Esther P. Leeflang

Meiotic Segregation Analysis of RB1 Alleles in Retinoblastoma Pedigrees by Use of Single-Sperm Typing

In hereditary retinoblastoma, different epidemiological studies have indicated a preferential paternal transmission of mutant retinoblastoma alleles to offspring, suggesting the occurrence of a meiotic drive. To investigate this mechanism, we analyzed sperm samples from six individuals from five unrelated families affected with hereditary retinoblastoma. Single-sperm typing techniques were performed for each sample by study of two informative short tandem repeats located either in or close to the retinoblastoma gene (RB1). The segregation probability of mutant RB1 alleles in sperm samples was assessed by use of the SPERMSEG program, which includes experimental parameters, recombination fractions between the markers, and segregation parameters. A total of 2,952 single sperm from the six donors were analyzed. We detected a significant segregation distortion in the data as a whole (P=.0099) and a significant heterogeneity in the segregation rate across donors (.0092). Further analysis shows that this result can be explained by segregation distortion in favor of the normal allele in one donor only and that it does not provide evidence of a significant segregation distortion in the other donors. The segregation distortion favoring the mutant RB1 allele does not seem to occur during spermatogenesis, and, thus, meiotic drive may result either from various mechanisms, including a fertilization advantage or a better mobility in sperm bearing a mutant RB1 gene, or from the existence of a defectively imprinted gene located on the human X chromosome.

Single‐Sperm Typing

This unit presents protocols for sperm isolation using two different methods, amplification of simple sequence‐length polymorphisms (SSLP) and/or single nucleotide polymorphisms (SNP) from single cells or whole genome‐amplified single cells using primer extension preamplification (PEP), and discusses the statistical analysis of sperm‐typing recombination data. Newer methods for studying recombination over very short distances (a few kilobases) using total sperm DNA and allele‐specific PCR are also discussed.

The mutation properties of spinal and bulbar muscular atrophy disease alleles.

ABSTRACTWe studied the gene for the trinucleotide repeat disorder X-linked spinal and bulbar muscular atrophy (SBMA) to quantify the spectrum of mutations and gain insight into genetic anticipation. This analysis was performed using single sperm typing from an affected individual. This method allows the quantification of large numbers of meioses and therefore provides accurate information about genetic instability of the CAG repeat expansions which cause SBMA. Among 198 X chromosome-containing sperm cells, 20% had a CAG repeat number equal to the donors somatic DNA of 49 CAG repeats, 56% were expansions, and 24% contractions. Most of the expansions (84%) and contractions (94%) were between 1 and 3 CAG repeats. These results are consistent with those obtained from one previously studied SBMA patient and reveal greater CAG repeat instability in sperm than in somatic tissue. Our results indicate that in SBMA, in contrast to sperm typing analysis of Huntingtons disease, there is relative stability of the CAG repeat number during paternal transmissions and that the spectrum of mutations is narrow. These results are in agreement with the limited available clinical data and suggest that anticipation may not be a significant feature of this disease.

Direct estimation of the recombination frequency between the RB1 gene and two closely linked microsatellites using sperm typing.

In this study, single sperm typing has been used for high-resolution recombination analysis between the retinoblastoma gene and two closely linked extragenic microsatellites (D13S284 and D13S1307). The analysis of 1198 single sperm from three donors allowed the determination of recombination fractions between RB1.20 and D13S284 and RB1.20 and D13S1307 of 0.022 and 0.033, respectively. These results show that RB1 gene and the two microsatellites are closely linked, which validates their potential use in indirect genetic diagnosis of retinoblastoma.