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.
Helix-hairpin-helix The helix-hairpin-helix is found in proteins that interact with DNA in a non-sequence-specific manner. It consists of two anti-parallel
alpha-helices connected by a short hairpin loop. The two alpha-helices are packed at an acute
angle of ~25–50° that dictates the characteristic pattern of
hydrophobicity in the sequences, while other DNA-binding structures like the helix-turn-helix motif, which is also formed by a pair of helices, can be easily distinguished by the packing of the helices at an almost right angle.
Zinc finger (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. 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. 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 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. 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.
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. OB-folds bind single-stranded DNA, and hence are
single-stranded binding proteins. == Unusual ==