Abstract
Lymph-borne, soluble factors (e.g., chemokines and others) influence lymphocyte recirculation and endothelial phenotype at high endothelial venules (HEVs) in lymph node cortex. Yet the route lymph-borne soluble molecules travel from the subcapsular sinus to the HEVs is unclear. Therefore, we injected subcutaneously into mice and rats a wide variety of fluorophore-labeled, soluble molecules and examined their distribution in the draining lymph nodes. Rather than percolating throughout the draining lymph node, all molecules, including microbial lipopolysaccharide, were very visible in the subcapsular and medullary sinuses but were largely excluded from the cortical lymphocyte microenvironments. Exclusion prevailed even during the acute lymph node enlargement accompanying viral infection. However, low molecular mass (MW) molecules, including chemokines, did gain entry into the cortex, but in a very defined manner. Low MW, fluorophore-labeled molecules highlighted the subcapsular sinus, the reticular fibers, and the abluminal and luminal surfaces of the associated HEVs. These low MW molecules were in the fibers of the reticular network, a meshwork of collagen fibers ensheathed by fibroblastic reticular cells that connects the subcapsular sinus floor and the HEVs by intertwining with their basement membranes. Thus, low MW, lymph-borne molecules, including chemokines, traveled rapidly from the subcapsular sinus to the HEVs using the reticular network as a conduit.
Highlights
Determining how elements of the immune system come together and interact in lymphoid tissues is important to understanding the immune response and its dysregulation
Lymphocytes enter the cortex of the lymph node by adhering to and migrating across specialized postcapillary venules called high endothelial venules (HEVs),1 found in Portions of this work have appeared in abstract form
The entry of soluble molecules from the subcapsular sinus into the cortex was dependent on Soluble molecule MW MR SCS IC Fiber HEV Ref
Summary
Determining how elements of the immune system come together and interact in lymphoid tissues is important to understanding the immune response and its dysregulation. Much progress has been made in ascertaining the cellular and molecular events of lymphocyte homing and recirculation, and APC–lymphocyte interactions. The anatomy of the lymphoid tissues in which these processes occur is well documented, the roles lymphoid structures play in the orchestration of immune responses remain to be fully understood. Lymphocytes recirculate through the body via the bloodstream to lymphoid tissue, such as lymph nodes, where they search for their respective antigens, return to the bloodstream via efferent lymphatics and the thoracic duct [1]. Lymphocytes enter the cortex of the lymph node by adhering to and migrating across specialized postcapillary venules called high endothelial venules (HEVs), found in Portions of this work have appeared in abstract form
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