TWEAK is expressed at the cell surface of monocytes during multiple sclerosis.

The TNF superfamily ligand, TNF-like weak inducer of apoptosis (TWEAK), regulates cellular responses ranging from proliferation to cell death in a manner highly dependent on the cell type and the microenvironmental context. We have shown previously that treatment of experimental autoimmune encephalomyelitis mice after the priming phase with neutralizing anti-TWEAK antibodies results in a reduction in the severity of the disease and leukocyte infiltration. To further characterize TWEAK/fibroblast growth factor-inducible 14-kDa protein (Fn14) involvement during multiple sclerosis (MS), we evaluated in MS patients and controls: TWEAK and Fn14 expression on PBMC and soluble TWEAK concentration in serum and cerebrospinal fluid (CSF). Thirty-six consecutive patients were enrolled, including 11 patients with relapsing-remitting MS, 11 with a clinical isolated syndrome suggestive of MS (CISSMS), and 14 controls with non-MS diseases. Intracellular TWEAK could be observed in lymphocytes and/or monocytes in all groups of patients. None of the 36 patients displayed TWEAK expression at the cell surface of lymphocytes. In contrast, 12 out of the 36 patients were positive for membrane TWEAK expression on their monocytes. Among these patients, eight were from the CISSMS group. Fn14 was not detected in PBMC. The soluble form of TWEAK is detectable in serum and CSF of patients, and TWEAK concentrations were not statistically different between the disease groups. We demonstrated for the first time that TWEAK is expressed at the cell surface of monocytes during MS, especially in the CISSMS group. Our results support the proposal that TWEAK could be a target for antibody therapy in MS.

Overexpression of PKD2 in the mouse is associated with renal tubulopathy.

Polycystin-2 (PC-2), a cation channel of the Trp family, is involved in autosomal dominant polycystic kidney disease (ADPKD) type 2 (ADPKD2). This protein has recently been localized to the primary cilium where its channel function seems to be involved in a mechanosensory phenomenon. However, its biological function is not totally understood, especially in tubule formation. In the present paper, we describe a mouse model for human PC-2 overexpression, obtained by inserting a human bacterial artificial chromosome (BAC) containing the PKD2 gene. Three lines were generated, expressing different levels of PKD2. One line, PKD2-Y, has been explored in more detail and we will present physiological and molecular exploration of these transgenic animals. Our data demonstrate that transgenic animals older than 12 months present tubulopathy with proteinuria and failure to concentrate urine. Moreover, the kidney cortex has been found disorganized. Finally, we observe that extracellular matrix protein expression is downregulated in these animals. In conclusion, overexpression of human PKD2 leads to anomalies in tubular function, probably due to abnormalities in tubule morphogenesis.

Centrosome overduplication and mitotic instability in PKD2 transgenic lines.

Polycystin-2 (PC-2), a protein encoded by PKD2 and involved in autosomal dominant polycystic kidney disease (ADPKD), is a non-selective cationic channel recently implicated in the function of primary cilia. We recently constructed a new animal model in the form of a transgenic mouse with a BAC-containing human PKD2 inserted in its genome. Two transgenic mouse lines overexpressing human PKD2 showed mitotic instability. Fibroblasts from these transgenic mouse lines have abnormal chromosomal numbers. These lines also have supernumerary centrosomes. PC-2 overexpression is associated with mitotic instability and centrosome overduplication. PC-2 therefore seems to play a role in centrosome duplication, and this hypothesis is being evaluated in other models.