Multiple active varieties of Neurospora glutamate dehydrogenase formed by hybridization between two inactive mutant proteins in vivo and in vitro

Inactivation of secretory phospholipase A2 by ionizing radiation

The extracellular phospholipase A2s (PLA2) from cobra venom, rattlesnake venom, and porcine pancreas were analyzed by radiation inactivation to determine their functional aggregation states. The analysis was performed in the presence of the protein transferrin at two different concentrations of PLA2: 5 micrograms/ml. The small size of these proteins necessitated the use of high radiation dosages. The catalytic activity of all samples decreased as a single exponential as a function of radiation dosage, to > 97% inactivation. Target size analysis of these curves yielded sizes corresponding to dimers for all three PLA2s, indicating that all three enzymes exist as dimers or larger aggregates under the conditions studied. An analysis of the amount of intact protein remaining by sodium dodecyl sulphate-polyacrylamide gel electrophoresis showed that the loss of protein also followed a dimeric size for all three PLA2s. The loss of protein as a dimer indicates that transfer of radiation energy is occurring between polypeptides.

Sequential gel mobility shift scanning of 5' upstream sequences of the Neurospora crassa am (GDH) gene

We have used gel mobility shift assays to scan 1.7 kb of 5' non-coding sequence of the am (glutamate dehydrogenase) gene of Neurospora crassa for binding by partially fractionated Neurospora proteins. Using genetic analysis this region had been shown to play an important role in the control of glutamate dehydrogenase (GDH) expression. Gel mobility shift analysis identified three regions to which Neurospora proteins bind specifically. Two of these corresponded to the two elements previously defined by genetic analysis (URSam alpha and URSam beta). The third protein binding site appears to be unrelated to am gene expression. Competition experiments showed that the proteins that bind to the URSam alpha and URSam beta elements are different. The URSam alpha element was shown to contain two independent binding sites for the URSam alpha binding protein(s). Both fragments contain a CCAAT motif, suggesting that URSam alpha binding protein(s) may be members of one of the CCAAT-binding protein families. The effect of deletion of either the URSam alpha or URSam beta elements on catabolite induction of am expression was also determined. Both elements appear to act as constitutive enhancers of gene expression.

An apparent rare-codon effect on the rate of translation of a Neurospora gene

As the result of two mutually compensating frameshift mutations, three successive codons with third-position A were generated in the Neurospora crassa am (NADP-specific glutamate dehydrogenase: GDH) gene. These codons do not occur at all elsewhere in the gene and only infrequently in other highly expressed Neurospora genes. The double-frameshift strain produces only 25 to 35% of the normal level of GDH, whether measured as enzyme activity or as immunoprecipitable protein, but its level of GDH mRNA is normal. Although the modified enzyme is somewhat more heat-sensitive than the wild-type in vitro, its stability in vivo was found to be indistinguishable from that of the wild-type. It is concluded that the introduction of consecutive rare codons reduces the efficiency of translation of the mRNA. The possible mechanisms of such an effect are discussed.

Distant upstream regulatory sequences control the level of expression of the am (GDH) locus of Neurospora crassa

We have constructed deletions in the 5' noncoding sequences of the cloned Neurospora crassa am gene. Vectors with a truncated fragment of the am gene were used in transformation experiments to introduce the deletions into the chromosome by homologous recombination. Analysis of glutamate dehydrogenase (GDH) expression by enzyme assay and immunoblots, as well as Northern and dot blots of poly (A)+ RNA, in the deletion strains indicates that there are two upstream regulatory sequences that control the level of gene expression. The closer of these two elements (URSam alpha) is at approximately 1.4 kb upstream of the transcriptional start site. The second elements (URSam beta) is located between 2.1 and 3.2 kb upstream of the transcription start site. Deletion of either of these two elements reduces am expression to about 50% of the wild-type level. Deletion of both elements reduce am expression to from 5-16% of the wild-type level. Deletion of 1.1 kb of sequence just downstream of URSam alpha, which brings this element to within 300 bp of the transcription start site, had no effect on am expression. Likewise, deletion of 3.5 kb of sequence upstream of URSam beta had no effect on expression. None of these deletions had any effect on the expression of usg-1, a gene of unknown function that is transcribed in the same direction as the am gene, and which terminates about 3.5 kb upstream of the URSam beta element.

Nucleotide sequence and nuclear protein binding of the two regulatory sequences upstream of the am (GDH) gene in Neurospora

We have constructed a series of deletions in the 5' non-coding sequences of the cloned Neurospora crassa am gene which specifies NADP specific glutamate dehydrogenase. All of the deletions begin at -4.4 kb with respect to the am transcription start site and extend for various distances toward the am gene. Using vectors with a truncated fragment of the am gene, we introduced these deletions into the chromosome upstream of am by transformation. Analysis of glutamate dehydrogenase expression in strains with the deletion mutations confirmed that there are two upstream regulatory sequences (URS) that control the expression of the am gene. The more distal of these elements (URSam beta) has been limited to the 157 bp between -1924 and -2081 with respect to the start of am transcription. The proximal element (URSam alpha) was limited to the 97 bp between -1296 and -1393. The DNA sequence of the entire region was determined. Within the sequences that contain the URS elements several regions of homology with yeast UAS sequences were found. Gel mobility assays with DNA fragments containing the URS elements indicated that sequences in both elements are bound by nuclear proteins from Neurospora. The interaction of these proteins and the DNA fragments was found to be specific.

Relationship of vector insert size to homologous integration during transformation of Neurospora crassa with the cloned am (GDH) gene

We used lambda and plasmid vectors containing the am+ gene in an insert of from 2.7 to 9.1 kb, to transform am point mutant and deletion strains. A total of 199 transformants were examined with the potential to yield am+ transformants by homologous recombination. When we used vectors that had 9.1 kb of homology with the chromosomal DNA, 30% of the transformants obtained were the result of homologous recombination regardless of whether the vector was a lambda molecule, a circular plasmid, or a plasmid that had been linearized prior to transformation. When vectors with up to 5.1 kb of homology were used, very few transformants (1 of 89 tested) resulted from homologous recombination. Of a sample of 29 ectopic integration events obtained by transformation with the 9.1 kb fragment cloned in a lambda vector, 18 included a major part (usually almost all) of both arms of lambda with the entire Neurospora 9.1 kb insert between them. Four included only lambda long arm sequence together with an adjacent segment of the insert containing the am gene. The remaining seven were the result of multiple integrations. There was no evidence of circularization of the lambda vector prior to integration. All transformants that had multiple copies of the am gene appeared to be subject to the RIP process, which causes multiple mutations in duplicated sequences during the sexual cycle.

Transformation of Neurospora crassa with recombinant plasmids containing the cloned glutamate dehydrogenase (am) gene: evidence for autonomous replication of the transforming plasmid

We have characterized Neurospora crassa transformants obtained with plasmid pJR2, which consists of the Neurospora glutamate dehydrogenase (am) gene cloned in pUC8 and an am132 host strain which contains a deletion encompassing the cloned fragment. Every one of 33 transformants tested showed extreme meiotic instability: less than 1 or 2% am+ progeny were obtained in initial or successive backcrosses between am+ transformants and am132 or in intercrosses between am+ progeny. Furthermore, am+ progeny from backcrosses gave a high proportion of auxotrophic (am) mitotic segregants during vegetative growth. These results indicate that the am+ character is not stably integrated into chromosomal DNA in any of the transformants tested. Nuclear DNAs from six transformants were analyzed by Southern hybridization. All six transformants contained sequences homologous to pJR2. Four showed restriction fragments expected for unmodified pJR2, but most showed additional bands. Southern blots of undigested DNAs showed that the plasmid sequences are present predominantly in high-molecular-weight form (larger than 20 kilobases). Southern blots showed that auxotrophic (am) progeny from a backcross to am132 had lost restriction bands corresponding to free plasmid but retained additional bands, apparently integrated into chromosomal DNA in a nonfunctional manner. Considered together, these results are most reasonably interpreted as follows: recombinant plasmids containing the am+ gene can replicate autonomously in N. crassa, the free plasmids are present in oligomeric or modified form or both, and plasmid sequences also integrate at multiple sites in the deletion host but in a nonfunctional manner. An alternate interpretation--that tandem repeats of the plasmid are integrated into chromosomal DNA but eliminated during meiosis--cannot be completely excluded. However, stable integration of the am gene can be obtained under a variety of other conditions, viz., using the am gene cloned in a phage lambda vector (J. A. Kinsey and J. A. Rambosek, Mol. Cell. Biol. 4:117-122, 1984), using derivatives of pJR2, or using pJR2 to transform a frameshift mutant.

Transformation of Neurospora crassa with recombinant plasmids containing the cloned glutamate dehydrogenase (am) gene: evidence for autonomous replication of the transforming plasmid

We have characterized Neurospora crassa transformants obtained with plasmid pJR2, which consists of the Neurospora glutamate dehydrogenase (am) gene cloned in pUC8 and an am132 host strain which contains a deletion encompassing the cloned fragment. Every one of 33 transformants tested showed extreme meiotic instability: less than 1 or 2% am+ progeny were obtained in initial or successive backcrosses between am+ transformants and am132 or in intercrosses between am+ progeny. Furthermore, am+ progeny from backcrosses gave a high proportion of auxotrophic (am) mitotic segregants during vegetative growth. These results indicate that the am+ character is not stably integrated into chromosomal DNA in any of the transformants tested. Nuclear DNAs from six transformants were analyzed by Southern hybridization. All six transformants contained sequences homologous to pJR2. Four showed restriction fragments expected for unmodified pJR2, but most showed additional bands. Southern blots of undigested DNAs showed that the plasmid sequences are present predominantly in high-molecular-weight form (larger than 20 kilobases). Southern blots showed that auxotrophic (am) progeny from a backcross to am132 had lost restriction bands corresponding to free plasmid but retained additional bands, apparently integrated into chromosomal DNA in a nonfunctional manner. Considered together, these results are most reasonably interpreted as follows: recombinant plasmids containing the am+ gene can replicate autonomously in N. crassa, the free plasmids are present in oligomeric or modified form or both, and plasmid sequences also integrate at multiple sites in the deletion host but in a nonfunctional manner. An alternate interpretation--that tandem repeats of the plasmid are integrated into chromosomal DNA but eliminated during meiosis--cannot be completely excluded. However, stable integration of the am gene can be obtained under a variety of other conditions, viz., using the am gene cloned in a phage lambda vector (J. A. Kinsey and J. A. Rambosek, Mol. Cell. Biol. 4:117-122, 1984), using derivatives of pJR2, or using pJR2 to transform a frameshift mutant.

Transformation of Neurospora crassa with the cloned am (glutamate dehydrogenase) gene

We used DNA containing the am gene of Neurospora crassa, cloned in the lambda replacement vector lambdaL-47 (this clone is designated lambdaC-10), and plasmid vector subclones of this DNA to transform am deletion and point mutant strains. By means of subcloning, all sequences required for transformation to am prototrophy and expression of glutamate dehydrogenase have been shown to reside on a 2.5-kilobase BamHI fragment. We also characterized several am+ strains that were obtained after transformation with lambdaC-10. These strains showed Mendelian segregation of the am+ gene, although less than 50% of the transformed strains showed the normal linkage relationship of am with inl. In all cases tested, the strains had incorporated lambda DNA as well. The lambda DNA also showed a Mendelian segregation pattern. In one case, the incorporation of am DNA in a novel position was associated with a mutagenic event producing a strain with a very tight colonial morphology. In all cases in which the am+ gene had become the resident of a new chromosome, glutamate dehydrogenase was produced to only 10 to 20% of the wild-type levels.

Assay of cytotoxicity and mutagenicity of alkylating agents by using Neurospora spheroplasts

A system relying on the use of Neurospora crassa spheroplasts has been developed for the assay of cytotoxicity and mutagenicity of chemical compounds. Mutagenicity was assayed by using reversion of alleles in the am gene selected to recognize certain specified transitions and also undefined point mutations. Cytotoxicity was quantified by measuring a 'cytotoxicity parameter', m, which appears in the exponential function that fits the survival/dose curve for each compound (under standard incubation conditions). Of the compounds tested, nitrogen mustard (Cl(CH2)2 NMe(CH2)2Cl) was cytotoxic and non-mutagenic, and ethyl nitrosourea was highly mutagenic but not cytotoxic. Of the remaining compounds tested, methyl nitrosourea, butadiene diepoxide, and cis platin (cis diammonia platinum II chloride) all showed comparable mutagenicity per survivor, although the values of m covered a wide range. Differences were found between the different compounds in the effects of the uvs-2 allele on survival and on the preponderance of G to A transitions.

Transformation of Neurospora crassa with the cloned am (glutamate dehydrogenase) gene

We used DNA containing the am gene of Neurospora crassa, cloned in the lambda replacement vector lambdaL-47 (this clone is designated lambdaC-10), and plasmid vector subclones of this DNA to transform am deletion and point mutant strains. By means of subcloning, all sequences required for transformation to am prototrophy and expression of glutamate dehydrogenase have been shown to reside on a 2.5-kilobase BamHI fragment. We also characterized several am+ strains that were obtained after transformation with lambdaC-10. These strains showed Mendelian segregation of the am+ gene, although less than 50% of the transformed strains showed the normal linkage relationship of am with inl. In all cases tested, the strains had incorporated lambda DNA as well. The lambda DNA also showed a Mendelian segregation pattern. In one case, the incorporation of am DNA in a novel position was associated with a mutagenic event producing a strain with a very tight colonial morphology. In all cases in which the am+ gene had become the resident of a new chromosome, glutamate dehydrogenase was produced to only 10 to 20% of the wild-type levels.

Neurospora crassa mutants deficient in asparagine synthetase

Neurospora crassa mutants deficient in asparagine synthetase were selected by using the procedure of inositol-less death. Complementation tests among the 100 mutants isolated suggested that their alterations were genetically allelic. Recombination analysis with strain S1007t, an asparagine auxotroph, indicated that the mutations were located near or within the asn gene on linkage group V. In vitro assays with a heterokaryon indicated that the mutation was dominant. Thermal instability of cell extracts from temperature-sensitive strains in an in vitro asparagine synthetase assay determined that the mutations were in the structural gene(s) for asparagine synthetase.

Liposome-mediated genetic transformation of Neurospora crassa

Transformation of Neurospora crassa spheroplasts is reported for three different genes, using uncloned Neurospora DNA, both naked and encapsulated in synthetic phosphatidylserine liposomes. Whereas transformation by naked DNA is DNase-sensitive, that by liposomes is not. Per unit of transforming DNA, liposome transformation is significantly more efficient than that with naked DNA, ranging from 19x for the am gene to 41x for pyr-3. Levels of activity of pyr-3 and am transformants, and segregation data on pyr-3 transformation are given.

Direct selective procedure for isolating Neurospora mutants defective in nicotinamide adenine dinucleotide phosphate-specific glutamate dehydrogenase

A procedure has been developed for isolating nicotinamide adenine dinucleotide phosphate-specific glutamate dehydrogenase (am) mutants of Neurospora. Physiological, genetic, and enzymatic tests show that the new mutants are am alleles. Reconstruction tests and analysis of the new alleles show that the procedure yields a broad spectrum of lesions at the am locus. The isolation of am mutants by this technique appears to be related to the effect of am mutants on the control of the general permease.

Slow conformational changes of a Neurospora glutamate dehydrogenase studied by protein fluorescence

1. The NADP-dependent glutamate dehydrogenase of Neurospora crassa undergoes slow reversible structural transitions, with half-times in the order of a few minutes, between active and inactive states. The inactive state of the enzyme, which predominates at pH values below 7.0, has an intrinsic tryptophan fluorescence 25% lower than that of the active state, which predominates at pH values above 7.6. The inactive state can be activated either by an increase in pH or by addition of activators such as succinate. 2. The kinetics of the slow transitions that follow activating and inactivating rapid changes in conditions have been monitored by measurements of protein fluorescence. The results show that the slow reversible conformational change detected by the change in fluorescence is the rate-limiting process for enzyme activation and inactivation. 3. In both directions this conformational change follows apparent first-order kinetics and the rate constant is independent of protein concentration. These kinetics and published measurements of molecular weight are indicative of an isomerization process. 4. In both directions the changes show a large energy of activation and a large positive entropy of activation, consistent with a considerable disturbance of conformation in the transition state. 5. Comparisons of the fluorescence emission spectra of the active and inactive states indicate that the difference in fluorescence is produced by quenching, possibly intramolecular, in the inactive conformation. Iodide ions cause similar quenching. 6. In some mutationally altered forms of the enzyme comparable but modified conformational changes can be followed by protein fluorescence.

Single gene heterosis for alcohol dehydrogenase in maize: the nature of the subunit interaction

The products of the Adh 1 (F) allele which specifies an active enzyme, and the Adh 1 (Cm) allele which specifies a stable enzyme, interact in the heterodimer to give an active stable alcohol dehydrogenase. Investigations on the nature of the heterotic interaction are presented including comparisons of in vivo and in vitro synthesized heterodimers.

Human-mouse cell hybrids: a suggestion of structural mutation for dipeptidase-2 deficiency in mouse cells

The dipeptidase-2 enzyme is inactive in certain cultured cell lines from the mouse. In somatic cell hybrids between such deficient cells and diploid human fibroblasts, the mouse deficiency was complemented when the homologous human peptidase-A was retained. The results suggested that the murine peptidase deficiency was the result of a structural mutation, rather than a regulatory one.

Sequential changes in amylase isozymes during grain maturation in barley

Changes in amylase isozyme patterns on polyacrylamide gels were followed during maturation in grains of Deba Abed barley. Early stage seeds contained a single, high-mobility enzyme (Band A) which had an estimated molecular weight of 4.2×10(4) and a high activity with β-limit dextrin as a substrate. It was shown, by dissection, that Band A was confined to the aleurone layer and probably represented the initial product of amylase synthesis.This form was succeeded, in mid-course, by a less mobile form (Band B), a β-amylase with a molecular weight of approximately 1.3×10(5). Late-dough stage grains contained a complex of low-mobility β-amylase bands which were shown, by papain digestion, to be protein-bound forms of Band B.The changes are discussed on the basis of a unified series consisting of elaborated forms of the initial Band A type of activity.

Nature of the complementation products formed by a complementing mutant of neurospora crassa

The mutant am-14 produces no active nicotinamide adenine dinucleotide phosphate-linked glutamate dehydrogenase (GDH) and no protein showing immunological cross-reaction with the enzyme. Nevertheless, it shows complementation with several other am mutants in heterokaryons. Active GDH can be extracted from heterokaryons formed from am-14 and other mutants which, by themselves, produce more or less inactive varieties of the enzyme. The enzyme from am-14 + am-3 heterokaryons can be partially separated from am-3 mutant GDH on a diethylaminoethyl cellulose column. It is characterized by abnormally high thermolability and by a capacity for activation by glutamate. By the same procedure as brings about hybridization between mutant GDH proteins, it has been possible to recover enzyme with the properties of pure am-3 GDH from a partially purified am-14 + am-3 GDH preparation which was initially substantially free of unhybridized am-3 enzyme. This is interpreted as evidence that the active complementation product is a hybrid oligomer containing am-3 monomers and also am-14 monomers, the latter being unable to aggregate by themselves. Heterokaryons formed from am-14 and wild type produce GDH of abnormally high thermolability, presumably due to the formation of am-14 + am(+) hybrids.