T Cell Subset Patterns That Predict Resistance to Spontaneous Lymphoma, Mammary Adenocarcinoma, and Fibrosarcoma in Mice

Miller, Richard A.; Chrisp, Clarence E.

doi:10.4049/jimmunol.169.3.1619

Cited by 36 publications

(29 citation statements)

References 19 publications

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“…58 Several observations suggest that immune competence has a major influence on lifespan and that changes in T-lymphocyte populations could be implicated in the age-related increase in incidence of infections, cancer, and autoimmune diseases. 57,59,60 Therefore, strategies to rejuvenate the thymus or to create thymus substitutes are being pursued with intense interest. [61][62][63][64] That OM ϩ extrathymic T cells cannot substitute for thymic T cells even though they have a diversified TCR repertoire implies that having the ability to generate new T cells is not sufficient to ensure immunocompetence.…”

Section: Discussionmentioning

confidence: 99%

Do thymically and strictly extrathymically developing T cells generate similar immune responses?

Blais

Gérard

Martinic

et al. 2004

Blood

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IntroductionOne hallmark of the adaptive immune system is that the thymus has been conserved as the primary T-lymphoid organ during 450 million years of evolution. 1 This level of conservation is remarkable when one considers that about 10 different organs have been used as primary sites of hematopoiesis in jawed vertebrates. 1 Thymic epithelial cells (TECs) derived from the third pharyngeal pouch are the main constituent of the thymic environment. 2 TECs provide 2 types of signals to thymocytes: T-cell receptor (TCR)-dependent and TCR-independent. [3][4][5] In conjunction with mesenchymal cells, TECs have a unique ability to provide TCR-independent interactions that are essential for several thymocyte developmental events but whose nature is still elusive. 2,[6][7][8][9] Indeed, studies in wild-type and TCR-transgenic euthymic and nude mice indicated that the efficiency of generating mature T cells was 100 to 1000 times less in nude compared to euthymic mice. 5 In contrast, TCR-mediated signals, dictating which TCR clonotypes are positively selected, can be supported by major histocompatibility complex (MHC)-peptide complexes displayed by other cell types. Thus, studies involving hematopoietic chimeras and thymus grafts have shown that hematopoietic cells can mediate positive selection of CD8 T cells in vivo. 5,10,11 In line with this, studies in tetraparental aggregation chimeras have demonstrated that the MHC of TECs is not required for efficient positive selection of MHC Ia-and MHC II-restricted T cells. 12 Moreover, under normal circumstances, preferential or exclusive positive selection on hematopoietic cells appears to be a general characteristic shared by many (if not all) MHC class Ib-restricted T cells. [13][14][15] These data indicate that the nonredundant role of TECs is to provide TCR-independent signals to thymocytes, but that TCR signals can be provided by other cells in the thymus and the periphery. 5,16 These considerations raise the question of whether the canonical influence of TECs on T-cell development is essential for survival. Would lymphocytes developing in a TEC-free milieu be functional and reach sufficient numbers to eradicate pathogens? Oncostatin M (OM)-transgenic mice represent a unique model to directly address this issue. Remarkably, chronic exposure to OM transforms the lymph node (LN) into a "primary" lymphoid organ whose ability to support T-cell development and to seed secondary lymphoid organs is similar to that of a normal thymus. 17,18 The lymphopoietic pathway modulated by OM is truly thymusindependent and takes place only in the LNs. 17,18 The proportions of double-negative, double-positive, and single-positive T cells in the OM ϩ LNs reproduce those found in a thymus, and the TCR repertoire of the single-positive cells is diversified. The effect of OM on extrathymic T-cell development in the LNs is probably due to some amplification of a cryptic pathway that is operative in conditions of defective thymopoiesis and was nicely characterized in nude mice. 19 Like normal LNs...

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Section: Discussionmentioning

confidence: 99%

Do thymically and strictly extrathymically developing T cells generate similar immune responses?

Blais

Gérard

Martinic

et al. 2004

Blood

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“…The result was that another mouse simply moved up the hierarchy to become the dominant mouse. Miller & Chrisp (2002) reported an unexpectedly high incidence of mouse urinary syndrome (MUS) in a lifespan study of four-way cross HET mice. It was restricted to males and it appeared that the syndrome resulted from dominance aggression between individuals.…”

Section: Housingmentioning

confidence: 99%

Exploiting the rodent model for studies on the pharmacology of lifespan extension

Nadon

2006

Aging Cell

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SummaryThe rodent is a particularly valuable model with which to test therapeutic interventions for aging, as rodent physiology is close enough to human physiology to give the findings relevance for human aging, and it is small enough to allow for use of statistically robust sample sizes. There are many rodent models to choose from, with advantages and disadvantages to each. The choice of model system, as well as other experimental design decisions such as diet and housing, is extremely important for the success of lifespan studies. These issues are discussed in this review of the use of the rodent model. The National Institute on Aging (NIA) Interventions Testing Program, which has grappled with all of these issues, is described.

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“…Inhibitors of mTOR function can block tumor growth directly (Hidalgo & Rowinsky, 2000), and it is plausible that direct effects on tumors may contribute to lifespan effects in mice, in which tumors are the most frequent class of lethal illness (Miller & Chrisp, 2002; Lipman et al ., 2004). Enteric-released rapamycin-treated UM-HET3 mice, however, show decelerated rates of change in a wide range of age-related physiological and pathological endpoints (Wilkinson et al ., 2012), suggesting that the drug may be inhibiting at least some aspects of the aging process in addition to any direct effects it may have on cancer cells.…”

Section: Introductionmentioning

confidence: 99%

Rapamycin‐mediated lifespan increase in mice is dose and sex dependent and metabolically distinct from dietary restriction

et al. 2014

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Rapamycin, an inhibitor of mTOR kinase, increased median lifespan of genetically heterogeneous mice by 23% (males) to 26% (females) when tested at a dose threefold higher than that used in our previous studies; maximal longevity was also increased in both sexes. Rapamycin increased lifespan more in females than in males at each dose evaluated, perhaps reflecting sexual dimorphism in blood levels of this drug. Some of the endocrine and metabolic changes seen in diet-restricted mice are not seen in mice exposed to rapamycin, and the pattern of expression of hepatic genes involved in xenobiotic metabolism is also quite distinct in rapamycin-treated and diet-restricted mice, suggesting that these two interventions for extending mouse lifespan differ in many respects.

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T Cell Subset Patterns That Predict Resistance to Spontaneous Lymphoma, Mammary Adenocarcinoma, and Fibrosarcoma in Mice

Cited by 36 publications

References 19 publications

Do thymically and strictly extrathymically developing T cells generate similar immune responses?

Do thymically and strictly extrathymically developing T cells generate similar immune responses?

Exploiting the rodent model for studies on the pharmacology of lifespan extension

Rapamycin‐mediated lifespan increase in mice is dose and sex dependent and metabolically distinct from dietary restriction

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