ERAD of proteins containing aberrant transmembrane domains requires ubiquitylation of cytoplasmic lysine residues.

Clearance of misfolded proteins from the endoplasmic reticulum (ER) is mediated by the ubiquitin-proteasome system in a process known as ER-associated degradation (ERAD). The mechanisms through which proteins containing aberrant transmembrane domains are degraded by ERAD are poorly understood. To address this question, we generated model ERAD substrates based on CD8 with either a non-native transmembrane domain but a folded ER luminal domain (CD8(TMD*)), or the native transmembrane domain but a misfolded luminal domain (CD8(LUM*)). Although both chimeras were degraded by ERAD, we found that the location of the folding defect determined the initial site of ubiquitylation. Ubiquitylation of cytoplasmic lysine residues was required for the extraction of CD8(TMD*) from the ER membrane during ERAD, whereas CD8(LUM*) continued to be degraded in the absence of cytoplasmic lysine residues. Cytoplasmic lysine residues were also required for degradation of an additional ERAD substrate containing an unassembled transmembrane domain and when a non-native transmembrane domain was introduced into CD8(LUM*). Our results suggest that proteins with defective transmembrane domains are removed from the ER through a specific ERAD mechanism that depends upon ubiquitylation of cytoplasmic lysine residues.

Restoration of mutant bestrophin-1 expression, localisation and function in a polarised epithelial cell model.

Autosomal recessive bestrophinopathy (ARB) is a retinopathy caused by mutations in the bestrophin-1 protein, which is thought to function as a Ca2+-gated Cl- channel in the basolateral surface of the retinal pigment epithelium (RPE). Using a stably transfected polarised epithelial cell model, we show that four ARB mutant bestrophin-1 proteins were mislocalised and subjected to proteasomal degradation. In contrast to the wild-type bestrophin-1, each of the four mutant proteins also failed to conduct Cl- ions in transiently transfected cells as determined by whole-cell patch clamp. We demonstrate that a combination of two clinically approved drugs, bortezomib and 4-phenylbutyrate (4PBA), successfully restored the expression and localisation of all four ARB mutant bestrophin-1 proteins. Importantly, the Cl- conductance function of each of the mutant bestrophin-1 proteins was fully restored to that of wild-type bestrophin-1 by treatment of cells with 4PBA alone. The functional rescue achieved with 4PBA is significant because it suggests that this drug, which is already approved for long-term use in infants and adults, might represent a promising therapy for the treatment of ARB and other bestrophinopathies resulting from missense mutations in BEST1.

Isocorilagin, a cholinesterase inhibitor from Phyllanthus niruri.

Drugs that have dual inhibition of acetylcholinesterase (AChE) and butyrylcholinesterase (BChE) produce better clinical efficacy against Alzheimer's disease (AD) than those that selectively inhibit one enzyme. A dual cholinesterase inhibitory-guided fractionation of Phyllanthus niruri leaves afforded isocorilagin, a bioactive tannin possessing good inhibitory activities against AChE (IC50: 0.49 microM) and BChE (IC50: 4.20 microM). Interestingly, isocorilagin was relatively 2- to 3-fold more potent than galanthamine, the clinically used inhibitor. The kinetic analyses suggested that isocorilagin was a non-competitive inhibitor for AChE and an uncompetitive inhibitor for BChE, with calculated Ki values of 1.49 microM and 2.86 microM, respectively. In silico molecular docking revealed that isocorilagin effectively blocked the substrate entry by forming hydrogen bonding with residues at the entrance of the AChE active site. With BChE, the compound completely docked inside and occupied the active site of the enzyme. This study demonstrated for the first time the potent cholinesterase inhibitory activities of isocorilagin, a promising lead that is worthy of further investigation.