Crumbs2 Is an Essential Slit Diaphragm Protein of the Renal Filtration Barrier.

BACKGROUND: Crumbs2 is expressed at embryonic stages as well as in the retina, brain, and glomerular podocytes. Recent studies identified CRB2 mutations as a novel cause of steroid-resistant nephrotic syndrome (SRNS). METHODS: To study the function of Crb2 at the renal filtration barrier, mice lacking Crb2 exclusively in podocytes were generated. Gene expression and histologic studies as well as transmission and scanning electron microscopy were used to analyze these Crb2podKO knockout mice and their littermate controls. Furthermore, high-resolution expansion microscopy was used to investigate Crb2 distribution in murine glomeruli. For pull-down experiments, live cell imaging, and transcriptome analyses, cell lines were applied that inducibly express fluorescent protein-tagged CRB2 wild type and mutants. RESULTS: Crb2podKO mice developed proteinuria directly after birth that preceded a prominent development of disordered and effaced foot processes, upregulation of renal injury and inflammatory markers, and glomerulosclerosis. Pull-down assays revealed an interaction of CRB2 with Nephrin, mediated by their extracellular domains. Expansion microscopy showed that in mice glomeruli, Crb2 and Nephrin are organized in adjacent clusters. SRNS-associated CRB2 protein variants and a mutant that lacks a putative conserved O-glycosylation site were not transported to the cell surface. Instead, mutants accumulated in the ER, showed altered glycosylation pattern, and triggered an ER stress response. CONCLUSIONS: Crb2 is an essential component of the podocyte's slit diaphragm, interacting with Nephrin. Loss of slit diaphragm targeting and increasing ER stress are pivotal factors for onset and progression of CRB2-related SRNS.

On the longevity of resident endoneurial macrophages in the peripheral nervous system: a study of physiological macrophage turnover in bone marrow chimeric mice.

Macrophages are intimately involved in the pathogenesis of peripheral nervous system (PNS) disorders. Recently, we characterized a resident endoneurial macrophage population, which contributes rapidly to the endoneurial macrophage response in PNS diseases. Unlike microglial cells, resident macrophages undergo a physiological turnover of 50% in the sciatic nerve and 80% in dorsal root ganglia (DRG) within 12 weeks. Further information about the dynamics of this turnover is not available. This study examined the macrophage turnover in the sciatic nerve and DRGs over a longer period and addresses the question whether the turnover of resident macrophages is complete or whether there is a truly resident endoneurial macrophage population. We used chimeric mice carrying GFP(+) bone marrow and immunohistochemistry to detect hematogenous (GFP(+)) endoneurial macrophages after turnover. Non-exchanged, resident macrophages were GFP(-). Quantification of GFP(+) and GFP(-) macrophages revealed a maximal turnover of 75%, reached in DRGs after 12 weeks and in sciatic nerves after 36 weeks. GFP(-) long-term resident macrophages were further characterized after sciatic nerve injury, where they participated in the early macrophage response of Wallerian degeneration. Our results point toward a small but truly resident PNS macrophage population. These macrophages are an interesting target for further characterization and might have a distinct role in peripheral nerve disease.

Further evidence for a crucial role of resident endoneurial macrophages in peripheral nerve disorders: lessons from acrylamide-induced neuropathy.

Endoneurial macrophages are crucially involved in the pathogenesis of neuropathies. Historically, the macrophage response in neuropathies is believed to be of hematogenous origin. However, recent studies could demonstrate an intrinsic generation of the early macrophage response by resident endoneurial macrophages after traumatic nerve injury and in a model of hereditary neuropathy. We hypothesized that the local macrophage response might suffice to generate an appropriate macrophage response in mild neuropathies, supplemented by infiltrating macrophages only in severe nerve pathology. To clarify this assumption, we investigated the macrophage response in acrylamide-induced neuropathy as a model of a slowly progressive neuropathy with a defined onset. We induced the neuropathy in bone marrow chimeric mice carrying green fluorescent protein transgenic bone marrow, allowing the differentiation of resident (GFP(-)) and invading hematogenous endoneurial (GFP(+)) macrophages. Quantification of GFP(-) and GFP(+) endoneurial macrophages in the sciatic nerve revealed an increase only of resident macrophages in proximal parts, whereas in distal parts a minor additional influx of hematogenous macrophages was observed. The immunohistochemical profile of GFP(-) and GFP(+) macrophages was similar but distal GFP(-) macrophages were differentially activated than their GFP(+) counterparts. Characterization of CCR2-deficient mice revealed a function for this chemokine system in attracting hematogenous macrophages but not in generating the intrinsic macrophage response. In conclusion, we provide evidence for a role of resident macrophages in acrylamide-induced neuropathy. Resident endoneurial macrophages intrinsically generate the macrophage response in this slowly progressive neuropathy, which only becomes supplemented by hematogenous macrophages in distal areas of more pronounced damage.

Contribution of resident endoneurial macrophages to the local cellular response in experimental autoimmune neuritis.

Macrophages are intimately involved in the pathogenesis of inflammatory neuropathies. The contribution of resident endoneurial macrophages is unknown since their differentiation from infiltrating macrophages is difficult due to missing cellular markers. Previous studies demonstrated the participation of resident macrophages in Wallerian degeneration and the pathogenesis of hereditary neuropathies. The question arises whether resident macrophages are involved in experimental autoimmune neuritis (EAN) where they could contribute to immunosurveillance and antigen presentation. To address this question we used bone marrow chimeric rats, allowing the differentiation between resident and hematogenous cells. Immunohistochemistry and in situ hybridization were applied on to identify and characterize resident macrophages in terms of morphological features, expression of activation markers, proliferation, phagocytosis, and MHC-II expression. Endoneurial macrophages of resident origin were detectable at all stages of disease with a contribution of at least 27% of the total macrophages. They appeared activated by morphological and immunohistochemical criteria and proliferated early. MHC-II-positive resident macrophages were observed that had phagocytosed myelin. These results demonstrate that the macrophage response in EAN is partly of intrinsic origin. The rapid activation and proliferation of resident endoneurial macrophages points toward an active role of these cells in inflammatory peripheral nerve disease, especially early in disease.

Macrophage response to peripheral nerve injury: the quantitative contribution of resident and hematogenous macrophages.

Whereas local microglial cells of the CNS rapidly respond to injury, little is known about the functional role of resident macrophages of the peripheral nervous system in nerve pathology. Using bone marrow chimeric rats, we recently identified individual resident endoneurial macrophages that rapidly became activated after nerve injury. However, the extent of local macrophage activation and its quantitative contribution to the total macrophage response is unknown. We now have created chimeric mice by transplanting bone marrow from green fluorescent protein (GFP)-transgenic mice into irradiated wild-type mice, allowing easy differentiation and quantification of hematogenous and resident endoneurial macrophages. After sciatic nerve crush injury, both GFP(-) and GFP(+) resident macrophages, the latter having undergone physiological turnover from the blood before injury, rapidly underwent morphological alterations and increased in number. Proliferating GFP(-) and GFP(+) resident macrophages were abundant and peaked 3 days after injury. A major lesion-induced influx of hematogenous macrophages with a disproportionate increase of GFP(+) macrophages was not observed until Day 4. Throughout all time points examined, GFP(-) resident macrophages were strikingly frequent, reaching maximum numbers 9.5-fold above baseline. There was also a notable proportion of GFP(-) resident endoneurial macrophages phagocytosing myelin and expressing major histocompatibility complex class II. Our results demonstrate for the first time that the rapid response of resident endoneurial macrophages to nerve injury is quantitatively important and that local macrophages contribute significantly to the total endoneurial macrophage pool during Wallerian degeneration.