The absence of a clathrin adapter confers unique polarity essential to proximal tubule function.

It is well established that many cognate basolateral plasma membrane proteins are expressed apically in proximal tubule cells thus optimizing the reabsorption capacity of the kidney. The protein clathrin and its adapter proteins normally regulate basolateral polarity. Here we tested whether the unique proximal tubule polarity is dependent on an epithelial-specific basolateral clathrin adapter, AP1B, present in most other epithelia. Quantitative PCR of isolated mouse renal tubules showed that AP1B was absent in proximal tubules but present in medullary and cortical thick ascending limbs of Henle, and cortical collecting ducts. Western blot confirmed the absence of AP1B in three established proximal tubule cell lines. Knockdown of AP1B by shRNA in prototypical distal tubule MDCK cells resulted in redistribution of the basolateral parathyroid hormone receptor, the insulin-like growth factor II receptor/calcium-independent mannose-6-phosphate receptor, and the junctional adhesion molecule, JAM-C, to a proximal tubule-like nonpolar localization. Yeast two-hybrid assays detected direct interactions between the cytoplasmic tails of these plasma membrane proteins and the cargo-binding region of the AP1B complex. Hence, our results show that differential expression of AP1B contributes to normal kidney function and illustrates possible roles of this adapter protein in kidney development, physiology, and pathology.

Protein microarray analysis of nasal polyps from aspirin-sensitive and aspirin-tolerant patients with chronic rhinosinusitis.

BACKGROUND: The purpose of this study was to apply protein microarray technology to the study of sinonasal tissue and to identify differential protein expression in nasal polyps from aspirin-sensitive (AS) versus aspirin-tolerant (AT) patients with chronic rhinosinusitis (CRS) and CRS with nasal polyps (CRSwNPs). METHODS: Nasal polyp specimens were prospectively obtained from two groups of patients with CRSwNP. The test group (AS) consisted of five patients that were diagnosed with CRSwNP and intolerance to aspirin based on medical history and physical exam. The control group (AT) consisted of four AT patients with CRSwNP. Protein was extracted and labeled from harvested polyps and the Sigma Panorama Antibody Microarray-Cell Signaling Kit was used to identify differences in protein expression between the two polyp groups. Western blot analysis was used to validate the results of the protein microarray. RESULTS: The protein microarray showed a greater than twofold change in expression of both beta-adaptin and heat shock protein 70 (HSP70). Western blot analysis confirmed up-regulation of beta-adaptin and HSP70 in nasal polyp tissue from AS patients. CONCLUSION: Pooled samples of AS and AT nasal polyps evaluated by protein microarray show distinct protein expression profiles in the stress response and receptor-mediated endocytosis pathways. This study establishes the successful application of protein microarray technology to study nasal polyposis, which in turn can be validated by Western blot analysis.

Beta-NAP, a cerebellar degeneration antigen, is a neuron-specific vesicle coat protein.

We have identified a target antigen in autoimmune cerebellar degeneration, beta-NAP, that is closely related to the beta-adaptin and beta-COP coat proteins. Beta-NAP is a nonclathrin-associated phosphoprotein expressed exclusively in neurons, from E12 through adulthood. Beta-NAP is present in the neuronal soma and nerve terminal as soluble and membrane-bound pools and is associated with a discrete set of nerve-terminal vesicles. These results establish beta-NAP as a neuron-specific vesicle coat protein. We propose a model in which beta-NAP mediates vesicle transport between the soma and the axon terminus and suggest that beta-NAP may represent a general class of coat proteins that mediates apical transport in polarized cells.