|
|
| (370 intermediate revisions not shown.) |
| Line 3: |
Line 3: |
| | <!-- INSERT YOUR SCENES AND TEXT BELOW THIS LINE --> | | <!-- INSERT YOUR SCENES AND TEXT BELOW THIS LINE --> |
| | | | |
| - | =='''YourMacromolecule'''== | + | =='''Structure of Oligonucleotide/Drug Complex (1xcs)<ref>PMID: 15926069 </ref>'''== |
| | + | by Michael Beauregard, Annie Burton, Jianlong Li, Daniel Marco, and Nathaneal Park |
| | | | |
| - | ===Introduction=== | + | [[Student Projects for UMass Chemistry 423 Spring 2016]] |
| - | Individuals with Sickle Cell Anemia, or Sickle Cell Disease, contain a mutated form of hemoglobin, the oxygen binding protein found in red blood cells. Mutated hemoglobin causes normal disk-shaped red blood cells to become sickle-shaped. These sickle cells are fragile, deliver less oxygen to the body's tissues, and clog small blood vessels and capillaries, which results in a variety of adverse symptoms and detrimental complications. Some of these symptoms include abdominal and bone pain, breathlessness, fatigue, and rapid heart rate. Over time, irreversible tissue damage leads to the failure of many organ systems.
| + | <StructureSection load='1xcs' size='350' side='right' caption='This cancer-treating complex is formed by an anthraquinone drug that intercalates into DNA (PDB entry [[1xcs]])' scene='48/483883/Homecomplex/2'> |
| | | | |
| - | Sickle Cell Disease results from a single point mutation in the Hemoglobin amino acid sequence. Normal Hb contains a hydrophilic glutamate residue at position 6 of the beta strand, whereas in HbS, this residue has been changed to a hydrophobic valine residue. <scene name='Sandbox_Reserved_426/Glu6_residue_of_hb/3'>Glu 6 Residue of normal Hemoglobin</scene>. The mutation region of one HbS molecule will then bind to a region defined by β Phe85 and β Leu88 in the Heme pocket of another HbS molecule via noncovalent hydrophobic interactions. The subsequent polymerization of HbS molecules leads to the sickling of red blood cells.
| + | ==Introduction== |
| | + | The intercalation of DNA and drug compounds has been studied thoroughly as a inhibitor of tumorigenesis or pathogenesis which is key in the progression of most cancers. Most intercalated ligands are aromatic compounds that bond <scene name='48/483883/1xcs_binding_site/3'>between base pairs</scene> through non-covalent interactions. In this case the nucleotide d(CGTACG) was complexed with an anthraquinone derivative. This derivative, 1,5-bis[3-(diethylamino)propionamido]anthracene-9,10-dione, provided researchers with the information needed to solve <scene name='48/483883/Rainbow_sheet/1'>the structure of the complex</scene> using X-Ray crystallography. Along with the structure, the important forces involved in binding were analyzed and described as heavily reliant on cations. Furthermore, the binding site seems to be specific to anthracene and similar molecules. Therefore, the potential for drug compounds to be carried by this nucleotide complex requires further research with respect to binding affinity, solubility, toxicology, and specificity with other analogues. |
| | | | |
| | + | The 1,5-bis[3-(diethylamino)propionamido]anthracene-9,10-dione complex was studied using synchrotron radiation, which is the energy emitted from particles traveling near the speed of light, which identified ionic sites and areas of high electron density. The binding site of the drug compound is one of these high electron density areas, and was a key component in it's identification. The electron density mappings also provides insight on issues typical with the intercalation of aromatic ligands such as their degrees of freedom and the effect of counterions. The aromatic anthraquinone derivative ligand is disordered disordered in the binding site with two solvable positions which are 180 degree rotations of each other. With respect to the issue of ionic strength, DNA is a polyanion therefore positively charged counterions shielding the interactions between the DNA and the drug is worth noting. In the case of Na+, it has been resolved near the binding site of the drug. In short, this DNA/Anthraquinone derivative complex provides a potential anti-cancer drug and information about the role of positively charged ions in the intercalation of the drug compound. |
| | | | |
| - | The cooperative binding of oxygen leads to a conformation change in hemoglobin from the tense, or T state, to the R, or relaxed state. Recently, studies have shown that multiple relaxed Hb conformers exist, such as the R2, RR2, and R3 states.
| + | ==Overall Structure== |
| | | | |
| - | It has been proven that sickling only occurs with the deoxygenated T-state Hb, and it is therefore desirable to explore ways in which allosteric equilibrium can be shifted toward the R- conformation. Compounds that achieve such an equilibrium shift are therefore being sought. Vanillin, a food flavoring compound, as well as the furanic aldehyde compounds 5-hydroxymethyl-2-furfural (5HMF), 5-methyl-2-furfural (5MF), 5-ethyl-furfural (5EF), and furfural (FUF) all exhibit such antisickling properties and are nontoxic to humans, and are therefore promising candidates for potential SCD drug treatments.
| + | The 1xcs (model at right) complex is a small, simple globular DNA-drug complex, and as such lacks any traditional protein-associated structures such as secondary beta sheets or alpha helices. The complex consists of two complimentary strands of DNA. A simplified model of 1xcs is shown <scene name='48/483883/Title/4'>here,</scene> with the nitrogenous bases removed for clarity. The deoxyribose backbones can be followed from 5' to 3' following along each strand from blue to red. Note that the strands are antiparallel where they are (hydrogen) bonded. <scene name='48/483883/1xcs_with_side_chains/2'>1xcs with its hydrogen bonding regions displayed (black)</scene> visualizes this bonding in the middle region of the complex, again following each strand from blue to red from 5' to 3' ends. |
| - |
| + | |
| | | | |
| | + | The 1xcs complex also binds to metal ions in more than one location, which have been shown to be important to the drug's binding ability. Different metal ions may be present, including Na(+) and Co(2+). The main metal ions sites are colored pink in <scene name='48/483883/1xcs_with_pink_metal_ions/2'>this</scene> scene. One other metal binding site was noted, which had the ability to bind <scene name='48/483883/Barium_binding_site/1'>Ba(2+)</scene> (teal). This ability to strongly bind metal ions was also important for x-ray crystallographic purposes, as it enabled researchers to form crystals of the complex by relying on interactions between neighboring molecules' binding sites. It is also believed that the tight packing of the 1xcs complex in its solid form contributes to its ability to retain drug molecules (see "Binding Interactions"). |
| | | | |
| | + | ==Binding Interactions== |
| | + | There are three main locations where ion ligands bind to the oligonucleotide/drug complex. The key ligand is shown <scene name='48/483883/Annie_scene/1'>here</scene> in pink. Its function is to close the drug cavity, holding the anthraquinone derivative in place. It can be an Na(+), Mg(2+), or Ba(2+) ion. The two other ligands, shown in cyan bind four to five nucleotides away from the drug itself. Co(2+) ions were always present at these locations in this complex and in similar complexes. Complexes that did not contain Co(2+) did not diffract. Literature states that the variable ion gives strength to the binding of the Co(2+) ions. It may be reasoned that this interaction may also behave oppositely. The binding of the Co(2+) ions may strengthen the closure of the pocket containing the drug. Co(2+) and Ba(2+) ions were found in more locations that are not shown here because they only appeared sporadically and in differing locations. Therefore, they are probably not precisely important to the function of this drug complex. |
| | | | |
| - | <Structure load='1qxd' size='500' frame='true' align='right' caption='Insert caption here' scene='Insert optional scene name here' /> | |
| | | | |
| - | ===Overall Structure=== | + | ==Additional Features== |
| - | Hemoglobin is a tetramer composed of two αβ dimers.
| + | In <scene name='48/483883/Mikescene/1'>this depiction</scene>, one can see that the anthraquinone derivative is located between the backbones and base pairs of DNA. The drug is squeezed or intercalated between the nucleotides <scene name='48/483883/Mikescene/3'>shown in red</scene>. In the human body, the <scene name='48/483883/Mikescene/2'>nucleotide in gold</scene> would also be interacting with the drug shown in black, but in order for this complex to be studied, a short segment of DNA had to be used. Consequently the gold nucleotide is involved in abnormal molecular interactions and is out of place. This intercalation interrupts the function of taq polymerase and telomerase.<ref>Human Telomerase Inhibition by Regioisomeric Disubstituted Amidoanthracene-9,10-diones |
| - | <scene name='Sandbox_Reserved_426/Ab_dimers/3'>αβ Dimers</scene> | + | Philip J. Perry,†, Anthony P. Reszka,†, Alexis A. Wood,†, Martin A. Read,†, Sharon M. Gowan,‡, Harvinder S. Dosanjh,†, John O. Trent,†,§, Terence C. Jenkins,†,‖, Lloyd R. Kelland,‡ and, and Stephen Neidle*,† |
| | + | Journal of Medicinal Chemistry 1998 41 (24), 4873-4884 |
| | + | DOI: 10.1021/jm981067o</ref> Taq polymerase is in part responsible for the replication of DNA and consequently, cell replication. Telomeres are repeating sections of non-coding DNA that protect the ends of coding sections of DNA from degradation. Each time a cell divides, telomeres shorten. Over time, telomeres shorten to the point of disappearance, causing DNA degradation and cell death. Telomerase builds up these protective sections of DNA. Cancer is characterized as an uncontrolled rate of cell growth. By inhibiting the replication of DNA and the construction of protective telomeres, this drug serves to slow and stop cancerous cell growth. |
| | | | |
| - | The majority of Hb consists of alpha helices, with each of the α and β domains containing 8 alpha helices and no beta strands. | |
| | | | |
| - | Each α chain contains 141 residues, and each β chain contains 146.
| + | ==Quiz Question 1== |
| | + | This complex serves to interrupt two enzymes involved in cell replication: Taq polymerase and <scene name='48/483883/This_complex/1'>this enzyme</scene>. |
| | + | A. nuclease |
| | + | B. telomerase |
| | + | C. ligase |
| | + | D. topoisomerase |
| | | | |
| - | Each of the four globular domains within hemoglobin contains a heme group, which consists of an iron ion bound within four cyclically bonded pyrrole molecules, and is bound to hemoglobin via a histidine sidechain.
| + | ==See Also== |
| | + | *[[1bp8]] |
| | + | *[[1d3x]] |
| | + | *[[1p3x]] |
| | | | |
| - | The point mutation responsible for this altered form of hemoglobin changes a glutamic acid residue in both beta subunits to a valine, resulting in hydrophobic interactions between separate Hb molecules, but no major structural changes on an individual basis.
| + | ==Credits== |
| | | | |
| - | ===Binding Interactions===
| + | Introduction - Daniel Marco |
| - | five-membered heterocyclic aldehydes inhibits sickling of homozygous sickle red blood cells and increases oxygen affinity of Hemoglobin
| + | |
| | | | |
| - | R state:
| + | Overall Structure - Nathaneal Park |
| - | N terminal αVall interactions
| + | |
| - | Sites:
| + | |
| - | α1ser131OG
| + | |
| - | 1Thr134OG1
| + | |
| - | [[α2ser138OG]]
| + | |
| - | <scene name='Sandbox_Reserved_426/Ser138/1'>TextToBeDisplayed</scene>
| + | |
| | | | |
| - | R2 state:
| + | Drug Binding Site - Annie Burton |
| - | N terminal αVall
| + | |
| - | Sites:
| + | |
| - | α2ser138OG
| + | |
| | | | |
| | + | Additional Features - Michael Beauregard |
| | | | |
| - | T state:
| + | Quiz Question 1 - Jianlong Li |
| - | N terminal αVall
| + | |
| - | Sites:
| + | |
| - | αTyr140OH - hydrogen bonding
| + | |
| - | ===Additional Features===
| + | |
| - | oxygen is bound to iron in a heme group through ion-induced dipole forces
| + | |
| - | <scene name='Sandbox_Reserved_426/Heme_group/1'>Heme Group</scene>
| + | |
| | | | |
| - | Heme made up of protoprophyrin with 4 linked pyrrole rings with a central Fe 2+ ion.
| + | ==References== |
| - | Iron ion is coordinated to side chain of a histidine residue in myoglobin. An oxygen atom from O2 binds to a open coordination site with iron. When oxygen is bound to iron, iron moves into plane of prophyrin.
| + | |
| - | T and R state depends on the amount of oxygen sites are bound to iron. R state refers to when oxygen is bound to sites, while T state reflects unbounded oxygen to oxygen binding sites.
| + | |
| - | | + | |
| - | Oxygen is bound to iron until it is ready to be released in tissue.
| + | |
| - | | + | |
| - | Hemoglobin is made of 4 monomers
| + | |
| - | | + | |
| - | (note to other members, I'm not sure what else i can say for additional features for hemogloblin) the structure itself is already described, those things that arent heme groups are the 5 member heterocyclic aldehydes)
| + | |
| - | ===Credits===
| + | |
| - | | + | |
| - | Introduction - Ryan Colombo
| + | |
| - | | + | |
| - | Overall Structure - Will Yarr
| + | |
| - | | + | |
| - | Drug Binding Site - Jacqueline Pasek-Allen
| + | |
| - | | + | |
| - | Additional Features - Joey Nguyen
| + | |
| - | | + | |
| - | ===References===
| + | |
| | <references/> | | <references/> |
by Michael Beauregard, Annie Burton, Jianlong Li, Daniel Marco, and Nathaneal Park
|
Introduction
The intercalation of DNA and drug compounds has been studied thoroughly as a inhibitor of tumorigenesis or pathogenesis which is key in the progression of most cancers. Most intercalated ligands are aromatic compounds that bond through non-covalent interactions. In this case the nucleotide d(CGTACG) was complexed with an anthraquinone derivative. This derivative, 1,5-bis[3-(diethylamino)propionamido]anthracene-9,10-dione, provided researchers with the information needed to solve using X-Ray crystallography. Along with the structure, the important forces involved in binding were analyzed and described as heavily reliant on cations. Furthermore, the binding site seems to be specific to anthracene and similar molecules. Therefore, the potential for drug compounds to be carried by this nucleotide complex requires further research with respect to binding affinity, solubility, toxicology, and specificity with other analogues.
The 1,5-bis[3-(diethylamino)propionamido]anthracene-9,10-dione complex was studied using synchrotron radiation, which is the energy emitted from particles traveling near the speed of light, which identified ionic sites and areas of high electron density. The binding site of the drug compound is one of these high electron density areas, and was a key component in it's identification. The electron density mappings also provides insight on issues typical with the intercalation of aromatic ligands such as their degrees of freedom and the effect of counterions. The aromatic anthraquinone derivative ligand is disordered disordered in the binding site with two solvable positions which are 180 degree rotations of each other. With respect to the issue of ionic strength, DNA is a polyanion therefore positively charged counterions shielding the interactions between the DNA and the drug is worth noting. In the case of Na+, it has been resolved near the binding site of the drug. In short, this DNA/Anthraquinone derivative complex provides a potential anti-cancer drug and information about the role of positively charged ions in the intercalation of the drug compound.
Overall Structure
The 1xcs (model at right) complex is a small, simple globular DNA-drug complex, and as such lacks any traditional protein-associated structures such as secondary beta sheets or alpha helices. The complex consists of two complimentary strands of DNA. A simplified model of 1xcs is shown with the nitrogenous bases removed for clarity. The deoxyribose backbones can be followed from 5' to 3' following along each strand from blue to red. Note that the strands are antiparallel where they are (hydrogen) bonded. visualizes this bonding in the middle region of the complex, again following each strand from blue to red from 5' to 3' ends.
The 1xcs complex also binds to metal ions in more than one location, which have been shown to be important to the drug's binding ability. Different metal ions may be present, including Na(+) and Co(2+). The main metal ions sites are colored pink in scene. One other metal binding site was noted, which had the ability to bind (teal). This ability to strongly bind metal ions was also important for x-ray crystallographic purposes, as it enabled researchers to form crystals of the complex by relying on interactions between neighboring molecules' binding sites. It is also believed that the tight packing of the 1xcs complex in its solid form contributes to its ability to retain drug molecules (see "Binding Interactions").
Binding Interactions
There are three main locations where ion ligands bind to the oligonucleotide/drug complex. The key ligand is shown in pink. Its function is to close the drug cavity, holding the anthraquinone derivative in place. It can be an Na(+), Mg(2+), or Ba(2+) ion. The two other ligands, shown in cyan bind four to five nucleotides away from the drug itself. Co(2+) ions were always present at these locations in this complex and in similar complexes. Complexes that did not contain Co(2+) did not diffract. Literature states that the variable ion gives strength to the binding of the Co(2+) ions. It may be reasoned that this interaction may also behave oppositely. The binding of the Co(2+) ions may strengthen the closure of the pocket containing the drug. Co(2+) and Ba(2+) ions were found in more locations that are not shown here because they only appeared sporadically and in differing locations. Therefore, they are probably not precisely important to the function of this drug complex.
Additional Features
In , one can see that the anthraquinone derivative is located between the backbones and base pairs of DNA. The drug is squeezed or intercalated between the nucleotides . In the human body, the would also be interacting with the drug shown in black, but in order for this complex to be studied, a short segment of DNA had to be used. Consequently the gold nucleotide is involved in abnormal molecular interactions and is out of place. This intercalation interrupts the function of taq polymerase and telomerase.[2] Taq polymerase is in part responsible for the replication of DNA and consequently, cell replication. Telomeres are repeating sections of non-coding DNA that protect the ends of coding sections of DNA from degradation. Each time a cell divides, telomeres shorten. Over time, telomeres shorten to the point of disappearance, causing DNA degradation and cell death. Telomerase builds up these protective sections of DNA. Cancer is characterized as an uncontrolled rate of cell growth. By inhibiting the replication of DNA and the construction of protective telomeres, this drug serves to slow and stop cancerous cell growth.
Quiz Question 1
This complex serves to interrupt two enzymes involved in cell replication: Taq polymerase and .
A. nuclease
B. telomerase
C. ligase
D. topoisomerase
See Also
Credits
Introduction - Daniel Marco
Overall Structure - Nathaneal Park
Drug Binding Site - Annie Burton
Additional Features - Michael Beauregard
Quiz Question 1 - Jianlong Li
References
- ↑ Valls N, Steiner RA, Wright G, Murshudov GN, Subirana JA. Variable role of ions in two drug intercalation complexes of DNA. J Biol Inorg Chem. 2005 Aug;10(5):476-82. Epub 2005 Sep 23. PMID:15926069 doi:10.1007/s00775-005-0655-3
- ↑ Human Telomerase Inhibition by Regioisomeric Disubstituted Amidoanthracene-9,10-diones
Philip J. Perry,†, Anthony P. Reszka,†, Alexis A. Wood,†, Martin A. Read,†, Sharon M. Gowan,‡, Harvinder S. Dosanjh,†, John O. Trent,†,§, Terence C. Jenkins,†,‖, Lloyd R. Kelland,‡ and, and Stephen Neidle*,†
Journal of Medicinal Chemistry 1998 41 (24), 4873-4884
DOI: 10.1021/jm981067o
|
