Penetrance and expressivity of genes involved in the development of epilepsy in the genetically epilepsy-prone rat (GEPR).

In order to understand the level of complexity of the epileptic phenotype in the two strains of Genetically Epilepsy-Prone Rats (GEPRs), we determined two important measures of genetic complexity, penetrance and expressivity. Penetrance is the percentage of animals of a specific genotype who express the phenotype associated with that underlying genotype. Expressivity refers to the degree that a particular genotype is expressed as a phenotype within an individual. Incomplete penetrance and variable expressivity are caused by genetic and environmental variation. In this paper we have studied the epileptic phenotype for 20,373 rats. Animals were tested on three occasions for audiogenic seizure and given an audiogenic response score (on a scale of 0-9, 0 being no seizure and 9 being the most severe). The GEPR-3 and GEPR-9 animals both show incomplete penetrance and variable expressivity of the underlying genetic predisposition. The GEPR-9 strain has more animals that have variable levels of seizure predisposition (as measured by a scoring system that denotes the severity of generalized tonic/clonic seizures) and a greater percentage of animals that exhibit no susceptibility to such seizures induced by sound. Both strains have a number of animals that are not susceptible to sound-induced GTCSs and that exhibit some variability in seizure severity. The GEPR-9 males show greater differences in expressivity and penetrance compared to GEPR-9 females. The GEPR-3 animals also show sex-associated variable penetrance and expressivity of the epileptic phenotype, although the differences are much smaller. These findings are the first step toward the mapping of the underlying quantitative trait loci (QTL) for seizure in these animals.

Gamma 2b provides only some of the signals normally given via mu in B cell development.

B cell development is a complex process involving interactions between B cell precursors, stroma, and known and unknown ligands and cytokines. In order to more fully understand the requirements for Ig in that development we have created transgenic mice that carry a gamma 2b transgene and express it early in B cell development. Previously it was believed that these B cells arrested in their development prior to the pro- to pre-B cell transition. We show here that in conventional gamma 2b mice, B cell development actually arrests later, at the pre-B cell stage. This shows for the first time that a constant region different from mu can allow signaling through the pre-B cell receptor, but cannot promote complete development. The pro- and pre-B cells in the conventional gamma 2b transgenics are not fully functional since they cannot grow in IL-7 without stromal cells. This is a novel phenotype, separating development from stroma independence. The few, mature B cells that do develop in these mice express both mu and gamma 2b simultaneously, and are CD5+. Expression of a Bcl-2 transgene allows survival of gamma 2b transgenic immature B cells, but does not promote full maturation, indicating that normally mu provides both an anti-apoptotic signal and a differentiation signal. One line of gamma 2b mice, the C line, does not have this phenotype. B cell development is accelerated in this unconventional line, and the developing B cells have a very different phenotype from both normal mice and conventional gamma 2b mouse lines, but are very similar to mu transgenics. Mature B cells are largely CD5-, gamma 2b-only expressing. This unique phenotype is apparently due to the activation in B cell precursors of a gene at the insertion site of the transgene, circumventing the need for mu. Comparison of conventional gamma 2b transgenics with the C line and mu transgenics reveals the multiple signals required throughout B cell development.