Histone - Wikipedia

Five major families of histone proteins exist: H1/H5, H2A, H2B, H3, and H4.[2][4][5][6] Histones H2A, H2B, H3 and H4 are known as the core or nucleosomal histones, while histones H1/H5 are known as the linker histones.

The core histones all exist as dimers, which are similar in that they all possess the histone fold domain: three alpha helices linked by two loops. It is this helical structure that allows for interaction between distinct dimers, particularly in a head-tail fashion (also called the handshake motif).[7] The resulting four distinct dimers then come together to form one octameric nucleosome core, approximately 63 Angstroms in diameter (a solenoid (DNA)-like particle). Around 146 base pairs (bp) of DNA wrap around this core particle 1.65 times in a left-handed super-helical turn to give a particle of around 100 Angstroms across.[8] The linker histone H1 binds the nucleosome at the entry and exit sites of the DNA, thus locking the DNA into place[9] and allowing the formation of higher order structure. The most basic such formation is the 10 nm fiber or beads on a string conformation. This involves the wrapping of DNA around nucleosomes with approximately 50 base pairs of DNA separating each pair of nucleosomes (also referred to as linker DNA). Higher-order structures include the 30 nm fiber (forming an irregular zigzag) and 100 nm fiber, these being the structures found in normal cells. During mitosis and meiosis, the condensed chromosomes are assembled through interactions between nucleosomes and other regulatory proteins.

Histones are subdivided into canonical replication-dependent histones, whose genes are expressed during the S-phase of the cell cycle and replication-independent histone variants, expressed during the whole cell cycle. In mammals, genes encoding canonical histones are typically clustered along chromosomes in 4 different highly-conserved loci, lack introns and use a stem loop structure at the 3' end instead of a polyA tail. Genes encoding histone variants are usually not clustered, have introns and their mRNAs are regulated with polyA tails.[10] Complex multicellular organisms typically have a higher number of histone variants providing a variety of different functions. Functionally, histone variants contribute to transcriptional control, epigenetic memory, and DNA repair, serving specialized functions beyond nucleosome packaging which plays distinct roles in chromatin dynamics. For example, H2A.Z is enriched at regulatory elements and promoters of actively transcribed genes, where it modulates nucleosome stability and transcription factor binding. In contrast, H3.3, a replacement variant of Histone H3, is associated with active transcription and is preferentially deposited at enhancer elements and transcribed gene bodies. Another critical variant, CENPA, replaces H3 in centromeric nucleosomes, providing a structural foundation essential for chromosome segregation.[11]

Variants also play essential roles in DNA repair. Variants such as H2A.X are phosphorylated at sites of DNA damage, marking regions for recruitment of repair proteins. This modification, commonly referred to as γH2A.X, serves as a key signal in the cellular response to double-strand breaks, facilitating efficient DNA repair processes. Defects in histone variant regulation have been linked to genome instability, a hallmark of many cancers and age-related diseases.[12]

Recent data are accumulating about the roles of diverse histone variants highlighting the functional links between variants and the delicate regulation of organism development.[13] Histone variants proteins from different organisms, their classification and variant specific features can be found in "HistoneDB 2.0 - Variants" database.[14][15] Several pseudogenes have also been discovered and identified in very close sequences of their respective functional ortholog genes.[16][17]

The following is a list of human histone proteins, genes and pseudogenes:[10]