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双功能酶 DmpFG 中反应中间体的生物沟道化。

Biological channeling of a reactive intermediate in the bifunctional enzyme DmpFG.

机构信息

School of Chemistry and Biochemistry, The University of Western Australia, Perth, Western Australia.

出版信息

Biophys J. 2012 Feb 22;102(4):868-77. doi: 10.1016/j.bpj.2012.01.029. Epub 2012 Feb 21.

DOI:10.1016/j.bpj.2012.01.029
PMID:22385858
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3283820/
Abstract

It has been hypothesized that the bifunctional enzyme DmpFG channels its intermediate, acetaldehyde, from one active site to the next using a buried intermolecular channel identified in the crystal structure. This channel appears to switch between an open and a closed conformation depending on whether the coenzyme NAD(+) is present or absent. Here, we applied molecular dynamics and metadynamics to investigate channeling within DmpFG in both the presence and absence of NAD(+). We found that substrate channeling within this enzyme is energetically feasible in the presence of NAD(+) but was less likely in its absence. Tyr-291, a proposed control point at the channel's entry, does not appear to function as a molecular gate. Instead, it is thought to orientate the substrate 4-hydroxy-2-ketovalerate in DmpG before reaction occurs, and may function as a proton shuttle for the DmpG reaction. Three hydrophobic residues at the channel's exit appear to have an important role in controlling the entry of acetaldehyde into the DmpF active site.

摘要

据推测,双功能酶 DmpFG 使用晶体结构中鉴定出的埋藏于分子间的通道,将其中间产物乙醛从一个活性部位传送到下一个活性部位。该通道似乎根据辅酶 NAD(+)的存在与否在开和闭构象之间切换。在这里,我们应用分子动力学和元动力学方法研究了有或没有 NAD(+)时 DmpFG 内的通道作用。我们发现,在存在 NAD(+)的情况下,该酶内的底物通道作用在能量上是可行的,但在没有 NAD(+)的情况下则不太可能。Tyr-291 是通道入口处的一个拟议控制点,似乎不起分子门的作用。相反,它被认为在 DmpG 中的反应发生之前将底物 4-羟基-2-酮戊酸定向在 DmpG 中,并且可能作为 DmpG 反应的质子穿梭。通道出口处的三个疏水性残基似乎在控制乙醛进入 DmpF 活性部位方面起着重要作用。

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