UMLS:C0024312 - FACTA Search

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Query: UMLS:C0024312 (lymphopenia)
4,859 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Diabetes-prone (DP) and diabetes-resistant (DR) sublines of the BB rat have been established in Edinburgh, U.K., separately from other existing colonies. In an examination of the lymphoid status of the two lines, BB-DP/Ed and BB-DR/Ed, it has been found that both lines have very low T-cell numbers, depressed B-lymphocyte numbers and a complete absence of peripheral CD8+ T cells, all features characteristic of the previously described genetic lymphopenia lesion. It was also noted that the peripheral T cells of both BB/Ed lines were larger than normal. The DP/Ed and DR/Ed lines were indistinguishable in all these respects, and furthermore, they were both shown to type as RT1u at the major histocompatibility complex (MHC). The genetic combination of lymphopenia and RT1u without expression of diabetes is not present in other extant BB lines and makes BB-DR/Ed a uniquely useful control strain for BB rat studies as well as a valuable genetic resource for the further genetic analysis of diabetes susceptibility in rats.
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PMID:BB-DR/Edinburgh: a lymphopenic, non-diabetic subline of BB rats. 809 84

Diabetes-prone DP-BB rats spontaneously develop insulin-dependent diabetes mellitus resembling type 1 diabetes mellitus in man. Expression of T cell lymphopenia and presence of at least one class II major histocompatibility complex (MHC) RT1u haplotype are required for development of diabetes. Diabetes segregation was studied in lymphopenic backcross (BC) offspring from a cross between male DP-BB/HRI and female BN/Mol rats. Diabetes occurred in 75% of BC rats with genotype RT1u/u and in 18% of those being RT1n/u in genotype. The latter developed diabetes significantly later than MHC homozygotes and parental DP-BBs. Our data further point to the existence of additional genes of minor importance for development of IDDM. One of these seemed to be positioned on the X chromosome. The recently published linkage to chromosome 18 could not be confirmed however. Finally, the BN-derived non-albino allele of the C gene was associated with higher diabetes incidence. This points to the existence of minor susceptibility genes in other strains of rats.
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PMID:Segregation of autoimmune type 1 diabetes in a cross between diabetic BB and brown Norway rats. 908 Feb 98

BB rats are used as models of autoimmune human IDDM. Genetic control of IDDM in both species is complex, including both major histocompatibility complex (MHC)-linked and non-MHC-linked genes. DP-BB rats develop IDDM spontaneously. Expression of disease in these animals requires homozygosity at the lyp locus, which causes lymphopenia. All genetic analyses of BB rat diabetes to date have backcrossed to the DP-BB strain or used (DP-BB x non-BB)F2 animals to ensure that a fraction of progeny are homozygous for lyp. Here we report the analysis of a backcross of the DP-BB rat to the histocompatible WF rat. Neither WF nor (WF x DP-BB)F1 animals develop spontaneous IDDM. However, 95% of (WF x DP-BB)F1 rats and a fraction of (WF x DP-BB) x WF backcross animals readily develop IDDM after treatment with polyinosinic:polycytidylic acid and a cytotoxic anti-RT6.1 monoclonal antibody. Using simple sequence length polymorphism analysis, we have mapped loci on chromosomes 4 and 13 that show significant linkage to IDDM expression and insulitis. The susceptibility locus on chromosome 4 is linked to, but not identical to, lyp. We propose a disease model for the BB rat that requires 1) the RT1u MHC haplotype for disease susceptibility, 2) a new locus on chromosome 4 for disease initiation (as measured by insulitis), 3) a new locus on chromosome 13 for disease progression in response to environmental perturbation, and 4) lyp for spontaneous expression of disease.
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PMID:Non-major histocompatibility complex-linked diabetes susceptibility loci on chromosomes 4 and 13 in a backcross of the DP-BB/Wor rat to the WF rat. 989 22

The genetic etiology of Type 1 (insulin-dependent) diabetes mellitus is complicated by the apparent presence of several diabetes susceptibility genetic regions. Type 1 diabetes in the inbred BioBreeding (BB) rat closely resembles the human disorder and was previously shown to involve two genes: the lymphopenia (lyp) region on Chromosome (Chr) 4 and RT1(u) in the major histocompatibility complex (MHC) on Chr 20. In addition, a segregation analysis of an F(2) intercross between the diabetes-prone congenic BB DR(lyp/lyp, u/u) and F344(+/+,)(lv/lv) rats indicated that at least one more genetic factor was responsible for Type 1 diabetes. In this study, we generated F(2)N(2) progeny in a cross between non-diabetic F(2)(DR(lyp/lyp,u/u) x F344)(lyp/lyp,u/u) and diabetic DR(lyp/lyp, u/u) rats. In a subsequent total genome scan, a third factor was mapped to the 21.3-cM region on Chr 2 between D2Mit14 and D2Mit15 (peak LOD score 4.7 with 67% penetrance). Interestingly, the homozygosity of the BB allele (b/b) for the Chr 2 region was significantly associated with a greater weight reduction after fasting than the homozygosity of the F344 allele (f/f, p < 0.008). In conclusion, the development of Type 1 diabetes in the congenic DR(lyp/lyp) rat is controlled by at least three genes: lymphopenia, MHC, and a third factor that may play a role in metabolism and body weight regulation.
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PMID:BB rat diabetes susceptibility and body weight regulation genes colocalize on chromosome 2. 1044 39

Diabetes-prone (DP) BB rats develop autoimmune type 1 diabetes spontaneously. At least five loci are linked to disease expression: the major histocompatibility complex (iddm2), two susceptibility loci (iddm4, iddm5), and, possibly, a resistance locus (iddm3). Spontaneous disease also requires homozygosity for lyp/iddm1, which causes lymphopenia. It has not been determined whether lyp/iddm1 is required for predisposition to diabetes autoimmunity in addition to being required for its spontaneous expression. We analyzed backcross rats segregating for diabetes but not lymphopenia using Wistar-Furth (WF) and diabetes-resistant (DR) BB animals. The latter are nonlymphopenic (lyp+/+) and develop diabetes only in response to immunological perturbants. Treatment of (DR-BB x WF)F1 x WF animals (all lyp+/+) using a standard induction protocol caused type 1 diabetes in 58% of progeny. Expression of type 1 diabetes was strongly linked to iddm4. The results suggest that lyp/iddm1 does not determine the predisposition to autoimmunity in BB rats and that iddm4 is a major diabetogenic locus in both DP- and DR-BB animals. The iddm4 gene maps to a region containing several major autoimmunity loci, including aia2, aia3, and cia3. We propose that BB rat diabetes requires 1) class II RT1u (iddm2) for susceptibility, 2) additional loci for disease initiation and progression in response to perturbants, and 3) lyp for spontaneous disease.
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PMID:Diabetes-prone and diabetes-resistant BB rats share a common major diabetes susceptibility locus, iddm4: additional evidence for a "universal autoimmunity locus" on rat chromosome 4. 1053 46

Athletes are exposed to acute and chronic stress that may lead to suppression of the immune system and increased oxidative species generation. In addition, the tendency to consume fewer calories than expended and to avoid fats may further compromise the immune system and antioxidant mechanisms. The exercise stress is proportional to the intensity and duration of the exercise, relative to the maximal capacity of the athlete. Muscle glycogen depletion compromises exercise performance and it also increases the stress. Glycogen stores can be protected by increased fat oxidation (glycogen sparing). The diets of athletes should be balanced so that total caloric intake equals expenditure, and so that the carbohydrates and fats utilised in exercise are replenished. Many athletes do not meet these criteria and have compromised glycogen or fat stores, have deficits in essential fats, and do not take in sufficient micronutrients to support exercise performance, immune competence and antioxidant defence. Either overtraining or under nutrition may lead to an increased risk of infections. Exercise stress leads to a proportional increase in stress hormone levels and concomitant changes in several aspects of immunity, including the following: high cortisol; neutrophilia; lymphopenia; decreases in granulocyte oxidative burst, nasal mucociliary clearance, natural killer cell activity, lymphocyte proliferation, the delayed-type sensitivity response, the production of cytokines in response to mitogens, and nasal and salivary immunoglobulin A levels; blunted major histocompatibility complex II expression in macrophages; and increases in blood granulocyte and monocyte phagocytosis, and pro- and anti-inflammatory cytokines. In addition to providing fuel for exercise, glycolysis, glutaminlysis, fat oxidation and protein degradation participate in metabolism and synthesis of the immune components. Compromising, or overusing, any of these components may lead to immunosuppression. In some cases, supplementation with micronutrients may facilitate the immune system and compensate for deficits in essential nutrients. In summary, athletes should eat adequate calories and nutrients to balance expenditure of all nutrients. Dietary insufficiencies should be compensated for by supplementation with nutrients, with care not to over compensate. By following these rules, and regulating training to avoid overtraining, the immune system can be maintained to minimise the risk of upper respiratory tract infections.
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PMID:Effect of dietary intake on immune function in athletes. 1192 59

Diabetes in the biobreeding (BB) rat results from autoimmune destruction of pancreatic beta cells and thereby it is sharing many features with human type 1 diabetes. Independent crossing studies have demonstrated that diabetes in the BB rat is explained by at least three recessively acting genes termed Iddm1 (major histocompatibility complex), Iddm2 (lymphopenia), Iddm3 (unknown). About 50% of Iddm1 and Iddm2 homozygous first backcross hybrids (BC1) usually develop diabetes. However, 75% of these homozygotes become diabetic when using diabetic BB/HRI and diabetes-resistant BN/Mol rats. That prompted us to carry out a cross between BB/OK and BN/Crl rats in order to localise diabetogenic gene(s) of BB and/or BN rats. Fifty nine Iddm1 and Iddm2 homozygous [(BNxBB)F1xBB] BC1 hybrids (35 M, 24 F) were observed for diabetes occurrence up to an age of 30 weeks. All hybrids were used in a genome-wide scan carried out with 238 microsatellite markers covering about 92% of the genome. Significantly more Iddm1 and Iddm2 homozygous BC1 hybrids became diabetic (69 vs. 50%, p<0.003) with an age at onset of 91+/-31 days. Significant deviations from expected allele distribution between diabetic and non-diabetic BC1 hybrids were found at loci on chromosomes 1, 2, 3, 9, 10, 15, 16 and 19, with the strongest effect observed at locus D10Mgh2, where more heterozygous (91%) than homozygous diabetics (44%) were found. We conclude that BN rats possess more than one gene contributing to type 1 diabetes development.
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PMID:Alleles of diabetes-resistant BN rats contribute to insulin-dependent type 1 diabetes mellitus. 1265 25

The thymus is the unique lymphoid organ inside which a confrontation occurs throughout life between neuroendocrine self-antigens and a recently evolved system with original recombination machinery driving random generation of immune response diversity. Through transcription of neuroendocrine genes in the thymus stromal network and expression of cognate receptors by immature T cells, the neuroendocrine system regulates early T cell differentiation. In addition and more specifically, intrathymic presentation of neuroendocrine self-antigens by, or in close association with, major histocompatibility complex (MHC) proteins is responsible for the establishment of central immune self-tolerance of neuroendocrine principles. All members of the insulin gene (INS) family are expressed in the thymus stroma according to a precise hierarchy and cell topography: IGF2 (thymic epithelial cells) > IGF1 (thymic macrophages) >> INS (thymic medullary epithelial cells and/or dendritic cells). Given this hierarchical pattern in gene expression, the protein IGF-2 is more tolerated than INS. Igf2 transcription is defective in the thymus of bio-breeding (BB) rat, one animal model of type 1 diabetes (T1DM). This thymus-specific defect in Igf2 expression may explain both the absence of central tolerance to INS-secreting beta cells and the lymphopenia (including lack of regulatory RT6(+) T cells) in diabetes-prone BB rats. INS B:9-23 and the homologous sequence of IGF-2 compete for binding to DQ8, an MHC class II allele conferring major susceptibility to T1DM. In young DQ8(+) T1DM patients, INS B:9-23 presentation by DQ8 elicits a dominant IFN-gamma secretion by isolated PBMCs, whereas presentation of the IGF-2 self-antigen promotes a dominant regulatory interleukin-10 secretion. These data demonstrate that opposite immune responses are driven by MHC presentation of a self-antigen (here, IGF-2) and an autoantigen (INS, as "altered" self). The important tolerogenic properties of thymic self-antigens deserve now to be exploited for prevention and/or cure of devastating autoimmune diseases such as T1DM.
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PMID:Role of the thymus in the development of tolerance and autoimmunity towards the neuroendocrine system. 1279 58

The size of the peripheral T cell pool is remarkably stable throughout life, reflecting precise regulation of cellular survival, proliferation, and apoptosis. Homeostatic proliferation refers to the process by which T cells spontaneously proliferate in a lymphopenic host. The critical signals driving this expansion are "space," contact with self-major histocompatibility complex (MHC)/peptide complexes, and cytokine stimulation. A number of studies have delineated an association between T cell lymphopenia, compensatory homeostatic expansion, and the development of diverse autoimmune syndromes. In the nonobese diabetic mouse model of type 1 diabetes, lymphopenia-induced homeostatic expansion fuels the generation of islet-specific T cells. Excess interleukin-21 facilitates T cell cycling but limited survival, resulting in recurrent stimulation of T cells specific for self-peptide/MHC complexes. Indeed, data from several experimental models of autoimmunity indicate that a full T cell compartment restrains homeostatic expansion of self-reactive cells that could otherwise dominate the repertoire. This review describes the mechanisms that govern T cell homeostatic expansion and outlines the evidence that lymphopenia presents a risk for development of autoimmune disease.
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PMID:T cell homeostasis in tolerance and immunity. 1589 86

Positive selection in the thymus and peripheral T cell survival depend on T cell receptor (TCR)-major histocompatibility complex (MHC) interactions, but it is not yet clear if both events follow exactly the same rules. We studied peripheral T cell survival and clone sizes in conditions of progressive reduction of restricting MHC-bearing cells or progressive ablation of different MHC molecules. Different CD8(+) T cell clones/polyclonal populations showed different survival and/or lymphopenia-driven proliferation requirements. We could correlate clone sizes to the capacity of each TCR to interact with different types of MHC complexes. Thus, although repertoire selection in the thymus is mainly conditioned by the affinity of TCR-MHC interactions, peripheral selection is determined by TCR cross-reactivity to environmental ligands.
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PMID:The clone size of peripheral CD8 T cells is regulated by TCR promiscuity. 1676 97

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