Tissue interaction in the development of thymus lymphocytes

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.

Evaluation of immunity

Immunodeficiency disease is rapidly increasing in frequency. The AIDS epidemic, the increasing use of transplantation with immunosuppression, the aggressive immunotherapy, the persistent deficiencies after bone marrow transplantation--all contribute to the astronomically increasing numbers of patients with host defense failure. This review has presented my viewpoint as to the approaches which can be utilized by practitioners with varying focal points to provide diagnosis and maximize the potential for a cure today or at least to provide the beginnings of understanding from which will come the cures of tomorrow.

Early genetic events in T cell development analyzed by in situ hybridization

In situ hybridization was used to investigate the expression of T cell receptor (TCR) alpha, beta, and gamma mRNAs in developing fetal and adult precursor thymocytes. gamma transcription was observed at the earliest time tested (day 12), followed by beta 12 h later, and TCR alpha on day 16. The early beta transcripts appeared to be from unrearranged or incompletely rearranged (D-J-C) beta loci. V beta region transcription was first detectable on day 14 and transcription of different V beta genes was induced at different times. These results delineate a schedule sequence of TCR gene activation, which begins within 1 d after entry of stem cells into the fetal thymus.

The effects of leukemosuppressive immunotherapy on bone marrow infectious cell centers in AKR mice

The bone marrow of AKR mice is the richest source of infectious ecotropic cell centers (ICCs) during the neonatal period. The bone marrow ICCs reside in a low-density population expressing high levels of viral glycoprotein (gp71) and Class I histocompatibility antigens (H-2Kk). In addition, ICCs are enriched in the lymphoid band of Ficoll-Hypaque-fractionated bone marrow, the adherent population of nylon wool separated cells and among the low-density subpopulation of Percoll-fractionated marrow. The observed dichotomy between viral antigen expression and actual virus production suggests that actively cycling cells may be the primary virus producers in the AKR bone marrow. The phenotypic and physical data indicate that bone marrow stem cells and/or prothymocytes may be among the initial virus producing cells in the AKR bone marrow. Leukemosuppressive antiviral immunotherapy delays the appearance of ICCs in the bone marrow but does not exert any major long-term changes on the populations of cells present.

Defective lymphopoiesis in bone marrow of motheaten (me/me) and viable motheaten (mev/mev) mutant mice. I. Analysis of development of prothymocytes, early B lineage cells, and terminal deoxynucleotidyl transferase-positive cells

This study identifies defects in the early stages of lymphopoiesis that may contribute to the abnormalities in the development and/or function of peripheral T and B lymphocytes in mice homozygous for the motheaten (me/me) and viable motheaten (mev/mev) mutations. The results indicate that in me/me and mev/mev mice prothymocytes in bone marrow are present in essentially normal numbers, as determined by intrathymic injection, but apparently lack the ability to home effectively to the thymus, as determined by intravenous transfer; early B lineage cells in bone marrow, identified by the B220 antigen, are markedly depleted, including immature B cells (sIg+), pre-B cells (cIg+, sIg-), and pro-B cells (B220+, cIg-, sIg-); TdT+ bone marrow cells, especially a subset that expresses the B220 B lineage antigen, are markedly depleted by two weeks of age; normal numbers of TdT+ thymocytes are present during the first 3 wk of postnatal life, but rapidly decrease thereafter. The results further indicate that neither the defective thymus homing capacity of prothymocytes nor the deficiency of TdT+ bone marrow cells is due to autoantibodies. The possible relationship of the defective development of lymphoid precursor cells to the premature onset of thymic involution and to the abnormalities of peripheral T and B lymphocytes in me/me and mev/mev mice is discussed; as are the results of in vitro studies (presented in a companion paper), which suggest that a primary defect in the stromal microenvironment of the bone marrow is responsible for the abnormal development of the lymphoid precursor cells.

Dynamics of early T cells: prothymocyte migration and proliferation in the adult mouse thymus

The object of this review has been to consider precursor cell migration into the normal adult thymus, using the mouse model. We have presented a series of experiments and discussed them in the context of other relevant experiments in the literature. The conclusions, qualified in the text, can be summarized as follows: There is a continual input of precursor cells into the normal undepleted adult thymus. The daily input of precursors under normal circumstances is very low (e.g. several per day). Once a precursor enters the pool of proliferating cells inside the thymus, its proliferation is limited to only several weeks. There is no permanent endogenous stem cell. There are a number of different precursor microenvironments in the thymus with different controls, since the kinetics of early (bone marrow-derived) and late (thymus-derived) precursors is quite different. All of these points require further analysis, and we have presented a minimal model as a basis for further experiment.

A scanning electron-microscopic study of the rat thymus with special reference to cell types and migration of lymphocytes into the general circulation

The three-dimensional structure of the rat thymus was studied by combined scanning- and transmission electron microscopy. The thymus consists mainly of four types of cells: epithelial cells, lymphocytes, macrophages, and interdigitating cells (IDCs). The epithelial cells form a meshwork in the thymus parenchyma. Cortical epithelial cells are stellate in shape, while the medullary cells comprise two types: stellate and large vacuolated elements. A continuous single layer of epithelial cells separates the parenchyma from connective tissue formations of the capsule, septa and vessels. Surrounding the blood vessels, this epithelial sheath is continuous in the cortex, while it is partly interrupted in the medulla, suggesting that the blood-thymus barrier might function more completely in the cortex. Cortical lymphocytes are round and vary in size, whereas medullary lymphocytes are mainly small, although they vary considerably in surface morphology. Two types of large wandering cells, macrophages and IDCs, could be distinguished, as well as intermediate forms. IDCs sometimes embraced or contacted lymphocytes, suggesting their role in the differentiation of the latter cells. Perivascular channels were present around venules and some arterioles in the cortico-medullary region and in the medulla. A few lymphatic vessels were present in extended perivascular spaces. The present study suggests the possible existence of two routes of passage of lymphocytes into the general circulation. One is via the lymphatics, while the other is through the postcapillary venules into the blood circulation. Our SEM images give evidence that lymphocytes use an intracellular route, i.e., the endothelium of venules.

Stromal cell types in the developing thymus of the normal and nude mouse embryo

The anatomical distribution of various nonlymphoid cell types in the embryonic mouse thymus in vivo and in vitro, as well as in the thymic rudiment of the nude mouse embryo, has been studied. For this purpose a panel of monoclonal antibodies, ER-TR3, 4, 5, 6 and 7, directed to various types of stromal cells of the mouse thymus, was used in combination with immunoperoxidase labeling on frozen sections. It was shown that as early as day 13 in thymic ontogeny distinction of TR4+ cortical epithelial cells and TR5+ medullary epithelial cells is possible. Thus, as far as stromal components are concerned, the thymus at day 13 in ontogeny is already subdivided into cortex and medulla. At day 13, Ia (TR3) was expressed in a focal pattern in the medulla subsequently appearing throughout both cortex and medulla by day 16. The thymic rudiment of the nude mouse embryo differs markedly from the normal embryonic thymus in its lack of demonstrable Ia antigen. Furthermore, TR4 and TR5 were only expressed on occasional epithelial cells lining the cysts of the nude thymus in a mutually exclusive fashion. The majority of stromal cells of the nude thymus, however, is negative for all ER-TR antibodies tested. In addition, we have shown that in organ cultures the organization of the stroma of thymic lobes remains intact, at least for a period of 11 days. Embryonic thymi cultured in the presence of deoxyguanosine, which causes depletion of lymphoid cells, also contain cortical and medullary areas as identified by the presence of TR3,4+ and TR5+ stromal cells. This indicates that the lack of organization in the nude thymus is not simply due to the absence of lymphoid cells.

The Pgp-1 antigen is expressed on early fetal thymocytes

The Pgp-1 glycoprotein is expressed on the bone marrow prothymocyte and on a class of intrathymic progenitor cells in the adult animal. Only 5% of adult thymocytes are strongly Pgp-1+. When fetal thymocytes of day 13-14 of gestation are examined by flow cytometric analysis, 80-90% of thymocytes are Pgp-1+, while the bulk of thymocytes are Thy-1-. By day 15-16, the percentage of Pgp-1+ cells begins to fall while nearly all cells become Thy-1+. Two-color immunofluorescence indicates that many Pgp-1+ cells are Thy-1+. The percentage of Pgp-1+ cells continues to fall over the next several days, reaching adult levels by day 19. These observations are consistent with the interpretation that at least some classes of thymocyte progenitors are Pgp-1+.

Genes encoding the Ti beta subunit of the antigen/MHC receptor undergo rearrangement during intrathymic ontogeny prior to surface T3-Ti expression

To obtain further information about the ontogeny of the T-cell antigen/MHC receptor, a Ti beta subunit cDNA probe and heteroantisera specific for the Ti alpha and Ti beta subunits were utilized to characterize human T-lineage cells. Analysis of thymic tumors and normal thymocytes at both the DNA and protein levels demonstrates that Ti beta gene rearrangement is evident in stage II (T11+T6+T3-) and stage III (T11+T6-T3+), but not stage I (T11+T6-T3-) thymocytes. In contrast, surface expression of Ti alpha and Ti beta molecules is exclusively restricted to stage III thymocytes. Thus human T-lineage ontogeny is characterized by an orderly series of differentiation steps wherein Ti beta gene rearrangement precedes surface expression of the T3-Ti molecular complex.

Ontogeny of primary lymphoid organs and lymphoid stem cells

Cells of the immune system go through a series of important developmental steps that begin early in embryonic life and include, first, the various waves of hemopoietic-cell production in the embryo and, second, the homing of these cells to the hemopoietic organs, which are the sites of hemopoiesis and lymphopoiesis in embryonic and adult life. The avian embryo is an important model for investigating these early steps; and this paper presents a comprehensive review of the work done on the early ontogeny of the avian immune system.

Properties of mouse leukemia viruses. XIX. Effective antibody therapy of AKR leukemia occurs independently of virus neutralization and produces long-term changes in the virus status of the thymus

Administration of high-titered goat anti-FLV gp71 IgG to AKR mice during a narrow neonatal therapy "window" suppresses the early development of MuLV infectious cell centers (ICC) in spleen, thymus, and bone marrow. By 4-5 weeks of age ICC appear in spleen and marrow cell populations, rapidly increasing to plateau levels within 2 weeks in the absence of viremia. The thymus of treated animals remains devoid of detectable ICC throughout the 4-month period of testing. This pattern of ICC suppression occurs independently of virus neutralization as shown by the inability of F(ab')2 preparations, which retained neutralizing activity, to prevent early establishment of ICC. Immune IgG significantly decreases, but does not eliminate gp71 expression in all tissues tested. In control animals, ICC reside within a minor subpopulation of cortical, thymic T cells, whereas peripheral (i.e., splenic) ICC are totally devoid of conventional T cell, B cell, and macrophage phenotypic markers. Although thymocytes appear to be a major target of this antibody therapy, T-cell reactivity is not compromised.

Leukemic transformation in hrs mice occurs in an immature-nonactivated thymocyte subpopulation

The murine leukemic strain HRS/J has an autosomal-recessive, mutant gene, hr, with homozygotes (hr/hr) having a 72% incidence of thymic leukemia at 18 months of age compared to 20% in heterozygotes (hr/+). This study was done to (a) determine if expression of thymocyte differentiation and murine leukemia virus (MuLV) antigens during leukemic transformation were different in hr/hr compared to hr/+ mice, (b) define the subpopulations that were targets for leukemic transformation, and (c) compare the results to reports in other leukemic strains. Flow cytometry analysis of thymus cell suspensions was done with anti-T-cell and anti-H-2 monoclonal antibodies, peanut agglutinin (PNA), and heteroantisera to MuLV antigens. Thymocytes of 1- to 3-month-old HRS/J mice were Thy 1.2+, Lyt 1+2+, H-2Kk-, and MuLV- with an immature-nonactivated phenotype, i.e., PNA+, and Iak-. Preleukemic and leukemic thymocytes showed diversity in expression of Thy 1.2 and Ly antigens with increased H-2Kk and MuLV expression. No differences in phenotype patterns were noted between hr/+ and hr/hr mice during the time course of leukemogenesis. Persistently high PNA/low Iak expression of preleukemic and leukemic thymocytes indicated that the target for HRS leukemic transformation was an immature-nonactivated thymocyte subpopulation in contrast to AKR/J mice in which leukemic transformation involves a mature-activated thymocyte subpopulation. These findings suggest that spontaneously generated leukemogenic viruses in HRS mice have tropism for thymocytes of an immature-nonactivated phenotype.

The human T cell receptor: analysis with cytotoxic T cell clones

Employing human T lymphocyte clones and monoclonal antibodies to their surface glycoproteins, the antigen receptors on these cells have been defined. Based on functional and biochemical data, it is shown that each T cell displays two major recognition units on its surface. One structure consists of the antigen-binding region (Tin-T3) which views antigen X in the context of a polymorphic region of an MHC molecule. A second (T8 or T4) serves as an associative recognition structure for a constant region of the class I or class II molecule. The antigen-binding structure is a heterodimer of disulfide linked 49KD and 43KD subunits, which contains clonally unique variable regions. These are non-covalently associated with the 20/25KD monomorphic T3 molecule expressed on all mature human T lymphocytes. The associative-recognition element on an individual clone is either T8 or T4, depending on its subset derivation. It is likely that these glycoproteins bind to constant regions of class I or class II molecules, respectively, and are independent of the Tin-T3 complex complex.

Postirradiation thymocyte regeneration after bone marrow transplantation. III. Intrathymic differentiation and development of thymocyte subpopulations

Fluorescence distributions of thymocytes stained for Thy-1 as well as size measurements were used to discriminate between thymocyte subpopulations during regeneration of the thymus after irradiation and bone marrow transplantation. Subpopulations with "low" and "high" Thy-1 density of donor- and recipient-derived progeny were quantitated. They were continuously present in the thymus and developed simultaneously but at different rates of growth. A similar developmental pattern was observed for donor- and host-derived "high" Thy-1+ cells, whereas "low" Thy-1+ cells of donor and recipient origin showed markedly different growth patterns. This indicated that development of the two subpopulations took place independently. During early regeneration donor-derived "low" and "high" Thy-1+ cells contain a high proportion of large cells, indicating the presence of cycling cells in both subpopulations.

Differentiation of the mouse hepatic primordium. II. Extrinsic origin of the haemopoietic cell line

The whole hepatic primordium (endoderm + mesenchyme of the septum transversum) was isolated from mouse embryos at various developmental stages, from 8 to 10 days of gestation, and was either grafted into chick or quail embryo or cultivated in vitro. Haemopoiesis developed only if the liver rudiment had been explanted after the 28- to 30-somite stage, but not if explanted prior to this stage, despite normal differentiation of the hepatocytes. However, when the liver rudiment, isolated before the 28-somite stage in in vitro culture, was supplied with exogenous haemopoietic stem cells, haemopoiesis developed in the hepatic tissue. These data show that foetal hepatic haemopoiesis depends on migration of haemopoietic cells which home the liver rudiment at the 28- to 30-somite stage.

Asymmetric division of lymphoid cells of the thymus of embryonic guinea-pigs. A cell kinetic study

Cell division of thymus lymphoid cells from 30- to 60-day-old embryonic guinea-pigs, as well as young adults was investigated on cell smears stained with Giemsa. Asymmetrically dividing cells were found in the developmental stage of thymocytes. At the telophase of such cells, the cytoplasma of one of two immature daughter cells was apparently larger in amount than that of the counterpart cell. When 40-day embryonic lymphoid cells were examined, most of the asymmetrically dividing cells at telophase belonged to the larger cell population (mean diameter 15.7 micrometer). The mean diameters of the larger and smaller immature daughter cells of these dividing cells were estimated as 12.0 and 9.2 micrometer, respectively. Ultrastructural study also revealed a lymphoid cell which was under-going in situ apparent symmetric division at telophase. One of two immature daughter cells alone possessed a large cytoplasmic protrusion with few organella. The frequence of asymmetric division calculated by a rough estimation was around 10% of the total cell division between days 30 and 40 of embryonic development, and decreased thereafter. During this developmental period, thymic lymphoid cells were shown to progressively transform into smaller cells. A scheme regarding the mode of thymocyte proliferation during the embryonic period is proposed. and the biological meaning of the present phenomenon is discussed.

Asymmetric division of immature lymphoid cells of the embryonic mouse thymus

Cell division of thymus lymphoid cells from 15- to 19-day-old embryonic mice, as well as from 2- and 7-day-old mice was investigated on cell smears stained with Giemsa or with the Feulgen reaction followed with malachite green. Asymmetrically dividing cells were observed during the development. At the anaphase and telophase of such cells, the nucleus of one of two immature daughter cells was apparently smaller and more condensed than that of the counterpart cell. The asymmetry was already apparent at the level of sister chromosomes at anaphase. Sometimes a difference also existed in the cytoplasm: the cytoplasm of the smaller immature daughter cell with condensed nucleus was stained with Giemsa more deeply than that of the counterpart. The frequency of cells displaying apparent asymmetric division among total dividing cells at the telophase was around 10% between 15 and 19 days of gestation, and decreased to 2% on days 2 and 7 after birth. Asymmetrically dividing cells belonged to immature lymphoid cells of larger size. The biological implications of the present phenomenon are discussed.

Studies on the termination of immunological tolerance in the mouse thymus cell population after irradiation

Immunological tolerance in the mouse thymus cell population induced by the intravenous injection of deaggregated bovine gamma globulin was terminated by whole body irradiation. After irradiation, the weight of the thymus recovered biphasically, and the termination of tolerance occurred as early as in the first phase. Both Thy-1 antigen expression and helper activity of the thymus cell population in irradiated mice recovered in parallel with the recovery of the thymus weight. Sensitivity of the regenerating thymus cell to the tolerogen was not different from that of the normal thymus cell. The first phase of thymus regeneration may be caused by the proliferation and differentiation of relatively radioresistant and tolerogen insensitive precursors residing in the thymus. Tolerogen and/or immunogen reactive thymus cells may originate from the precursor.

The characterization and function of human immunoregulatory T lymphocyte subsets

Functional T lymphocyte subpopulations can be identified in humans by antibodies which detect stable glycoprotein antigens on their surface. Thus, inducer T lymphocytes bear an antigen termed T4 while suppressor T lymphocytes bear an antigen termed T5. Immune homeostasis results from a delicate balance between inducer and suppressor subsets within the T-cell circuit and perturbation in subset dynamics may initiate a wide variety of immunopathological disorders. Here Ellis Reinherz and Stuart Schlossman discuss the present understanding of this circuit, its role in the pathogenesis of a number of diseases and how the human immune response can be manipulated in an orderly way through modulation of selected T-cell subsets.

Post-irradiation thymocyte regeneration after bone marrow transplantation. I. Regeneration and quantification of thymocyte progenitor cells in the bone marrow

Growth kinetics of the donor-type thymus cell population after transplantation of bone marrow into irradiated syngeneic recipient mice is biphasic. During the first rapid phase of regeneration, lasting until day 19 after transplantation, the rate of development of the donor cells is independent of the number of bone marrow cells inoculated. The second slow phase is observed only when low numbers of bone marrow cells (2.5 x 10(4)) are transplanted. The decrease in the rate of development is attributed to an efflux of donor cells from the thymus because, at the same time, the first immunologically competent cells are found in spleen. After bone marrow transplantation the regeneration of thymocyte progenitor cells in the marrow is delayed when compared to regeneration of CFUs. Therefore, regenerating marrow has a greatly reduced capacity to restore the thymus cell population. One week after transplantation of 3 x 10(6) cells, 1% of normal capacity of bone marrow is found. It is concluded that the regenerating thymus cells population after bone marrow transplantation is composed of the direct progeny of precursor cells in the inoculum.

Lyt 1+23- cells appear in the thymus before Lyt 123+ cells

Most thymocytes are either immature or functionally deficient and express a series of lymphocyte cell-surface antigen markers designated Lyt 1, Lyt 2 and Lyt 3 (refs 1, 2) which have been useful in distinguishing functional subsets of T cells. In contrast, a small population of cortisone-resistant thymocytes (CRT), confined to the thymic medulla after acute corticosteroid treatment are functionally more mature. These cells, like peripheral T cells, have restricted expression of Lyt antigens and mostly are either Lyt 1 or Lyt 123 cells. It has thus been assumed that all thymocytes initially are Lyt 1+, 2+, 3+ and by differentiation lose either Lyt 1 or Lyt 2, 3 to result in Lyt 1+(23-) and Lyt (1-)23+ cells. Using immunofluorescence (IF) and flow microfluorometry (FMF) analyses to detect Lyt antigen expression quantitatively without the requirement for cell lysis, we have now re-examined the expression of Lyt 1, 2 and 3 antigens on murine fetal thymocytes from 14 to 19 days of gestation and on normal thymocytes from birth to 2-3-month-old adults. These studies demonstrate that cells with the Lyt 1+23- phenotype first appear in the thymus several days before Lyt 123+ thymocytes are detected, and suggest either a micro-environmental or site-specific influence for phenotypic differentiation and/or two independent, pre-committed lineages.

Discrete stages of human intrathymic differentiation: analysis of normal thymocytes and leukemic lymphoblasts of T-cell lineage

A series of monoclonal antibodies was used to define three discrete stages of human intrathymic T-cell differentiation. The earliest stage was confined to <10% of thymocytes, which were.reactive with both OKT9 and OKT10. Subsequently, approximately 70% of human thymocytes acquired a thymocyte-restricted antigen, OKT6, lost OKT9 antigen, and expressed reactivity with OKT4 and OKT5. These last two monoclonal antibodies were previously shown to define inducer (helper) and cytotoxic/suppressor populations, respectively, in peripheral blood. The OKT4(+), OKT5(+), OKT6(+) "common" thymocyte population represents the majority of thymocytes and accounts for more than 70% of thymocytes. With further maturation, thymocytes lose OKT6 reactivity, segregate into OKT4(+) and OKT5(+) subsets, and acquire reactivity with OKT3 (and OKT1). This latter stage corresponds to the more functionally mature subset. The possible relationship of acute lymphoblastic leukemia of T-cell lineage to these proposed stages of intrathymic differentiation was determined. Analysis of 25 tumor populations showed that 21 could be related to one or another differentiative stage. The majority (15/21) were derived from an early thymocyte or prothymocyte subpopulation, 5/25 were derived from a common thymocyte subpopulation, and 1/25 was derived from a mature (OKT3(+)) subpopulation. These data suggest that is it now possible to define stages of T-cell differentiation that can be related to T-cell malignancies in humans.

A cytophotometric and flow cytofluorometric approach to the differentiation of T lymphocytes in the thymus

By cytophotometric and flow cytofluorometric DNA and protein determinations two main proliferating subpopulations of thymus lymphocytes with a different percentage of cells in the S phase could be distinguished. One subpopulation had a very low protein content, was cortisone sensitive and located in the cortex. Cells with comparable low protein contents were not found amongst lymphocytes of the peripheral blood. The other lymphocyte subpopulation had a higher protein content, was cortisone resistant and situated in the cortex around a group of epithelial cells and in the medulla. The protein content of these thymus lymphocytes appeared to be comparable to that of the peripheral blood lymphocytes. On the basis of the protein content per cell, it is possible to identify and isolate the more often described major subpopulation of cortisone sensitive thymus lymphocytes remaining and dying in the thymus, and the minor cortisone resistant subpopulation of thymus lymphocytes which is the source of the peripheral T lymphocyte.

The in vitro migration of murine fetal liver cells to thymic rudiments

The migration of murine fetal liver cells to thymus rudiments was studied in vitro using a migration under agar technique. There appeared to be a minor population that migrated specifically to the thymus from the age of 10 to 14 days of gestation. The specificity of migration was demonstrated in 12-day fetal liver cells by a series of competition studies. The ability of these cells to colonize a thymus rudiment was shown by further incubation after invasion of the epithelial thymus rudiments: small colonies of lymphoid cells were present in invaded tissue but absent from uninvaded control tissue. At 13 to 14 days of gestation, there appeared an additional population that migrated specifically to the spleen, as demonstrated, again, with a competition protocol. Studies with avian and human tissue as attractants in the same system showed that migration was specific to the thymus and did cross species barriers. This observation was used to demonstrate a similar attractant activity in cell-free conditioned medium from human thymus epithelial cultures, and to demonstrate the absence of such a cell-attractant factor in the conditioned medium from the thymus of a child with previously documented severe combined immunodeficiency disease.

Functional relationship of macrophages and basophils to the thymus gland

Human thymus epithelium, depleted of thymocytes and macrophages by means of organ culture, was used in chemotaxis experiments with peripheral blood cells. Such cultured thymus epithelium can attract specifically macrophages and basophils. T-lymphocytes were attracted only by short-term (8 day) cultured thymus tissue which still retains some of the original macrophage population. Thymic macrophages formed rosette structures with thymocytes. In other experiments 'activated' rabbit macrophages had the capability to destroy thymocytes, whether autochthonous or allogeneic. The possible role of macrophages and basophils in thymus function is discussed.

Lymphocytes. 2. Differentiation. Differentiation of lymphoid precursor cells

Images

The differentiation of murine thymocytes in vivo and in vitro

The differentiation of lymphoid cells in the early foetal mouse thymus was studied in vivo and in organ culture. The lymphoid precursors found in the 13 and 14 day foetal thymus constituted about 50% of the total thymus cell population. These T precursors were large blast-like cells which already expressed the Thy-1 antigen but were mostly TL negative. Both in vivo and in vitro the blasts were rapidly replaced by a population of typical small lymphocytes which were strongly Thy-1 and TL positive but Ig negative. In organ cultures grown under optimal conditions, large bimodal increases in cell numbers occurred. An initial population of about 2 x 10(4) T precursors per thymus lobe gave rise to nearly 10(6) predominantly Thy-1 and TL positive small lymphocytes by the 6--8th day in vitro. After this time lymphocyte numbers decreased until about the 10th day when they again increased to form a second peak of small lymphocytes on the 12--13th day. These cells were also predominantly Thy-1 positive but the majority were now TL negative. No Ig positive B lymphocytes were detected either by immunofluorescence or by autoradiography using polyvalent anti-MIg sera and no plasma cells were detected by electronmicroscopy. At all times however, minor subpopulations of Thy-1 negative small cells were present. The production of small lymphocytes during the 1st week of culture was critically dependent on culture conditions and particularly on the batch of FCS used. The population developing during the 2nd week required less stringent conditions and was less dependent on FCS. The culture systems described should prove useful in the study of T-lymphocyte differentiation.