A COMPARTMENTAL ANALYSIS OF CIRCULATORY LYMPHOCYTES IN THE SPLEEN

A tentative model describing the passage of circulatory lymphocytes through the spleen is formulated in accord with known anatomical features. In order to preserve isomorphism between the model and the splenic system, the model is formulated in compartmental form and its design allows alternative routes and modes of lymphocyte transit to be considered. The simultaneous differential equations arising from the model are solved using an analogue computer which also provides the means whereby the performance of the model may be compared with suitable dynamic data drawn from literature. This not only allows the selection of a particular configuration of the model in preference to its alternatives, but also allows the numerical determination of certain unknown parameters. In the case of the rat spleen, best agreement between model and experimental data is obtained when between 10 and 25% of the total lymphocyte flux in the model spleen passes through the marginal zone where the average dwell time of the lymphocytes is about 50 min. The white pulp receives a lymphocyte flux from the marginal zone amounting to about 10% of the total splenic flux and the white pulp lymphocytes are sequestered for a period of 4–6 hr before release to the venous circulation. The red pulp receives 90% of the total splenic flux but the majority of lymphocytes find transit through the red pulp in less than 5 min. The remaining flux of lymphocytes, amounting to 10% of the splenic input, is delayed in transit through the red pulp by 2–3 hr before release to the venous circulation.     

Anatomical pathways from the white to the red pulp in the human spleen

In the human spleen we failed to find marginal zone bridging channels which in rats and mice are said to serve as return routes for lymphocytes from the white into the red pulp. In human spleens, using anticartilaginous antisera which distinctly visualized extracellular structures, in some parts we found the periarterial lymphocyte sheath to be closely attached to the red pulp, so that lymphocytes and other material could pass from the white pulp directly into the red pulp and vice versa. The strips of reticular fibres that seemed to bridge the marginal zone between the follicles and the red pulp proved to be components of reticular structures around the arteries, passing from the periarterial lymphocyte sheath into the follicles or from the follicles through the marginal zone into the red pulp.     

The architecture of the spleen of the yellow-bellied toad, Bombina variegata

The spleen of the yellow-bellied toad, Bombina variegata , consists of distinct white and red pulps. The well-developed white pulp is formed by a large central lymphocytic region around the numerous blood vessels and by its smaller peripheral ramifications, both surrounded by the more or less developed connective tissue boundary layer. Large peripheral sinuses of the white pulp, filled mostly with lymphocytes, are usually present at the inner side of this boundary. At the outer side of the boundary layer, the lymphocytic marginal zone is often observed. This zone merges into the erythrocyte-rich red pulp formed by cellular cords and small venous sinusoids.
The structure of the spleen of Bombina variegata differs considerably from the spleens of other anuran species studied so far. The highly developed white pulp and its distinct separation from the red pulp may be connected with the important role of the spleen as the main secondary lymphoid organ of B. variegata. The splenic compartmentalization makes the yellow-bellied toads a useful model for experimental immunobiological studies.     

Deep splenic lymphatic vessels in the mouse: a route of splenic exit for recirculating lymphocytes

A study of pathways of lymphocyte migration through mouse spleen revealed lymphatic channels closely following arteries in trabeculae and white pulp. Because there is no detailed record of the layout of deep splenic lymphatics in the mouse, or other species, we present our observations in this paper, relating our findings to normal migratory pathways of lymphocytes through the spleen. Lymphatics draining the spleen are so inconspicuous that they often are not mentioned in anatomical discussions. The data presented clearly demonstrate 1) the existence and layout of deep lymphatic vessels in the mouse spleen, and 2) that migrating lymphocytes exit white pulp via these lymphatic vessels. CD4+ and CD8+ T cell subsets migrated proximally along the central artery from distal (dPALS) to proximal periarterial lymphatic sheaths (pPALS) and exited via deep lymphatic vessels that originate there. B cells migrated from dPALS to enter lymphatic nodules (NOD), thus segregated from T cells. B cells then migrated toward and exited via deep lymphatics. The appearance of labelled lymphocytes in lymph coincided with their disappearance from white pulp compartments. Labelled T cells were observed in splenic lymphatics as early as 1 hr after intravenous infusion but took, on average, about 6 hr. B cells took somewhat longer. Thus T and B cells entered and left white pulp through shared pathways, but took divergent intermediate routes through dedicated zones, pPALS for T cells, NOD for B cells.     

THE KINETICS OF LYMPHOCYTE RECIRCULATION WITHIN THE RAT SPLEEN

The migration of lymphocytes from the blood into the splenic pulp and the release of lymphocytes from the spleen into the blood was studied by isolating the rat spleen and perfusing it with 15 ml of recirculating, oxygenated blood. When thoracic duct lymphocytes labelled with tritiated uridine were added to the initial perfusate the concentration of these cells fell exponentially for 2–3 hr and then rose to a flat secondary peak. From this pattern it was inferred that small lymphocytes entered the spleen at a rate proportional to their instantaneous concentration in the perfusate, traversed the splenic pulp and re-entered the perfusate with a minimum transit time of 2–3 hr. The rate of release of small lymphocytes from the spleen was not influenced by the prevailing concentration of small lymphocytes in the perfusate but probably reflected the rate of migration into the spleen over a period earlier than 2 hr before. The rate of exchange of small lymphocytes between the blood and the intact spleen in vivo was estimated to be about 84 × 10⁶ cells/hr. The size of the intrasplenic pool of recirculating small lymphocytes was probably 400–500 × 10⁶ cells. The rate of migration of small lymphocytes into the spleen was not affected by prior irradiation of the spleen donor. When either of two antigenic materials were added to the perfusate no inhibition of lymphocyte migration into the spleen was noted although the release of lymphocytes from the spleen was diminished by the addition of a large dose of sheep erythrocytes.     

"Intermediate zone" of mammalian spleens: light and electron microscopic study of three primitive mammalian species (platypus, shrew, and mole) with special reference to intrasplenic arteriovenous communication

The intermediate zone (IZ) of nonperfused and perfused spleens in three species of primitive mammals (shrew, mole, platypus) was studied morphologically. The IZ is a tissue zone consisting of plexiform vessels, probably venous capillaries, and is located transitionally between the white and red pulp. The IZ is separated from the white pulp by the arterial net (AN), in which the white pulp arteries terminate. Development of the IZ differs between the three species examined being distinctive in the platypus and shrew. The IZ is thin in the mole spleen. A closed type of arteriovenous (A-V) anastomosis was demonstrated in or around the IZ in the two Insectivora species examined. In the shrew spleen, peripheral arterial branches running within the IZ anastomose with the AN around the follicle. The AN anastomoses eventually with venous plexiform vessels of the IZ around the nonfollicular area of the white pulp to form a closed system. In the mole spleen, A-V anastomoses were noted between white pulp arteries (follicular and AN) and veins of the red pulp, either by direct communication or through fenestrated IZ vessels compatible with the plexiform vessels of the shrew spleen. A-V anastomosis in the IZ is probable, but not confirmed, in the platypus spleen, as analysis was limited to a nonperfused specimen. Well-developed ellipsoids were noted around arterial terminals of the IZ in the shrew spleen. Ellipsoids were also noted around all arterial terminals of the mole spleen directed to the red pulp. Most ellipsoids of the mole spleen appeared located within the IZ. No ellipsoids were present around arterial terminals of the IZ in the platypus spleen. Closed circulation was noted in terminals of the pulp artery in spleens of all three species. All pulp arteries of the mole spleen are postellipsoid segments of white pulp (AN and follicle) arteries. No ellipsoids were found around terminals of the pulp artery (penicillar artery) in shrew and platypus spleens. The IZ is probably homologous to the perilymphatic sinusoid (vein) of the lungfish spleen and may be regarded as part of the red pulp. The IZ may be representative of primitive mammalian spleens that have closed circulation. The marginal zone (MZ) of common mammalian spleens is probably a modified IZ by differentiation (remodelling) of the intrasplenic vein. In this process, withdrawal of venous vessels from the IZ occurred, leaving a lymphoreticular zone with open circulation (MZ). The marginal sinus reported in some mammalian spleens is probably a modified AN formed during this process. Possible morphological alterations of the spleen in vertebrate phylogeny are discussed.     

Migration pathways of recirculating murine B cells and CD4+ and CD8+ T lymphocytes

Migration pathways of B cell and CD4+ and CD8+ T cell subsets of murine thoracic duct lymphocytes (TDL) were mapped. Per weight, the spleen accumulated more TDL than any other organ, regardless of lymphocyte subset. Spleen autoradiographs showed early accumulations of TDL in marginal zone and red pulp. Many TDL exited the red pulp within 1 hr via splenic veins. The remaining TDL entered the white pulp, not directly from the adjacent marginal zone but via distal periarterial lymphatic sheaths (dPALS). From dPALS, T cells migrated proximally along the central artery into proximal sheaths (pPALS) and exited the white pulp via deep lymphatic vessels. B cells left dPALS to enter lymphatic nodules (NOD), then also exited via deep lymphatics. T cells homed to lymph nodes more efficiently than B cells. Lymphocytes entered nodes via high-endothelial venules (HEV). CD4+ TDL reached higher absolute concentrations in diffuse cortex than did CD8+ T cells. However, CD8+ TDL moved more quickly through diffuse cortex than did CD4+ TDL. B cells migrated from HEV into NOD. Both T and B TDL exited via cortical and medullary sinuses and efferent lymphatics. A migration pathway across medullary cords is described. All TDL subsets homed equally well to Peyer's patches. T TDL migrated from HEV into paranodular zones while B cells moved from HEV into NOD. All TDL exited via lymphatics. Few TDL entered zones beneath dome epithelium. All subsets were observed within indentations in presumptive M cells of the dome epithelium.     

Structure and histochemical organization of the spleen of Agama stellio (Sauria: Agamidae) and Chalcides ocellatus (Sauria: Scincidae)

The spleen of Agama stellio is composed mainly of red pulp; the white pulp is poorly developed, and its clusters are scattered throughout the organ and contain lymphocytes, reticular cells, and some plasma cells. The red pulp consists of clear reticular cells intermingled with blood cells, sinusoids, and pigment cells. The spleen of Chalcides ocellatus is encapsulated by connective tissue and is composed of white and red pulp. The white pulp consists of lymphoid tissue that surrounds the central arterioles, forming the periarteriolar lymphocyte sheath (PALS). The red pulp is composed of a system of venous sinuses and cords. The results of various histochemical procedures designed to demonstrate mucosubstances, proteins, and nucleic acids indicate that the spleen in these species resembles the mammalian spleen. © 1993 Wiley-Liss, Inc.     

Immune proteasomes in the developing rat spleen

Changes in the structure of the rat spleen and the distribution of immune proteasomes in it during early postnatal development have been studied using double immunofluorescent staining of tissue sections with antibodies to the LMP7 immune proteasome subunit and to specific markers of T and B lymphocytes. It has been shown that the white pulp on postnatal day 5 is not yet colonized by lymphocytes and contains a smaller amount of immune proteasomes than the red pulp. At this stage, T and B lymphocytes concentrate mainly in the red pulp. On day 8, B lymphocytes occupy the marginal zone, while T lymphocytes aggregate into dense strands close to the white pulp. By day 18, T lymphocytes form periarteriolar sheaths in the white pulp, and the contents of immune proteasomes in the red and white pulp become equally high. An increase in the total content of immune proteasomes in the spleen on the third postnatal week was revealed in our previous study by Western blotting. In addition to T and B lymphocytes, immune proteasomes have also been revealed in other spleen cell types, probably in macrophages and reticular cells of the white pulp. Thus, the postnatal development of the spleen is associated with an increase in the contents of immune proteasomes in it.     

Microcirculation in mouse spleen (nonsinusal) studied by means of corrosion casts

Corrosion casts of mouse spleen, examined by scanning electron microscopy, enabled vascular pathways of the arterial, intermediate, and venous circulations to be traced over considerable distances. The arterial tree is surrounded by white pulp immediately upon entering at the hilus, and relatively few arterioles extend into red pulp. A profusion of capillaries is present in both periarterial lymphatic sheaths and lymphatic nodules, arranged as bifurcating systems (rather than anastomosing networks) terminating in the marginal sinus (MS) and marginal zone (MZ). The MS, which is situated between white pulp and MZ, consists of a discontinuous layer of flattened anastomosing spaces which are up to six times as large as those in rat spleen. Extensive filling of the entire MZ took place before appreciable filling of surrounding red pulp occurred. Capillary terminations in red pulp are always continuous with reticular meshwork, i.e., no evidence for a “closed” circulation was found. Casts of the venous origins support the classification “pulp venules” rather than “venous sinuses” and show major morphological differences from the richly anastomosing system of sinuses in rat. In the subcapsular region of mouse spleen large anastomosing veins ramify over the surface, with reticular meshwork occupying extensive areas between adjacent veins. For in vivo microscopy this arrangement offers advantages over that found in rat spleen (accompanying paper), where almost the entire surface is densely covered with venous sinuses.     

Microcirculatory pathways in normal human spleen, demonstrated by scanning electron microscopy of corrosion casts

Confusion regarding microcirculatory pathways in normal human spleen has arisen due to extrapolation from pathological material and from other mammalian spleens, not to mention difficulties in tracing intricate three-dimensional routes from the study of thin sections or cut surfaces of tissue. We examined microcirculatory pathways in normal human spleens freshly obtained from organ transplant donors. A modified corrosion casting procedure was used to obtain an open view of vessels and their connections. Our results demonstrate: 1) "arteriolar-capillary bundles" within lymphatic nodules and extensive branching of arterioles in the marginal zone (MZ); 2) the marginal sinus around lymphatic nodules; 3) the peri-marginal cavernous sinus (PMCS) outside the MZ or immediately adjacent to the nodule itself; the PMCS receives flow via ellipsoid sheaths and MZ, or directly from arterial capillaries, and drains into venous sinuses; 4) fast pathways for flow into venous sinuses via ellipsoid sheaths; 5) arterial capillary terminations in the reticular meshwork of the red pulp or MZ ("open" circulation); direct connections to venous sinuses also occur ("closed" circulation), although rarely; and 6) numerous open-ended venous sinuses in the MZ, allowing a large proportion of the splenic inflow to bypass the red cell filtration sites in the reticular meshwork and at venous sinus walls.     

Microvascularization of the spleen in larval and adult Xenopus laevis: Histomorphology and scanning electron microscopy of vascular corrosion casts

Microvascular anatomy and histomorphology of larval and adult spleens of the Clawed Toad, Xenopus laevis were studied by light microscopy of paraplast embedded serial tissue sections and scanning electron microscopy (SEM) of vascular corrosion casts (VCCs). Histology showed i) that white and red pulp are present at the onset of metamorphic climax (stage 57) and ii) that splenic vessels penetrated deeply into the splenic parenchyma at the height of metamorphic climax (stage 64). Scanning electron microscopy of VCCs demonstrated gross arterial supply and venous drainage, splenic microvascular patterns as well as the structure of the interstitial (extravasal) spaces representing the “open circulation routes.” These spaces identified themselves as interconnected resin masses of two distinct forms, namely “broccoli‐shaped” forms and highly interconnected small resin structures. Arterial and venous trees were clearly identified, as were transitions from capillaries to interstitial spaces and from interstitial spaces to pulp venules. Venous sinuses were not diagnosed (nonsinusal spleen). The splenic circulation in Xenopus laevis is “open.” It is hypothesized that red blood cells circulate via splenic artery, central arteries, penicillar arteries, and red pulp capillaries primarily via “broccoli‐shaped” interstitial spaces, pulp venules and veins into subcapsular veins to splenic veins while lymphocytes circulate also via the interstitial spaces represented by the highly interconnected small resin structures in vascular corrosion casts. In physiological terms, the former most likely represent the fast route for blood circulation, while the latter represent the slow route. J. Morphol. 277:1559–1569, 2016. © 2016 Wiley Periodicals, Inc.     

Macrophages and Reticulum Cells in the Spleen of the Dogfish,Scyliorhinus canicula

The presence and ultrastructural features of reticulum cells and macrophages were studied in the spleen of the dogfish Scyliorhinus canicula. Three morphologically distinguishable regions of the spleen were identified: the white pulp, the red pulp and the ellipsoids. In all three, the splenic parenchyma was a meshwork supported by reticulum cells and fibres. Reticulum cells in both the white and the red pulp are irregular elements, the processes of which are joined by cell junctions and embrace developing reticular fibres. The ellipsoids of the dogfish spleen are terminal branches of the splenic arteries of the white pulp, with a sheath consisting of reticulum cells, reticular fibres, ground substance, macrophages and occasional lymphocytes. Isolated melanomacrophages also occur in the ellipsoid walls as well as in the red pulp. In both the white and the red pulp phagocytic reticulum cells, and macrophages appear frequently forming cell associations with surrounding blood cells, mainly lymphocytes. The functional significance of the ellipsoids and the cell-cell clusters of the white and the red pulp is discussed in relation to the immune capacities demonstrated in elasmobranchs.     

Development of antigenic heterogeneity in the splenic meshwork of severe combined immunodeficient (SCID) mice after reconstitution with T and B lymphocytes

Recently, we produced monoclonal antibodies reacting specifically with the reticular meshwork (RM) of lymphoid tissues, and demonstrated that, in the splenic white pulp of normal mouse, the antigenic heterogeneity of RM was associated with the segregation of the T and B lymphocytes. In the present study, we attempted to visualize further the interaction between splenic RM and T and B lymphocytes transferred into severe combined immunodeficient (SCID) mice. The splenic white pulp of naive SCID mice, containing a few T and B cells, showed little tendency for T-B segregation and antigenic diversity of RM. Transfer of spleen or bone marrow cells from normal mice resulted in complete recovery of lymphocyte populations, showing not only a clear segregation of T and B lymphocytes but also a remarkable antigenic diversity of RM. The same results were obtained following the transfer of spleen or bone marrow cells from the nude mouse. Next, we transferred purified T lymphocytes to one group of SCID mice and B cells to another. In mice given T cells, a few B cells were observed in the white puop; T lymphocytes lodged not only in the inner periarterial lymphatic sheath (PALS) but also in the outer PALS and follicles. In the animals to which B cells were transferred, T cells were few and the homing of B cells occurred only into their proper compartments, such as the outer PALS, follicles and marginal zone, but not in the inner PALS. Thus, B cells can home into their proper compartments of the splenic white pulp independently of T lymphocytes.     

Ultrastructural changes in the spleen of the natterjack,Bufo calamita,after antigenic stimulation

Summary In the present study comparative aspects of the ultrastructure of the spleen were analyzed in non-immunized and T-dependent antigen-challenged natterjacks, Bufo calamita. Special attention is focused on the role of the non-lymphoid components in the splenic immunoreactivity. Ten days after primary immunization with sheep erythrocytes, splenic lymphoid follicles increase considerably in number and size. By that time, lymphoblasts, medium and large lymphocytes abound in the periphery of the white pulp near the marginal zone. Meanwhile, in the red pulp numerous monocytes migrating across the sinusoidal walls apparently transform into giant, dendritic-like cells. Twenty days after immunization the splenic lymphoid follicles decrease in number, although certain reactivity persists and numerous plasma cells occur in the cell cords and sinusoids of the red pulp. These results are discussed comparatively with those reported in other lower vertebrates.     

STUDIES ON LYMPHOCYTES

Continuous extracorporeal irradiation of the circulating blood (ECIB) of from 3 to 501/2 hr duration was used to study in the calf the differential depletion of lymphocytes from spleen, lymph nodes and thymus as compared to blood and thoracic duct lymph. The cell content of tissues was measured by planimetry and/or test point analysis. Lymphocyte depletion by ECIB from various lymphoreticular organs, and from different areas within a given organ, was less than in the circulating blood or the thoracic duct lymph and varied from one site of a lymphoreticular organ to another. The degree of depletion with time followed an exponential function with at least two components. The first component corresponded to a relatively rapid fall and the second to a very slow reduction in lymphocyte content. The former is related to the elimination of an easily mobilizable pool of lymphocytes while the latter corresponds to a more sessile mass of lymphocytes which exchange with blood lymphocytes very slowly. Elimination of the easily mobilizable pool of lymphocytes by ECIB from all tissues studied was observed within 10–15 hr, indicating that the rate of exchange with blood is similar for this group of cells in various lymphoreticular tissues. The size, however, of the easily mobilizable vs the more sessile pools of lymphocytes may vary considerably, the best estimates for the former being as follows (in per cent of total lymphocyte mass): lymph node medulla, less than 10%; lymph node cortex plus paracortical zone, 18% (depletion mainly paracortical); red pulp of the spleen, 37%; densely populated white pulp of the spleen, 55%; and loosely populated white pulp of the spleen, 60%. In comparison, the approximate fractions of lymphocytes originating fromthe easily mobilizable pools in various lymphoreticular tissues plus the cells already circulating a t the onset of EClB correspond to 64% for the thoracic duct lymph and 78% for the circulating blood respectively. These findings are discussed in relation to production, recirculation and life span of lymphocytes, and immune reactions.     

Lectin histochemistry of the spleen: a new lectin visualizes the stromal architecture of white pulp and the sinuses of red pulp.

The subcompartmentalization of the white pulp in the spleen is the result of interactions of specific resident stromal cells and migrating subtypes of lymphocytes. Because carbohydrate residues of cell membranes and extracellular matrices are involved in cell-cell and cell-matrix interactions, they were investigated in rat spleen by a broad panel of lectins. Splenic macrophages, which were also demonstrated by Perls' Prussian blue reaction, were labeled selectively by most mannose-specific lectins and gave the characteristic distribution patterns in all splenic (sub)compartments. One recently isolated lectin, Chelidonium majus agglutinin (CMA), visualized predominantly central arterioles, the reticular meshwork (RM) in the periarteriolar lymphatic sheaths (PALS), the circumferential reticulum cells limiting PALS and follicles, and some follicular dendritic cells (FDCs) in white pulp. The endothelial cells of venous sinuses in red pulp were also labeled by CMA and, if frozen sections were used, CMA also labeled the macrophages of the red pulp. Compared to CMA, the monoclonal antibody CD11, which can be used only in frozen sections, stained almost solely the fibrous (extracellular) component of the RM. Because CMA stains the reticulum cells in particular, it is better suited to visualize the stromal architecture of splenic white pulp than the monoclonal antibody. Because CMA can be applied to paraffin-embedded material, it is a particularly useful tool to study the splenic stromal architecture in archival material.     

Ultrastructure of splenic white pulp of the turtle,Mauremys caspica

Summary The ultrastructure of splenic tissue of non-immunized turtles, Mauremys caspica, shows two areas, namely, the white pulp which is lymphoid in nature, and the red pulp which is formed by cell cords and sinusoids. Between both areas there is always a marginal zone with gaps through which cells leak. In the white pulp, there are two blood vessel types; one with muscled walls, and the other showing thinner walls sheathed by reticular cells. Reticular cells constitute a network where there occur dendritic macrophages, lymphoblasts and small and medium lymphocytes. Mature plasma cells are scarce in the white pulp.     

汞离子及铬离子对黄鳝脾免疫细胞的影响

采用毒性实验方法,用不同浓度的汞离子(Hg2+)、铬离子(Cr6+)分别处理黄鳝(Monopterusalbus),经1、2、4、8 d后,通过光镜观察黄鳝脾组织结构及免疫细胞数量的变化。结果表明,对照组黄鳝脾被膜较薄,未见明显的小梁,实质由红髓和白髓构成。白髓中淋巴细胞聚集成群,未见明显脾小结,但可见动脉周围淋巴鞘。红髓由脾索与脾窦组成。脾中有椭圆体,其末端向脾髓开放。黑色素巨噬细胞中心形成。经两种重金属离子分别染毒后的黄鳝脾与对照组相比,组织结构表现出相似的变化,即随着重金属离子浓度的增加和染毒时间的延长,脾组织中的黑色素巨噬细胞中心逐渐增大、增多,最后减少;黑色素巨噬细胞先增加后减少。淋巴组织逐渐松散,排列稀疏混乱,淋巴细胞界限逐渐不清晰,呈退化趋势,数量先增加后减少。粒细胞数量的变化趋势与淋巴细胞一致。红血细胞大量破坏,血窦扩张。     

Antigen transport II. The significance of the localization of antigen-laden cells in the spleen

Previous studies have demonstrated that macrophage-like cells transporting antigen, e.g., human serum albumin (HSA) appear in thoracic duct lymph and blood shortly after antigen injection. The in vivo migration of these antigen-laden (Ag-L) cells from the blood stream was examined systematically by transferring Ag-L cells bearing ¹²⁵I-labelled HSA into syngeneic rats. There was no evidence autoradiographically that Ag-L cells migrated into lymph nodes, but the localization in the spleen followed a defined pattern: within the first hours after transfer, a majority of radiolabelled cells were identified in the marginal zone; by 3 hr and up to 4 days later, 60–80% of labelled cells were resident in the red pulp; Ag-L cells failed to migrate into the white pulp in significant numbers. Ag-L cells which had localized to the spleen, when examined 3 and 18 hr after transfer using combined autoradiography and immunoperoxidase staining, did not express la determinants in situ. The ability of Ag-L cells to stimulate an adoptive secondary response was tested in splenectomized, irradiated recipients receiving HSA-specific memory cells. Removal of the spleen before transfer severely reduced the antibody response evoked by Ag-L cells transporting HSA, thus indicating the functional importance of antigen transport to the spleen. Since Ag-L cell migration was primarily into the red pulp, we have considered whether the red pulp may provide a relevant microenvironment for lymphocyte/ antigen interaction.