Evolution of inhibitor-resistant natural mutant forms of HIV-1 protease probed by pre-steady state kinetic analysis.

Pre-steady state kinetic analysis of mechanistic features of substrate binding and processing is crucial for insight into the evolution of inhibitor-resistant forms of HIV-1 protease. These data may provide a correct vector for rational drug design assuming possible intrinsic dynamic effects. These data should also give some clues to the molecular mechanism of protease action and resistance to inhibitors. Here we report pre-steady state kinetics of the interaction of wild type or mutant forms of HIV-1 protease with a FRET-labeled peptide. The three-stage "minimal" kinetic scheme with first and second reversible steps of substrate binding and with following irreversible peptide cleavage step adequately described experimental data. For the first time, a set of "elementary" kinetic parameters of wild type HIV-1 protease and its natural mutant inhibitor-resistant forms MDR-HM, ANAM-11 and prDRV4 were compared. Inhibitors of the first and second generation were used to estimate the inhibitory effects on HIV-1 protease activity. The resulting set of kinetic data supported that the mutant forms are kinetically unaffected by inhibitors of the first generation, proving their functional resistance to these compounds. The second generation inhibitor darunavir inhibited mutant forms MDR-HM and ANAM-11, but was ineffective against prDRV4. Our kinetic data revealed that these inhibitors induced different conformational changes in the enzyme and, thereby they have different mode of binding in the enzyme active site. These data confirmed hypothesis that the driving force of the inhibitor-resistance evolution is disruption of enzyme-inhibitor complex by changing of the contact network in the inhibitor binding site.

Design of protein homocystamides with enhanced tumor uptake properties for (19)F magnetic resonance imaging.

Straightforward and reliable tools for in vivo imaging of tumors can benefit the studies of cancer development, as well as contribute to successful diagnosis and treatment of cancer. (19)F NMR offers an exceptional quantitative way of in vivo imaging of the infused agents because of the lack of (19)F signals from the endogenous molecules in the body. The purpose of this study is to develop molecular probes with appropriate NMR characteristics and the biocompatibility for in vivo applications using (19)F MRI. We have studied the reaction between perfluorotoluene and homocysteine thiolactone resulting in the formation of N-substituted homocysteine thiolactone derivative. It has been shown that the reaction occurs selectively at the para position. This fluorine-labeled homocysteine thiolactone has been employed for the introduction of a perfluorotoluene group as a (19)F-containing tag into human serum albumin. The modified protein has been studied in terms of its ability to aggregate and promote the formation of free radicals. By comparing the properties of N-perfluorotoluene-homocystamide of albumin with N-homocysteinylated albumin, it has been revealed that blocking of the alpha-amino group of the homocysteine residue in the fluorinated albumin conjugate inhibits the dangerous aggregation process, as well as free radical formation. A dual-labeled albumin-based molecular probe for (19)F MRI and fluorescence microscopy has been obtained by functionalizing the protein with both maleimide of a fluorescent dye and a fluorinated thiolactone derivative. The incubation of cells with this conjugate did not reveal any significant reduction in cell viability with respect to the parent albumin. The perfluorotoluene-labeled albumin has been demonstrated to act as a promising agent for in vivo (19)F MRI.

Synthesis and characterization of fluorinated homocysteine derivatives as potential molecular probes for ¹9F magnetic resonance spectroscopy and imaging.

A N-trifluoroacetyl-protected amino acid containing a thioester function, 2,2,2-trifluoro-N-(2-oxo-tetrahydrothiophen-3-yl)acetamide (TFA-tHcy), has been synthesized and characterized. It was then used to prepare a fluorine-labeled N-homocysteinylated protein, (19)F-Hcy-εN-Lys-albumin, that was characterized by SDS-PAGE, MALDI-TOF-MS, UV-vis and (19)F NMR spectroscopy. On average, four N-trifluoroacetylhomocysteine residues were covalently conjugated to human serum albumin through the N-substituted homocysteine thiolactone. The in situ homocysteinylation of human plasma proteins with TFA-tHcy has also been performed and has led to the formation of N-homocysteinylated proteins, with albumin modification accounting for ca. 75% of all fluorine-labeled human plasma proteins. The synthesized fluorinated molecular probes can be potentially used as informative molecular probes for in vivo (19)F magnetic resonance spectroscopy and imaging.

RNA-hydrolyzing activity of human serum albumin and its recombinant analogue.

The comparative analysis of RNA-hydrolyzing activity of albumin from human serum and albumin expressed in methylotrophic yeast Pichia pastoris has been carried out. The rate of polyribonucleotide phosphodiester bond cleavage in the presence of recombinant albumin has been found to be similar to that of the reaction mediated by the native protein. According to 31P NMR data, RNA hydrolysis follows the mechanism of intermolecular trans-esterification to yield 2',3'-cyclophosphodiester reaction products that are further slowly hydrolyzed to form nucleoside-3'- and nucleoside-2'-phosphates. Analysis of pH dependence suggests an acid-base mechanism of catalysis. The catalytic activity and substrate specificity of albumin in RNA hydrolysis distinguish it from human ribonucleases.

PELDOR study of conformations of double-spin-labeled single- and double-stranded DNA with non-nucleotide inserts.

DNA fragments were synthesized consisting of 12 nucleotides and containing non-nucleotide inserts of different length in the middle. Two nitroxide spin labels 4-amino-2,2,6,6-tetramethylpiperidine-1-oxyl were attached at the two ends of the molecules. Single-stranded DNAs and double-stranded DNAs (DNA duplexes) in frozen at 77 K glassy water/glycerol solutions were studied using pulsed electron-electron double resonance (PELDOR). The distance distributions between two spin labels in molecules were obtained from PELDOR data using Tikhonov regularization algorithm, and were found to be close to the Gaussian functions. Experimental PELDOR data were fitted by adjusting precisely the maximum position and the width of these functions. The obtained results show that duplexes possess a substantially narrower distribution, as compared to the single-stranded DNAs. Introduction of a non-nucleotide insert 2-hydroxymethyl-3-hydroxy-tetrahydrofuran leads to a slight but nevertheless detectable decrease of the mean distance between two spin labels. This decrease may be attributed to bending of the molecule around the insert site, by an angle of approximately 20 degrees . An introduction of a non-nucleotide insert bis-(di-ethyleneglycol)-phosphate results in a remarkable broadening of the distance distribution. The results evidence that PELDOR of spin-labeled DNA molecules may be used as a "molecular ruler" for studying the influence of local damages on the DNA conformations.

Substrate recognition of anthrax lethal factor examined by combinatorial and pre-steady-state kinetic approaches.

Lethal factor (LF), a zinc-dependent protease of high specificity produced by Bacillus anthracis, is the effector component of the binary toxin that causes death in anthrax. New therapeutics targeting the toxin are required to reduce systemic anthrax-related fatalities. In particular, new insights into the LF catalytic mechanism will be useful for the development of LF inhibitors. We evaluated the minimal length required for formation of bona fide LF substrates using substrate phage display. Phage-based selection yielded a substrate that is cleaved seven times more efficiently by LF than the peptide targeted in the protein kinase MKK6. Site-directed mutagenesis within the metal-binding site in the LF active center and within phage-selected substrates revealed a complex pattern of LF-substrate interactions. The elementary steps of LF-mediated proteolysis were resolved by the stopped-flow technique. Pre-steady-state kinetics of LF proteolysis followed a four-step mechanism as follows: initial substrate binding, rearrangement of the enzyme-substrate complex, a rate-limiting cleavage step, and product release. Examination of LF interactions with metal ions revealed an unexpected activation of the protease by Ca(2+) and Mn(2+). Based on the available structural and kinetic data, we propose a model for LF-substrate interaction. Resolution of the kinetic and structural parameters governing LF activity may be exploited to design new LF inhibitors.