Tetrahydrofolate stability

Jones, M. L, Nixon, P. F. (2002). Tetrahydrofolates are greatly stabilized by binding to bovine milk folate-binding protein. J. Nutr., 132,2690-2694. 

There is some evidence that riboflavin status affects the stability of the thermolab ile variant of methylene tetrahydrofolate reductase (Section 10.3.2.1), and that supplements of riboflavin may lower plasma homocysteine (Section 10.3.4.2) in people who are homozygous for the variant enzyme (McNulty et al., 2002). 

It is interesting that E. coli contains two genes that code for methionine synthase metH for the cobalamin-dependent enzyme and metE for a cobalamin-independent enzyme that depends on an active site Zn + to stabilize deprotonated homocysteine (24). This thiolate species demethylates A -methyl-tetrahydrofolate, which is activated by proton transfer to N-5. MetE is less active ( 100 x ) than MetH, and so in the absence of Bi2 E. coli it produces much more MetE to compensate for the lack of MetH. 

The use of pH variation and isotope effects in transient kinetics can be illustrated with a recent study on dihydrofolate reductase. Analysis by steady-state methods had indicated an apparent p/fa of 8.5 that was assigned to an active site aspartate residue required to stabilize the protonated state of the substrate (59). In addition, it was shown that there was an isotope effect on substitution of NADPD (the deuterated analog) for NADPH at high pH but not at low pH, below the apparent p/fa This somewhat puzzling finding was explained by transient-state kinetic analysis. Hydride transfer, the chemical reaction converting enzyme-bound NADPH and dihydrofolate to NAD+ and tetrahydrofolate, was shown to occur at a rate of approximately 1000 sec at low pH. The rate of reaction decreased with increasing pH with a of 6.5, a value more in line with expectations for an active site aspartate residue. As shown in Fig. 14, there was a threefold reduction in the rate of the chemical reaction with NADPD relative to NADPH. Thus direct measurement of the chemical reaction revealed the full isotope effect. 

The other factor that needs to be taken into consideration during sample processing is the stability of folate vitamers. Stability of the vitamers differs with respect to the susceptibility to oxidative degradation, thermal, pH, and ultra-violet light [51]. Interconversion of folate vitamers occurs during sample preparation and analysis, for example, 5,10-methylenetetrahydrofolate dissociates from tetrahydrofolate and formaldehyde in the presence of mercaptoethanol (antioxidant) at low pH [49]. Furthermore, it has been argued that 5,10-methenyltetrahydrofolate is difficult to analyze on a reversed-phase (RP-18) HPLC column with a low pH mobile phase [13]. This is because interconversion of 10-formyltetrahydrofoIate to 5,10-methenyltetrahydrofolate occurs at low pH [18]. 

Fig. 17.5 Effect of nitric oxide on the synthesis of methionine and S-adenosylmethionine and methylation reactions. NO inhibits methyltetrahydrofolate reductase (MTR). This results in a decrease in tetrahydrofolate (FH4) and methionine. Additional reduction in the FH4 level may occur by the NO-induced oxidation of ferritin, a compound that inhibits the proteasomal degradation of FH4. NO affects SAM synthesis not only by inducing a decrease in methionine synthesis but also by directly inhibiting the liver-specific methyl-thioadenosyltransferase I/III (MATI/III) isozymes. The fall in SAM level cannot be fully compensated by an increase in the extrahepatic isozyme MATH, since this enzyme is inhibited by its reaction product. The reduction in homocysteine utilization for methionine synthesis may result in homocysteine accumulation. This probably does not lead to a consistent rise in cystathionine and reduced glutathione synthesis, dne to a reduced stabilization of cystathionine P-synthase (CBS) by SAM. Consequently, an inciea.se in SAH, associated with a decrease in the SAM/SAH ratio, inhibits methyltransferases (MT) and DNA methylation. The reduction in SAM level may decrease IicBa activation, thus favoring NF-kB activity...

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