Regulatory Mutants at the his1 Locus of Yeast

The his1 gene in Saccharomyces cerevisiae codes for phosphoribosyl transferase, an allosteric enzyme that catalyzes the initial step in histidine biosynthesis. Mutants that specifically alter the feedback regulatory function were isolated by selecting his1 prototrophic revertants that overproduce and excrete histidine. The prototrophs were obtained from diploids homoallelic for his1--7 and heterozygous for the flanking markers thr3 and arg6. Among six independently derived mutant isolates, three distinct levels of histidine excretion were detected. The mutants were shown to be second-site alterations mapping at the his1 locus by recovery of the original auxotrophic parental alleles. The double mutants, HIS1--7e, are dominant with respect to catalytic function but recessive in regulatory function. When removed from this his1--7 background, the mutant regulatory site (HIS1-e) still confers prototrophy but not histidine excretion. To yield the excretion phenotype, the primary and altered secondary sites are required in cis array. Differences in histidine excretion levels correlate with resistance to the histidine analogue, triazoalanine.     

Spontaneous and induced mutability or frameshift strains of Salmonella typhimurium carrying uvrB and polA mutations

Three strains Salmonella typhimurium carrying frameshift mutations affecting the histidine genes (hisC3076, hisD3052 and hisC207) showed increased sensitivity to mutagenesis by ICR-191 (as judged by measuring back mutation to prototrophy), if they were made deficient in excision repair by deleting the uvrB gene. One frameshift strain, hisC3076, also showed increased sensitivity to mutagenesis by ICR-191 when it carried either of two different polA alleles, whereas the hidD305 and hisD207 frameshifts reduced sensitivity to mutagenesis in the presence of these alleles. Studies of spontaneous back mutation to prototrophy revealed siginificant mutator effects of the polA1 mutation on reversion of the hisD3052 frameshift and of the polA3 mutation on reversion of the hisC3076 frameshift. Other smaller mutator effects of the polA alleles on reversion of the his mutations may also be present. In an attempt to explain the complex interactions between different polA alleles and different frameshift mutations, it is tentatively suggested that deletion frameshift may arise mainly during DNA replication, while addition frameshifts may arise mainly during post-replication repair.     

Reversion of an S49 cell cyclic AMP-dependent protein kinase structural gene mutant occurs primarily by functional elimination of mutant gene expression.

The regulatory subunits of cyclic AMP (cAMP)-dependent protein kinase from a dibutyryl cAMP-resistant S49 mouse lymphoma cell mutant, clone U200/65.1, and its revertants were visualized by two-dimensional polyacrylamide gel electrophoresis. Clone U200/65.1 co-expressed electrophoretically distinguishable mutant and wild-type subunits (Steinberg et al., Cell 10:381-391, 1977). In all 48 clones examined, reversion of the mutant to dibutyryl cAMP sensitivity was accompanied by alterations in regulatory subunit labeling patterns. Some spontaneous (3 of 11) and N-methyl-N'-nitro-N-nitrosoguanidine-induced (2 of 11) revertants retained mutant subunits, but these were altered in charge, degree of phosphorylation, or both. The charge alterations were consistent with single amino acid substitutions, suggesting that reversion was the result of second-site mutations in the mutant regulatory subunit allele that restored wild-type function, although not wild-type structure, to the gene product. The majority of spontaneous (8 of 11) and N-methyl-N'-nitro-N-nitrosoguanidine-induced (9 of 11) revertants and all of the revertants induced by ethyl methane sulfonate (14 of 14) and ICR191 (12 of 12) displayed only wild-type subunits. Dibutyryl cAMP-resistant mutants isolated from several of these revertants displayed new mutant but not wild-type subunits, suggesting that the revertant parent expresses only a single, functional regulatory subunit allele. The mutant regulatory subunit allele can, therefore, be modified in two general ways to produce revertant phenotypes: (i) by mutations that restore its wild-type function, and (ii) by mutations that eliminate its function.     

A Search for a General Phenomenon of Adaptive Mutability

The most prominent systems for the study of adaptive mutability depend on the specialized activities of genetic elements like bacteriophage Mu and the F plasmid. Searching for general adaptive mutability, we have investigated the behavior of Salmonella typhimurium strains with chromosomal lacZ mutations. We have studied 30 revertible nonsense, missense, frameshift, and insertion alleles. One-third of the mutants produced >=10 late revertant colonies (appearing three to seven days after plating on selective medium). For the prolific mutants, the number of late revertants showed rank correlation with the residual β-galactosidase activity; for the same mutants, revertant number showed no correlation with the nonselective reversion rate (from fluctuation tests). Leaky mutants, which grew slowly on selective medium, produced late revertants whereas tight nongrowing mutants generally did not produce late revertants. However, the number of late revertants was not proportional to residual growth. Using total residual growth and the nonselective reversion rate, the expected number of late revertants was calculated. For several leaky mutants, the observed revertant number exceeded the expected number. We suggest that excess late revertants from these mutants arise from general adaptive mutability available to any chromosomal gene.     

The induction and characterization of recessive suppressors of arg-2 in Schizophyllum commune

Summary Genetic analyses have been made to detect recessive suppressor mutations in eight prototrophic strains derived by treating an arginine dependent strain with hydroxylamine. The results indicate that one strain possesses a recessive suppressor, su-1, which maps outside the arg-2 locus and is capable of suppressing auxotrophy conferred by the arg-2 mutation. This suppressor is incapable of suppressing auxotrophy conferred by eight other loci. Prototrophy in the remaining seven strains resulted from either intragenic suppression, reversion, or from a suppressor mutation that is closely linked to the arg-2 locus. The results of heterokaryotic allelic tests with the seven strains indicate that the mutation to prototrophy is recessive.     

The frequency of reversion of the opaque2 locus mutable alleles controlled by the Bg-rbg system of mobile elements in maize

Maize lines differing in the frequency of reversion of the opaque2 (o2) mutable alleles controlled by the system of Bg-rbg transportable elements were studied. In the presence of the Bg regulatory element, these alleles can revert to normal. When reversion occurs prior to the first division of the primary endosperm nucleus, either phenotypically normal kernels or whole endosperm revertants (WER) develop. Low frequency of whole endosperm revertant formation may be produced by different genetic mechanisms. The frequency of WER formation was shown to nonlinearly depend on the dose of the Bg-hf regulatory element. A dose increase from two to three failed to cause an essential increase in the number of revertants. The regulatory elements Bg-lf and Bg-hf differed in ability to induce excision of the receptor element at the same dose. The frequency of reversion of the receptive alleles was shown to be regulated by epigenetic mechanisms so that high frequency of reversion of receptive alleles requires preliminary premeiotic association between the regulatory and receptor elements. The inheritance of the maize alleles o2-hf and o2-lf proved to be similar to that an3 mutable alleles in petunia.     

ABI1 protein phosphatase 2C is a negative regulator of abscisic acid signaling.

The plant hormone abscisic acid (ABA) is a key regulator of seed maturation and germination and mediates adaptive responses to environmental stress. In Arabidopsis, the ABI1 gene encodes a member of the 2C class of protein serine/threonine phosphatases (PP2C), and the abi1-1 mutation markedly reduces ABA responsiveness in both seeds and vegetative tissues. However, this mutation is dominant and has been the only mutant allele available for the ABI1 gene. Hence, it remained unclear whether ABI1 contributes to ABA signaling, and in case ABI1 does regulate ABA responsiveness, whether it is a positive or negative regulator of ABA action. In this study, we isolated seven novel alleles of the ABI1 gene as intragenic revertants of the abi1-1 mutant. In contrast to the ABA-resistant abi1-1 mutant, these revertants were more sensitive than the wild type to the inhibition of seed germination and seedling root growth by applied ABA. They also displayed increases in seed dormancy and drought adaptive responses that are indicative of a higher responsiveness to endogenous ABA. The revertant alleles were recessive to the wild-type ABI1 allele in enhancing ABA sensitivity, indicating that this ABA-supersensitive phenotype results from a loss of function in ABI1. The seven suppressor mutations are missense mutations in conserved regions of the PP2C domain of ABI1, and each of the corresponding revertant alleles encodes an ABI1 protein that lacked any detectable PP2C activity in an in vitro enzymatic assay. These results indicate that a loss of ABI1 PP2C activity leads to an enhanced responsiveness to ABA. Thus, the wild-type ABI1 phosphatase is a negative regulator of ABA responses.     

Allelic Complementation in the First Gene for Histidine Biosynthesis in SACCHAROMYCES CEREVISIAE. I. Characteristics of Mutants and Genetic Mapping of Alleles

A number of his1 mutants were tested for suppressibility, for reversion by EMS, ICR-170, and nitrous acid, for their allelic complementation response, and for their temperature sensitivity and osmotic remediability. None of 52 mutants tested was suppressible by a known ochre suppressor. This is a very surprising result compared with other studies of suppressibility in yeast and suggests that another function essential to the cell is associated with the his1 gene product, the polarity effect of a nonsense mutation destroying the activity of the his1 enzyme and this second function.Sixty-four his1 alleles were ordered by allelic mapping methods utilizing gamma rays, X-rays, and MMS. The three maps agree well in placement of alleles and have been oriented on chromosome V of yeast with respect to the centromere. The 18 noncomplementing alleles are localized in the distal half of the gene, whereas the complementing alleles are distributed more or less evenly. Mutations which revert to feedback resistance map in the proximal end. Also at this end are mutations having a very high X-ray or MMS induced homoallelic reversion rate. This suggests that a number of missense mutations can occur in this region which result in innocuous amino acid substitutions in the enzyme. One X-ray map unit is estimated to correspond to about 131 base pairs or 43 amino acids, in agreement with results for the cytochrome-c protein obtained by Parker and Sherman (1969).     

Spontaneous mutability in UV-sensitive excision-defective strains of Saccharomyces.

The genes RAD1, RAD2, RAD3 and RAD4 encode enzymes in the pathway leading to excision repair of UV-induced DNA damage in Saccharomyces cerevisiae. Four mutant alleles of these loci (rad1-1, rad2-2, rad3-12, and rad4-3) were studied for their effect on spontaneous reversion rate to lysine and histidine independence, by means of the 1000-compartment fluctuation test of von Borstel, Cain and Steinberg. Of these four excision-defective alleles, only rad3-12 was found to substantially increase the spontaneous reversion rate of the nonsense-suppressible lys1-1 allele, both through locus reversion as well as by forward mutation at one of eight suppressor loci. Similarly, only rad3-12 conferred a considerable increase in the reversion frequency of the missense his1-7 mutant. As the RAD3 gene product is believed to mediate the first step in the excision-repair pathway, it is assumed that spontaneous lesions in the rad3 strain are channelled into a mutagenic repair pathway, thus accounting for the enhanced spontaneous mutation rate.     

Selective systems for obtaining recessive ribosomal suppressors in saccharomycete yeasts

Recessive mutations only occurring in two genes (ribosomal suppressors sup1 and sup2) can be obtained using special selective system. We demonstrate that the absolute selectivity of the system is based on selection for simultaneous reversions to prototrophy in mutants requiring adenine and histidine in haploids marked by two different nonsense mutations--his7-1 (UAA) and ade1-14 (UGA, this being identified in the present study). In support to this conclusion, we developed an analogous system utilising his7-1 (UAA) and lys2-87 (UGA). The selectivity of the system is shown to be influenced both by the choice of nonsense alleles and by genotypic background.     

A cis/trans Test of the Effect of the First Enzyme for Histidine Biosynthesis on Regulation of the Histidine Operon

Previous studies showed that when triazolalanine was added to a derepressed culture of a histidine auxotroph, repression of the histidine operon occurred as though histidine had been added (6). However, when triazolalanine was added to a derepressed culture of a strain with a mutation in the first gene of the histidine operon which rendered the first enzyme for histidine biosynthesis resistant to inhibition by histidine, repression did not occur. The studies reported here represent a cis/trans test of this effect of mutations to feedback resistance. Using specially constructed merodiploid strains, we were able to show that the wild-type allele is dominant to the mutant (feedback resistant) allele and that the effect operates in trans. We conclude that the enzyme encoded by the first gene of the histidine operon exerts its regulatory effect on the operon not by acting locally at its site of synthesis, but by acting as a freely diffusible protein.     

A regulatory locus,Hdc-e,determines the response of mouse kidney histidine decarboxylase to estrogen

Levels of histidine decarboxylase (HDC; EC 4.1.1.22) activity in female mouse kidney are modulated by estrogen (administered as implanted pellets). In some inbred strains HDC activity is induced by estrogen, while in others the enzyme is repressed. Immunoprecipitation with an anti-fetal rat HDC antiserum has shown that induction and repression of HDC levels are due to changes in enzyme concentration. Segregation analysis has identified a single additively inherited regulatory locus, Hdc-e, which determines the response to estrogen. The allele Hdc-eb (C57BL/10) determines induction, and the allele Hdc-ed (DBA/2) determines repression. Preliminary evidence indicates cosegregation of Hdc-e alleles with alleles of another regulatory locus, Hdc-c (determining kidney HDC concentration), and therefore putative linkage of Hdc-e with the HDC gene complex on chromosome 2. This is the first report of a mammalian regulatory gene controlling two opposite mechanisms, induction and repression in response to a single effector.     

Molecular characterization of a nonautonomous transposable element (dTph1) of petunia.

An insertion sequence of 283 base pairs has been isolated from the DFR-C gene (dihydroflavonol-4-reductase) of petunia. This insert was found only in a line unstable for the An1 locus (anthocyanin 1, located on chromosome VI) and not in fully pigmented progenitor and revertant lines or in stable white derivative lines. This implies that the An1 locus encodes the DFR-C gene. The unstable An1 system in the line W138 is known to be a two-element system, the autonomous element being located on chromosome I. In the presence of the autonomous element, W138 flowers exhibit a characteristic pattern of red revertant spots and sectors on a white background. In the absence of the autonomous element, the W138 allele gives rise to a stable recessive (white) phenotype. Sequence analysis of progenitor, unstable, and revertant alleles revealed dTph1 to contain perfect terminal inverted repeats of 12 base pairs. In DFR-C, it is flanked by an 8-base pair target site duplication. Sequences homologous to dTph1 are present in at least 50 copies in the line W138. Sequence analysis of An1 revertant alleles indicated that excision, including removal of the target site duplication, is required for reversion to the wild-type phenotype. Derivative stable recessive alleles showed excision of dTph1 and a rearrangement of the target site duplication. dTph1 is the smallest transposable element described to date that is still capable of transposition. The use of dTph1 in tagging experiments and subsequent gene isolation is discussed.     

Antipolarity in the ilv operon of Escherichia coli K-12

The genes governing three of the enzymes of the isoleucine-valine biosynthetic pathway form the operon: operator-ilvA-ilvD-ilvE. The enzymes are: ilvA, l-threonine deaminase; ilvD, dihydroxy acid dehydrase; and ilvE, transaminase B. A nonsense mutation in the ilvD gene (D-ochre) and a nonsense mutation in the ilvE gene (E-amber) affect the properties of the proximal gene product, l-threonine deaminase (TD), in addition to inactivating the enzymes produced by the genes in which the mutations have occurred. The D-ochre mutation causes TD to move in diffusion and gel filtration experiments as though it were 30% smaller than the wild-type enzyme. The E-amber mutation causes TD to move in similar experiments as though it were much larger than the wild-type enzyme. Both mutations completely abolish the sensitivity of TD to l-isoleucine, the normal feedback inhibitor of the wild-type enzyme. The effects of the nonsense mutations on TD can be reversed in three ways: by genetic reversion of the D-ochre mutation; by treatment of the altered enzymes with 3.0 m urea; and by forming a heterozygous diploid, containing the wild-type allele as well as the mutant allele of ilvD or ilvE. The results suggest that the subunits of TD undergo abnormal aggregation in the presence of the partial polypeptides produced by the mutant alleles of ilvD or ilvE; multi-enzyme aggregates in extracts of wild type, however, could not be detected.     

trans-Recessive mutation in the first structural gene of the histidine operon that results in constitutive expression of the operon.

The first enzyme for histidine biosynthesis, encoded in the hisG gene, is involved in regulation of expression of the histidine operon in Salmonella typhimurium. The studies reported here concern the question of how expression of the histidine operon is affected by a mutation in the hisG gene that alters the allosteric site of the first enzyme for histidine biosynthesis, rendering the enzyme completely resistant to inhibition by histidine. The intracellular concentrations of the enzymes encoded in the histidine operon in a strain carrying such a mutation on an episome and missing the chromosomal hisG gene are three- to fourfold higher than in a strain carrying a wild-type hisG gene on the episome. The histidine operon on such a strain fails to derepress in response to histidine limitation and fails to repress in response to excess histidine. Furthermore, utilizing other merodiploid strains, we demonstrate that the wild-type hisG gene is trans dominant to the mutant allele with respect to this regulatory phenomenon. Examination of the regulation of the histidine operon in strains carrying the feedback-resistant mutation in an episome and hisT and hisW mutations in the chromosome showed that the hisG regulatory mutation is epistatic to the hisT and hisW mutations. These data provide additional evidence that the first enzyme for histidine biosynthesis is involved in autogenous regulation of expression of the histidine operon.     

Ultraviolet-Induced Reversion of cyc1 Alleles in Radiation Sensitive Strains of Yeast. II. rev2 Mutant Strains

The range of specificity of the rev2-1 mutation, an allele that reduces the frequency of ochre revertants induced by UV in Saccharomyces cerevisiae (LEMONTT 1971a), has been investigated by examining its influence on the reversion of eleven well-defined and contrasting cyc1 mutations. We have shown, in support of a suggestion of LEMONTT (1971a), that the REV2 gene product is concerned only with the reversion of ochre alleles; it plays virtually no role in the reversion of amber, missense or frameshift mutations. We have also shown that its effect is specific and confined to only some highly revertible ochre alleles. The REV2 gene product appears to enhance reversion at these sites by facilitating the conversion of two otherwise nonmutagenic photo-products into a single premutational lesion. UV-induced killing of rev2-1 strains was found to be significantly greater on fermentable rather than on nonfermentable media.     

Intragenic recombination in maize: pollen analysis methods and the effect of parental adh1 isoalleles

The ability to stain mature pollen grains for the presence of alcohol dehydrogenase (ADH) activity permits the quantitation of ADH( +) gametophytes at frequencies below 10(-6). This resolution allows reversion and genetic fine structure analyses. The rationale of pollen analysis follows Nelson's prototype studies with waxy. As with the waxy gene, revertant frequencies for seven Adh1-deficient ( Adh1(-)) alleles appear to be in excess of microbially derived expectations. Each of the seven Adh1(-) alleles were derived from one of three naturally occurring isoalleles. Based on Schwartz's protein level characterizations of the mutants' products, it was anticipated that the seven Adh1(-) alleles should recombine to yield ADH(+) cistrons in certain pairwise combinations. This expectation was not met. The parental "wild-type" isoalleles from which the mutants were derived appear to be structurally divergent. The discussion interprets these data in view of understanding naturally occurring cistronic variation.