Lymphatic Vessel Memory Stimulated by Recurrent Inflammation

Inflammation stimulates new lymphatic vessel growth (inflammatory lymphangiogenesis). One key question is how recurrent inflammation, a common clinical condition, regulates lymphatic vessel remodeling. We show here that recurrent inflammation accelerated the development a functional lymphatic vessel network. This observation suggests a novel program of lymphangiogenesis and identifies a property of lymphatic vessel memory in response to recurrent inflammation. A brief episode of initial inflammation regressed lymphatic vessels, and a significant increase in CD11b⁺ macrophages were associated with the development of lymphatic vessel memory. These vessels had major differences in the structure and the spatial distribution of specialized lymphatic vessel features. Surprisingly, we found that the lymphatic vessel memory response did not depend on the vascular endothelial growth factor C or A pathway, indicating that different molecular pathways regulate inflammatory lymphangiogenesis and lymphatic vessel memory. These findings uncover a priming mechanism to facilitate a rapid lymphatic vessel memory response: a potential important component of peripheral host defense.The lymphatic vasculature is one component of the inflammatory response that is remarkably understudied. The lymphatic system can be broadly classified into the lymphoid tissue (tonsils, lymph nodes, and spleen) and the conduit system or lymphatic vasculature. The focus of these studies is the lymphatic capillaries which literally are the most peripheral extension of the immune system and reside intimately in the diseased tissue. Aside from the classic functions of the lymphatic vasculature described many years ago (transport of extracellular fluid, cells, antigens, and lipid), surprisingly little is known about the normal physiology of this system and how it regulates inflammation and wound recovery. Multiple lines of evidence have shown that the lymphatic vasculature proliferates in response to inflammatory conditions, suggesting an active, perhaps essential, role during the inflammatory response.^1–6 Inflammatory lymphangiogenesis is thought to be a physiological mechanism that develops to meet the increased demands of fluid, antigen, and cellular transport during an inflammatory response. New lymphatic vessel growth has been associated with beneficial effects in several different preclinical models of acute or chronic inflammatory disease.^3,7–9 It is well recognized that vascular endothelial growth factor (VEGF)-C-VEGF receptor (VEGFR)-3 and VEGF-A-VEGFR-2 pathways are important in inflammatory lymphangiogenesis.¹⁰ The most accepted model of inflammatory lymphangiogenesis is that vessels sprout and elongate from pre-existing lymphatic vessels. In contrast, is some evidence is available that circulating endothelial progenitors or macrophages differentiate into lymphatic endothelial cells to comprise newly synthesized lymphatic vessels.^11,12Clinically, two general outcomes occur after an initial episode of inflammatory disease: wound recovery or recurrent inflammation. We developed a mouse model of wound recovery and recurrent inflammation to simulate these clinical outcomes and to study the lymphatic vasculature during these conditions. We recently demonstrated that lymphatic vessel regression developed during wound recovery in the cornea.¹³ Fragmented lymphatic vessels that persisted over time were visualized in wound recovery conditions.In contrast to wound recovery, recurrent inflammation is a common clinical outcome after an initial episode of inflammation. We studied the effects of recurrent inflammation in corneal tissue recovered from an initial inflammatory response. This approach is different from earlier studies in that it features wound recovery followed by recurrent inflammation rather than an acute or chronic unrelenting pathogen or tumor-based inflammatory stimuli.^3,4,7,14 We induced recurrent inflammation in recovered corneal tissue by placing a subsequent suture in the cornea (re-suturing). Here, we show that one feature of recurrent inflammation was the accelerated localized development of a functional lymphatic vessel network. The rapid kinetics and memory response were reminiscent of an immunological memory response; for this reason we describe this process as lymphatic vessel memory. This response appeared to stimulate the anastomosis of fragmented lymphatic vessels. Unlike inflammatory lymphangiogenesis induced by initial inflammation, we showed that lymphatic vessel memory was independent of the VEGF-C and VEGF-A pathways. Thus, these studies reveal a novel program of lymphatic vessel memory.