• 대한의생명과학회지
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• 제8권4호
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• pp.211-215
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• 2002

The baculovirus/Sf9 cell expression can be employed as a powerful system for producing large amounts of the human erythrocyte glucose transporter, GLUT1 heterologously In order to exploit the system further, it is necessary to develop a convenient method for demonstrating that the transporter expressed in insect cells is biologically active. To achieve this, we have expressed the human CLUT1 in insect cells and photolabelled the expressed protein with [$^3$H] cytochalasin B, a potent inhibitor of the human erythrocyte glucose transporter. Subsequently, the labelled proteins were analysed by SDS-polyacrylamide gel electrophoresis (SDS-PAGE). Membranes labelled with [$^3$H] cytochalasln B in the presence of L-Glucose yielded a single sharp peak of labelling of apparent $M_r$ 45,000 on SDS/polyacrylamide gels. The mobility of this peak corresponded exactly to that of the band detected by anti-glucose transporter antibodies on Western blots of membranes prepared from insect cells infected with recombinant virus. In addition, the sharpness of the radioactive peak provides further evidence for the conclusion that the expressed protein is much less heavily and heterogeneously glycosylated than its erythrocyte counterpart. No peak of labelling was seen with the membranes prepared from non-infected Sf9 cells. Furthermore, the incorporation of label into this peak was completely inhibited by the presence of 500 mM-D-Glucose during tile photolabelling procedure, showing the stereoselectivity of the labelling. These evidences clearly show that human glucose transporter expressed in insect cells exhibits native-like biological activity, and that photolabelling with [$^3$H] cytochalasin B can be a convenient means for analysing the biological activity of the transport protein expressed in insect cells.

• 생명과학회지
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• 제24권1호
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• pp.86-91
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• 2014

Trichoplusia ni (T. ni) 세포는 사람 당 수송체를 이성질적으로 많은 양 생산하려 할 때 유용하게 사용되는, baculovirus 발현 시스템의 숙주세포로서 이용된다. 그러나 T. ni 세포에 존재하는 내재된 당 수송체의 높은 활동은, 발현된 외재적 당 수송체의 수송활성과 같은 직접적 증거 제시에 장애가 된다. 뿐만 아니라 곤충세포에 내재하는 당 수송체계의 특성에 대해서는 밝혀진 바가 거의 없다. 그래서 본 연구에서는 baculovirus 발현 시스템을 보다 잘 활용하기 위해 T. ni 세포의 2dGlc기질 수송에 D-fructose가 미치는 영향을 살펴 보았으며, T. ni 세포에 발현된 사람 당 수송체의 생물학적 활성을 보다 용이하게 검증하기 위해 발현된 수송체를 [$^3H$] cytochalasin B를 이용하여 photolabelling 하였다. 우선 감염되지 않은 세포와 recombinant AcMPV-GTL 감염시킨 T. ni 세포의 2dGlc uptake를 300 mM D-fructose가 있을 때와 없을 때, 그리고 $20{\mu}M$ cytochalasin B가 있을 때와 없을 때의 상황에서 살펴보았다. 감염되지 않은 세포에서의 육탄당 uptake는 D-fructose에 의해 강력하게 억제 되었으나 cytochalasin B에 의해서는 단지 미미한 억제 효과만을 보여주었다. 흥미롭게도 AcMPV-GTL 바이러스 감염된 T. ni 세포에서는 비록 2dGlc uptake율은 감염되지 않은 세포와 비교해 다소 낮았지만 육탄당 수송 억제 반응은 근본적으로 동일함을 보여 주었다. 또한 [$^3H$] cytochalasin B를 이용한 발현단백질 photolabelling에서는, L-glucose가 존재하는 상황 하에만 하나의 날카롭게 표지된 peak가, 바이러스 감염된 세포에서 관찰되었다. 감염되지 않은 세포에서는 이러한 peak는 관찰되지 않았다. 게다가 D-glucose 존재 하에서는 발현된 단백질의 photolabelling이 완전히 억제되어짐을 보여주어, labelling의 입체선택성(stereoselectivity)을 입증하였다.

• The Korean Journal of Physiology
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• 제24권2호
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• pp.331-344
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• 1990

What makes glucose transport function sensitive to insulin in one cell type such as adipocyte, and insensitive in another such as liver cells is unresolved question at this time. Recently it is known that insulin stimulates glucose transport in adipocytes largely by redistributing transporter from the storage pool that is included in a low density microsomal fraction to plasma membrane. Therefore, insulin sensitivity may depend upon the relative distribution of gluscose transporters between the plasma membrane and in an intracellular storage compartment. In hepatocytes, the subcellular distribution of glucose transporter is less well documented. It is thus possible that the apparent insensitivity of the hepatocyte system could be either due to lack of the constitutively maintained, intracellular storage pool of glucose transporter or lack of insulin-mediated transporter translocation mechanism in this cell. In this study, I examined if any intracellular glucose transporter pool exists in hepatocytes and this pool is affected by insulin. The results obtained summarized as followings: 1) Distribution of subcellular fractions of hepatocyte showed that there are $24.9{\pm}1.3%$ of plasma membrane, $36.9{\pm}1.7%$ of nucleus-mitochondria enriched fraction, $23.5{\pm}1.2%$ of lysosomal fraction, $9.6{\pm}1.0%$ of high density microsomal fraction and $4.9{\pm}0.5%$ of low density microsomal fraction. 2) In adipocyte, there were $29.9{\pm}2.6%$ of plasma membrane, $19.4{\pm}1.9%$ of nucleus-mitochondria enriched fraction, $26.7{\pm}1.8%$ of high density microsomal fraction and $23.9{\pm}2.1%$ of low density microsomal fraction. 3) Surface labelling of sodium borohydride revealed that plasma membrane contaminated to lysosomal fraction by $26.8{\pm}2.8%$, high density microsomal fraction by $8.3{\pm}1.3%$ and low density microsomal fraction by $1.7{\pm}0.4%$ respectively. 4) Cytochalasin B bound to all of subcellular fractions with a Kd of $1.0{\times}10^{-6}M$. 5) Photolabelling of cytochalasin B to subcellular fractions occurred on 45 K dalton protein band, a putative glucose transporter and D-glucose inhibited the photolabelling. 6) Insulin didn't affect on the distribution of subcellular fractions and translocation of intracellular glucose transporters of hepatocytes. 7) HEGT reconstituted into hepatocytes was largely associated with plasma membrane and very little was found in low density microsomal fraction which equals to the native glucose transporter distribution. Insulin didn't affect on the distribution of exogeneous glucose transporter in hepatocytes. From the above results it is concluded that insulin insensitivity of hepatocyte may due to lack of intracellular storage pool of glucose transporter and thus intracellular storage pool of glucose transporter is an essential feature of the insulin action.