Trace elements in blood of Baltic gray seal pups (Halichoerus grypus) from the Gulf of Riga and their relationship with biochemical and clinical parameters.

Trace elements are pollutants of both natural and anthropogenic origin which can influence negatively on ecosystem and wildlife health. We evaluated trace element in blood samples of gray seal (Halichoerus grypus) stranded in the Gulf of Riga and their influence on their health status through hematological and biochemical profiles. Zn showed the highest levels followed by Cu > Se > Pb > THg > As. Cr and Cd were not detected. Most trace element levels were generally comparable to those reported in seal species; however, high Pb values were observed in those sample showing detectable concentrations (<0.046-257.6 µg/kg ww). Significant positive correlations were found between trace elements concentrations and various biochemical parameters, including Se-ASAT, Se:Hg-ASAT, Cu-TP, Cu-ALB, CuCa, Zn-ALAT, ZN-LDH, ZnP, Zn-Segment neutrophils, and Pb-CK. Nevertheless, most relationships were not strong enough (p > 0.04) to assume a toxicological implication. Despite its limitations, this information could serve as the baseline for future research.

Characterization of mevalonate kinase V377I, a mutant implicated in defective isoprenoid biosynthesis and HIDS/periodic fever syndrome.

The list of diseases linked to defects in lipid metabolism has recently been augmented by the addition of hyperimmunoglobulinemia D and periodic fever syndrome (HIDS: MIM 260920), which are correlated with depressed levels of mevalonate kinase activity [1,2] and protein [1]. More specifically, a V377I substitution has been proposed to account for this disease. We observed that V377 appears to be far from invariant in eukaryotic mevalonate kinases. Prokaryotic mevalonate kinases are lower in molecular weight and several terminate prior to residue 377 of the eukaryotic proteins. These observations prompted our direct test of the impact of V377 on activity and protein stability by engineering a V377I mutation in a recombinant human mevalonate kinase. The mutant protein has been isolated and kinetically characterized. In comparison with wild-type enzyme, V377I exhibits only modest differences (notably > or = 6-fold inflation of K(m(MVA))) that do not account for the diminished mevalonate kinase activity assayed in HIDS cell extracts. Moreover, thermal inactivation (50 degrees C) of isolated wild-type and V377I enzymes demonstrates little difference in stability between these proteins. We conclude that a single V377I substitution is unlikely to explain the observation of depressed mevalonate kinase stability and catalytic activity in HIDS.

Investigation of invariant serine/threonine residues in mevalonate kinase. Tests of the functional significance of a proposed substrate binding motif and a site implicated in human inherited disease.

Mevalonate kinase serine/threonine residues have been implicated in substrate binding and inherited metabolic disease. Alignment of >20 mevalonate kinase sequences indicates that Ser-145, Ser-146, Ser-201, and Thr-243 are the only invariant residues with alcohol side chains. These residues have been individually mutated to alanine. Structural integrity of the mutants has been demonstrated by binding studies using fluorescent and spin-labeled ATP analogs. Kinetic characterization of the mutants indicates only modest changes in K(m)((ATP)). K(m) for mevalonate increases by approximately 20-fold for S146A, approximately 40-fold for T243A, and 100-fold for S201A. V(max) changes for S145A, S201A, and T243A are < or =3-fold. Thus, the 65-fold activity decrease associated with the inherited human T243I mutation seems attributable to the nonconservative substitution rather than any critical catalytic function. V(max) for S146A is diminished by 4000-fold. In terms of V/K(MVA), this substitution produces a 10(5)-fold effect, suggesting an active site location and catalytic role for Ser-146. The large k(cat) effect suggests that Ser-146 productively orients ATP during catalysis. K(D(Mg-ATP)) increases by almost 40-fold for S146A, indicating a specific role for Ser-146 in liganding Mg(2+)-ATP. Instead of mapping within a proposed C-terminal ATP binding motif, Ser-146 is situated in a centrally located motif, which characterizes the galactokinase/homoserine kinase/ mevalonate kinase/phosphomevalonate kinase protein family. These observations represent the first functional demonstration that this region is part of the active site in these related phosphotransferases.

Functional evaluation of serine/threonine residues in the P-Loop of Rhodobacter sphaeroides phosphoribulokinase.

The N-terminal region of phosphoribulokinase (PRK) has been proposed to contain a "P-loop" or "Walker A" motif. In Rhodobacter sphaeroides PRK, four alcohol side chains, contributed by S14, T18, S19, and T20, map within the P loop and represent potential Mg-ATP ligands. Each of these has been individually replaced with an alanine and the impact of these substitutions on enzyme-ATP interactions and overall catalytic efficiency evaluated. Each mutant PRK retains the ability to tightly bind the positive effector, NADH (0.7-0.9 per site), and exhibits allosteric activation, suggesting that the proteins retain a high degree of structural integrity. Similarly, each mutant PRK retains the ability to stoichiometrically (0.7-1.2 per site) bind the alternative substrate trinitrophenyl-ATP. Despite the large size of the PRK oligomer (8 x 32 kDa), (31)P NMR can be used to detect stoichiometrically bound Mg-ATP substrate, which produces markedly broadened peaks in comparison with signals from unbound Mg-ATP. Elimination of alcohol substituents in mutants T18A, S19A, or T20A produces enzymes which retain the ability to form stable PRKMg-ATP complexes. Each mutant complex is characterized by (31)P resonances for alpha- and gamma-phosphoryls of bound Mg-ATP which are narrower than measured for wild-type PRKMg-ATP; signals for the beta-phosphoryl are poorly detectable for mutant PRKMg-ATP complexes. Kinetic characterization indicates that these mutants differ markedly with respect to catalytic activity. T20A exhibits V(m) comparable to wild-type PRK, while V(m) is diminished by 8-fold for T18A and by 40-fold for S14A. In contrast to these modest effects, S19A exhibits decreases in V(m) and V(m)/K(Ru5P) of 500-fold and >15000-fold, respectively. S19A and T18A exhibit only modest (6-7-fold) increases in S(1/2) for ATP but larger (30-45-fold) increases in K(m) for Ru5P. K(I) values for the competitive inhibitor, 6-phosphogluconate, do not significantly change upon mutation of T18 or S19, suggesting that these residues are not crucial to Ru5P binding. A role for the alcohol group of S19, the eighth residue in P-loop motif, as a ligand to the Mg-ATP substrate seems compatible with the characterization data; adjacent alcohols do not efficiently function as surrogates. Such a proposed function for S19 is compatible with its proximity to E131, the acidic residue in a putative Walker B motif and probable second Mg-ATP ligand in PRK's active site.