Cystic kidney diseases and planar cell polarity signaling.

Renal cystic diseases are a major clinical concern as they are the most common genetic cause of end-stage renal disease. While many of the genes causing cystic disease have been identified in recent years, knowing the molecular nature of the mutations has not clarified the mechanisms underlying cyst formation. Recent research in model organisms has suggested that cyst formation may be because of defective planar cell polarity (PCP) and/or ciliary defects. In this review, we first outline the clinical features of renal cystic diseases and then discuss current research linking our understanding of cystic kidney disease to PCP and cilia.

ADPKD: a human disease altering Golgi function and basolateral exocytosis in renal epithelia.

Epithelial cells explanted from autosomal dominant polycystic kidney disease (ADPKD) tissue exhibit impaired exocytosis, specifically between the Golgi and basolateral membrane (Charron A, Nakamura B, Bacallo R, Wandinger-Ness A. Compromised cytoarchitecture and polarized trafficking in autosomal dominant polycystic kidney disease cells. J Cell Biol 2000; 148: 111-124.). Here the defect is shown to result in the accumulation of the basolateral transport marker vesicular stomatitis virus (VSV) G protein in the Golgi complex. Golgi complex morphology is consequently altered in the disease cells, evident in the noticeable fenestration and dilation of the cisternae. Further detailed microscopic evaluation of normal kidney and ADPKD cells revealed that ineffective basolateral exocytosis correlated with modulations in the localization of select post-Golgi transport effectors. The cytosolic coat proteins p200/myosin II and caveolin exhibited enhanced association with the cytoskeleton or the Golgi of the disease cells, respectively. Most cytoskeletal components with known roles in vesicle translocation or formation were normally arrayed with the exception of Golgi beta-spectrin, which was less prevalent on vesicles. The rab8 GTPase, important for basolateral vesicle targeting, was redistributed from the perinuclear Golgi region to disperse vesicles in ADPKD cells. At the basolateral membrane of ADPKD cells, there was a notable loss of the exocyst components sec6/sec8 and an unidentified syntaxin. It is postulated that dysregulated basolateral transport effector function precipitates the disruption of basolateral exocytosis and dilation of the ADPKD cell Golgi as basolateral cargo accumulates within the cisternae.

Cablin: a novel protein of the capillary basal lamina.

The microvascular wall is remarkably simple, consisting only of the endothelial lining, subjacent basal lamina, and underlying periendothelial cells. This study describes the characterization of a novel microvascular protein. This 80,000-molecular weight protein was predominantly associated with electron-lucent amorphous material in capillary basal laminae and therefore termed cablin (protein of the capillary basal lamina). Consistent with its immunolocalization to the microvasculature, cablin was synthesized and secreted by cultured endothelial cells and vascular smooth muscle cells. Furthermore, cablin expression was induced during neovascularization. The predicted amino acid sequence of cablin revealed a prevalence of polar amino acids. Accounting for the low yet significant homology to several alpha-helical proteins, these residues were best accommodated by secondary structure predictions that aligned the molecule into two large alpha-helical domains. The presence of the integrin-binding RGD tripeptide and a putative elastin-binding sequence suggest that this rodlike molecule is suited to cross-link cells and matrix constituents. In this capacity it could contribute to the mechanical strength or the angiogenic potential of the microvasculature.

Apiconuclear organization of microtubules does not specify protein delivery from the trans-Golgi network to different membrane domains in polarized epithelial cells.

In nonpolarized epithelial cells, microtubules originate from a broad perinuclear region coincident with the distribution of the Golgi complex and extend outward to the cell periphery (perinuclear [PN] organization). During development of epithelial cell polarity, microtubules reorganize to form long cortical filaments parallel to the lateral membrane, a meshwork of randomly oriented short filaments beneath the apical membrane, and short filaments at the base of the cell; the Golgi becomes localized above the nucleus in the subapical membrane cytoplasm (apiconuclear [AN] organization). The AN-type organization of microtubules is thought to be specialized in polarized epithelial cells to facilitate vesicle trafficking between the trans-Golgi Network (TGN) and the plasma membrane. We describe two clones of MDCK cells, which have different microtubule distributions: clone II/G cells, which gradually reorganize a PN-type distribution of microtubules and the Golgi complex to an AN-type during development of polarity, and clone II/J cells which maintain a PN-type organization. Both cell clones, however, exhibit identical steady-state polarity of apical and basolateral proteins. During development of cell surface polarity, both clones rapidly establish direct targeting pathways for newly synthesized gp80 and gp135/170, and E-cadherin between the TGN and apical and basolateral membrane, respectively; this occurs before development of the AN-type microtubule/Golgi organization in clone II/G cells. Exposure of both clone II/G and II/J cells to low temperature and nocodazole disrupts >99% of microtubules, resulting in: 1) 25-50% decrease in delivery of newly synthesized gp135/170 and E-cadherin to the apical and basolateral membrane, respectively, in both clone II/G and II/J cells, but with little or no missorting to the opposite membrane domain during all stages of polarity development; 2) approximately 40% decrease in delivery of newly synthesized gp80 to the apical membrane with significant missorting to the basolateral membrane in newly established cultures of clone II/G and II/J cells; and 3) variable and nonspecific delivery of newly synthesized gp80 to both membrane domains in fully polarized cultures. These results define several classes of proteins that differ in their dependence on intact microtubules for efficient and specific targeting between the Golgi and plasma membrane domains.

Recent advances in the understanding of polycystic kidney disease.

Polycystic kidney disease is characterized by localized autonomous cellular proliferation, compartmentalized fluid accumulation within the cysts, and intraparenchymal fibrosis of the kidney. The clinical features include renal failure, liver cysts, and vascular and cardiac valve abnormalities. Recent developments have extended our understanding of cyst formation, fluid secretion, and the genetics of polycystic kidney disease. Two causal genes for polycystic kidney disease, PKD1 and PKD2, that are responsible for greater than 95% of cases of autosomal dominant polycystic kidney disease, have been identified and sequenced. The mechanisms of cystogenesis are being uncovered and the phenotypic features of cystic epithelial cells are being discovered. This review describes recent advances made in the molecular biology of the genetic causes of polycystic kidney disease. The mechanistic details of cystogenesis are discussed and contrasted with the paradigms that guide current experimental approaches.