Factors regulating stem cell recruitment to the fetal thymus

Colonization of the thymic rudiment during development is initiated before vascularization so that hemopoietic precursors must leave the pharyngeal vessels and migrate through the perithymic mesenchyme to reach the thymus, suggesting that they may be responding to a gradient of chemoattractant factors. We report that diffusible chemoattractants are produced by MHC class II+ epithelial cells of the fetal thymus, and that the response of precursors to these factors is mediated via a G protein-coupled receptor, consistent with factors being members of the chemokine family. Indeed, a number of chemokine receptors are expressed by thymic precursors, and several chemokines are also expressed by thymic epithelial cells. However, these chemokines are also expressed in a tissue that is unable to attract precursors, although the thymus expressed chemokine, TECK, is expressed at higher levels in thymic epithelial cells and we show that it has chemotactic activity for isolated thymic precursors. Neutralizing Ab to TECK, however, did not prevent thymus recolonization by T cell precursors, suggesting that other novel chemokines might be involved in this process. In addition, we provide evidence for the involvement of matrix metalloproteinases in chemoattractant-mediated T cell precursor recruitment to the thymus during embryogenesis.     

The embryonic thymus produces chemotactic peptides involved in the homing of hemopoietic precursors

During ontogeny, T cell precursors must colonize the thymus to acquire immunocompetency. Using migration assays, a chemotactic activity was detected in conditioned media from avian embryonic thymic epithelial cells. The responding cells were shown to acquire T lymphocyte markers after homing into the thymus. Absorption experiments demonstrated surface receptors for the chemotactic substance on these hemopoietic precursors, which were not found on thymus-derived lymphocytes. Two peaks of chemotactic activity in the 1 kd-4 kd molecular weight range were detected after fractionation of thymic epithelial cell-conditioned medium. One of these activities was retained after heating to 95 degrees C but was destroyed after proteolytic treatment. Thus chemotactic peptides may be responsible for the thymic recruitment of the first hemopoietic precursors and may also be involved in the renewal of these precursors throughout adult life.     

Macromolecular insoluble cold globulin (MICG): a marker for pluripotential hemopoietic stem cells

In embryonic mice pluripotential hemopoietic stem cells (PHSC) originate in the yolk sac and migrate to the fetal liver and from there to the bone marrow. Hemopoietic cells from yolk sac and fetal liver also migrate to the thymic primordium, and within the thymic environment these prothymocytes differentiate into mature T cells. We have recently demonstrated that macromolecular insoluble cold globulin (MICG), a T cell marker, is synthesized and inserted into the plasma membrane of embryonic prothymocytes as soon as these cells appear in the early thymus. In addition, we have shown that MICG+ cells are present within the fetal liver before the thymus has fully formed. In the present study we show that pluripotential hemopoietic stem cells in the fetal liver and bone marrow have MICG on their surface and represent a subpopulation of these MICG+ cells. The implications of these findings in relationship to stem cell differentiation and isolation are discussed.     

Evidence for a cyclic renewal of lymphocyte precursor cells in the embryonic chick thymus

Experiments involving sequential transplantations of the chick embryonic thymus at E9 to E12 into a first 3-day host quail embryo and then into a second chick host allowed demonstration of the cyclic periodicity of hemopoietic cell seeding of the embryonic thymus. After a first wave of colonization occurring between E6.5 and E8, the thymus becomes refractory to hemopoietic cell entry for about 4 days. It resumes its capacity to be seeded by a second wave of blood-borne stem cells at E12. After a second period of non receptivity starting at E14, a third wave of incoming cells reaches the thymus around E18. Therefore, with a slightly different periodicity, the same cyclic mechanism regulates the renewal of lymphocytes in chick and quail embryos. Quail hemopoietic cells were immunostained in the chimeric thymuses, with a species specific monoclonal antibody (anti-MB1) which recognizes a common surface antigenic determinant on all endothelial and blood cells of the quail (except erythrocytes). Two steps could thus be distinguished in the seeding process. When the thymus becomes receptive for hemopoietic cells, the latter first accumulate in the intrathymic blood vessels before penetrating massively in the thymic parenchyma. The quail chick-chimera system combined with the use of a species- and cell-type-specific antibody provides a unique tool for studying thymic colonization by lymphocyte precursors.     

Seeding of the 10-day mouse embryo thymic rudiment by lymphocyte precursors in vitro

The thymic rudiment was removed from the mouse embryo at 10 days of gestation, while it was still included in the 3rd branchial arch. When cultured alone, either in vitro or on the chick chorioallantoic membrane (CAM), it failed to develop as a lymphopoietic organ and remained in an epithelial state. If it was associated in transfilter culture with various types of hemopoietic organs from either embryonic or adult mice (e.g. yolk sac, fetal liver, thymus, bone marrow), it became seeded by lymphoid precursor cells and underwent a normal histogenetic process. If the donor and the receptor explants belonged to different strains of mice, the thymus that developed in culture was chimeric: thymic stroma cells (i.e., epithelial and connective cells) were of the receptor explant type, whereas the lymphoid population was of the donor type. Two genetic markers were used to label the thymic cell types, the Thy-1-1-Thy-1-2 system and the isozymes of the glucose phosphate isomerase.     

Inhibition of in vitro tumor cell invasion by Arg-Gly-Asp-containing synthetic peptides [published erratum appears in J Cell Biol 1989 Jun;108(6):following 2546]

The interaction of cells with extracellular matrix components such as fibronectin, vitronectin, and type I collagen has been shown to be mediated through a family of cell-surface receptors that specifically recognize an arginine-glycine-aspartic acid (RGD) amino acid sequence within each protein. Synthetic peptides containing the RGD sequence can inhibit these receptor-ligand interactions. Here, we use novel RGD-containing synthetic peptides with different inhibition properties to investigate the role of the various RGD receptors in tumor cell invasion. The RGD-containing peptides used include peptides that inhibit the attachment of cells to fibronectin and vitronectin, a peptide that inhibits attachment to fibronectin but not to vitronectin, a cyclic peptide with the opposite specificity, and a peptide, GRGDTP, that inhibits attachment to type I collagen in addition to inhibiting attachment to fibronectin and vitronectin. The penetration of two human melanoma cell lines and a glioblastoma cell line through the human amniotic basement membrane and its underlying stroma was inhibited by all of the RGD-containing peptides except for the one that inhibits only the vitronectin attachment. Various control peptides lacking RGD showed essentially no inhibition. This inhibitory effect on cell invasion was dose-dependent and nontoxic. A hexapeptide, GRGDTP, that inhibits the attachment of cells to type I collagen in addition to inhibiting fibronectin- and vitronectin-mediated attachment was more inhibitory than those RGD peptides that inhibit only fibronectin and vitronectin attachment. Analysis of the location of these cells that were prevented from invading indicated that they attached to the amniotic basement membrane but did not proceed further into the tissue. These results suggest that interactions between RGD-containing extracellular matrix adhesion proteins and cells are necessary for cell invasion through tissues and that fibronectin and type I collagen are important for this process.     

Extrathymic hemopoietic progenitors committed to T cell differentiation in the adult mouse

The role of the thymus in T cell commitment of hemopoietic precursor is yet controversial. We previously identified a major T cell progenitor activity in precursor cells isolated from bone marrow-derived spleen colonies. In this study, we characterize the properties of these pre-T cells. We demonstrate that they have unique phenotype and can be generated in a total absence of any thymic influence. Indeed, even when studied at the single-cell level, extrathymic T cell-committed precursors express T cell-specific genes. Moreover, these cells are not committed to a particular T cell differentiation pathway because they can generate both extrathymic CD8alphaalpha+ intraepithelial lymphocytes and thymus-derived conventional thymocytes. We also compared these pre-T cells with fully T cell-committed thymic progenitors. When tested in vitro or by direct intrathymic transfer, these cells have a low clonogenic activity. However, after i.v. transfer, thymus repopulation is efficient and these precursors generate very high numbers of peripheral T cells. These results suggest the existence of extra steps of pre-T cell maturation that improve thymus reconstitution capacity and that can be delivered even after full T cell commitment. Consequently, our studies identify a source of extrathymic progenitors that will be helpful in defining the role of the thymus in the earliest steps of T cell differentiation.     

Fibronectin-plasma membrane interaction in the adhesion of hemopoietic cells

Many hemopoietic cell lines were examined for their ability to adhere to culture dishes coated with extracellular matrix proteins. Adhesion assay was performed with murine and human leukemic cell lines representative of different stages of differentiation along both erythroid and myeloid lineages. All the hemopoietic cell lines tested adhered to fibronectin but not to laminin, types I, III, and IV collagen, serum-spreading factor, and cartilage proteoglycans. In addition to immortalized cell lines, immature erythroid and myeloid mouse bone marrow cells adhered to fibronectin. To define the fibronectin region involved in hemopoietic cell adhesion, proteolytic fragments, monoclonal antibodies, and synthetic peptides were used. Among different fibronectin fragments tested, only a 110-kD polypeptide, corresponding to the fibroblast attachment domain, was active in promoting adhesion. Moreover, a monoclonal antibody to the cell binding site located within this domain prevented hemopoietic cell adhesion. Finally, the tetrapeptide Arg-Gly-Asp-Ser, which corresponds to the fibronectin sequence recognized by fibroblastic cells, specifically and competitively inhibited attachment of hemopoietic cells to this molecule. The cell surface molecule involved in the interaction of mouse hemopoietic cells with fibronectin was identified as a 145,000-D membrane glycoprotein by adhesion-blocking antibodies. This glycoprotein was found to be antigenically and functionally related to the GP135 membrane glycoprotein involved in the adhesion of fibroblasts to fibronectin (Giancotti, F. G., P. M. Comoglio, and G. Tarone, 1986, Exp. Cell Res., 163:47-62). On the basis of these data, we conclude that interaction of hemopoietic cells with fibronectin involves a specific fibronectin sequence and a 145,000-D cell surface glycoprotein. We speculate that this property might be relevant for the interaction of hemopoietic cells with the bone marrow stroma, which represents the natural site of hemopoiesis.     

Migration of putative progenitor T cells in response to thymus-derived chemotactic factors

Progenitor T cells reach the thymus through the circulation from hematopoietic organs and then migrate toward the site of differentiation in the thymus. The mechanism that regulates such intrathymic migration is not well understood. In order to clarify this mechanism, in vitro chemotactic activity for murine thymocytes was assayed in the extracts and culture supernatants of thymic tissue elements. A potent thymocyte chemotactic activity was found in the extract and culture supernatant from Ig-, Ia- thymic stromal cells. Peanut agglutinin-positive (PNA+1), Thy 1+, TL-, Lyt 1+2-, L3T4- thymocytes, Ig-, Thy 1- bone marrow cells, and mononuclear cells of spleen and peripheral blood, but neither B cells nor lymph node cells, were chemotactically attracted by the factor(s). The chemotactic activity was found in none of the following materials tested: the extract and culture supernatant of thymocytes, culture supernatant of lymph node stromal cells, normal mouse serum, and zymosan-activated serum. The chemotactic activity was found in three molecular fractions by gel chromatography. The activity in all three fractions was destroyed by trypsin digestion or by heating at 56 degrees C for 30 min. These results suggest that Ig-, Ia- thymic stromal cells but not thymocytes secrete a chemotactic factor(s) for progenitor T cells with three molecular species. The factor is considered to play an important role in the migration of intrathymic progenitor T cells into the site of differentiation.     

Laminin chains in the basement membranes of human thymus

Summary In recent studies, the α2 chain of laminin (Ln) has been suggested to be the only laminin α chain expressed in mouse and human thymus. We have now used chain-specific monoclonal antibodies and indirect immunofluorescence microscopy to study the expression of laminin chains in samples of foetal and 6-year-old human thymus. The subepithelial basement membrane of the capsule of foetal 16- to 18-week thymus presented a bright immunoreactivity for Ln α1, α3, β1, β3 and γ1 chains but not for α2 chain, suggesting the expression of laminins-1 and-5. Most cortical and medullary epithelial cells, including Hassall's corpuscles, however, lacked laminin immunoreactivity. Immunoreactivity for Ln β2 chain was only seen in basal laminae of larger blood vessels. In thymic specimens from 6-year-old children, immunoreactivity for the laminin α1, α3, β1, β3 and γ1 chains was invariably found in subepithelial basement membrane of the capsule and that for laminin α2 chain was now also distinct but more heterogeneous. Furthermore, the thymic subepithelial basement membrane of the capsule at all stages showed immunore-activity for collagen type VII, forming the anchoring fibres in epithelial basement membranes. The subcapsular thymic epithelium also showed immunoreactivity for the BP 230 antigen and β₄ integrin subunit, both components of hemidesmosomes. The present results show that the thymic subepithelial basement membrane of the capsule presents properties which are commonly seen in stratified and combined epithelia, and are compatible with suggestions of the antigenic similarity of thymic epithelial cells and keratinocytes.     

Extracellular matrix of lymphoid tissues in the chick

We describe the immunohistochemical distribution of components of the extracellular matrix of the chick lymphoid system. In the thymus, basement membranes of epithelial cells bordering the lobules were intensely stained by laminin antibodies; fibronectin antibodies labeled the capsule and the septal matrix, and similar reactivity was seen with tropoelastin and gp 115 antibodies. No positivity was detected with any of the antibodies within the cortical parenchymal cells. Laminin was not detected in the medullary parenchyma, whereas fibronectin was present as coarse fibers. Tropoelastin and gp 115 appeared as a finer and more diffuse meshwork. In the bursa, laminin antibodies outlined the epithelial cells separating the cortex from the medulla. Fibronectin, tropoelastin, and gp 115 antibody stained the interfollicular septa and the cortical matrix, although to a different extent. Laminin was also detected in association with the interfollicular epithelium (IFE) basement membrane, whereas no staining was found underneath the follicle-associated epithelium (FAE). FAE cells not only lack a proper basement membrane but are also not separated from medullary lymphocytes by any of the other extracellular matrix components were investigated. Consequently, medullary lymphocytes are not sequestered, and can come easily into contact with antigens present in the intestinal lumen. All four antibodies stained the spleen capsule and spleen blood vessels, tropoelastin and gp 115 antibodies giving the strongest reactivity. A fine trabecular staining pattern was detected with gp 115 antibodies in the white pulp.     

Bone marrow-derived hemopoietic precursors commit to the T cell lineage only after arrival in the thymic microenvironment

T lymphocytes develop in the thymus from hemopoietic precursors that commit to the T cell lineage under the influence of Notch signals. In this study, we show by single cell analyses that the most immature hemopoietic precursors in the adult mouse thymus are uncommitted and specify to the T cell lineage only after their arrival in the thymus. These precursors express high levels of surface Notch receptors and rapidly lose B cell potential upon the provision of Notch signals. Using a novel culture system with complexed, soluble Notch ligands that allows the titration of T cell lineage commitment, we find that these precursors are highly sensitive to both Delta and Jagged ligands. In contrast, their phenotypical and functional counterparts in the bone marrow are resistant to Notch signals that efficiently induce T cell lineage commitment in thymic precursors. Mechanistically, this is not due to differences in receptor expression, because early T lineage precursors, bone marrow lineage marker-negative, Sca-1-positive, c-Kit-positive and common lymphoid progenitor cells, express comparable amounts of surface Notch receptors. Our data demonstrate that the sensitivity to Notch-mediated T lineage commitment is stage-dependent and argue against the bone marrow as the site of T cell lineage commitment.     

Differential participation of ventral and dorsolateral mesoderms in the hemopoiesis of Xenopus, as revealed in diploid-triploid or interspecific chimeras

The thymocytes in the early larvae of Xenopus laevis have been shown to be derived from precursor cells immigrating interstitially through the mesenchyme into the organ rudiments at 3-4 days of age (Nieuwkoop and Faber stages 42-45). Orthotopic grafting of diploid tissues onto triploid stage 22 embryos followed by ploidy analyses of their hemopoietic cells revealed that both thymocytes and erythrocytes in early larvae are derived from the ventral blood islands (VBI), whereas those in late larvae and adults come mainly from the dorsolateral plate (DLP). To study how the VBI cells of embryos at stage 22 participate in hemopoiesis, a number of interspecific chimeras were produced in X. laevis and X. borealis embryos. Sections of the chimeras at various developmental stages were examined by employing the unique stainability of X. borealis nuclei to quinacrine as a marker; the results show that the VBI-derived cells enter into the circulation around stage 35/36, and that some of them leave the blood vessels to migrate interstitially through the mesenchyme toward the thymic rudiment during stages 43-45. A minor population of the VBI-derived cells was also found extravascularly in the mesonephric primordia. In contrast to the VBI, the DLP-derived cells contributed to the hemopoietic cell population not in early larvae, but in late ones as a major constituent in the mesonephros, thymus, liver, and peripheral blood.     

Extracellular matrix components synthesized by human amniotic epithelial cells in culture

Epithelial cells from human post-partal amniotic membrane in primary culture secreted two major matrix proteins, fibronectin and procollagen type III, and small amounts of laminin and basement membrane collagens (types IV and AB). Identified in the culture medium by immunoprecipitation, these components were located by immunofluorescence to a pericellular matrix beneath the cell monolayer. Deposition of fibronectin, laminin and procollagen type III occurred under freshly seeded spreading cells. In the matrix of confluent cultures, fibronectin and procollagen type III had a moss-like distribution. Matrix laminin had predominantly a punctate pattern and was sometimes superimposed on the fibronectin-procollagen type III matrix. In the human amniotic membrane in vivo, laminin, type IV collagen and fibronectin were located to a narrow basement membrane directly beneath the epithelial cells. Fibronectin and procollagen type III were detected in the underlying thick acellular compact layer. Fibronectin secreted by amniotic epithelial cells is a disulfide-bonded dimer of slightly higher apparent molecular weight (240 kilodaltons) than fibronectins isolated from human plasma or fibroblast cultures. Laminin was detected in small amounts in the culture medium. Laminin antibodies precipitated a polypeptide of about 400 kilodaltons, and two polypeptides with slightly faster mobility in electrophoresis under reducing conditions than fibronectin. Procollagen type III was by far the major collagenous protein whereas little or no production of procollagen type I could be observed. Basement membrane collagens were identified as minor components in the medium by immunoprecipitation (type IV) or chemical methods (αA and αB chains).     

The netrin receptor DCC focuses invadopodia-driven basement membrane transmigration in vivo

Though critical to normal development and cancer metastasis, how cells traverse basement membranes is poorly understood. A central impediment has been the challenge of visualizing invasive cell interactions with basement membrane in vivo. By developing live-cell imaging methods to follow anchor cell (AC) invasion in Caenorhabditis elegans, we identify F-actin–based invadopodia that breach basement membrane. When an invadopodium penetrates basement membrane, it rapidly transitions into a stable invasive process that expands the breach and crosses into the vulval tissue. We find that the netrin receptor UNC-40 (DCC) specifically enriches at the site of basement membrane breach and that activation by UNC-6 (netrin) directs focused F-actin formation, generating the invasive protrusion and the cessation of invadopodia. Using optical highlighting of basement membrane components, we further demonstrate that rather than relying solely on proteolytic dissolution, the AC’s protrusion physically displaces basement membrane. These studies reveal an UNC-40–mediated morphogenetic transition at the cell–basement membrane interface that directs invading cells across basement membrane barriers.     

Immunohistochemical localization of fibronectin in the human placentas at their different stages of maturation

Summary The distribution of fibronectin in the human placenta was studied by the aid of the immunoperoxidase technique using specific antibodies against it. In the early chorionic tissue, fibronectin was distributed along the trophoblastic basement membrane, on the wall of fetal blood vessels, in the counective tissue core, and in the cytotrophoblastic cell columns. In the term placenta, this glycoprotein was detected mainly on the fetal blood vessels and less intensely in the stroma, but not along the trophoblastic basement membrane. Endothelial cells of the blood vessels, fibroblastic cells in the stroma, and unidentified cells in the cytotrophoblastic cell columns were immunostained positively for fibronectin. These data suggest that fibronectin of the placenta is produced locally and retained in the tissue, if not all.     

Further characterization of the suppressor cells, activated by goat anti-Th-B antibody reagent and responsible for enhanced growth of sarcoma 180 in AKR mice.

In our previous study, thymus cells were shown to be responsible for enhancing the growth of the allogeneic sarcoma 180 (S180) in AKR mice that had been injected with goat anti-Th-B antibody reagent (antiserum raised in goats against Balb/c myeloma MOPC 104E cells and purified). We suggested that the cells producing enhancement are suppressor T cells. We now show that the cells responsible for tumor enhancement are indeed T cells, since they carry the Thy-1 antigen on their surface. Treatment of the cells in vitro with anti-Thy-1 plus complement completely eliminates their ability to enhance tumor growth. The thymocytes responsible for tumor enhancement do not carry the Th-B determinant. Treating thymocytes in vitro with goat anti-Th-B antibody reagent plus complement does not abrogate their tumor-enhancing activity. This suggests that the suppressor T cells involved in tumor enhancement are generated by the interaction of anti-Th-B antibodies with precursor suppressor cells which do carry Th-B. Once generated, the active suppressor cells lose the Th-B antigen. This suggestion is supported by our finding that the thymic precursors of Con A-inducible suppressor cells bear Th-B, since they are killed by anti-Th-B plus complement, whereas active suppressor cells induced by Con A do not carry Th-B, since they are not killed by anti-Th-B plus complement. Neither splenic precursors of Con A-inducible suppressor cells nor the active suppressor cells thus induced carry Th-B since neither is killed by anti-Th-B plus complement. We have also found that there are apparently nonthymic suppressor cell precursors which can also be activated by anti-Th-B, since spleen cells from thymectomized mice bearing S180 and treated with anti-Th-B can transfer the tumor-enhancing effect. We conclude that precursors of suppressor cells carry the Th-B determinant. These precursors differentiate to active suppressor cells when stimulated by anti-Th-B antibodies. This process can take place either outside the thymus or in the thymus. Once differentiated, the mature suppressor cells no longer bear the Th-B marker and migrate from their sites of induction. Such cells can suppress immune mechanisms responsible for allogeneic tumor graft rejection and thus cause tumor enhancement.     

Development of functional thymic epithelial cells occurs independently of lymphostromal interactions

The thymus provides a specialised microenvironment for the development of T-cell precursors. This developmental programme depends upon interactions with stromal cells such as thymic epithelial cells, which provide signals for proliferation, survival and differentiation. In turn, it has been proposed that development of thymic epithelial cells themselves is regulated by signals produced by developing thymocytes. Evidence in support of this symbiotic relationship, termed thymic crosstalk, comes from studies analysing the thymus of adult mice harbouring blocks at specific stages of thymocyte development, where it is difficult to separate mechanisms regulating the initial development of thymic epithelial cells from those regulating their maintenance. To distinguish between these processes, we have analysed the initial developmental programme of thymic epithelial cells within the embryonic thymus, in either the presence or absence of normal T-cell development. We show that keratin 5+8+ precursor epithelial cells present in the early thymic rudiment differentiate into discrete cortical and medullary epithelial subsets displaying normal gene expression profiles, and acquire functional competence, independently of signals from T-cell precursors. Thus, our findings redefine current models of thymus development and argue against a role for thymocyte-epithelial cell crosstalk in the development of thymic epithelial progenitors.