Segregation products of male mice doubly heterozygous for the RB(6.16) and RB (16.17) translocations: influence of sperm karyotype on fertilizing competence under varying mating frequencies

Chromosomal Polymorphism and Speciation: The Case of the Genus Mazama (Cetartiodactyla; Cervidae)

Chromosomal polymorphism plays a major role in speciation processes in mammals with high rates of karyotypic evolution, as observed in the family Cervidae. One remarkable example is the genus Mazama that comprises wide inter- and intra-specific chromosomal variability. To evaluate the impact of chromosomal polymorphisms as reproductive barriers within the genus Mazama, inter-specific hybrids between Mazama gouazoubira and Mazama nemorivaga (MGO × MNE) and intra-specific hybrids between cytotypes of Mazama americana (MAM) differing by a tandem (TF) or centric fusion (Robertsonian translocations—RT) were evaluated. MGO × MNE hybrid fertility was evaluated by the seminal quality and testicular histology. MAM hybrids estimation of the meiotic segregation products was performed by sperm-FISH analysis. MGO × MNE hybrids analyses showed different degrees of fertility reduction, from severe subfertility to complete sterility. Regarding MAM, RT, and TF carriers showed a mean value for alternate segregation rate of 97.74%, and 67.23%, and adjacent segregation rate of 1.80%, and 29.07%, respectively. Our results suggested an efficient post-zygotic barrier represented by severe fertility reduction for MGO × MNE and MAM with heterozygous TF. Nevertheless, RT did not show a severe effect on the reproductive fitness in MAM. Our data support the validity of MGO and MNE as different species and reveals cryptic species within MAM.

Sperm chromosome study of two bulls heterozygous for different Robertsonian translocations

Haploid chromosomes of a total of 354 spermatozoa from two bulls heterozygous for different Robertsonian translocations, a Holstein-Friesian bull carrying a t(1;21) and a Japanese Black bull carrying a t(7;21), were analyzed using an interspecific in vitro fertilization system with zona-free hamster oocytes. The proportion of chromosomally normal and balanced spermatozoa was approximately equal in both carriers (51.8% and 47.0% in the 1/21 carrier, and 47.3% and 50.0% in the 7/21 carrier). The combined incidences of normal and balanced spermatozoa, i.e., incidences of spermatozoa resulting from alternate meiotic segregation were very high (98.8% and 97.3%) in both carrier. On the contrary, the incidences of chromosomally unbalanced spermatozoa resulting from adjacent meiotic segregation were only 0.6% and 2.7%. These results indicate that the alternate segregation of a trivalent chromosome is predominant in these Robertsonian translocation carriers.

Lack of Sharing of Spam1 (Ph-20) among Mouse Spermatids and Transmission Ratio Distortion1

Gametic equality is thought to exist, despite haploid gene action in mammalian spermiogenesis, because of product sharing via the intercellular bridges of conjoined spermatids. However, mice carrying different t-alleles have been known to produce functionally different sperm, leading to transmission ratio distortion (TRD), whose mechanism is unknown. The reduced Spam1 mRNA levels, previously shown to be associated with TRD and reduced fertility in mice carrying the Rb(6.16) or the Rb(6.15) Robertsonian translocation, are reflected in the levels of its encoded membrane protein (Spam1) and its accompanying insoluble hyaluronidase activity. Studies of the temporal expression pattern of Spam1 reveal that it is haploid expressed, with both the RNA and protein first appearing on Day 21.5. RNA fluorescence in situ hybridization and immunocytochemistry show both the mRNA and the protein to be compartmentalized. Compartmentalization of the mRNA along with its immediate translation and insertion of the protein in the plasma membrane suggests the nonsharing of Spam1 transcripts among spermatids, resulting in functionally different sperm in males with different Spam1 alleles. Evidence for biochemically different sperm in these heterozygous males was revealed by flow cytometry and confocal microscopy. Our findings support the notion that the Spam1 antigen is not shared, and we may have uncovered a mechanism for TRD.

Absence of selection against aneuploid mouse sperm at fertilization

Is there selection against aneuploid sperm during spermatogenesis and fertilization? To address this question, we used male mice doubly heterozygous for the Robertsonian (Rb) translocations Rb(6. 16)24Lub and Rb(16.17)7Bnr, which produce high levels of sperm aneuploid for chromosome 16, the mouse counterpart of human chromosome 21. The frequencies of aneuploid male gametes before and after fertilization were compared by analyzing approximately 500 meiosis II spermatocytes and approximately 500 first-cleavage zygotes using fluorescence in situ hybridization with a DNA painting probe mixture containing three biotin-labeled probes specific for chromosomes 8, 16, and 17 plus a digoxigenin-labeled probe specific for chromosome Y. Hyperhaploidy for chromosome 16 occurred in 20.0% of spermatocytes and in 21.8% of zygotes. Hypohaploidy for chromosome 16 occurred in 17.0% and 16.7% of spermatocytes and zygotes, respectively. In addition, there was no preferential association between chromosome 16 aneuploidy and either of the sex chromosomes, nor was there an elevation in aneuploidy for chromosomes not involved in the Rb translocations. These findings provide direct evidence that there is no selection against aneuploid sperm during spermiogenesis, fertilization, and the first cell cycle of zygotic development.

The murine Spam1 gene: RNA expression pattern and lower steady-state levels associated with the Rb(6.16) translocation

Recently we mapped the murine Spam1 gene to the proximal region of chromosome 6 (MMU 6). Based on the map location and physiological characteristics of its encoded sperm antigen, the gene is an attractive candidate for the sperm dysfunction seen in Rb(6.16) translocation heterozygotes and the reduced fertility of homozygotes. We have analyzed the expression of Spam1 mRNA in normal and Rb(6.16) mice. The expression of Spam1 mRNA was found to be: 1) tissue specific; it is expressed exclusively in testis; and 2) developmentally regulated, with a haploid expression. Notably, the steady-state mRNA level of Spam1 in Rb(6.16) homozygotes was 25-30% of that in chromosomally normal consomic mice and those homozygous for Rb(2.8) (7.18). In Rb(6.16) and Rb(6.15) heterozygotes the levels were 61% and 66% of the normal. Studies are currently under way to determine the protein levels and gene structure of Spam1, to detect the underlying cause of the mRNA reduction associated with these translocations.

The mouse Spam1 maps to proximal chromosome 6 and is a candidate for the sperm dysfunction in Rb(6.16)24Lub and Rb(6.15)1Ald heterozygotes

We have determined the chromosomal localization of the murine gene encoding the 68-kDa sperm adhesion molecule 1, Spam1 or Ph-20. Using two independent approaches, fluorescence in situ hybridization (FISH) and interspecific backcross analysis we show the Spam1 maps to proximal mouse Chromosome (Chr) 6. This map position is within the conserved linkage group corresponding to human Chr 7q, where the human homolog, SPAM 1, has been shown to map previously. Genetic mapping shows the gene to be very closely linked to Met, one of the most proximal loci on MMU 6. It thus places the gene near the centromere and the junction of the Rb(6.16)24Lub and Rb(6.15)1Ald translocations. The essential role of the Spam1 sperm antigen in mouse sperm-egg interactions and its gene location provide strong support for its candidacy as the gene involved in the dysfunction of mouse sperm bearing the Rb(6.16)24Lub or Rb(6.15)1Ald translocation.

Genetic analysis of the maternal factors controlling the survival of trisomy 16 mouse fetuses

The B x H recombinant inbred strains of mice were used to undertake a genetic analysis of the maternal factors controlling the survival of trisomy 16 fetuses. The data presented indicate that the prevalence of trisomic fetuses on day 15 of gestation varies significantly with the genetic background of the mother. The strain difference in the frequency of trisomy appears to be the result of selective elimination of trisomic fetuses. Various statistical methods employed to elucidate the genetic architecture of the trait from the recombinant inbred strains data indicate that the number of loci involved in the selection process ranges from one to five. Linkage association with two loci has been found; however, with a low probability level (P = 0.292).

Evidence for differential maturation of reciprocal sperm segregants in the murine Rb(6.16) translocation heterozygote

The fertilizing ability of unaged sperm and those aged experimentally in the cauda by surgically ligating the corpus epididymis in males carrying the Rb(6.16) translocation was studied. Chromosomally normal females were inseminated with unaged sperm delivered by males mating at 3-day intervals, and aged sperm were studied after matings on 6-14 postoperative days. The sperm chromosome complement was analyzed in first-cleavage metaphase zygotes after sequential G- and C-banding of the chromosomes. Of 283 metaphasic zygotes in the control group, 183 (or 64.7%) were analyzed and showed a ratio of 2.7:1 for chromosomally normal and balanced segregants of the translocation, deviating significantly (P less than 0.001) from the expected 1:1. The ratio of X- to Y-bearing sperm also deviated from expected (P less than 0.01) mostly due to a significant deficiency (P less than 0.05) of balanced sperm that were X-bearing. Fertilized oocytes were recovered from matings of 10 males on days 6-8 postoperatively, and, of 139 metaphasic one-cell zygotes, 101 (or 72.3%) were analyzed. These showed a Mendelian ratio of 1:1 for normal and balanced segregants. The sex ratio in the aged group (57Y:41X) also showed no deviation from 1:1. The results, which reveal significant physiological distortions for both the segregation and the sex ratios in males heterozygous for the Rb(6.16) translocation, suggest that differential maturation of the translocation-bearing sperm and the chromosomally normal reciprocal exists. The findings further support the concept that sperm chromosomal complement affects their maturation and function, and that factors on chromosome 6 and the X or Y chromosome additively affect sperm function.

Protamine transcript sharing among postmeiotic spermatids

Sharing of cytoplasmic constituents through intercellular bridges connecting postmeiotic spermatids can allow for functional equivalence of genetically nonequivalent spermatids. The technique of in situ hybridization was used to study postmeiotic distribution of transcripts from the mouse protamine 1 (Prm-1) gene among spermatids of mice with chromosomally unbalanced gametes. The Prm-1 gene is located on chromosome 16 and is expressed exclusively in haploid spermatids. Mice doubly heterozygous for two Robertsonian translocations involving chromosome 16 were used for the study of postmeiotic accumulation of transcripts of the Prm-1 gene in spermatogenic cells. The meiotic segregation pattern of chromosomal homologues in these mice produces some spermatids that are chromosomally unbalanced; some spermatids lack chromosome 16 while others have two. In situ hybridization with a cDNA probe for the Prm-1 gene transcript performed on both whole testis sections and spermatogenic cell suspensions showed that there was no statistical difference in distribution of grains over step-5 to step-10 spermatids from Robertsonian-translocation heterozygous mice and from control mice of normal karyotype. These results are consistent with sharing of transcripts of the Prm-1 gene among spermatids within a syncytium.

Genetic control of the survival of murine trisomy 16 fetuses

A mouse model that allows for the experimental induction of an aneuploid state has been employed to investigate the factors that control the survival of trisomy 16 fetuses. The prevalence of trisomy 16 fetuses on day 15 of gestation was shown to vary significantly with the genetic background of the female parent. The ability to spontaneously abort a trisomy 16 conceptus was shown to be higher in the mouse strain with a low prevalence of trisomy 16, compared to those mouse strains with a high prevalence of trisomy 16. Furthermore, the maternal ability that selects against, or promotes the survival of a trisomic conceptus was shown to be specific for the trisomy in question.