Gene Interactions: the Mode of Action of the Suppressor of Acetate-requiring Mutants of Neurospora crassa

Strauss, Bernard S.; Pierog, Sophie

doi:10.1099/00221287-10-2-221

Cited by 37 publications

(11 citation statements)

References 9 publications

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“…Examples of suppression by both the above mechanisms are known. [2][3][4] In addition it has been suggested that certain suppressor genes might act by permitting the formation of new, effective enzymes to function for the absent or defective ones. In Neurospora crassa several cases of suppression are known in mutants which form an altered protein immunologically related to the enzyme tryptophan synthetase;' in the presence of the suppressor gene normal enzymatic activity appears.…”

mentioning

confidence: 99%

The Formation of a New Enzymatically Active Protein as a Result of Suppression

Crawford¹,

Yanofsky²

1959

Proc. Natl. Acad. Sci. U.S.A.

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confidence: 99%

The Formation of a New Enzymatically Active Protein as a Result of Suppression

Crawford¹,

Yanofsky²

1959

Proc. Natl. Acad. Sci. U.S.A.

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“…We therefore investigated the characteristics of this type of suppressor to determine whether a new type of gene interaction was represented. Our results indicate that in methionine biosynthesis, these particular suppressors act by preventing the formation of an inhibitor accumulated as a result of the original mutation to auxotrophy, an action similar in nature to that of the suppressors of the acetate-requiring mutants (Strauss & Pierog, 1954). In the course of our studies, some observations were and M7 respond to either cystathionine, homocysteine or methionine, but not to cysteine, these strains are not alleles.…”

Section: Introductionmentioning

confidence: 51%

“…Such an action by the s u gene might account for the restoration of cystathionase I and I1 activities observed in m e mutants by Fischer (1957). This scheme is analogous to that devised to account for the behaviour of the suppressors of the acetate-requiring mutants of Neurospora (Strauss & Pierog, 1954). It was supposed a t that time that the acetate suppressors lowered the production of an inhibitor (acetaldehyde) formed in excess as a result of the first mutation.…”

Section: Discussionmentioning

confidence: 99%

Gene Interactions Affecting Methionine Biosynthesis and the Response to S-methylcysteine by Mutants of Neurospora crassa

Tokuno

Strauss

Tsuda

1962

Journal of General Microbiology

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SUMMARYTwo non-allelic suppressors have been isolated which suppress nonallelic, leaky, met hionine-requiring mu tan t s blocked either be tween cysteine and cystathionine or between cystathionine and homocysteine. Strains carrying either suppressor gene in the presence of the me+ allele were stimulated by either cysteine or methionine, whereas the suppressed methionine-requiring mutants (me su) although stimulated by methionine were inhibited by cysteine. S-methylcysteine supported the growth of leaky methionine-requiring mutants when it was present as the sole sulphur source and it also stimulated the growth of suppressed methioninerequiring mutants inhibited by cysteine. Sulphate or cysteine inhibited the growth response of certain methionine-requiring mutants to Smethylcysteine. The incorporation of radioactive sulphate into protein methionine was inhibited to a greater extent by S-methylcysteine than was its incorporation into protein cysteine. The results suggest that the sulphur of S-methylcysteine is converted to methionine without prior conversion to cysteine and that the suppressors act by retarding the formation of an inhibitor which accumulates as a result of the primary mutation to methionine requirement.

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“…Pyruvic acid, AMC and C, condensation products which do not require complete oxidation accumulate in cultures of the SUC mutants (necessarily grown in the presence of nitrogen salts) because of the deficiency in the dicarboxylic acid catalyst required for C, fragment oxidation. The same accumulation products are produced in the suc mutants, where there is no immediate block to pyruvate oxidation as in the ac mutants (Strauss & Pierog, 1954), where there is a block in the oxidation of pyruvate : another illustration of the danger of using accumulations as evidence of genetic block (Adelberg, 1953). The relationship between succinate, a growth requirement, and AMC, a by-product of a true intermediate, is another case in which an end product controls the accumulation of a precursor (Strauss, 1955a, b ;Adelberg & Umbarger, 1953).…”

Section: Cl?mentioning

confidence: 99%

“…-f See (Strauss & Pierog, 1954). The at locus apparently acts only as a modifier to the SUC gene, preventing response of SUC strains to acetate.…”

Section: B S Straussmentioning

confidence: 99%

The Nature of the Lesion in the Succinate-requiring Mutants of Neurospora crassa: Interaction between Carbohydrate and Nitrogen Metabolism

Strauss

1956

Journal of General Microbiology

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SUMMARY: Mutants of Neurospora crmsa requiring dicarboxylic acids for an immediate growth response (SUC and at suc) oxidize acetate, and are inhibited by fluoroacetate with consequent citric acid accumulation to approximately the same extent as the wild-type. The concentration of nitrogen (as ammonium and nitrate salts) present in the conventional growth medium is inhibitory to the growth of these mutants and leads to an accumulation of acetylmethylcarbinol, pyruvic acid and a-ketoisovaleric acid. This inhibition is reduced and growth is stimulated by the addition of dicarboxylic acids or by diminution of the nitrogen present in 'minimal' medium. The addition of nitrogen salts to SUC mutants probably diverts dicarboxylic acids (already in short supply) from the catalysis of the oxidation of C, fragments via the tricarboxylic acid cycle to other reactions. This effect of nitrogen salts upsets the already precarious dicarboxylic acid balance of the suc mutants leading to a growth requirement and to the accumulation of intermediates.This investigation was begun because the existence of mutants of the ascomycete Neurospora crassa, which grow on minimal medium only after the addition of small quantities of dicarboxylic acids (succinate-requiring mutants), seemed difficult to reconcile with an apparent use of the tricarboxylic acid cycle for both synthesis and energy by Nearospora spp. (Lewis, 1948;Strauss, 1955a). Accepting the idea of a 'genetic block' in the cyclic metabolism of dicarboxylic acids by the succinate-requiring mutants seems to require the assumption that acetate is oxidized by some mechanism other than the tricarboxylic acid cycle (Krebs, Gurin & Eggleston, 1952) or that the 'genetic block' is not absolute. Since either of these explanations would be of interest, the properties of the succinate-requiring mutants have been studied in some detail.It now appears that the succinate-requiring mutants do use the tricarboxylic acid cycle, and that there is no enzymic block to the operation of the cycle. Dicarboxylic acids required to catalyse acetate oxidation are in short supply and, as a result, excess ammonium or nitrate nitrogen inhibits these mutants by withdrawing this limited supply of dicarboxylic acids for synthetic purposes. Inhibition by excess nitrogen is at least partly responsible for the failure of succinate-requiring mutants to grow normally on ' minimal medium' (Beadle & Tatum, 1945).It is the purpose of this paper to present the evidence for the interaction of carbohydrate and nitrogen metabolism in the succinate-requiring mutants, and to discuss briefly the implications of these findings.

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Gene Interactions: the Mode of Action of the Suppressor of Acetate-requiring Mutants of Neurospora crassa

Cited by 37 publications

References 9 publications

The Formation of a New Enzymatically Active Protein as a Result of Suppression

The Formation of a New Enzymatically Active Protein as a Result of Suppression

Gene Interactions Affecting Methionine Biosynthesis and the Response to S-methylcysteine by Mutants of Neurospora crassa

The Nature of the Lesion in the Succinate-requiring Mutants of Neurospora crassa: Interaction between Carbohydrate and Nitrogen Metabolism

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