Modern approaches to chemical toxicity screening

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Folding control and unfolding free energy of yeast iso-1-cytochrome c bound to layered zirconium phosphate materials monitored by surface plasmon resonance

The free energy change (Delta G degrees ) for the unfolding of immobilized yeast iso-1-cytochrome c (Cyt c) at nanoassemblies was measured by surface plasmon resonance (SPR) spectroscopy. Data show that SPR is sensitive to protein conformational changes, and protein solid interface exerts a major influence on bound protein stability. First, Cyt c was self-assembled on the Au film via the single thiol of Cys-102. Then, crystalline sheets of layered alpha-Zr(O(3)POH)(2).H(2)O (alpha-ZrP) or Zr(O(3)PCH(2)CH(2)COOH)(2).xH(2)O (alpha-ZrCEP) were adsorbed to construct alpha-ZrP/Cyt c/Au or alpha-ZrCEP/Cyt c/Au nanoassemblies. The construction of each layer was monitored by SPR, in real time, and the assemblies were further characterized by atomic force microscopy and electrochemical studies. Thermodynamic stability of the protein nanoassembly was assessed by urea-induced unfolding. Surprisingly, unfolding is reversible in all cases studied here. Stability of Cyt c in alpha-ZrP/Cyt c/Au increased by approximately 4.3 kJ/mol when compared to the unfolding free energy of Cyt c/Au assembly. In contrast, the protein stability decreased by approximately 1.5 kJ/mol for alpha-ZrCEP/Cyt c/Au layer. Thus, OH-decorated surfaces stabilized the protein whereas COOH-decorated surfaces destabilized it. These data quantitate the role of specific functional groups of the inorganic layers in controlling bound protein stability.     

Biochemical applications of ultrathin films of enzymes, polyions and DNA

This feature article summarizes recent applications of ultrathin films of enzymes and DNA assembled layer-by-layer (LbL). Using examples mainly from our own research, we focus on systems developed for biocatalysis and biosensors for toxicity screening. Enzyme-poly(L-lysine) (PLL) films, especially when stabilized by crosslinking, can be used for biocatalysis at unprecedented high temperatures or in acidic or basic solutions on electrodes or sub-micron sized beads. Such films have bright prospects for chiral synthesis and biofuel cells. Excellent bioactivity and retention of enzyme structure in these films facilitates their use in detailed kinetic studies. Biosensors and arrays employing DNA-enzyme films show great promise in predicting genotoxicity of new drug and chemical product candidates. These devices combine metabolic biocatalysis, reactive metabolite-DNA reactions, and DNA damage detection. Catalytic voltammetry or electrochemiluminescence (ECL) can be used for high throughput arrays utilizing multiple LbL "spots" of DNA, enzyme and metallopolymer. DNA-enzyme films can also be used to produce nucleobase adduct toxicity biomarkers for detection by LC-MS. These approaches provide valuable high throughput tools for drug and chemical product development and toxicity prediction.     

Minor groove binding of a novel tetracationic diviologen

Novel tetracationic diviologen compounds of the general formula CH3(CH2)nV2+(CH2)6V2+(CH2)nCH3 (where V2+ = 4,4'-bipyridinium and n = 5 or 11) were investigated as electrochemical reporters of DNA duplex formation. These compounds bind to both single-stranded DNA (ssDNA) and double-stranded DNA (dsDNA) when the DNA is either present in solution or immobilized at electrode surfaces. Binding to thiolated ssDNA and dsDNA immobilized at Au electrodes was characterized using the electrochemical response for the reduction of the V2+ state to the V+ (viologen radical cation) state. An analysis of the charge for this reduction provided isotherms and binding constants for binding of these diviologens to both forms of immobilized DNA. Saturation of the binding is achieved at solution concentrations near 20 microM. For both the n = 5 and 11 diviologens, binding to ssDNA is driven by electrostatic charge neutralization. For the n = 11 case, the binding is cooperative. In the presence of dsDNA, the n = 11 diviologen exhibits a unique reduction potential for the V2+/+ redox couple that is shifted approximately 100 mV negative of that in the presence of ssDNA. This new electrochemical signature is attributed to the reduction of viologen groups bound in the minor groove of the DNA duplex. For dsDNA in solution, an increase in the thermal denaturation temperature (Tm) from 60 to 66 degrees C as a function of the n = 11 diviologen concentration confirmed its interaction with the duplex. Circular dichroism (CD) spectroscopy also was used to investigate the binding of both the V2+ and V+ redox states of the n = 11 diviologen to dsDNA in solution. For the V+ state, a CD signal was observed that is consistent with the presence of face-to-face pi dimers of the viologen groups. This unambiguously demonstrates the binding of this redox state of the diviologen in the dsDNA minor groove and the formation of such dimers in the minor groove.     

Genotoxicity screening for N-nitroso compounds. Electrochemical and electrochemiluminescent detection of human enzyme-generated DNA damage from N-nitrosopyrrolidine

We report for the first time voltammetric/electrochemiluminescent sensors applied to predict genotoxicity of N-nitroso compounds bioactivated by human cytochrome P450 enzymes.