Impact of site-directed mutant luciferase on quantitative green and orange/red emission intensities in firefly bioluminescence.

Firefly bioluminescence has attracted great interest because of its high quantum yield and intriguing modifiable colours. Modifications to the structure of the enzyme luciferase can change the emission colour of firefly bioluminescence, and the mechanism of the colour change has been intensively studied by biochemists, structural biologists, optical physicists, and quantum-chemistry theorists. Here, we report on the quantitative spectra of firefly bioluminescence catalysed by wild-type and four site-directed mutant luciferases. While the mutation caused different emission spectra, the spectra differed only in the intensity of the green component (λmax ~ 560 nm). In contrast, the orange (λmax ~ 610 nm) and red (λmax ~ 650 nm) components present in all the spectra were almost unaffected by the modifications to the luciferases and changes in pH. Our results reveal that the intensity of the green component is the unique factor that is influenced by the luciferase structure and other reaction conditions.

Deleting two C-terminal alpha-helices is effective to crystallize the bacterial ABC transporter Escherichia coli MsbA complexed with AMP-PNP.

An MsbA deletion mutant DeltaC21 that lacks the two C-terminal alpha-helices was expressed in Escherichia coli strain C41 and purified by metal-affinity and gel-filtration chromatography. Purified DeltaC21 retained 26% of the activity of the wild-type ATPase and had a similar binding affinity to fluorescent nucleotide derivatives. Although crystals of wild-type MsbA complexed with adenosine 5'-(beta,gamma-imido)triphosphate could not be obtained, crystals of DeltaC21 that diffracted to 4.5 A resolution were obtained. The preliminary DeltaC21 structure had the outward-facing conformation, in contrast to the previously reported E. coli MsbA structure. This result suggests that deletion of the C-terminal alpha-helices may play a role in facilitating the outward-facing nucleotide-bound crystal structure of EcMsbA.

Improved expression and purification of human multidrug resistance protein MDR1 from baculovirus-infected insect cells.

Multidrug resistance protein MDR1 (P-glycoprotein/ABCB1) is an ATP-dependent efflux pump for various cytotoxic agents, and is implicated in the resistance of human tumors to chemotherapeutic drugs. To achieve the three-dimensional structural analysis for its mechanistic implications, large amounts of high-quality and homogeneous MDR1 protein are essential. Here we report a cost-effective method for large-scale expression of human MDR1 using a baculovirus/insect expressSF+ cell system and an alterative purification method to maintain MDR1 in a monodispersed state. After extensively optimizing the detergent, pH, and additives, a high yield (2.8 mg/L) of purified MDR1 was obtained by immobilized metal chelate affinity and size-exclusion chromatographies with 49% recovery. The purified MDR1 exhibited specific ATP hydrolase activity (1.7 micromol/min/mg) in the presence of a substrate, verapamil. This value was 14-fold greater than the basal activity without the drug. Size-exclusion chromatography analysis of purified MDR1 showed a monodispersed elution profile. The present purification method provides suitable material for structural and functional studies on human MDR1.

Molecular characterization and antifungal activity of a family 46 chitosanase from Amycolatopsis sp. CsO-2.

An actinomycete strain, Amycolatopsis sp. CsO-2, produces a 27-kDa chitosanase. To reveal the molecular characteristics of the enzyme, its corresponding gene ctoA was cloned by a reverse genetic technique, based on the N-terminal amino acid sequence of the protein. The encoded CtoA protein was deduced to be composed of 286 amino acids, including a putative signal peptide (1-48), and exhibited 83% identity in the amino acid sequence with the family 46 chitosanases from Streptomyces sp. N174 or Nocardioides sp. N106. The active recombinant CtoA protein was successfully overproduced in Escherichia coli. The mutant protein E22Q, in which the glutamic acid residue 22 was replaced with glutamine, abolished the chitosanase activity, showing that the Glu22 residue is required for the enzymatic activity. CtoA exhibited antifungal activity against Rhizopus oryzae, which is known to produce chitosan probably as a cell wall component. In contrast, E22Q did not inhibit the growth of the fungus, suggesting that chitosan-hydrolyzing activity is essential for the antifungal activity. It is noteworthy that the antifungal effect of CtoA against R. oryzae was drastically enhanced by the simultaneous addition of the family 19 chitinase ChiC from Streptomyces griseus.

Dynamic mechanism for the serpin loop insertion as revealed by quantitative kinetics.

The serpin conformational change by insertion of the reactive center loop into beta-sheet A plays a central role in multiple physiological consequences such as serine proteinase inhibition, latency and serpinopathic polymerization. To study the dynamic mechanism for the loop insertion, a novel kinetic method was established utilizing the ovalbumin mutant R339T/A352R; the loop insertion progressed after the cleavage of P1-P1' (Arg352-Ser353) by trypsin was quenched at pH 8 and 0.5 degrees C, and different conformers were quantified by separation using ion-exchange HPLC. The apparent first-order rate constant k(app) determined for various R339T/A352R derivatives differing in conformational stability was greatly increased by lowering the pH. The pH-dependence of k(app) indicated that the protonation of side-chain(s) with a pK(a) value of around 4.6 is a pre-requisite for the loop insertion. The theoretical rate constant k for the protonated form calculated from k(app) was highly variable, depending on the ovalbumin derivative; structural modifications that give increased mobility to helix F and the sheet-A half (s3A/s2A/s1A) resulted in a striking increase in the loop insertion rate constant k. The k values were determined at different temperatures for all the ovalbumin derivatives, and DeltaH(double dagger) and DeltaS(double dagger) values for the loop insertion reaction were determined according to the transition theory. The formation of the transition state was highly endothermic with minor entropy gain, requiring a DeltaG(double dagger) larger than 18 kcal/mol, which can offset the hydrogen-bond cleavages between s3A and s5A. These results are consistent with the transition state with an opened sheet A and altered orientation of helix F.