Interactions of ribosomal antibiotics and informational suppressors of Aspergillus nidulans

Strains of Aspergillus nidulans containing informational suppressors were grown on medium containing antibiotics known to affect protein synthesis at the ribosomal level. These strains reacted in the anticipated manner: presumed ribosomal suppressors suaA101, suaA105, suaC109 and sua-115 were sensitive or even hypersensitive to aminoglycoside antibiotics, whereas presumed tRNA-like suppressors suaB111, suaD103 and D108 were only slightly sensitive or wild-type in response. Hygromycin and paromomycin were the most useful antibiotics. All the antibiotics reduced the colony radial growth rate, Kr, increased the lag phase and produced wrinkled morphology. Hygromycin was the most toxic. Resistant sectors were produced on paromomycin and hygromycin. The selective action of 'misreading' antibiotics on suaA and suaC strains is further evidence that these are ribosomal suppressors, whereas suaB and suaD may code for altered tRNA molecules. The results imply that hygromycin or paromomycin could be used for isolating ribosomal suppressors.     

Suppression of erythromycin resistance in ery-M1 mutants of Chlamydomonas reinhardi

Summary After mutagenesis of the erythromycin-resistant Chlamydomonas reinhardi strain ery-M1b, four mutants were isolated, each more sensitive to erythromycin than ery-M1b. All four mutants carry the original ery-M1b mutation which confers resistance and a separate mutation (es) which partially suppresses resistance. The mutants are designated es5ery-M1b, es101ery-M1b, es105ery-M1b, and es115ery-M1b. The suppressor mutations represent at least three different Mendelian loci. The suppressor es101 is located on the same linkage group as ery-M1, while the other suppressors are not linked to ery-M1.Although some of these suppressors can also mask the erythromycin resistance of ery-M2 strains, none had any effect on the non-Mendelian mutant ery-Ula. In addition, each suppressor affected the cross-resistance of ery-M1 mutants to other antibiotics. At least two of the changes in cross-resistance are due solely to the suppressor.Chloroplast ribosomes from cells carrying es5ery-M1b, es101ery-M1b, and es115ery-M1b have a greater affinity for ¹⁴C-erythromycin in vitro than those from ery-M1b. The degree of affinity depends upon the concentration of KCl.Each of these Mendelian suppressors probably affects a chloroplast ribosome function. Hence, a number of nuclear genes must play roles in the biogenesis of the chloroplast ribosome in Chlamydomonas reinhardi.     

Mutations in genes encoding extracellular matrix proteins suppress the emb-5 gastrulation defect in Caenorhabditis elegans

The second division of the gut precursor E cells is lethally accelerated during Caenorhabditis elegans gastrulation by mutations in the emb-5 gene, which encodes a presumed nuclear protein. We have isolated suppressor mutations of the temperature-sensitive allele emb-5(hc61), screened for them among dpy and other mutations routinely used as genetic markers, and identified eight emb-5 suppressor genes. Of these eight suppressor genes, at least four encode extracellular matrix proteins, i.e., three collagens and one proteoglycan. The suppression of the emb-5 gastrulation defect seemed to require the maternal expression of the suppressors. Phenotypically, the suppressors by themselves slowed down early embryonic cell divisions and corrected the abnormal cell-division sequence of emb-5 mutant embryos. We propose an indirect stress-response mechanism to be the main cause of the suppression because: (1) none of these suppressors is specific, either to particular temperature-sensitive emb-5 alleles or to the emb-5 gene; (2) suppressible alleles of genes, reported here or elsewhere, are temperature sensitive or weak; (3) the suppression is not strong but marginal; (4) the suppression itself shows some degree of temperature dependency; and (5) none of the extracellular matrix proteins identified here is known to be expressed in oocytes or early embryos, despite the present observation that the suppression is maternal. Received: 19 August 1997 / Accepted: 11 December 1997     

Dominant and recessive informational suppressors of a missense mutation in Coprinus

Summary Twenty-one suppressor gene mutations which suppress the met-5.1 missense mutation of Coprinus were separated into six groups (A-F) on the basis of dominance or recessiveness, linkage to the met-5 locus, comlementation in heterozygous cells and growth behaviour. The actual number of suppressor loci could not be determined because crosses between suppressed mutants were inviable. The allele specificity of group A, C, D and F suppressors was confirmed by appropriate crosses. Group B and E suppressors were not tested because of close linkage to the met-5 locus. No evidence for functional suppression of met-5 mutations was obtained thus it is likely that all the suppressors cause translational corelation of met-5.1. Suppressors in four groups (C-F) have properties expected of tRNA structural gene mutations: the group C mutation is dominant, the other mutations are recessive but do not complement in heterozygous cells. The relative efficiencies of the tRNA species involved was assessed by comparing the degree to which the different sup ⁺ mutations depressed the growth rate on methionine supplemented medium. The dominant mutation depressed growth to the greatest extent and is, therefore, the most efficient suppressor. The least efficient suppressors did not depress growth at all. When growth was compared on minimal medium it was found that the more efficient the suppressor the less well it restored growth. The mutations in groups A and B depressed growth more than the tRNA mutations but affect some other component in translation because they are recessive and complement normally. It is suggested that they may act to alter tRNA modifying enzymes.     

Suppression of XopQ–XopX-induced immune responses of rice by the type III effector XopG

Effectors that suppress effector-triggered immunity (ETI) are an essential part of the arms race in the co-evolution of bacterial pathogens and their host plants. Xanthomonas oryzae pv. oryzae uses multiple type III secretion system (T3SS) secreted effectors such as XopU, XopV, XopP, XopG, and AvrBs2 to suppress rice immune responses that are induced by the interaction of two other effectors, XopQ and XopX. Here we show that each of these five suppressors can interact individually with both XopQ and XopX. One of the suppressors, XopG, is a predicted metallopeptidase that appears to have been introduced into X. oryzae pv. oryzae by horizontal gene transfer. XopQ and XopX interact with each other in the nucleus while interaction with XopG sequesters them in the cytoplasm. The XopG E76A and XopG E85A mutants are defective in interaction with XopQ and XopX, and are also defective in suppression of XopQ–XopX-mediated immune responses. Both mutations individually affect the virulence-promoting ability of XopG. These results indicate that XopG is important for X. oryzae pv. oryzae virulence and provide insights into the mechanisms by which this protein suppresses ETI in rice.     

Frameshift Suppression in SACCHAROMYCES CEREVISIAE. V. Isolation and Genetic Properties of Nongroup-Specific Suppressors

Two classes of frameshift suppressors distributed at 22 different loci were identified in previous studies in the yeast Saccharomyces cerevisiae. These suppressors exhibited allele-specific suppression of +1 G:C insertion mutations in either glycine or proline codons, designated as group II and group III frameshift mutations, respectively. Genes corresponding to representative suppressors of each group have been shown to encode altered glycine or proline tRNAs containing four base anticodons.—This communication reports the existence of a third class of frameshift suppressor that exhibits a wider range in specificity of suppression. The suppressors map at three loci, suf12, suf13, and suf14, which are located on chromosomes IV, XV, and XIV, respectively. The phenotypes of these suppressors suggest that suppression may be mediated by genes other than those encoding the primary structure of glycine or proline tRNAs.     

Frameshift Suppression in SACCHAROMYCES CEREVISIAE. III. Isolation and Genetic Properties of Group III Suppressors

Suppressors of ICR-induced mutations that exhibit behavior similar to bacterial frameshift suppressors have been identified in the yeast Saccharomyces cerevisiae. The yeast suppressors have been divided into two groups. Previous evidence indicated that suppressors of one group (Group II: SUF1, SUF3, SUF4, SUF5 and SUF6) represent mutations in the structural genes for glycyl-tRNA's. Suppressors of the other group (Group III: SUF2 and SUF7) were less well characterized. Although they suppressed some ICR-revertible mutations, they failed to suppress Group II frameshift mutations. This communication provides a more thorough characterization of the Group III suppressors and describes the isolation and properties of four new suppressors in that group (SUF8, SUF9, SUF10 and suf11).——In our original study, Group III suppressors were isolated as revertants of the Group III mutations his4–712 and his4–713. All suppressors obtained as ICR-induced revertants of these mutations mapped at the SUF2 locus near the centromere of chromosome III. Suppressors mapping at other loci were obtained in this study by analyzing spontaneous and UV-induced revertants of the Group III mutations. SUF2 and SUF10 suppress both Group III his4 mutations, whereas SUF7, SUF8, SUF9 and suf11 suppress his4–713, but not his4–712. All of the suppressors except suf11 are dominant in diploids homozygous for his4-713. The suppressors fail to suppress representative UAA, UAG and UGA nonsense mutations.——SUF9 is linked to the centromere of chromosome VI, and SUF10 is linked to the centromere of chromosome XIV. A triploid mapping procedure was used to determine the chromosome locations of SUF7 and SUF8. Subsequent standard crosses revealed linkage of SUF7 to cdc5 on chromosome XIII and linkage of SUF8 to cdc12 and pet3 on chromosome VIII.     

Suppression of the acuH13 and acuH31 nonsense mutations in the carnitine/acylcarnitine translocase (acuH) gene of Aspergillus nidulans by the G265S substitution in the domain 2 of the release factor eRF1

A search for suppressors of the carnitine/acylcarnitine translocase (CACT) deficiency in Aspergillus nidulans permitted the identification of the suaE7 mutation, mapping at a new translational suppressor (suaE) gene. The suaE gene is essential in A. nidulans and encodes the eukaryotic release factor 1 (eRF1). The suaE7 mutation suppresses two acuH alleles (acuH13 and acuH31), both carrying nonsense mutations in the CACT encoding gene that involve the replacement of a CAG (Gln) codon with a premature TAG stop codon. In contrast, the suaE7 gene does not suppress the acuH20 amber nonsense mutation involving a TGG-->TAG change. The phenotype associated to the suaE7 mutation strictly resembles that of mutants at the suaA and suaC genes, two translational suppressor genes previously identified, suggesting that their gene products might functionally interact in translation termination. Sequencing of the suaE7 gene allowed the identification of a mutation in the domain 2 of the omnipotent class-1 eukaryotic release factor involving the Gly265Ser substitution in the A. nidulans eRF1. This mutation creates a structural context unfavourable for normal eRF binding that allows the misreading of stop codons by natural suppressor tRNAs, such as the tRNAs(Gln). Structural analysis using molecular modelling of A. nidulans eRF1 domain 2 bearing the G265S substitution and computer simulation results suggest that this mutation might impair the necessary conformational changes in the eRF1 to optimally recognize the stop codon and simultaneously interact with the peptidyl transferase centre of the 60S ribosomal subunit.     

Mutations in genes encoding extracellular matrix proteins suppress the emb-5 gastrulation defect in Caenorhabditis elegans

The second division of the gut precursor E cells is lethally accelerated during Caenorhabditis elegans gastrulation by mutations in the emb-5 gene, which encodes a presumed nuclear protein. We have isolated suppressor mutations of the temperature-sensitive allele emb-5(hc61), screened for them among dpy and other mutations routinely used as genetic markers, and identified eight emb-5 suppressor genes. Of these eight suppressor genes, at least four encode extracellular matrix proteins, i.e., three collagens and one proteoglycan. The suppression of the emb-5 gastrulation defect seemed to require the maternal expression of the suppressors. Phenotypically, the suppressors by themselves slowed down early embryonic cell divisions and corrected the abnormal cell-division sequence of emb-5 mutant embryos. We propose an indirect stress-response mechanism to be the main cause of the suppression because: (1) none of these suppressors is specific, either to particular temperature-sensitive emb-5 alleles or to the emb-5 gene; (2) suppressible alleles of genes, reported here or elsewhere, are temperature sensitive or weak; (3) the suppression is not strong but marginal; (4) the suppression itself shows some degree of temperature dependency; and (5) none of the extracellular matrix proteins identified here is known to be expressed in oocytes or early embryos, despite the present observation that the suppression is maternal.     

Long range control circuits within mitochondria and between nucleus and mitochondria

Summary In the preceding paper of this series (Dujardin et al. 1980a) we described general methods of selecting and genetically characterizing suppressor mutations that restore the respiratory capacity of mit ^- mitochondrial mutations. Two dominant nuclear (NAM1-1 and NAM2-1) and one mitochondrial (mim2-1) suppressors are more extensively studied in this paper. We have analysed the action spectrum of these suppressors on 433 mit ^- mutations located in various mitochondrial genes and found that they preferentially alleviate the effects of mutations located within intron open reading frames of the cob-box gene. We conclude that these suppressors permit the maturation of cytochrome b mRNA by restoring the synthesis of intron encoded protein(s) catalytically involved in splicing i.e. mRNA-maturase(s) (cf. Lazowska et al. 1980). NAM1-1 is allele specific and gene non-specific: it suppresses mutations located within different introns. NAM2-1 and mim2-1 are intron-specific: they suppress mutations all located in the same (box7) intron of the cobbox gene. Analyses of cytochrome absorption spectra and mitochondrial translation products of cells in which the suppressors are associated with various other mit ^- mutations show that the suppressors restore cytochrome b and/or cytochrome oxidase (cox 1) synthesis, as expected from their growth phenotype. This suppression is, however, only partial: some new polypeptides characteristic of the mit ^- mutations can be still detected in the presence of suppressor. Interestingly enough when box7 specific suppressors NAM2-1 and mim2-1 are associated with a complete cob-box deletion (leading to a total deficiency of cytochrome b and oxidase) partial restoration of cox I synthesis is observed while cytochrome b is still totally absent. These results show that in strains carrying NAM2-1 or mim2-1 the presence of cytochrome b gene is no longer required for the expression of the oxi3 gene pointing out to the possibility of a mutational switch-on of silent genes, whether mitochondrial, mim2-1, or nuclear, NAM2-1. This switch-on would permit the synthesis of an active maturase acting as a substitute for the box7 maturase in order to splice the cytochrome b and oxidase mRNAs.     

Design of Ca2+‐independent Staphylococcus aureus sortase A mutants

The catalytic activity of Staphylococcus aureus sortase A (SaSrtA) is dependent on Ca²⁺, because binding of Ca²⁺ to Glu residues distal to the active site stabilizes the substrate binding site. To obtain Ca²⁺‐independent SaSrtA, we substituted two Glu residues in the Ca²⁺‐binding pocket (Glu¹⁰⁵ and Glu¹⁰⁸). Although single mutations decreased SaSrtA activity, mutations of both Glu¹⁰⁵ and Glu¹⁰⁸ resulted in Ca²⁺‐independent activity. Kinetic analysis suggested that the double mutations affect the substrate binding site, without affecting substrate specificity. This approach will allow us to develop SaSrtA variants suitable for various applications, including in vivo site‐specific protein modification and labeling. Biotechnol. Bioeng. 2012; 109: 2955–2961. © 2012 Wiley Periodicals, Inc.     

Lethal mutations defining 112 complementation groups in a 4.5?Mb sequenced region of Caenorhabditis elegans chromosome III

The central gene cluster of chromosome III was one of the first regions to be sequenced by the Caenorhabditis elegans genome project. We have performed an essential gene analysis on the left part of this cluster, in the region around dpy-17III balanced by the duplication sDp3. We isolated 151 essential gene mutations and characterized them with regard to their arrest stages. To facilitate positioning of these mutations, we generated six new deficiencies that, together with preexisting chromosomal rearrangements, subdivide the region into 14 zones. The 151 mutations were mapped into these zones. They define 112 genes, of which 110 were previously unidentified. Thirteen of the zones have been anchored to the physical sequence by polymerase chain reaction deficiency mapping. Of the 112 essential genes mapped, 105 are within these 13 zones. They span 4.2 Mb of nucleotide sequence. From the nucleotide sequence data, 920 genes are predicted. From a Poisson distribution of our mutations, we predict that 234 of the genes will be essential genes. Thus, the 105 genes constitute 45% of the estimated number of essential genes in the physically defined zones and between 2 and 5% of all essential genes in C. elegans. Received: 23 April 1998 / Accepted: 18 August 1998     

Long range control circuits within mitochondria and between nucleus and mitochondria

Summary To uncover the functional circuitry both within the mitochondrial genome and between the mitochondrial and the nuclear genome, we have developed a general method for selecting and characterizing genetically suppressor mutations that restore the respiratory capacity of mit ^- mitochondrial mutants.Several hundreds of pseudo-wild type revertants due to a second unlinked mutation which suppresses a target mit ^- mutation were isolated. The suppressor mutations were found located either in the nuclear (abbreviated NAM for nuclear accommodation of mitochondria) or in the mitochondrial genome (abbreviated MIM for mitochondrial-mitochondrial interaction).The specificity of action of various suppressors upon some 250 different mit ^- mutations located in several genes was tested. According to this specificity of action, suppressors were subdivided into two major classes: allele specific or gene specific suppressors. Because the cob-box mitochondrial gene has a mosaic organization, we were able to find a novel third class of extragenic suppressors specific for mit ^- mutations within the introns of this gene.Four examples of suppressors showing various specificities of action illustrate our approach. (1) a nuclear gene controlling specific alleles of different mitochondrial genes; (2) a nuclear gene controlling selectively one intron of a split mitochondrial gene; (3) a mitochondrial gene controlling specific alleles of different mitochondrial genes; (4) a region in one complex mitochondrial gene which controls selectively one intron of another split mitochondrial gene.Different mechanisms of suppression are discussed stressing the alleviation of splicing deficiencies of intron mutations.     

Frameshift Suppression in SACCHAROMYCES CEREVISIAE. II. Genetic Properties of Group II Suppressors

Suppressors of ICR-induced mutations that exhibit behavior similar to bacterial frameshift suppressors have been identified in the yeast Saccharomyces cerevisiae. The yeast suppressors have been divided into two groups. One of these groups (Group II: SUF1, SUF3, SUF4, SUF5 and SUF6) appears to include a set of informational suppressors in which the vehicle of suppression is glycyl-tRNA. Some of the genetic properties of Group II suppressors are described in this communication.——Corevertants of the Group II frameshift mutations his4–519 and leu2–3 have been characterized to determine the spectrum of reversion events induced by the frameshift mutagen ICR-170. Seventythree ICR-induced corevertants were analyzed. With the exception of one corevertant, which carried an allele of SUF1, all carried alleles of SUF3 or SUF5. SUF1, SUF3, SUF4 and SUF6 were represented among spontaneous and UV-induced corevertants. In the course of these experiments one of the suppressors was mapped. SUF5, the probable structural gene for tRNA^GLY1, is located between ade2 and ade9 on chromosome XV.——SUF1, SUF4 and SUF6 have novel properties and comprise a distinct subset of suppressors. Although these suppressors show no genetic linkage to each other, they share several common features including lethality in haploid pairwise combinations, reduced tRNA^GLY3 isoacceptor activity and increased efficiency of suppression in strains carrying the cytoplasmically inherited [PSI] element. In addition, strains carrying SUF1, SUF4 or SUF6 are phenotypically unstable and give rise to mitotic Suf⁺ segregants at high frequency. These segregants invariably contain a linked, second-site mutation that maps in or adjacent to the suppressor gene itself. Strains carrying any of these suppressors also give rise to mitotic segregants that exhibit enhanced efficiency of suppression; mutations responsible for this phenotype map at two loci, upf1 and upf2. These genes show no genetic linkage to any of the Group II suppressors.——Methods that permit positive selection for mutants with decreased or enhanced efficiency of suppression have been devised in order to examine large numbers of variants. The importance of these interacting mutants is underscored by their potential utility in studying suppressor function at the molecular level.     

Extragenic Suppressors of Saccharomyces Cerevisiae Prp4 Mutations Identify a Negative Regulator of Prp Genes

The PRP4 gene encodes a protein that is a component of the U4/U6 small nuclear ribonucleoprotein particle and is necessary for both spliceosome assembly and pre-mRNA splicing. To identify genes whose products interact with the PRP4 gene or gene product, we isolated second-site suppressors of temperature-sensitive prp4 mutations. We limited ourselves to suppressors with a distinct phenotype, cold sensitivity, to facilitate analysis of mutants. Ten independent recessive suppressors were obtained that identified four complementation groups, spp41, spp42, spp43 and spp44 (suppressor of prp4, numbers 1-4). spp41-spp44 suppress the pre-mRNA splicing defect as well as the temperature-sensitive phenotype of prp4 strains. Each of these spp mutations also suppresses prp3; spp41 and spp42 suppress prp11 as well. Neither spp41 nor spp42 suppresses null alleles of prp3 or prp4, indicating that the suppression does not occur via a bypass mechanism. The spp41 and spp42 mutations are neither allele- nor gene-specific in their pattern of suppression and do not result in a defect in pre-mRNA splicing. Thus the SPP41 and SPP42 gene products are unlikely to participate directly in mRNA splicing or interact directly with Prp3p or Prp4p. Expression of PRP3-lacZ and PRP4-lacZ gene fusions is increased in spp41 strains, suggesting that wild-type Spp41p represses expression of PRP3 and PRP4. SPP41 was cloned and sequenced and found to be essential. spp43 is allelic to the previously identified suppressor srn1, which encodes a negative regulator of gene expression.     

Phenotypic reversion in some early blocked sporulation mutants of Bacillus subtilis. Genetic study of polymyxin resistant partial revertants

Summary A class of suppressor mutations restores, in pleiotropic sporulation mutants of B. subtilis (SPO mutants), the wild type level of resistance to Polymyxin, and, most often, other properties of the wild strain as well, but never the ability to sporulate. These suppressors, extracistronic, are active on mutations occurring in any one of the 5 genes in which SPO mutations have been found. The phenotype of the suppressed strains is dependent on both the suppressed (SPO) and the suppressive mutations. All these suppressors are located in a single locus and some of them are thermosensitive. The evidence suggests that a physiological compensation is at work in the partial revertants, so that the locus at which the suppressors are located was called cps X. Two hypotheses are discussed that might account for these observations.     

Genetic mapping of the G101 bacteriophage (Pseudomonas aeuruginosa by temperature-sensitive mutations

Temperature-sensitive (ts) mutations of the G101 phage were isolated after mutagenesis with hydroxylamine. A complementation analysis of 61ts mutants showed that these mutants may be divided into at least 12 complementation groups. Twots mutants probably originated in genes which control lytic functions of the G101 phage. It was shown by three factor crosses that all of the 12ts mutations tested are localized on that side of the “c” region where the probablecI repressor gene is positioned. Sevents mutations is closely linked to thecI ₂₆ clear marker, three exhibit a closer linkage and two do not exhibit any linkage withcI. All mutations isolated until now can be arrange linearly. According to the present knowledge the preliminary genetic map of the G101 phage is linear.     

Crossover Suppressors and Balanced Recessive Lethals in CAENORHABDITIS ELEGANS

Two dominant suppressors of crossing over have been identified following X-ray treatment of the small nematode C. elegans. They suppress crossing over in linkage group II (LGII) about 100-fold and 50-fold and are both tightly linked to LGII markers. One, called C1, segregates independently of all other linkage groups and is homozygous fertile. The other is a translocation involving LGII and X. The translocation also suppresses crossing over along the right half of X and is homozygous lethal. C1 has been used as a balancer of LGII recessive lethal and sterile mutations induced by EMS. The frequencies of occurrence of lethals and steriles were approximately equal. Fourteen mutations were assigned to complementation groups and mapped. They tended to map in the same region where LGII visibles are clustered.     

Suppression of Nonsense and Frameshift Mutations Obtained by Different Methods for Inactivating the Translation Termination Factor eRF3 in Yeast Saccharomyces cerevisiae

Mutations in genes of omnipotent nonsense suppressors SUP35 and SUP45 in yeast Saccharomyces cerevisiae encoding translation termination factors eRF3 and eRF1, respectively, and prionization of the eRF3 protein may lead to the suppression of some frameshift mutations (CPC mutations). Partial inactivation of the translation termination factor eRF3 was studied in strains with unstable genetically modified prions and also in transgenic yeast S. cerevisiae strains with the substitution of the indigenous SUP35 gene for its homolog from Pichia methanolica or for a recombinant S. cerevisiae SUP35gene. It was shown that this partial inactivation leads not only to nonsense suppression, but also to suppression of the frameshift lys2-90 mutation. Possible reasons for the correlation between nonsense suppression and suppression of the CPC lys2-90 mutation and mechanisms responsible for the suppression of CPC mutations during inactivation of translation termination factors are discussed.     

Linkage analysis of developmental mutations in aggregation-deficient mutants of Dictyostelium discoideum

Summary Simple parasexual genetic techniques have been employed to extend the linkage analysis initiated in an earlier study (Coukell, 1975) of developmental mutations (agg mutations) in 40 independently isolated aggregation-deficient mutants of Dictyostelium discoideum. Using these techniques, agg mutations in 28 of the 40 mutants have been assigned to 4 linkage groups: 16 in group II, 1 in group III, 10 in group IV, and 1 in group VI. None of the agg mutations analyzed appear to map in linkage group I. In addition, a new temperature-sensitive growth locus, designated tsgJ, was mapped in group III. It was also found that diploid strains of D. discoideum are readily induced to undergo haploidization when grown on 0.1% p-fluorophenylalanine (PFP) at 25.5 °C. Growth of diploid strains on PFP had no effect on the type of segregant classes obtained (i.e., PFP does not induce mitotic crossing-over), the subsequent growth and/or development of the segregants, or the ability of the segregants to reform stable diploids.