Increased drug resistance to anti-malarials highlights the need for the development of new therapeutics for the treatment of malaria. To this end, the lactate dehydrogenase (LDH) gene was cloned and sequenced from genomic DNA of Plasmodium vivax ( PvLDH) Belem strain. The 316 amino acid protein-coding region of the PvLDH gene was inserted into the prokaryotic expression vector pKK223-3 and a 34 kDa protein with LDH activity was expressed in E. coli. Structural differences between human LDHs and PfLDH make the latter an attractive target for inhibitors leading to novel anti-malarial drugs. The sequence similarity between PvLDH and PfLDH (90% residue identity and no insertions or deletions) indicate that the same approach could be applied to Plasmodium vivax, the most common human malaria parasite in the world.
Biochemical studies have shown that domain 5 of the TrkA (tropomyosin receptor kinase A) receptor is involved in the binding of NGF (nerve growth factor). Crystallographic studies have confirmed this, demonstrating that one homodimer of NGF binds to two TrkAd5 molecules. TrkAd5 has been made recombinantly in Escherichia coli, purified and shown to bind NGF with picomolar affinity. We have used the co-ordinates of the crystal structure of the NGF-TrkAd5 complex to screen approximately two million compounds in silico for the identification of small molecule agonists/antagonists. Selected hits were shown to be active in an in vitro ligand-binding assay; structure-activity relationships are now being investigated. In addition, TrkAd5 has been shown to be efficacious in preclinical models of inflammatory pain and asthma by the sequestration of excess levels of endogenous NGF, and therefore represents a novel therapeutic agent.
The tyrosine kinase A (TrkA) receptor
is a validated therapeutic
intervention point for a wide range of conditions. TrkA activation
by nerve growth factor (NGF) binding the second extracellular immunoglobulin
(TrkAIg2) domain triggers intracellular signaling cascades. In the
periphery, this promotes the pain phenotype and, in the brain, cell
survival or differentiation. Reproducible structural information and
detailed validation of protein–ligand interactions aid drug
discovery. However, the isolated TrkAIg2 domain crystallizes as a β-strand-swapped
dimer in the absence of NGF, occluding the binding surface. Here we
report the design and structural validation by nuclear magnetic resonance
spectroscopy of the first stable, biologically active construct of
the TrkAIg2 domain for binding site confirmation. Our structure closely
mimics the wild-type fold of TrkAIg2 in complex with NGF (1WWW.pdb), and the 1H–15N correlation spectra confirm that both
NGF and a competing small molecule interact at the known binding interface
in solution.
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