Active transport is an important mechanism in cellular biology and is related to the production of ATP, used as energy currency in the body. So, how does active transport work?
It is the process by which the molecules move from the lower to higher concentration region across a membrane against the gradient. As the molecules move against the gradient, it requires energy in the form of ATP to complete the process.
Active transport is necessary for maintaining important functions like the sodium-potassium pump and the uptake of glucose in the intestine. The topic has all the detailed information about active transport and how it works to regulate several processes in the body.
Active transport is moving against the gradient.
The movement of the ions in and out of the cells creates an electrochemical gradient. As the ions inside the cells are negatively charged concerning the extracellular fluid, which consists of positively charged ions, it forms a gradient. As the molecules move from a lower to a higher solute concentration, it does so against the electrochemical gradient. The active transport mechanism is known as either pumps or protein carriers, and hence it depends on the cellular metabolism for energy. To answer how active transport works, it leads to molecule movement at the expense of energy.
How does active transport work, and what are its types?
Before delving into the mechanism and types of active transport, it is important to know about electrochemical gradients. It is the combination of the concentration gradient and voltage that affect the ions’ movement. Hence, the molecules move against the electrochemical gradient at the expense of energy. There are mainly two types of active transport:
Primary Active Transport
- The primary active transport uses ATP as the energy source for facilitating the movement of molecules across a membrane against the electrochemical gradient.
- It is also called direct active transport as it uses the metabolic energy for the direct transport of the molecules across the membrane. It helps transport ions like Na+, K+, Ca2+ etc. These ions cross the membranes and distribute throughout the body.
- An example of one of the most important primary active transports is the sodium-potassium pump. The ATPase pump is used for the process and helps maintain the cell potential. The sodium-potassium pump helps maintain the membrane potential by moving three Na+ ions out of the cells and moving in two K+ ions in the cell.
Secondary Active Transport
- It is also known as a co-transport system of coupled transport, and it relies on the electrochemical potential difference, which is created by the pumping in and out of the ions in the cell.
- The movement of the glucose molecules from the small intestine to the blood against the concentration gradient is an example of secondary active transport.
- As the ions move back down their gradients, the energy stored in the electrochemical gradients is used for the process. Hence the movement of the ion along the electrochemical gradient is coupled with the transport of another ion or molecule in the same or opposite direction.
The secondary active transport uses two types of co-transporters called symport and antiport So, how does active transport work with the help of co-transporters?
Symport: When two ions move in the same direction, the protein that assists in the movement is called symporter protein. It helps with the downhill movement of one solute from high to low concentration while moving another molecule uphill from low to higher concentration, both in the same direction. One molecule is transported along and another against a concentration gradient.
Antiport: The antiporter protein helps with the movement of the ion or solution in the opposite direction across a membrane. In this secondary active transport, one molecule or ion moves from high to low concentration, which leads to the formation of the entropic energy that helps with the transport of another solute from low to high concentration. An example of an antiporter system is the sodium-calcium exchanger.
How does active transport work in the small intestine?
This is an important process necessary for providing energy for all metabolic and regulatory functions. So, how does active transport work in the small intestine for the transport of the glucose from the gut to blood?
In humans and animals, the glucose molecule is important as it helps produce ATP, which provides energy for all functions. After a meal, the carbohydrates break down into glucose and are absorbed into the bloodstream. The symporter SGLT1 is located along small intestines, which co-transports one glucose for absorption of sugar through the intestine for two sodium ions and hence facilitates glucose reabsorption.
Conclusion
Active transport is an important process necessary for many functions in humans, animals and plants. The active transport process involves the transfer of the solute across the membrane from low to high concentration against the electrochemical gradient. However, this process requires energy for completion, and this is how active transport works. Primary active transport is important for maintaining the sodium-potassium balance necessary for homeostasis and electrolyte balance. Secondary active transport is essential for glucose metabolism and other functions. In summary, active transport is vital for life functioning.