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Target Concepts:
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Query: UMLS:C0848283 (
rundown
)
502
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Human
bestrophin
-1 (hBest1), which is genetically linked to several kinds of retinopathy and macular degeneration in both humans and dogs, is the founding member of a family of Cl(-) ion channels that are activated by intracellular Ca(2+). At present, the structures and mechanisms responsible for Ca(2+) sensing remain unknown. Here, we have used a combination of molecular modeling, density functional-binding energy calculations, mutagenesis, and patch clamp to identify the regions of hBest1 involved in Ca(2+) sensing. We identified a cluster of a five contiguous acidic amino acids in the C terminus immediately after the last transmembrane domain, followed by an EF hand and another regulatory domain that are essential for Ca(2+) sensing by hBest1. The cluster of five amino acids (293-308) is crucial for normal channel gating by Ca(2+) because all but two of the 35 mutations we made in this region rendered the channel incapable of being activated by Ca(2+). Using homology models built on the crystal structure of calmodulin (CaM), an EF hand (EF1) was identified in hBest1. EF1 was predicted to bind Ca(2+) with a slightly higher affinity than the third EF hand of CaM and lower affinity than the second EF hand of troponin C. As predicted by the model, the D312G mutation in the putative Ca(2+)-binding loop (312-323) reduced the apparent Ca(2+) affinity by 20-fold. In addition, the D312G and D323N mutations abolished Ca(2+)-dependent
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of the current. Furthermore, analysis of truncation mutants of hBest1 identified a domain adjacent to EF1 that is rich in acidic amino acids (350-390) that is required for Ca(2+) activation and plays a role in current
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. These experiments identify a region of hBest1 (312-323) that is involved in the gating of hBest1 by Ca(2+) and suggest a model in which Ca(2+) binding to EF1 activates the channel in a process that requires the acidic domain (293-308) and another regulatory domain (350-390). Many of the approximately 100 disease-causing mutations in hBest1 are located in this region that we have implicated in Ca(2+) sensing, suggesting that these mutations disrupt hBest1 channel gating by Ca(2+).
...
PMID:Regulation of bestrophin Cl channels by calcium: role of the C terminus. 1902 75
Bestrophin proteins are calcium (Ca
2+
)-activated chloride channels. Mutations in
bestrophin 1
(
BEST1
) cause macular degenerative disorders. Whole-cell recordings show that ionic currents through
BEST1
run down over time, but it is unclear whether this behavior is intrinsic to the channel or the result of cellular factors. Here, using planar lipid bilayer recordings of purified
BEST1
, we show that current
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is an inherent property of the channel that can now be characterized as inactivation. Inactivation depends on the cytosolic concentration of Ca
2+
, such that higher concentrations stimulate inactivation. We identify a C-terminal inactivation peptide that is necessary for inactivation and dynamically interacts with a receptor site on the channel. Alterations of the peptide or its receptor dramatically reduce inactivation. Unlike inactivation peptides of voltage-gated channels that bind within the ion pore, the receptor for the inactivation peptide is on the cytosolic surface of the channel and separated from the pore. Biochemical, structural, and electrophysiological analyses indicate that binding of the peptide to its receptor promotes inactivation, whereas dissociation prevents it. Using additional mutational studies we find that the "neck" constriction of the pore, which we have previously shown to act as the Ca
2+
-dependent activation gate, also functions as the inactivation gate. Our results indicate that unlike a ball-and-chain inactivation mechanism involving physical occlusion of the pore, inactivation in
BEST1
occurs through an allosteric mechanism wherein binding of a peptide to a surface-exposed receptor controls a structurally distant gate.
...
PMID:An allosteric mechanism of inactivation in the calcium-dependent chloride channel BEST1. 3032 84
