Valine, 3-hydroxy

Valinomycin is one of a group of compounds termed ionophores, which facilitate movement of ions across phospholipid membranes. Valinomycin has the cyclic structure f-t>valine-lactate-L-valine-hydroxy valerate-] 3. This figure shows the structure of the complex formed between valinomycin and K+. The complex is soluble in organic solvents and can pass through the phospholipid bilayer of the mitochondrial inner membrane. K+ dissociates reversibly from the complex in the aqueous solution on either side of the membrane. 

Fig. 8. Stmcture of (a) valinomycin and (J3) and enniatins and beauvericin. Hov = a-hydroxy-isovaleric acid and Lac = lactic acid. The /V-methylamino acid for enniatin A is isoleucine enniatin B, valine enniatin C, leucine and beauvericin, phenylalanine.

FIGURE 5.5 (a) The hydroxy amino acids serine and threonine are slowly destroyed during the course of protein hydrolysis for amino acid composition analysis. Extrapolation of the data back to time zero allows an accurate estimation of the amonnt of these amino acids originally present in the protein sample, (b) Peptide bonds involving hydrophobic amino acid residues snch as valine and isolencine resist hydrolysis by HCl. With time, these amino acids are released and their free concentrations approach a limiting value that can be approximated with reliability. 

Furthermore, rwri-/ -hydroxy-L-histidine can be synthesized starting from the (R)-valine derived bromoacetate (see above). The diastereomeric purity of this acid is 30 1 (desired isomer/sum of all others)100. 

Use of the valine derived (4S )-3-acetyl-4-isopropyl-1,3-oxazolidine (8)92, the C2-symmetric reagents (2.5,55)-l-acetyl-2,5-bissubstituted pyrrolidine 994, or the doubly deprotonated acetyl urea /V-acetyl- V..V -bis[(.S)-l-phcnylethyl]urea (10), also does not lead to sufficient induced stereoselectivity combined with acceptable chemical yield. When the acetyl urea enolate is reacted with aliphatic and aromatic aldehydes, the diastereomeric adducts (ratios ranging from 1 1 to 3 1) may be separated by column chromatography to give ultimately both enantiomers of the 3-hydroxy acids in 99% ee110. 

A -[(4-nitrophenoxy)carbonyI]-L-valine methyl ester (Ci HijNiOs 162537-10-2) see Ritonavir ( )-l-(4-nitrophenoxy)-2-hydroxy-3-(tcrt-butylamino)-propane... 

As the name implies, the odor of urine in maple syrup urine disease (brancbed-chain ketonuria) suggests maple symp or burnt sugar. The biochemical defect involves the a-keto acid decarboxylase complex (reaction 2, Figure 30-19). Plasma and urinary levels of leucine, isoleucine, valine, a-keto acids, and a-hydroxy acids (reduced a-keto acids) are elevated. The mechanism of toxicity is unknown. Early diagnosis, especially prior to 1 week of age, employs enzymatic analysis. Prompt replacement of dietary protein by an amino acid mixture that lacks leucine, isoleucine, and valine averts brain damage and early mortality. 

Similarly, a series of hydroxy-terminated poly(ether) dendrimers, 35, with a single carborane nucleus at their core, were observed to have water solubilities comparable to that of chloroacetic acid, or D,L-valine. Again this is in direct contrast to the starting carborane nucleus which is insoluble in aqueous solutions and permitted the use of 35 in neutron capture therapy. Similar effects have also been observed with dendrimers containing calixarenes [66] and porphyrins [67] as the central units. 

Figure 9-4. Metabolism of the branched-chain amino acids. The first two reactions, transamination and oxidative decarboxylation, are catalyzed by the same enzyme in all cases. Details are provided only for isoleucine. Further metabolism of isoleucine and valine follows a common pathway to propionyl CoA. Subsequent steps in the leucine degradative pathway diverge to yield acetoacetate. An intermediate in the pathway is 3-hydroxy-3-methylglutaryl CoA (HMG-CoA), which is a precursor for cytosolic cholesterol biosynthesis.

Another derivatization approach is reduction of the hydroperoxide, followed by structural characterization of the corresponding alcohol, which is usually easier to handle. Thus, the structure of amino acid hydroperoxides can be characterized more easily if, after having ascertained the hydroperoxide nature of the compound, it is reduced to the alcohol with NaBH4. The structure of three valine hydroperoxides obtained on y-radiation of bovine serum albumin, a tripeptide (31) or valine (34) was elucidated after reduction, hydrolysis (if necessary), chromatographic separation, and application of the usual MS and NMR methods on the individual hydroxy derivatives of valine. ... 

Hi. Lysine. Gamma radiolysis of aerated aqueous solution of lysine (94) has been shown, as inferred from iodometric measurements, to give rise to hydroperoxides in a similar yield to that observed for valine and leucine. However, attempts to isolate by HPLC the peroxidic derivatives using the post-column derivatization chemiluminescence detection approach were unsuccessful. This was assumed to be due to the instability of the lysine hydroperoxides under the conditions of HPLC analysis. Indirect evidence for the OH-mediated formation of hydroperoxides was provided by the isolation of four hydroxylated derivatives of lysine as 9-fluoromethyl chloroformate (FMOC) derivatives . Interestingly, NaBILj reduction of the irradiated lysine solutions before FMOC derivatization is accompanied by a notable increase in the yields of hydroxylysine isomers. Among the latter oxidized compounds, 3-hydroxy lysine was characterized by extensive H NMR and ESI-MS measurements whereas one diastereomer of 4-hydroxylysine and the two isomeric forms of 5-hydroxylysine were identified by comparison of their HPLC features as FMOC derivatives with those of authentic samples prepared by chemical synthesis. A reasonable mechanism for the formation of the four different hydroxylysines and, therefore, of related hydroperoxides 98-100, involves initial OH-mediated hydrogen abstraction followed by O2 addition to the carbon-centered radicals 95-97 thus formed and subsequent reduction of the resulting peroxyl radicals (equation 55). 

Not surprinsingly, the aldol addition of the lithium enolates derived from these systems proved to be unsatisfactory. However, the derived zirkonium enolates in these and related systems have proven to be exceptional 176). The amides (171) and (172), each of which is readily derived from (S)-proline and (S)-valine respectively, exhibit good stereoselectivity with a range of aldehydes. The optical purity of the P-hydroxy amides (173) was very good (>95% e.e.). However, this method has a limitation which has been associated with the acidic conditions that are required to hydrolize these chiral amides (173) to their derived carboxylic acids (174). While... 

Such a rearrangement is not observed with glycine, alanine, 2-aminobutanoic acid or 2-amino-3-cyclohexylpropanoic acid, occurs partially with valine and isoleucine, but is complete with phenylalanine, tyrosine and threonine. By analogy with previous dediazoniation studies on 2-amino acids in acidic media,309 this rearrangement has been explained by the anchimeric assistance of alkyl (Val, lie), aryl (f he, Tyr) or hydroxy (Thr) groups during the dediazoniation process 306 for example, in the case of phenylalanine (4). 

Using haemoglobin and epoxybutene, Osterman-Golkar et al. (1991) observed the formation of two diastereomeric pairs of adducts to the N-terminal valine of haemoglobin namely V-(2-hydroxy-3-buten-l-yl) valine and V-( I -hydroxy-3 -buten-2-yl)valine. These findings were corroborated by Richardson et al. (1996), who incubated erythrocyte suspensions obtained from mice, rats and humans with epoxybutene. The second-order rate constant of adduct formation for the sum of both adducts (HOBVal) was determined in vitro at 37°C to be 0.29 x 10- L/g globin/h with erythrocytes isolated from mice (Recio et al., 1992 value corrected by the same authors to the one quoted here, Osterman-Golkar et al., 1993). 

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