A population genetic study of six VNTR loci in three ethnically defined populations.

To investigate the population genetic characteristics of VNTR polymorphisms in human populations, we have studied the allele frequency distribution of six VNTR loci (D1S57, RB1, D1S77, D1S61, alpha-globin 5'HVR, D1S76) in three well-defined populations (Kachari of Northeast India; Dogrib Indian of Canada; and New Guinea Highlander of Papua New Guinea). Even though the number of alleles sampled is limited, 48 to 92 alleles per locus per population, significant variation is noticed in the number of alleles per locus for all the populations. Using alternate summary measures, we have observed that genotype distributions at the six VNTR loci apparently conform to their respective Hardy-Weinberg predictions. Multilocus genotype profiles of the individuals in each of the three populations suggest that the VNTR alleles are independently segregating with the exception of the two linked loci D1S76 and D1S77. Lack of fit of all VNTR loci to one particular model of mutational change, either the Infinite Allele Model or the Stepwise Mutation Model, suggests more than one mechanism for production of new VNTR alleles. This study also indicates that increased heterozygosity at VNTR loci in comparison to protein and blood group loci may lead to more accurate estimates of genetic distance.     

Population Genetic Characteristics of the D1S80 locus in seven human populations

We have analyzed the allele frequency distribution at the highly polymorphic variable number of tandem repeat (VNTR) locus D1S80 (pMCT118) in seven ethnic populations (namely, New Guinea Highlanders of Papua New Guinea, Dogrib Indians of Canada, Pehuenche Indians of Chile, American and Western Samoans, Kacharis of Northeast India, and German Caucasians) using the polymerase chain reaction (PCR) technique. In the pooled sample of 443 unrelated individuals 20 segregating alleles were detected. A trimodal pattern of allelic distribution is present in the majority of populations and is indicative of the evolutionary antiquity of the polymorphism at this locus. In spite of the observed high degree of polymorphism (expected heterozygosity 56%–86%), with a single exception — the marginally significant P value (0.04) of the exact test in American Samoans — the genotype distributions in all populations conform to their respective Hardy-Weinberg expectations. Summary statistics indicate that, in general, the allele frequency distribution at this locus may be approximated by the infinite allele model. The data also demonstrate that alleles that are shared by all populations have the highest average frequency within populations. Furthermore, the kinship bioassay analysis demonstrates that the extensive variation observed at the D1S80 locus is at the interindividual within population level, which dwarfs any interpopulation allele frequency variation, consistent with the population dynamics of hypervariable polymorphisms. These characteristics of the D1S80 locus make it a very useful marker for population genetic research, genetic linkage studies, forensic identification of individuals, and for determination of biological relatedness of individuals.     

Population genetics of dinucleotide (dC-dA)n.(dG-dT)n polymorphisms in world populations.

We have characterized eight dinucleotide (dC-dA)n.(dG-dT)n repeat loci located on human chromosome 13q in eight human populations and in a sample of chimpanzees. Even though there is substantial variation in allele frequencies at each locus, at a given locus the most frequent alleles are shared by all human populations. The level of heterozygosity is reduced in isolated or small populations, such as the Pehuenche Indians of Chile, the Dogrib of Canada, and the New Guinea highlanders. On the other hand, larger average heterozygosities are observed in large and cosmopolitan populations, such as the Sokoto population from Nigeria and German Caucasians. Conformity with Hardy-Weinberg equilibrium is generally observed at these loci, unless (a) a population is isolated or small or (b) the repeat motif of the locus is not perfect (e.g., D13S197). Multilocus genotype probabilities at these microsatellite loci do not show departure from the independence rule, unless the loci are closely linked. The allele size distributions at these (CA)n loci do not follow a strict single-step stepwise-mutation model. However, this features does not compromise the ability to detect population affinities, when these loci are used simultaneously. The microsatellite loci examined here are present and, with the exception of the locus D13S197, are polymorphic in the chimpanzees, showing an overlapping distribution of allele sizes with those observed in human populations.     

Characteristics of polymorphism at a VNTR locus 3' to the apolipoprotein B gene in five human populations.

We have analyzed the allele frequency distribution at the hypervariable locus 3' to the apolipoprotein B gene (ApoB 3' VNTR) in five well-defined human populations (Kacharis of northeast India, New Guinea Highlanders of Papua New Guinea, Dogrib Indians of Canada, Pehuenche Indians of Chile, and a relatively homogeneous Caucasian population of northern German extraction) by using the PCR technique. A total of 12 segregating alleles were detected in the pooled sample of 319 individuals. A fairly consistent bimodal pattern of allele frequency distribution, apparent in most of these geographically and genetically diverse populations, suggests that the ApoB 3' VNTR polymorphism predates the geographic dispersal of ancestral human populations. In spite of the observed high degree of polymorphism at this locus (expected heterozygosity levels 55%-78%), the genotype distributions in all populations (irrespective of their tribal or cosmopolitan nature) conform to their respective Hardy-Weinberg predictions. Furthermore, analysis of the congruence between expected heterozygosity and the observed number of alleles reveals that, in general, the allele frequency distributions at this locus are in agreement with the predictions of the classical mutation-drift models. The data also show that alleles that are shared by all populations have the highest average frequency within populations. These findings demonstrate the potential utility of highly informative hypervariable loci such as the ApoB 3' VNTR locus in population genetic research, as well as in forensic medicine and determination of biological relatedness of individuals.     

Human minisatellite alleles detectable only after PCR amplification.

We present evidence that a proportion of alleles at two human minisatellite loci is undetected by standard Southern blot hybridization. In each case the missing allele(s) can be identified after PCR amplification and correspond to tandem arrays too short to detect by hybridization. At one locus, there is only one undetected allele (population frequency 0.3), which contains just three repeat units. At the second locus, there are at least five undetected alleles (total population frequency 0.9) containing 60-120 repeats; they are not detected because these tandem repeats give very poor signals when used as a probe in standard Southern blot hybridization, and also cross-hybridize with other sequences in the genome. Under these circumstances only signals from the longest tandemly repeated alleles are detectable above the nonspecific background. The structures of these loci have been compared in human and primate DNA, and at one locus the short human allele containing three repeat units is shown to be an intermediate state in the expansion of a monomeric precursor allele in primates to high copy number in the longer human arrays. We discuss the implications of such loci for studies of human populations, minisatellite isolation by cloning, and the evolution of highly variable tandem arrays.     

Direct molecular analysis of the fragile X syndrome in a sample of Egyptian and German patients using non-radioactive PCR and Southern blot followed by chemiluminescent detection

Molecular genetic analysis of individuals from 6 Egyptian and 33 German families with fragile X syndrome and 240 further patients with mental retardation was performed applying a completely non-radioactive system. The aim of our study was the development of a non-radioactive detection method and its implementation in molecular diagnosis of the fragile X syndrome. Furthermore, we wanted to assess differences in the mutation sizes between Egyptian and German patients and between Egyptian and German carriers of a premutation. Using non-radioactive polymerase chain reaction (PCR), agarose gel electrophoresis and blotting of the PCR products, followed by hybridisation with a digoxigenin-labelled oligonucleotide probe (CGG)₅ and chemiluminescent detection, we identified the fragile X full mutation (amplification of a CGG repeat in the FMR-1 gene ranging from several hundred to several thousand repeat units) in all patients. We observed no differences in the length of the CGG repeat between the Egyptian and German patients and carriers, respectively. However, in one prenatal diagnosis, we detected only one normal sized allele in a female fetus using the PCR-agarose assay, whereas Southern blot analysis with the digoxigenin labelled probe StB 12.3 revealed presence of a full mutation. Our newly established nonradioactive genomic blotting method is based on the conventional radioactive Southern blot analysis. Labelling of the probe StB 12.3 with digoxigenin via PCR allowed the detection of normal, premutated and fully mutated alleles. For exact sizing of small premutated or large normal alleles, we separated digoxigenin labelled PCR products through denaturing poly-acrylamide gelelectrophoresis (PAGE) and transfered them to a nylon membrane using a gel dryer. The blotted PCR-fragments can easily be detected with alkaline phosphate-labelled anti-digoxigenin antibody. The number of trinucleotide repeat units can be determined by scoring the detected bands against a digoxigenated M13 sequencing ladder. Our newly developed digoxigenin/chemiluminescence approach using PCR and Southern blot analysis provides reliable results for routine detection of full fragile X mutations and premutations.     

Genetic studies of low-abundance human plasma proteins. V. Evidence for a second orosomucoid structural locus (ORM2) expressed in plasma.

Orosomucoid (ORM) or alpha-1-acid glycoprotein is an acute-phase protein of human plasma whose function is suggested to be the competitive inhibition of cellular recognition by infective agents. Genetically determined variation in ORM has been reported, with two major alleles segregating in all populations studied to date. Isoelectric focusing-immunoblotting studies of ORM revealed the presence of isoprotein species that did not segregate with the predominant alleles at the ORM locus and suggested the expression of a second structural gene locus for orosomucoid (ORM2). Genetically independent variation consistent with expression of the ORM2 locus was observed in plasma samples from American blacks but was not observed in U.S. whites or sampled populations of North- and South-American Indians, Eskimos, Aleuts, or New Guinea Highlanders. The population allele frequencies for this locus were .958, .025, .006, and .011 for alleles ORM*1, ORM2*2, ORM2*3, and ORM2*4, respectively. Family studies confirm the autosomal codominant inheritance of the observed phenotypes.     

Analysis of a CGG sequence at the FMR-1 locus in fragile X families and in the general population.

In this study, we have characterized a CGG repeat at the FMR-1 locus in more than 100 families (more than 500 individuals) presenting for fragile X testing and in 247 individuals from the general population. Both Southern blot and PCR-based assays were evaluated for their ability to detect premutations, full mutations, and variability in normal allele sizes. Among the Southern blot assays, the probes Ox1.9 or StB12.3 with a double restriction-enzyme digest were the most sensitive in detecting both small and large amplifications and, in addition, provided information on methylation of an adjacent CpG island. In the PCR-based assays, analysis of PCR products on denaturing DNA sequencing gels allowed the most accurate determination of CGG repeat number up to approximately 130 repeats. A combination of a Southern blot assay with a double digest and the PCR-sequencing-gel assay detected the spectrum of amplification-type mutations at the FMR-1 locus. In the patient population, a CGG repeat of 51 was the largest to be stably inherited, and a repeat of 57 was the smallest size of premutation to be unstably inherited. When premutations were transmitted by females, the size of repeat correlated with risk of expansion to a full mutation in the next generation. Full mutations (large repeats typically associated with an abnormal methylation pattern and mitotic instability) were associated with clinical and cytogenetic manifestations in males but not necessarily in females. In the control population, the CGG repeat ranged from 13 to 61, but 94% of alleles had fewer than 40 repeats. The most frequent allele (34%) was a repeat of 30. One female had an allele (61 repeats) within a range consistent with fragile X premutations, while two other individuals each had a repeat of 52. This suggests that the frequency of unstable alleles in the general population may be approximately 1%.     

Analysis of the VNTR locus D1S80 by the PCR followed by high-resolution PAGE.

Allelic data for the D1S80 locus was obtained by using the PCR and subsequent analysis with a high-resolution, horizontal PAGE technique and silver staining. Compared with RFLP analysis of VNTR loci by Southern blotting, the approach described in this paper offers certain advantages: (1) discrete allele resolution, (2) minimal measurement error, (3) correct genotyping of single-band VNTR patterns, (4) a nonisotopic assay, (5) a permanent record of the electrophoretic separation, and (6) reduced assay time. In a sample of 99 unrelated Caucasians, the D1S80 locus demonstrated a heterozygosity of 80.8% with 37 phenotypes and 16 alleles. The distribution of genotypes is in agreement with expected values according to the Hardy-Weinberg equilibrium. Furthermore, the observed number of alleles and the level of heterozygosity, obtained through the protocol described here, were congruent with each other in accordance with the expectation of a mutation-drift equilibrium model for a single, homogeneous, random-mating population. Therefore, the analysis of D1S80 and similar VNTR loci by amplified fragment length polymorphism (AMP-FLP) may prove useful as models for population genetic issues for VNTR loci analyzed by RFLP typing via Southern blotting.     

DNA sequence variation of the human ABO-secretor locus (FUT2) in New Guinean populations: possible early human migration from Africa

We have investigated the allelic polymorphism of the human ABO-secretor locus (FUT2) in 90 unrelated Papuan-speaking New Guineans (Dani group), 101 admixed New Guineans from Irian Jaya, Indonesia, and 32 New Guineans from Papua New Guinea by DNA sequencing analysis. Whereas the total frequency of various nonfunctional alleles at the FUT2 locus in the worldwide populations so far examined is around 0.5, we have found only one individual heterozygous for a nonfunctional allele in the 90 Dani group members and a frequency of nonfunctional alleles of 0.1–0.2 in the admixed New Guineans. Admixed New Guineans had the Asian-specific null allele se³⁸⁵ and the characteristic nonfunctional allele se^del2 found in Polynesians. In addition, both New Guinean populations had unique functional alleles (Se³⁷⁵ and Se⁴⁰⁰) with high frequencies (0.11–0.37); these are absent in other populations of the world except for African and Samoan populations. The Se³⁷⁵ allele had G and C at positions 1009 and 1011 of the 3' untranslated region, respectively, whereas all other FUT2 alleles found so far in the world, except for se⁴²⁸, have 1009A and 1011T. The Se³⁷⁵ allele found in Africans has 1009G and 1011T, or 1009A and 1011T. Corresponding positions of nonhuman primates have G and C, suggesting that the Se³⁷⁵ allele is one of the ancestral alleles, reflecting the early human migration from Africa to New Guinea and the long isolation of Dani populations from neighboring populations.     

Simple fluorescent PCR assay for discriminating FRAXA fully mutated females from normal homozygotes

Fragile X syndrome linked to the FRAXA locus is the most common inherited genetic disease accounting for mental retardation and is usually caused by the expansion of an unstable CGG repeat in the first exon of the FMR1 gene on the X chromosome. Despite its robustness, Southern blot is not suitable for large-scale routine screening as part of neuropediatric practice. PCR appears as an interesting alternative, and various protocols have been successfully applied to molecular screening in mentally retarded boys and girls. Unfortunately, as of this date these protocols are unable to detect the expanded allele in FRAXA females reliably, thereby failing to discriminate between fully mutated females from normal homozygotes. Therefore, we opted for an alternative approach in designing a semiquantitative PCR assay, based on the amplification of the sole wild-type allele. This method allowed us to detect the presence of one or two normal alleles with the same sizes, thereby discriminating between a FRAXA fully mutated female or a normal homozygote, respectively. A trial on 95 DNA samples from normal and mutated females demonstrated the reliability of the procedure. We believe this simple PCR assay is a powerful approach that would reduce the recourse to Southern blotting in females with mental retardation of unknown etiology.     

Estimation of genotyping error rate from repeat genotyping,unintentional recaptures and known parent–offspring comparisons in 16 microsatellite loci for brown rockfish (Sebastes auriculatus)

Genotyping errors are present in almost all genetic data and can affect biological conclusions of a study, particularly for studies based on individual identification and parentage. Many statistical approaches can incorporate genotyping errors, but usually need accurate estimates of error rates. Here, we used a new microsatellite data set developed for brown rockfish (Sebastes auriculatus) to estimate genotyping error using three approaches: (i) repeat genotyping 5% of samples, (ii) comparing unintentionally recaptured individuals and (iii) Mendelian inheritance error checking for known parent–offspring pairs. In each data set, we quantified genotyping error rate per allele due to allele drop‐out and false alleles. Genotyping error rate per locus revealed an average overall genotyping error rate by direct count of 0.3%, 1.5% and 1.7% (0.002, 0.007 and 0.008 per allele error rate) from replicate genotypes, known parent–offspring pairs and unintentionally recaptured individuals, respectively. By direct‐count error estimates, the recapture and known parent–offspring data sets revealed an error rate four times greater than estimated using repeat genotypes. There was no evidence of correlation between error rates and locus variability for all three data sets, and errors appeared to occur randomly over loci in the repeat genotypes, but not in recaptures and parent–offspring comparisons. Furthermore, there was no correlation in locus‐specific error rates between any two of the three data sets. Our data suggest that repeat genotyping may underestimate true error rates and may not estimate locus‐specific error rates accurately. We therefore suggest using methods for error estimation that correspond to the overall aim of the study (e.g. known parent–offspring comparisons in parentage studies).     

A population genetic survey of the haptoglobin polymorphism in Melanesians by DNA analysis.

We have determined the haptoglobin (Hp) genotypes of 831 Melanesians from Vanuatu, Papua New Guinea, and New Caledonia by Southern blot analysis of DNA extracted from umbilical cord and peripheral blood samples. There was complete agreement between these genotypes and the protein phenotype in cases where both were determined, and genotyping was possible in cases where no serum haptoglobins were measurable. Subtyping of Hp1 alleles using restriction enzymes showed that Melanesians, like Mongoloids and Australian Aboriginals, have only the Hp1S allele. Three cases of Hp Johnson were found in Vanuatu, and further restriction mapping supported a partial gene triplication model for the structure of this variant. We also report a new common BclI restriction enzyme polymorphism upstream of the Hp1 gene. The advantages of using DNA for haptoglobin typing are discussed.     

A minisatellite and a microsatellite polymorphism within 1.5 kb at the human muscle glycogen phosphorylase (PYGM) locus can be amplified by PCR and have combined informativeness of PIC 0.95.

We sequenced a genomic clone (pMCMP1), previously reported to detect a VNTR polymorphism at the PYGM locus, and found a dinucleotide repeat segment (CA)14(GA)25 and a complex (AT)-repeat-rich segment containing 63 repeats spanning 160 bp. Resolution of PCR-amplified genomic DNA from the (CA)(GA) repeat region on DNA sequencing gels revealed a highly informative polymorphism with alleles differing by 2-bp intervals and ranging in size from 156 to 190 bp. Among three racial groups, a total of 18 alleles were observed. Fourteen alleles were observed in Caucasians (PIC 0.89), 12 alleles in American Blacks (PIC 0.89), and 9 alleles in Pima Indians (PIC 0.73). PCR amplification of the (AT) repeat region and resolution of the products on DNA sequencing gels revealed a complex variable length polymorphism with alleles distributed in size from 367 to 970 bp. Twenty-eight alleles were found in American Blacks (PIC 0.94), 6 alleles in Pima Indians (PIC 0.70), and 11 alleles in Caucasians (PIC 0.71). Comparison of the previously described VNTR RFLP alleles visualized by Southern hybridization to the PCR products described in this report demonstrated that the polymorphism described in both assays was identical. However, a larger number of alleles could be detected from the PCR-amplified products. Combined informativeness, PIC 0.95, for the two polymorphisms was determined from haplotype analysis of 100 Caucasian chromosomes. Therefore, for genotyping purposes, informativeness is maximized from using both polymorphisms.     

Phylogenetic Analysis of the Friedreich Ataxia GAA Trinucleotide Repeat

Friedreich ataxia is an autosomal recessive neurodegenerative disorder associated with a GAA repeat expansion in the first intron of the gene (FRDA) encoding a novel, highly conserved, 210 amino acid protein known as frataxin. Normal variation in repeat size was determined by analysis of more than 600 DNA samples from seven human populations. This analysis showed that the most frequent allele had nine GAA repeats, and no alleles with fewer than five GAA repeats were found. The European and Syrian populations had the highest percentage of alleles with 10 or more GAA repeats, while the Papua New Guinea population did not have any alleles carrying more than 10 GAA repeats. The distributions of repeat sizes in the European, Syrian, and African American populations were significantly different from those in the Asian and Papua New Guinea populations (p < 0.001). The GAA repeat size was also determined in five nonhuman primates. Samples from 10 chimpanzees, 3 orangutans, 1 gorilla, 1 rhesus macaque, 1 mangabey, and 1 tamarin were analyzed. Among those primates belonging to the Pongidae family, the chimpanzees were found to carry three or four GAA repeats, the orangutans had four or five GAA repeats, and the gorilla carried three GAA repeats. In primates belonging to the Cercopithecidae family, three GAA repeats were found in the mangabey and two in the rhesus macaque. However, an AluY subfamily member inserted in the poly(A) tract preceding the GAA repeat region in the rhesus macaque, making the amplified sequence approximately 300 bp longer. The GAA repeat was also found in the tamarin, suggesting that it arose at least 40 million years ago and remained relatively small throughout the majority of primate evolution, with a punctuated expansion in the human genome. Received: 18 August 2000 / Accepted: 10 November 2000     

An allele-specific genotyping method for rat lyst (lysosomal trafficking regulator) gene.

Two spontaneous mutant beige rats, with phenotypes resembling human Chediak- Higashi syndrome (CHS), were found independently in two inbred strains. Both beige mutations were identified to be recessive alleles in the Lyst locus on rat chromosome 17 and the alleles were denoted Lyst(bg) and Lyst(bg-Kyo). As it is almost impossible to discriminate these mutations phenotypically, we developed an allele-specific genotyping method for the Lyst gene. The nested PCR amplification was followed by restriction fragment length polymorphism (RFLP) analysis. By this method, we could discriminate the mutant Lyst(bg), Lyst(bg-Kyo) alleles, and the normal Lyst allele, easily and accurately.     

Genotyping of pantophysin I (Pan I) of Atlantic cod (Gadus morhua L.) by allele‐specific PCR

The two main allelic variants of the Atlantic cod (Gadus morhua L.) pantophysin I (Pan I) locus have different frequencies within different cod stocks. The Dra I polymorphism which distinguishes the two alleles can thus be used for discrimination of coastal and offshore cod populations. We present a new method for Pan I genotyping using fluorescent allele‐specific duplex polymerase chain reaction (PCR). This method is more rapid, reliable and cost‐effective than the previously published method and it is not affected by DNA source and quality. This improvement is important for studies demanding high throughput and accuracy of Pan I genotyping     

Patterns of instability of expanded CAG repeats at the ERDA1 locus in general populations.

A highly polymorphic CAG repeat locus, ERDA1, was recently described on human chromosome 17q21.3, with alleles as large as 50-90 repeats and without any disease association in the general population. We have studied allelic distribution at this locus in five human populations and have characterized the mutational patterns by direct observation of 731 meioses. The data show that large alleles (>/=40 CAG repeats) are generally most common in Asian populations, less common in populations of European ancestry, and least common among Africans. We have observed a high intergenerational instability (46. 3%+/-5.1%) of the large alleles. Although the mutation rate is not dependent on parental sex, paternal transmissions have predominantly resulted in contractions, whereas maternal transmissions have yielded expansions. Within this class of large alleles, the mutation rate increases concomitantly with increasing allele size, but the magnitude of repeat size change does not depend on the size of the progenitor allele. Sequencing of specific alleles reveals that the intermediate-sized alleles (30-40 repeats) have CAT/CAC interruptions within the CAG-repeat array. These results indicate that expansion and instability of trinucleotide repeats are not exclusively disease-associated phenomena. The implications of the existence of massively expanded alleles in the general populations are not yet understood.     

Evolution of Microsatellite Alleles in Four Species of Mice (Genus Apodemus)

Microsatellite length variation was investigated at a highly variable microsatellite locus in four species of Apodemus. Information obtained from microsatellite allele sequences was contrasted with allele sizes, which included 18 electromorphs. Additional analysis of a 400-bp unique sequence in the flanking region identified 26 different haplotype sequences or ``true' alleles in the sample. Three molecular mechanisms, namely, (1) addition/deletion of repeats, (2) substitutions and indels in the flanking region, and (3) mutations interrupting the repeat, contributed to the generation of allelic variation. Size homoplasy can be inferred for alleles within populations, from different populations of the same species, and from different species. We propose that microsatellite flanking sequences may be informative markers for investigating mutation processes in microsatellite repeats as well as phylogenetic relationships among alleles, populations, and species. Received: 3 November 1999 / Accepted: 2 May 2000     

Evolution and selection of Rhg1, a copy‐number variant nematode‐resistance locus

The soybean cyst nematode (SCN) resistance locus Rhg1 is a tandem repeat of a 31.2 kb unit of the soybean genome. Each 31.2‐kb unit contains four genes. One allele of Rhg1, Rhg1‐b, is responsible for protecting most US soybean production from SCN. Whole‐genome sequencing was performed, and PCR assays were developed to investigate allelic variation in sequence and copy number of the Rhg1 locus across a population of soybean germplasm accessions. Four distinct sequences of the 31.2‐kb repeat unit were identified, and some Rhg1 alleles carry up to three different types of repeat unit. The total number of copies of the repeat varies from 1 to 10 per haploid genome. Both copy number and sequence of the repeat correlate with the resistance phenotype, and the Rhg1 locus shows strong signatures of selection. Significant linkage disequilibrium in the genome outside the boundaries of the repeat allowed the Rhg1 genotype to be inferred using high‐density single nucleotide polymorphism genotyping of 15 996 accessions. Over 860 germplasm accessions were found likely to possess Rhg1 alleles. The regions surrounding the repeat show indications of non‐neutral evolution and high genetic variability in populations from different geographic locations, but without evidence of fixation of the resistant genotype. A compelling explanation of these results is that balancing selection is in operation at Rhg1.