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| - | =='''Insulin Receptor'''== | + | =='''Vitamin D binding protein (1j7e)<ref>PMID: 11799400 </ref>'''== |
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| - | ===Introduction===
| + | Alex Debreceni, Robert Green, Uday Prakhya, Nicholas Rivelli, Elizabeth Swanson |
| - | <Structure load='2dtg' size='500' frame='true' align='right' caption='Insulin receptors are expressed at the cell surface as disulfide-linked homodimers composed of alpha/beta monomers(pdb code 3loh).' scene='Sandbox_Reserved_427/Rcb_dimer_monomers/2' />
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| - | The insulin receptor is a tyrosine kinase, that is a type of ligand-activated receptor kinase. The crystallized protein, shown here, is the <scene name='Sandbox_Reserved_427/Rcb_original_monomer/1'>ectodomain monomer</scene> of the insulin receptor, as it is difficult to crystallize the protein and determine the structure when the greasy transmembrane portion of the protein is included. Four FAB antibodies (shown in peach, yellow, light green, and light blue) are attached to the protein to aid in crystallization. The insulin receptor is <scene name='Sandbox_Reserved_427/Rcb_dimer_betastrand/1'>bound</scene> to the membrane at the <span style="color:orange">'''beta strand'''</span>, which extends through the cell membrane. The receptor is attached to the cell membrane by the beta strand, which extends through the membrane and into the interior of the cell and mediates activity by the addition of phosphate to tyrosines on specific proteins in cell.
| + | [[Student Projects for UMass Chemistry 423 Spring 2016]] |
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| + | <StructureSection load='1j7e' size='350' side='right' caption='caption for Molecular Playground (PDB entry [[1j7e]])' scene=''> |
| - | Insulin receptors are found in many diverse organisms organisms, from cnidarians and insects to humans. In humans, correctly functioning insulin receptors are essential for maintaining glucose levels in the blood. The insulin receptor also has role in growth and development (through insulin growth factor II); studies have shown that signalling through IGF2 plays a role in the mediation embryonic growth. <ref>PMID: 12471165</ref>
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| - | In everyday function, insulin binding leads to increase in the high-affinity glucose transporter (Glut4) molecules on the outer membrane of the cell in muscle and adipose tissue. Glut4 mediates the transport of glucose into the cell, so an increase in Glut4 leads to increased glucose uptake. Insulin has two different receptor-binding surfaces on opposite sides of the molecule, that interact with two different <scene name='Sandbox_Reserved_427/Rcb_dimer_bindinghighlighted/1'>sites on the insulin receptor</scene>. The first binding insulin surface interacts with a site on the <span style="color:blue">'''L1'''</span> module as well as a 120-amino-acid peptide from the insert in <span style="color:red">'''FnIII-2'''</span>. The second binding site consists of resides on the C-terminal portion of <span style="color:aqua">'''L2'''</span> and in the <span style="color:fuchsia">'''FnIII-1'''</span> and <span style="color:red">'''FnIII-2'''</span> modules <ref>PMID: 2657531</ref>. Binding sites are shown <scene name='Sandbox_Reserved_427/Rcb_dimer_bindinghighlighted2/1'>here</scene> highlighted in both monomers of the biologically functional dimer. <ref>PMID: 18991400</ref>
| + | ==Introduction== |
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| - | Maintaining appropriate blood glucose levels is essential for appropriate life-sustaining metabolic function, and insulin receptor malfunction is associated with several severe diseases. Insulin insensitivity, or decreased insulin receptor signalling, leads to diabetes mellitus type 2. Type 2 diabetes is also known as non-insulin-dependent or adult onset diabetes, and is believed to be caused by a combination of obesity and genetic predisposition. In type 2 diabetes, cells are unable to uptake glucose due to decreased insulin receptor signaling, which leads to hyperglycemia (increased circulating glucose). Type 2 diabetes can be managed with dietary and lifestyle modifications to aid in proper metabolism.
| + | <scene name='48/483884/Spacefill_dbp/1'>Vitamin D-Binding Protein</scene> belongs to the albumin gene family. It is a multifunctional protein found in plasma, ascitic fluid, cerebrospinal fluid and other cell types as a surface protein. It is synthesized in the liver and is prevalent throughout the body. DBP is a major carrier of vitamin D3 and all of its metabolites. The active D3 hormone is critical for the maintenance of calcium levels, bone health, and regulates cell proliferation. This makes the D3 hormone of a compound of interest for many therapies, and by conjunction gives importance to DBP which can affect the pharmacokinetics of the D3 hormone. DBP ensures continuous metabolism of D3 hormone derived from human skin cells, and functions as storage for the hormone. Being part of the Human Serum Albumin family, it has similar structural components, however the unique interactions of DBP can be attributed to the arrangement of the helices of <scene name='48/483884/Domain_i/2'>Domain I</scene>, shown in color. Since vitamin D3 analogs have so much potential as therapies, the understanding of DBP’s structure and binding properties could yield brand new in-sites into the workings of vitamin D3 pathways. This would allow the creation of new, more specific therapies centered around vitamin D3 metabolism. |
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| - | Mutations in both copies of the insulin receptor gene causes Donohue syndrome, which is also known as leprechaunism. Donohue syndrome is an autosomal recessive disorder that results in a totally non-functional insulin receptor. The disorder results in distorted facial features, severe growth retardation, and often death within a year.<ref>PMID: 12023989</ref> A less severe mutation of the same gene causes a much milder form of the disease in which there is some insulin resistance but normal growth and subcutaneous fat distribution.<ref>PMID: 8326490</ref> | |
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| - | ===Overall Structure===
| + | ==Overall Structure== |
| - | <Structure load='2dtg' size='500' frame='true' align='right' caption='The Different Domains of the Insulin Receptor Ectodomain' scene='Sandbox_Reserved_427/Ectodomain_dimer/1' />
| + | =====Basic Information===== |
| | + | The secondary structure consists of mainly <scene name="48/483884/Alpha_helices/2">alpha helices</scene>, which can be seen in pink. The quaternary structure of the protein consists of <scene name='48/483884/Twosubunits/1'>two asymmetrical subunits</scene> forming a complex. Due to “significant rotational freedom among the subdomains”[1] the two subunits when superimposed upon one another differ by about 6 degrees of rotation. The structure is about 52.1 kDA in size and made up of 458 amino acids. |
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| - | The ectodomain of the insulin receptor is a <scene name='Sandbox_Reserved_427/Ectodomain_dimer/1'>dimer</scene> of 2 identical monomers. Each v-shaped <scene name='Sandbox_Reserved_427/Kml_monomer6domain/1'>monomer</scene> is composed of 6 domains, three on each side of the V, shown in different colors. The <font color='red'>red</font> <scene name='Sandbox_Reserved_427/Kml_l1domain/1'>Leucine-rich repeat domain</scene> (<font color='red'>L1</font>) is involved in substrate binding. Its main feature is a 6 parallel stranded beta sheet. The <font color='orange'>orange</font> <scene name='Sandbox_Reserved_427/Kml_crdomain/1'>Cysteine-rich region</scene> (<font color='orange'>CR</font>) is composed mostly of loops and turns. The <font color='yellow'>yellow</font> domain is a second <scene name='Sandbox_Reserved_427/Kml_l2domain/1'>Leucine-rich repeat domain</scene>, (<font color='gold'>L2</font>) which contains a five parallel stranded beta sheet and several surface alpha helices. <ref>PMID: 16957736</ref> | + | =====Alpha Helical Domains===== |
| | + | The Vitamin D binding protein consists of <scene name='48/483884/Three_domains/2'>three alpha helical domains</scene> which are homologous to one another (Domain I: Blue, Domain II: Green, Domain III: Purple). <scene name='48/483884/Domain_i/2'>Domain I</scene> containing 10 alpha helices, <scene name='48/483884/Domain_ii/4'>Domain II</scene> 9, and <scene name='48/483884/Domain_iii/3'>Domain III</scene> 4 being shorter than the other domains. |
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| - | The next three domains are Fibronectin Type III domains. Fibronectin domains, characterized by beta sandwiches, are named after the protein fibronectin, which contains 16 of these domains.<ref>PMID: 2992939</ref> The <font color='lime'>green FnIII-1</font> <scene name='Sandbox_Reserved_427/Kml_fniii-1domain/1'>domain</scene>, contains one antiparallel and one mixed beta sheet. The <font color='mediumblue'>blue FnIII-2</font> <scene name='Sandbox_Reserved_427/Kml_fniii-2domain/2'>domain</scene> contains an <font color='deepskyblue'>insert</font> domain of 120 residues. The <font color='mediumorchid'>purple FnIII-3</font> <scene name='Sandbox_Reserved_427/Kml_fniii-3domain/1'>domain</scene> contains just four beta strands. Each domain occurs twice in the <scene name='Sandbox_Reserved_427/Ectodomain_dimer/2'>biological dimer</scene>.<ref>PMID: 16957736</ref> | + | =====Vitamin D Binding Protein and Human Serum Albumin===== |
| | + | The overall structure is closely related to that of the human serum albumin, to which it is homologous. The proteins are very similar yet the three dimensional structure differs somewhat to facilitate binding. The differences are due to bends at the C-terminal alpha-helices of the first and second domains in addition to rotations at the loops connecting the first two domains. |
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| - | The <font color='deepskyblue'>insert</font> domain of the <font color='mediumblue'>FnIII-2</font> domain separates the <font color='silver'>alpha</font> and '''beta''' chains of each monomer. The alpha chain contains the <font color='red'>L1</font>, <font color='orange'>CR</font>, <font color='yellow'>L2</font>, <font color='lime'>FnIII-1</font> domains and part of the <font color='mediumblue'>FnIII-2</font> domain. The beta chain contains the rest of the <font color='mediumblue'>FnIII-2</font> domain and the <font color='orchid'>FnIII-3</font> domain. The <font color='deepskyblue'>insert</font> domain starts and ends with a cleavage site where the chain is cut. The alpha and beta chains are then linked by a single <scene name='Sandbox_Reserved_427/Kl_disulphide/1'>disulphide bond</scene> between <font color='hotpink'>cysteines C647 and C860</font>, leaving the <font color='deepskyblue'>insert</font> domain as a separate peptide which forms disulphide bonds with cysteines in the <font color='lime'>FnIII-1</font> domain. The alpha chain lies completely on the exterior of the cell, while the end of the beta chain extends through the cell membrane and is involved in signaling.<ref>PMID: 20348418</ref> This section of the beta chain, after the <font color='orchid'>FnIII-3</font> domain in the sequence, is not shown in the structure which reflects only the <scene name='Sandbox_Reserved_427/Ectodomain_dimer/2'>ectodomain</scene>. There are few interactions between the two legs of the monomer- just two salt bridges near the connection between the <font color='yellow'>L2</font> and <font color='lime'>FnIII-1</font> domains. However there are many interactions between the two monomers including salt bridges and disulphide bonds.<ref>PMID: 16957736</ref>
| + | =====Actin Binding===== |
| | + | The tertiary structure of the protein is optimized for it binding with actin, efficiently folding into a complex requiring little change of the structure. Once DPB binds to actin, the C-terminal alpha helix of the first domain and the loop between the second and third domain move to be in contact with the actin. The binding of actin to the <scene name='48/483884/Dbp/1'>DBP</scene> differs from that of its homolog <scene name='48/483884/Hsa/3'>HSA</scene> in the conformational changes that the protein undergoes, which can be attributed to differences in rotation in the first domain and the region between domain II III. Both green scenes are depicted with the same color scheme seen below. |
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| - | This structure is significant relative to previous structures for the protein because of the relative position of the <font color='red'>L1</font> domains in the two monomers of the biological unit. In previously proposed structures, the <font color='yellow'>L2</font>, <font color='orange'>CR</font>, and <font color='red'>L1</font> domains formed a straight leg of the V similar to that of the fibronectin leg. With this model, it was thought that both <font color='red'>L1</font> domains could bind to a single insulin molecule. With this folded over structure of the <font color='yellow'>L2</font>-<font color='orange'>CR</font>-<font color='red'>L1</font> leg, it is clear that this is not the case, as the <font color='red'>L1</font> domains of each monomer face away from each other.<ref>PMID: 16957736</ref>
| + | {{Template:ColorKey_N52C3Rainbow}} |
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| - | ===Binding Interactions=== | |
| - | <Structure load='2dtg' size='500' frame='true' align='right' caption='Depicted here is the monomer form of human insulin. The hydrophilic residues are shown in purple and the hydrophobic residues are shown in gray.' scene='Sandbox_Reserved_427/Insulin/2' /> | |
| - | The insulin receptor's (IR) main substrate is insulin, which is referred to as insulin receptor substrate 1 (IRS-1). As insulin binds to the IR, the IR is phosphorylated. Phosphorylation of tyrosine residues in the IR leads to an increase in the glucose transporter (Glut-4) which has a high affinity for glucose molecules. This occurs mainly in muscle and adipose (fat) tissues where glucose uptake is most needed. This increase in Glut-4 causes an increase in glucose uptake from blood. Simply stated, 3loh is activated by insulin (IRS-1) which signals for an increase in Glut-4. Glut-4 finds its way to the cell surface where it can perform its function and transport glucose into the cell. | |
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| - | The binding mechanism and site are not completely understood. What is known, however, is that insulin is able to bind at two different locations on each monomer of the insulin receptor. Since there are two monomers in the biologically functional ectodomain, there are in total four locations available for binding and interaction. These locations are explained in the Introduction section of this page. Current literature describes the locations for insulin binding as follows: the region between L1 and Fn2 as site 1, the region involving L2, Fn1, and Fn2 as site 2. Based on knowledge of the structure of the insulin receptor (it is a dimer with anti-mirrored symmetry), one can see that the site 1 of one monomer will be adjacent to site 2 on the other. In order to eliminate confusion, most literature refer to the binding sites across from site 1 and site 2 as site 2' and site 1', respectively. One of the most popular theories that is used to explain insulin binding describes that two molecules of insulin must bind to the IR in order for it to become active and for the kinase cascade to initiate. In this case, binding of two insulin molecules would occur at sites 1/2' and 2/1'. This is only a theory, however, and none of these theories have been completely confirmed <ref>PMID: 19274663</ref>.
| + | ==Binding Interactions== |
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| - | Recent research has indicated that it may be possible that both the structure of the insulin receptor and the structure of insulin itself may change upon binding. It is also thought that insulin may possess multiple surfaces that are capable of binding to the functional ectodomain.
| + | '''The Vitamin D Binding Site''' |
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| - | In order to better understand the binding of the insulin receptor, it would make sense to observe its main substrate, <scene name='Sandbox_Reserved_427/Insulin/2'>insulin</scene>. This green scene shows both the <font color='gray'>hydrophobic</font> and <font color='magenta'>hydrophilic</font> residues. The binding surface is mostly comprised of residues that are hydrophobic.
| + | The Vitamin D binding site is located in domain I and contains helices 1 through 6. The binding site is lined with hydrophobic residues that interact with the hydrophobic parts of the vitamin D3 ligand.<scene name='48/483884/Site_where_25ohd3_binds/3'>Hydrogen Bonds</scene>(locations highlighted in yellow) are formed between, the 25-hydroxyl and Tyr 32 with a distance of 2.85 angstroms, the 3-hydroxyl and Ser 76 with a distance of 3.01 angstroms and Met 109 with a distance of 3.01 angstroms.[1] Different analogs of the vitamin D3 ligand influence hydrogen bond locations and binding affinities. <scene name='48/483884/Jy_site_where_25ohd3_binds/5'>The JY analog</scene>(yellow), for example, has a binding affinity to DBP of 1314, which is much greater compared to the affinity of 25OHD3, which is 667.[1] This is due to the <scene name='48/483884/Stacking_stabilization_with_jy/3'>stacking of the aromatic sidechain of JY</scene> and the aromatic residues of Phe 24, Tyr 34, Phe 36, and Tyr 38. The JX analog switches the meta hydroxyl group on JY to para, increasing the binding affinity to 2111. By switching the hydroxyl group to the para position tighter hydrogen bonds can be formed to the Ser 28 residue stabilizing the complex.[1] |
| | + | '''Biological Relevance of The Vitamin D Binding Site''' |
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| - | Another interesting point to mention is that insulin in its <scene name='Sandbox_Reserved_427/Insulin_hexamer/5'>hexamer form</scene> can also interact with the binding sites available on the insulin receptor. Hexamers of insulin are found in the pancreas and help store insulin. They consist of 3 <font color='red'>insulin dimers</font> that are held together by 2 <font color='blue'>Zn ions</font>.Upon creating the hexamer form, a new binding surface for insulin is created that exhibits normal binding at site 1. Binding does not occur at site 2 however, and thus the hexamer form of insulin does not activate the insulin receptor as does regular form of insulin. Here is a <scene name='Sandbox_Reserved_427/Insulin_hexamer_highlight/2'>green scene</scene> that highlights the second binding surface. The second binding surface is highlighted on one of the three dimers and involves a small group of specific residues: SerA12, LeuA13, GluA17, HisB10, GluB13, and LeuB17 <ref>PMID: 19274663</ref>.
| + | Vitamin D hormone 1,25(OH)2D3 used to treat renal osteodystrophy, hypoparathyroidism and osteoporosis. Administration of 1,25(OH)2D3 is limited due severe side effects, such as hypercalciuria, hypercalcemia and increased bone resorption.[1] The analogs of 1,25(OH)2D3 are being created to increase the activity and bind affinity without out the negative side effects. |
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| - | ===Additional Features=== | |
| - | <Structure load='2dtg' size='500' frame='true' align='right' caption='Shown above is the Insert Domain in green within the homodimer' scene='Sandbox_Reserved_427/Insert_domain/3' /> | |
| - | Interestingly, the molecular basis as to how insulin binds to the insulin receptor substrate (IRS) is not yet fully understood. However, there has been some light shed on the kinase cascade pathway that insulin induces. | |
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| - | Recently, studies have shown that poor diet and increased sugar intake have led to a halt in the kinase cascade pathway, leading to what is now termed as insulin resistance. | |
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| - | Insulin Resistance: Happens when the cells essentially don't open the door when insulin comes knocking. When this happens, the body puts out more insulin to stabilize blood glucose in the body. This allows for a vicious cycle where the cells become more and more desensitized as the concentration of insulin increases to tackle the constant influx of glucose. This occurs when the insulin receptor cannot activate the glucose transporter (Glut-4) vesicles through the kinase cascade in order for Glut-4 to bind to the cell membrane and bring in glucose. <ref>PMID:10675357</ref>
| + | ==Additional Features== |
| | + | =====Actin Binding Interactions===== |
| | + | The most well documented auxiliary function of Vitamin D binding protein is its ability to bind and sequester circulating actin monomers. [4] The actin interaction occur at the sites shown in <scene name='48/483884/Dbp_actin_binding_site/2'>red</scene>. While the vitamin D binding domain resides between leucine 35 and serine 49, the actin binding domain lies far away in sequence, between glycine 373 and glycine 403, the site is <scene name='48/483884/Dbp_actin_dbinding_distance/1'>much closer</scene> in the folded protein, with residues serine 42 and lysine 388 only 21.44Å apart on complementary subunits or 43.58Å apart on the same subunit. |
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| - | Mechanism: When insulin binds it phosphorylates the IRS, leading to a kinase cascade pathway that ineveitably activates Glut-4 to bind to the cell membrane. Naturally, once the blood glucose has reached a normal level, the kinases are then dephosphorylated, which in turn slowly lowers the amount of glucose channels on the membrane surface. This is the normal negative feedback loop that takes place within the cell. However, when sugar intake is too high for too long, the amount of stored glucose (glycogen) will reach levels where the cell will try to stop the kinase pathway at any point necessary. At this point, the IRS will not be able to perform signal transduction even with the binding of insulin, proving insulin to be ineffective. In response to the increase in blood glucose, the Pancreas cranks out insulin in an attempt to lower blood glucose, when the binding interaction with IRS will essentially do nothing. In the end, all of the kinases become stuck in the dephosphorylated state even with high concentrations of insulin, and no glucose can be stored. The traffic jam will either kill the cell, or if glucose intake recedes, the cell can try to restore itself to its normal feedback loop. <ref>Zick, Y. ''Biochemical Society''. '''2004''', ''32'', 812-816</ref>
| + | At the level of the organism, this actin binding of DBP is an important mechanism for clearing actin from necrotic or apoptotic tissue [1]. This actin binding quality serves to prevent clotting and actin toxicity, as large quantities of circulating actin have been shown to be fatal to mice. |
| | + | [4] Interestingly enough, DBP -/- mice are phenotypically normal and physically indistinguishable from normal mice, indicating that there may be other mechanisms and proteins involved in actin sequestration. [4] |
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| - | So what's the cure?
| + | =====Immune Function and Macrophage Activation===== |
| | + | As the name suggests, macrophages (loosely translated from Greek as “big glutton”) are a class of white blood cells that move through the bloodstream and extracellular matrix in search of large debris and pathogens. They have been known to endocytose just about any foreign material that it does not recognize as self, including a wide range of microbes, cancer cells, and other debris. They are also important in antibody formation, as they often carry the instructions for how to destroy cells they have eaten. |
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| - | Extensive research has been conducted to see if the IRS can bind to other proteins which can then induce the kinase cascade pathway. In one experiment, the <scene name='Sandbox_Reserved_427/Insert_domain/3'>Insert Domain</scene> within the IRS has shown to exhibit binding to the active sites of the IRS. It does so through what has been hypothesized to be <scene name='Sandbox_Reserved_427/Trans_crosslinking/2'>trans crosslinking</scene> between the two monomers in the homodimer. The actual peptide connecting one piece of the insert domain to the other has yet to be resolved, however the binding portion of the insert domain has been <scene name='Sandbox_Reserved_427/Binding_site_of_insert_domain/1'>located</scene> to be at Site 1, between the <font color='red'>L1</font> and <font color='hotpink'>FnIII-2</font> domains. Since insulin binds to Site 1 as well, it is also hypothesized that the binding portion of the insert domain competitively binds with the insulin protein because of its mimical structure to insulin. This is quite an important discovery, because a compound that can mimic the structure of insulin could have a higher affinity for the IRS, which could activate the signal transduction pathway. Therefore, the IRS may provide a target for a drug, perhaps also achievable in part by molecules the size of antibiotics. <ref>PMID:20348418</ref>
| + | DBP plays a role in macrophage activation through its conversion within immune cells to a compound called macrophage activating factor (MAF). At the site of the wound various immune cells act on DBP and deglycosylate it at several sites along the backbone. [6] This factor is important in the recruitment of macrophages to wound sites and other potential areas of infection. [6] Taking into account the above mention that DBP is important for clearing actin from wound sites, it makes logical sense that it would also be able to be easily converted to an endocrine or paracrine signal in this manner. [1] |
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| - | Best solution? Eat Healthy! Reducing sugar intake by eating less sweets should cause a break down of excess glycogen, returning cells to normal over time.
| + | ==Quiz Question 1== |
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| - | ===Credits=== | |
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| - | Introduction - Rebecca Bishop
| + | <scene name='48/483884/Cartoondpb/1'>Vitamin D Binding Protein</scene>. is very similar to <scene name='48/483884/Cartoonhsa/1'>Human Serum Albumin(HSA)</scene>based on sequence similarity as well as a similar tertiary structure. The two proteins can both bind to actin, however HSA is unable to bind to Vitamin D3. Based on what you have learned about the binding nature DBP, and looking at the structures of the two proteins, hypothesize a reason why HSA cannot bind to Vitamin D3. How can altering only a couple of amino acids so greatly alter the function and tertiary structure of proteins? |
| | + | ==See Also== |
| | + | *[[1kxp]] |
| | + | *[[1kw2]] |
| | + | *[[1j7e]] |
| | + | *[[1j78]] |
| | + | *[[1ma9]] |
| | + | *[[1lot]] |
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| - | Overall Structure - Kathryn Liedell
| + | ==Credits== |
| | | | |
| - | Drug Binding Site - Ryan Deeney
| + | Introduction - Uday Prakhya |
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| - | Additional Features - Jeffrey Boerth
| + | Overall Structure - Elizabeth Swanson |
| | | | |
| - | ===References===
| + | Drug Binding Site - Alex Debreceni |
| | + | |
| | + | Additional Features - Nick Rivelli |
| | + | |
| | + | Quiz Question 1 - Robert Green |
| | + | |
| | + | ==References== |
| | <references/> | | <references/> |
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| | + | [http://www.ncbi.nlm.nih.gov/pubmed/15245906] Gomme PT, Bertolini J. 2004. Therapeutic potential of vitamin D-binding protein. Trends Biotechnol. 22:340–345. |
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| | + | [http://www.ncbi.nlm.nih.gov/pubmed/7626513] Haddad JG. 1995. Plasma vitamin D-binding protein (Gc-globulin): Multiple tasks. J. Steroid Biochem. Mol. Biol. 53:579–582. |
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| | + | [http://www.ncbi.nlm.nih.gov/pubmed/12048248] Otterbein LR, Cosio C, Graceffa P, Dominguez R. 2002. Crystal structures of the vitamin D-binding protein and its complex with actin: structural basis of the actin-scavenger system. Proc. Natl. Acad. Sci. U. S. A. 99:8003–8008. |
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| | + | [http://www.ncbi.nlm.nih.gov/pubmed/16697362] Speeckaert M, Huang G, Delanghe JR, Taes YEC. 2006. Biological and clinical aspects of the vitamin D binding protein (Gc-globulin) and its polymorphism. Clin. Chim. Acta 372:33–42. |
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| | + | [http://www.ncbi.nlm.nih.gov/pubmed/16697362] Verboven C, Rabijns A, De Maeyer M, Van Baelen H, Bouillon R, De Ranter C. 2002. A structural basis for the unique binding features of the human vitamin D-binding protein. Nat. Struct. Biol. 9:131–6. |
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| | + | [http://www.ncbi.nlm.nih.gov/pubmed/10996527] White P, Cooke N. 2000. The multifunctional properties and characteristics of vitamin D-binding protein. Trends Endocrinol. Metab. 11:320–327. |
