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With the new revelations, other chro-matin regulatory mechanisms such as covalent histone Keywords chromatin; nucleosome; histones; gene expression; histone variants Correspondence P.. A

Histones in functional diversification

Core histone variants

Rama-Haritha Pusarla and Purnima Bhargava

Centre for Cellular & Molecular Biology, Tarnaka, Hyderabad, India

Introduction

Eukaryotic cells package their DNA in the form of

chromatin to accommodate it in the small space

provi-ded by their nuclei [1] In spite of the 10 000-fold

com-paction of DNA due to this packaging, minute details

of a local structure regulate the accessibility of any

small region The folding of 147 bp of DNA over a

histone octamer (two molecules each of the four core

histones, H4, H3, H2A and H2B) surface gives a neat

organization of the DNA into a chromatin fibre of

10 nm diameter The primary structure of 10 nm

chro-matin has a characteristic ‘beads on a string’

appear-ance This uniformity of the nucleosomal chain might

impose difficulties in region-specific, localized

recogni-tion and in uncoiling of the structure; both essential

for function Thus, higher order folding of the

chroma-tin into a 30 nm fibre and larger domains could be an

attempt by the genome to demarcate itself into various

regions of activities

Histones are abundant, basic, structural proteins that bring in variety and novelty to the complicated gene regulation mechanisms [1] Apart from binding to DNA and giving chromatin its strength, stability and form, certain highly similar forms of histones, termed

‘histone variants’, have evolved to carry out many vital functions Though the focus on histone variants appears to be very recent, they were known as early as

1969 when only standard biochemical methods of pro-tein fractionation could be applied to discover and iso-late new proteins [1] Their incorporation into nucleosomes as a mode of marking chromatin regions

is now shown to have high impact on gene regulation, DNA repair and meiotic events They have been impli-cated in epigenetic inheritance mechanisms of chroma-tin markings [2,3] and shown to play significant roles

in gene expression, antisilencing, heterochromatiniza-tion and the formaheterochromatiniza-tion of specialised regions of the chromatin [4–7] With the new revelations, other chro-matin regulatory mechanisms such as covalent histone

Keywords

chromatin; nucleosome; histones; gene

expression; histone variants

Correspondence

P Bhargava, Centre for Cellular & Molecular

Biology, Uppal Road, Tarnaka,

Hyderabad-500007, India

Fax: +91 40 27160591

Tel: +91 40 27192603

E-mail: purnima@ccmb.res.in

(Received 6 July 2005, accepted 22 August

2005)

doi:10.1111/j.1742-4658.2005.04930.x

Recent research suggests that minor changes in the primary sequence of the conserved histones may become major determinants for the chromatin structure regulating gene expression and other DNA-related processes An analysis of the involvement of different core histone variants in different nuclear processes and the structure of different variant nucleosome cores shows that this may indeed be so Histone variants may also be involved in demarcating functional regions of the chromatin We discuss in this review why two of the four core histones show higher variation A comparison of the status of variants in yeast with those from higher eukaryotes suggests that histone variants have evolved in synchrony with functional require-ment of the cell

Abbreviations

Cid, centromere identifier; DSB, double strand break; IRIF, irradiation induced foci; MSCI, meiotic sex chromosome inactivation;

NHEJ, nonhomologous end joining; RC, replication coupled; RI, replication independent.

modifications or ATP-dependent chromatin

remodel-ling [8–10] are joined now by histone variants This

review focusses mainly on new advances in

chromatin-related processes with reference to the ‘core histone

variants’ and their contribution to chromatin structure

Other aspects, including the role of linker histone

vari-ants, can be found in other recent reviews [11–13]

Variation in high conservation – the

evolution of histone variants

Histones are among the most conserved proteins in

eukaryotes, and make the chromatin nonstatic and

parent nucleosomes regulatory Folding of chromatin

domains is defined at a lower level by the compactness

of the basic units, guided and determined by the

his-tone–DNA as well as particle–particle interactions

High conservation of core histone structure and their

contacts with each other and with DNA leaves little

scope for any heterogeneity Therefore, apart from

try-ing to reshuffle or remove nucleosomes from the

underlying DNA, eukaryotic cells have developed

some very subtle and precise methods for breaking the

monotony of the chromatin structure by adding a

vari-ety of tags to their basic units, histones in the

nucleo-somes These taggings result in altered structures and

interactions of the core particles, affecting the local

chromatin structure Tags in the form of covalent

modifications of histone tails have been extensively

studied over the past few years [14,15] Histone codes

of the genes generated by histone modifications along

with other chromatin remodelling mechanisms have

been proposed to be the major players in gene

regula-tion mechanisms [16,17] More recent research suggests

that minor changes in the primary sequence of

con-served histones also contribute to altering the

chroma-tin structure [18–20]

The ‘bulk’ histones are encoded by genes belonging

to multicopy, intronless families that are transcribed

into nonpolyadenylated mRNA Their highly conserved

sequences suggest that they nonspecifically bind DNA

from any source A variation could be detrimental as it

may restrict the required interactions The variants are

nonallelic isoforms of the major histones that display

sequence variations, often at single residue, and occupy

restricted and defined locations in chromatin They are

encoded by genes located outside the canonical histone

gene cluster, mostly in single copies and with introns

They are constitutively expressed into polyadenylated

mRNA, and as the cell ages they replace the bulk

histones, suggesting that this exchange is an active

pro-cess throughout the cell cycle and quiescence (old age)

[21,22] The variants have diverged from the normal

histones early in the course of evolution, acquiring differential expression patterns The structural hetero-geneity conferred by the variants to chromatin can potentially regulate various nuclear functions such as transcription, gene silencing, chromosome segregation, replication, repair and recombination Such multiface-ted regulatory activities of the nucleosomes through variations in the subunits of the histone octamer would not have been possible with a strict conservation of histones at all the times and everywhere Variants have provided an added advantage

Variants of H2A Histones are proposed to have evolved from a com-mon and simple ancestral archeal protein [23,24] and followed three evolutionary histories H2A and H2B have diverged faster than H3 and H4 Different H2A variants have arisen in two single events, while variants

of H3 have probably evolved through multiple inde-pendent events [25] They have evolved slowly in such

a way that they could not only fulfill the basic function

of DNA compaction and maintain the higher order chromatin structure but also have gained functional specialization due to the acquired changes [23,26] Var-iants of H2A show divergent functions in different contexts (Table 1) H2A has the largest macro hetero-geneous family of variants and all of them are found

to have a crucial role in gene expression and nuclear dynamics [4] Five human H2A genes encode proteins with sequences considerably different from the major H2A sequence (Fig 1) Of these, H2A.X and H2A.Z were identified in the 1980s, two others (macroH2A1 and macroH2A2) in the 1990s, and finally H2A.Bbd in

2001 [27] Homologues of H2A.X are found across all phyla, including fungi, animals, plants and the most primitive eukaryotes such as Giardia [23] However, a comparative analysis of H2A.X from various organ-isms does not give a clear idea of the evolutionary links [23] The sequence of mammalian H2A.X is nearly identical to the major vertebrate H2A comple-ment H2A.1⁄ 2 homologues [27] but the distance between the globular region and carboxyl terminus in H2A.X is increased

One of the best studied H2A variants, H2A.Z com-prises roughly 5–10% of cellular H2As and probably controls several major functions of the cell [28] Highly conserved H2A.Z sequences have been given different names in different organisms The H2A variants H2A.Z (mammals), H2A.F (birds), H2A.F⁄ Z (sea urchin), H2Av (Drosophila), Htz1 (Saccharomyces cere-visiae) and hv1 (Tetrahymena) arose very early in evo-lution and are more closely related to each other than

to major H2A from the same species [25] The third

H2A variant, macroH2A (mH2A), may have evolved

comparatively recently It is a 42 kDa protein [29],

extremely divergent from major H2A, with 64%

iden-tity at its N-terminus and an extensive 25 kDa

non-histone region at the carboxyl end, which forms two

third of the protein’s molecular mass The H2A region

of this variant is 50% identical to H2A.Z, both having

homology with the corresponding region of

conven-tional H2A The nonhistone region, now termed as the

‘macrodomain’, contains a short, highly basic region

and a putative leucine zipper domain (Fig 1; amino

acids 132–159 and 181–208, respectively, in rat liver

protein) Macrodomains may be associated with

differ-ent functions as they are found in diverse proteins such

as those containing poly(ADP-ribose) polymerase

activity and other single strand RNA viral proteins

They show structural similarity to the DNA binding

domain of leucine aminopeptidases, suggesting that

DNA binding activity is associated with macrodomains [30] The exact functional status of the macrodomain

in mH2A is not known

Variants of H3 Initial studies on histone H3 variants in mice have helped to classify them according to their relationship with DNA replication The major, bulk histones are deposited over newly synthesized DNA during replica-tion in a replicareplica-tion-dependent chromatin assembly pathway, whereas the replacement histone variants undergo a replication-independent chromatin assembly [31] A replication coupled (RC)⁄ dependent assembly pathway involves a variety of components such as CAF-1, RCAF (histone chaperones) and proliferating cell nuclear antigen (PCNA), and deposits histones on replicating DNA during the S-phase [32–34] The repli-cation-independent (RI) pathway occurs outside the

Table 1 Functional diversity of histone variants.

Histone

Variant

Functional association

pericentric and telomeric heterochromatin, transcriptional activation and viability

condensation and silencing of male sex chromosome

factor binding and SWI ⁄ SNF remodelling

a Drosophila melanogaster has a single H2A variant, H2Av, in addition to the major H2A H2Av is not only a member of H2A.Z family, it also contains an SQ motif similar to mammalian H2A.X It is phosphorylated at Ser137 and hence it is a functional homologue of H2A.X.

Fig 1 Schematic comparison of the organization of histone H2A variants Solid blocks represent a-helical regions, the histone fold is consti-tuted by helices a1–a3, and the acidic patch of H2A.Z is shown by the overlined regions The C-terminal SQ motif in H2A.X, and basic as well as leucine zipper regions of mH2A are indicated.

S-phase or in nondividing cells that undergo continued

gene expression Of the three somatic H3 variants

known, H3.1 and H3.2 were classified as ‘strictly

repli-cation dependent’ and H3.3 as replirepli-cation-independent

[1] The RI variant accumulates as the tissue matures

H3.1 and H3.2 are closely related, only differing in a

Cys-to-Ser substitution at amino acid 96, and belong

to the S-phase subtypes [35] While only one type of

histone H3, similar to H3.3 is expressed [36] in yeast,

there are three variants of H3 in Drosophila; major

H3, H3.3 and centromeric centromere identifier (Cid)

H3.3 is almost identical to H3 and differs at only four

positions; one in the N-terminal tail (A31) and three in

the histone fold domain (S87, V89, M90) [37]

Centromere-specific H3 variants of all Drosophila

species are documented to show adaptive evolution

continuing for 25 million years [38] Unlike H3.3, Cid

is characteristically a structural component of the

centromeres It is very much diverged from H3, having

homologies only in histone fold domains although

con-served blocks are also seen in the N-terminal tail [38]

The evolutionary comparison of CenH3s from various

Drosophila species suggests a unique packaging

func-tion for the N-terminal tail at the cytological marker

of centromeres, the primary constriction [38] In

com-parison, human centromeric H3-like protein, CENP-A,

shows 62% identity with H3 in its carboxy terminal

portion but there is no sequence similarity in the

N-terminus, which varies from 20 to 200 amino acids

in CENP-A as compared to 45 amino acids in the

N-terminus of H3 [39] The histone fold domain of

CENP-A, the region required for localization of

CENP-A to the centromere, has evolved more rapidly

than that of H3 [23,39]

Variants of other histones

It is evident from the above description that a variety

of changes have evolved in the primary sequence of

core histones While no variants are known for H4, a

few variants of H2B and H1 are known, which play

important roles in spermatogenesis How can small

changes in the primary sequence of one of the histones

introduce a change in the overall structure of the core

particle? Can this change be tolerated? These could

have been the major issues that guided the evolution

of the variants

Variants of core histones in various

nuclear processes

Histone variants might act as ‘control panels’ in

regu-lating all DNA-related processes Minor histone

variants are now becoming known as major players in chromatin metabolism Cells exploit the intimacy of nuclear processes with the chromatin structure of genomic DNA for regulatory purposes by using chro-matin modifications and histone variants Thus, func-tional requirements of a nuclear process in which chromatin may be involved would have established the suitability of variation in histones

Variants in DNA repair and recombination Transcription in both prokaryotes and eukaryotes is coupled to the repair process, in particular nucleotide excision repair, through factors that allow recruitment

of the repair machinery by the transcription complex

at the DNA damage site [40,41] However, DNA may

be damaged under various conditions and cells have several mechanisms for its repair [42] Under nontran-scribing conditions, recognition of DNA damage and recruitment of the repair machinery may need other signalling mechanisms [43,44] For example, during radiation-induced DNA damage or other events lead-ing to double stranded breaks (DSBs) in DNA, a his-tone variant present at the DNA damage point may act as a marker for the quick recruitment of a repair complex, thereby helping to maintain the eukaryotic genome [45]

H2A.X is randomly incorporated into nucleosomes and represents 10–15% of the total cellular H2A Phosphorylation of H2A.X is suggested to mark the damaged DNA for recruitment of the repair machin-ery, although it is not clear how the damage is indica-ted in regions with bulk H2A Nevertheless, immunocytochemical analyses have shown that not every contiguous H2A.X molecule is phosphorylated [46] The carboxy terminus of H2A.X differs from that

of bulk H2A in being longer and having a four amino acid sequence element SQEL at the extreme end of the protein (Fig 1) Within this C-terminal motif, an aci-dic residue follows the two relatively invariant amino acids (SQ) while the last carboxy-terminal residue is hydrophobic [27] The SQE motif is part of the com-mon consensus motif found in targets of the phospha-tidylinositol kinases Indeed, three members of the phosphatidylinositol kinase family (ATM, ATR and DNA-PK) are now known to generate this terminally phosphorylated form called c-H2A.X While H2A phosphorylation in yeast is shown to require both ATM⁄ ATR homologues Mec1p and Tel1p in response

to DSBs [47,48], ATM is required for H2A.X phos-phorylation in murine fibroblasts [49] Recent evidence, however, shows that ATR is the kinase that phos-phorylates H2A.X and the tumour suppressor protein

BRCA1 plays an important role in recruiting ATR to

XY chromatin [50] Phosphorylation at the conserved

serine of the SQ motif (Ser129 in yeast and Ser139 in

mammals) is now shown to regulate DNA DSB repair

[45,46], meiotic recombination preceding synaptic

crossover [51], apoptotic DNA digestion following

caspase-activated DNase activity [46], V(D)J splicing

[52] and class switch recombination [53] during the

development of immunoglobulin variability

The presence of doubly charged, bulky phosphate in

c-H2A.X may generate localized decondensation of

chromatin domains with increased accessibility to

var-ious effectors such as modulating enzymes or repair

complexes, or simply mark spots for downstream

events In agreement with this, genomic DNA showed

nuclease hypersensitivity in an S129E yeast H2A.X

mutant that mimics the charged state of c-H2A.X [47]

Removal of the SQE motif leads to impaired

nonho-mologous end joining (NHEJ) in S cerevisiae, whereas

phosphorylation of the serine residue in response to

DNA fragmentation facilitates NHEJ by decondensing

chromatin at the damaged DNA sites and making it

accessible to repair factors [47] Deficiency of H2A.X

in mice leads to meiotic defects, such as retaining

unprocessed double stranded breaks after asynapsis

and increased predisposition to various tumours in the

absence of p53 [54] Thus the rapid observed

colocali-zation of the p53 binding protein1 (53BP1) with

c-H2A.X foci after introduction of DNA double

strand breaks may have great clinical implications

Phosphorylated H2A.X ensures an error-free process

by using the sister chromatid as a template in

exclu-ding the error-prone repair (single-strand annealing) at

chromosomal DSBs [55] Furthermore, H2A.X

phos-phorylation by primary DNA damage checkpoint

kin-ases makes a large chromatin domain permissive for a

de novo recruitment of cohesins required for cohesion

of sister chromatids Cohesins tether the broken DNA

ends, making them a preferred substrate for repair and

preventing the highly reactive DNA ends from

aber-rant translocations and large interstitial deletions [56]

Several examples from various species, including

Xenopus, Drosophila, mammals and S cerevisiae, have

shown that ionizing radiations and other agents that

cause double-strand breaks result in rapid and massive

phosphorylation of the histone variant H2A.X

Effi-cient, homologous recombinational repair of a

chro-mosomal DSB is evidently found to require Ser139 of

mammalian H2A.X Recent studies with yeast have

given better understanding of the involvement of

H2A.X in the repair process Yeast H2A

phosphoryla-tion is not required for activaphosphoryla-tion of S-phase DNA

damage check points [48] or for the initial recruitment

of several repair factors [57], which is followed by for-mation of large, irradiation-induced foci (IRIFs) con-taining a large number of repair factors Formation of IRIFs that sequester multiple DNA DSBs [58,59] uses the SQ motif of H2A.X [57,60], suggesting that the phosphorylation may promote the spreading and sta-bilization of the repair factors through IRIFs It is quite likely that some of the initially recruited repair factors bring in the specific kinases for the subsequent phosphoryation of H2A.X The phosphorylation is seen to spread for approximately 25 kb on both the sides of a DSB, but is absent from approximately 1–2 kb immediately adjacent This is probably due to the loss or exchange of H2A.X, brought about by the recruited chromatin modifying activities at DSBs, as discussed later

A mechanism that recruits and spreads the repair machinery from the foci having c-H2A.X at the dam-age point rather than globally recruiting it to other points having bulk H2A as well (probably via certain other mechanisms) may be advantageous for cells It reduces the number of recruitment sites and therefore the total requirement of these repair factors This may also be a mechanism of tethering the repair machinery

to the DNA double strand breaks, analogous to the transcription-coupled nucleotide excision repair path-way, which uses a general transcription factor [40,41] Phosphorylation at the SQ motif of the variant may be easier and more economical than developing a new method of marking the damage site with the bulk H2A

ATP-dependent chromatin remodelling and covalent histone modifications are two processes associated with the regulation of gene expression from a chromatin region A close relationship between chromatin remod-elling and DNA repair reported recently [61] is an excellent example of the economy practiced by cells in general It suggests that chromatin remodelling may not be a process related only to gene expression Rather, the same proteins may be active in other DNA-related processes, coupling the two processes

An HMG-like subunit, Nhp10, of the yeast chromatin remodelling complex INO80, is shown to interact with c-H2A.X at DSBs to recruit the INO80 complex Gen-etic evidence for the interaction of Nhp10 with mem-bers of the RAD52-dependent repair pathway suggests that INO80 may in turn recruit the repair machinery

at the damage site through Nhp10 [62] In Drosophila, the H2A variant H2Av, is a functional homologue of both H2A.X as well as H2A.Z in mammals [63] The Drosophila Tip60 chromatin remodelling complex acetylates nucleosomal phospho-H2Av At the same time, the ATPase activity of dTip60 exchanges the

phospho-H2Av with the unmodified H2Av, presenting

an example of two chromatin modifying activities

within the same complex [64] One of the histone acetyl

transferase (HAT) complexes of yeast, NuA4, through

one of its subunits (Arp4) is shown to associate

specif-ically with the phospho-H2A peptide Arp4, which is

also a subunit of two further ATP-dependent

chroma-tin remodelling complexes, INO80 and Swr1, is

required for the recruitment of NuA4 to DSB,

con-comitant with Ser129 phosphorylation of c-H2A.X

The other two remodellers also interact with P-Ser129,

although after NuA4 recruitment [65] Therefore,

effi-cient DNA repair in yeast appears to require

sequen-tial remodelling by three chromatin modifiers These

chromatin modifications may lead to the

decondensa-tion of the chromatin required for DSB repair, as well

as help remove the phosphorylated H2A.X and

thereby avoiding a permanent marking of the damage

spot

Variants in silencing and heterochromatinization

Eukaryotic genomic DNA is organized into two

char-acteristically different forms Euchromatin is

constitu-ted by the transcriptionally active, open and

decondensed chromatin structure In contrast,

hetero-chromatin is considered transcriptionally inactive, with

compact and highly condensed chromatin regions

Methylation of H3K9, recruitment of HP1 and other

condensing proteins, and DNA methylation participate

in the process of heterochromatinization In addition,

by virtue of their capacity to generate different

nucleo-somal conformations, some histone variants are also

known to associate with and promote the

heterochro-matin formation [66] For example, Drosophila H2Av

is found to participate in heterochromatin formation

by marking the region for subsequent acetylation at

H4K12 and methylation at H3K9 with HP1

recruit-ment [67] It shows a nonuniform pattern of wide

dis-tribution in the genome and is present in thousands of

euchromatic bands as well as the heterochromatic

chromocentre of polytene chromosomes [28]

In mouse spermatocytes, c-H2A.X plays a crucial

role in sex chromosome condensation and

transcrip-tional inactivation under the process of meiotic sex

chromosome inactivation (MSCI) It regulates

chroma-tin remodelling and associated silencing of male sex

chromosomes by initiating heterochromatinization in

the sex body Absence of H2A.X in mice results in

infertility in the male but not in the female, and several

sex body proteins such as XMR and macroH2A1⁄ 2

fail to localize to the sex chromosome [68] The

absence of condensed sex body and the failure of

meiotic pairing by X and Y chromosomes in H2A.X deficiency suggests that H2A.X is more important for heterochromatinization in the male than the female Mammalian H2A.Z is also found to be essential for establishing higher order chromatin structure at consti-tutive heterochromatic domains, probably by control-ling the localization of HP1a It is localized along with HP1a on chromosome arms but not on centromeric regions [69] Arrays of positioned nucleosomes con-taining H2A.Z over the defined sequence 208–12 DNA (12 repeats of 208 bp sea urchin 5S rDNA positioning sequence), organize into 30 nm fibres but do not con-dense into the next higher level of compaction [70], even at high Mg2+ levels that are known to promote chromatin condensation Another study has now established that the acidic patch of H2A.Z (described below) provides an altered nucleosome surface for localized compaction of chromatin fibre folding with-out crosslinking, and enhances the binding of HP1 to the condensed higher order chromatin structures [71] Therefore, H2A.Z along with HP1 appears to regulate heterochromatin formation by preventing the further compaction of the 30 nm chromatin fibre

One of the H2A variants, macroH2A, with its two nonallelic forms mH2A1 and mH2A2, appears to be involved in X chromosome inactivation It shows high-est expression in liver followed by thigh-estes [72], with one mH2A for every 30 nucleosomes in rat liver [29] Its presence in the XY body of spermatocytes indicates its role in the spermatogenic process, which is consistent with its absence in invertebrates and evolution in verte-brates It evidently associates with Barr bodies (the inactive X chromosomes) at levels higher than other chromatin proteins [73,74] The inactive chromatin of the Barr body is characterized by denser chromatin domains and higher nucleosome density, and shows the presence of both H2A and mH2A [75] Addition-ally, mH2A colocalizes on the uncoiled X chromo-some, with methylated H3-K4 at a potential activation boundary during metaphase [73], and with heterochro-matin protein M31 during meiotic prophase [76], thus suggesting that the association of macroH2A may not

be specific to the Barr body It brings about X-chro-mosome inactivation probably by stabilizing the bind-ing of Xist to the X chromosome through its nonhistone region [77]

Nucleosomes containing mH2A have altered struc-ture owing to the high a-helical content in their C-ter-minal nonhistone regions [78] The unusual structure

of mH2A with a large C-terminal tail may give a unique conformation to the nucleosome, as reflected

by their low sedimentation coefficient despite a 25% increase in the mass The core particles having mH2A

show slower gel mobility but the same stability as that

of native nucleosomes, suggesting an asymmetric and

extended conformation Presence of the nonhistone

region may be responsible for the observed DNaseI

hypersensitivity near the dyad axis and around

entry⁄ exit sites of DNA in the nucleosome [78]

Macro-H2A exerts its repressive action through control over

transcription and chromatin remodelling The presence

of mH2A in a positioned nucleosome disrupts access

for NF-jB, as well as remodelling and mobilization of

variant nucleosomes by SW1⁄ SNF without affecting

either its binding or ATPase activity [79] A

macro-H2A C-terminal region present near to a promoter

reduces the transcriptional activity, probably by acting

as a road-block to the passage of RNA polymerase

[75]

Variants in gene expression

Several core histone variants have been found to

regu-late gene expression and antisilencing mechanisms in

different ways Active participation of the chromatin

structure in the process of transcription on a

tran-scribed gene demands a dynamic nature in the

chroma-tin template requiring a constant reshuffling of the

nucleosomes over this A chromatin structure

estab-lished due to deposition of the major histones in the

S-phase of the cell cycle may not be fluid enough to

give the required dynamism, as histones are strong

DNA-binding proteins Replacement or exchange of

the major histones or their modified forms by their

variants having different affinities and strength of

binding to the DNA may provide a better alternative

outside the S-phase

RC assembly usually results in a rigid chromatin

structure over genes, which are deficient in

modifica-tions that facilitate the mobility of nucleosomes RI

assembly delineates active regions making them

relat-ively dynamic and variants mark these regions in

addi-tion to giving them the required flexibility The

replacement variant H3.3 is found to account for

 25% of total histone H3 in a Drosophila cell line,

sufficient to deposit nucleosomes on all of the

tran-scribed DNA [80] It is also found deposited over

act-ive rDNA arrays on the X chromosome, where it

shows a constant turnover The deposition of H3.3 is

directly linked to active transcription at the hsp70 gene

locus, as it stops replacing H3 after the induced gene is

switched off [81] Constitutive synthesis replenishes

H3.3, which is shown to be short-lived compared to

bulk H3 The changing of one amino acid from

his-tone H3 to its H3.3 counterpart relieved the block to

RI assembly and further deposition of H3 outside S

phase [82] Thus, while the N-terminal was required for RC deposition, specific residues in the histone fold could switch it to the RI deposition pathway, which seems to be restricted to H3.3 deposition and targeted

to transcriptionally active chromatin

In mice, the transcript levels of both H3.1 and H3.2 decrease as cell division slows down during differenti-ation, whereas H3.3 continues to be synthesized and maintained throughout differentiation Similarly, Droso-phila H3 is deposited only during S-phase, whereas H3.3 is deposited both during and outside of S-phase, suggesting that H3.3 might accumulate in nondividing cells [2] Excess accumulation of H3.3 in nerve cells leads to further severity of Rett syndrome, a common mental disorder directly related to the loss of MeCP2,

a methylated CpG binding protein MeCP2 deficiency leads to the loss of silencing mechanisms involving H3K9 methylation and histone deacetylase activity Acetylation of H3K9 is associated with active chroma-tin while H3K9 methylation marks inactive chromachroma-tin regions Thus, the unintended activation due to H3.3 accumulation (associated with transcribed regions) and excess H3 acetylation (due to reduced deacetylation) might further aggravate the condition [83]

As compared to H3, H3.3 shows several fold enrichment of modifications found on active genes, which is a significant mark for active chromatin [80,84] The chromatin modifiers introduce these act-ive modifications probably by associating with specific nucleosome assembly proteins The stepwise assembly pathway of a nucleosome core particle proposes the association of histones H3 and H4 (two copies each) into a tetramer as the first step in assembly The RC variant H3.1 and RI variant H3.3 form complexes with distinct histone chaperones [85] A histone chap-erone, HIRA, which acts as a specific nucleosome assembly factor, deposits H3.3 in a replication-inde-pendent manner [86] while CAF-1 deposits the major variant H3.1 Isolation of the two complexes also suggested that histones H3 and H4 can exist and be deposited as dimers rather than tetramers [85] Tran-scription-coupled deposition of H3.3 in an RI nucleo-some assembly pathway targets it to transcriptionally active loci throughout the cell cycle Thus, modified histones such as methylated H3, which act as an epi-genetic mark for silencing, can be rapidly replaced by H3.3 in the RI pathway A detailed account of deposition pathways for histone variants can be found in a recent review [6]

Histone replacement⁄ exchange by RI assembly on transcribed templates suggests a possible mechanism for read-through of a nucleosomal template by the enzyme RNA polymerase It was found in an in vitro

study that RNA polymerase II (pol II) can transcribe

through a nucleosome without completely displacing

histones from it [87] The protein complex facilitates

chromatin transcription (FACT) facilitates

read-through of the nucleosomal template by RNA

polym-erase II during transcription elongation [88]

Associ-ated histone chaperone activity of FACT can help

remove as well as redeposit an H2A-H2B dimer during

the transcription [89] Chromatin reassembly in yeast

becomes dependent on the Hir⁄ Hpc (human HIRA

homologue) pathway on the loss of yeast FACT

activ-ity [90], suggesting that both chaperones may be

work-ing on transcribed templates Removal of H2A⁄ H2B

by FACT may facilitate access of H3 for exchange

with H3.3 by HIRA in the next step Nevertheless, a

recent study reports the exchange of H2A.Z with bulk

H2A on the c-myc gene during transcription [91]

These findings suggest that nucleosomes can indeed be

shuffled during read-through by RNA pol II in vivo

without displacing the histone octamer completely

In the budding yeast S cerevisiae, H2A.Z is found

to be important for both positive and negative gene

regulation [92–95] Loss of Htz1 in yeast cells leads

to slow growth and formamide sensitivity at 28
C

and lethality at 37
C [96] The PHO5 promoter is

found to be more open in the htz1D ⁄ snf2D mutant

[95], suggesting this H2A variant in yeast acts with

chromatin modifiers such as SWI⁄ SNF and SAGA

on this locus Thus, it binds the PHO5 locus and

regulates its expression An important role for

H2A.Z in both gene activation and silencing is also

demonstrated by localization of H2A.Z containing

transcriptionally activated gene domains near

telom-eres as well as in regions flanking HMR loci These

regions prevent the ectopic spread of the repressor

proteins Sir2 and Sir3 into the flanking euchromatin,

as Sir proteins are found to extend beyond the

nor-mal boundaries in htz1D cells [97] Global sensitivity

of chromatin to nucleases is affected in htz1D cells

while H2A.Z is found to facilitate the recruitment of

RNA pol II transcription machinery to gene

promo-ters [92] and modulate its functional interactions with

the regulatory components This activator-like

func-tion of H2A.Z resides in its C-terminal region, which

is linked to its ability to preferentially localize to

cer-tain intergenic DNA regions [98] Thus, the

associ-ation of H2A.Z with transcriptionally active

chromatin may require the carboxy terminal and not

the histone fold region, which is essential for viability

[99,100]

The nucleosome core particles with variant H2A.Z

also showed an altered surface harbouring a metal

ion This altered surface may act as an activating

surface by participating in the recruitment of tran-scription factors and chromatin remodellers, and set the stage for gene activation upon a proper induction [98] Thus, the variant may be required to mark and not maintain the transcriptionally active state In a functional dynamic study, nucleosomes were found to show two types of large motions in space; a stretch-ing-compression along the dyad axis and the flipping, bending sideways motions with respect to the dyad axis, a result of the dynamism of the N-termini of H3 and the H2A.Z-H2B dimer The nucleosomes with variant histones show comparatively weaker correla-tions between internal mocorrela-tions, resulting in the per-turbation of interactions between the contact regions

of the variant histones with overlying DNA [19] In agreement with this, H2A.Z-H2B dimers in the vari-ant nucleosomes dissociate with comparative ease, correlating with the observation that chromatin regions containing H2A.Z probably do not require SW1⁄ SNF remodelling complexes [95] However, in a global analysis, a 13 protein complex, SWR-C, neces-sary for promoting gene expression near silent hetero-chromatic regions of yeast, is found to be required for the recruitment of Htz1 to chromatin also [101] Incorporation of Htz1 is facilitated by one of the components of SWR-C, Swr1, an ATPase of Snf2 family, which acts as a histone exchanger and effi-ciently replaces H2A with H2A.Z in nucleosome arrays [94] Genetic and biochemical approaches also demonstrated the requirement of Swr1p for the depos-ition of H2A.Z into euchromatic regions at several sites [102] Both groups identified a bromodomain (which recognizes an acetyl group) containing protein Bdf1 that also interacts with transcription factor IID (TFIID, a basal transcription factor) as another com-ponent of the Swr1 complex Higher acetylation levels

in euchromatin may recruit a Bdf1-containing Swr1 complex that may finally replace H2A with H2A.Z A genetic interaction between SWR-dependent H2A.Z recruitment at centromeres, the SWR1 complex and NuA4 (a histone H4 acetylase) is linked to chromo-somal stability [103], suggesting a direct role for H2A.Z

in chromosomal segregation Both NuA4 and SWR-C share some common subunits Acetylation is a post-translational histone modification, which happens pre-dominantly in the N-terminal tail and changes its charge H2A.Z acetylation is essential in Tetrahymena, and the replacement of all six lysines that can be acetylated with arginines is lethal Nevertheless, retaining even a single such lysine can avert this leth-ality, suggesting that the function of H2A.Z is guided through a charge patch and not the histone code [104]

Variants in different chromatin structures

Variations in core histones can give minor, localized

alterations in nucleosomal conformation Subtle

chan-ges in one of the components can generate unique

nucleosomal surfaces that may regulate interparticle

interactions thereby bringing about changes in the

three-dimensional folding of the chromatin fibre and

establishing special chromatin structural regions

Fig-ure 2 illustrates the involvement of various H2A

vari-ants in generating a variety of chromatin structures

Generation of the condensed chromatin domains

(Fig 2H), starting from fully extended and relaxed

‘beads on a string’ (Fig 2C), requires compaction of

the 10 nm fibre (Fig 2B) followed by folding,

conden-sation and superfolding through the 30 nm stage to

higher order chromatin structure The details of the

nucleosome structure in Fig 2A depict the positions where two of the core histones H3 and H2A can acquire changes H2A variants can lead to inactive or condensed heterochromatin (Fig 2D,E,G) as explained above However, they can also be found in active, euchromatic regions as described in the following stud-ies Thus, H2A.Z is one of the variants that has been found to induce both repressive and antisilencing effects

H2A.Z is essential for establishing the proper chro-matin structure required for early development in many organisms, including mice, Drosophila and Tetra-hymena [105–107] Absence of H2A.Z in mammals leads to genome instability and defects in chromosome segregation [69] During embryonic differentiation sta-ges, it is excluded from the nucleolus as well as the inactive X chromosome and made its first appearance

A

B

C

D

E

F

G

H

Fig 2 Involvement of H2A variants in the formation of different chromatin structures (A) Nucleosome core structure details showing only H3 and H2A (H4 and H2B are omitted for clarity) The right half shows the normal histones, while possible positions of the variations in amino acids are marked with an asterisk in the left hand side counterparts (B) Normal folding of the 10 nm fibre with canonical, bulk histones into the zig-zag fibre (C) The extended 10 nm fibre with ‘beads on a string’ appearance (D) H2A.X helps in higher order structure formation at the constitutive heterochromatin (E) Shorter length and greater accessibility of DNA wrapped in nucleosomes due to H2A.Bbd (F) The acidic patch of H2A.Z allows greater interaction with the N-terminal tail of H4 from the neighbouring nucleosome (G) Longer C-termini of mH2A or CENP-A may interact with the nucleosomal DNA to make nucleosomes more rigid and help further condensation (H) Condensed chromatin showing close contacts of core particles due to the dense packing.

in the pericentric regions of nucleus, providing a

poss-ible signal to distinguish constitutive and facultative

heterochromatin [108]

Biophysical studies of chromatin fibres having

H2A.Z suggested that it resists condensation when

compared to its major H2A counterpart and the fibre

assumes a relaxed conformation [70] This proposes a

mechanism under which chromatin is poised for

tran-scriptional initiation by depositing variant

nucleo-somes Native gel electrophoresis did not distinguish

between the core particles having major H2A.1 or the

variant H2A.Z, which is only 59% identical to the

conventional H2A [109] However, sedimentation

ana-lysis under changing ionic strength showed a

substan-tial instability of the variant core particle, indicating a

less tight binding of the H2A.Z-H2B dimer to the rest

of the octamer [109] A recent thermodynamic study

has confirmed that the H2A.Z-H2B dimer has the least

stable folding and that the canonical H2A-H2B dimer

shows the most stable folding [110] The 2.6 A˚

resolu-tion crystal structure of the variant nucleosome core

particle showed surprisingly small changes in the

over-all structure of H2A.Z [111] However, distinct and

subtle destabilization of the interaction between the

H2A.Z-H2B dimer and the (H3-H4)2 tetramer is seen

The L1 loop domain of H2A (Fig 2B), which ensures

incorporation of only one type of molecule, is altered

in H2A.Z As a result, pairing of H2B with both

H2A.Z and H2A within the same nucleosome core

particle leads to steric imbalance that may favour

binding to another H2A.Z A unique feature of the

acidic patch on the surface of normal H2A is extended

by replacement of Asn and Lys with Asp and Ser in

H2A.Z [111] This enhanced charge patch at the

C-ter-minus is required for higher order chromatin

forma-tion and may offer a stronger docking domain for the

H4 tail of a neighbouring nucleosome [71], thereby

promoting interparticle folding in arrays (Fig 2F)

Functional evidence of the implicit repressive role of

H2A.Z comes from a recent study demonstrating

replacement of the H2A.Z-H2B dimer by the

H2A-H2B dimer by transcribing RNA pol II [91]

While the acidic nature of the charged patch of

H2A is increased in H2A.Z, it is decreased in a newly

identified ‘Barr body deficient’ histone variant,

H2A.Bbd This is found to be 48% identical to (but

shorter than) conventional H2A Its distribution is

similar to that of acetylated H4 and it is excluded from

the inactive X chromosome, hence the name [112] Its

primary sequence in the docking domain differs

con-siderably from H2A It is conspicuous by the absence

of lysines or any of the target residues for

the post-translational modifications acetylation,

phosphorylation and ubiquitination [15], but its hall-marks are the presence of a continuous stretch of six arginines in the N-terminus

H2A.Bbd organizes only 118 ± 2 bp into nucleo-somes as compared with 147 in canonical nucleonucleo-somes [113] It gives arrays with shorter repeat length and higher nucleosome density, an organization that could repress transcription from a natural promoter in

an activator-responsive manner (Fig 2E) Within H2A.Bbd-containing nucleosome core particles, DNA ends are less tightly bound and interactions of H2A.Bbd-H2B with an (H3-H4)2 tetramer are weak [113] It is also found that the relaxed structure and altered conformation of the Bbd nucleosome is due to the changes in the H2A docking domain and not due

to the absence of the C-terminal tail Thus, H2A.Bbd has destabilizing effect on nucleosome structure under normal conditions but SWI⁄ SNF and ACF complexes (ATP-dependent chromatin remodellers) failed to mobilize H2A.Bbd containing nucleosomes [114] However, the lower stability of H2A.Bbd-containing nucleosomes may facilitate the exchange of the H2A.Bbd compared to H2A [115], probably promoting transcription through nucleosomes during the elonga-tion phase

Similar to H3.3, the third H3 variant in Drosophila, Cid, is deposited in an RI manner throughout the cell cycle An open chromatin configuration at both cen-tromeres (due to the lack of H3K9 methylation in Cid)

as well as active chromatin is proposed to be the com-mon basis of RI histone deposition at these sites [37] Conserved blocks in the N-terminus and histone fold

of Cid may mediate essential protein–protein interac-tions for recruitment of other centromeric proteins, neutralize phosphates in linker DNA and further help

in higher order chromatin structure Centromeric nucleosomes of mice also are characterized by the pres-ence of the centromeric H3 variant CENP-A [116] It

is required for the recruitment of components essential for kinetochore formation and chromosome segrega-tion; disturbance in these important activities due to targeted deletion of CENP-A in mice results in embryo-nic death [117] CENP-A competes with H3 for H4 during nucleosome formation and can be reconstituted with DNA into nucleosomes with properties similar to those of bulk nucleosomes [118] CENP-A and H4 subnucleosome tetramers are more compact and con-formationally rigid compared to normal tetramers [119] This tetrameric compaction in the nucleosomes gives the centromeres a specialized, rigid structure: a competent configuration necessary at centromeres to withstand various mechanical and physical insults of pulls to the two poles during cell division