Parkinson's disease-linked LRRK2 is expressed in circulating and tissue immune cells and upregulated following recognition of microbial structures.

Sequence variants at or near the leucine-rich repeat kinase 2 (LRRK2) locus have been associated with susceptibility to three human conditions: Parkinson's disease (PD), Crohn's disease and leprosy. As all three disorders represent complex diseases with evidence of inflammation, we hypothesized a role for LRRK2 in immune cell functions. Here, we report that full-length Lrrk2 is a relatively common constituent of human peripheral blood mononuclear cells (PBMC) including affinity isolated, CD14(+) monocytes, CD19(+) B cells, and CD4(+) as well as CD8(+) T cells. Up to 26% of PBMC from healthy donors and up to 43% of CD14(+) monocytes were stained by anti-Lrrk2 antibodies using cell sorting. PBMC lysates contained full-length (>260 kDa) and higher molecular weight Lrrk2 species. The expression of LRRK2 in circulating leukocytes was confirmed by microscopy of human blood smears and in sections from normal midbrain and distal ileum. Lrrk2 reactivity was also detected in mesenteric lymph nodes and spleen (including in dendritic cells), but was absent in splenic mononuclear cells from lrrk2-null mice, as expected. In cultured bone marrow-derived macrophages from mice we made three observations: (i) a predominance of higher molecular weight lrrk2; (ii) the reduction of autophagy marker LC3-II in (R1441C)lrrk2-mutant cells (<31%); and (iii) a significant up-regulation of lrrk2 mRNA (>fourfold) and protein after exposure to several microbial structures including bacterial lipopolysaccharide and lentiviral particles. We conclude that Lrrk2 is a constituent of many cell types in the immune system. Following the recognition of microbial structures, stimulated macrophages respond with altered lrrk2 gene expression. In the same cells, lrrk2 appears to co-regulate autophagy. A pattern recognition receptor-type function for LRRK2 could explain its locus' association with Crohn's disease and leprosy risk. We speculate that the role of Lrrk2 in immune cells may also be relevant to the susceptibility of developing PD or its progression.

Cathepsin D expression level affects alpha-synuclein processing, aggregation, and toxicity in vivo.

BACKGROUND: Elevated SNCA gene expression and intracellular accumulation of the encoded alpha-synuclein (aSyn) protein are associated with the development of Parkinson disease (PD). To date, few enzymes have been examined for their ability to degrade aSyn. Here, we explore the effects of CTSD gene expression, which encodes the lysosomal protease cathepsin D (CathD), on aSyn processing. RESULTS: Over-expression of human CTSD cDNA in dopaminergic MES23.5 cell cultures induced the marked proteolysis of exogenously expressed aSyn proteins in a dose-dependent manner. Unexpectedly, brain extractions, Western blotting and ELISA quantification revealed evidence for reduced levels of soluble endogenous aSyn in ctsd knock-out mice. However, these CathD-deficient mice also contained elevated levels of insoluble, oligomeric aSyn species, as detected by formic acid extraction. In accordance, immunohistochemical studies of ctsd-mutant brain from mice, sheep and humans revealed selective synucleinopathy-like changes that varied slightly among the three species. These changes included intracellular aSyn accumulation and formation of ubiquitin-positive inclusions. Furthermore, using an established Drosophila model of human synucleinopathy, we observed markedly enhanced retinal toxicity in ctsd-null flies. CONCLUSION: We conclude from these complementary investigations that: one, CathD can effectively degrade excess aSyn in dopaminergic cells; two, ctsd gene mutations result in a lysosomal storage disorder that includes microscopic and biochemical evidence of aSyn misprocessing; and three, CathD deficiency facilitates aSyn toxicity. We therefore postulate that CathD promotes 'synucleinase' activity, and that enhancing its function may lower aSyn concentrations in vivo.

The use of rapid assessment of enteric ICC and neuronal morphology may improve patient management in pediatric surgery: a new clinical pathological protocol.

Alterations in interstitial cells of Cajal (ICC) distribution and density may seriously influence gut motility. We and others have documented a disturbance of ICC and neurons in Hirschsprung's disease (HD), intestinal ischemia, and inflammation. The ability to remove intestine with permanent dysmotility improves significantly the prognosis. This may be important in the developing intestine especially in HD. More complete pathological information increases the accuracy of surgical decisions. Therefore we sought to develop a rapid, intraoperative immunohistochemical protocol for ICC and neurons in surgical specimens for routine diagnostic and therapeutic assessment of pediatric patients. To date, cKit is the only reliable immunohistochemistry for ICC identification. There are multiple antibodies in use for neuronal identification. A comparison of fixation methods and immunostaining using cKit and multiple intestinal neuronal antibodies was done. Fresh segments of surgically resected intestine were sectioned and stained using antibodies for ICC cell identification (anti-cKit) and for neuronal characterization. By carefully changing tissue fixation methods, different neuronal antibodies were tested to determine an optimal rapid protocol. Each suggested protocol was tested on normal and pathological intestinal tissue and compared to the previous overnight immunostaining of the same tissue. A new rapid tissue fixation and immunostaining protocol using cKit for ICC identification and NF 68 was developed. By employing this protocol, we could obtain ICC and neuro-immunohistochemistry in unfixed frozen sections within 1 h with tissue vibration to diminish the time for immunostaining. Without vibration the protocol takes 3 h. ICC and enteric neuronal changes could be readily observed and the quality of staining was comparable to standard immunohistochemistry. Each gut pathology displayed characteristic changes in ICC and neuronal density/distribution in the affected bowel. The time-scale of the 1-h immunoprocessing is still longer than the standard clinical pathological "quick" sections using H&E staining; however, the protocol duration is within the surgery timescale. Standard H&E stain used in combination with our rapid neuronal and ICC immunohistochemistry protocol enables a fast, comprehensive, and accurate assessment of the pathophysiology of signaling networks controlling gut motility while the patient is still in the operating room. We propose that the addition of this simple and rapid immunohistochemical assessment in the pathologist evaluation of surgical specimens would result in a more complete characterization for diagnosis and prognosis of the pediatric patient. Specifically, we propose that this test will differentiate good versus poor prognosis HD patients based on their neuron/ICC ratio and present a rapid, standardized method for use in general pathology.