Javier García-Ceca

Thymic Alterations in EphA4-Deficient Mice

In the present work, we have demonstrated in vivo an altered maturation of the thymic epithelium that results in defective T cell development which increases with age, in the thymus of Eph A4-deficient mice. The deficient thymi are hypocellular and show decreased proportions of double-positive (CD4+CD8+) cells which reach minimal numbers in 4-wk-old thymi. The EphA4 −/− phenotype correlates with an early block of T cell precursor differentiation that results in accumulation of CD44−CD25+ triple-negative cells and, sometimes, of CD44+CD25− triple-negative thymocytes as well as with increased numbers of apoptotic cells and an important reduction in the numbers of cycling thymocytes. Various approaches support a key role of the thymic epithelial cells in the observed phenotype. Thymic cytoarchitecture undergoes profound changes earlier than those found in the thymocyte maturation. Thymic cortex is extremely reduced and consists of densely packed thymic epithelial cells. Presumably the lack of forward Eph A4 signaling in the Eph A4 −/− epithelial cells affects their development and finally results in altered T cell development.

Alterations in the thymocyte phenotype of EphB‐deficient mice largely affect the double negative cell compartment

In the present study, we have analysed the phenotype of EphB2 and/or EphB3 deficient thymocytes confirming and extending previous studies on the role of this family of molecules in T‐cell differentiation. In all mutant thymuses statistically significant reduced cell contents were observed. This reduction of thymic cellularity correlated with increased proportions of apoptotic cells, largely both double negative (DN; CD4− CD8−) and double positive (CD4+ CD8+) cells, and decreased proportions of DN cycling cells. Adult deficient thymuses also showed increased proportions of DN cells but not significant variations in the percentages of other thymocyte subsets. In absolute terms, the thymocyte number decreased significantly in all thymocyte compartments from the DN3 (CD44− CD25+) cell stage onward, without variations in the numbers of both DN1 (CD44+ CD25−) and DN2 (CD44+ CD25+) cells. Remarkably, all these changes also occurred from the 15‐day fetal EphB2 and/or EphB3 deficient mice, suggesting that adult phenotype results from the gradual accumulations of defects appearing early in the thymus ontogeny. As a reflection of thymus condition, a reduction in the number of T lymphocytes occurred in the peripheral blood and mesenteric lymph nodes, but not in spleen, maintaining the proportions of T‐cell subsets defined by CD4/CD8 marker expression, in all cases.

Biology of Stem Cells: The Role of Microenvironments

From the discovery of the first line of human embryonic stem cells, thousands of studies have been published concerning adult stem cells and their possible alleged therapeutic potential. However, very little real progress has been made in the application of cell therapy to patients. We can conclude that there remains a great deal for us to learn about the biology of stem cells, and especially, the mechanisms that regulate their differentiation and use under conditions of biosafety. In this chapter, we are going to review some of the mechanisms that seem to control the biology of stem cells, in particular the microenvironments, also called niches, where they house and which exert a strong influence over them. The regulation, survival, proliferation and differentiation of stem cells is ultimately determined by a combination of factors intrinsic to the stem cells themselves and extrinsic signals received from the microenvironment. A better understanding of the cellular components of microenvironments and their cellular and molecular interactions with the other components of the niche, including the stem cells themselves, will be key to make progress in this field.

On the role of Eph signalling in thymus histogenesis; EphB2/B3 and the organizing of the thymic epithelial network

In the current study, we extend our own previous results on the thymocyte phenotype of EphB2 and/or EphB3 deficient mice by analyzing the phenotype and the histological organization of their thymic epithelial stroma. All studied adult EphB-deficient thymi showed profound alterations with respect to the wild-type (WT) ones. Each mutant exhibited a specific phenotype, but also showed common features including occurrence of K5+K8+MTS10+ immature medullary epithelial cells, numerous K5-K8-MTS20+ cells and K5+K8+ cells in the thymic cortex and cortical and medullary K5-K8- areas devoid of epithelial cell markers. In addition, comparative analysis of WT and EphB-deficient embryonic and newborn thymi demonstrated that the observed adult phenotype was a consequence of the gradual accumulation of early phenotypic and morphological defects, becoming more severe at the end of embryonic life and in newborn animals. Together, these results confirm a role for EphB2 and EphB3 in thymus morphogenesis. The obtained data are discussed from the point of view of the recognized role played by these two Ephs in the homeostasis of other epithelia and their possible relationships with molecules known to be involved in thymic epithelial cell development.

Eph/Ephrin-Mediated Interactions in the Thymus

In the present study, we review available information on the relevance of Eph and ephrins in numerous processes occurring in the thymus that regulate not only T cell differentiation but also thymic epithelial cell (TEC) development and organization. Eph/ephrins are a large family of receptors and ligands involved in organogenesis and homeostasis of adult tissues. They are extensively expressed in the thymus and seem to be involved in the colonization of lymphoid progenitor cells and their migration throughout the thymic parenchyma necessary to provide an adequate topological location of developing thymocytes in the epithelial network that ensures their correct differentiation. In addition, EphB2 and EphB3 play a cell-autonomous role in regulating the transitions of double-negative to double-positive cells and of double-positive to single-positive thymocytes and the lack of these molecules or their ligands ephrin B1 and ephrin B2 induces profound alterations of the TEC maturation and in the arrangement of epithelial network. We emphasize that these results are largely reflecting the role played by this family of molecules in controlling thymocyte-TEC interactions within the thymus.

The Eph/ephrinB signal balance determines the pattern of T-cell maturation in the thymus

In order to carry out an in‐depth study of the roles of EphB receptors in T‐cell development and to determine the specific relevance of forward and reverse signals in the process, we established severe combined immunodeficient (SCID) mice chimeras with wild‐type (WT) or EphB‐deficient bone marrow cells. The obtained results demonstrate that EphB2 contributes more significantly than EphB3 in the control of CD4−CD8− (DN)–CD4+CD8+ (DP) progression, and that reverse signals generated in SCID mice receiving EphB2LacZ precursors, which express the EphB2 extracellular domain, partially rescue the blockade of DN cell maturation observed in EphB2‐null chimeras. In addition, increased apoptotic DP thymocytes occurring in EphB2 and/or EphB3 SCID chimeras also contribute to the reduced proportions of DP cells. However, EphB2LacZ chimeras do not show any changes in the proportions of apoptotic DP cells, thus suggesting that there is a role for ephrinB reverse signaling in thymocyte survival. The maturation of DP to CD4+CD8− or CD4−CD8+ seems to need EphB2 forward signaling and EphB3; a fact that was confirmed in reaggregates formed with either EphB2‐ or EphB3‐deficient DP thymocytes and WT thymic epithelial cells (TECs). The DP thymocyte–TEC conjugate formation was also affected by the absence of EphB receptors. Finally, EphB‐deficient SCID chimeras show profoundly altered thymic epithelial organization that confirms a significant role for EphB2 and EphB3 receptors in the thymocyte–TEC crosstalk.

Cell-autonomous role of EphB2 and EphB3 receptors in the thymic epithelial cell organization

The role of EphB2 and EphB3 in the organization of thymic epithelial cells has been studied in EphB‐deficient fetal thymus lobes grafted under the kidney capsule of WT mice. The deficient lobes, as compared with WT ones, showed altered distribution of medullary areas, shortening of medullary epithelial cell processes and presence of K5−K8− areas. EphB2 and EphB3 expressed on thymic epithelial cells play an autonomous role in their organization. The relevance of Eph/ephrinB forward and reverse signals for this process was evaluated in grafted fetal thymus lobes from mice expressing a truncated EphB2 receptor capable of activating reverse, but not forward, signaling. These deficient lobes showed important alterations of the thymic epithelial organization as compared with the grafted WT lobes, but a less severe phenotype than the grafted EphB2‐deficient thymus lobes, which confirms the relevance of EphB2 forward signal for the thymic epithelial organization but, also, a role of the reverse signaling in determining the final epithelial phenotype.

Eph/Ephrins-Mediated Thymocyte–Thymic Epithelial Cell Interactions Control Numerous Processes of Thymus Biology

Numerous studies emphasize the relevance of thymocyte–thymic epithelial cell (TECs) interactions for the functional maturation of intrathymic T lymphocytes. The tyrosine kinase receptors, Ephs (erythropoietin-producing hepatocyte kinases) and their ligands, ephrins (Eph receptor interaction proteins), are molecules known to be involved in the regulation of numerous biological systems in which cell-to-cell interactions are particularly relevant. In the last years, we and other authors have demonstrated the importance of these molecules in the thymic functions and the T-cell development. In the present report, we review data on the effects of Ephs and ephrins in the functional maturation of both thymic epithelial microenvironment and thymocyte maturation as well as on their role in the lymphoid progenitor recruitment into the thymus.

Ephrin-B–Dependent Thymic Epithelial Cell–Thymocyte Interactions Are Necessary for Correct T Cell Differentiation and Thymus Histology Organization: Relevance for Thymic Cortex Development

Previous analysis on the thymus of erythropoietin-producing hepatocyte kinases (Eph) B knockout mice and chimeras revealed that Eph-Eph receptor–interacting proteins (ephrins) are expressed both on T cells and thymic epithelial cells (TECs) and play a role in defining the thymus microenvironments. In the current study, we have used the Cre-LoxP system to selectively delete ephrin-B1 and/or ephrin-B2 in either thymocytes (EfnB1thy/thy, EfnB2thy/thy, and EfnB1thy/thyEfnB2thy/thy mice) or TECs (EfnB1tec/tec, EfnB2tec/tec, and EfnB1tec/tecEfnB2tec/tec mice) and determine the relevance of these Eph ligands in T cell differentiation and thymus histology. Our results indicate that ephrin-B1 and ephrin-B2 expressed on thymocytes play an autonomous role in T cell development and, expressed on TECs, their nonautonomous roles are partially overlapping. The effects of the lack of ephrin-B1 and/or ephrin-B2 on either thymocytes or TECs are more severe and specific on thymic epithelium, contribute to the cell intermingling necessary for thymus organization, and affect cortical TEC subpopulation phenotype and location. Moreover, ephrin-B1 and ephrin-B2 seem to be involved in the temporal appearance of distinct cortical TECs subsets defined by different Ly51 levels of expression on the ontogeny.

Developing T-cell migration: role of semaphorins and ephrins

Cell migration is a crucial event for normal T‐cell development, and various ligand/receptor pairs have been implicated. Most of them, including chemokines and extracellular matrix proteins, have attractant properties on thymocytes. We discuss herein two further groups of ligand/receptor pairs, semaphorins/neuropilins and ephs/ephrins, which are constitutively expressed by thymocytes and thymic microenvironmental cells. Evidence shows that the corresponding interactions are relevant for developing T‐cell migration, including the entry of bone marrow progenitor cells, migration of CD4/CD8‐defined thymocyte subpopulations triggered by chemokines and/or extracellular matrix proteins, and thymocyte export. Conceptually, the data summarized here show that thymocyte migration results from a complex network of molecular interactions, which generate not only attraction, but also repulsion of migrating T‐cell precursors.—Mendes‐da‐Cruz, D. A., Stimamiglio, M. A., Muñoz, J. J., Alfaro, D., Terra‐Granado, E., Garcia‐Ceca, J., Alonso‐Colmenar, L. M., Savino, W., Zapata, A. G. Developing T‐cell migration: role of semaphorins and ephrins. FASEB J. 26, 4390–4399 (2012). www.fasebj.org