Characterization of rat T cell precursors sorted by chemotactic migration toward thymotaxin

Thymic stromal cells produce soluble factors which increase polarization of chicken thymocytes

The effects were examined of soluble factors present in culture supernatant (CS) of thymic stromal cells (TSC) on the differentiation and locomotor activity of chicken thymocytes. The locomotor activity of thymocytes was assessed by cell polarization assay. When thymocytes were incubated in the presence of TSC-CS, the proportion of polarized cells increased. This indicates that thymocytes acquired a potent locomotor activity. A high proportion of peanut agglutinin-positive (PNA + ) thymocytes, as well as CD4(-)CD8(-) and CD4(+)CD8(+) thymocytes showed polarization in TSC-CS. Bone marrow cells exhibited higher level of polarizing activity compared to CD4(+)CD8(-) and CD4(-)CD8(+) thymocytes and spleen T cells. These results suggest that thymic stromal cells secrete a soluble factor(s) which enhances mobilizing activity of immature T cells. The factor may take part in the intrathymic migration of progenitor T cells into the site of differentiation.

Evolution of the thymus size in response to physiological and random events throughout life

During embryogenesis and in the early stages of life, the thymus is a crucial organ for the generation of the T cell repertoire. T cells are generated from hematopoietic stem cells already differentiated to precursor T cells in the bone marrow. These cells enter the thymus guided by chemotactic factors secreted by this organ. The complex maturation process takes place that ensures self-tolerance and homeostasis. Thymocytes that show autoreactivity do not leave the thymus, but rather die by apoptosis. The final percentage of mature T cells that survive to migrate from the thymus to the periphery is very low: at most 5%, under optimal conditions. The highest migration occurs in childhood and adulthood, at least in mice and humans; however, it declines throughout life and is minimal in the elderly. Under normal circumstances, the thymus commences involution soon after birth, and this involution correlates with the capacity to export mature T cells to the periphery. Hormones, cytokines, and neurotransmitters all play a role in this age-associated process, but the reasons for and mechanisms of this involution remain unknown. Apart from physiological conditions that change throughout life and govern age-related thymus evolution, random states and events provoked by intrinsic or extrinsic factors can induce either thymus involution, as in reversible transient thymic hypoplasias, or thymic hyperplasias. The age-associated involution, unlike transient involutions, follows a regular pattern for all individuals, though there are clear differences between the sexes. Nevertheless, even the age-associated involution seems to be reversible, raising the possibility of therapeutic strategies aimed at enhancing thymus function in the elderly.

Nutrition disorders and immunologic parameters: study of the thymus in growing rats

OBJECTIVES

We studied the effect of a low-quality dietary protein on cellular proliferation and maturation in the thymus of growing rats over time.

METHODS

After weaning Wistar rats were fed a diet containing 6.5 g/100 g of corn flour for 6, 10, 18, and 45 d (M groups). For comparison, other rats were fed a diet containing 6.5 g/100 g of casein (Cas groups), and well-nourished age-matched control rats were fed a commercial laboratory diet (C groups). Food intake, body weight, thymus weight, total number of thymocytes, and the percentages of CD43(+) and Thy1(+) thymocyte phenotypic antigen determinants were measured.

RESULTS

M versus Cas and C groups showed significant differences (P < 0.01) in body and thymus weights after 6 d of feeding, and the total number of thymocytes and the percentages of CD43(+) and Thy1(+) were significantly lower after 10 d of feeding. The results indicated that consuming a cereal diet for short or long periods causes thymus atrophy in growing rats, with significant reductions in the total number of T-cells concomitant with increases in the number of immature thymocytes.

CONCLUSIONS

The data showed that, in addition to low-protein concentration, low-quality dietary protein is a limiting factor in certain steps of cellular intrathymic pathways, probably related to the requirement of specific amino acids for optimal immune response.

Analysis of early reconstitution events in the SCID mouse thymus following rat bone marrow cell transplantation

In this work, we provide comprehensive evidence that sublethally irradiated Thy-1.2 SCID mice can be used as a model system for thymus homing and reconstitution after intravenous transfer of rat bone marrow cells. Full short-term SCID mouse thymus reconstitutions were obtained using a plastic nonadherent low-density rat bone marrow cell subset. Cell counts and flow cytometric analysis showed that at 3 weeks post-transfer the SCID mouse thymus contained up to 41 x 10(6) Thy-1.1high rat lymphoid cells comprising the expected percentages and distribution of CD2+, CD5+, CD3+, alpha beta TCR+ and CD4+ CD8+ cells. As seen on cryostat sections, bone marrow-derived MHC class II+ accessory cells had already developed by 2 weeks post-transfer, preceding the thymocyte expansion apparent at 3 weeks. Thus, analysis of the early events of SCID thymus reconstitution by rat bone marrow cells shows that they closely resemble those described in congenic animals and points out the temporally distinct development of dendritic cells and thymocytes. The SCID mouse-rat chimera model system represents a new in vivo tool for manipulating rat T-cell differentiation from bone marrow-resident precursor cells and in addition supports our previous xenogeneic reconstitution studies performed in organ culture.

Enrichment and characterization of thymus-repopulating cells in stroma-dependent cultures of rat bone marrow

The bone marrow precursor cells seeding the thymus have been difficult to investigate using fresh bone marrow and in vivo thymus reconstitution assays. We have therefore designed a short-term bone marrow culture system allowing the study of thymus-repopulating cells in the marrow microenvironment. Low-density rat bone marrow cells were grown on pre-established mouse bone marrow stromal cell layers. Cocultured cells were maintained either under steroid-free conditions (Whitlock/Witte-type culture) or in the presence of 10(−7) M hydrocortisone (Dexter-type culture). After 3 days in vitro, the unanchored cell fractions were tested for their ability to colonize and repopulate fetal mouse thymic lobes in vitro. Both fresh low-density cells and Whitlock/Witte-type cultures, but not Dexter-type cultures, gave rise intrathymically to significant numbers of rat donor-type Thy-1.1high CD2+ CD5low CD43+ cells accounting for 50% to 90% of the organ-cultured cells at day 14. Repopulation of fetal mouse thymic lobes by rat Thy-1.1high cells could be used as a readout assay for initiation of thymopoiesis from bone marrow precursor cells, since 90% of the cells were CD3-/low and TCR alpha beta-/low and 15% of the cells co-expressed CD4 and CD8. Dose-response analysis showed that thymus repopulating cells were at least maintained, if not amplified during the 3-day culture period, leading to at least a 10-fold enrichment as compared to unfractionated bone marrow. Unlike fresh low-density cells before culture, short-term Whitlock/Witte-type cultures were depleted in myeloid-restricted precursor cells. In culture, the thymus-repopulating activity was predominantly associated with a 10% lymphoid cell subset which did not express the B-lineage-associated antigens revealed by HIS24 (the rat B220 equivalent) and HIS50 mAbs. We propose that unanchored thymus-repopulating cells enriched in Whitlock/Witte-type cultures may represent lymphoid-restricted, T-cell precursors of the bone marrow capable of emigrating and colonizing the thymus.

EA-1, a novel adhesion molecule involved in the homing of progenitor T lymphocytes to the thymus

The mouse progenitor T lymphocyte (pro-T) cell line FTF1 binds in vitro to thymus blood vessels, the thymic capsule, and liver from newborn mice. A mAb, EA-1, raised against an embryonic mouse endothelial cell line, blocked adhesion. The antibody also interfered with pro-T cell adhesion to a thymus-derived mouse endothelial cell line; it had no effect on the adhesion of mature T lymphocytes and myeloid cells. The antigen recognized by EA-1 is located on the vascular endothelium of various mouse tissues and absent on pro-T cells. EA-1 antibody precipitates molecules with apparent molecular weights of 110,000, 140,000, 160,000, and 200,000. Immunoclearing and binding-inhibition studies with antibodies against known adhesion molecules suggest that the EA-1 antigen is a novel adhesion molecule involved in colonization of the embryonic thymus by T cell progenitors.

T and B cell collaboration: induction of motility in small, resting B cells by interleukin 4

In this report we investigate if IL 4 can work as a chemoattractant factor by inducing locomotion in B cells. We found that murine recombinant IL 4 (rIL 4) induced motile morphology and migration through polycarbonate micropore filters of murine, splenic B cells at an optimal concentration of 3 ng/ml. Kinetic studies revealed optimal migration at 8-16 h, although a significant response could be detected already after 1 h. Flow cytometric studies confirmed that the migrated cells were indeed B cells. We also compared the activity of small, dense B cells and large, low-density B cells, based on Percoll gradient separation. We found no difference in IL 4-induced motility among the two groups. Furthermore, we looked at B cells activated in vitro by preculture in lipopolysaccharide (LPS) or IL 4. Our data indicate that both LPS and IL 4 can increase the general capacity for motility in B cells after preculture for 24 h. T and B cell collaboration requires close cell-cell contacts in order for T cell help to be administered to the B cell. One way of enhancing such cell contacts could be through directional cell migration induced by helper factors (chemotaxis). We suggest that IL 4 can play a role as a chemoattractant factor that enhances cell contacts between T helper cells and B cells.

Two gut intraepithelial CD8+ lymphocyte populations with different T cell receptors: a role for the gut epithelium in T cell differentiation

Mouse gut intraepithelial lymphocytes (IEL) consist mainly (90%) of two populations of CD8+ T cells. One bears heterodimeric alpha/beta CD8 chains (Lyt-2+, Lyt-3+), a T cell receptor (TCR) made of alpha/beta chains, and is Thy-1+; it represents the progeny of T blasts elicited in Peyer's patches by antigenic stimulation. The other bears homodimeric alpha/alpha CD8+ chains, contains no beta chain mRNA, and is mostly Thy-1- and TCR-gamma/delta + or -alpha/beta +; it is thymo-independent and does not require antigenic stimulation, as shown by its presence: (a) in nude and scid mice; (b) in irradiated and thymectomized mice repopulated by T-depleted bone marrow cells bearing an identifiable marker; (c) in thymectomized mice treated by injections of monoclonal anti-CD8 antibody, which lead to total depletion of peripheral CD8+ T lymphocytes; and (d) in germ-free mice and in suckling mice. In young nude mice, alpha/alpha CD8 chains, CD3-TCR complexes, and TCR mRNAs (first gamma/delta) are found on IEL, while they are not detectable on or in peripheral or circulating lymphocytes or bone marrow cells. IEL, in contrast to mature T cells, contain mRNA for the RAG protein, which is required for the rearrangement of TCR and Ig genes. We propose that the gut epithelium (an endoderm derivative, as the thymic epithelium) has an inductive property, attracting progenitors of bone marrow origin, and triggering their TCR rearrangement and alpha/alpha CD8 chains expression, thus giving rise to a T cell population that appears to belong to the same lineage as gamma/delta thymocytes and to recognize an antigenic repertoire different from that of alpha/beta CD8+ IEL.

Towards an integrated view of thymopoiesis

One prediction from the complex series of steps in intrathymic T-cell differentiation is that to regulate it the stroma controlling the process must be equally complex: the attraction of precursors, commitment to the T-cell lineage, induction of T-cell receptor (TCR) gene rearrangement, accessory molecule expression, repertoire expansion, major histocompatibility complex (MHC) molecule-based selection (positive and negative), acquisition of functional maturity and migratory capacity must all be controlled. In this review, Richard Boyd and Patrice Hugo combine knowledge of T-cell differentiation with thymic stromal cell heterogeneity to offer an integrated view of thymopoiesis within the thymic microenvironment.

Rat bone marrow cells undergo thymopoiesis in mouse fetal thymic organ culture

We have developed an in vitro differentiation assay allowing the study of thymopoiesis from rat bone marrow cells. In this assay, Wistar rat bone marrow cells repopulated fetal Swiss mouse thymic lobes depleted in endogeneous lymphoid cells by deoxyguanosine treatment. Due to the xenogeneic situation, repopulating rat cells from any hemopoietic lineage could be easily recognized by anti-rat monoclonal antibodies such as anti-Thy-1.1 that did not react with Swiss mouse thymocytes. After 15 days in vitro, 80% of the developing rat cells were Thy-1.1+ lymphoid cells and about 70% of the Thy-1.1+ cells expressed CD5, CD2 and leukosialin. The percentages of cells expressing pre-B cell, B cell and myeloid determinants were less than 20%. The developing thymocytes comprised CD4-CD8- T cell receptor (TcR) alpha/beta-, CD4-CD8+TcR alpha/beta low and CD4+CD8+TcR alpha/beta low cells, indicating that the early stages of rat thymopoiesis occurred within mouse thymic lobes. Limiting dilution assays showed that 50% of positive assays were obtained with 3000 nucleated bone marrow cells, which is in good agreement with recent estimates derived from in vivo reconstitution after intrathymical transfer. Moreover the limiting dilution assays proved to be sensitive enough to evidence a tenfold enrichment of pre-T cell activity in the low-density fraction of rat bone marrow. This xenogeneic system might greatly facilitate studies on prethymic and intrathymic stages of rat T cell development and permit new in vitro approaches of the colonizing bone marrow T cell precursor properties.

Subsets of thymopoietic rat thymocytes defined by expression of the CD2 antigen and the MRC OX-22 determinant of the leukocyte-common antigen CD45

The MRC OX-22 monoclonal antibody recognizes a restricted determinant of the rat leukocyte-common antigen (L-CA, CD45), which is expressed on most peripheral T cells and all B cells. In contrast only 2%-3% of thymocytes are OX-22+ and these are now shown to be mostly of the immature CD4-CD8- (double-negative, DN), phenotype with very few of the mature phenotype cells being OX-22+. Analysis of immunoperoxidase sections suggests that the DN OX-22+ cells are located in the cortex. Among the DN cells about 60% are OX-22+ and a similar percentage are positive for CD2 antigen. Double staining showed that OX-22+CD2-, OX-22+CD2+, and OX-22-CD2+ populations can be defined and that these three sets account for approximately 95% of the DN cells. Measurement of the thymopoietic activity of DN subsets showed that OX-22+CD2- and OX-22+CD2+ cells have regenerative capacity whilst OX-22-CD2+ cells do not.

Thymotaxin, a chemotactic protein, is identical to beta 2-microglobulin

Thymotaxin, an 11-kilodalton protein chemotactic for rat bone marrow hematopoietic precursors, was purified from media conditioned by a rat thymic epithelial cell line. The NH2-terminal sequence of thymotaxin was identical to that of rat beta 2-microglobulin (beta 2m). Antibodies to beta 2m removed thymotaxin activity from the fraction containing the 11-kilodalton protein. Chemotactic activity was observed with rat plasma beta 2m, human beta 2m, and mouse recombinant beta 2m, further supporting the identity of thymotaxin with beta 2m. The directional migration, as opposed to random movement, of the cells was also confirmed. The only rat bone marrow cells that migrated toward beta 2m were Thy1+ immature lymphoid cells devoid of T cell, B cell, and myeloid cell differentiation markers.