An expression of an insect membrane-bound cytochrome P450 CYP6AA3 in the Escherichia coli in relation to insecticide resistance in a malarial vector.

This laboratory investigation was carried out at the Faculty of Sciences, Mahidol University, Thailand during October 2007 to May 2009. The objectives of this study include: the search for heterologous expression of the cytochrome P450 CYP6AA3 enzyme of the Anopheles minimus mosquitoes in relation to Malaria disease and to provide some information on molecular mechanism of insects' pyrethroid resistance. The polymerase chain reaction aided by the Pfu DNA polymerase and some specific generated primers were used to modify the CYP6AA3 gene. The PCR product was ligated with a predigested pET-3a at the NdeI and BamHI restriction sites. The modified CYP6AA3 enzyme was expressed in the Escherichia coli BL21 (DE3) pLysS in order to achieve a high amount of soluble form of its expression. The results showed that the use of the isopropyl-beta-D-thiogalactopyranoside (IPTG) and incubation together with ferric chloride and delta-aminolevulinic acid did not increase any soluble form of the CYP6AA3 enzyme. A significant amount of soluble enzyme was produced upon the replacement of the 30 N-terminal residues with a short peptide where it gave Ldelta30CYP6AA3 protein and after purification process was taken place, it yielded up to 10.64 mg 10 L(-1) or approximately 1 mg L(-1) of the homogenous Ldelta30CYP6AA3. When this purified Ldelta30CYP6AA3 protein was used in a metabolizing process with the cypermethrin, deltamethrin and permethrin substrates, it gave their apparent Km values for cypermethrin and deltamethrin of 12.5 and 23.5 microM, respectively. The heterologous expression carried out with the use of the E. coli gave a high amount of soluble CYP6AA3 enzyme of the An. minimus mosquitoes hence the modified technique being used was successfully achieved.

A simple dual selection for functionally active mutants of Plasmodium falciparum dihydrofolate reductase with improved solubility.

Sufficient solubility of the active protein in aqueous solution is a prerequisite for crystallization and other structural studies of proteins. In this study, we have developed a simple and effective in vivo screening system to select for functionally active proteins with increased solubility by using Plasmodium falciparum dihydrofolate reductase (pfDHFR), a well-known malarial drug target, as a model. Prior to the dual selection process, pfDHFR was fused to green fluorescent protein (GFP), which served as a reporter for solubility. The fusion gene was used as a template for construction of mutated DNA libraries of pfDHFR. Two amino acids with large hydrophobic side chains (Y35 and F37) located on the surface of pfDHFR were selected for site-specific mutagenesis. Additionally, the entire pfDHFR gene was randomly mutated using error-prone PCR. During the first step of the dual selection, mutants with functionally active pfDHFR were selected from two libraries by using bacterial complementation assay. Fluorescence signals of active mutants were subsequently measured and five mutants with increased GFP signal, namely Y35Q + F37R, Y35L + F37T, Y35G + F37L and Y35L + F37R from the site-specific mutant library and K27E from the random mutant library, were recovered. The mutants were expressed, purified and characterized as monofunctional pfDHFR following excision of GFP. Our studies indicated that all mutant pfDHFRs exhibited kinetic properties similar to that of the wild-type protein. For comparison of protein solubility, the maximum concentrations of mutant enzymes prior to aggregation were determined. All mutants selected in this study exhibited 3- to 6-fold increases in protein solubility compared with the wild-type protein, which readily aggregated at 2 mg/ml. The dual selection system we have developed should be useful for engineering functionally active protein mutants with sufficient solubility for functional/structural studies and other applications.

Malarial (Plasmodium falciparum) dihydrofolate reductase-thymidylate synthase: structural basis for antifolate resistance and development of effective inhibitors.

Dihydrofolate reductase-thymidylate synthase (DHFR-TS) from Plasmodium falciparum, a validated target for antifolate antimalarials, is a dimeric enzyme with interdomain interactions significantly mediated by the junction region as well as the Plasmodium-specific additional sequences (inserts) in the DHFR domain. The X-ray structures of both the wild-type and mutant enzymes associated with drug resistance, in complex with either a drug which lost, or which still retains, effectiveness for the mutants, reveal features which explain the basis of drug resistance resulting from mutations around the active site. Binding of rigid inhibitors like pyrimethamine and cycloguanil to the enzyme active site is affected by steric conflict with the side-chains of mutated residues 108 and 16, as well as by changes in the main chain configuration. The role of important residues on binding of inhibitors and substrates was further elucidated by site-directed and random mutagenesis studies. Guided by the active site structure and modes of inhibitor binding, new inhibitors with high affinity against both wild-type and mutant enzymes have been designed and synthesized, some of which have very potent anti-malarial activities against drug-resistant P. falciparum bearing the mutant enzymes.

Crystal structure of the dual specificity protein phosphatase VHR.

Dual specificity protein phosphatases (DSPs) regulate mitogenic signal transduction and control the cell cycle. Here, the crystal structure of a human DSP, vaccinia H1-related phosphatase (or VHR), was determined at 2.1 angstrom resolution. A shallow active site pocket in VHR allows for the hydrolysis of phosphorylated serine, threonine, or tyrosine protein residues, whereas the deeper active site of protein tyrosine phosphatases (PTPs) restricts substrate specificity to only phosphotyrosine. Positively charged crevices near the active site may explain the enzyme's preference for substrates with two phosphorylated residues. The VHR structure defines a conserved structural scaffold for both DSPs and PTPs. A "recognition region," connecting helix alpha1 to strand beta1, may determine differences in substrate specificity between VHR, the PTPs, and other DSPs.

The purification and characterization of a human dual-specific protein tyrosine phosphatase.

An expression and purification method was developed to obtain the recombinant human dual-specific protein tyrosine phosphatase (PTPase) VHR in quantities suitable for both kinetic studies and crystallization. Physical characterization of the homogeneous recombinant protein verified the mass to be 20,500 +/- 100 by matrix-assisted laser desorption mass spectrometry, confirmed the anticipated NH2-terminal amino acid sequence and demonstrated that the protein exists as a monomer. Conditions were developed to obtain crystals which were suitable for x-ray structure determination. Using synthetic diphosphorylated peptides corresponding to MAP177-189 (mitogen-activated protein) kinase (DHTG-FLpTEpYVATR), an assay was devised which permitted the determination of the rate constants for dephosphorylation of the diphosphorylated peptide on threonine and tyrosine residues. The diphosphorylated peptides are preferred over the singly phosphorylated on tyrosine by 3-8-fold. The apparent second-order rate constant kcat/Km for dephosphorylation of phosphotyrosine on DHTGFLpTEpYVATR was 32,000 M-1 S-1 while dephosphorylation of phosphothreonine was 14 M-1 S-1 (pH 6). The reaction of DHTGFLpTEpYVATR with VHR is ordered, with rapid dephosphorylation on tyrosine occurring first followed by slow dephosphorylation on threonine. Similar results were obtained with F(NLe)(N-Le)pTPpYVVTR, a peptide corresponding to a MAP kinase-like protein (JNK1(180-189)) which is involved in the stress response signaling pathway.