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This Sandbox is Reserved from January 19, 2016, through August 31, 2016 for use for Proteopedia Team Projects by the class Chemistry 423 Biochemistry for Chemists taught by Lynmarie K Thompson at University of Massachusetts Amherst, USA. This reservation includes Sandbox Reserved 425 through Sandbox Reserved 439.

Vitamin D receptor/vitamin D (1db1)^[1]

by Roger Crocker, Kate Daborowski, Patrick Murphy, Benjamin Rizkin and Aaron Thole

Student Projects for UMass Chemistry 423 Spring 2016

1 Introduction
2 Overall Structure
3 Binding Interactions
4 Additional Features
5 Quiz Question 1
6 See Also
7 Credits
8 References

Introduction

The (VDR) is a ligand-dependent transcriptional regulator with two strands. VDR belongs to the superfamily of nuclear receptors which control homeostasis, cell differentiation and growth, and many physiological processes. All proteins that belong to the nuclear receptor superfamily have a variable N-terminus region (A/B region), a hinge region that is flexible (D region), a conserved DNA-binding region (DBD, C region), and a moderately conserved ligand-binding region (LBD, E/F region). In the case of VDR, the A/B region is very short so it does not have any AF-1 function and the ligand binding region has a dimerization interface and a transcriptional activation domain that is ligand-dependent (AF-2).[1]

The VDR has both an active and suppressed form. The activation or suppression function is caused by the binding of the DR3 response element as a heterodimer with the retinoid X receptor of the target genes. Due to the interactions with the basal transcriptional machinery and transcriptional cofactors, transcription is either activated or suppressed. When VDR is in its active form it regulates both phosphate and calcium metabolism, has immunosuppressive effects, and induces cell differentiation. When there are defects in the VDR that effect its metabolism it can lead to diseases such as severe rickets, secondary hyperparathyroidism, and hypocalcemia. Though defects in VDR can cause many diseases, fully functioning VDR can be used as treatment for disease such as cancer, autoimmune disease, psoriasis, osteoporosis, and renal osteodystrophy.[1]

Overall Structure

The contains 427 amino acids with a total molecular weight of 48,289 Da. The protein is also composed almost entirely of alpha helices with only a single beta sheet. The vitamin D receptor also does not have a quaternary structure [2]. is a large organic compound made up of 27 carbon atoms, 44 hydrogen atoms and a single oxygen atom, with the ligand having a total molecular weight of 385 Da [3]. In studying the vitamin d receptor, the regions of the protein have been categorized into domains, with the A/B domain located at the N-terminus, the C domain, which is located between amino acid 20 and amino acid 115, the D domain, which is located between the end of the C domain and amino acid 220, and the EF domain, which encompasses the rest of the protein [4].

Other aspects of interest about the vitamin D receptor include the protein revealing a binding pocket when it is in its active folded state, allowing the ligand to bind to the receptor. The ligand interacts with the activation helix by stabilizing the agonist position. This is accomplished through Van der Waals interactions between the ligand and the activation helix. The activation ligand is a nuclear receptor. There is also some empty space observed around the aliphatic chain [1]. The protein has an active conformation of 1,25 (OH)_2D_3 that has a ligand binding pocket in its active folded state. The activation ligand, a nuclear receptor (VDR), interacts with with the activation helix by stabilizing the agonist position. This is accomplished through Van der Waals interactions between the ligand and the activation helix. There is some empty space observed around the aliphatic chain, indicating the presence of water to stabilize all possible hydrogen bonds [1].

Binding Interactions

Protein 1db1 is found to complex with 1,25 Dihydroxy . This molecule has three notable alcohol groups shown in red. Oxygen is electronegative, giving alcohols the ability to participate in hydrogen bonding with the protein. Vitamin D3 has a large number of relations with the residues on the protein chain. First in the sequence are . Tyr143, shown in blue, is the closest to the ligand at 2.83 angstroms. This is sightly large but there is still the possibility of hydrogen bonding. Tyr147 in green and Phe150 in black are also known to have interactions with vitamin D3 they are farther away and therefore less significant. Next down the peptide chain are . Ser237, shown in green, has significant interactions with vitamin D3 this can be seen by its short distance 2.78 angstroms. Only 40 residues away, more hydrogen bonding is occurring. form bonds with the same oxygen atoms as Tyr143 and Ser237 respectively. This means that the oxygen atoms of vitamin D3, when bound to the receptor, are negatively charged and stabilized by protons. On the opposite end of vitamin D3 there is an additional negatively charged oxygen. Although this oxygen does not participate in hydrogen bonding. , shown in blue and green respectively, Contain aromatic rings. These rings are able to momentarily accept the electrons donated by the oxygen because they can delocalize the charge. This creates two pseudo-covalent bonds that is approximately 2.81 angstroms. When looking at , it can be seen that all of the binding sights are centered around oxygen [5,6].

Additional Features

Hereditary Vitamin D Resistant Rickets (HVDRR) is a condition that most commonly occurs in children and results in soft and weak bone formation, which often causes deformities in bone structure. A lack of proper nutrients, Vitamin D3 in particular, as well as defects in the Vitamin D receptor can cause rickets in humans. HVDRR can occur when the VDR is impaired in its ability to activate transcription in response to the 1,25-(OH)2D3 ligand [7]. VDR regulates the hormonal form of Vitamin D, through modifying the transcription of the target to a certain sequence of DNA, called the Vitamin D responsive element (VDRE). This activation requires an additional receptor, which is a Retinoid X Receptor (RXR) to bind to the heterodimer [7]. A mutation in the transcription of the protein has the potential to result in this disease and the mutation results in the not forming properly. Current research shows that there are two mechanisms that can cause this failed transcription and inability to bind to the heterodimer to occur within the body. The first is a point mutation of an amino acid in the zinc finger region of the VDR that reduces the binding of the heterodimer, this region is found in the amino acid residues 21-85 [7]. The other is a premature stop codon in the DNA sequences that does not allow for the full transcription, which can have an effect of reducing the affinity of the heterodimer binding [7]. Although there may be other mutations that could cause HVDRR to occur within the body, these two types of mutations have been shown to be major causes of the disease.

Also, the VDR has an effect on the hair follicle cycle, which has been observed through the eliminating the expression of this receptor. In null-VDR mice, it has been shown that with normal mineral ion levels that the mice result in alopecia, a disease that causes hair loss [8]. VDR is expressed in the hair follicle keratinocytes and its levels are higher in the late anagen and catagen stages of the hair cycle [8]. These two stages are vital in the differentiation and proliferation of hair follicle keratinocytes, which regulate hair growth in the body. Much research has been done into the mechanism in which the VDR effects the hair follicle cycle with the overall mechanism still unknown. The mechanism was first believed to be that of binding the VDR to 1,25- dihydroxyvitamin D causing transactivation due to the fact that targeted expressions of wild-type VDR to the keratinocytes of VDR null mice rescued alopecia [8]. Although, this was disproven through investigations in vitamin D3-deficient mice that had no detectable 1,25-dihydroxyvitamin D for the VDR to bind, yet the mice did not develop alopecia. This shows that the VDR transcriptional activation of DNA is not the main cause of the loss of hair follicles. Current research observes the ligand-independent actions of the VDR that have not been observed extensively as a mechanism [8]. Nuclear receptor co-repressor genes have been observed in studies to have an effect on the hair follicle cycle including the HR gene (Hairless). This corepressor has been shown to have interactions with the VDR in vivo and tests with the mutation of Hairless have caused alopecia in mice in vivo [8]. Thus, although the mechanism behind the interaction of Hairless and the VDR is still unknown it has been shown in studies that there is a relationship between the two in the body and that it has been linked to the hair follicle cycle.

Quiz Question 1

Osteoporosis is a disease in which the bones become porous and fragile. The most common cause of the ailment is calcium deficiency. As the vitamin D receptor has association with calcium uptake, mutations in VDR could be detrimental.If an individual had a point mutation that would replace with serine amino groups, would that individual be more likely to develop osteoporosis? why?

Credits

Introduction - Kate Daborowski

Overall Structure - Aaron Thole and Benjamin Rizkin

Drug Binding Site - Roger Crocker

Additional Features - Patrick Murphy

Quiz Question 1 - Roger Crocker

References

↑ Rochel N, Wurtz JM, Mitschler A, Klaholz B, Moras D. The crystal structure of the nuclear receptor for vitamin D bound to its natural ligand. Mol Cell. 2000 Jan;5(1):173-9. PMID:10678179

1. Rochel N, Wurtz JM, Mitschler A, Klaholz B, Moras D. The crystal structure of the nuclear receptor for vitamin D bound to its natural ligand. Mol Cell. 2000 Jan;5(1):173-9.

2. VDR Gene http://www.genecards.org/cgi-bin/carddisp.pl?gene=VDR (accessed Apr 2, 2016).

3. Vitamin D3 https://pubchem.ncbi.nlm.nih.gov/compound/Vitamin_D3#section=2D-Structure (accessed Apr 10, 2016).

4. Strugnell, S.; Deluca, H. The Vitamin D Receptor - Structure and Transcriptional Activation. Experimental Biology and Medicine1997, 215, 223–228.

5. Vitamin D Receptor http://pdb101.rcsb.org/motm/155 (accessed Apr 4, 2016).

6. 3D Binding Pocket http://www.rcsb.org/pdb/explore/jmol.do?structureId=1DB1&residueNr=VDX (accessed Apr 4, 2016).

7. Whitfield, G.K.; Selznick, S.H.; Haussler, C.A.; Hsieh, J.; Galligan, M.A.; Jurutka, P.W.; Thompson, P.D.; Lee, S.M.; Zerwekh, J.E.; Haussler, M.R. Vitamin D Receptors from Patients with Resistance to 1,25-Dihydroxyvitamin D3: Point Mutations Confer Reduced Transactivation in Response to Ligand and Impair Interaction with the Retinoid X Receptor Heterodimeric Partner. Mol Endocrinol, 1996 10 (12): 1617-1631

8. Skorija, K.; Cox, M.; Sisk, J.M.; Dowd, D.R.; MacDonald, P.N.; Thompson, C.C.; Demay, M.B. Ligand- Independent Actions of the Vitamin D Receptor Maintain Hair Follicle Homeostasis. Mol Endocrinol, April 2005, 19(4):855–862

Retrieved from "http://52.214.119.220/wiki/index.php/Sandbox_Reserved_428"

@@ Line 3: / Line 3: @@
 <!-- INSERT YOUR SCENES AND TEXT BELOW THIS LINE -->
-=='''EcoRV endonuclease'''==
+=='''Vitamin D receptor/vitamin D (1db1)<ref>PMID: 10678179 </ref>'''==
+by Roger Crocker, Kate Daborowski, Patrick Murphy, Benjamin Rizkin and Aaron Thole
-<Structure load='1rva' size='500' frame='true' align='right' caption='EcoRV is a restriction enzyme found in escherichia coli bacteria.  It can be thought of as scissors for cutting DNA and applications are being researched in gene analysis and cloning.' scene='Insert optional scene name here' />
-===Introduction===
+[[Student Projects for UMass Chemistry 423 Spring 2016]]
+<StructureSection load='1db1' size='350' side='right' caption='caption for Molecular Playground (PDB entry [[1db1]])' scene=''>
-EcoRV endonuclease is a type II restriction enzyme, or restriction endonuclease, found in e. coli bacteria.  The main biological function of restriction endonucleases is to protect the cell's genome against any foreign DNA.  Restriction enzymes recognize and cleave specific sequences of DNA.  In the figure to the right, the enzyme is shown with the <scene name='Sandbox_Reserved_428/Dna_sequence/1'>eleven base sequence</scene> AAA<font color=red>GATATC</font>TT, which includes the recognition site <font color=red>GATATC</font>.  The recognition site is shown <scene name='Sandbox_Reserved_428/Gatatc/1'>here</scene>.  A type II restriction enzymes cleave at a short distance from the recognition site and often use Mg(2+) as a cofactor, as does this enzyme.  They are commonly found in bacteria and shared structural features indicate that they are evolutionarily related.<ref>PMID:7819264</ref>  Type II endonucleases have been the site of much research because of applications in gene analysis and cloning and because they are great at modeling protein-DNA interactions.<ref>PMID:11557805</ref>
+==Introduction==
+<br>
+The <scene name='48/483885/Color1/6'>vitamin D receptor</scene> (VDR) is a ligand-dependent transcriptional regulator with two strands. VDR belongs to the superfamily of nuclear receptors which control homeostasis, cell differentiation and growth, and many physiological processes. All proteins that belong to the nuclear receptor superfamily have a variable N-terminus region (A/B region), a hinge region that is flexible (D region), a conserved DNA-binding region (DBD, C region), and a moderately conserved ligand-binding region (LBD, E/F region). In the case of VDR, the A/B region is very short so it does not have any AF-1 function and the ligand binding region has a dimerization interface and a transcriptional activation domain that is ligand-dependent (AF-2).[1] <br> <br>
+The VDR has both an active and suppressed form. The activation or suppression function is caused by the binding of the DR3 response element as a heterodimer with the retinoid X receptor of the target genes. Due to the interactions with the basal transcriptional machinery and transcriptional cofactors, transcription is either activated or suppressed. When VDR is in its active form it regulates both phosphate and calcium metabolism, has immunosuppressive effects, and induces cell differentiation. When there are defects in the VDR that effect its metabolism it can lead to diseases such as severe rickets, secondary hyperparathyroidism, and hypocalcemia. Though defects in VDR can cause many diseases, fully functioning VDR can be used as treatment for disease such as cancer, autoimmune disease, psoriasis, osteoporosis, and renal osteodystrophy.[1]
-Specifically, EcoRV is an orthodox restriction endonuclease.  This means that the DNA sequence recognized is palindromic, meaning each strand contains the same sequence.<ref>PMID:11557805</ref>  The DNA duplex is cleaved at the phosphodiester bond located at 5'-<font color=red>GAT</font><font color=blue>*</font><font color=red>ATC</font>-3'.  The other DNA strand will also be cleaved in the same location, producing blunt ends.  The cleavage site is shown <scene name='Sandbox_Reserved_428/Cleavage_site/1'>here</scene>.  This is relatively unique among restriction enzymes, as many cleave each DNA stand at a different location, leaving what are known as sticky ends.  Cleavage occurs by the breaking of the bond between a 3' oxygen and the phosphorus by nucleophilic attack by water.<ref>PMID:11557805</ref>  Mg(2+) acts as a catalyst for this reaction, however it is not shown in the representation to the right.<ref>PMID:7819264</ref>  The process of DNA cleavage is covered in more detail in the Binding Interactions section.
-The steps of DNA cleavage are as follows.  EcoRV binds to the DNA without specificity, which is followed by a diffusional walking "search" down the DNA molecule.  If the protein encounters its recognition site, conformational changes occur in the enzyme-DNA complex.<ref>PMID:11557805</ref>  These changes are discussed in more depth in the additional features section.
+==Overall Structure==
+The <scene name='48/483885/Alphabeta_picture/1'>vitamin d receptor</scene> contains 427 amino acids with a total molecular weight of 48,289 Da. The protein is also composed almost entirely of alpha helices with only a single beta sheet. The vitamin D receptor also does not have a quaternary structure [2]. <scene name='48/483885/Vitamin_d3/2'>Vitamin D3</scene> is a large organic compound made up of 27 carbon atoms, 44 hydrogen atoms and a single oxygen atom, with the ligand having a total molecular weight of 385 Da [3]. In studying the vitamin d receptor, the regions of the protein have been categorized into domains, with the A/B domain located at the N-terminus, the C domain, which is located between amino acid 20 and amino acid 115, the D domain, which is located between the end of the C domain and amino acid 220, and the EF domain, which encompasses the rest of the protein [4].
+<br> <br>
+Other aspects of interest about the vitamin D receptor include the protein revealing a binding pocket when it is in its active folded state, allowing the ligand to bind to the receptor. The ligand interacts with the activation helix by stabilizing the agonist position. This is accomplished through Van der Waals interactions between the ligand and the activation helix. The activation ligand is a nuclear receptor. There is also some empty space observed around the aliphatic chain [1].
+The protein has an active conformation of 1,25 (OH)_2D_3 that has a ligand binding pocket in its active folded state. The activation ligand, a nuclear receptor (VDR), interacts with with the activation helix by stabilizing the agonist position. This is accomplished through Van der Waals interactions between the ligand and the activation helix. There is some empty space observed around the aliphatic chain, indicating the presence of water to stabilize all possible hydrogen bonds [1].
+==Binding Interactions==
+Protein 1db1 is found to complex with 1,25 Dihydroxy <scene name='48/483885/Vitamin_d3/1'>vitamin D3</scene>. This molecule has three notable alcohol groups shown in red. Oxygen is electronegative,  giving alcohols the ability to participate in hydrogen bonding with the protein. Vitamin D3 has a large number of relations with the residues on the protein chain. First in the sequence are <scene name='48/483885/Residues_140-151/2'>residues 140-151</scene>. Tyr143, shown in blue, is the closest to the ligand at 2.83 angstroms. This is sightly large but there is still the possibility of hydrogen bonding. Tyr147 in green and Phe150 in black are also known to have interactions with vitamin D3 they are farther away and therefore less significant. Next down the peptide chain are <scene name='48/483885/Residues_235-240/1'>residues 235-240</scene>. Ser237, shown in green, has significant  interactions with vitamin D3 this can be seen by its short distance 2.78 angstroms. Only 40 residues away, more hydrogen bonding is occurring.<scene name='48/483885/Residues_270-280/1'>Arg274 and Ser278</scene> form bonds with the same oxygen atoms as Tyr143 and Ser237 respectively. This means that the oxygen atoms of vitamin D3, when bound to the receptor, are negatively charged and stabilized by protons. On the opposite end of vitamin D3 there is an additional negatively charged oxygen. Although this oxygen does not participate in hydrogen bonding. <scene name='48/483885/His305_and_his397/1'>His305 and His397</scene>, shown in blue and green respectively, Contain aromatic rings. These rings are able to momentarily accept the electrons donated by the oxygen because they can delocalize the charge. This creates two pseudo-covalent bonds that is approximately 2.81 angstroms. When looking at <scene name='48/483885/All_binding_interactions/1'>all binding interactions</scene>, it can be seen that all of the binding sights are centered around oxygen [5,6].
+==Additional Features==
+Hereditary Vitamin D Resistant Rickets (HVDRR) is a condition that most commonly occurs in children and results in soft and weak bone formation, which often causes deformities in bone structure.  A lack of proper nutrients, Vitamin D3 in particular, as well as defects in the Vitamin D receptor can cause rickets in humans.  HVDRR can occur when the VDR is impaired in its ability to activate transcription in response to the 1,25-(OH)2D3 ligand [7].  VDR regulates the hormonal form of Vitamin D, through modifying the transcription of the target to a certain sequence of DNA, called the Vitamin D responsive element (VDRE). This activation requires an additional receptor, which is a Retinoid X Receptor (RXR) to bind to the heterodimer [7].  A mutation in the transcription of the protein has the potential to result in this disease and the mutation results in the <scene name='48/483885/Heterodimer/1'>heterodimer</scene> not forming properly. Current research shows that there are two mechanisms that can cause this failed transcription and inability to bind to the heterodimer to occur within the body.  The first is a point mutation of an amino acid in the zinc finger region of the VDR that reduces the binding of the heterodimer, this region is found in the amino acid residues 21-85 [7]. The other is a premature stop codon in the DNA sequences that does not allow for the full transcription, which can have an effect of reducing the affinity of the heterodimer binding [7].  Although there may be other mutations that could cause HVDRR to occur within the body, these two types of mutations have been shown to be major causes of the disease.
+Also, the VDR has an effect on the hair follicle cycle, which has been observed through the eliminating the expression of this receptor. In null-VDR mice, it has been shown that with normal mineral ion levels that the mice result in alopecia, a disease that causes hair loss [8]. VDR is expressed in the hair follicle keratinocytes and its levels are higher in the late anagen and catagen stages of the hair cycle [8]. These two stages are vital in the differentiation and proliferation of hair follicle keratinocytes, which regulate hair growth in the body. Much research has been done into the mechanism in which the VDR effects the hair follicle cycle with the overall mechanism still unknown.  The mechanism was first believed to be that of binding the VDR to 1,25- dihydroxyvitamin D causing transactivation due to the fact that targeted expressions of wild-type VDR to the keratinocytes of VDR null mice rescued alopecia [8]. Although, this was disproven through investigations in vitamin D3-deficient mice that had no detectable 1,25-dihydroxyvitamin D for the VDR to bind, yet the mice did not develop alopecia. This shows that the VDR transcriptional activation of DNA is not the main cause of the loss of hair follicles.  Current research observes the ligand-independent actions of the VDR that have not been observed extensively as a mechanism [8].  Nuclear receptor co-repressor genes have been observed in studies to have an effect on the hair follicle cycle including the HR gene (Hairless). This corepressor has been shown to have interactions with the VDR in vivo and tests with the mutation of Hairless have caused alopecia in mice in vivo [8]. Thus, although the mechanism behind the interaction of Hairless and the VDR is still unknown it has been shown in studies that there is a relationship between the two in the body and that it has been linked to the hair follicle cycle.
+==Quiz Question 1==
+Osteoporosis is a disease in which the bones become porous and fragile. The most common cause of the ailment is calcium deficiency. As the vitamin D receptor has association with calcium uptake, mutations in VDR could be detrimental.If an individual had a point mutation that would replace <scene name='48/483885/Point_mutation/1'>His305 and His397</scene> with serine amino groups, would that individual be more likely to develop osteoporosis? why?
+==See Also==
+*[[3w0a]]
+*[[3w0c]]
+*[[3w0y]]
+*[[3w5t]]
+*[[3w5r]]
+*[[1db1]]
+==Credits==
+Introduction - Kate Daborowski
+Overall Structure - Aaron Thole and Benjamin Rizkin
+Drug Binding Site - Roger Crocker
-.
+Additional Features - Patrick Murphy
-===Overall Structure===
+Quiz Question 1 - Roger Crocker
-<Structure load='1rva' size='500' frame='true' align='right' caption='EcoRV' scene='Insert optional scene name here' />
+==References==
-EcoRV endonuclease is functional as a <scene name='Sandbox_Reserved_428/Dimer_complex/4'>dimer</scene> consisting of two monomers; <font color='limegreen'>monomer B</font> and <font color='violet'>monomer A</font> are in a U shape.  Each monomer consists of 245 amino acids arranged in alpha/beta secondary structures.  These monomers are identical in their sequencing but not their structure.
+<references/>
-The monomer's structure are identical in all but two sets of residue numbers.  There are 9 identical <font color='crimson'>alpha helices</font> shown <scene name='Sandbox_Reserved_428/Dimeralphahelix/2'>here</scene> and 10 identical <font color='aqua'>beta strands</font> shown <scene name='Sandbox_Reserved_428/Dimerbetasheets/2'>here</scene>.
+. Rochel N, Wurtz JM, Mitschler A, Klaholz B, Moras D. The crystal structure of the nuclear receptor for vitamin D bound to its natural ligand. Mol Cell. 2000 Jan;5(1):173-9.
-The structures <scene name='Sandbox_Reserved_428/Diff_dimer/2'>differ</scene> at residue number 144-150, where <font color='violet'>monomer A</font> has an additional <font color='dark orange'>alpha helix</font> and a residue numbers 150-153, where <font color='limegreen'>monomer B</font> has an additional <font color='navy'>beta strand</font>.
+. VDR Gene http://www.genecards.org/cgi-bin/carddisp.pl?gene=VDR (accessed Apr 2, 2016).
-At the point on the U dimer where the monomers meet there is a 5 strand <scene name='Sandbox_Reserved_428/Dimer_connection_betasheet/1'>interlocking beta sheet</scene>.  This anti-parallel beta sheet is made of 3 stands from <font color='limegreen'>monomer B</font> and 2 strands from <font color='violet'>monomer A</font>.  This beta sheet also has three alpha helices packed against it shown <scene name='Sandbox_Reserved_428/Alpha_beta_sandwhich/2'>here</scene>.  Two of these alpha helicies are from <font color='violet'>monomer A</font> and the other is from <font color='limegreen'>monomer B</font>  This structure assists in the structure and stability of the dimer as a whole.  Once you <scene name='Sandbox_Reserved_428/Zoomout_alpha_beta_sandwhich/1'>zoom out</scene>, you can see how these beta strands form one anti-parallel beta sheet connecting the two monomers at the bottom of the U shape.
+. Vitamin D3 https://pubchem.ncbi.nlm.nih.gov/compound/Vitamin_D3#section=2D-Structure (accessed Apr 10, 2016).
-There are two structural sub-domains.  The first, called the <font color='orange'>dimerization sub-domain</font>,shown <scene name='Sandbox_Reserved_428/Sub-domain_dimer/4'>here</scene>, is the smallest of the sub-domains, residue numbers 19-32, 150-160, and 144-150 of <font color=violet>monomer A</font>.   This section forms all of the dimer interface interactions and stabilizes the dimer.  This sub-domain is unique to EcoRV and only one other restriction endonuclease.  The second is called the <font color='deep pink'>DNA binding sub-domain</font> shown <scene name='Sandbox_Reserved_428/Sub-domain_dimer/2'>here</scene>, residue numbers 2-18 38-140 and 167-243.  This sub-domain is where the majority of the dimer's function occurs.  This sub-domain contains the loops that are responsible for the interactions with DNA which include binding to and breaking it's bonds.   The remaining segments of amino acids make up the <font color='mediumspringbreeze'>flexible linkage</font> between the two sub-domains, residue numbers 33-37,141-143, and 161-165 shown <scene name='Sandbox_Reserved_428/Sub-domain_dimer/5'>here</scene>.  This flexibility allows for the enzyme to open up and the monomers to slightly separate during the free enzyme form.
-<ref>PMID: 8491171</ref>
-.
-===Binding Interactions===
-<Structure load='1rva' size='500' frame='true' align='right' caption='EcoRV' scene='Insert optional scene name here' />
-The EcoRV molecule is a type II restriction endonuclease, which means that its purpose is to cleave DNA at the center of its <scene name='Sandbox_Reserved_428/Recognition_sequence/3'>recognition sequence</scene>, which is the site that the enzyme recognizes on the DNA to be cleaved.  DNA recognition sites on the EcoRV molecule, called R-loops, bind to the major grooves of the double stranded DNA at its recognition sequence, which is <font color='yellow'>GATATC,</font> by hydrogen bonding.  These hydrogen bonds make the DNA form a kinked conformation that is later stabilized by the addition of the Mg2+ ion.  The Mg2+ ion is a catalyst that causes the DNA to shift in a way that increases the rate necessary for the DNA cleavage.  It does not bind to EcoRV until the enzyme is prepared to cleave the DNA helix.  When the enzyme is ready to cleave, the affinity for the Mg2+ ion increases and then it binds to the enzyme.  The recognition sequence of the DNA is shown in yellow and it is cleaved at the center <font color='darkmagenta'>between the T and A base pairs</font> on the D chain when interacted with a Mg2+ ion, leaving a blunt end in the DNA.
-The <scene name='Sandbox_Reserved_428/Active_site/3'>active site</scene> of the enzyme is shown here in pink.  It consists of four residues, <font color='fuchsia'> Asp74, Asp90, Ile91, and Lys92, </font> which participate in the binding of the Mg2+ ion along with binding interactions of the Adenine, A, base pair.  Mg2+ binding only occurs in <scene name='Sandbox_Reserved_428/Active_site_one_subunit/1'>subunit B</scene> along one side of the DNA double helix.  The Mg2+ binding site is formed when ionic interactions cause the slightly acidic Asp90 residue and the slightly negatively charged scissile phosphodiester group on the DNA strand to approach each other.  This allows the Mg2+ ion to bind to this enzyme, also with ionic interactions between the positively charged Mg2+ and the partially negative charged <scene name='Sandbox_Reserved_428/6_oxygens_that_bind_to_mg2/2'>oxygen atoms</scene>.  These molecules that bind to the Mg2+ ion are the <font color='red'>carboxylate oxygen atoms</font> from the Asp74 and Asp90 residues, the <font color='red'>nonesterified oxygen</font> from the scissile phosphodiester group, and three additional <font color='blue'>oxygen atoms from three water molecules</font>.  These six ionic bonds form an octahedral shape in the active site of this enzyme.
-These six ionic interactions all have about the same binding distance except for one bond between the oxygen from the <scene name='Sandbox_Reserved_428/Asp74_molecule_farther/1'>Asp74 residue</scene> and the Mg2+ ion that is significantly longer.   The five similar bond lengths are all about 2.08 Å, but the bond between Mg2+ and the Asp74 oxygen spans a distance of 2.9 Å.  This is noted because the Asp90 and scissile phosphodiester molecules that bind to this Mg2+ ion change their bonding interactions with hydrogen to accommodate the addition of the Mg2+ ion.  The Asp74 residue maintains its hydrogen bond interactions on its side chain with the main chain of the Ile91 residue and the water molecule, which is why it keeps a greater distance between itself and the Mg2+ ion.<ref>PMID:7819264</ref>
-.
-===Additional Features===
-<Structure load='1rva' size='500' frame='true' align='right' caption='EcoRV' scene='Insert optional scene name here' />
-As a prerequisite for efficient target site recognition, the enzyme is capable of nonspecific binding with a DNA molecule's Phosphate backbone. The non-specific Enzyme(PDB: 2RVE) slides along a DNA molecule with movement characterized by a helical diffusion due to hydrogen bonding along the minor groove . The biological significance of this process is accelerated target site location, increased processivity, and dissociation of the enzyme upon cleavage. Specific binding on the other hand is precisely the process of recognition which involves an interplay between interaction with the bases of the recognition sequence as well as indirect interaction with the respective phosphate backbone. Recognition precedes conformational changes in both DNA and the protein, thereby bending the DNA and activating the catalytic centers. In both the <scene name='Sandbox_Reserved_428/Specific_minorgroove/2'>specific</scene> and <scene name='Sandbox_Reserved_428/Ns_minorgroove_trackng/2'>Non-Specific</scene> complexes, the DNA is oriented so that the minor groove faces the <font color='blue'> floor</font> of the Binding site.<ref>PMID:11557805</ref>
-Unlike <font color ='red'>R-loops</font> (Recognition Loops, Residues 182-187) which are disordered in both the <scene name='Sandbox_Reserved_428/Nonspecificenzyme_qloops/1'>Non-Specific</scene> and <scene name='Sandbox_Reserved_428/Ns_rloops/1'>free enzyme</scene> complex(PDB: 1RVE). <font color='yellow'>Q-Loops</font> (Residues 68-71) are ordered in the <scene name='Sandbox_Reserved_428/Ns_qloops/1'>non-specific complex</scene>, forming a beta turn. They are disordered in the <scene name='Sandbox_Reserved_428/Qloops_freeenzyme/1'>free enzyme</scene>. Hydrogen bond interactions in the non-specific complex are indicated in crystal structures of the <scene name='Sandbox_Reserved_428/Nonspecific_gah/1'>non-specific complex</scene> between the two <font color='Blue'>Glutamine</font>, <font color='red'>Aspargarine</font>, and <font color='green'>Histidine</font> Residues of the Q-Loops and the DNA Phosphates. While <font color='green'>Histidine</font> and the two <font color='Blue'>Glutamine</font> residues contribute less to hydrogen bonding due to their high conformational entropy, <font color='red'>Aspargarine</font> forms the strongest hydrogen bonds with the Phosphates because of its short alkyl chain, and thus is a strong contributor to the ability of the Enzyme to diffuse Linearly along the DNA molecule.<ref>PMID: 8491171</ref>
-.
-=='''References'''==
-<references/>
-=='''Credits'''==
+. Strugnell, S.; Deluca, H. The Vitamin D Receptor - Structure and Transcriptional Activation. Experimental Biology and Medicine1997, 215, 223–228.
-Introduction - Jesse Guillet
+. Vitamin D Receptor http://pdb101.rcsb.org/motm/155 (accessed Apr 4, 2016).
-Overall Structure - Nicole Bundy
+. 3D Binding Pocket http://www.rcsb.org/pdb/explore/jmol.do?structureId=1DB1&residueNr=VDX (accessed Apr 4, 2016).
-Binding Interactions - Julia Tomaszewski
+. Whitfield, G.K.; Selznick, S.H.; Haussler, C.A.; Hsieh, J.; Galligan, M.A.; Jurutka, P.W.; Thompson, P.D.; Lee, S.M.; Zerwekh, J.E.; Haussler, M.R. Vitamin D Receptors from Patients with Resistance to 1,25-Dihydroxyvitamin D3: Point Mutations Confer Reduced Transactivation in Response to Ligand and Impair Interaction with the Retinoid X Receptor Heterodimeric Partner.  Mol Endocrinol, 1996 10 (12): 1617-1631
-Additional Features - Sam Kmail
+. Skorija, K.; Cox, M.;  Sisk, J.M.; Dowd, D.R.; MacDonald, P.N.; Thompson, C.C.; Demay, M.B. Ligand- Independent Actions of the Vitamin D Receptor Maintain Hair Follicle Homeostasis. Mol Endocrinol, April 2005, 19(4):855–862

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From Proteopedia

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Vitamin D receptor/vitamin D (1db1)^[1]

Contents

Introduction

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Sandbox Reserved 428

From Proteopedia

Current revision

Vitamin D receptor/vitamin D (1db1)[1]

Contents

Introduction

Overall Structure

Binding Interactions

Additional Features

Quiz Question 1

See Also

Credits

References

Views

Personal tools

Navigation

Search

Toolbox

Vitamin D receptor/vitamin D (1db1)^[1]