The Na+/K+ pump provides energy for both symport and antiport transport systems. Explain how this is...

Describe the three mechanisms via which the transport of a solute against its free energy gradient...

Describe the three mechanisms via which the transport of a solute against its free energy gradient can be coupled to a source of energy (identify the source of energy in each case). Explain the difference between direct (primary) and indirect (secondary) active transport and discuss how these two processes are "connected" to each other in cells. Think about how the effect of Na+/K+ ATPase (Na+/K+ pump) on the intracellular concentration (and electrochemical potential) of Na+ can be used to drive...

The Na –glucose symport system of intestinal epithelial cells couples the \"downhill\" transport of two Na...

The Na –glucose symport system of intestinal epithelial cells couples the \"downhill\" transport of two Na ions into the cell to the \"uphill\" transport of glucose, pumping glucose into the cell against its concentration gradient. If the Na concentration outside the cell ([Na ]out) is 159 mM and that inside the cell ([Na ]in) is 23.0 mM, and the cell potential is -49.0 mV (inside negative), calculate the maximum ratio of [glucose]in to [glucose]out that could theoretically be produced if...

why are the Na/K ion pump needed?

why are the Na/K ion pump needed?

Why is the Na+, K+ pump essential for glucose absorption?

Why is the Na+, K+ pump essential for glucose absorption?

which of the following in cell transport processes does not require energy? Receptor binding Production of...

which of the following in cell transport processes does not require energy? Receptor binding Production of cyclic AMP Na K pump Phosphorylation cascade G protein activation

1. Calculate the free energy of transport (Gt) for the movement of sodium ions (Na+ )...

1. Calculate the free energy of transport (Gt) for the movement of sodium ions (Na+ ) from the extracellular space into the cell under the following conditions: [Na+ ]out = 140 mM; [Na+ ]in = 12.0 mM;  =−60.0 mV; T = 37.0C. Use R = 8.314 J/mol K; F = 96,500 J/V mol. 2. Calculate the free energy of transport (Gt) for the movement of potassium ions (K+ ) from the extracellular space into the cell under the following...

The sodium (Na+) potassium (K+) pump is a protein channel in the nephron. The pump moves...

The sodium (Na+) potassium (K+) pump is a protein channel in the nephron. The pump moves sodium out of the nephron and moves potassium into the nephron. The nephron is exchanging molecules with the Group of answer choices A. capillary B. adrenal gland C. collecting duct D. urethra

How are intestinal epithelial cells and renal tubular cells similar? They both have Na+/amino acid co-transporters...

How are intestinal epithelial cells and renal tubular cells similar? They both have Na+/amino acid co-transporters on the basal surface of the cell. They both require Na+/K+ pumps to create a Na+ gradient on the basal side of the cell. They both actively transport K+ into the cell from the lumen. They both have a close relationship with capillaries to promote motility of the chyme or filtrate.

Describe and draw a sodium/potassium pump. What type of transport is this? Does it use energy...

Describe and draw a sodium/potassium pump. What type of transport is this? Does it use energy in order to function?

The standard free energy that is required for the sodium-potassium ATPase to pump two K+ ions...

The standard free energy that is required for the sodium-potassium ATPase to pump two K+ ions into the cell and three Na+ ions out is +43.8 kJ/mol but the standard free energy change of hydrolysis of ATP is only -32 kJ/mol. This apparent imbalance of free energy can be accounted for because: A) the movement of Na+ ions is down the concentration gradient . B) the movement of K+ ions is down the concentration gradient. C) the free energy provided...