected. 3 MMC-induced and 1 EMS-induced mutants had reduced levels of hprt mRNA. All the other mutants showed normal levels of hprt mRNA and the message detected was always of the correct size.It is suggested that the poor mutagenic response induced by MMC may be due to the lethal nature of large deletions involving both the hemizygous hprt locus and adjacent essential genes. This may lead to an underestimate of the mutagenicity of clastogenic agents such as MMC in the V79 HPRT mutation assay.     

The use of suicide substrates to select mutants of Escherichia coli lacking enzymes of alcohol fermentation

Summary Mutants of Escherichia coli resistant to chloroethanol or to chloroacetaldehyde were selected. Such mutants were found to lack the fermentative coenzyme A (CoA) linked acetaldehyde dehydrogenase activity. Most also lacked the associated fermentative enzyme alcohol dehydrogenase. Both types of mutants, those lacking acetaldehyde dehydrogenase alone or lacking both enzymes, mapped close to the regulatory adhC gene at 27 min on the E. coli genetic map. The previously described acd mutants which lack acetaldehyde dehydrogenase and which map at 63 min were shown to be pleiotropic, affecting respiration and growth on a variety of substrates. It therefore seems likely that the structural genes for both the acetaldehyde and alcohol dehydrogenases lie in the adhCE operon. This interpretation was confirmed by the isolation of temperature sensitive chloracetaldehyde-resistant mutants, some of which produced thermolabile acetaldehyde dehydrogenase and alcohol dehydrogenase and were also found to map at the adh locus. Reversion analysis indicated that mutants lacking one or both enzymes carried single mutations. The gene order in the adh region was determined by three point crosses to be trp - zch:: Tn10 - adh - galU- bglY - tyrT - chlC.     

Biochemical and Immunological Characterization of Nitrate Reductase Deficient nia Mutants of Nicotiana plumbaginifolia

Sixty-five Nicotiana plumbaginifolia mutants affected in the nitrate reductase structural gene (nia mutants) have been analyzed and classified. The properties evaluated were: (a) enzyme-linked immunosorbent assay (two-site ELISA) using a monoclonal antibody as coating reagent and (b) presence of partial catalytic activities, namely nitrate reduction with artificial electron donors (reduced methyl viologen, reduced flavin mononucleotide, or reduced bromphenol blue), and cytochrome c (Cyt c) reduction with NADH. Four classes have been defined: 40 mutants fall within class 1 which includes all mutants that have no protein detectable in ELISA and no partial activities; mutants of classes 2 and 3 exhibit an ELISA-detectable nitrate reductase protein and lack either Cyt c reductase activity (class 2: fourteen mutants) or the terminal nitrate reductase activities (class 3: eight mutants) of the enzyme. Three mutants (class 4) are negative in the ELISA test, lack Cyt c reductase activity, and lack or have a very low level of reduced methyl viologen or reduced flavin mononucleotide-nitrate reductase activities; however, they retain the reduced bromphenol blue nitrate reductase activity. Variations in the degrees of terminal nitrate reductase activities among the mutants indicated that the flavin mononucleotide and methyl viologen-dependent activities were linked while the bromphenol blue-dependent activity was independent of the other two. The putative positions of the lesions in the mutant proteins and the nature of structural domains of nitrate reductase involved in each partial activity are discussed.     

A further characterization of the cinnamon gene in Drosophila melanogaster

Summary Two mutants of Saccharomyces cerevisiae lacking pyruvate kinase (EC.2.7.1.40) are described. The mutations are recessive, segregate 2⁺:2^- in tetrads and do not complement each other. Single-step spontaneous revertants, isolated on glucose plates, get back pyruvate kinase activity. The enzymes from various revertants display a wide spectrum of specific activity, thermolability and altered affinity for ligands such as P-enol pyruvate, ADP and fructose 1,6-diphosphate. The mutants produce materials crossreacting to the rabbit antibody raised against purified pyruvate kinase from the wild type yeast. These mutations thus define the structural gene of pyruvate kinase.The mutations map on the leaft arm of chromosome I and form a single complementation group with five other pyruvate kinase mutations in the pyk1 gene that was earlier suggested to be a regulatory locus controlling the synthesis of this enzyme. A comparative study of these mutants has been made with the structural mutants described here.     

Genetic Control of the Transport of Hexose Phosphates in Escherichia coli: Mapping of the uhp Locus

A number of mutations affecting the transport of hexose phosphates in Escherichia coli were ordered within the uhp locus. Three-point crosses by transduction or conjugation allowed the ordering of the alleles relative to the adjacent pyrE marker. The same linear map was obtained by both methods. This, combined with the regulatory properties of revertants of these mutants, allowed a tentative identification of two genes, one presumably coding for the transport system (uhpT) and the other(s) specifying a regulatory element (uhpR). The order of these is pyrE-uhpT-uhpR. Mutants exhibiting constitutive expression of the transport system were isolated. This behavior is genetically linked to the uhp locus, but more precise localization was not possible.     

2-Deoxyribose 5-phosphate aldolase: Genetic analyses of structure

A total of 33 mutant strains of Salmonella typhimurium deficient in deoxyribose 5-phosphate activity have been isolated and characterized as missense or nonsense. Three-factor transductional analyses of the mutants were used to construct a fine structure map of the deoC gene, which codes for a peptide of 28,500 molecular weight. An unusual clustering of the missense mutants was observed, where 75% of all the missense mutants mapped in an area which corresponds to 19% of the total gene length. It is suggested that this area of the protein is particularly sensitive to amino acid replacements but that other areas of the protein are reasonably tolerant of such changes. Nonsense mutations are found scattered throughout the gene. This is expected since the carboxyl-terminal tyrosine is essential for enzymatic activity.     

Host participation in bacteriophage lambda head assembly

Mutants of Escherichia coli, called groE, specifically block assembly of bacteriophage λ heads. When groE bacteria are infected by wild type λ, phage adsorption, DNA injection and replication, tail assembly, and cell lysis are all normal. No active heads are formed, however, and head related “monsters” are seen in lysates. These monsters are similar to the structures seen on infection of wild-type cells by phage defective in genes B or C.We have isolated mutants of λ which can overcome the block in groE hosts and have mapped these mutants. All groE mutations can be compensated for by mutation of phage gene E (hence the name groE). Gene E codes for the major structural subunit of the phage head. Some groE mutants, called groEB, can be compensated by mutation in either gene E or in gene B. Gene B is another head gene.During normal head assembly the protein encoded by phage head gene B or C appears to be converted to a lower molecular weight form, h3, which is found in phage. The appearance of h3 protein in fast sedimenting head related structures requires the host groE function.We suggest that the proteins encoded by phage genes E, B and C, and the bacterial component defined by groE mutations act together at an early stage in head assembly.     

Subunit–subunit interactions are weakened in mutant forms of acetohydroxy acid synthase insensitive to valine inhibition

In acetohydroxy acid synthase from Streptomyces cinnamonensis mutants affected in valine regulation, the impact of mutations on interactions between the catalytic and the regulatory subunits was examined using yeast two-hybrid system. Mutations in the catalytic and the regulatory subunits were projected into homology models of the respective proteins. Two changes in the catalytic subunit, E139A (α domain) and ΔQ217 (β domain), both located on the surface of the catalytic subunit dimer, lowered the interaction with the regulatory subunit. Three consecutive changes in the N-terminal part of the regulatory subunit were examined. Changes G16D and V17D in a loop and adjacent α-helix of ACT domain affected the interaction considerably, indicating that this region might be in contact with the catalytic subunit during allosteric regulation. In contrast, the adjacent mutation L18F did not influence the interaction at all. Thus, L18 might participate in valine binding or conformational change transfer within the regulatory subunits. Shortening of the regulatory subunit to 107 residues reduced the interaction essentially, suggesting that the C-terminal part of the regulatory subunit is also important for the catalytic subunit binding.     

Evidence for the Inclusion of Controlling Elements within the Structural Gene at the Waxy Locus in Maize

Minimal limits for the structural gene at the waxy locus have been set by investigations of the protein product of the gene. An altered protein is produced by four of the waxy mutants including B3, a controlling-element mutation. All are similar to wild type in molecular weight as determined by electrophoresis in SDS acrylamide gels. At least three of the five wx controlling-element mutations studied have been shown to lie within the limits of the structural gene.     

A Heterozygous Truncating Mutation in RRM2B Causes Autosomal-Dominant Progressive External Ophthalmoplegia with Multiple mtDNA Deletions

Autosomal-dominant progressive external ophthalmoplegia (adPEO) is a mitochondrial disorder that is characterized by accumulation of multiple mitochondrial DNA (mtDNA) deletions in postmitotic tissues. The disorder is heterogeneous, with five known nuclear disease genes that encode the proteins ANT1, Twinkle, POLG, POLG2, and OPA1. Defects in these proteins affect mtDNA maintenance, probably leading to stalled replication forks, consequent mtDNA deletion formation, and progressive respiratory chain deficiency. Here we present a large adPEO family with multiple mtDNA deletions, whose disease was not explained by mutations in any of the known adPEO loci. We mapped the disease locus in this family to chromosome 8q22.1-q23.3. The critical linkage region contained the RRM2B gene, which encodes the small subunit of the ribonucleotide reductase p53R2, which has previously been shown to be essential for the maintenance of mtDNA copy number. Mutation screening of RRM2B revealed a heterozygous nonsense mutation in exon 9 (c.979C→T [p.R327X]) in all affected individuals that was absent in 380 control chromosomes. The same mutation was found to segregate in another adPEO family. The mutant mRNA escaped nonsense-mediated decay and resulted in a protein with truncation of 25 highly conserved C-terminal amino acids essential for the interaction with the ribonucleotide reductase subunit R1. We conclude that dominant-negative or gain-of-function mutations in RRM2B are a cause of multiple mtDNA deletions and adPEO.     

Genetic characterization and regulation of the nadB locus of Salmonella typhimurium.

The nadB locus encodes the first enzyme of NAD synthesis. It has been reported that this gene and nadA are regulated by a positive regulatory protein encoded in the nadB region. In pursuing this regulatory mechanism, we constructed a fine-structure genetic map of the nadB gene. The region appears to include a single complementation group; no evidence for a positive regulatory element was found. Several mutations causing resistance to the analog 6-aminonicotinamide mapped within the structural gene and probably cause resistance to feedback inhibition. Regulatory mutations for nadB were isolated. These mutants mapped far from nadB near the pnuA gene, which encodes a function required for nicotinamide mononucleotide transport. The regulatory mutations appear to affect a distinct function encoded in the same operon as pnuA.     

Suppression of dnaE nonsense mutations by pcbA1.

DNA polymerase III has been recognized as the required replication enzyme in Escherichia coli. The synthesis subunit of DNA polymerase III holoenzyme (alpha subunit) is encoded by the dnaE gene. We have reported that E. coli cells can survive and grow in the absence of a functional dnaE gene product if DNA polymerase I and the pcbA1 mutation are present. Existing mutations in the dnaE gene have been conditionally defective thermolabile mutations. We report here construction of nonsense mutations in the dnaE gene by use of a temperature-sensitive suppressor mutation to permit survival at the permissive temperature (32 degrees C). Introduction of the pcbA1 mutation eliminated the temperature-sensitive phenotype. We confirmed by immunoblotting the lack of detectable alpha subunit at 43 degrees C.     

Normal germ line establishment in mice carrying a deletion of the Ifitm/Fragilis gene family cluster

The family of interferon-inducible transmembrane proteins (Ifitm) consists of five highly sequence-related cell surface proteins, which are implicated in diverse cellular processes. Ifitm genes are conserved, widely expressed, and characteristically found in genomic clusters, such as the 67-kb Ifitm family locus on mouse chromosome 7. Recently, Ifitm1 and Ifitm3 have been suggested to mediate migration of early primordial germ cells (PGCs), a process that is little understood. To investigate Ifitm function during germ cell development, we used targeted chromosome engineering to generate mutants which either lack the entire Ifitm locus or carry a disrupted Ifitm3 gene only. Here we show that the mutations have no detectable effects on development of the germ line or on the generation of live young. Hence, contrary to previous reports, Ifitm genes are not essential for PGC migration. The Ifitm family is a striking example of a conserved gene cluster which appears to be functionally redundant during development.     

Functional Characterization of PRKAR1A Mutations Reveals a Unique Molecular Mechanism Causing Acrodysostosis but Multiple Mechanisms Causing Carney Complex

The main target of cAMP is PKA, the main regulatory subunit of which (PRKAR1A) presents mutations in two genetic disorders: acrodysostosis and Carney complex. In addition to the initial recurrent mutation (R368X) of the PRKAR1A gene, several missense and nonsense mutations have been observed recently in acrodysostosis with hormonal resistance. These mutations are located in one of the two cAMP-binding domains of the protein, and their functional characterization is presented here. Expression of each of the PRKAR1A mutants results in a reduction of forskolin-induced PKA activation (measured by a reporter assay) and an impaired ability of cAMP to dissociate PRKAR1A from the catalytic PKA subunits by BRET assay. Modeling studies and sensitivity to cAMP analogs specific for domain A (8-piperidinoadenosine 3′,5′-cyclic monophosphate) or domain B (8-(6-aminohexyl)aminoadenosine-3′,5′-cyclic monophosphate) indicate that the mutations impair cAMP binding locally in the domain containing the mutation. Interestingly, two of these mutations affect amino acids for which alternative amino acid substitutions have been reported to cause the Carney complex phenotype. To decipher the molecular mechanism through which homologous substitutions can produce such strikingly different clinical phenotypes, we studied these mutations using the same approaches. Interestingly, the Carney mutants also demonstrated resistance to cAMP, but they expressed additional functional defects, including accelerated PRKAR1A protein degradation. These data demonstrate that a cAMP binding defect is the common molecular mechanism for resistance of PKA activation in acrodysosotosis and that several distinct mechanisms lead to constitutive PKA activation in Carney complex.     

Cyclic AMP-dependent protein kinase catalytic subunits have divergent roles in virulence factor production in two varieties of the fungal pathogen Cryptococcus neoformans

Our earlier findings established that cyclic AMP-dependent protein kinase functions in a signaling cascade that regulates mating and virulence of Cryptococcus neoformans var. grubii (serotype A). Mutants lacking the serotype A protein kinase A (PKA) catalytic subunit Pka1 are unable to mate, fail to produce melanin or capsule, and are avirulent in animal models, whereas mutants lacking the PKA regulatory subunit Pkr1 overproduce capsule and are hypervirulent. Because other mutations have been observed to confer different phenotypes in two diverged varieties of C. neoformans (grubii variety [serotype A] and neoformans variety [serotype D]), we analyzed the functions of the PKA genes in the serotype D neoformans variety. Surprisingly, the Pka1 catalytic subunit was not required for mating, haploid fruiting, or melanin or capsule production of serotype D strains. Here we identify a second PKA catalytic subunit gene, PKA2, that is present in both serotype A and D strains of C. neoformans. The divergent Pka2 catalytic subunit was found to regulate mating, haploid fruiting, and virulence factor production in serotype D strains. In contrast, Pka2 has no role in mating, melanin production, or capsule formation in serotype A strains. Our studies illustrate how different components of signaling pathways can be co-opted and functionally specialized during the evolution of related but distinct varieties or subspecies of a human fungal pathogen.