Laboratory mice carrying three pairs of Robertsonian translocations: establishment of a strain and analysis of meiotic segregation

Abstract

The evolution of a 2n = 34 combined Robertsonian translocation strain Rb(5.19)1Wh/(6.15)1Ald/(8.17)HEM is described. Homozygotes had three large ring translocation bivalents at M I and regular meiotic disjunction at M II. Male and female F_1· heterozygotes had similar frequencies of abnormal meiotic disjunction at M II, but aneuploid embryos were more frequent in (F₁♂ X NIH GP ♀) crosses (25.6%) than (F₁ ♀ X GP ♂) crosses (13.5%) at 10 days’ gestation. It could not be determined whether this discrepancy was genetic in origin or due to limitations in the techniques of M II analysis. Rb(5.19), as well as Rb(6.15) or (8.17), contributed to the aneuploidy, although previous M II analysis of singly heterozygous Rb(5.19)/+ males demonstrated comparatively regular meiotic disjunction. Trisomic embryos were not detected beyond 10 days in five (F₁ ♀ X GP ♂) crosses, suggesting that their survival in F₁ females is limited. The ratios of the different types of balanced embryos from the (F₁ X GP) crosses indicated random meiotic segregation of the three translocation chromosomes in triple heterozygotes. Analysis of complementary groups of balanced embryos from the same crosses also demonstrated lack of preferential segregation of the translocations; embryos with translocations and those with their corresponding homologous acrocentrics were equally frequent. Triploid embryos (3.3 %) were also detected in (F₁♂ X NIH GP ♀) crosses. The translocations and Y chromosome served as paternal markers, permitting its origin to be determined in two of three cases (dispermy). One growth-retarded triploid had a distinctive anomaly: failure of lens induction and lack of optic cup development. The combined strain provided a complex of markers for determining polyploidy mechanisms, as well as a common genetic background for comparing behavior of the three translocations at M I.