Genetic analysis of the T/t complex

Exacerbation of autoimmune neuroinflammation by dietary sodium is genetically controlled and sex specific

Multiple sclerosis (MS) is a debilitating autoimmune neuroinflammatory disease influenced by genetics and the environment. MS incidence in female subjects has approximately tripled in the last century, suggesting a sex-specific environmental influence. Recent animal and human studies have implicated dietary sodium as a risk factor in MS, whereby high sodium augmented the generation of T helper (Th) 17 cells and exacerbated experimental autoimmune encephalomyelitis (EAE), the principal model of MS. However, whether dietary sodium interacts with sex or genetics remains unknown. Here, we show that high dietary sodium exacerbates EAE in a strain- and sex-specific fashion. In C57BL6/J mice, exposure to a high-salt diet exacerbated disease in both sexes, while in SJL/JCrHsd mice, it did so only in females. In further support of a genetic component, we found that sodium failed to modify EAE course in C57BL6/J mice carrying a 129/Sv-derived interval on chromosome 17. Furthermore, we found that the high-sodium diet did not augment Th17 or Th1 responses, but it did result in increased blood-brain barrier permeability and brain pathology. Our results demonstrate that the effects of dietary sodium on autoimmune neuroinflammation are sex specific, genetically controlled, and CNS mediated.

Exacerbation of autoimmune neuroinflammation by dietary sodium is genetically controlled and sex specific

Multiple sclerosis (MS) is a debilitating autoimmune neuroinflammatory disease influenced by genetics and the environment. MS incidence in female subjects has approximately tripled in the last century, suggesting a sex-specific environmental influence. Recent animal and human studies have implicated dietary sodium as a risk factor in MS, whereby high sodium augmented the generation of T helper (Th) 17 cells and exacerbated experimental autoimmune encephalomyelitis (EAE), the principal model of MS. However, whether dietary sodium interacts with sex or genetics remains unknown. Here, we show that high dietary sodium exacerbates EAE in a strain- and sex-specific fashion. In C57BL6/J mice, exposure to a high-salt diet exacerbated disease in both sexes, while in SJL/JCrHsd mice, it did so only in females. In further support of a genetic component, we found that sodium failed to modify EAE course in C57BL6/J mice carrying a 129/Sv-derived interval on chromosome 17. Furthermore, we found that the high-sodium diet did not augment Th17 or Th1 responses, but it did result in increased blood-brain barrier permeability and brain pathology. Our results demonstrate that the effects of dietary sodium on autoimmune neuroinflammation are sex specific, genetically controlled, and CNS mediated.

Deficit of HLA homozygotes in a Caucasian isolate

Deficits of HLA-A, -B homozygotes observed many years ago in two inbred populations suggested negative selection against HLA homozygotes. To determine whether a similar deficiency would be observed in the S-leut Hutterites, a well-characterized Caucasian isolate of European ancestry, and to determine whether selection operated at the allele, locus, or haplotype level, observed and expected numbers of homozygotes were compared in 852 adult Hutterites. Deficits ranging from 11% to 24% were observed for all five loci examined (HLA-A, -B, -C, -DR, and -DQ). However, these deficits were secondary to, and almost completely accounted for by, a 64% loss of individuals homozygous for the haplotype. There was no evidence of deficits affecting only a single allele or locus. The data indicate strong negative selection against HLA homozygotes. This could be due, at least in part, to decreased fecundability among couples sharing HLA-DR. However, these data suggest that additional selective factors acting at the level of the haplotype also operate in this population.

Major histocompatibility complex, t-complex, and leukemia

In experimental models, leukemia was the first disease shown to have an association with the major histocompatibility complex (MHC) genes. In humans, several allelic human-leukocyte antigen (HLA) associations also have been recognized. In addition to allelic associations, atypical HLA segregation patterns have been observed in leukemic families. These include a higher frequency of HLA-identical unaffected siblings, increased HLA homozygosity and increased maternal HLA-DR identity. These observations suggest preferential transmission of disease-associated haplotypes and a male transmission bias in leukemic families. The lack of disease-specific segregation, however, supports the idea that the HLA system is not directly relevant in leukemogenesis. Therefore, the existence of another genetic region linked to the MHC, causing segregation distortion, and containing recessive leukemia susceptibility genes may be postulated. The mouse t-complex would fit this model. This gene complex has recessive (semi-) lethal genes, is transmitted preferentially through fathers, and both the mouse t-complex and its rat homolog, growth and reproduction complex grc, confer susceptibility to carcinogenesis. This model could also explain the increased spontaneous abortion rate in mothers of leukemic patients, epidemiologic associations of leukemia with oral clefts and neuroectodermal tumors, and the transmission of a radiation-induced leukemia risk through fathers. Such segregation distortion might be the reason behind the maintenance of a gene(s) with a lethal effect in the population.

Susceptibility genetics of systemic lupus erythematosus

The etiology of systemic lupus erythematosus (SLE) is determined in part by genetic factors which influence susceptibility to the disease. These factors presumably have a major role in determining the clinical and laboratory manifestations of SLE. Certain newer observations which may pertain to an understanding of the genetic basis of SLE will be critically reviewed in this chapter. These observations are based on advances in the analysis of human SLE and the increased knowledge provided by various murine models of human autoimmune processes. However, the specific genes involved and the mechanisms by which they exert their effect are at present still unknown. Special attention will be given newer insights into the role of genes of the major histocompatibility complex (MHC) and their relationship to the genes encoding the T cell antigen receptor. The role of classic immunoglobulin genes as well as more complex mechanisms involving preferential maternal or paternal genetic effects are also discussed. The contribution of genes encoding complement and complement receptors toward the expression of the disease state are discussed in brief.