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PDBsum entry 5fmg
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Contents |
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219 a.a.
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212 a.a.
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220 a.a.
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215 a.a.
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217 a.a.
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219 a.a.
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219 a.a.
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191 a.a.
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186 a.a.
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191 a.a.
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194 a.a.
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189 a.a.
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199 a.a.
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187 a.a.
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References listed in PDB file
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Key reference
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Title
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Structure- And function-Based design of plasmodium-Selective proteasome inhibitors.
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Authors
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H.Li,
A.J.O'Donoghue,
W.A.Van der linden,
S.C.Xie,
E.Yoo,
I.T.Foe,
L.Tilley,
C.S.Craik,
P.C.Da fonseca,
M.Bogyo.
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Ref.
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Nature, 2016,
530,
233-236.
[DOI no: ]
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PubMed id
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Abstract
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The proteasome is a multi-component protease complex responsible for regulating
key processes such as the cell cycle and antigen presentation. Compounds that
target the proteasome are potentially valuable tools for the treatment of
pathogens that depend on proteasome function for survival and replication. In
particular, proteasome inhibitors have been shown to be toxic for the malaria
parasite Plasmodium falciparum at all stages of its life cycle. Most compounds
that have been tested against the parasite also inhibit the mammalian
proteasome, resulting in toxicity that precludes their use as therapeutic
agents. Therefore, better definition of the substrate specificity and structural
properties of the Plasmodium proteasome could enable the development of
compounds with sufficient selectivity to allow their use as anti-malarial
agents. To accomplish this goal, here we use a substrate profiling method to
uncover differences in the specificities of the human and P. falciparum
proteasome. We design inhibitors based on amino-acid preferences specific to the
parasite proteasome, and find that they preferentially inhibit the β2-subunit.
We determine the structure of the P. falciparum 20S proteasome bound to the
inhibitor using cryo-electron microscopy and single-particle analysis, to a
resolution of 3.6 Å. These data reveal the unusually open P. falciparum β2
active site and provide valuable information about active-site architecture that
can be used to further refine inhibitor design. Furthermore, consistent with the
recent finding that the proteasome is important for stress pathways associated
with resistance of artemisinin family anti-malarials, we observe growth
inhibition synergism with low doses of this β2-selective inhibitor in
artemisinin-sensitive and -resistant parasites. Finally, we demonstrate that a
parasite-selective inhibitor could be used to attenuate parasite growth in vivo
without appreciable toxicity to the host. Thus, the Plasmodium proteasome is a
chemically tractable target that could be exploited by next-generation
anti-malarial agents.
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