Stereoselective amino acid synthesis by synergistic photoredox-pyridoxal radical biocatalysis.

Developing synthetically useful enzymatic reactions that are not known in biochemistry and organic chemistry is an important challenge in biocatalysis. Through the synergistic merger of photoredox catalysis and pyridoxal 5'-phosphate (PLP) biocatalysis, we developed a pyridoxal radical biocatalysis approach to prepare valuable noncanonical amino acids, including those bearing a stereochemical dyad or triad, without the need for protecting groups. Using engineered PLP enzymes, either enantiomeric product could be produced in a biocatalyst-controlled fashion. Synergistic photoredox-pyridoxal radical biocatalysis represents a powerful platform with which to discover previously unknown catalytic reactions and to tame radical intermediates for asymmetric catalysis.

Nitric oxide donor, V-PROLI/NO, provides protection against arsenical induced toxicity in rat liver cells: requirement for Cyp1a1.

Arsenic is a cancer chemotherapeutic but hepatotoxicity can be a limiting side effect. O(2)-vinyl 1-[2-(carboxylato)pyrrolidin-1-yl]diazen-1-ium-1,2-diolate (V-PROLI/NO) is a nitric oxide (NO) donor prodrug and metabolized by liver cytochromes P450 (CYP450) to release NO. The effects of V-PROLI/NO pretreatment on the toxicity of arsenic (as NaAsO(2)) were studied in a rat liver cell line (TRL 1215). The cells acted upon the prodrug to release NO, as assessed by nitrite levels, in a time-dependent fashion to maximal levels of 8-fold above basal levels. Pretreatment with V-PROLI/NO markedly reduced arsenic cytolethality which was directly related to the level of NO produced by V-PROLI/NO treatment. Cyp1a1 expression was directly related to the level of NO production and to reduced arsenic cytotoxicity. V-PROLI/NO pretreatment markedly reduced arsenic-induced apoptosis and suppressed phosphorylation of JNK1/2. V-PROLI/NO pretreatment facilitated additional increases in arsenic-induced metallothionein, a metal-binding protein important in arsenic tolerance. Thus, V-PROLI/NO protects against arsenic toxicity in rat liver cells, reducing cytolethality, apoptosis and dysregulation of MAPKs, through generation of NO formed after metabolism by liver cell enzymes, possibly including Cyp1a1. CYP450 required for NO production from V-PROLI/NO treatment in the rat and human appears to differ as we have previously studied the ability of V-PROLI/NO to prevent arsenic toxicity in human liver cells where it reduced toxicity apparently through a CYP2E1-mediated metabolic mechanism. None-the-less, it appears that both rat and human liver cells act upon V-PROLI/NO via a CYP450-related mechanism to produce NO and subsequently reduce arsenic toxicity.