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DNA-binding domain

A DNA-binding domain (DBD) is an independently folded protein domain that contains at least one structural motif that recognizes double- or single-stranded DNA. A DBD can recognize a specific DNA sequence (a recognition sequence) or have a general affinity to DNA.[1] Some DNA-binding domains may also include nucleic acids in their folded structure.

Function

Example of a DNA-binding domain in the context of a protein. The N-terminal DNA-binding domain (labeled) of Lac repressor is regulated by a C-terminal regulatory domain (labeled). The regulatory domain binds an allosteric effector molecule (green). The allosteric response of the protein is communicated from the regulatory domain to the DNA binding domain through the linker region.[2]

One or more DNA-binding domains are often part of a larger protein consisting of further protein domains with differing function. The extra domains often regulate the activity of the DNA-binding domain. The function of DNA binding is either structural or involves transcription regulation, with the two roles sometimes overlapping.[citation needed]

DNA-binding domains with functions involving DNA structure have biological roles in DNA replication, repair, storage, and modification, such as methylation.[citation needed]

Many proteins involved in the regulation of gene expression contain DNA-binding domains. For example, proteins that regulate transcription by binding DNA are called transcription factors. The final output of most cellular signaling cascades is gene regulation.[citation needed]

The DBD interacts with the nucleotides of DNA in a DNA sequence-specific or non-sequence-specific manner, but even non-sequence-specific recognition involves some sort of molecular complementarity between protein and DNA. DNA recognition by the DBD can occur at the major or minor groove of DNA, or at the sugar-phosphate DNA backbone (see the structure of DNA). Each specific type of DNA recognition is tailored to the protein's function. For example, the DNA-cutting enzyme DNAse I cuts DNA almost randomly and so must bind to DNA in a non-sequence-specific manner. But, even so, DNAse I recognizes a certain 3-D DNA structure, yielding a somewhat specific DNA cleavage pattern that can be useful for studying DNA recognition by a technique called DNA footprinting.[citation needed]

Many DNA-binding domains must recognize specific DNA sequences, such as DBDs of transcription factors that activate specific genes, or those of enzymes that modify DNA at specific sites, like restriction enzymes and telomerase. The hydrogen bonding pattern in the DNA major groove is less degenerate than that of the DNA minor groove, providing a more attractive site for sequence-specific DNA recognition.[citation needed]

The specificity of DNA-binding proteins can be studied using many biochemical and biophysical techniques, such as gel electrophoresis, analytical ultracentrifugation, calorimetry, DNA mutation, protein structure mutation or modification, nuclear magnetic resonance, x-ray crystallography, surface plasmon resonance, electron paramagnetic resonance, cross-linking and microscale thermophoresis (MST).

DNA-binding protein in genomes

A large fraction of genes in each genome encodes DNA-binding proteins (see Table). However, only a rather small number of protein families are DNA-binding. For instance, more than 2000 of the ~20,000 human proteins are "DNA-binding", including about 750 Zinc-finger proteins.[3]

Types

DNA contacts of different types of DNA-binding domains

Helix-turn-helix

Originally discovered in bacteria, the helix-turn-helix motif is commonly found in repressor proteins and is about 20 amino acids long. In eukaryotes, the homeodomain comprises 2 helices, one of which recognizes the DNA (aka recognition helix). They are common in proteins that regulate developmental processes.[5]

Zinc finger

Crystallographic structure (PDB: 1R4O​) of a dimer of the zinc finger containing DBD of the glucocorticoid receptor (top) bound to DNA (bottom). Zinc atoms are represented by grey spheres and the coordinating cysteine sidechains are depicted as sticks.

The zinc finger domain is mostly found in eukaryotes, but some examples have been found in bacteria.[6] The zinc finger domain is generally between 23 and 28 amino acids long and is stabilized by coordinating zinc ions with regularly spaced zinc-coordinating residues (either histidines or cysteines). The most common class of zinc finger (Cys2His2) coordinates a single zinc ion and consists of a recognition helix and a 2-strand beta-sheet.[7] In transcription factors these domains are often found in arrays (usually separated by short linker sequences) and adjacent fingers are spaced at 3 basepair intervals when bound to DNA.

Leucine zipper

The basic leucine zipper (bZIP) domain is found mainly in eukaryotes and to a limited extent in bacteria. The bZIP domain contains an alpha helix with a leucine at every 7th amino acid. If two such helices find one another, the leucines can interact as the teeth in a zipper, allowing dimerization of two proteins. When binding to the DNA, basic amino acid residues bind to the sugar-phosphate backbone while the helices sit in the major grooves. It regulates gene expression.

Winged helix

Consisting of about 110 amino acids, the winged helix (WH) domain has four helices and a two-strand beta-sheet.

Winged helix-turn-helix

The winged helix-turn-helix (wHTH) domain SCOP 46785 is typically 85-90 amino acids long. It is formed by a 3-helical bundle and a 4-strand beta-sheet (wing).

Helix-loop-helix

The basic helix-loop-helix (bHLH) domain is found in some transcription factors and is characterized by two alpha helices (α-helixes) connected by a loop. One helix is typically smaller and due to the flexibility of the loop, allows dimerization by folding and packing against another helix. The larger helix typically contains the DNA-binding regions.

HMG-box

HMG-box domains are found in high mobility group proteins which are involved in a variety of DNA-dependent processes like replication and transcription. They also alter the flexibility of the DNA by inducing bends.[8][9] The domain consists of three alpha helices separated by loops.

Wor3 domain

Wor3 domains, named after the White–Opaque Regulator 3 (Wor3) in Candida albicans arose more recently in evolutionary time than most previously described DNA-binding domains and are restricted to a small number of fungi.[10]

OB-fold domain

The OB-fold is a small structural motif originally named for its oligonucleotide/oligosaccharide binding properties. OB-fold domains range between 70 and 150 amino acids in length.[11] OB-folds bind single-stranded DNA, and hence are single-stranded binding proteins.[11]

OB-fold proteins have been identified as critical for DNA replication, DNA recombination, DNA repair, transcription, translation, cold shock response, and telomere maintenance.[12]

Unusual

Immunoglobulin fold

The immunoglobulin domain (InterProIPR013783) consists of a beta-sheet structure with large connecting loops, which serve to recognize either DNA major grooves or antigens. Usually found in immunoglobulin proteins, they are also present in Stat proteins of the cytokine pathway. This is likely because the cytokine pathway evolved relatively recently and has made use of systems that were already functional, rather than creating its own.

B3 domain

The B3 DBD (InterProIPR003340, SCOP 117343) is found exclusively in transcription factors from higher plants and restriction endonucleases EcoRII and BfiI and typically consists of 100-120 residues. It includes seven beta sheets and two alpha helices, which form a DNA-binding pseudobarrel protein fold.

TAL effector

TAL effectors are found in bacterial plant pathogens of the genus Xanthomonas and are involved in regulating the genes of the host plant in order to facilitate bacterial virulence, proliferation, and dissemination.[13] They contain a central region of tandem 33-35 residue repeats and each repeat region encodes a single DNA base in the TALE's binding site.[14][15] Within the repeat it is residue 13 alone that directly contacts the DNA base, determining sequence specificity, while other positions make contacts with the DNA backbone, stabilising the DNA-binding interaction.[16] Each repeat within the array takes the form of paired alpha-helices, while the whole repeat array forms a right-handed superhelix, wrapping around the DNA-double helix. TAL effector repeat arrays have been shown to contract upon DNA binding and a two-state search mechanism has been proposed whereby the elongated TALE begins to contract around the DNA beginning with a successful Thymine recognition from a unique repeat unit N-terminal of the core TAL-effector repeat array.[17]Related proteins are found in bacterial plant pathogen Ralstonia solanacearum,[18] the fungal endosymbiont Burkholderia rhizoxinica[19] and two as-yet unidentified marine-microorganisms.[20] The DNA binding code and the structure of the repeat array is conserved between these groups, referred to collectively as the TALE-likes.

See also

References

  1. ^ Lilley DM (1995). DNA-protein: structural interactions. Oxford: IRL Press at Oxford University Press. ISBN 0-19-963453-X.
  2. ^ Swint-Kruse L, Matthews KS (April 2009). "Allostery in the LacI/GalR family: variations on a theme". Current Opinion in Microbiology. 12 (2): 129–37. doi:10.1016/j.mib.2009.01.009. PMC 2688824. PMID 19269243.
  3. ^ "reviewed:yes AND organism:"Homo sapiens (Human) [9606]" AND proteome:up000005640 in UniProtKB". www.uniprot.org. Retrieved 2017-10-25.
  4. ^ a b Malhotra S, Sowdhamini R (August 2013). "Genome-wide survey of DNA-binding proteins in Arabidopsis thaliana: analysis of distribution and functions". Nucleic Acids Research. 41 (15): 7212–9. doi:10.1093/nar/gkt505. PMC 3753632. PMID 23775796.
  5. ^ "HTH search at PROSITE". Expasy. Retrieved 2024-06-17.
  6. ^ Malgieri G, Palmieri M, Russo L, Fattorusso R, Pedone PV, Isernia C (December 2015). "The prokaryotic zinc-finger: structure, function and comparison with the eukaryotic counterpart". The FEBS Journal. 282 (23): 4480–96. doi:10.1111/febs.13503. PMID 26365095.
  7. ^ Pabo CO, Peisach E, Grant RA (2001). "Design and selection of novel Cys2His2 zinc finger proteins". Annual Review of Biochemistry. 70: 313–40. doi:10.1146/annurev.biochem.70.1.313. PMID 11395410.
  8. ^ Murugesapillai D, et al. (2014). "DNA bridging and looping by HMO1 provides a mechanism for stabilizing nucleosome-free chromatin". Nucleic Acids Res. 42 (14): 8996–9004. doi:10.1093/nar/gku635. PMC 4132745. PMID 25063301.
  9. ^ Murugesapillai D, McCauley MJ, Maher LJ 3rd, Williams MC (2017). "Single-molecule studies of high-mobility group B architectural DNA bending proteins". Biophys Rev. 9 (1): 17–40. doi:10.1007/s12551-016-0236-4. PMC 5331113. PMID 28303166.
  10. ^ Lohse MB, Hernday AD, Fordyce PM, Noiman L, Sorrells TR, Hanson-Smith V, Nobile CJ, DeRisi JL, Johnson AD (May 2013). "Identification and characterization of a previously undescribed family of sequence-specific DNA-binding domains". Proceedings of the National Academy of Sciences of the United States of America. 110 (19): 7660–5. Bibcode:2013PNAS..110.7660L. doi:10.1073/pnas.1221734110. PMC 3651432. PMID 23610392.
  11. ^ a b Flynn RL, Zou L (August 2010). "Oligonucleotide/oligosaccharide-binding fold proteins: a growing family of genome guardians". Critical Reviews in Biochemistry and Molecular Biology. 45 (4): 266–75. doi:10.3109/10409238.2010.488216. PMC 2906097. PMID 20515430.
  12. ^ Theobald DL, Mitton-Fry RM, Wuttke DS (2003). "Nucleic acid recognition by OB-fold proteins". Annual Review of Biophysics and Biomolecular Structure. 32: 115–33. doi:10.1146/annurev.biophys.32.110601.142506. PMC 1564333. PMID 12598368.
  13. ^ Boch J, Bonas U (2010). "Xanthomonas AvrBs3 family-type III effectors: discovery and function". Annual Review of Phytopathology. 48: 419–36. doi:10.1146/annurev-phyto-080508-081936. PMID 19400638.
  14. ^ Moscou MJ, Bogdanove AJ (December 2009). "A simple cipher governs DNA recognition by TAL effectors". Science. 326 (5959): 1501. Bibcode:2009Sci...326.1501M. doi:10.1126/science.1178817. PMID 19933106. S2CID 6648530.
  15. ^ Boch J, Scholze H, Schornack S, Landgraf A, Hahn S, Kay S, Lahaye T, Nickstadt A, Bonas U (December 2009). "Breaking the code of DNA binding specificity of TAL-type III effectors". Science. 326 (5959): 1509–12. Bibcode:2009Sci...326.1509B. doi:10.1126/science.1178811. PMID 19933107. S2CID 206522347.
  16. ^ Mak AN, Bradley P, Cernadas RA, Bogdanove AJ, Stoddard BL (February 2012). "The crystal structure of TAL effector PthXo1 bound to its DNA target". Science. 335 (6069): 716–9. Bibcode:2012Sci...335..716M. doi:10.1126/science.1216211. PMC 3427646. PMID 22223736.
  17. ^ Cuculis L, Abil Z, Zhao H, Schroeder CM (June 2015). "Direct observation of TALE protein dynamics reveals a two-state search mechanism". Nature Communications. 6: 7277. Bibcode:2015NatCo...6.7277C. doi:10.1038/ncomms8277. PMC 4458887. PMID 26027871.
  18. ^ de Lange O, Schreiber T, Schandry N, Radeck J, Braun KH, Koszinowski J, Heuer H, Strauß A, Lahaye T (August 2013). "Breaking the DNA-binding code of Ralstonia solanacearum TAL effectors provides new possibilities to generate plant resistance genes against bacterial wilt disease". The New Phytologist. 199 (3): 773–86. doi:10.1111/nph.12324. PMID 23692030.
  19. ^ Juillerat A, Bertonati C, Dubois G, Guyot V, Thomas S, Valton J, Beurdeley M, Silva GH, Daboussi F, Duchateau P (January 2014). "BurrH: a new modular DNA binding protein for genome engineering". Scientific Reports. 4: 3831. Bibcode:2014NatSR...4E3831J. doi:10.1038/srep03831. PMC 5379180. PMID 24452192.
  20. ^ de Lange O, Wolf C, Thiel P, Krüger J, Kleusch C, Kohlbacher O, Lahaye T (November 2015). "DNA-binding proteins from marine bacteria expand the known sequence diversity of TALE-like repeats". Nucleic Acids Research. 43 (20): 10065–80. doi:10.1093/nar/gkv1053. PMC 4787788. PMID 26481363.
  21. ^ Blanc-Mathieu, Romain; Dumas, Renaud; Turchi, Laura; Lucas, Jérémy; Parcy, François (July 2023). "Plant-TFClass: a structural classification for plant transcription factors". Trends in Plant Science. doi:10.1016/j.tplants.2023.06.023.

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