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Chemically induced dimerization

From Wikipedia, the free encyclopedia

Chemically induced dimerization (CID) is a biological mechanism in which two proteins bind only in the presence of a certain small molecule, enzyme or other dimerizing agent.[1] Genetically engineered CID systems are used in biological research to control protein localization, to manipulate signalling pathways and to induce protein activation.[2]

Schematic of chemically induced dimerization. Two proteins that do not normally interact (top) bind in the presence of a dimerizing agent (bottom).

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Transcription

So why is it so important to learn about protein structure? Well, let's take the example of Alzheimer's disease, which affects the brain. So in certain people as they age, proteins and their neurons start to become misfolded and then form aggregates outside of the neurons, and this is called amyloid. So amyloid is really just clumps of misfolded proteins that look a bit like this. And as you can see, as this amyloid builds up, it starts to interfere with the neuron's ability to send messages, and this leads to dementia and memory loss. So if we can understand how these proteins become misfolded in the first place, then we might be able to find a cure for this debilitating disease. And to understand how proteins become misfolded, we must first understand how they become properly folded. So before we begin, I just want to do a quick review of terms. You can have one amino acid, so I'll just write AA for amino acid. And then you can have two amino acids that are linked together by a peptide bond. So this is a peptide bond. And as you add more and more amino acids to this chain of amino acids, you start to get what is called a polypeptide, or many peptide, bonds. And each amino acid within this polypeptide is then termed a residue. And then proteins consist of one or more polypeptides. And so I will use the terms polypeptide and protein interchangeably. So at the most basic level, you have primary structure. And primary structure just describes the linear sequence of amino acids, and it is determined by the peptide bond linking each amino acid. So if I were to take my amyloid example from Alzheimer's disease and I stretch out that protein all the way, then this linear sequence is just the primary structure. So then, moving on, we have secondary structure. And secondary structure just refers to the way that the linear sequence of amino acids folds upon itself. This is determined by backbone interactions. And this is determined primarily by hydrogen bonds. There are two motifs or patterns that you should be familiar with, the first of which is called an alpha helix. And if you were to take this polypeptide and wrap it around itself into a coil-like structure, just like so, then you'd have the alpha helix. And the hydrogen bonds just run up and down, stabilizing this coiled structure. And another motif or pattern that you can be familiar with is with a beta sheet, and that just looks like this. It kind of looks more like a zigzag pattern. And the beta sheet is stabilized by hydrogen bonds, just like so. And if you have the amino ends and the carboxyl ends line up, like so, then this sheet is called a parallel beta sheet. And then conversely, if you have a single polypeptide that is then wrapping up upon itself just like this, and you have the hydrogen bond stabilizing like so, then you have the amino end coming around and lining up with the carboxyl end, and you have an anti-parallel configuration. There is a third level of protein structure called tertiary structure, and tertiary structure just refers to a higher order of folding within a polypeptide chain. And so you can kind of think of it as the many different folds within a polypeptide, which then fold upon each other again. And so this depends on distant group interaction, so distant interactions. And just like secondary structure, it is stabilized by hydrogen bonds, but you also have some other interactions that come into play, such as van der Waals interactions. You also have hydrophobic packing, and also disulfide bridge formation. So if we explore hydrophobic packing just a little bit more over here-- say we have a folded up polypeptide or protein. And this protein is found within the watery polar environment of the interior of a cell. So if we have water on the exterior of this protein, then we will find all of the polar groups on the exterior interacting with this water. And then on the interior, you would find the nonpolar or hydrophobic groups hiding from the water. Disulfide bridges, on the other hand, describe an interaction that happens only between cystines. So cystines are a type of amino acid that have a special thiol group as part of its side-chain. And this thiol group has a sulfur atom that can become oxidized, and when this oxidation occurs, you get the formation of a covalent bond between the sulfur groups. The formation of a disulfide bridge happens on the exterior of a cell, and you tend to see the formation of separated thiol groups on the interior of a cell. And that is because the interior of the cell has antioxidants, which generate a reducing environment. And since the exterior of a cell lacks these antioxidants, you get an oxidizing environment. So if I were to ask you which environment favors the formation of disulfide bridges, you would say the extracellular space does. Then there is one final level of protein structure, and that is called quaternary structure. And quaternary structure describes the bonding between multiple polypeptides. The same interactions that determine tertiary structure play a role in quaternary structure. And so let's say I have one folded up polypeptide, two folded up polypeptides, and a third and a fourth. The quaternary structure is described by the interactions between these four polypeptides. And within the completed protein structure, each individual polypeptide is termed a subunit. Since this protein has four subunits, it is called a tetramer. And so if I were to have two subunits, it would be called a dimer, three would be called a trimer, and then anything above four is called a multimer. So the term for a completely properly folded up protein is called the proper confirmation of a protein. And to achieve the proper confirmation, you must have the correct primary structure, secondary structure, tertiary structure, and quaternary structure. And if any of these levels of protein structure were to break down, then you start to have misfolding, which can then contribute to any of a number of disease states.

History

The first small molecule CID system was developed in 1993 and used FK1012, a derivative of the drug tacrolimus (FK506), to induce homo-dimerization of FKBP.[2] This system was used in vivo to induce binding between cell surface receptors which could not bind in the normal way because they lacked the transmembrane and extracellular domain. Addition of FK1012 to the cells caused signal transduction.

Chemically induced dimerization systems

Target proteins Dimerizing agent References
FKBP FKBP FK1012 [3]
FKBP Calcineurin A (CNA) FK506 [4]
FKBP CyP-Fas FKCsA [5]
FKBP FRB (FKBP-rapamycin-binding) domain of mTOR Rapamycin [6]
GyrB GyrB Coumermycin [7]
GAI GID1 (gibberellin insensitive dwarf 1) Gibberellin [8]
ABI PYL Abscisic acid [9]
ABI PYRMandi Mandipropamid [10]
SNAP-tag HaloTag HaXS [11]
eDHFR HaloTag TMP-HTag [12]
Bcl-xL Fab (AZ1) ABT-737 [13]
Anti caffeine camelid nanobody Camelid nanobody (homodimer) Caffeine [14]
VH-anti nicotine VL-anti nicotine Nicotine [15]
Anti RR120 camelid nanobody Camelid nanobody (homodimer) RR120 (Azo dye) [15]

Applications

CID has been used for a number of applications in biomedical research. In most applications each dimerizing protein is expressed as part of a fusion construct with other proteins of interest. Adding the chemical dimerizing agent brings both constructs into proximity with each other and induces interactions between the proteins of interest. CID has been used to regulate and monitor gene transcription, signal transduction and post translational modifications in proteins.

Recently, CID has also been used to create a basic component of biocomputers, logic gates, from genetically manipulated cells.[8] In this application, two independent CID systems, one based on plant proteins and one based on bacterial proteins are expressed in the same cell. Each set of proteins can be induced to dimerize by the addition of a separate chemical. By creating fusion proteins with the dimerizing proteins, membrane bound proteins and proteins that activate cell ruffling an AND gate and OR gate can be created that take chemical dimerizing agents as inputs and returns a ruffled or unruffled state as output.

References

  1. ^ Kopytek SJ, Standaert RF, Dyer JC, Hu JC (May 2000). "Chemically induced dimerization of dihydrofolate reductase by a homobifunctional dimer of methotrexate". Chemistry & Biology. 7 (5): 313–21. doi:10.1016/s1074-5521(00)00109-5. PMID 10801470.
  2. ^ a b Fegan A, White B, Carlson JC, Wagner CR (June 2010). "Chemically controlled protein assembly: techniques and applications". Chemical Reviews. 110 (6): 3315–36. doi:10.1021/cr8002888. PMID 20353181.
  3. ^ Spencer DM, Wandless TJ, Schreiber SL, Crabtree GR (November 1993). "Controlling signal transduction with synthetic ligands". Science. 262 (5136): 1019–24. Bibcode:1993Sci...262.1019S. doi:10.1126/science.7694365. PMID 7694365.
  4. ^ Ho SN, Biggar SR, Spencer DM, Schreiber SL, Crabtree GR (August 1996). "Dimeric ligands define a role for transcriptional activation domains in reinitiation". Nature. 382 (6594): 822–6. Bibcode:1996Natur.382..822H. doi:10.1038/382822a0. PMID 8752278. S2CID 3145479.
  5. ^ Belshaw PJ, Ho SN, Crabtree GR, Schreiber SL (May 1996). "Controlling protein association and subcellular localization with a synthetic ligand that induces heterodimerization of proteins". Proceedings of the National Academy of Sciences of the United States of America. 93 (10): 4604–7. Bibcode:1996PNAS...93.4604B. doi:10.1073/pnas.93.10.4604. PMC 39324. PMID 8643450.
  6. ^ Rivera VM, Clackson T, Natesan S, Pollock R, Amara JF, Keenan T, et al. (September 1996). "A humanized system for pharmacologic control of gene expression". Nature Medicine. 2 (9): 1028–32. doi:10.1038/nm0996-1028. PMID 8782462. S2CID 30469863.
  7. ^ Farrar MA, Alberol-Ila J, Perlmutter RM (September 1996). "Activation of the Raf-1 kinase cascade by coumermycin-induced dimerization". Nature. 383 (6596): 178–81. Bibcode:1996Natur.383..178F. doi:10.1038/383178a0. PMID 8774884. S2CID 4264147.
  8. ^ a b Miyamoto T, DeRose R, Suarez A, Ueno T, Chen M, Sun TP, et al. (March 2012). "Rapid and orthogonal logic gating with a gibberellin-induced dimerization system". Nature Chemical Biology. 8 (5): 465–70. doi:10.1038/nchembio.922. PMC 3368803. PMID 22446836.
  9. ^ Liang FS, Ho WQ, Crabtree GR (March 2011). "Engineering the ABA plant stress pathway for regulation of induced proximity". Science Signaling. 4 (164): rs2. doi:10.1126/scisignal.2001449. PMC 3110149. PMID 21406691.
  10. ^ Ziegler MJ, Yserentant K, Middel V, Dunsing V, Gralak AJ, Pakari K, et al. (2020-04-09). "A chemical strategy to control protein networks in vivo". doi:10.1101/2020.04.08.031427. S2CID 215790898. {{cite journal}}: Cite journal requires |journal= (help)
  11. ^ Erhart D, Zimmermann M, Jacques O, Wittwer MB, Ernst B, Constable E, et al. (April 2013). "Chemical development of intracellular protein heterodimerizers". Chemistry & Biology. 20 (4): 549–57. doi:10.1016/j.chembiol.2013.03.010. PMID 23601644.
  12. ^ Ballister ER, Aonbangkhen C, Mayo AM, Lampson MA, Chenoweth DM (November 2014). "Localized light-induced protein dimerization in living cells using a photocaged dimerizer". Nature Communications. 5 (5475): 5475. Bibcode:2014NatCo...5.5475B. doi:10.1038/ncomms6475. PMC 4308733. PMID 25400104.
  13. ^ Hill ZB, Martinko AJ, Nguyen DP, Wells JA (February 2018). "Human antibody-based chemically induced dimerizers for cell therapeutic applications". Nature Chemical Biology. 14 (2): 112–117. doi:10.1038/NCHEMBIO.2529. PMC 6352901. PMID 29200207.
  14. ^ Lesne, Jean; Chang, Hung-Ju; De Visch, Angelique; Paloni, Matteo; Barthe, Philippe; Guichou, Jean-François; Mayonove, Pauline; Barducci, Alessandro; Labesse, Gilles; Bonnet, Jerome; Cohen-Gonsaud, Martin (2019-02-12). "Structural basis for chemically-induced homodimerization of a single domain antibody". Scientific Reports. 9 (1): 1840. Bibcode:2019NatSR...9.1840L. doi:10.1038/s41598-019-38752-y. ISSN 2045-2322. PMC 6372657. PMID 30755682. S2CID 60441585.
  15. ^ a b Scheller, Leo; Strittmatter, Tobias; Fuchs, David; Bojar, Daniel; Fussenegger, Martin (2018-04-23). "Generalized extracellular molecule sensor platform for programming cellular behavior". Nature Chemical Biology. 14 (7): 723–729. doi:10.1038/s41589-018-0046-z. ISSN 1552-4469. PMID 29686358. S2CID 13821360.
This page was last edited on 4 January 2024, at 19:43
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