Detection of lethal mutations appearing in the somatic tissue cells of Drosophila

A method of selective screening of recessive sex-linked lethal mutations, that are manifested only in somatic cells of D. melanogaster, has been developed. Lethals were induced with X-irradiation of X-chromosomes at the moment of their topographic segregation from embryonic somatic cells. Analysis of mutation expression confirmed the method selectivity.     

Somatic mutations in organisms with complex life histories.

A theoretical model is developed of the fate of mutations for organisms with such life-history characteristics as indeterminate growth and clonal reproduction. It focuses on how the fate of a particular mutant depends on whether it arises during mitotic cell division (somatic mutation) or during meiotic cell division (meiotic mutation). At gamete production, individuals carrying somatic mutations will produce some proportion of gametes reflecting the original, zygotic genotype and some proportion reflecting genotypes carrying the somatic mutation. Focusing on allele frequencies at gamete production allows the effects of growth and clonal reproduction to be summarized. The relative strengths of somatic and meiotic mutation can be determined, as well as the conditions under which the change in allele frequency due to one is greater than that due to the other. Examples from a published demographic study of clonal corals are used to compare somatic and meiotic mutation. When there is no selection acting on either type of mutation, only a few cell divisions per time unit on average are needed for the change in allele frequency due to somatic mutation to be greater, given empirically based mutation rates. When somatic selection is added, the most dramatic effect is seen with fairly strong negative selection acting against the somatic mutation within individuals. In this case, selection within organisms can effectively counteract the effects of somatic mutation, and the change in allele frequency due to somatic mutations will not be greater than that due to meiotic mutations for reasonable numbers of within-generation cell divisions. The majority of the mutation load, which would have been due to somatic mutation, is purged by selection within the individual organism.     

Medullary thyroid carcinoma: pitfalls in diagnosis by fine needle aspiration cytology and relationship of cytomorphology to RET proto-oncogene mutations

OBJECTIVE: To elucidate the pitfalls in the diagnosis of medullary thyroid carcinoma (MTC) by fine needle aspiration cytology (FNAC) and the relationship of cytomorphology to RET proto-oncogene mutations. STUDY DESIGN: Cytomorphology was reviewed in the fine needle aspiration slides of 34 patients with MTC proven by surgery and pathology. Germline or somatic RET proto-oncogene mutations were determined using polymerase chain reaction-based sequencing in 15 of 34 patients, and the relationship to cytomorphology was evaluated. RESULTS: Twenty-eight (82.4%) of 34 cases were diagnosed correctly as MTC by FNAC, 3 cases were misdiagnosed as follicular neoplasm and 1 as desmoid, and 2 cases were suspicious for MTC. The main reason for misdiagnosis was overlooking the slight angular shape of the nuclei or atypical changes. In 15 of 34 cases with germline or somatic RET proto-oncogene mutations determined, 10 cases had a germline mutation, and 1 had only a somatic mutation. There were 4 cases that had neither germline nor somatic RET proto-oncogene mutations. Cells with small/round and spindled forms were the predominant findings of codon 918 ATG-->ACG mutation, and cells with small/round and large oval to polygonal forms were the main findings of codon 634 mutations. There were no misdiagnoses in patients with RET proto-oncogene mutations. CONCLUSION: FNAC is a good diagnostic method for MTC. Codon 918 mutation correlates mainly with small/round and spindled cells and codon 634 with small/round, large oval to polygonal forms.     

Enhanced mutability at the tk locus in the radiosensitive double-strand break repair mutant xrs5

The thymidine kinase locus (tk) has been utilised as the target locus to measure the induced mutation frequency following X-irradiation in the X-ray-sensitive xrs5 mutant and its parent CHO K1 line of Chinese hamster cells. Mutations to tk- cells were measured by plating cells in selective medium containing trifluorothymidine after a post-irradiation expression time of 4 days. Our results show that the mutation frequency was 3-4 times higher in the xrs5 mutant than in the CHO K1 cell line. This enhanced mutation frequency in xrs5 is though to result from the deficiency in DNA double-strand break repair in this cell line which also results in the enhanced cell killing and higher frequencies of chromosomal aberrations in response to X-irradiation. The findings of the present study suggest that DNA double-strand break is a critical lesion leading to mutations in irradiated cells.     

Role of the mismatch repair gene, Msh6, in suppressing genome instability and radiation-induced mutations

Mismatch repair (MMR) is critical for preserving genomic integrity. Failure of this system can accelerate somatic mutation and increase the risk of developing cancer. MSH6, in complex with MSH2, is the MMR protein that mediates DNA repair through the recognition of 1- and 2-bp mismatches. To evaluate the effects of MSH6 deficiency on genomic stability we compared the frequency of in vivo loss of heterozygosity (LOH) between MSH6-proficient and deficient, 129S2xC57BL/6 F1 hybrid mice that were heterozygous for our reporter gene Aprt. We recovered mutant cells that had functionally lost APRT protein activity and categorized the spectrum of mutations responsible for the LOH events. We also measured the mutant frequency at the X-linked gene, Hprt, as a second reporter for point mutation. In Msh6-/-Aprt+/- mice, mutation frequency at Aprt was elevated in both T cells and fibroblasts by 2.5-fold and 5.7-fold, respectively, over Msh6+/+Aprt+/- littermate controls. While a modest increase in mitotic recombination (MR) was observed in MSH6-deficient fibroblasts compared to wild type controls, point mutation was the predominant mechanism leading to APRT deficiency in both cell types. Base substitution, consisting of multiple types of transitions, accounted for all of the point mutations identified within the Aprt coding region. We also assessed the role of MSH6 in preventing mutations caused by a common environmental mutagen, ionizing radiation (IR). In Msh6-/-Aprt+/- mice, 4Gy of X-irradiation induced a significant increase in point mutations at both Aprt and Hprt in T cells, but not in fibroblasts. These findings indicate that MutS alpha reduces spontaneous and IR-induced mutation in a cell type-dependant manner.     

Characterization of melanocyte-specific inducible Cre recombinase transgenic mice

Conditional Cre-mediated recombination has emerged as a robust method of introducing somatic genetic alterations in an organ-specific manner in the mouse. Here, we generated and characterized mice harboring a 4-hydroxytamoxifen (OHT)-inducible Cre recombinase-estrogen receptor fusion transgene under the control of the melanocyte-specific tyrosinase promoter, designated Tyr::CreER(T2). Cre-mediated recombination was induced in melanocytes in a spatially and temporally controlled manner upon administration of OHT and was documented in embryonic melanoblasts, follicular bulb melanocytes, dermal dendritic melanocytes, epidermal melanocytes of tail skin, and in putative melanocyte stem cells located within the follicular bulge. Functional evidence suggestive of recombination in follicular melanocyte stem cells included the presence of Cre-mediated recombination in follicular bulb melanocytes 1 year after topical OHT administration, by which time several hair cycles have elapsed and the melanocytes residing in this location have undergone multiple rounds of apoptosis and replenishment. These Tyr:: CreER(T2) transgenic mice represent a useful resource for the evaluation of melanocyte developmental genetics, the characterization of melanocyte stem cell function and dynamics, and the construction of refined mouse models of malignant melanoma.     

Oxidative Stress Is Not a Major Contributor to Somatic Mitochondrial DNA Mutations

The accumulation of somatic mitochondrial DNA (mtDNA) mutations is implicated in aging and common diseases of the elderly, including cancer and neurodegenerative disease. However, the mechanisms that influence the frequency of somatic mtDNA mutations are poorly understood. To develop a simple invertebrate model system to address this matter, we used the Random Mutation Capture (RMC) assay to characterize the age-dependent frequency and distribution of mtDNA mutations in the fruit fly Drosophila melanogaster. Because oxidative stress is a major suspect in the age-dependent accumulation of somatic mtDNA mutations, we also used the RMC assay to explore the influence of oxidative stress on the somatic mtDNA mutation frequency. We found that many of the features associated with mtDNA mutations in vertebrates are conserved in Drosophila, including a comparable somatic mtDNA mutation frequency (∼10⁻⁵), an increased frequency of mtDNA mutations with age, and a prevalence of transition mutations. Only a small fraction of the mtDNA mutations detected in young or old animals were G∶C to T∶A transversions, a signature of oxidative damage, and loss-of-function mutations in the mitochondrial superoxide dismutase, Sod2, had no detectable influence on the somatic mtDNA mutation frequency. Moreover, a loss-of-function mutation in Ogg1, which encodes a DNA repair enzyme that removes oxidatively damaged deoxyguanosine residues (8-hydroxy-2′-deoxyguanosine), did not significantly influence the somatic mtDNA mutation frequency of Sod2 mutants. Together, these findings indicate that oxidative stress is not a major cause of somatic mtDNA mutations. Our data instead suggests that somatic mtDNA mutations arise primarily from errors that occur during mtDNA replication. Further studies using Drosophila should aid in the identification of factors that influence the frequency of somatic mtDNA mutations.     

Mitochondrial D-Loop instability in thyroid tumours is not a marker of malignancy

Despite the numerous studies describing a high frequency of mitochondrial DNA (mtDNA) somatic mutations in many types of human primary tumors the mechanisms that generate such mutations and the role of mtDNA mutations in tumor development remain unclear. We present the results obtained in the study of mtDNA displacement-loop (D-Loop) region in a series of 66 thyroid tumors, and respective adjacent parenchyma, including benign (adenomas, n=30) and malignant tumors (follicular carcinomas, n=17 and papillary carcinomas, n=19). Three repetitive regions were analyzed [two mononucleotide repetitive (D310 and D568) and one dinucleotide repetitive (D514)]. Thirty-two (48.5%) of the 66 tumors [15/30 (50.0%) adenomas, 8/17 (47.1%) follicular carcinomas and 9/19 (47.4%) papillary carcinomas] harbored somatic insertions in D-Loop repetitive regions. Twenty (30.3%) of the 66 tumors [12/30 (40%) adenomas, 3/17 (17.6%) follicular carcinomas and 5/19 (26.3%) papillary carcinomas] harbored somatic insertions at the D310 mononucleotide repeat. Three (4.6%) of the 66 tumors [1/30 (3.3%) adenomas and 2/17 (11.8%) follicular carcinomas] harbored somatic insertions at the D568 mononucleotide repeat. Fifteen (22.7%) of the 66 tumors [3/30 (10.0%) adenomas, 5/17 (29.4%) follicular carcinomas and 7/19 (36.8%) papillary carcinomas] harbored somatic insertions at the D514 dinucleotide repeat. Five (7.6%) of the 66 tumors [1/30 (3.3%) adenomas, 1/17 (5.9%) follicular carcinomas and 2/19 (10.5%) papillary carcinomas] harbored somatic insertions in more than one region, and in one of them (a carcinoma) alterations were detected in the three regions. We conclude that mutations in the mtDNA D-Loop region are frequent in benign and malignant thyroid tumors and cannot be considered a marker of malignancy. Our study shows, furthermore, two repetitive regions (D310 and D514) that appear to be susceptible to mutation in thyroid tumors.     

Interindividual Variation in Mitotic Recombination

Mitotic recombination (MR) between homologous chromosomes is a mutational event that results in loss of heterozygosity in half of the segregants at mitosis. Loss of heterozygosity may have important biological consequences. The purpose of this study was to describe human variation in the spontaneous frequency of MR. Using an immunoselection technique for isolating the somatic mutations that result in loss of expression of one of the codominant alleles at the HLA-A locus, we have measured the frequency and molecular basis of somatic mutations in lymphocytes from a population of young adults. Mutations were classified as being the result of intragenic changes, major deletions, or MR. Here we show that the MR mutation frequency in females was significantly greater than that in males but that intragenic mutation frequency showed no association with sex. Individual variation in MR frequency ranged over more than two orders of magnitude and was not normally distributed. Furthermore, the observed number of individuals from whom no mutants resulting from MR were obtained was significantly greater than was expected. The endogenous level of MR may be under genetic control. Given the association of loss of heterozygosity with cancer initiation and progression, low endogenous MR may confer a reduced lifetime risk of cancer, and the converse may apply.     

Length, orientation, and plant host influence the mutation frequency in microsatellites.

Microsatellites are simple, tandem DNA repeats that represent unstable regions of the genome. They undergo frequent changes in tract length by base additions or deletions due to DNA polymerase slippage during replication. To characterize factors affecting the frequency of spontaneous mutations occurring in microsatellites in plants, a reporter system was used in Arabidopsis thaliana and tomato (Lycopersicon esculentum). The beta-glucuronidase (GUS) reporter system was used to measure the mutation frequency in various microsatellites (G(7), G(10), G(13), G(16), and C(16)) in somatic tissues. Our results indicate that this frequency increases with the number of repeats: a G(16) tract was almost 80-fold more mutable than a G(7) tract. Furthermore, the frequency of mutations depends on repeat orientation, as G(16) was 3-fold more mutable than C(16). The mutation rate was also found to differ markedly in Arabidopsis and tomato for an identical microsatellite. Indeed, Arabidopsis showed a 5-fold higher mutation frequency than tomato with the same G(7) reporter construct. Finally, mutation in a G(16) tract was frequent enough that mutations transmitted germinally to the next generation could be detected at a relatively high frequency.     

Mutations of the immunoglobulin heavy chain variable region gene in CD99-deficient BJAB cell line

Hodgkin's disease (HD) is a lymphoid neoplasm characterized by a low frequency of malignant giant tumor cells, known as Hodgkin's and Reed-Sternberg (HRS) cells. Sequence analysis of the immunoglobulin heavy chain hypervariable region (IgH V) genes of HRS cells revealed multiple nucleotide substitutions, indicating somatic mutations, and suggested that HRS cells originate from germinal center B cells or their progeny. We previously reported that CD99-antisense transfected B cell lines led to the generation of cells with a HRS phenotype. Because it is considered that HRS cells in HD carry somatic mutations of the IgH genes, we assume that somatic mutation may take place in the IgH genes of HRS-like cells which do not express CD99. Here we report that CD99 downregulated BJAB cell line has several mutations in IgH V genes. The frequency of mutation was 5.2 x 10(-4) mut.bp(-1) out of total sequenced cell clones. On the contrary, control vector transfected BJAB cell line or CD99 downregulated IM9 cell line did not show any mutations on single strand conformational polymorphism (SSCP) and sequence analysis. We expect that the analysis of the mutation pattern of the CD99-deficient BJAB cell line might be the basis for the understanding of the molecular and cellular mechanism that regulate somatic mutation and B cell selection.     

DNA repair gene polymorphisms, pre-natal factors and the frequency of somatic mutations in the glycophorin-A gene among healthy newborns

This study investigates variation in somatic mutation frequency, as measured by the glycophorin-A (GPA) somatic mutation assay, in relation to polymorphic variation among 435 newborn babies in DNA repair genes XRCC1, XRCC3 and XRCC4 and gender, parental age, social class and smoking habits. The three polymorphisms under investigation were an Arg --> Gln substitution at codon 399 in exon 10 of XRCC1, a Thr --> Met substitution at codon 241 in exon 7 of XRCC3 and an Ile --> Thr substitution at codon 401 in exon 4 of XRCC4. The study population is an extension of that previously analysed for GPA mutations and XRCC1 polymorphisms. A significant difference was seen in the earlier work in the genotype distribution for the XRCC1 Arg399Gln polymorphism between the main population and the small number with extreme values for NN variant frequency and this was maintained in the larger study group (OR 3.20 [95% CI: 1.16, 8.81]) P = 0.043). No such association was seen for XRCC3 or XRCC4 polymorphisms. When adjustments were made for multiple testing, neither N0 nor NN variant frequencies in the main study population were found to be influenced by the polymorphisms in XRCC1, XRCC3, or XRCC4. In addition, neither maternal or paternal smoking, age or social class nor the gender of the offspring were found to affect variant frequencies nor were variant frequencies influenced by any interaction between any of these factors and genotype. It is concluded that the genotypic variation in DNA repair genes examined in this study has no discernable effect on the genesis of the somatic mutations observed at birth.     

Estimation of Mutation Rates Based on the Analysis of Polypeptide Constituents of Cultured Human Lymphoblastoid Cells

A subclone of a human diploid lymphoblastoid cell line, TK-6, with consistently high cloning efficiency has been used to estimate the rates of somatic mutations on the basis of protein variation detected by two-dimensional polyacrylamide gel electrophoresis. A panel of 267 polypeptide spots per gel was screened, representing the products of approximately 263 unselected loci. The rate of human somatic mutation in vitro was estimated by measuring the proportion of protein variants among cell clones isolated at various times during continuous exponential growth of a TK-6 cell population. Three mutants of spontaneous origin were observed, giving an estimated spontaneous rate of 6 x 10(-8) electrophoretic mutations per allele per cell generation (i.e., 1.2 x 10(-7) per locus per cell generation). Following treatment of cells with N-ethyl-N-nitrosourea, a total of 74 confirmed variants at 54 loci were identified among 1143 clones analyzed (approximately 601,000 allele tests). The induced variants include 65 electromorphs which exhibit altered isoelectric charge and/or apparent molecular weight and nine nullimorphs for each of which a gene product was not detected at its usual location on the gel. The induced frequency for these 65 structural gene mutants is 1.1 x 10(-4) per allele. An excess of structural gene mutations at ten known polymorphic loci and repeat mutations at these and other loci suggest nonrandomness of mutation in human somatic cells. Nullimorphs occurring at three heterozygous loci in TK-6 cells may be caused by genetic processes other than structural gene mutation.     

Patterns of Somatic Mutations in Immunoglobulin Variable Genes

The mechanism responsible for somatic mutation in the variable genes of antibodies is unknown and may differ from previously described mechanisms that produce mutation in DNA. We have analyzed 421 somatic mutations from the rearranged immunoglobulin variable genes of mice to determine if the nucleotide substitutions differ from those generated during meiosis and if the presence of nearby direct and inverted repeated sequences could template mutations around the variable gene. The results reveal a difference in the pattern of substitutions obtained from somatic mutations vs. meiotic mutations. An increased frequency of T:A to C:G transitions and a decreased frequency of mutations involving a G in the somatic mutants compared to the meiotic mutants is indicated. This suggests that the mutational processes responsible for somatic mutations in antibody genes differs from that responsible for mutation during meiosis. An analysis of the local DNA sequences revealed many direct repeats and palindromic sequences that were capable of templating some of the known mutations. Although additional factors may be involved in targeting mutations to the variable gene, mistemplating by nearby repeats may provide a mechanism for the enhancement of somatic mutation.     

High throughput interrogation of somatic mutations in high grade serous cancer of the ovary

Background

Epithelial ovarian cancer is the most lethal of all gynecologic malignancies, and high grade serous ovarian cancer (HGSC) is the most common subtype of ovarian cancer. The objective of this study was to determine the frequency and types of point somatic mutations in HGSC using a mutation detection protocol called OncoMap that employs mass spectrometric-based genotyping technology.

Methodology/Principal Findings

The Center for Cancer Genome Discovery (CCGD) Program at the Dana-Farber Cancer Institute (DFCI) has adapted a high-throughput genotyping platform to determine the mutation status of a large panel of known cancer genes. The mutation detection protocol, termed OncoMap has been expanded to detect more than 1000 mutations in 112 oncogenes in formalin-fixed paraffin-embedded (FFPE) tissue samples. We performed OncoMap on a set of 203 FFPE advanced staged HGSC specimens. We isolated genomic DNA from these samples, and after a battery of quality assurance tests, ran each of these samples on the OncoMap v3 platform. 56% (113/203) tumor samples harbored candidate mutations. Sixty-five samples had single mutations (32%) while the remaining samples had ≥2 mutations (24%). 196 candidate mutation calls were made in 50 genes. The most common somatic oncogene mutations were found in EGFR, KRAS, PDGRFα, KIT, and PIK3CA. Other mutations found in additional genes were found at lower frequencies (<3%).

Conclusions/Significance

Sequenom analysis using OncoMap on DNA extracted from FFPE ovarian cancer samples is feasible and leads to the detection of potentially druggable mutations. Screening HGSC for somatic mutations in oncogenes may lead to additional therapies for this patient population.     

Efficient simulation under a population genetics model of carcinogenesis

MOTIVATION: Cancer is well known to be the end result of somatic mutations that disrupt normal cell division. The number of such mutations that have to be accumulated in a cell before cancer develops depends on the type of cancer. The waiting time T(m) until the appearance of m mutations in a cell is thus an important quantity in population genetics models of carcinogenesis. Such models are often difficult to analyze theoretically because of the complex interactions of mutation, drift and selection. They are also computationally expensive to simulate because of the large number of cells and the low mutation rate. RESULTS: We develop an efficient algorithm for simulating the waiting time T(m) until m mutations under a population genetics model of cancer development. We use an exact algorithm to simulate evolution of small cell populations and coarse-grained τ-leaping approximation to handle large populations. We compared our hybrid simulation algorithm with the exact algorithm in small populations and with available asymptotic results for large populations. The comparison suggested that our algorithm is accurate and computationally efficient. We used the algorithm to study the waiting time for up to 20 mutations under a Moran model with variable population sizes. Our new algorithm may be useful for studying realistic models of carcinogenesis, which incorporates variable mutation rates and fitness effects.     

Quantification of the paternal allele bias for new germline mutations in the retinoblastoma gene

New germline mutations in the human retinoblastoma gene are known to arise preferentially on paternally derived chromosomes, but the magnitude of that bias has not been measured. We evaluated 49 cases with a new germline mutation and found that in 40 cases (82%) the mutation arose on the paternally derived allele. We also evaluated 48 cases likely to have a somatic initial mutation; in this group the initial mutation arose on paternal or maternal chromosomes with approximately equal frequency. There was no statistically significant difference in the average age of fathers of children with new paternal germline mutations from the average age of fathers of children with new maternal germline mutations or somatic initial mutations. Combining the data with that from previous reports from other groups, the proportion of new germline mutations arising on a paternally derived allele is 85% (based on 72 cases; 95% confidence interval = 76–93%). This number can be useful in the genetic counseling of some families with retinoblastoma. Received: 18 December 1996 / Accepted: 30 April 1997     

X-ray-induced specific-locus mutation rates in young male mice

The specific-locus mutation frequency resulting from 300 R of acute X-irradiation has been determined for the germ cells present in male mice at 2, 4, 6, 8, 10, 14, 21, 28, and 35 days of age. The sample size was large enough for each of these nine age groups to ensure that a high mutation rate would be noticed. The testis of the mouse undergoes many developmental changes between birth, when most or all germ cells are gonocytes, and 35 days, when the cell population has come to resemble that of the adult. It was important to know if the germ cells present in these developmental stages of immature male mice yield the same mutation frequency as that found earlier for spermatogonia in the adult by W. L. Russell.None of the nine age groups has a mutation rate statistically significantly higher than that of the adult. Taken together, the nine groups of males have an average mutation frequency quite to that of the adult. This does not rule out the possibility that individual age groups may have a mutation frequency somewhat different from that of the adult.The distribution of mutations among the loci seems to be similar to that found for mutations induced in spermatogonia of the adult. Clusters of specific-locus mutations were found only on day 21.This paper and that presented earlier on the newborn report the first specific-locus mutation-rate studies on male mice irradiated between birth and adulthood. If the results can be carried over to man, it can be concluded that irradiation of the immature testis, from birth to puberty, will not present any greatly increased genetic hazard over that from irradiation of the adult testis. In fact, as the data stand in the mouse, they indicate a mutation rate similar to the adult for all but the earlier stages tested and, for these stages, a probably lower rate, representing a transition from the significantly lower rate reported earlier for newborns.     

Spontaneous changes in somatic compatibility in Fusarium circinatum

Filamentous fungi grow by the elaboration of hyphae, which may fuse to form a network as a colony develops. Fusion of hyphae can occur between genetically different individuals, provided they share a common allele at loci affecting somatic compatibility. Diversity in somatic compatibility phenotypes reduces the frequency of hyphal fusion in a population, thereby slowing the spread of deleterious genetic elements such as viruses and plasmids, which require direct cytoplasmic contact for transmission. Diverse somatic compatibility phenotypes can be generated by recombining alleles through sexual reproduction, but this mechanism may not fully account for the diversity found in nature. For example, multiple compatibility phenotypes of Fusarium circinatum were shown to be associated with the same clonal lineage, which implies they were derived by a mutation rather than recombination through sexual reproduction. Experimental tests of this hypothesis confirmed that spontaneous changes in somatic compatibility can occur at a frequency between 5 and 8 per million spores. Genomic analysis of F. circinatum strains with altered somatic compatibility revealed no consistent evidence of recombination and supported the hypothesis that a spontaneous mutation generated the observed phenotypic change. Genes known to be involved in somatic compatibility had no mutations, suggesting that mutation occurred in a gene with an as yet unexplored function in somatic compatibility.     

The effect of ploidy on chemical mutagenesis in cultured Chinese hamster cells

The frequency of mutations induced by ethyl methane sulfonate was compared in a pseudodiploid Chinese hamster cell strain and in a tetraploid substrain derived from it. The frequency of reverse mutations from glycine auxotrophy to glycine independence was similar in the two strains, as expected for a dominant phenotype. Forward mutation to 6-thioguanine-resistance was 25 fold lower in the tetraploid as compared to the diploid strain. The resistant mutants lack hypoxanthine phosphoribosyl transferase activity and their resistant phenotype is recessive in somatic cell hybrids. A combination of chromosomal segregation and mutation could account for the frequency of these recessive drug-resistant mutants in the tetraploid population.