Distribution of lactic dehydrogenase in X-irradiated tissues.

Exposure to whole-body X-irradiation in rats causes a marked increase in total lactic dehydrogenase (LDH) activity and decrease in H-LDH/M-LDH ratio in serum and tissues, the maximum effect being observed on the 8th post-irradiation day. While there is an elevation of M-LDH isoenzyme, H-LDH remains relatively constant. Studies on incorporation of DL-leucine-l-14C into heart LDH isoenzymes also revealed increased biosynthesis of M-LDH isoenzyme. This indicates that an adaptive mechanism is operative in the X-irradiated rats, whereby, in order to augment anaerobic glycolysis, synthesis of M-LDH is stimulated. Administration of the radioprotector cystamine does not alter the effects of X-irradiation on serum LDH activity.     

Conformational effects of coenzyme binding to porcine lactic dehydrogenase.

Changes induced on addition of the coenzyme, NADH or NAD+, to porcine lactic dehydrogenase isoenzymes H4 and M4 have been studied by hydrodynamic and spectroscopic methods. As shown by ultracentrifugal analysis, the native subunit structure remains unchanged on holoenzyme formation; an approximately 5% increase of the sedimentation coefficient, parallelled by a slight decrease of the partial specific volume (less than 1%) indicate a significant change in the native tertiary and/or quaternary structure of the enzymes, corroborating earlier calorimetric data (Hinz and Jaenicke, 1975). The binding constant for the enzyme from skeletal muscle (M4) and NADH are found to be in agreement with KD-values obtained from equilibrium dialysis, as well as spectroscopic and thermal titration experiments (8 muM). Far UV circular dichroism measurements do not show significant changes on ligand binding, indicating unchanged helicity or compensatory conformational effects. In the near UV, ligand binding is reflected by an extrinsic Cotton effect around 340 nm; in the range of aromatic absorption no changes are detectable. The experimental results suggest that there are gross structural changes on coenzyme binding to lactic dehydrogenase which do not affect the intrinsic spectral properties normally applied to analyze transconformation reactions in protein molecules.     

Characterisation of lactic dehydrogenase fromLactobacillus casei

Lactic dehydrogenase fromLactobacillus casei ATCC 7469 has been purified to homogeneity by a two-step affinity chromatography procedure which gave an yield of 35%. The enzyme specifically catalysed the conversion of pyruvate to lactate. The enzyme was maximally active at pH 4.6, which was shifted to 5.4 in the presence of fructose 1,6-biphosphate. The enzyme had a molecular weight of 70,800 with two identical subunits, unlike the lactic dehydrogenase from other sources. Histidine and primary amino groups appeared to be involved in catalysis.     

Trichomonas gallinae: charaterization and regulatory properties of lactic dehydrogenase.

The lactic dehydrogenase (l-lactate: NAD oxidoreductase, EC 1.1.1.27, LDH)of Trichomonas gallinae was characterized and some of its regulatory properties studied. Electrophoretic analysis, with specific enzymatic staining of crude and dialyzed cell-free extracts and dialyzed ammonium sulfate fractions, all revealed a single band of enzymatic activity suggesting only one molecular form of the enzyme. The pH optima were found to be the following: 7.0 in the pyruvate to lactate direction and 9.0 in the reverse direction. Thermal inactivation studies showed a narrow temperature optimum peaking at 35 C. The K_m values for all four reaction components were determined and found to be: NADH, 70 μm; pyruvate, 88 μm; NAD, 65 μm; and l-lactate, 4.6 mM. T. gallinae LDH was absolutely specific for NAD, NADH, l-lactate, and pyruvate. The enzyme exhibited negative cooperativity, with both NADH and l-lactate, as evidenced by curvilinear Lineweaver-Burk kinetics and Hill coefficients of less than one. Several glycolytic intermediates lowered the K_m of NADH with variable effects on the K_m of pyruvate. The regulation of LDH by glycolytic intermediates is discussed.