Factors of maintaining chromosome polymorphism in common vole Microtus arvalis Pallas, 1779: reduced fertility and meiotic drive

The common vole Microtus arvalis (the form obscurus) exhibits polymorphism of a pericentric inversion in chromosome pair 5 throughout the species range. In the Urals populations, the frequency of an acrocentric variant of the heteromorphic chromosome is very low (on average 3.2%) and virtually does not change annually. The factors of maintaining stable chromosomal polymorphism in the common vole were studied under conditions of a laboratory colony. Heterozygous and homozygous for the acrocentric chromosome females showed a significant reduction of the reproductive output irrespective of the male karyotype. This effect was manifested mostly in litter size at birth. A number of cytogenetic and exophenotypic characteristics, as well as parent--offspring transmission of this chromosome in crosses of various types, were examined. We have found meiotic drive in favor of the acrocentric, as a result of which the frequency of the acrocentric (without taking into account the postnatal mortality) totaled over all cross variants (0.48) was significantly higher than that expected with random segregation (0.42). It is likely that meiotic drive of the acrocentric largely compensates for the reduced fertility of its carriers, being among the factors of maintaining it in natural populations.     

Factors of maintaining chromosome polymorphism in common vole Microtus arvalis pallas, 1779: Reduced fertility and meiotic drive

The common vole Microtus arvalis (the form obscurus) exhibits polymorphism of a pericentric inversion in chromosome pair 5 throughout the species range. In the Urals populations, the frequency of an acrocentric variant of the heteromorphic chromosome is very low (on average 3.2%) and virtually does not change annually. The factors of maintaining stable chromosomal polymorphism in the common vole were studied under conditions of a laboratory colony. Heterozygous and homozygous for the acrocentric chromosome females showed a significant reduction of the reproductive output irrespective of the male karyotype. This effect was manifested mostly in litter size at birth. A number of cytogenetic and exophenotypic characteristics, as well as parent-offspring transmission of this chromosome in crosses of various types, were examined. We have found meiotic drive in favor of the acrocentric, as a result of which the frequency of the acrocentric (without taking into account the postnatal mortality) totaled over all cross variants (0.48) was significantly higher than that expected with random segregation (0.42). It is likely that meiotic drive of the acrocentric largely compensates for the reduced fertility of its carriers, being among the factors of maintaining it in natural populations.     

Molecular analysis of recombination in a family with Duchenne muscular dystrophy and a large pericentric X chromosome inversion.

It has been demonstrated in animal studies that, in animals heterozygous for pericentric chromosomal inversions, loop formation is greatly reduced during meiosis. This results in absence of recombination within the inverted segment, with recombination seen only outside the inversion. A recent study in yeast has shown that telomeres, rather than centromeres, lead in chromosome movement just prior to meiosis and may be involved in promoting recombination. We studied by cytogenetic analysis and DNA polymorphisms the nature of meiotic recombination in a three-generation family with a large pericentric X chromosome inversion, inv(X)(p21.1q26), in which Duchenne muscular dystrophy (DMD) was cosegregating with the inversion. On DNA analysis there was no evidence of meiotic recombination between the inverted and normal X chromosomes in the inverted segment. Recombination was seen at the telomeric regions, Xp22 and Xq27-28. No deletion or point mutation was found on analysis of the DMD gene. On the basis of the FISH results, we believe that the X inversion is the mutation responsible for DMD in this family. Our results indicate that (1) pericentric X chromosome inversions result in reduction of recombination between the normal and inverted X chromosomes; (2) meiotic X chromosome pairing in these individuals is likely initiated at the telomeres; and (3) in this family DMD is caused by the pericentric inversion.     

Genetic variability in Muscari comosum L. (Liliaceae) IV Geographical distribution and adaptive role of the polymorphic variants of chromosome 2

Muscari comosum L. (Liliaceae) has a chromosomal polymorphism for a pericentric inversion and a supernumerary chromosome segment probably due to an unequal interchange or insertional translocation. Both arrangements are widely distributed throughout the species range and the mean genetic distance among populations is D=0.131±0.075. There are no correlations between genetic distance and geographic distance or latitude. Only appreciable decreases in the frequencies of the inversion are detected in populations with ecologically marginal characteristics. There is a permanent and extended association between chromosomal inversion and an enzymatic locus (ADH). An excess of individuals heterozygous for the inversion was found and female productivity of heterozygotes is higher than that of corresponding homozygotes. A low rate of inversion heterozygosity in populations with ecologically marginal characteristics could be explained by natural selection. With respect to the adaptive role of the segment, although no homozygotes are found and may be selected against, heterozygotes could have heterotic effects.     

Evidence for a role of the synaptonemal complex in provision for normal chromosome disjunction at meiosis II in maize

The meiotic behavior of heterozygotes from three different maize pericentric inversion stocks was quantitatively observed at a variety of stages throughout meiosis I and II. With heterozygosity for either of two of these inversions, the usual mode of pairing observed at pachytene involved synapsis of the centromere containing inverted region, and synaptic failure of the centromere region was rarely found. Abnormal chromosome behavior at subsequent meiotic stages was rare in these cases. With heterozygosity for the third inversion, however, homologous synapsis was generally found in the distal regions of the chromosome involved, the inverted region was often non-homologously synapsed, and a substantial frequency of cells apparently showed synaptic failure in the centromere containing inverted region. A substantial frequency of cells at anaphase II in this case contained two lagging monads in the plate region of the spindle. Where cells could be identified as sisters, sister cells showed identical behavior at anaphase II. Findings seem to be most simply explained by the supposition that pachytene synapsis of the centromere region is important to provision for sister centromere association until anaphase II.     

Meiotic analysis of a pericentric inversion, inv(7) (p22q32), in the father of a child with a duplication-deletion of chromosome 7

In a family in which a large pericentric inversion of chromosome 7 is segregating, two of the four progeny of inversion heterozygotes show severe psychomotor retardation and have the karyotype 46,XX,rec(7),dup q,inv(7)(p22q32), derived from crossing-over within the inversion. Meiotic analysis in one of the heterozygotes revealed no evidence of inversion loops in well-spread pachytene cells. In approximately 20% of cells in diakinesis, the presumptive bivalent 7 had only one chiasma. Two alternatives to the reversed loop mode of meiotic pairing of inversions are proposed. Review of the literature supports the view that "small" pericentric inversions have a much better genetic prognosis than "large" pericentric inversions.     

Inversion homozygosity of chromosome no. 9 in a higly inbred kindred.

A pericentric inversion of chromosome no. 9 was present in seven of 10 members of a highly inbred kindred investigated; two were inversion homozygotes and five were heterozygotes. Inversion homozygosity was observed in both the propositus, ascertained because of ambiguous genitalia, and his phenotypically normal father. A phenotypically normal sister and brother with similar clinical findings proved to be inversion heterozygotes. These findings conclude that no causal relationship exists between the inversion and the abnormal phenotype.     

The Fertility Effects of Pericentric Inversions in Drosophila Melanogaster

Heterozygotes for pericentric inversions are expected to be semisterile because recombination in the inverted region produces aneuploid gametes. Newly arising pericentric inversions should therefore be quickly eliminated from populations by natural selection. The occasional polymorphism for such inversions and their fixation among closely related species have supported the idea that genetic drift in very small populations can overcome natural selection in the wild. We studied the effect of 7 second-chromosome and 30 third-chromosome pericentric inversions on the fertility of heterokaryotypic Drosophila melanogaster females. Surprisingly, fertility was not significantly reduced in many cases, even when the inversion was quite large. This lack of underdominance is almost certainly due to suppressed recombination in inversion heterozygotes, a phenomenon previously observed in Drosophila. In the large sample of third-chromosome inversions, the degree of underdominance depends far more on the position of breakpoints than on the inversion's length. Analysis of these positions shows that this chromosome has a pair of ``sensitive sites' near cytological divisions 68 and 92: these sites appear to reduce recombination in a heterozygous inversion whose breakpoints are nearby. There may also be ``sensitive sites' near divisions 31 and 49 on the second chromosome. Such sites may be important in initiating synapsis. Because many pericentric inversions do not reduce the fertility of heterozyotes, we conclude that the observed fixation or polymorphism of such rearrangements in nature does not imply genetic drift in very small populations.     

Pericentric inversion of chromosome 12; a three family study

Summary A pericentric inversion of chromosome 12 has been followed in three large independently ascertained Danish families. Out of a total number of 52 persons examined, 25 were found to carry the inversion. The break-points in all three families were localized to p13 and q13, resulting in more than one-third of the total length of the chromosomes being inverted. However, no chromosomal aberrations arising because of meiotic crossing-over inside the inverted area have been found among the offspring of the carriers. The percentage of spontaneous abortions among carriers is found to be high, viz. 33%. The segregation rate is calculated to be 0.58, which is not significantly different from an expected segregation rate of 0.5. In family 3, an additional inversion of a chromosome 9 has been found in 4 individuals. Our results are discussed in relation to previous findings and with respect to the genetic counselling of families with pericentric inversions.     

Lack of Underdominance in a Naturally Occurring Pericentric Inversion in Drosophila Melanogaster and Its Implications for Chromosome Evolution

In(2LR)PL is a large pericentric inversion polymorphic in populations of Drosophila melanogaster on two Indian Ocean islands. This polymorphism is puzzling: because crossing over in female heterokaryotypes produces inviable zygotes, such inversions are thought to be underdominant and should be quickly eliminated from populations. The observed fixation for such inversions among related species has led to the idea that genetic drift can cause chromosome evolution in opposition to natural selection. We found, however, that In(2LR)PL is not underdominant for fertility, as heterokaryotypic females produce perfectly viable eggs. Genetic analysis shows that the lack of underdominance results from the nearly complete absence of crossing over in the inverted region. This phenomenon is probably caused by mechanical and not genetic factors, because crossing over is not suppressed in In(2LR)PL homokaryotypes. Our observations do not support the idea that the fixation of pericentric inversions among closely related species implies the action of genetic drift overcoming strong natural selection in very small populations. If chromosome arrangements vary in their underdominance, it is those with the least disadvantage as heterozygotes, like In(2LR)PL, that will be polymorphic or fixed in natural populations.     

Frequency of recombinant and nonrecombinant products of pericentric inversion of chromosome 1 in sperm nuclei of carrier: by FISH technique

Meiotic segregation products of carriers with pericentric inversion are very important for assessing the risk of unbalanced forms and appropriate genetic counseling. We investigated the incidence of recombinant and nonrecombinant products of chromosome 1 with pericentric inversion, in the sperm nuclei of the carrier by using triple color fluorescence in situ hybridization (FISH). The centromere specific and telomere specific probes for chromosome 1 were used. In the segregation analysis, 1,636 sperm nuclei were analyzed; 82.5% of the sperms were including normal or inverted chromosome 1, and the dup(p)/del(q) and del(p)/dup(q) recombinant products in sperm nuclei of our carrier were 8.7 and 7.3%, respectively. The number of recombinant products may be dependent on the formation of an inversion loop, which the number of the formation of chiasmata results in the different number of normal/balanced and recombinant products. The use of FISH, using different probe combination, in sperm nuclei has proved to be an accurate approach to determine the meiotic segregation patterns and could help to better establish a reproductive prognosis and genetic counseling.     

Chiasma studies in structural hybrids IX. Crossing-over in pericentric inversion ofScilla scilloides

InScilla scilloides (Lindle) Druce, the heterozygotes for a pericentric inversion were found to be predominant in a small natural population consisting of cytogenetic type BB (2n=18). Pericentric inversion may include about half the length of the original subtelocentric chromosome, changing it to submetacentric. The 9II were always formed in these heterozygotes as well as in normal plants at MI in PMCs. A single chiasma was formed in the shorter one of two inverted segments divided by the kinetochore at MI, while one or two inversion chiasmata were observed in the longer segment. The AI separation was always regular. Since both arms of a normal chromosome and those of an inverted one were clearly distinguishable from one another at AI and AII, two kinds of crossover chromatids could be identified. Both sides of the single inversion chiasma always opened out reductionally. The frequency of bivalent without inversion chiasma agreed statistically with that of half-bivalent at AI or chromatid structure at AII, which resulted from non crossing-over within the inverted segment. Likewise, no statistical difference was found between the frequency of a single chiasma and that of a single crossing-over product in a longer inverted segment. These findings have clearly proved that the chiasma is a consequence of genetic crossing-over. The average proportion of good pollen grains in the inversion heterozygotes, 53.6%, amounted to about half that of normal plants, 97.7%.     

The clinical significance of pericentric inversion of the human Y chromosome: a rare "third" type of heteromorphism

A 28-year-old normal East Indian was found to have a pericentric inversion of the Y chromosome. After reviewing the literature, it was concluded that an inverted Y chromosome does not impede the production of normal sperm and does not predispose to non-disjunction of other chromosomes in the progeny. Thus, the earlier concept of nondisjunction was rejected, and it is suggested that aberrant cases with aneuploidy and an inverted Y are fortuitous. The pericentric inverted Y is inherited from generation to generation and has no clinical significance. The prevalence of males with pericentric Y inversion in the general population is approximately 1 per 1000. It is suggested that a pericentric inversion of the Y chromosome is a rare chromosomal heteromorphism and should be called type III.     

Synapsis of a chromosomal pair heterozygous for a pericentric inversion and the presence of a heterochromatic short arm

Analysis of meiotic pairing configurations in a deer mouse heterozygous for both a pericentric inversion and the presence of a heterochromatic short arm at chromosome 15 revealed straight-paired synaptonemal complexes with equal axial lengths in a majority of the pachytene nuclei. Nonhomologous pairing in this bivalent occurs by direct heterosynapsis of the inverted segments followed by synaptic adjustment of the heterochromatin heteromorphism.     

Meiosis and speciation: A study in a speciatingMus terricolor complex

The three chromosomal species of theMus terricolor complex possess 2n = 40 chromosomes. We show that their karyotypes differ in stable heterochromatin variations fixed in homozygous condition as prominent short arms in autosomes 1, 3 and 6. The three chromosomal species exhibit a high incidence of polymorphisms for Robertsonian fusions and pericentric inversions. Breeding experiments and histological analysis of testis show that heterozygosity for pericentric inversions and Robertsonian fusions had no effect on fertility. Meiotic analysis shows normal overall progression of meiosis in the heterozygotes, which is consistent with their normal gametogenesis. Nevertheless, both the inversion and fusion heterozygotes had undergone some alterations in the regular process of homologous synapsis, and it appeared that certain features of the meiotic system circumvented the potential negative effects of these polymorphic chromosomal rearrangements. The results indicate that the attributes of the meiotic system in a given organism could modulate the potential of a chromosomal rearrangement as reproductive barrier. The meiotic modulation hypothesis offers an explanation for the contradictory effects of the similar kinds of chromosomal mutations reported in different species.     

Modification du caryotype par une inversion péricentrique à l'état homozygote chez l'Amphibien Urodèle Pleurodeles waltlii Michahelles

A cytogenetic study on four generations of the newt Pleurodeles waltlii has resulted in a stock homozygous for a pericentric inversion in chromosomes no. 6.-The chromosomal rearrangement has first been detected at the heterozygous state in a female resulting from a cross between a normal female and a male treated with X rays. — The rearranged chromosome is very easily recognizable under direct microscopic investigation. The heterozygotes and the homozygotes for the aberration grow normally; thus, the inversion constitutes a nuclear marker which can be readily used.     

Complex, compound inversion/translocation polymorphism in an ape: presumptive intermediate stage in the karyotypic evolution of the agile gibbon Hylobates agilis.

Karyotypic variation in five gibbon species of the subgenus Hylobates (2n = 44) was assessed in 63 animals, 23 of them wild born. Acquisition of key specimens of Hylobates agilis (agile gibbon), whose karyotype had been problematic due to unresolved structural polymorphisms, led to disclosure of a compound inversion/translocation polymorphism. A polymorphic region of chromosome 8 harboring two pericentric inversions, one nested within the other, was in turn bissected by one breakpoint of a reciprocal translocation. In double-inversion + translocation heterozygotes, the theoretical meiotic pairing configuration is a double inversion loop, with four arms of a translocation quadrivalent radiating from the loop. Electron-microscopic analysis of synaptonemal complex configurations consistently revealed translocation quadrivalents but no inversion loops. Rather, nonhomologous pairing was evident in the inverted region, a condition that should preclude crossing over and the subsequent production of duplication-deficiency gametes. This is corroborated by the existence of normal offspring of compound heterozygotes, indicating that fertility may not be reduced despite the topological complexity of this polymorphic system. The distribution of inversion and translocation morphs in these taxa suggests application of cytogenetics in identifying gibbon specimens and avoiding undesirable hybridization in captive breeding efforts.     

Meiotic mutations from natural populations ofDrosophila melanogaster

Two meiotic genes from natural populations are described. A female meiotic mutation,mei(1)g13, mapped to 17.4 on the X chromosome, causes nondisjunction of all homologs except for the fourth chromosomes. In addition, it reduces recombination by 10% in the homozygotes and causes 18% increased recombination in the heterozygotes. A male meiotic mutation,mei-1223 ^m144 , is located on the third chromosome. Although this mutation causes nondisjunction of all chromosomes, each chromosome pair exhibits a different nondisjunction frequency. Large variations in the sizes of the premature sperm heads observed in the homozygotes may reflect irregular meiotic pairing and the subsequent abnormal segregation, resulting in aneuploid chromosome complements.     

Cytological assessment of meiotic exchange in a human male with a pericentric inversion of chromosome No. 4.

Mitotic chromosome studies carried out on newborn male infant with congenital abnormalities and on his family members showed that the father and paternal grandmother were heterozygotes for an unequal pericentric inversion. The child appeared to have inherited a recombinant duplication/deletion chromosome. The results of meiotic studies carried out on a testicular biopsy from the father were used to ascertain the risk of recurrence of chromosomal abnormalities in future pregnancies. A model is presented which permits the analysis of C-banded diakinetic chromosomes as to whether crossing-over has occurred within the inversion segment or not. In the present study, it was estimated that either one or two cross-overs had occurred in 52% of the cells within the inversion segment. This would result in approximately 26% of the spermatozoa carrying either one of two types of duplication/deficiencies of chromosome No. 4.     

Modification of an existing chromosomal inversion to engineer a balancer for mouse chromosome 15

Chromosomal inversions are valuable genetic tools for mutagenesis screens, where appropriately marked inversions can be used as balancer chromosomes to recover and maintain mutations in the corresponding chromosomal region. For any inversion to be effective as a balancer, it should exhibit both dominant and recessive visible traits; ideally the recessive trait should be a fully penetrant lethality in which inversion homozygotes die before birth. Unfortunately, most inversions recovered by classical radiation or chemical mutagenesis techniques do not have an overt phenotype in either the heterozygous or the homozygous state. However, they can be modified by relatively simple procedures to make them suitable as an appropriately marked balancer. We have used homologous recombination to modify, in embryonic stem cells, the recessive-lethal In(15)21Rk inversion to endow it with a dominant-visible phenotype. Several ES cell lines were derived from inversion heterozygotes, and a keratin-14 (K14) promoter-driven agouti minigene was introduced onto the inverted chromosome 15 in the ES cells by gene targeting. Mice derived from the targeted ES cells carry the inverted chromosome 15 and, at the same time, exhibit lighter coat color on their ears and tails, making this modified In(15)21Rk useful as a balancer for proximal mouse chromosome 15.