2018
DOI: 10.1002/prot.25597
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Comparative study of the effect of disease causing and benign mutations in position Q92 on cholesterol binding by the NPC1 n‐terminal domain

Abstract: The Niemann-Pick type C1 (NPC1) protein is a large transmembrane protein located in lysosomes/endosomes. NPC1 binds cholesterol (CLR) and transports it to cellular membrane and endoplasmic reticulum. Mutations in NPC1 cause Niemann-Pick type C (NPC) disease, a rare autosomal disorder characterized by intracellular accumulations of CLR and subsequent neurodegeneration leading to premature death. Among known disease-causing mutations in NPC1, Q92R is the one that is located in the N-terminal cholesterol-binding … Show more

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Cited by 4 publications
(8 citation statements)
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“…[35] On the other hands, the computer simulation with NTD protein and its two mutations (Q92R and Q92S) shows the importance of correct electrostatic distribution near the entrance of cholesterol pocket as well as structural stability for suitable binding cholesterol to NTD. [36] In combination with experiment, the molecular dynamics simulation of L472P mutation indicates disruption of the tunnel between MLD and CTD that is believed to play essential role for cholesterol transport as mentioned earlier. [27] Since it was pointed that the R518W mutation decrease cholesterol transfer activity not because of misfolding of NPC1 but because of the functional defection of NPC1, [12] the atomic level detailed mechanism behind this defective functionality could provide insights on the structure and functional relationship of NPC1, especially its interaction with NPC2.…”
Section: Introductionmentioning
confidence: 74%
“…[35] On the other hands, the computer simulation with NTD protein and its two mutations (Q92R and Q92S) shows the importance of correct electrostatic distribution near the entrance of cholesterol pocket as well as structural stability for suitable binding cholesterol to NTD. [36] In combination with experiment, the molecular dynamics simulation of L472P mutation indicates disruption of the tunnel between MLD and CTD that is believed to play essential role for cholesterol transport as mentioned earlier. [27] Since it was pointed that the R518W mutation decrease cholesterol transfer activity not because of misfolding of NPC1 but because of the functional defection of NPC1, [12] the atomic level detailed mechanism behind this defective functionality could provide insights on the structure and functional relationship of NPC1, especially its interaction with NPC2.…”
Section: Introductionmentioning
confidence: 74%
“…Those residues have been implicated in control of the sterol transfer between NPC1–NTD and NPC2. ,, However, it is important to note that there are also residues in NPC1–NTD whose mutation leads to an NPC disease phenotype and which have no counterparts in NPC1L1–NTD. For example, Q92, which corresponds to A108 in NPC1L1–NTD, is located next to the pocket entrance (Figure S12), where it stabilizes the opening and overall structure of the NPC1–NTD binding pose . Mutations Q92R and Q92S in NPC1–NTD are known to give a severe clinical phenotype. , It is likely that the majority of these nonconserved residues leading to NPC disease is involved in docking to or sterol transfer from NPC2 or plays other functional roles apart from sterol binding.…”
Section: Discussionmentioning
confidence: 99%
“…RMSD/RMSF Analysis. Once the production phase of MD simulations for each of the systems was finished, the snapshots were aligned in a way to minimize RMSF of all cysteine residues within the snapshot 26 (as they were shown to be important in supporting the protein structure by forming cysteine bridges 8 ). Aligned snapshots allowed generating the average protein structure.…”
Section: ■ Computational Methodsmentioning
confidence: 99%
“…NPC2-NPC1 interaction promotes the CLR transfer from NPC2 to NPC1 by facilitating reorientation of the helical subdomain, enlarging opening (“S-opening”) of the CLR-binding pocket in NPC1 and thus releasing CLR. ,,,, The type of interaction between NPC1 and NPC2 for CLR transport was termed a “hydrophobic hand-off” or “sliding” transfer model, where close NPC2-NPC1 interaction allows CLR transfer from NPC2 to NPC1­(NTD) without being exposed to the water phase. , NTD binds the 3β-hydroxyl site of CLR facing the interior of the domain and the iso-octyl side chain exposed, which is opposite to orientation of CLR when bound by NPC2. ,, NPC1­(NTD) is located in the luminal part of endosomes/lysosomes, , where pH is in a range of 4.0–6.5 and CLR transport from NPC2 to NPC1 is pH dependentit is twice slower at pH = 7.0 compared to pH = 5.5 . Previously, we demonstrated that the Q92 residue in NTD is crucial in CLR transfer from NPC2 to NPC1 as it provides the favorable electrostatic environment between proteins . Both MLD and CTD interact with the NTD and thus modulate its activity. , …”
Section: Introductionmentioning
confidence: 99%
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