A comparison of induced mutation at homologous alleles of the tk locus in human cells. II. Molecular analysis of mutants.

Previously we described the dose-response relationship for X-ray-induced mutation of the two homologous alleles of the thymidine kinase (tk) gene in a human lymphoblastoid cell line (Amundson and Liber, 1991). The two alleles were differentially mutable by X-rays, with one allele 6-10 times more mutable than the other. This difference was shown to be due to the virtual absence of the class of slow growth mutants from one allele. In the present report, restriction fragment length polymorphism (RFLP) analyses of informative markers along chromosome 17 have been used to delineate a region of chromosome 17 in which heterozygosity is lost with relatively high frequency among slow growth TK- mutants from the more mutable allele. However, loss of heterozygosity of this region has never been observed in normal growth mutants obtained from the more mutable allele, or in TK- mutants from the other, less mutable, allele. This may indicate the presence of a heterozygous essential gene on chromosome 17 distal to TK1.     

De novo methylation as major event in the inactivation of transfected herpesvirus thymidine kinase genes in human cells

Spontaneous inactivation of integrated thymidine kinase genes was studied in three human cell lines, one with multiple copies and two with a single copy of a transfected shuttle plasmid containing two selectable genes: the HSV tk gene and the Eco gpt gene. Selection for gpt expression prevented the isolation of TK- mutants which are the result of plasmid loss. Under these conditions TK- clones were isolated with a frequency of 5.10(-6) both with the cell line containing 5 or 6 copies of the tk gene and with one of the two cell lines containing one copy of this gene. This inactivity of the tk gene was associated with de novo methylation as the number of HAT-resistant (TK+) clones strongly increased after growth of the TK- derivatives in the presence of the demethylating agent, 5-azacytidine. Digestion with methylation-sensitive restriction enzymes revealed two different patterns of DNA methylation in the genomic DNA of TK- variants. In the TK- derivatives of the cell line containing multiple copies of the tk gene many HpaII restriction sites in the gene copies were insensitive to digestion. These HpaII sites were, however, not methylated in TK- variants of the cell line containing one copy of the plasmid, and methylated CpGs could be detected only with EcoRI which recognizes the cGAATTCg sequence in the tk promoter region. With the other of the two single-copy TK+ cell lines no TK- mutants were obtained, suggesting that the position of a gene in the genome is an important factor in determining the frequency and the extent of de novo methylation. Additionally, we observed that remethylation is an even more efficient process of gene inactivation as TK+ clones reactivated with 5-azacytidine can become TK- again at a 100-fold higher rate than the original TK+ cell line.     

Evidence for allelic exclusion in Chinese hamster ovary cells.

Earlier results suggested that the functional hemizygosity of genes in pseudodiploid Chinese hamster ovary (CHO) cells is due to the silencing of one allele by DNA methylation. From this one could make a strong prediction that we have now been able to confirm by genetic experiments, using thymidine kinase (TK) alleles. TK- mutants induced by ethylmethane sulphonate (EMS) were all revertible to TK+ at high frequency by the demethylating agent 5-azacytidine (5-aza-CR). This revertibility was due to reactivation of a silent nonmutant TK allele. Further mutagenesis by EMS yielded TK- derivatives that were no longer revertible by 5-aza-CR; these are assumed to have mutations in both alleles. TK- cells were also transfected with equine herpes virus TK+ DNA, and the TK+ derivatives were shown to be markedly less stable than cells with the normal TK+ gene. CHO cells lack metallothionein activity (sensitive to cadmium), and also require proline for growth, because genes have become silenced during the establishment of the cell line. In both cases 5-aza-CR reactivates these genes to give the cadmium resistant and proline independent phenotypes. Long-term experiments with reactivants in the absence of selection showed that the genes become silent, presumably as a result of de novo methylation. A strain resistant to cytosine arabinoside (araCR) was also resistant to 5-azadeoxycytidine (5-aza-CdR), but not to 5-aza-CR, which would be expected if the araCR strain lacked deoxycytidine kinase.(ABSTRACT TRUNCATED AT 250 WORDS)     

Induction of multilocus lesions by UVC-radiation in mouse L5178Y lymphoblasts

The survival, the mutant frequency and the nature of the DNA alteration responsible for the inactivation of the thymidine kinase (tk) locus were investigated in 5 strains of mouse L5178Y lymphoblasts exposed to UVC radiation. The nature of the DNA alteration was investigated in independent TK-/- mutants using Southern blot analysis. The concomitant loss of galactokinase (GK) activity in homogenates of individual TK-/- mutants was taken as an indication that the lesion inactivating the tk allele extended to the neighboring galactokinase (gk) allele. The survival of strains LY-R16 and LY-R83 was decreased to a greater extent than that of strains LY-S1, LY-SR1, and LY-3.7.2C, reflecting a deficiency in excision repair in strains derived from LY-R cells. The TK-/- mutant frequency of strain LY-R83, which is monosomic for chromosome 11 and thus hemizygous for the tk and gk genes, was only 50% of the mutant frequency of strain LY-R16 which is heterozygous for the tk gene. Moreover, a greatly reduced percentage of individual spontaneous and UVC-induced TK-/- mutants of strain LY-R83 showed loss of GK activity in comparison to the other strains. This result indicates that UVC irradiation induces intergenic mutations and that such mutants are poorly recovered in the hemizygous strain. Strain LY-3.7.2C appears to have only one active galactokinase (gk) allele, and very few TK-/- mutants of this strain showed loss of GK activity, possibly because this strain, although heterozyogous for the tk gene, is hemizygous in the region of the gk gene. Strains LY-R16 and LY-S1 are deficient in the repair of UVC- and X-radiation-induced damage, respectively, and the percentage of TK-/- mutants with intergenic mutations was higher for strain LY-R16 after UVC-radiation and for strain LY-S1 after X-radiation. These results indicate that unrepaired DNA lesions lead to an increase in intergenic mutations.     

Multiple Allele Approach to the Study of Genes in DROSOPHILA MELANOGASTER That Are Involved in Imaginal Disc Development

The phenotypes of five different lethal mutants of Drosophila melanogaster that have small imaginal discs were analyzed in detail. From these results, we inferred whether or not the observed imaginal disc phenotype resulted exclusively from a primary imaginal disc defect in each mutant. To examine the validity of these inferences, we employed a multiple-allele method. Lethal alleles of the five third-chromosome mutations were identified by screening EMS-treated chromosomes for those which fail to complement with a chromosome containing all five reference mutations. Twenty-four mutants were isolated from 13,197 treated chromosomes. Each of the 24 was then tested for complementation with each of the five reference mutants. There was no significant difference in the mutation frequencies at these five loci. The stage of lethality and the imaginal disc morphology of each mutant allele were compared to those of its reference allele in order to examine the range of defects to be found among lethal alleles of each locus. In addition, hybrids of the alleles were examined for intracistronic complementation. For two of the five loci, we detected no significant phenotypic variation among lethal alleles. We infer that each of the mutant alleles at these two loci cause expression of the null activity phenotype. However, for the three other loci, we did detect significant phenotypic variation among lethal alleles. In fact, one of the mutant alleles at each of these three loci causes no detectable imaginal disc defect. This demonstrates that attempting to assess the developmental role of a gene by studying a single mutant allele may lead to erroneous conclusions. As a byproduct of the mutagenesis procedure, we have isolated two dominant, cold-sensitive mutants.     

Isolation and characterization of mutants at the APRT locus in the L-5178Y TK+/TK- mouse lymphoma cell line

2,6-Diaminopurine(DAP)-resistant mutants have been isolated from mouse lymphoma 5178Y TK+/TK- heterozygotes. In the presence of 50 microM DAP, two colony types were isolated. Small colonies contained 50% wild-type adenine phosphoribosyl transferase (APRT) activity (partial mutants), whereas large colonies have undetectable levels of APRT (aprt- mutants). aprt- mutants could be isolated following mutagenesis with ICR-191 or EMS from the partial mutants. Southern blot analysis of EcoRI digested wild-type DNA using a 3.1 kb mouse aprt genomic probe indicated sequence polymorphism at one or both EcoRI sites flanking the allele. Southern blot analysis of one of the partial mutants and one ICR-induced aprt- mutant (single step) indicated that both strains were hemizygous at the APRT locus. Such stable hemizygous strains would be useful in short-term mutagen tests.     

Different capacities for recombination in closely related human lymphoblastoid cell lines with different mutational responses to X-irradiation.

WIL2-NS and TK6 are two distinct human lymphoblast cell lines derived from a single male donor. WIL2-NS cells are significantly more resistant to the cytotoxic effects of X-irradiation but considerably more sensitive to induced mutation. In an effort to determine the mechanistic basis for these differences, we analyzed the physical structures of thymidine kinase (tk)-deficient mutants isolated after X-ray treatment of tk heterozygotes derived from TK6 and the more mutable WIL2-NS. Southern analysis showed that while 84% of TK6-derived mutants had arisen by loss of heterozygosity (LOH), all 106 mutants from WIL2-NS derivatives arose with LOH at tk and all but one showed LOH at other linked loci on chromosome 17. We adapted a fluorescence in situ hybridization technique to distinguish between LOH due to deletion, which results in retention of only one tk allele, and LOH due to a mechanism involving the homologous chromosome (e.g., recombination), which results in the retention of two alleles. Among the LOH mutants derived that were analyzed in this way, 9 of 26 from WIL2-NS and 11 of 17 from TK6 cell lines arose by deletion. The remaining mutants retained two copies of the tk gene and thus arose by a mechanism involving the homologous allele. Since many of these mutants arising by a homologous mechanism retained partial heterozygosity of chromosome 17, they must have arisen by recombination or gene conversion, and not chromosome loss and reduplication. Finally, the recombinational capacities of WIL2-NS and TK6 were compared in transfection assays with plasmid recombination substrates. Intermolecular recombination frequencies were greater in WIL2-NS than in TK6. These data are consistent with a model suggesting that a recombinational repair system is functioning at a higher level in WIL2-NS than in TK6; the greater mutability of the tk locus in WIL2-NS results from more frequent inter- and intramolecular recombination events.     

The effect of dose rate on X-radiation-induced mutant frequency and the nature of DNA lesions in mouse lymphoma L5178Y cells

The induction of mutants at the heterozygous tk locus by X radiation was found to be dose-rate dependent in L5178Y-R16 (LY-R16) cells, but very little dose-rate dependence was observed in the case of strain L5178Y-S1 (LY-S1), which is deficient in the repair of DNA double-strand breaks. Induction of mutants by X radiation at the hemizygous hprt locus was dose-rate independent for both strains. These results are in agreement with the hypothesis that the majority of X-radiation-induced TK-/- mutants harbor multilocus deletions caused by the interaction of damaged DNA sites. Repair of DNA lesions during low-dose-rate X irradiation would be expected to reduce the probability of lesion interaction. The results suggest that in contrast to the TK-/- mutants, the majority of mutations at the hprt locus in these strains of L5178Y cells are caused by single lesions subject to dose-rate-independent repair. The vast majority of the TK-/- mutants of strain LY-R16 showed loss of the entire active tk allele, whether the mutants arose spontaneously or were induced by high-dose-rate or low-dose-rate X irradiation. The proportion of TK-/- mutants with multilocus deletions (in which the products of both the tk gene and the closely linked gk gene were inactivated) was higher in the repair-deficient strain LY-S1 than in strain LY-R16. However, even though the mutant frequency decreased with dose rate, the proportion of mutants showing inactivation of both the tk and gk genes increased with a decrease in dose rate. The reason for these apparently conflicting results concerning the effect of DNA repair on the induction of extended lesions is under investigation.     

Production of homozygous mutant ES cells with a single targeting construct.

We have developed a simple method for producing embryonic stem (ES) cell lines whereby both alleles have been inactivated by homologous recombination and which requires a single targeting construct. Four different ES cell lines were created that were heterozygous for genes encoding two guanine nucleotide-binding protein subunits, alpha i2 and alpha i3, T-cell receptor alpha, and beta-cardiac myosin heavy chain. When these heterozygous cells were grown in high concentrations of G418, many of the surviving cells were homozygous for the targeted allele and contained two copies of the G418 resistance gene. This scheme provides an easy method for obtaining homozygous mutationally altered cells, i.e., double knockouts, and should be generally applicable to other genes and to cell lines other than ES cells. This method should also enable the production of cell lines in which more than one gene have had both alleles disrupted. These mutant cells should provide useful tools for defining the role of particular genes in cell culture.     

Complete Knockout of the Lactate Dehydrogenase A Gene is Lethal in Pyruvate Dehydrogenase Kinase 1, 2, 3 Down-Regulated CHO Cells

Accumulation of high level of lactate can negatively impact cell growth during fed-batch culture process. In this study, we attempted to knockout the lactate dehydrogenase A (LDHA) gene in CHO cells in order to attenuate the lactate level. To prevent the potential deleterious effect of pyruvate accumulation, consequent to LDHA knockout, on cell culture, we chose a pyruvate dehydrogenase kinase 1, 2, and 3 (PDHK1, 2, and 3) knockdown cell line in which to knock out LDHA alleles. Around 3,000 clones were screened to obtain 152 mutants. Only heterozygous mutants were identified. An attempt to knockout the remaining wild-type allele from one such heterozygote yielded only two mutants after screening 567 clones. One had an extra valine. Another evidenced a duplication event, possessing at lease one wild-type and two different frameshifted alleles. Both mutants still retained LDH activity. Together, our data strongly suggest that a complete knockout of LDHA is lethal in CHO cells, despite simultaneous down-regulation of PDHK1, 2, and 3.     

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.     

The Auxin Transport Inhibitor N-(1-Naphthyl)phthalamic Acid Elicits Pseudonodules on Nonnodulating Mutants of White Sweetclover

The collection of symbiotic (sym) mutants of white sweetclover (Melilotus alba Desr.) provides a developmental sequence of mutants blocked early in infection or nodule organogenesis. Mutant phenotypes include non-nodulating mutants that exhibit root-hair deformations in response to Rhizobium meliloti, mutants that form ineffective nodules lacking infection threads, and mutants that form infection threads and ineffective nodules. Mutant alleles from both the sym-1 and the sym-3 loci exhibited a non-nodulating phenotype in response to R. meliloti, although one allele in the sym-1 locus formed ineffective nodules at a low frequency. Spot-inoculation experiments on a non-nodulating allele in the sym-3 locus indicated that this mutant lacked cortical cell divisions following inoculation with R. meliloti. The auxin transport inhibitor N-(1-naphthyl)phthalamic acid elicited development of pseudonodules at a high frequency on all of the sweetclover sym mutants, including the non-nodulating mutants, in which the early nodulin ENOD2 was expressed. This suggests that N-(1-naphthyl)phthalamic acid activates cortical cell divisions by circumventing a secondary signal transduction event that is lacking in the non-nodulating sweetclover mutants. The sym-3 locus and possibly the sym-1 locus appear to be essential to early host plant responses essential to nodule organogenesis.     

Mutational analysis of the [Het-s] prion analog of Podospora anserina. A short N-terminal peptide allows prion propagation

The het-s locus is one of nine known het (heterokaryon incompatibility) loci of the fungus Podospora anserina. This locus exists as two wild-type alleles, het-s and het-S, which encode 289 amino acid proteins differing at 13 amino acid positions. The het-s and het-S alleles are incompatible as their coexpression in the same cytoplasm causes a characteristic cell death reaction. We have proposed that the HET-s protein is a prion analog. Strains of the het-s genotype exist in two phenotypic states, the neutral [Het-s*] and the active [Het-s] phenotype. The [Het-s] phenotype is infectious and is transmitted to [Het-s*] strains through cytoplasmic contact. het-s and het-S were associated in a single haploid nucleus to generate a self-incompatible strain that displays a restricted and abnormal growth. In the present article we report the molecular characterization of a collection of mutants that restore the ability of this self-incompatible strain to grow. We also describe the functional analysis of a series of deletion constructs and site-directed mutants. Together, these analyses define positions critical for reactivity and allele specificity. We show that a 112-amino-acid-long N-terminal peptide of HET-s retains [Het-s] activity. Moreover, expression of a mutant het-s allele truncated at position 26 is sufficient to allow propagation of the [Het-s] prion analog.     

A Female Sterile Screen of the Drosophila Melanogaster X Chromosome Using Hybrid Dysgenesis: Identification and Characterization of Egg Morphology Mutants

We have conducted a hybrid dysgenic screen of the X chromosome for mutations affecting female fertility, with particular attention to those causing abnormal egg and eggshell morphology. In a screen of 4017 dysgenic strains, 398 mutants derived from 168 different germ lines were isolated and assigned to eight classes according to their diverse phenotypes. One interesting class consists of mutants that block oogenesis at specific stages. Our analysis has focused on mutations affecting eggshell formation, including mutants that lay morphologically abnormal sterile eggs as well as those that lay no eggs but exhibit blocks in the late stages of oogenesis. A subset of 48 mutants was assorted into 30 allelic groups by inter se complementation and genetically localized by interval mapping. Two multiallele complementation groups, de1 (7 alleles) and ne1 (8 alleles), were identified as well as five two-allele complementation groups. A search for alleles among mutants generated in other female sterile screens was unsuccessful, pointing to the distinctive nature of the dysgenic mutant collection. The single case of allelism determined in this study was one with a lethal allele of the Broad-Complex, l(1)npr, suggesting a possible involvement of ecdysone in choriogenesis. A subset of 18 dysgenic strains was analyzed for P element hybridization and 16 of these were found to have hybridization signals in the appropriate cytogenetic interval. By examining these signals in two or more alleles of the same complementation group, we have been able to tentatively localize two mutations. Light and electron microscopy of the eggshell in 43 different strains has revealed a variety of effects. The respiratory appendages were defective in 27 of these mutants. Effects on the ultrastructure of the main body of the endochorion were not strongly correlated with the appendage defects, and could be classified as minor (14 mutants) or major (16 mutants). Although 13 mutants showed no ultrastructural chorion defects, six of these had defective respiratory appendages.     

Mutation at autosomal loci of Chinese hamster ovary cells: involvement of a high-frequency event silencing two linked alleles.

Two classes of cell lines heterozygous at the galactokinase (glk) locus have been isolated from Chinese hamster ovary cells. Class I, selected by plating nonmutagenized wild-type cells at low density in medium containing 2-deoxygalactose at a partially selective concentration, underwent subsequent mutation to the glk-/- genotype at a low frequency (approximately 10(-6) per cell), which was increased by mutagenesis. Class II heterozygotes, isolated by sib selection from mutagenized wild-type cells, had a higher spontaneous frequency of mutation to the homozygous state (approximately 10(-4) per cell), which was not affected by mutagenesis. About half of the glk-/- mutants derived from a class II heterozygote, but not the heterozygote itself, were functionally hemizygous at the syntenic thymidine kinase (tk) locus. Similarly, a tk+/- heterozygote with characteristics analogous to the class II glk+/- cell lines underwent high-frequency mutation to tk-/-, and most of these mutants, but not the tk+/- heterozygote, were functionally hemizygous at the glk locus. A model is proposed, similar to that for the mutational events at the adenine phosphoribosyl transferase locus (W. E. C. Bradley and D. Letovanec, Somatic Cell Genet. 8:51-66, 1982), of two different events, high and low frequency, being responsible for mutation at either of the linked loci tk and glk. The low-frequency event may be a point mutation, but the high-frequency event, in many instances, involves coordinated inactivation of a portion of a chromosome carrying the two linked alleles. Class II heterozygotes would be generated as a result of a low-frequency event at one allele, and class I heterozygotes would be generated by a high-frequency event. Supporting this model was the demonstration that all class I glk+/- lines examined were functionally hemizygous at tk.     

Selection of human cells having two different types of mutations in individual cells (genetic/artificial mutants)

Summary We have previously reported the establishment and characterization of B cell lines from patients and family members with various types of adenine phosphoribosyltransferase (APRT) deficiencies. These cell lines contain, at the APRT locus, three different alleles (APRT ^* 1, APRT ^* Q0, and APRT ^* J) that are clearly distinguishable from each other. From five genetically heterozygous cell lines with two different genotypes (APRT ^* 1/APRTQ0 and APRT ^* 1/APRT ^* J), we have selected 48 clones resistant to 2,6-diaminopurine. Resistance to this adenine analogue is a characteristic of cells having defects in both of the APRT alleles in individual cells. The mutant clones from a cell line from a complete-type heterozygote had APRT activities close to zero (mean=0.04 nmol/min per milligram protein) in the cell extracts, while 15 clones from four cell lines from the four Japanese-type heterozygotes had significant enzyme activities (mean=3.88 nmol/min per milligram protein). Kinetic studies on two of the mutants from two Japancse-type heterozygous cell lines have shown that affinity to substrate 5-phosphoribosyl-1-pyrophosphate was reduced, indicating that APRT in those clones reflected the characteristics of the Japanese-type enzyme. The data presented here indicate that clones we obtained are genetic/artificial mutants, each having a genetic mutation in a single allele (APRT ^* J or APRT ^* Q0) and an artificially produced mutation in the other previously functional allele (APRT ^*1). The present procedure provided the only diagnostic method for Japanese-type APRT heterozygotes (APRT ^* 1/APRT ^* J).     

A two-locus mutation—Selection model and some of its evolutionary implications

The deterministic properties of a two-locus model with mutation and selection have been investigated. The mutation process is unidirectional, and the model is so constructed that the genetic variation at one locus is selectively neutral in the absence of a mutant allele at the other locus. All genotypes with three or four mutant alleles are deleterious, while the double heterozygotes may have the same fitness as the standard genotype. If one of the mutant alleles becomes fixed in the population, then the other locus will show a regular one-locus mutation-selection balance. Such a boundary equilibrium may be unstable or stable in the full two-locus setting. In the symmetric case, which is analyzed in details, the population will either go to one of the two boundary equilibria, or to a fully polymorphic equilibrium at which both the mutant alleles are rare. The origin of reproductive separation between two populations via the fixation of complementary deleterious mutants at different loci, and the fixation of nonfunctional alleles at duplicated loci, are two biological processes which both can be studied with the present model. In the last part of the paper we show how the results from the deterministic analysis can be used to predict how different factors will influence the rates of evolution in these systems.     

Identification of Genes Required for the Function of Non-Race-Specific mlo Resistance to Powdery Mildew in Barley

Recessive alleles (mlo) of the Mlo locus in barley mediate a broad, non-race-specific resistance reaction to the powdery mildew fungus Erysiphe graminis f sp hordei. A mutational approach was used to identify genes that are required for the function of mlo. Six susceptible M2 individuals were isolated after inoculation with the fungal isolate K1 from chemically mutagenized seed carrying the mlo-5 allele. Susceptibility in each of these individuals is due to monogenic, recessively inherited mutations in loci unlinked to mlo. The mutants identify two unlinked complementation groups, designated Ror1 and Ror2 (required for mlo-specified resistance). Both Ror genes are required for the function of different tested mlo alleles and for mlo function after challenge with different isolates of E. g. f sp hordei. A quantitative cytological time course analysis revealed that the host cell penetration efficiency in the mutants is intermediate compared with mlo-resistant and Mlo-susceptible genotypes. Ror1 and Ror2 mutants could be differentiated from each other by the same criterion. The spontaneous formation of cell wall appositions in mlo plants, a subcellular structure believed to represent part of the mlo defense, is suppressed in mlo/ror genotypes. In contrast, accumulation of major structural components in the appositions is seemingly unaltered. We conclude that there is a regulatory function for the Ror genes in mlo-specified resistance and propose a model in which the Mlo wild-type allele functions as a negative regulator and the Ror genes act as positive regulators of a non-race-specific resistance response.     

Mitotic recombination is responsible for the loss of heterozygosity in cultured murine cell lines.

Heterozygous mammalian cell lines normally express both parental alleles at most autosomal loci. However, mutants can be isolated that fail to express one of the alleles. Using a murine pre-B cell line that is heterozygous for several loci on chromosome 12, including one encoding the cell surface antigen Ly-18, we found that one of the two Ly-18 antigenic forms was lost at a rate of 1.5 x 10(-5) per cell per generation. Molecular analysis revealed that a genetic marker distal to Ly-18 became homozygous. Analysis of the genotype of the mutants at the rDNA cluster, located close to the centromere, strongly suggests that the mutants arose by mitotic recombination within this multicopy locus.