DETECTION OF NONDISJUNCTION AND RECOMBINATION IN MEIOTIC AND POSTMEIOTIC CELLS FROM XY(SXR) [XY,TP(Y)1CT] MICE USING MULTICOLOR FLUORESCENCE IN-SITU HYBRIDIZATION

Current meiotic dogma holds that synapsis is required for recombination and that recombination is required for proper disjunction. The mouse chromosome aberration XY(Sxr) [sex reversal; redesignated XY, Tp(Y)1Ct] appears to challenge this assumption, for although chromosomes X and Y often fail to synapse and recombine, there is no dramatic increase in aneuploid progeny. An explanation of this conundrum might be that X-Y univalent spermatocytes do not survive. The phenotype of sex reversal is generated by the ''obligatory'' crossover between the X and Y chromosomes, which always occurs proximal to a duplicated copy of the testis determining gene Sry and transfers one copy from one chromatid of the Y chromosome to one chromatid of the X. Animals that inherit an X chromosome with the Sly gene are chromosomally female but phenotypically male. We have used fluorescence in situ hybridization (FISH) to visualize probes for the X and Y chromosomes and for the Sry sequence and chromosome 8 to track the fate of both recombinant and nonrecombinant chromosomes through metaphases I and II into spermatids and sperm. In the 219 gametes examined by multicolor FISH, the frequency of aneuploid products (XY or ''O'') was low (3.7%) despite a high frequency (66%) of X-Y separation at metaphase I, In balanced gametes, X and Y recombinant chromosomes slightly exceeded nonrecombinants. Both of these observations support the earlier proposal that asynapsis and nondisjunction in primary spermatocytes lead to their developmental arrest and degeneration.