Trypanosoma equiperdum: Movement from the dermis

Twelve dogs were injected intradermally with 352,770 to 14,391,660 Trypanosoma equiperdum and afferent and efferent lymph, lymph nodes, and blood examined by mouse inoculation at minute, hourly, and daily intervals following inoculation. The log dosage of trypanosomes given each dog was closely related to their body weight (P < 0.01). Afferent lymph contained trypanosomes as soon as 5 and 27 min after inoculation. Lymph nodes on the side of injection became positive within 5 min of injection, while those on the contralateral side remained negative for at least 120 min after injection. Blood contained trypanosomes as soon as 5 min after injection, although the average time for all dogs, before trypanosomes were demonstrated in the blood, was 40 min postinjection. Efferent lymph did not contain organisms until 25–76 hr after inoculation. We consider this sequence to indicate that T. equiperdum can leave the dermis in afferent lymphatics, reach the local lymph node, invade the blood stream from this site, and only after a day or longer do they leave the node via the efferent lymphatics.     

Regeneration of autotransplanted lymph node fragments

Summary In normal young minipigs thin slices of autologous mesenteric or superficial inguinal lymph nodes were implanted either in the greater omentum or subcutaneously in the groin region. The regeneration was studied histologically and connections between the afferent lymphatics and the regenerated tissue were checked. In the greater omentum, no regenerated lymph node tissue was found. In the inguinal region, lymphoid tissue with all the typical lymph node compartments was identified following antigenic stimulation in the draining area. Sinuses, germinal centres with a lymphatic corona, and a paracortex with typical high endothelial venules were seen. There was evidence of afferent lymphatics, e.g., macroscopically visible lymphatics, the occurrence of a subcutaneously injected dye, the effect of antigenic stimulation and a normal lymph node structure. Avascular transplants of autologous lymph node fragments regenerate subcutaneously, possibly providing a future technique for treating lymphoedema after radical excision or irradiation of lymph nodes.     

The influence of afferent lymphatic vessel interruption on vascular addressin expression

Tissue-selective lymphocyte homing is directed in part by specialized vessels that define sites of lymphocyte exit from the blood. These vessels, the post capillary high endothelial venules (HEV), are found in organized lymphoid tissues, and at sites of chronic inflammation. Lymphocytes bearing specific receptors, called homing receptors, recognize and adhere to their putative ligands on high endothelial cells, the vascular addressins. After adhesion, lymphocytes enter organized lymphoid tissues by migrating through the endothelial cell wall. Cells and/or soluble factors arriving in lymph nodes by way of the afferent lymph supply have been implicated in the maintenance of HEV morphology and efficient lymphocyte homing. In the study reported here, we assessed the influence of afferent lymphatic vessel interruption on lymph node composition, organization of cellular elements; and on expression of vascular addressins. At 1 wk after occlusion of afferent lymphatic vessels, HEV became flat walled and expression of the peripheral lymph node addressin disappeared from the luminal aspect of most vessels, while being retained on the abluminal side. In addition, an HEV-specific differentiation marker, defined by mAb MECA-325, was undetectable at 7-d postocclusion. In vivo homing studies revealed that these modified vessels support minimal lymphocyte traffic from the blood. After occlusion, we observed dramatic changes in lymphocyte populations and at 7-d postsurgery, lymph nodes were populated predominantly by cells lacking the peripheral lymph node homing receptor LECAM-1. In addition, effects on nonlymphoid cells were observed: subcapsular sinus macrophages, defined by mAb MOMA-1, disappeared; and interdigitating dendritic cells, defined by mAb NLDC-145, were dramatically reduced. These data reveal that functioning afferent lymphatics are centrally involved in maintaining normal lymph node homeostasis.     

γδ T cell homing to skin and migration to skin-draining lymph nodes is CCR7 independent

In most species, γδ T cells preferentially reside in epithelial tissues like the skin. Lymph duct cannulation experiments in cattle revealed that bovine dermal γδ T cells are able to migrate from the skin to the draining lymph nodes via the afferent lymph. For αβ T cells, it is generally accepted that epithelial and mucosal tissue egress is regulated by expression of the CCR7 chemokine receptor. In this study, we tracked the migratory route of bovine lymph-derived γδ T cells and examined their CCR7 cell surface expression in several compartments along this route. Total lymph cells from afferent and efferent origin were labeled with PKH fluorescent dyes and injected into the bloodstream. PKH(+) cells already reappeared in the afferent lymph after 4 h. The vast majority of the PKH(+) cells retrieved from the afferent lymph were of the WC1(+) γδ T cell phenotype, proving that this PKH(+) γδ T cell subset is able to home to and subsequently exit the skin. PKH(+) γδ T cells from afferent and efferent lymph lack CCR7 surface expression and display high levels of CD62L compared with CD4 T cells, which do express CCR7. Skin homing receptors CCR4 and CCR10 in contrast were transcribed by both CD4 and γδ T cells. Our findings suggest that γδ T cell skin egress and migration into the peripheral lymphatics is CCR7-independent and possibly mediated by CD62L expression.     

Biosynthesis of glycosaminoglycans and proteoglycans by the lymph node

Previous studies of hyaluronan uptake and catabolism by lymph nodes indicated that the nodes might also add some HA of low molecular weight to the unabsorbed fraction that passes through from afferent to efferent lymph vessels.The ability of lymph nodes to synthesise HA and proteoglycans was therefore examined (i) by perfusion of [³H] acetate through an afferent lymph vessel in vivo, and recovery of labeled products from the efferent lymph vessel and from the node after perfusion; and (ii) by tissue culture of lymph nodes with [³H] acetate.Perfusion of lymph nodes with [³H] acetate in situ yielded: (a), in outflowing lymph, small amounts of chondroitin/dermatan sulfate within the first hour which continued to be produced for up to 24[emsp4 ]h; heparin in the second hour and HA in the third. In the nodes removed 17 to 19[emsp4 ]h later, equal amounts of hyaluronan and chondroitin/dermatan sulfate and heparan sulfate proteoglycans were detected. In the tissue culture of lymph nodes: (1) HA, heparin and proteoglycans of heparan sulfate and chondroitin/dermatan sulfate were released into the medium but in the cell extract only heparan sulfate proteoglycan was detected; and (ii) molecular weight of the released hyaluronan ranged widely but was mostly less than 4–5×10⁵[emsp4 ]D; heparan sulfate proteoglycan was 2.8×10⁴ to 9.4×10⁵[emsp4 ]D; heparin 7.9×10⁴[emsp4 ]D and chondroitin sulfate 1.3×10⁴[emsp4 ]D, suggesting that the chondrotin sulfate were released from their proteoglycans core by enzymic degradation.It is concluded that lymph nodes can release HA, heparin, heparan sulfate and chondroitin/dermatan sulfate proteoglycans into efferent lymph but the amount of hyaluronan is likely to be small without immune or other stimulation and its molecular weight is lower than in other tissues.     

Stochastic regulation of cell migration from the efferent lymph to oxazolone-stimulated skin

The systemic immune response is a dynamic process involving the trafficking of lymphocytes from the Ag-stimulated lymph node to the peripheral tissue. Studies in sheep have demonstrated several phases of cell output in the efferent lymph after Ag stimulation. When skin contact sensitizers are used as Ag, the efferent lymph cell output peaks approximately 96 h after Ag stimulation and is temporally associated with the recruitment of cells into the skin. To investigate the relative contribution of this high-output phase of efferent lymphocytes to lymphocytic inflammation in the skin, we used a common contact sensitizer 2-phenyl-4-ethoxymethylene-5-oxazolone (oxazolone) to stimulate the skin and draining prescapular lymph node of adult sheep. The efferent lymph ducts draining the Ag-stimulated and contralateral control lymph nodes were cannulated throughout the experimental period. The lymphocytes leaving the lymph nodes during the 72-h period before maximum infiltration were differentially labeled with fluorescent tracers, reinjected into the arterial circulation, and tracked to the site of Ag stimulation. Quantitative tissue cytometry of the skin at the conclusion of the injection period (96 h after Ag stimulation) demonstrated more migratory cells derived from the Ag-stimulated lymph node than the contralateral control (median 18.5 vs 15.5 per field; p < 0.05). However, when corrected for total cell output of the lymph node, the Ag-stimulated migratory cells were 3.8-fold more prevalent in the skin than the contralateral control cells. These results suggest that the in situ immune response generally mirrors the frequency of recruitable lymphocytes in the peripheral blood.     

Homing of germinal-center cells into germinal centers of lymph node via afferent lymphatics

Summary Affinity of lymphoid cells for the microenvironment of germinal centers (GC), as detectable in transfer experiments by rapid homing in spleen GC from the blood, is a capacity expressed by only a subset of lymphoid cells, in particular by those constituting a GC. However, when introduced into the blood stream, these cells do not home into GC of lymph nodes and gut-associated lymphoid tissues. To investigate further this homing inability for high endothelial venule (HEV)-containing lymphoid tissues, GC cells isolated from donor rabbit appendix were labeled in vitro with ³H-leucine and injected into an afferent lymph vessel of recipient popliteal lymph nodes. Draining lymph nodes were removed 15 min to 24 h after cell administration and prepared for radioautography. For reference, the migration of cells isolated from Peyer's patches and thoracic duct lymph was also studied. By use of appendix GC cells, large numbers of labeled cells were found to migrate into GCs of the outer cortex centripetally, i.e., from the subcapsular sinus through the lymphocyte corona into the GC proper. The same was observed for cells from Peyer's patches, although in smaller numbers. Thoracic duct lymphocytes were only localized in the lymphocyte corona and the deep cortex. Thus, appendix GC cells and a subpopulation of cells from Peyer's patches can reach lymph node GC, but only when administered intralymphatically. We conclude that cells expressing affinity for the GC microenvironment do so for both spleen and lymph node GC, but do not have the capacity to interact with the wall of HEV; its implication for the understanding of the dynamics of a GC reaction is discussed.Abbreviations GC germinal center - GCC germinal-center cells - AGCC appendix germinal-center cells - GCPC germinal-center precursor cells - GCSC germinal-center seeking cells - HEV high endothelial venules - SRBC sheep red blood cells - PP Peyer's patch - TDL thoracic duct lymphocytes - NCS newborn calf serum - PBS phosphate-buffered saline - PNA peanut agglutinin - LN lymph node - LC lymphocyte corona - DC deep cortex unit     

Properties of reticulum cell sarcomas in SJL/J mice: II. Fate of labeled tumor cells in normal and irradiated syngeneic mice

Transplantable reticulum cell sarcoma (RCS) cells were labeled with ³H-uridine or ³H-thymidine in vitro and injected intravenously into normal and irradiated syngeneic SJL/J mice. RCS cells exhibited typical B cell migration characteristics in peripheral lymphoid organs in both normal and irradiated recipients, localizing in follicles in a pattern resembling that of labeled normal bone marrow cells. However, over the first 72 hr after transfer, RCS cells diluted their label much less in irradiated than in normal recipients, reflecting their inability to proliferate in the irradiated hosts. The presence of unlabeled tumor cells did not significantly affect the distribution of labeled normal bone marrow or lymph node cells in the recipients. Thus, RCS fails to grow in irradiated recipients in spite of undisturbed homing characteristics and in the absence of any evidence of cytotoxic influences from the host.     

Directional Migration of Recirculating Lymphocytes through Lymph Nodes via Random Walks

Naive T lymphocytes exhibit extensive antigen-independent recirculation between blood and lymph nodes, where they may encounter dendritic cells carrying cognate antigen. We examine how long different T cells may spend in an individual lymph node by examining data from long term cannulation of blood and efferent lymphatics of a single lymph node in the sheep. We determine empirically the distribution of transit times of migrating T cells by applying the Least Absolute Shrinkage & Selection Operator () or regularised to fit experimental data describing the proportion of labelled infused cells in blood and efferent lymphatics over time. The optimal inferred solution reveals a distribution with high variance and strong skew. The mode transit time is typically between 10 and 20 hours, but a significant number of cells spend more than 70 hours before exiting. We complement the empirical machine learning based approach by modelling lymphocyte passage through the lymph node . On the basis of previous two photon analysis of lymphocyte movement, we optimised distributions which describe the transit times (first passage times) of discrete one dimensional and continuous (Brownian) three dimensional random walks with drift. The optimal fit is obtained when drift is small, i.e. the ratio of probabilities of migrating forward and backward within the node is close to one. These distributions are qualitatively similar to the inferred empirical distribution, with high variance and strong skew. In contrast, an optimised normal distribution of transit times (symmetrical around mean) fitted the data poorly. The results demonstrate that the rapid recirculation of lymphocytes observed at a macro level is compatible with predominantly randomised movement within lymph nodes, and significant probabilities of long transit times. We discuss how this pattern of migration may contribute to facilitating interactions between low frequency T cells and antigen presenting cells carrying cognate antigen.     

The lymphatic system in body homeostasis: physiological conditions

The lymphatic system is an organized network composed of functionally interrelated lymphoid tissue, and transportation pathways of tissue fluid/lymph and lymphoid cells. Its main components are 1. migrating dendritic cells, macrophages and lymphocytes, organized lymphoid tissue such as lymph nodes, thymus, spleen, bone marrow, and lymphoid tissue in gut and lungs, liver lymphoid cells, and the dendritic cell network of nonlymphoid organs; 2. vessels (intercellular space, lymphatics, and perivascular spaces); 3. fluids (tissue fluid and lymph). The lymphatic system can be divided into the following compartments: peripheral (from the interstitial space to and within the nearest lymph node), and central (efferent lymphatics, cysterna chyli, and thoracic duct, all lymphoid organs). Organs and tissues with the most active afferent arm of the lymphatic system are skin, gut, and lungs. These are the body structures exposed to the external environment. All other nonlymphoid bodily tissues are also percolated by tissue fluid/lymph, and contain a network of dendritic cells and macrophages. Data obtained from normal human subjects on lymph composition and flow are presented. Future trends in lymphatic research are outlined.     

Reutilization by maternal and embryonal cells of nuclear materials from H3-thymidine labeled lymphocytes introduced into the lumen of intestine of rats

Summary H³-thymidine labeled lymphocytes from thymus and lymph nodes of donor rats were washed and injected in to the intestine of recipient rats on the 11th and 19th day of gestation; subsequent labeling of maternal and embryonal cells was studied autoradiographically 24 hours after injection. In 12-day embryos, numerous stem cells or hemocytoblasts were labeled frequently intensely. In 20-day embryos, stem cells or hemocytoblasts scattered throughout the liver were often labeled. In other fetal tissues at this stage, cells in thymus, spleen, mesenteric lymph node and intestine were labeled but scarcely and weakly. In mothers, labeling in lymphoid tissues was scarce but definite, in thymus, mesenteric lymph node and spleen. These results suggest that nuclear materials from lymphocytes emigrated into the intestinal canal of the mother could be reutilized by maternal and embryonal cells.     

Altered lymphatics in an ovine model of congenital heart disease with increased pulmonary blood flow

Abnormalities of the lymphatic circulation are well recognized in patients with congenital heart defects. However, it is not known how the associated abnormal blood flow patterns, such as increased pulmonary blood flow (PBF), might affect pulmonary lymphatic function and structure. Using well-established ovine models of acute and chronic increases in PBF, we cannulated the efferent lymphatic duct of the caudal mediastinal node and collected and analyzed lymph effluent from the lungs of lambs with acutely increased PBF (n = 6), chronically increased PBF (n = 6), and age-matched normal lambs (n = 8). When normalized to PBF, we found that lymph flow was unchanged following acute increases in PBF but decreased following chronic increases in PBF. The lymph:plasma protein ratio decreased with both acute and chronic increases in PBF. Lymph bioavailable nitric oxide increased following acute increases in PBF but decreased following chronic increases in PBF. In addition, we found perturbations in the transit kinetics of contrast material through the pleural lymphatics of lambs with chronic increases in PBF. Finally, there were structural changes in the pulmonary lymphatic system in lambs with chronic increases in PBF: lymphatics from these lambs were larger and more dilated, and there were alterations in the expression of vascular endothelial growth factor-C, lymphatic vessel endothelial hyaluronan receptor-1, and Angiopoietin-2, proteins known to be important for lymphatic growth, development, and remodeling. Taken together these data suggest that chronic increases in PBF lead to both functional and structural aberrations of lung lymphatics. These findings have important therapeutic implications that warrant further study.     

Peritoneal macrophages introduced into mouse foot pads enter the germinal center of regional lymph nodes nonspecifically.

Male mice were injected into their foot pads with sheep erythrocytes (SRBC) to form lymph follicles in the germinal centers in the popliteal lymph nodes. 4 weeks later, peritoneal macrophages labeled with carbon from syngeneic donors sensitized with SRBC or typhoid-paratyphoid bacilli (TAB) were separately injected into the foot pads as well. The popliteal lymph nodes were histologically examined at 6 h to 5 days after injection. Labeled macrophages appeared in the marginal sinus, migrated straight across the cortex from the marginal sinus to the lymph follicles and then entered the germinal centers. There was no difference in the mode of appearance, migration and localization of labeled macrophages in the regional lymph nodes between the mice given labeled macrophages from SRBC-sensitized donors and those given macrophages from TAB-sensitized donors. The entrance of lymph macrophages into the germinal centers of the regional lymph nodes would be immunologically nonspecific. After the injection of Pelikan ink into the foot pads, the macrophages which have taken up carbon in the peripheral tissue reached the regional lymph nodes via the afferent lymphatics and then entered the germinal centers, mainly through the medullary pole of the lymph follicles, after migrating along their immediate exterior from their marginal sinus to their medullary pole.     

Mechanisms of suppressed cell-mediated immunity and impaired antigen-induced interleukin 2 production in granuloma-bearing mice

Pulmonary granulomas were induced in BALB/c mice immunized with methylated bovine serum albumin in complete Freund's adjuvant by the intratracheal injection of plain agarose beads or beads conjugated to specific antigen. Large hypersensitivity granulomas developed around antigen-coupled beads in immunized animals. Smaller but still prominent granulomatous reactions developed around plain beads in immunized mice. In nonimmunized animals, both plain and antigen conjugated beads produced very small granulomas. Granuloma formation in sensitized animals was associated with suppressed delayed-type hypersensitivity reactions induced by the footpad injection of specific and nonspecific antigens. Lymph node cells from sensitized granuloma-bearing mice with cutaneous anergy showed suppressed specific and nonspecific antigen-induced proliferative responses in vitro. These cells also showed suppressed interleukin 2 production in response to specific antigen. Although no soluble suppressive factor was detected in granuloma extracts, suppressor cells were found in lymph nodes of granuloma-bearing mice, which could inhibit antigen-induced production of interleukin 2 by lymph node cells from immunized mice. Antigen-specific immunoglobulin G antibody production was not suppressed in immunized granuloma-bearing mice. Previous studies from our laboratory have demonstrated migration inhibition factor and interleukin 1 activities in aqueous extracts prepared from granuloma-bearing lungs of immunized mice. These results and the findings reported here indicate that granuloma formation and the associated anergy observed in this system are primarily expressions of cell-mediated immunity; selective suppression of in vivo and in vitro expressions of cell-mediated immunity in granuloma-bearing mice may be due to impaired antigen-induced interleukin 2 production; and such impairment is caused by suppressor cells.     

'Morphology of immune lymphocytes in homograft lymph'

Uropod-bearing lymphocytes (UBLs) resembling cytotoxic cells found in vitro were identified in lymph collected from rabbit hind-limbs bearing homografts. UBLs were found in lymph leaving the regional lymph node (efferent), both before and after rejection, but not in that draining the homograft (afferent) even though they were present in the graft tissue itself. UBLs may represent the sub-class of immune lymphocytes which induce necrosis of the grafted cells. Mitotic lymphocytes and cells resembling lymphocytes transformed by phytohaemagglutinin were also found in efferent homograft lymph.     

Three-dimensional organization of lymphatics and its relationship to blood vessels in rat small intestine

Summary The lymphatic organization and its relationship to the vascular system in the rat small intestine was studied by scanning electron microscopy of corrosion casts and freeze-fractured tissues, and by light microscopy of injected preparations. The villus possessed 3–10 or more central lacteals depending upon the villous width. The lacteals in each villus possessed interconnections between adjacent ones and were surrounded externally by the villous capillary network. At the villous base, the lacteals fused and formed a wide sinus, from which 2 or 3 lymphatics descended and led into the submucosal ones. In the muscularis externa there was a coarse lymphatic network which, together with the submucosal one, drained into collecting lymphatics continuous with the mesenteric ones. The central lacteals and the sinus were lined with thin endothelial cells with cytoplasmic leaves interdigitating with those of adjacent ones. There were tissue channels in the villous interstitial space, which opened through the gaps between the lymphatic endothelial cells into the central lacteals.The voluminous lacteals in the villi suggest their great potential for lymph formation. The existence of collecting lymphatics with valves in the muscularis externa suggests that contraction of the layer is involved in transporting lymph towards the efferent lymphatics.     

Further evidence for the existence of B-lymphocyte subpopulations.

We have studied the homing properties of B lymphocytes by using ⁵¹Cr-labeled lymphoid cells obtained from athymic, nu/nu mice, and animals made T-lymphocyte deficient by thymectomy and lethal irradiation followed by reconstitution with syngeneic bone marrow. Comparison was made to the patterns of distribution observed when cell preparations containing normal numbers of T and B lymphocytes were migrated. A small but significant percentage of labeled lymphocytes from lymph nodes, spleen, Peyer's Patches, and bone marrow of T-cell-deficient animals was shown to be lymph node seeking. Secondary transfers of lymph node cells from primary recipients caused enrichment of this lymph node-seeking population. Treatment of T-lymphocyte-deficient lymphoid cell preparations with neuraminidase reduced the percentages of cells homing to the lymph nodes. The data showed that B lymphocytes exhibit unique homing properties when injected into normal recipients. In addition, direct comparison of the homing patterns of B lymphocytes prepared from spleen and lymph nodes of athymic mice revealed differences suggesting that these lymphoid organs contained unique mixtures of at least two different kinds of B cell. The evidence supports the notion that the B-lymphocyte populations contain at least two subpopulations, one of which possesses the ability to home to lymph nodes.     

Dissemination of bovine leukemia virus-infected cells from a newly infected sheep lymph node

To investigate the early establishment of bovine leukemia virus (BLV) infection, we injected BLV-infected or mock-infected allogeneic cells into the shoulder of sheep in which an efferent lymphatic duct of the draining prescapular lymph node had been cannulated. Rare mononuclear cells acting as centers of BLV infection in culture were present within 4 to 6 days in efferent lymph and within 6 to 10 days in blood. Soon after BLV injection, immunoglobulin M+ (IgM+) and CD8+ cells increased in efferent lymph and oscillated reciprocally in frequency. CD8+ blasts increased on days 4 to 6, when infectious centers increased 100-fold in lymph. On days 6 and 7, both lymph and blood were enriched with CD8+ cells that were labeled late on day 5 with an intravenous pulse of 5-bromo-2'-deoxyuridine (BrdU). Lymph, but not blood, was enriched with BrdU+ B cells on day 7. Capsid-specific antibodies became detectable in efferent lymph on days 6 to 8 and surface glycoprotein-specific antibodies on day 9, preceding their detection in serum by 9 to 14 days. Systemic dissemination of BLV-infected cells was thus accompanied by an increase in proliferating CD8+ cells and the onset of BLV-specific antibodies in lymph. Infectious centers reached maximum frequencies of 0.2% in lymph by days 11 to 13, and then their frequencies increased by 5- to 40-fold in blood cells, suggesting that many infected blood cells do not recirculate back into lymph. Beginning on days 10 to 13, a subpopulation of B cells having high levels of surface IgM increased sharply in peripheral blood. Such cells were not present in lymph. After a day 16 pulse of BrdU, recently proliferated cells that stained intensely for surface IgM appeared in blood within 15 h. Predominantly B lymphocytes contained the viral capsid protein when lymph and blood cells were cultured briefly to allow BLV expression. However, both early in lymph and later in blood, BrdU+ B cells greatly exceeded productively infected cells, indicating that new BLV infections stimulate proliferation of two different populations of B cells.     

CXCR4 Is Dispensable for T Cell Egress from Chronically Inflamed Skin via the Afferent Lymph

T cell recirculation through extralymphoid tissues is essential to immune surveillance, host defense and inflammation. In this process, T cells enter the tissue from the blood and subsequently leave via the afferent lymph. In the absence of inflammation, T cells require CCR7 expression to egress from the skin or lung, which is consistent with the constitutive expression of the CCR7 ligand CCL21 on lymphatic endothelium. However, during chronic inflammation alternative chemoattractants come into play, allowing Ccr7-deficient (Ccr7^−/−) T cells to egress efficiently from affected skin. As T cell egress from inflamed sites is a potential control point of the inflammatory response, we aimed to determine alternative T cell exit receptors using a mouse and a sheep model. We show that CCR7⁺ and CCR7^– T cells exiting from the chronically inflamed skin were highly responsive to the CXCR4 ligand CXCL12, which was induced in the lymphatics in the inflamed site. Based on these findings, we hypothesized that CXCR4 mediates T cell egress from inflamed skin. However, pharmacological inhibition of CXCR4 did not affect the tissue egress of wildtype or Ccr7^−/− CD4 and CD8 T cells after adoptive transfer into chronically inflamed skin. Similarly, adoptively transferred Cxcr4^−/− Ccr7^−/− and Ccr7^−/− T cells egressed from the inflamed skin equally well. Based on these data, we conclude that, while CXCR4 might play an essential role for other cell types that enter the afferent lymphatics, it is dispensable for T cell egress from the chronically inflamed skin.     

The kinetics of antigen-reactive cells during lymphocyte recruitment

Lymphocyte recruitment, the increased traffic of lymphocytes from blood to lymph which occurs within antigenically stimulated lymph nodes, was monitored in the efferent lymph of single lymph nodes in sheep after immunization with allogeneic lymphocytes or purified protein derivative. Specific antigen-reactive cells were assayed by their ability to proliferate in vitro in the presence of the priming antigen. During lymphocyte recruitment such cells were no longer detected in the efferent lymph draining either the immunized node or a nonstimulated node remote from the region of antigen administration. These results probably reflect the selective removal of specific lymphocytes from the recirculating pool. Alternatively, the findings could involve a state of specific unresponsiveness of the cells.