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Introduction
Diabetes type II was previously referred to as noninsulin-dependent diabetes mellitus as well as adult-onset diabetes. Diabetes type II is a metabolic disorder that influences the glucose metabolism process by the body. The body resisting the impact of insulin as well as producing less insulin to maintain normal glucose levels characterizes the condition (Goldstein and Mueller-Wieland 5). In other words, the metabolic disorder is exemplified by high blood glucose due to insulin resistance as well as comparative insulin deficit.
Of all the cases of diabetes, diabetes type II accounts for 0.9 of the cases. Further, obesity in individuals that are genetically subjected to the condition is the main source of diabetes type II. The development of diabetes type II is also caused by anxiety and a poor diet characterized by excess consumption of sugar-sweetened foods. Individuals suffering from the condition often experience recurrent urination, increased thirst, polyphagia, and loss in weight. The conditional can result in cardiovascular diseases, limb amputations as well as kidney failure (Goldstein and Mueller-Wieland 33). Regular workouts and an appropriate diet are significant in the prevention of diabetes type II.
Hormonal mechanism
The reduced capability of the body cells to respond to the activities of insulin is regulated by intracellular and trans-membrane protein receptors. The types of receptors in the activities of insulin include ion channel-linked receptors including calcium ions and enzyme-linked receptors such as tyrosine kinase receptors. Alpha and beta subunits make up the insulin receptor. Disulfide bonds join the subunits of insulin receptors together. The former subunits are extracellular and house insulin-combining realms whereas the latter subunits infiltrate through the plasma membrane. The pancreas plays the role of producing insulin. Additionally, the pancreas moves the hormone from the bloodstream into the body cells to be utilized for energy. In diabetes type II, the resistance to insulin is a critical aspect. In essence, the glucose that builds up in the bloodstream and the body cells is unable to operate efficiently (Goldstein and Mueller-Wieland 15). During the regulation of glucose metabolism, multifaceted signaling interfaces between fat, liver, and muscle tissues as well as brain tissues occur.
When there is high glucose sugar, the insulin combines with the receptor tyrosine kinase on the cell surface. The receptor transports phosphate groups from ATP to tyrosine deposits on intracellular target proteins. The receptor then undergoes endocytosis. The islets of Langerhans release excess insulin to achieve homeostatic levels in the blood. The increase in blood insulin causes the receptor to diminish the number of insulin receptors thereby increasing the hormone resistance through the decrease of insulin sensitivity leading to diabetes type II.
Essentially, the binding of receptor kinase decreases the activity of the insulin receptor complex. As such, the combination of the signaling effectors to the insulin is reduced because of condensed phosphorylation sites on the insulin receptor as well as inhibition of response on the signaling molecules (Goldstein and Mueller-Wieland 56). Feedback inhibition on the signaling molecule thwarts joining to insulin receptor thereby leading to malfunctioning downstream activation of kinase flow and second messenger indicating passageway. Consequently, decreased glucose transporter fusion to the cell membrane and less transported glucose in the body cells occur.
The activation of second messengers including Ca2+ ions, phosphoinositides, and diacylglycerol is also a common mechanism of multi-protein signal transduction. The messengers move freely through the cytoplasm as well as the membrane. When the second messengers are released, signal intensification, as well as augmented speed in signal transduction, is achieved due to simultaneous interactions with numerous targets in the cells. The receptor makes active a pair of second messenger pathways by breaking phosphoinositide into diacylglycerol and calcium ions (Goldstein and Mueller-Wieland 37). For instance, the Ca2+ ions from the endoplasmic reticulum diffuse through the cell activating other signaling molecules thereby initiating cellular feedback.
Intracellular effects of insulin
Insulin plays a critical role in regulating the delivery of glucose in the body cells to provide energy. As such, in the case of diabetes type II, the cells are unable to absorb glucose and amino acids. The deficiency in the quotient of insulin and glucagon slows down glycolysis. The inhibition of glycolysis reduces energy production (Roper 114). In other words, insulin holds back the discharge of glucagon thereby halting the utilization of fats as a source of energy. Additionally, insulin leads to the control of glucose levels in the blood at a stable ratio.
Actually, insulin is significant in endocrine metabolism. The hormone has diverse cellular effects on the regulation of glucose levels in the blood. Specifically, insulin is invaluable in enhancing the progress of glucose admission into a muscle as well as adipose tissues. Most importantly, hexose transporters make easy the mechanisms through which cells absorb glucose. In particular, the action of insulin is essential for availing GLUT4, the transporters utilized in the uptake of glucose in the plasma membrane (Roper 112). Further, insulin facilitates the process through which amino acids are absorbed for energy and balance in blood sugar at different levels of the hormone.
In circumstances where the concentrations of insulin are stumpy, the GLUT4 transporters play a worthless role in transporting glucose in the cytoplasm vesicles. In fact, the joining of insulin to receptors initiates the fusion of vesicles together with the plasma membrane as well as the incorporation of the GLUT4 transporters. Consequently, the blood cells are capable of taking up glucose effectively.
Another significant cellular impact of insulin is that the hormone facilitates the storage of glucose as glycogen. In essence, insulin triggers hexokinase that traps glucose through phosphorylation. Essentially, insulin hampers the action of glucose-6-phosphatase while activating the activities of phosphofructokinase and glycogen synthase enzymes that are significant in the synthesis of glycogen (Roper 82).
Generally, the effect of insulin entails the lessening of glucose concentration in the blood cells. In other words, the take-up of glucose by body cells for energy depends on the availability of insulin. Additionally, insulin hampers the crashing of adipose tissue by slowing intercellular activities. When the breakdown of fat in adipose tissue is inhibited, hydrolysis of triglycerides to release fatty acids is thwarted.
How diabetes type II affects glucose regulation mechanism
Diabetes type II significantly influences how the body cells normalize blood glucose levels. For instance, in diabetes type II patients, the body is incapable of standardizing the blood glucose levels since there is ineffective functioning between insulin and glucagon. In other words, the body resists insulin, which leads to higher glucose levels in the body and comparative insulin deficit. As a result, excessive insulin is released by the insulin-secreting tumor called insulinoma in the pancreas (Roper 77). The excess release of insulin can be hazardous life since there is a rapid drop in glucose blood levels leading to insulin shock in the brain due to starvation of energy. Additionally, high glucose in the blood cells has adverse effects on glucose metabolism ranging from hardening of arteries to hyperosmolar nonketotic diabetic coma.
Works Cited
Goldstein, Barry J. and Dirk Mueller-Wieland. Type 2 Diabetes: Principles and Practice. Boca Raton, FL: CRC Press, 2013. Print.
Roper, Marcia Ruth. Type 2 Diabetes: The Adrenal Gland Disease. Bloomington, IN: AuthorHouse, 2005. Print.
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