We demonstrated that essentially meningeal lymphatic vessels around the brain and spinal cord develop during the first postnatal month and that VEGFR3/VEGFC signaling is indispensable for their development and maintenance. We showed that tuning the VEGFR3/VEGFC pathway by genetic and biochemical methods allows regression or expansion of meningeal lymphatic vessels in adulthood, resulting in a corresponding decrease or increase of cerebrospinal fluid clearance via the lymphatic vessels. We found that the lymphatic network is extensive, it functions in transport of cerebrospinal fluid and it is plastic, reacting to injury or inflammation. Furthermore, we have developed multiple new and improved methods for imaging and analysis of the meningeal lymphatic vessels and their function, including imaging of the cleared transparent skull and analysis of tracer drainage from CSF to lymph nodes and blood. Based on this, we have reported on the effects of VEGF-C and VEGFR-3 on cerebrospinal fluid flow and protein clearance.
We demonstrated a significant role of the main lymphangiogenic factor VEGF-C in regulation of cerebrospinal fluid (CSF) flow and drainage. Administration of VEGF-C protein immediately after ischemic stroke ensure faster recovery and improved behavioral outcome in mice. Analysis of transgenic K14-sVEGFR3-Ig mice, in which lymphatic vessel development to the dura fails, revealed a number of interesting changes in immune cells in CNS tissues. We have also described and characterized meningeal lymphatics in primates (marmosets).
We have characterized the role of meningeal lymphatic vessels in Alzheimer’s disease in two widely used mouse models. The basic characterization of tissues related to mLVs, namely dura mater, brain and cervical lymph nodes were examined at different time-points of disease course by IHC and functional drainage analysis. The exceptional dependence of meningeal lymphatic vessels the lymphangiogenic growth factor VEGF-C allowed us to selectively modulate the amount and functionality of mLVs and study their role in Alzheimer’s disease.
In addition to the VEGFC-VEGFR3 signaling pathway, angiopoietin (Angpt)-Tie signaling pathway plays important roles in regulating vascular permeability and leukocyte trafficking. Experimental autoimmune encephalomyelitis (EAE) is a well-characterized experimental model of multiple sclerosis (MS), which is the most common human demyelinating CNS autoimmune disease. To our surprise, the lack of mLVs did not alter the clinical severity of EAE or the percentage of body weight loss. During our study, we found that neuroinflammation in this model increases the expression of the Angpt2 ligand that is required for lymphangiogenic signaling. Transgenic mice expressing Angpt2 specifically in ECs developed a more severe EAE than control mice whereas both prophylactic and preemptive treatment with an Angpt2-blocking antibody ameliorated EAE. Thus, Angpt2 targeting may serve as an alternative therapeutic option for the treatment of CNS autoimmune disease.
Our current results (in collaboration with Dr. Francesco Noe) showed that mLVs are pivotal for a proper and specific neuro-immune response after traumatic brain injury TBI, which is principally mediated by the resident memory cytotoxic CD8+ T cells.
Further studies should determine how the obtained knowledge could be translated to the treatment of CNS autoimmune disease, TBI and stroke.