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The insulin transduction pathway is a biochemical pathway by which
insulin Insulin (, from Latin ''insula'', 'island') is a peptide hormone produced by beta cells of the pancreatic islets encoded in humans by the ''INS'' gene. It is considered to be the main anabolic hormone of the body. It regulates the metabolism o ...
increases the uptake of glucose into fat and muscle cells and reduces the
synthesis Synthesis or synthesize may refer to: Science Chemistry and biochemistry *Chemical synthesis, the execution of chemical reactions to form a more complex molecule from chemical precursors ** Organic synthesis, the chemical synthesis of organ ...
of glucose in the liver and hence is involved in maintaining
glucose homeostasis Blood sugar regulation is the process by which the levels of blood sugar, primarily glucose, are maintained by the body within a narrow range. This tight regulation is referred to as glucose homeostasis. Insulin, which lowers blood sugar, and ...
. This pathway is also influenced by fed versus fasting states,
stress levels Stress may refer to: Science and medicine * Stress (biology), an organism's response to a stressor such as an environmental condition * Stress (linguistics), relative emphasis or prominence given to a syllable in a word, or to a word in a phrase ...
, and a variety of other
hormones A hormone (from the Ancient Greek, Greek participle , "setting in motion") is a class of cell signaling, signaling molecules in multicellular organisms that are sent to distant organs by complex biological processes to regulate physiology and beh ...
. When
carbohydrates In organic chemistry, a carbohydrate () is a biomolecule consisting of carbon (C), hydrogen (H) and oxygen (O) atoms, usually with a hydrogen–oxygen atom ratio of 2:1 (as in water) and thus with the empirical formula (where ''m'' may or may ...
are consumed, digested, and absorbed the pancreas senses the subsequent rise in blood glucose concentration and releases
insulin Insulin (, from Latin ''insula'', 'island') is a peptide hormone produced by beta cells of the pancreatic islets encoded in humans by the ''INS'' gene. It is considered to be the main anabolic hormone of the body. It regulates the metabolism o ...
to promote uptake of glucose from the bloodstream. When insulin binds to the insulin receptor, it leads to a cascade of cellular processes that promote the usage or, in some cases, the storage of glucose in the cell. The effects of insulin vary depending on the tissue involved, e.g., insulin is most important in the uptake of glucose by
muscle Skeletal muscles (commonly referred to as muscles) are organs of the vertebrate muscular system and typically are attached by tendons to bones of a skeleton. The muscle cells of skeletal muscles are much longer than in the other types of muscl ...
and adipose tissue. This insulin signal transduction pathway is composed of trigger mechanisms (e.g., autophosphorylation mechanisms) that serve as signals throughout the cell. There is also a counter mechanism in the body to stop the secretion of insulin beyond a certain limit. Namely, those counter-regulatory mechanisms are glucagon and epinephrine. The process of the regulation of blood glucose (also known as
glucose homeostasis Blood sugar regulation is the process by which the levels of blood sugar, primarily glucose, are maintained by the body within a narrow range. This tight regulation is referred to as glucose homeostasis. Insulin, which lowers blood sugar, and ...
) also exhibits oscillatory behavior. On a pathological basis, this topic is crucial to understanding certain disorders in the body such as diabetes,
hyperglycemia Hyperglycemia is a condition in which an excessive amount of glucose circulates in the blood plasma. This is generally a blood sugar level higher than 11.1 mmol/L (200  mg/dL), but symptoms may not start to become noticeable until even ...
and hypoglycemia.


Transduction pathway

The functioning of a signal transduction pathway is based on extra-cellular signaling that in turn creates a response that causes other subsequent responses, hence creating a chain reaction, or cascade. During the course of signaling, the cell uses each response for accomplishing some kind of a purpose along the way. Insulin secretion mechanism is a common example of
signal transduction Signal transduction is the process by which a chemical or physical signal is transmitted through a cell as a series of molecular events, most commonly protein phosphorylation catalyzed by protein kinases, which ultimately results in a cellula ...
pathway mechanism. Insulin is produced by the pancreas in a region called Islets of Langerhans. In the islets of Langerhans, there are beta-cells, which are responsible for production and storage of insulin. Insulin is secreted as a response mechanism for counteracting the increasing excess amounts of glucose in the blood. Glucose in the body increases after food consumption. This is primarily due to carbohydrate intake, but to a much lesser degree protein intake

. Depending on the tissue type, the glucose enters the cell through facilitated diffusion or active transport. In muscle and adipose tissue, glucose enters through GLUT 4 receptors via facilitated diffusion

. In brain, retina, kidney, RBC, placenta and many other organs, glucose enters using GLUT 1 and GLUT 3. In the beta-cells of the pancreas and in liver cells, glucose enters through the GLUT 2 receptors (process described below).


Insulin biosynthesis and transcription

Insulin biosynthesis is regulated by transcriptional and translational levels. The β-cells promote their protein transcription in response to nutrients. The exposure of rat Langerhans islets to glucose for 1 hour is able to remarkably induce the intracellular proinsulin levels. It was noted that the proinsulin mRNA remained stable. This suggests that the acute response to glucose of the insulin synthesis is independent of mRNA synthesis in the first 45 minutes because the blockage of the transcription decelerated the insulin accumulation during that time. PTBPs, also called Polypyrimidine tract binding proteins, are proteins that regulate the translation of mRNA. They increase the viability of mRNA and provoke the initiation of the translation. PTBP1 enable the insulin gene-specific activation and insulin granule protein mRNA by glucose. Two aspects of the transduction pathway process are explained below: insulin secretion and insulin action on the cell.


Insulin secretion

The glucose that goes into the bloodstream after food consumption also enters the beta cells in the Islets of Langerhans in the pancreas. The glucose diffuses in the beta-cell facilitated by a Glucose transporter, GLUT-2 vesicle. Inside the beta cell, the following process occurs: Glucose gets converted to Glucose-6-Phosphate (G6P) through Glucokinase, and G6P is subsequently oxidized to form
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. This process inhibits the ATP-sensitive potassium ion channels of the cell causing the Potassium ion channel to close and not function anymore. The closure of the ATP-sensitive potassium channels causes depolarization of the cell membrane causing the cell membrane to stretch which causes the voltage-gated
calcium channel A calcium channel is an ion channel which shows selective permeability to calcium ions. It is sometimes synonymous with voltage-gated calcium channel, although there are also ligand-gated calcium channels. Comparison tables The following tables e ...
on the membrane to open causing an influx of Ca2+ ions. This influx then stimulates fusion of the insulin vesicles to the cell membrane and secretion of insulin in the extracellular fluid outside the beta cell; thus making it enter the bloodstream. lso Illustrated in Figure 1.1.1 There are 3 subfamilies of Ca+2 channels; L-type Ca+2 channels, Non-L-Type Ca+2 channels (including R-Type) and the T-type Ca+2 channels. There are two phases of the insulin secretion, the first phase involves the L-type Ca+2 channels and the second phase involves the R-type Ca+2 channels. The Ca+2 influx generated by R-type Ca+2 channels is not enough to cause insulin exocytosis, however, it increases the mobilization of the vesicles towards the cell membrane.


Fatty acids and insulin secretion

Fatty acids also affect insulin secretion. In type 2 diabetes, fatty acids are able to potentiate insulin release to compensate the increment need of insulin. It was found that the β-cells express free fatty acid receptors at their surface, through which fatty acids can impact the function of β-cells. Long-chain acyl-CoA and DAG are the metabolites resulting from the intracellular metabolism of fatty acids. Long-chain acyl-CoA has the ability to acylate proteins that are essential in the insulin granule fusion. On the other hand, DAG activates PKC that is involved in the insulin secretion.


Hormonal regulation of insulin secretion

Several hormones can affect insulin secretion. Estrogen is correlated with an increase of insulin secretion by depolarizing the β-cells membrane and enhancing the entry of Ca+2. In contrast, growth hormone is known to lower the serum level of insulin by promoting the production of insulin-like growth factor-I (IGF-I). IGF-I, in turn, suppresses the insulin secretion.


Action on the cell

After insulin enters the bloodstream, it binds to a membrane-spanning receptor tyrosine kinase (RTK). This glycoprotein is embedded in the cellular membrane and has an extracellular receptor domain, made up of two α-subunits, and an intracellular catalytic domain made up of two β-subunits. The α-subunits act as insulin receptors and the insulin molecule acts as a ligand. Together, they form a receptor-ligand complex. Binding of insulin to the α-subunit results in a conformational change of the protein, which activates tyrosine kinase domains on each β-subunit. The tyrosine kinase activity causes an autophosphorylation of several tyrosine residues in the β-subunit. The phosphorylation of 3 residues of tyrosine is necessary for the amplification of the kinase activity. This autophosphorylation triggers the activation of the docking proteins, in this case IRS (1-4) on which Phosphatidylinositol-3-Kinase (PI-3K) can be attached or GRB2 where the ras Guanine nucleotide exchange factor (GEF) (also known as
SOS is a Morse code distress signal (), used internationally, that was originally established for maritime use. In formal notation is written with an overscore line, to indicate that the Morse code equivalents for the individual letters of "SOS" ...
) can be attached. PI-3K causes the phosphorylation of PIP2 to PIP3. This protein acts as a docking site for
PDPK1 In the field of biochemistry, PDPK1 refers to the protein 3-phosphoinositide-dependent protein kinase-1, an enzyme which is encoded by the ''PDPK1'' gene in humans. It is implicated in the development and progression of melanomas. Function PD ...
and
Protein kinase B Protein kinase B (PKB), also known as Akt, is the collective name of a set of three serine/threonine-specific protein kinases that play key roles in multiple cellular processes such as glucose metabolism, apoptosis, cell proliferation, transc ...
(also known as AKT), which is then phosphorylated by the latter and PK2 to be activated. This leads to crucial metabolic functions such as synthesis of lipids, proteins and glycogen. It also leads to cell survival and cell proliferation. Most importantly, the PI-3K pathway is responsible for the distribution of glucose for important cell functions. For example, the suppression of hepatic glucose synthesis and the activation of glycogen synthesis. Hence, AKT possesses a crucial role in the linkage of the glucose transporter ( GLUT4) to the insulin signaling pathway. The activated GLUT4 will translocate to the cell membrane and promotes the transportation of glucose into the intracellular medium. The Ras-GEF stimulates the exchange of GDP to GTP in the RAS protein, causing it to activate. Ras then activates the
Mitogen-activated protein kinase A mitogen-activated protein kinase (MAPK or MAP kinase) is a type of protein kinase that is specific to the amino acids serine and threonine (i.e., a serine/threonine-specific protein kinase). MAPKs are involved in directing cellular responses to ...
(MAP-Kinase) route, which ultimately results in changes in protein activity and gene expression. Thus, insulin's role is more of a promoter for the usage of glucose in the cells rather than neutralizing or counteracting it.


Regulation of the insulin receptor signal

PI-3K is one of the important components in the regulation of the insulin signaling pathway. It maintains the insulin sensitivity in the liver. PI-3K is composed of a regulatory subunit (P85) and a catalytic subunit (P110). P85 regulates the activation of PI-3K enzyme. In the PI-3K heterodimer (P85-p110), P85 is responsible for the PI-3K activity, by binding to the binding site on the insulin receptor substrates (IRS). It was noted that an increase of P85 a (isoform of P85) results in a competition between the later and the P85-P110 complex to the IRS binding site, reducing the PI-3k activity and leading to insulin resistance. Insulin resistance refers also to Type 2 diabetes. It was also noted that increased serine phosphorylation of IRS is involved in the insulin resistance by reducing their ability to attract PI3K. The serine phosphorylation can also lead to degradation of IRS-1.


Feedback mechanisms

Signal transduction Signal transduction is the process by which a chemical or physical signal is transmitted through a cell as a series of molecular events, most commonly protein phosphorylation catalyzed by protein kinases, which ultimately results in a cellula ...
is a mechanism in which the cell responds to a signal from the environment by activating several proteins and enzymes that will give a response to the signal.
Feedback Feedback occurs when outputs of a system are routed back as inputs as part of a chain of cause-and-effect that forms a circuit or loop. The system can then be said to ''feed back'' into itself. The notion of cause-and-effect has to be handled ...
mechanism might involve negative and positive feedbacks. In the negative feedback, the pathway is inhibited and the result of the transduction pathway is reduced or limited. In positive feedback, the transduction pathway is promoted and stimulated to produce more products.


Positive

Insulin secretion results in positive feedback in different ways. Firstly, insulin increases the uptake of glucose from blood by the translocation and
exocytosis Exocytosis () is a form of active transport and bulk transport in which a cell transports molecules (e.g., neurotransmitters and proteins) out of the cell ('' exo-'' + ''cytosis''). As an active transport mechanism, exocytosis requires the use o ...
of GLUT4 storage vesicles in the muscle and fat cells. Secondly, it promotes the conversion of glucose into triglyceride in the liver, fat, and muscle cells. Finally, the cell will increase the rate of glycolysis within itself to break glucose in the cell into other components for tissue growth purposes. An example of positive feedback mechanism in the insulin transduction pathway is the activation of some enzymes that inhibit other enzymes from slowing or stopping the insulin transduction pathway which results in improved intake of the glucose. One of these pathways, involves the PI(3)K enzyme (
Phosphoinositide 3-kinase Phosphoinositide 3-kinases (PI3Ks), also called phosphatidylinositol 3-kinases, are a family of enzymes involved in cellular functions such as cell growth, proliferation, differentiation, motility, survival and intracellular trafficking, which i ...
). This pathway is responsible for activating glycogen, lipid-protein synthesis, and specific gene expression of some proteins which will help in the intake of glucose. Different enzymes control this pathway. Some of these enzymes constrict the pathway causing a negative feedback like the GSK-3 pathway. Other enzymes will push the pathway forward causing a positive feedback like the AKT and P70 enzymes. When insulin binds to its receptor, it activates the glycogen synthesis by inhibiting the enzymes that slow down the PI(3)K pathway such as PKA enzyme. At the same time, it will promote the function of the enzymes that provide a positive feedback for the pathway like the AKT and P70 enzymes. The inactivation of the enzymes that stop the reaction and activating of enzymes that provide a positive feedback will increase glycogen, lipid & protein syntheses and promote glucose intake.
Image to help explain the function of the proteins mentioned above in the positive feedback.


Negative

When insulin binds to the cell's receptor, it results in negative feedback by limiting or stopping some other actions in the cell. It inhibits the release and production of glucose from the cells which is an important part in reducing the glucose blood level. Insulin will also inhibit the breakdown of glycogen into glucose by inhibiting the expression of the enzymes that catalyzes the degradation of
Glycogen Glycogen is a multibranched polysaccharide of glucose that serves as a form of energy storage in animals, fungi, and bacteria. The polysaccharide structure represents the main storage form of glucose in the body. Glycogen functions as one o ...
. An example of negative feedback is slowing or stopping the intake of glucose after the pathway was activated. Negative feedback is shown in the insulin signal transduction pathway by constricting the phosphorylation of the insulin-stimulated tyrosine. The enzyme that deactivates or phosphorylates the insulin-stimulated tyrosine is called tyrosine phosphatases (PTPases). When activated, this enzyme provides a negative feedback by catalyzing the dephosphorylation of the insulin receptors. The dephosphorylation of the insulin receptor slows down glucose intake by inhibiting the activation (phosphorylation) of proteins responsible for further steps of the insulin transduction pathway.


Trigger mechanism

Insulin is synthesized and secreted in the beta cells of the islets of Langerhans. Once insulin is synthesized, the beta cells are ready to release it in two different phases. As for the first phase, insulin release is triggered rapidly when the blood glucose level is increased. The second phase is a slow release of newly formed vesicles that are triggered regardless of the blood sugar level. Glucose enters the beta cells and goes through glycolysis to form ATP that eventually causes depolarization of the beta cell membrane (as explained in Insulin secretion section of this article). The depolarization process causes voltage-controlled calcium channels (Ca2+) opening, allowing the calcium to flow into the cells. An increased calcium level activates phospholipase C, which cleaves the membrane phospholipid phosphatidylinositol 4,5-bisphosphate into Inositol 1,4,5-trisphosphate (IP3) and diacylglycerol (DAG). IP3 binds to receptor proteins in the membrane of the endoplasmic reticulum (ER). This releases (Ca2+) from the ER via IP3 gated channels, and raises the cell concentration of calcium even more. The influx of Ca2+ ions causes the secretion of insulin stored in vesicles through the cell membrane. The process of insulin secretion is an example of a trigger mechanism in a signal transduction pathway because insulin is secreted after glucose enters the beta cell and that triggers several other processes in a chain reaction.


Counter mechanism


Function of glucagon

While insulin is secreted by the pancreas to lower blood glucose levels, glucagon is secreted to raise blood glucose levels. This is why glucagon has been known for decades as a counter-regulatory hormone. When blood glucose levels are low, the pancreas secretes glucagon, which in turn causes the liver to convert stored glycogen polymers into glucose monomers, which is then released into the blood. This process is called glycogenolysis. Liver cells, or hepatocytes, have glucagon receptors which allow for glucagon to attach to them and thus stimulate glycogenolysis. Contrary to insulin, which is produced by pancreatic β-cells, glucagon is produced by pancreatic α-cells. It is also known that an increase in insulin suppresses glucagon secretion, and a decrease in insulin, along with low glucose levels, stimulates the secretion of glucagon.


Oscillatory behavior

When blood glucose levels are too low, the pancreas is signaled to release glucagon, which has essentially the opposite effect of insulin and therefore opposes the reduction of glucose in the blood. Glucagon is delivered directly to the liver, where it connects to the glucagon receptors on the membranes of the liver cells, signals the conversion of the
glycogen Glycogen is a multibranched polysaccharide of glucose that serves as a form of energy storage in animals, fungi, and bacteria. The polysaccharide structure represents the main storage form of glucose in the body. Glycogen functions as one o ...
already stored in the liver cells into glucose. This process is called
glycogenolysis Glycogenolysis is the breakdown of glycogen (n) to glucose-1-phosphate and glycogen (n-1). Glycogen branches are catabolized by the sequential removal of glucose monomers via phosphorolysis, by the enzyme glycogen phosphorylase. Mechanism The ...
. Conversely, when the blood glucose levels are too high, the pancreas is signaled to release insulin. Insulin is delivered to the liver and other tissues throughout the body (e.g., muscle, adipose). When the insulin is introduced to the liver, it connects to the insulin receptors already present, that is tyrosine kinase receptor. These receptors have two alpha subunits (extracellular) and two beta subunits (intercellular) which are connected through the cell membrane via disulfide bonds. When the insulin binds to these alpha subunits, 'glucose transport 4' (GLUT4) is released and transferred to the cell membrane to regulate glucose transport in and out of the cell. With the release of GLUT4, the allowance of glucose into cells is increased, and therefore the concentration of blood glucose might decrease. This, in other words, increases the utilization of the glucose already present in the liver. This is shown in the adjacent image. As glucose increases, the production of insulin increases, which thereby increases the utilization of the glucose, which maintains the glucose levels in an efficient manner and creates an oscillatory behavior.


References

{{Reflist Molecular biology