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Enzyme
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Target Concepts:
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Query: EC:1.12.7.2 (
hydrogenase
)
3,522
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The cells of Rhodospirillum rubrum and Thiocapsa roseopersicina grown in media containing glutamate and arginine, respectively, as well as under conditions of nitrogen fixation evolve H2 in the light. If the cultures were grown in media with NH4+, NO3-, urea, glutamine or asparagine, hydrogen photoevolution by the cells and acetylene reduction started after the lag-phase and proceeded at a low rate. Extracts of such cells did not display the activity of nitrogenase which could be assayed by the ATP-dependent evolution of H2 from dithionite. The data obtained confirm the fact that hydrogen photoevolution by purple bacteria involves nitrogenase whose synthesis is regulated (according to the action of glutamine) with the participation of
glutamine synthetase
. NH4+, glutamine and asparagine inhibit also hydrogen photoproduction by purple bacteria and acetylene photoreduction. However, they have no effect on hydrogen evolution in the dark by the cells of R. rubrum and T. roseopersicina in the presence of formiate or pyruvate, respectively, whereas carbon monoxide inhibits hydrogen production. Therefore, hydrogen production by purple bacteria in the dark must be catalyzed by
hydrogenase
.
...
PMID:[Effect of nitrogen-containing compounds on hydrogen light emission and nitrogen fixation by purple bacteria]. 11 58
Negative staining, some closely related alternative preparation techniques and radiation stability are considered. An attempt is made to clarify the mechanism of action and ultimate resolution limit of negative staining. The results of electron diffraction investigation of thermitase microcrystals embedded in glucose and glucose + stains are presented. It is shown that at doses not exceeding 10 electrons/nm2 electron diffraction from thermitase crystals demonstrate diffraction fields up to 0.2 nm. When adding heavy-atom salts to glucose or using negative staining, the relative intensities of reflections change and electron diffraction patterns for every type of heavy-atom additive (or negative stain) have their specific features. Such characteristic changes of reflection intensities indicate specific interaction of these additives (or stains) with the object. In the case of electron diffraction from the crystals stained using the routine negative staining technique the ordering was preserved down to 0.4-0.5 nm. Increasing the dose up to the normal value results in fading of distant reflections. Thus, negative staining with radiation doses less than the critical one could yield resolution down to 0.4 nm. Yet, the structure may change due to interaction with the stain. Nevertheless, the possibility that such resolution could be obtained for a limited number of objects should not be excluded. Some examples of the application of negative staining for investigation of quaternary and domain structure of proteins (nitrogenase,
glutamine synthetase
, mitochondrial ATP-synthase, membrane monooxygenase enzymes), tubular and two-dimensional protein crystals (catalase, phosphorylase, HWV protein,
hydrogenase
), as well as ribosomes and bacteriophages are given in the review.
...
PMID:Negative staining of proteins. 171 74
Livers of starved rats refed for 2 h were perfused in situ by a modification of the dual digitonin pulse technique of Quistorff and Grunnet (Quistorff, B., and Grunnet, N. (1987) Biochem. J. 243, 87-95). A pulse of digitonin (2 mg/ml) was infused first antegrade through the portal vein followed retrograde through the vena cava, or in reverse order, 13 mg of digitonin per zone. Microscopic examination showed that this procedure permeabilized the periportal and perivenous zones of the liver without overlap, with a narrow unaffected band of hepatocytes between the zones. The distribution pattern between periportal and perivenous zones ratio for alanine transaminase, lactate
hydrogenase
, fructose-1,6-bisphosphatase, and phosphoenolpyruvate carboxykinase ranged from 1.5 to 3. Glucokinase activity was higher in the perivenous zone (periportal/perivenous ratio of 0.7) and
glutamine synthetase
was exclusively present in that zone. Fructose 2,6-bisphosphate concentration was nearly equal in the two zones.
...
PMID:The zonation of liver and the distribution of fructose 2,6-bisphosphate in rat liver. 289 7
The photosynthetic bacteria can evolve H2 in the light through a nitrogenase-mediated reaction. The nitrogenase enzyme in the photosynthetic bacteria is similar to other nitrogenases. It is made of two soluble components: a) the Fe protein (dinitrogenase reductase or Component II) which receives electrons from ferredoxin, and b) the Mo-Fe protein (dinitrogenase or Component I) on which the substrates (including protons) are reduced. In photosynthetic bacteria, the physiological regulation of nitrogenase activity involves inactivation by covalent modification of the nitrogenase Fe protein. This inactivation can be reversed by an activating factor (or activating enzyme) which is an extrinsic membrane protein. After an ammonia shock, both the Fe protein of nitrogenase, and the
glutamine synthetase
, become adenylylated in vivo. In the adenylylation state,
glutamine synthetase
has AMP moieties bound to the protein by phosphate linkage. In toluene-treated cells of Rhodopseudomas capsulata preincubated with radioactive ATP, labelled either by 14C on the adenine or by 32P on the P alpha of ATP and then submitted to an ammonia shock, the Fe protein becomes covalently labelled only with [14C]ATP ad not with [32P]alpha ATP, while
glutamine synthetase
becomes labelled with both radioactive ATP molecules. This indicates that a different type of linkage is involved in the binding of the modifying group to Fe protein and to
glutamine synthetase
. Like other N2 fixers, the photosynthetic bacteria also contain a
hydrogenase
. In R. capsulata, the
hydrogenase
is an intrinsic membrane protein which protrudes in the cytoplasmic space and is not accessible to anti-
hydrogenase
antibodies from the periplasmic side. The
hydrogenase
can transfer electrons from H2 to the electron transport chain. It functions physiologically as an uptake-
hydrogenase
and may contribute to the recycling of electrons to nitrogenase. In the presence of excess carbon compounds, its main role may be to maintain an anaerobic microenvironment for the nitrogenase. Ferredoxin has been isolated from photosynthetic bacteria. Rhodospirillum rubrum and Rhodopseudomonas capsulata each contain two different soluble ferredoxin molecules. Reduced Fd I from R. capsulata has been shown to donate its electrons to nitrogenase.
...
PMID:H2 metabolism in photosynthetic bacteria and relationship to N2 fixation. 613 53
The activity, protein, and isoenzymic profiles of glutamate de-
hydrogenase
(GDH) and
glutamine synthetase
(GS) were studied during development and ripening of avocado (Percea americana Mill. cv Hass) fruit. During fruit development, the activity and protein content of both GDH and GS remained relatively constant. In contrast, considerable changes in these enzymes were observed during ripening of avocado fruit. The specific activity of GDH increased about 4-fold, coincident with a similar increase in GDH protein content and mRNA levels. On the other hand, GS specific activity showed a decline at the end of the ripening process. On the isoenzymic profile of GDH, changes in the prevalence of the seven isoenzymes were found, with a predominance of the more cathodal isoenzymes in the unripe and of the most anodal isoenzymes in the ripe fruit. Two-dimensional electrophoresis revealed that avocado fruit GDH consists of two subunits whose association gives rise to seven isoenzymes. The results support the view that the predominance of the more anodal isoenzymes in the overripe fruit was due to the accumulation of the [alpha]-polypeptide.
...
PMID:Regulation of Glutamate Dehydrogenase and Glutamine Synthetase in Avocado Fruit during Development and Ripening. 1223 22
Rhodopseudomonas palustris is a purple, facultatively phototrophic bacterium that uses hydrogen gas as an electron donor for carbon dioxide fixation during photoautotrophic growth or for ammonia synthesis during nitrogen fixation. It also uses hydrogen as an electron supplement to enable the complete assimilation of oxidized carbon compounds, such as malate, into cell material during photoheterotrophic growth. The R. palustris genome predicts a membrane-bound nickel-iron uptake
hydrogenase
and several regulatory proteins to control
hydrogenase
synthesis. There is also a novel sensor kinase gene (RPA0981) directly adjacent to the
hydrogenase
gene cluster. Here we show that the R. palustris regulatory sensor
hydrogenase
HupUV acts in conjunction with the sensor kinase-response regulator protein pair HoxJ-HoxA to activate
hydrogenase
expression in response to hydrogen gas. Transcriptome analysis indicated that the HupUV-HoxJA regulatory system also controls the expression of genes encoding a predicted dicarboxylic acid transport system, a putative formate transporter, and a
glutamine synthetase
. RPA0981 had a small effect in repressing
hydrogenase
synthesis. We also determined that the two-component system RegS-RegR repressed expression of the uptake
hydrogenase
, probably in response to changes in intracellular redox status. Transcriptome analysis indicated that about 30 genes were differentially expressed in R. palustris cells that utilized hydrogen when growing photoheterotrophically on malate under nitrogen-fixing conditions compared to a mutant strain that lacked uptake
hydrogenase
. From this it appears that the recycling of reductant in the form of hydrogen does not have extensive nonspecific effects on gene expression in R. palustris.
...
PMID:Regulation of uptake hydrogenase and effects of hydrogen utilization on gene expression in Rhodopseudomonas palustris. 1692 81
