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PDBsum entry 4jb2
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Transport protein
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PDB id
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4jb2
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References listed in PDB file
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Key reference
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Title
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The coupstu and tarpqm transporters in rhodopseudomonas palustris: redundant, Promiscuous uptake systems for lignin-Derived aromatic substrates.
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Authors
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R.C.Salmon,
M.J.Cliff,
J.B.Rafferty,
D.J.Kelly.
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Ref.
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Plos One, 2013,
8,
e59844.
[DOI no: ]
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PubMed id
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Abstract
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The biodegradation of lignin, one of the most abundant carbon compounds on
Earth, has important biotechnological applications in the derivation of useful
products from lignocellulosic wastes. The purple photosynthetic bacterium
Rhodopseudomonas palustris is able to grow photoheterotrophically under
anaerobic conditions on a range of phenylpropeneoid lignin monomers, including
coumarate, ferulate, caffeate, and cinnamate. RPA1789 (CouP) is the periplasmic
binding-protein component of an ABC system (CouPSTU; RPA1789, RPA1791-1793),
which has previously been implicated in the active transport of this class of
aromatic substrate. Here, we show using both intrinsic tryptophan fluorescence
and isothermal titration calorimetry that CouP binds a range of phenylpropeneoid
ligands with K d values in the nanomolar range. The crystal structure of CouP
with ferulate as the bound ligand shows H-bond interactions between the 4-OH
group of the aromatic ring with His309 and Gln305. H-bonds are also made between
the carboxyl group on the ferulate side chain and Arg197, Ser222, and Thr102. An
additional transport system (TarPQM; RPA1782-1784), a member of the tripartite
ATP-independent periplasmic (TRAP) transporter family, is encoded at the same
locus as rpa1789 and several other genes involved in coumarate metabolism. We
show that the periplasmic binding-protein of this system (TarP; RPA1782) also
binds coumarate, ferulate, caffeate, and cinnamate with nanomolar K d values.
Thus, we conclude that R. palustris uses two redundant but energetically
distinct primary and secondary transporters that both employ high-affinity
periplasmic binding-proteins to maximise the uptake of lignin-derived aromatic
substrates from the environment. Our data provide a detailed thermodynamic and
structural basis for understanding the interaction of lignin-derived aromatic
substrates with proteins and will be of use in the further exploitation of the
flexible metabolism of R. palustris for anaerobic aromatic biotransformations.
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