you pay internet bills

Obviously... Most of your teachers are bored and often quite dumb...

@@nayomayo603 internet bills! Lol! Who cares about 3$-5$

Also, a teacher can hardly draw a circle nicely, not to mention this kind of graphics!

יעל רובה thankyou!

GLuT 4 is the only one which is Independent of Insulin..allows free movement of Glucose.

Isn't this backward? Glut-4 is insulin INDEPENDENT, whilst the others are all dependent?

@@involuntarytwitch9771 yup sorry typo!. Glut 4 is the only Ins dependant for heart , skmuscle & adipose . Rest tissues Glucose move freely. However it's said that insulin somehow also has a fat sparing effect, don't know how exactly !

Beta cells in the pancreas have actually GLUT1. GLUT2 is only in mice and rats and not in humans.

Glucokinase is in the liver which phosphorylates glucose to G6P. In other tissues, such as adipose and muscles, it's hexokinase which phosphorylates glucose to G6P. So essentially yeah, you got it :)

Its not very complicated.....glucose is a hexose sugar....and thus hexokinase or glucokinase are terms used interchangeably

Yupp!

GLUT4 is in the muscle and adipose tissues, so a low insulin level would trigger the translocation of GLUT4 from vesicles intracellularly, to the cell membrane. The GLUT4 then fuse to the membrane and allow a rapid increase of glucose uptake into the cell. GLUT2 is associated with the liver

moshtarakman Insulin binds to tyrosine-kinase receptors in the adipose and skeletal muscle because their glucose is insulin dependent. This stimulates IRS-1, then GLUT 4 release from vesicles into the membrane. You are right. The GLUT 2 receptors are located in the pancreatic beta cells, liver, kidney and small intestine. They are insulin independent. Therefore, binding of Insulin to tyrosine kinase is not necessary. From my understanding. The insulin independent glucose transporters, such as GLUT 2, GLUT 1, and GLUT 3 are always there and are not unregulated or down regulated. Correct me if I'm wrong.

MedEdCYP450 Correct. I wouldn't go as far as saying that the non-insulin dependent GLUT receptors (1,2, and 5) are not regulated - they probably are regulated (depending on pathology) but you are right in that they are not regulated by insulin. Just a recap in case anyone needed it When sugar is high (after a meal), glucose can bind to non-insulin GLUT receptors. When glucose binds to GLUT2 on the B-cells of the pancreas, it induces insulin secretion. Insulin's main role is to prevent hyperglycemia. The big tissues that can really uptake glucose are skeletal tissue and adipose tissue but they can only take up glucose if they have GLUT4 expressed - only insulin can accomplish this upregulation. So what happens? Insulin binds to skeletal and adipose tissue's tyrosine kinase receptor. This causes two things to happen. First, it upregulates GLUT4 onto those tissues to allow glucose enter (and thus prevent hyperglycemia). The second thing it does is within those cells, it increases glycogen, protein, and lipid synthesis - this makes sense because the insulin wants to use up all the glucose to prevent hyperglycemia and so glucose gets used up to drive fat, protein, and glycogen synthesis.

moshtarakman I would like to add to this conversation that GLUT2 has a low affinity for glucose, which means it will only be "stimulated" or rather "accept" glucose in high levels. This makes perfect sense when it comes to the pancreas. The GLUT2 will only be stimulated after a meal (when you have high glucose levels) and thus release insulin, but as soon as the glucose levels diminish it won't be stimulated anymore due to it's low affinity. This is (probably) the reason why insulin is not released at normal P-glucose levels. EDIT: To clarify, GLUT1 and GLUT3 does NOT have a low affinity for glucose, they work just as well as GLUT4 but are insulin independent. Correct me if I'm wrong.

+salmjak your comment is Sooooo quite thanks I really enjoyed

moshtarakman yeah u r ri8