Kinetic magnetic-field effect involving the small biologically relevant inorganic radicals NO and O2(·-).

Oxidation of dihydrorhodamine 123 (DHR) to rhodamine 123 (RH) by oxoperoxonitrite (ONOO(-)), formed through recombination of NO and O(2)(·-) radicals resulting from thermal decomposition of 3-morpholinosydnonimine (SIN-1) in buffered aerated aqueous solution at pH 7.6, represents a kinetic model system of the reactivity of NO and O(2)(·-) in biochemical systems. A magnetic-field effect (MFE) on the yield of RH detected in this system is explored in the full range of fields between 0 and 18 T. It is found to increase in a nearly linear fashion up to a value of 5.5±1.6 % at 18 T and 23 °C (3.1±0.7 % at 40 °C). A theoretical framework to analyze the MFE in terms of the magnetic-field-enhanced recombination rate constant k(rec) of NO and O(2)(·-) due to magnetic mixing of T(0) and S spin states of the radical pair by the Δg mechanism is developed, including estimation of magnetic properties (g tensor and spin relaxation times) of NO and O(2)(·-) in aqueous solution, and calculation of the MFE on k(rec) using the theoretical formalism of Gorelik at al. The factor with which the MFE on k(rec) is translated to the MFE on the yield of ONOO(-) and RH is derived for various kinetic scenarios representing possible sink channels for NO and O(2)(·-). With reasonable assumptions for the values of some unknown kinetic parameters, the theoretical predictions account well for the observed MFE.

Stability and reactivity of free radicals: a physicochemical perspective with biological implications.

Several factors control the reactivity of radicals and can provide the strategies to convert highly reactive species into more persistent species that are easier to detect in an experiment. A reaction can only proceed if sufficient mobility and thermodynamic driving force are provided and the reaction is allowed by steric considerations and by electronic states of the reagents and products. A violation of at least one of these conditions can make the radical relatively stable. In certain cases, these factors occur naturally, in other situations, they can be purposefully manipulated to reduce the reactivity of highly reactive radicals, prolonging their lifetime and increasing their concentration. The discussed examples cover a vast range of lifetimes, from 10(-9) seconds to 10(9) years, at concentration levels down to 10(3) radicals per sample (10(-18) M), and stress that stability and reactivity are not independent notions and are the two sides of the same coin.

The role of Sp1 in the detection and elimination of cells with persistent DNA strand breaks.

Maintenance of genome stability suppresses cancer and other human diseases and is critical for organism survival. Inevitably, during a life span, multiple DNA lesions can arise due to the inherent instability of DNA molecules or due to endogenous or exogenous DNA damaging factors. To avoid malignant transformation of cells with damaged DNA, multiple mechanisms have evolved to repair DNA or to detect and eradicate cells accumulating unrepaired DNA damage. In this review, we discuss recent findings on the role of Sp1 (specificity factor 1) in the detection and elimination of cells accumulating persistent DNA strand breaks. We also discuss how this mechanism may contribute to the maintenance of physiological populations of healthy cells in an organism, thus preventing cancer formation, and the possible application of these findings in cancer therapy.

Sp1-independent downregulation of NHEJ in response to BER deficiency.

Base excision repair (BER) is the major repair pathway that removes DNA single strand breaks (SSBs) arising spontaneously due to the inherent instability of DNA. Unrepaired SSBs promote cell-cycle delay, which facilitates DNA repair prior to replication. On the other hand, in response to persistent DNA strand breaks, ATM-dependent degradation of transcription factor Sp1 leads to downregulation of BER genes expression, further accumulation of SSBs and renders cells susceptible to elimination via apoptosis. In contrast, many cancer cells are not able to block replication and to downregulate the expression of Sp1 in response to DNA damage. However, knockdown of BER in cancer cells leads to the accumulation of DNA double strand breaks (DSBs), suggesting deficiency in non-homologous end joining (NHEJ) repair of DSBs. Here we investigated whether DNA repair deficiency caused by knockdown of the XRCC1 gene expression in proliferating cells results in downregulation of NHEJ genes expression. We find that knockdown of the XRCC1 gene expression does not cause degradation of Sp1, but leads to downregulation of Lig4/XRCC4 and Ku70/80 at the transcription and protein levels. We thus propose the existence of Sp1-independent backup mechanism that in response to BER deficiency downregulates NHEJ in proliferating cells.

19F NMR measurements of NO production in hypertensive ISIAH and OXYS rats.

Recently we demonstrated the principal possibility of application of 19F NMR spin-trapping technique for in vivo *NO detection [Free Radic. Biol. Med. 36 (2004) 248]. In the present study, we employed this method to elucidate the significance of *NO availability in animal models of hypertension. In vivo *NO-induced conversion of the hydroxylamine of the fluorinated nitronyl nitroxide (HNN) to the hydroxylamine of the iminonitroxide (HIN) in hypertensive ISIAH and OXYS rat strains and normotensive Wistar rat strain was measured. Significantly lower HIN/HNN ratios were measured in the blood of the hypertensive rats. The NMR data were found to positively correlate with the levels of nitrite/nitrate evaluated by Griess method and negatively correlate with the blood pressure. In comparison with other traditionally used methods 19F NMR spectroscopy allows in vivo evaluation of *NO production and provides the basis for in vivo *NO imaging.