Secondary Active Transport

One example of how cells use the energy contained in electrochemical gradients is demonstrated by glucose transport into cells. The ion vital to this process is sodium (Na+), which is typically present in higher concentrations extracellularly than in the cytosol. Such a concentration difference is d...

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Detalles Bibliográficos
Autor principal: Corporation, myJoVE.
Autor Corporativo: Corporation, myJoVE (-)
Formato: Video
Idioma:Inglés
Publicado: Cambridge, MA : MyJoVE Corp 2016.
Colección:JOVE Science Education.
Core Bio.
Acceso en línea:Acceso a vídeo desde UNAV
Ver en Universidad de Navarra:https://innopac.unav.es/record=b42118499*spi
Descripción
Sumario:One example of how cells use the energy contained in electrochemical gradients is demonstrated by glucose transport into cells. The ion vital to this process is sodium (Na+), which is typically present in higher concentrations extracellularly than in the cytosol. Such a concentration difference is due, in part, to the action of an enzyme zpumpy embedded in the cellular membrane that actively expels Na+ from a cell. Importantly, as this pump contributes to the high concentration of positively-charged Na+ outside a cell, it also helps to make this environment zmore positivey than the intracellular region. As a result, both the chemical and electrical gradients of Na+ point towards the inside of a cell, and the electrochemical gradient is similarly directed inwards. Sodium-glucose Cotransporters Sodium-glucose cotransporters (SGLTs) exploit the energy stored in this electrochemical gradient. These proteins, primarily located in the membranes of intestinal or kidney cells, help in the absorption of glucose from the lumen of these organs into the bloodstream. In order to function, both an extracellular glucose molecule and two Na+ must bind to the SGLT. As Na+ migrates into a cell through the transporter, it travels with its electrochemical gradient, expelling energy that the protein uses to move glucose inside a cell—against its chemical gradient, since this sugar tends to be at a higher concentration within a cell. As a result, glucose travels uphill against its concentration gradient simultaneously with Na+ that travels down its electrochemical gradient. This is an example of secondary active transport, so-named because the energy source used is electrochemical in nature, rather than the primary form of ATP. Therapies Targeting SGLTs Given the role of glucose in certain diseases, scientists have begun to look at ways of interfering with glucose transport into cells. For example, diabetes is characterized by excess glucose in the bloodstream, which can lead to nerve damage and other complications. As a result, some researchers are assessing how SGLT expression differs between diabetics and non-diabetics, and whether inhibiting different SGLTs can help treat the disease. Alternatively, since cancer cells have been demonstrated to require more glucose compared to their normal counterparts, other investigators are examining whether glucose transporters can be a new target of anti-cancer therapies.
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Descripción Física:1 recurso electrónico (92 seg.) : son., col
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