• 대한약리학회지
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• 제18권2호
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• pp.69-77
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• 1982

$Na^+,\;K^+-ATPase$ is a component of plasma membrane in almost all animal cell, and maintains ionic distribution and membrane potential of normal cell. In the mechanism of adrenergic transmission, it is relatively well known that drug-receptor combination leads to stimulate adenylate cyclase and so on. In the cholinergic transmisison, the mechanism is not well known but is simply interpreted as the change of membrane permeability results from acetylcholine receptor interaction. To study the relationship between cholinergic transmission and membrane $Na^+,\;K^+-ATPase$, the effect of carbachol on $Na^+,\;K^+-ATPase$ activity in rabbit erythrocyte membrane is studied. The results are summarized as follows. 1) Total ATPase, $Mg^{+2}-ATPase$ and $Na^+,\;K^+-ATPase$ of rabbit erythrocyte membrane show maximum activities at 1mM of tris-ATP. 2) Total ATPase activity tends to increase when treated with carbachol $(10-^{-9}M-10^{-3}M)$. 3) The $Mg^{+2}-ATPase$ activity also tends to increase when treated with carbachol $(10-^{-9}M-10^{-3}M)$. 4) The $Na^+,\;K^+-ATPase$ activity is inhibited when treated with carbachol $(10-^{-9}M-10^{-7}M)$. It is suggested that the inhibition of $Na^+,\;K^+-ATPase$ by cholinergic drugs may be considered as one part of mechanism of cholinergic transmission.

• 대한약리학회지
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• 제26권1호
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• pp.35-49
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• 1990

A highly purified $(Na^+,\;K^+)-ATPase$ from the rectal gland of Squalus acanthias and from the electric organ of Electrophorus electricus has been used to raise antibodies in rabbits. The 97,000 dalton catalytic subunit and glycoprotein derived from the rectal gland of spiny shark were also used as antigens. The two $(Na^+,\;K^+)-ATPase$ holoenzymes and the two shark subunits were antigenic. In Ouchterlony double diffusion experiments, these antibodies formed precipitation bands with their antigens. Antibodies prepared against the two subunits of shark holoenzyme also formed precipitation bands with their antigens and shark holoenzyme, but not with eel holoenzyme. These observations are in good agreement with inhibitory effect of these antibodies on the catalytic activity of $(Na^+,\;K^+)-ATPase$ both from the shark and the eel, since there is very little cross-reaction between the shark anticatalytic subunit antibodies and the eel holoenzyme. The maximum antibodies titer of the anticatalytic subunit antibodies is found to be 6 weeks after the initial single exposure to this antigen. Multiple injections of the antigen increased the antibody titer. However, the time required to produce the maximum antibody titer was approximately the same. These antibodies also inhibit catalytic activity of $(Na^+,\;K^+)-ATPase$ vesicles reconstituted by a slow dialysis of cholate after solubilization of the enzyme in a presonicated mixture of cholate and phospholipid. In these reconstituted $(Na^+,\;K^+)-ATPase$ vesicles, effects of these antibodies on the fluxes of $Na^+$, $Rb^+$, and $K^+$ were investigated. Control or preimmune serum had no effect on the influx of $^{22}Na^+$ or the efflux of $^{86}Rb^+$. Immunized sera against the shark $(Na^+,\;K^+)-ATPase$ holoenzyme, its glycoprotein or catalytic subunit did inhibit the influx of $^{22}Na^+$ and the efflux of $^{86}Rb^+$. It was also demonstrated that these antibodies inhibit the coupled counter-transport of $Na^+$ and $K^+$ as studied by means of dual labeling experiments. However, this inhibitory effect of the antibodies on transport of ions in the $(Na^+,\;K^+)-ATPase$ vesicles is manifested only on the portion of energy and temperature dependent alkali metal fluxes, not on the portion of ATP and ouabain insensitive ion movement. Simultaneous determination of effects of the antibodies on ion fluxes and vesicular catalytic activity indicates that an inhibition of active ion transport in reconstituted $(Na^+,\;K^+)-ATPase$ vesicles appears to be due to the inhibitory action of the antibodies on the enzymatic activity of $(Na^+,\;K^+)-ATPase$ molecules incorporated in the vesicles. These findings that the inhibitory effects of the antibodies specific to $(Na^+,\;K^+)-ATPase$ or to its subunits on ATP and temperature sensitive monovalent cation transport in parallel with the inhibitory effect of vesicular catalytic activity by these antibodies provide direct evidence that $(Na^+,\;K^+)-ATPase$ is the molecular machinery of active cation transport in this reconstituted $(Na^+,\;K^+)-ATPase$ vesicular system.

• Archives of Pharmacal Research
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• 제21권6호
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• pp.707-711
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• 1998

The (Na,K)ATPase is responsible for generating the ionic gradients and membrane potentials by the exchange of intracellular $Na^+$ for $K^+$. It has been recentl y shown that (Na,K)ATPase is involved in the exocytic pathway of basic fibroblast growth factor (bFGF), although it is not known that bFGF is secreted to the outside of cell through direct interaction with (Na,K) ATPase. To understand the role for (Na,K)ATPase in the secretary pathway of bFGF, we have sought to identify the cytoplasmic domains of the alpha1 isoform of (Na,K)ATPase interacting with bFGF by yeast two-hybrid system. We have also investigated the interaction between the alpha2 isoform of (Na,K)ATPase and bFGF to find out whether the interaction is isoform-specific. We found that none of the cytoplasmic domains of (Na,K)ATPase isoforms interacted with bFGF. The result suggests that the interaction between bFGF and (Na,K)ATPase might be indirect, thus requiring other proteins which are involved in the formation of protein complexes for the interaction, although we cannot exclude the possibility that the interaction requires the element of the whole alpha subunit structure that was not present in the isolated alpha subunit cytoplasmic domains.

• 한국미생물·생명공학회지
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• 제33권4호
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• pp.322-326
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• 2005

IgE-dependent histamine-releasing factor (HRF) is found extracellularly to regulate the degranulation process of histamine in mast cells and basophils and known to play a predominant role in the pathogenesis of chronic allergic disease. HRF has been also identified in the intracellular region of the cell. Previously, we reported that HRF interacts with the 3rd cytoplasmic domain of the alpha subunit of Na,K-ATPase and inhibits Na,K-ATPase activity. Since it is known that estroaen activates the sarcolemmal Na,K-ATPase, we tested whether estrogen recovers the Na,K-ATPase activity repressed by HRF. In this study, we showed that estrogen activates Na,K-ATPase repressed by HRF. RT-PCR and western blot analysis showed that estrogen doesn't reduce the expression level of HRF in HeLa cell, suggesting that this recovery effects of estrogen probably occur via indirect mechanism on HRF and Na,K-ATPase.

• Applied Biological Chemistry
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• 제48권3호
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• pp.212-216
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• 2005

Thapsigargin은 동물조직에서 ER/SR-type $Ca^{2+}-ATPase$의 선택적 저해제로서, 토마토 뿌리조직으로부터 분리한 마이크로솜에서 ATPase의 특성을 조사하기 위하여 사용되었다. Thapsigargin은 마이크로솜 ATPase 활성을 농도의존적으로 저해하였으며, $10\;{\mu}M$ 농도에서 총활성의 약 30%를 저해하였다. 이것은 뿌리조직에서 $Ca^{2+}-ATPase$의 활성이 매우 낮다는 것을 고려할 때, thapsigargin이 뿌리조직의 주된 ATPase 활성인 원형질막 및 액포막의 $H^+-ATPase$ 활성을 저해할 가능성을 보인다. Thapsigargin의 효과는 ${NO_3}^-$를 사용하여 액포막 $H^+-ATPase$ 활성을 저해하였을 때 현저하게 감소하였다. 그러나, thapsigargin의 효과는 원형질막의 $H^+-ATPase$ 활성에는 영향을 미치지 않아, thapsigargin이 토마토 뿌리조직에서 액포막 $H^+-ATPase$를 선택적으로 저해함을 보여준다.

• 대한의생명과학회지
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• 제6권3호
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• pp.165-170
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• 2000

Vacuolar (H$^{+}$)-ATPase (V-ATPase)는 multi-subunit로 구성된 단백질로서, proton pumping을 통해 세포내 산성화반응에 관여를 한다. 최근에 이 단백질이 synaptic vesicle에서도 발견된 것으로 보아 뇌 신경전달에 중요한 역할을 수행할 것으로 추정하고 있다. 우리는 흰쥐 뇌에서 분리한 mRNA를 주형으로 한 PCR 반응에서 16 kDa subunit의 V-ATPase cDHA를 클로닝할 수 있었고, 이의 염기서열 또한 결정하였다. 분리된 뇌 16 kDa V-ATPase의 coding sequence는 전체 468 bp로서 간에서 보고되었던 것과 동일한 크기였다. 단지 3' 말단의 염기 하나가 A에서 C로 바뀌어 있었는데 모두 alanine (GCA, GCC)을 지정하기 때문에 단백질의 일차구조에는 변화가 없는 것으로 확인되었다. 한편 rat brain cDNA library에서도 동일한 clone이 분리되었는데 역시 같은 부분에서 polymorphism이 발견되었고, RNA splicing 등 더 이상의 조직특이적 변화는 없었다. 본 연구는 16 kDa V-ATPase의 뇌에서의 기능과 신경말단에서의 neurotransmission 및 synaptic vesicle의 재순환 기전을 이해하는데 유용한 정보가 될 것이다.

• Applied Biological Chemistry
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• 제41권2호
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• pp.130-136
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• 1998

토마토의 뿌리조직에 존재하는 여러 가지 이온이동 기작을 밝혀내기 위하여 뿌리조직으로부터 마이크로솜을 분리하였고, 마이크로솜에 존재하는 이온점프(ATPase)의 활성을 측정하였다. 원형질막과 액포막에 위치하는 $H^+-ATPase$들의 활성은 각각의 선택적 저해제인 vanadate와 $NO^-_3$를 이용하여 평가하였고, 이들의 활성은 각각 마이크로솜 ATPase 총활성의 ${\sim}30%$, ${\sim}38%$로 나타났다. 이들 두 가지 저해제 효과는 additive하게 나타났으며, 전체활성의 약 $50{\sim}70%$를 저해함을 확인하였다. 마이크로솜 ATPase활성은 pH의 영향을 받으며, 최대 활성은 pH 7.4에서 나타났다. ATPase 활성은 또한 10 mM 이상의 $K^+$에 의해서 약 30% 증가를 보였으며, $K^+$에 의한 활성촉진 효과는 $Na^+$에 의해서 완전히 저해되었다. $K^+$에 의한 ATPase 활성증가 기작을 조사하기 위해, 반응용액의 $K^+$농도를 조절하면서 선택적 저해제들의 효과를 측정하였다. 반응용액에 $K^+$이 없는 조건과 120mM $K^+$을 함유하는 조건에서 vanadate는 ATPase 활성을 동일하게 27% 저해하였으나, $NO^-_3$는 각각의 조건에서 32%, 40% 저해하였다. 이것은 $NO^-_3$에 민감한 액포막의 $H^+-ATPase$활성이 $K^+$에 의해서 촉진된다는 것을 시사한다. 마이크로솜 ATPase 활성은 $Ca^{2+}$에 의해서도 저해되었으며, $NO^-_3$는 $Ca^{2+}$에 의한 저해효과를 억제하였다. 이상의 결과는 토마토 뿌리조직의 마이크로솜 ATPase중 액포막의 $H^+-ATPase$ 활성이 $K^+$에 의해서 증가하며, $Ca^{2+}$에 의해서 저해되는 것을 보여준다.

• The Korean Journal of Physiology
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• 제1권2호
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• pp.141-150
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• 1967

The present investigation was initially undertaken to see if there exists $Na^+-K^+$ activated ATPase in the microsome fraction of the kidney. Having confirmed the presence of such an enzyme, further attempts have been made to characterize its nature and the following conclusions were obtained: (1) The ATPase activity was greatest at the $Na^+$ concentration of 100 mM as well as at $K^+$ concentration of 10 mM. Moreover, the ATPase activity was found to be depressed by $Ca^{++}$ in the presence of $Mg^{++}$. (2) While the ATPase activity was depressed by Ouabain, the magnitude of inhibition was greater in the Na medium than in the K medium. (3) NaCN augmented the ATPase activity whereas NaF and IAA depressed it. On the other hand, DNP had little influence on the ATPase activity. (4) Diamox, vasopressin and aldosterone had no effect while $HgCl_2$ markedly depressed the ATPase activity These findings indicate that the nature of ATPase isolated from the microsome fraction of the rabbit kidney is quite similar to that from other organs such as the heart and the muscle, although there are certain features specific to the type of organs.

• 대한한의학회지
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• 제17권2호
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• pp.264-276
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• 1996

This study was carried out to evaluate the effect of Samhwasan on the Na-K-ATPase activity of heart muscle. The Na-K-ATPase activity was prepared from rabbit heart ventricles. Samhwasan markedly inhibited the Na- K - ATPase activity in a dose-dependent manner with an estimated $I_{50}$ of 0.56%. Hill coefficient was 1.70, indicating that the enzyme has more than one binding site for the Samhwasan. Inhibition of enzyme activity by Samhwasan increased as pretreatment time was prolonged. Inhibition by the drug was not affected by a change in enzyme protein concentration. Kinetic studies of substrate activation of the enzyme indicated classical noncompetitive inhibition, showing significant reduction in Vmax without a change in Km value. Inhibitory effect by Samhwasan was not altered by changes in concentration of $Mg^{2+}$, $Na^+$ or $K^+$, dithiothreitol. a sulfhydryl reducing reagent, did not protect the inhibition of Na-K-ATPase activity by Samhwasan combination of Samhwasan and ouabain showed a cumulative inhibition fashion. These results suggest that Samhwasan inhibits Na-K-ATPase activity of heart ventricles with an unique binding site different from that of ATP, $Mg^{2+}$, $Na^+$ or $K^+$ and ouabain.

• 대한한의학회지
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• 제16권1호통권29호
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• pp.281-294
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• 1995

The effect of Sam Hwa San on the Na-K-ATPase activity was evaluated in microsomal fraction prepared from rabbit cerebral cortex to determine whether Sam Hwa San affects Na-K-ATPase activity of nervous system. Sam Hwa San markedly inhibited the Na-K-ATPase activity in a dose-dependent manner with an estimated $I_{50}$ of 0.12%. Optimal pH for the Na-K-ATPase activity was at 7.5 in the presence or absence of Sam Hwa San. The degree of inhibition by the drug more increased at acidic and alkalic pHs than neutral pH. Kinetic studies of substrate and cationic activation of the enzyme indicate classic noncompetitive inhibition fashion for ATP, Na and K, showing significant reduction in Vmax without a change in Km. Dithiothreitol, a sulfhydryl reducing reagent, partially protects the inhibition of Na-K-ATPase activity by Sam Hwa San. Combination of Sam Hwa San and ouabain showed higher inhibition than cumulative inhibition. These results suggest that Sam Hwa San inhibits Na-K-ATPase activity in central nervous system by reacting with, at least a part, sulfhydryl group and ouabain binding site of the enzyme protein, but with different binding site from those of ATP, Na and K.