Báo cáo khoa học: A chromatin-associated protein from pea seeds preferentially binds histones H3 and H4 pptx

Keywords: chromatin; histones; nuclear proteins; histone acetylation; histone-binding proteins.. The latter work confirmed that the overall structure of the isolated histone octamer is co

A chromatin-associated protein from pea seeds preferentially binds histones H3 and H4

Josefa Castillo, A´ngel Zu´n˜iga*, Luis Franco and M Isabel Rodrigo

Department of Biochemistry and Molecular Biology, University of Valencia, Spain

Pisum sativump16 is a protein present in the chromatin of

ungerminated embryonic axes The purification of p16 and

the isolation of a cDNA clone of psp54, the gene encoding its

precursor have been recently reported [Castillo, J., Rodrigo,

M I., Ma´rquez, J A., Zu´n˜iga, A and Franco, L (2000) Eur

J Biochem 267, 2156–2165] In the present paper, we present

data showing that p16 is a nuclear protein First, after

subcellular fractionation, p16 was clearly found in nuclei,

although the protein is also present in other organelles

Immunocytochemical methods also confirm the above

results p16 seems to be firmly anchored to chromatin, as

only extensive DNase I digestion of nuclei allows its release Far Western and pull-down experiments demonstrate a strong in vitro interaction between p16 and histones, especi-ally H3 and H4, suggesting that p16 is tethered to chromatin through histones Because the psp54 gene is specifically expressed during the late development of seed, the role of p16 might be related to the changes that occur in chromatin during the processes of seed maturation and germination Keywords: chromatin; histones; nuclear proteins; histone acetylation; histone-binding proteins

The highly conserved nucleosome core particle is formed by

146 bp of DNA wrapped around a histone octamer The

structure of the histone octamer was resolved at 3.1 A˚

resolution almost 10 years ago by the group of

Moudri-anakis, who described it as a wedge-shaped, tripartite

structure, formed by a tetramer of two copies each of

histones H3 and H4 and two flanking H2A-H2B dimers [1]

An unexpected finding was the discovery of the histone fold,

a common motif of tertiary structure, which generates the

heterodimeric pair-wise association of histones via the

handshake motif [1] Six years later, the group of Richmond

described the structure of reconstituted nucleosome cores at

2.8 A˚ resolution [2] The latter work confirmed that the

overall structure of the isolated histone octamer is conserved

in the whole core particle, and added some details to the

known structure of histones and showed the exact path of

DNA around the histones

It was recognized early on that the nucleosome structure

represents a serious obstacle to the different dynamic

nuclear processes such as transcription and, obviously,

higher order organization of chromatin adds further

impediments to the transcriptional machinery; the

pack-aging of DNA in eukaryotic chromatin results in a high

concentration of the nucleic acid, which may be as high as

0.1 mgÆmL)1in some interphase nuclei [3]

Nevertheless, chromatin cannot be just considered as a static structure A dynamic remodelling of chromatin continuously occurs at many loci and histones play a definite role in these changes, as they are the targets for many protein factors The early view of histones as mere structural proteins changed about 10 years ago to envisage them as gene expression regulators, a role that is played via specific interactions with other proteins Since the early genetic data on the involvement of histone N-terminal tails

in silencing via the interaction with specific proteins [4–8], several lines of evidence have shown that histone-binding proteins typically act as silencers, corepressors or coactiva-tors in a way often modulated by histone post-translational modifications (reviewed in [9,10]) Apart from these typical functions, histones may bind other proteins that play diverse roles, such as chaperones in chromatin assembly (reviewed

in [11,12]) or remodelling [13,14] In many cases, however, the functional role of histone-binding proteins remains still unknown [15,16]

As mentioned above, the histone N-terminal tails are involved in protein binding They are accessible both in the nucleosome [2] and in chromatin [17] and they are the site of post-translational modifications that can modulate protein binding [10] Apart from the genetic evidence referred to above, biochemical data substantiated the actual existence of proteins able to bind histones via the N-terminal tails in an acetylation-dependent manner [18–20] Nevertheless, non-histone proteins may bind non-histone domains other than the amino termini The histone fold is not restricted to core histones and it may be involved in the dimerization of several proteins [21] The use of novel methods of search for protein motifs [22,23] has allowed Sullivan et al to expand the number of known proteins having the histone-fold motif [24] Several of the proteins included in the generated database (http://genome.nhgri.nih.gov/histones/) may potentially bind histones through the histone fold For instance, the centromeric protein CENP-A and macro-H2A, a rat nonhistone, H2A-related protein, have been proposed to

Correspondence to L Franco, Department of Biochemistry and

Molecular Biology, University of Valencia, E-46100 Burjassot,

Valencia, Spain Fax: + 34 96 4635, Tel.: + 34 96 3864385,

E-mail: luis.franco@uv.es

Abbreviations: AUT, acetic acid/urea/Triton X-100; GST, glutathione

S-transferase.

*Present address: Hospital de La Ribera, E-46600 Alzira, Valencia,

Spain.

(Received 3 June 2002, revised 23 July 2002,

accepted 1 August 2002)

substitute for H3 and H2A, respectively, in some

nucleo-somes [25] In most cases, however, the histone fold of

nonhistone proteins is involved in the

dimerization-depend-ent acquisition of a tertiary structure suitable for further

interacting either with DNA or with other proteins For

instance, it has been recently found that CHRAC-14 and

CHRAC-16, two components of the Drosophila

chromatin-remodelling complex CHRAC, are able to form

heterodi-mers via their histone-fold domains These diheterodi-mers bind

ISWI, the ATPase of the complex, under conditions of

increased stringency where CHRAC-14 and CHRAC-16

alone are unable to interact with ISWI [26] A similar

situation seems to occur in HuCHRAC, the human

homo-logue of the Drosophila chromatin-remodelling complex [27]

We have recently reported the purification of a protein,

p16, abundant in the chromatin of ungerminated pea

embryonic axes, and the isolation of a cDNA clone of its

gene, psp54 The gene, which is expressed only during seed

maturation or in adult tissues undergoing hydric stress,

encodes a large polypeptide that is processed to yield p16

This protein seems to be associated to chromatin as it can be

obtained together with octamer histones from formaldehyde

cross-linked chromatin Moreover, p16 is partially

recov-ered from nuclei as heterodimers with H3 when the disulfide

bridges occurring in vivo are preserved [28] This means that

at least some of the p16 molecules are close enough to H3 to

allow them to interact in vivo with the histone, In the present

paper, we report further experiments showing that p16 is a

bona fide nuclear protein that interacts with histones,

especially with H3 and H4

M A T E R I A L S A N D M E T H O D S

Materials

Pea (P sativum, cv Lincoln) seeds were purchased locally

To obtain ungerminated embryo axes, seeds were imbibed

in cold water as described previously [29] and the embryonic

axes were excised from the cotyledons Chicken erythrocyte

histones were prepared as previously described [30] and they

were kindly provided by E Ballestar, CNIO, Madrid,

Spain Pea histones were prepared as reported elsewhere

[31] Chicken erythrocyte histones were acetylated in vitro

with [14C]acetyl-CoA in the presence of yeast recombinant

Esa1p AUT/PAGE (acetic acid/urea/Triton X-100/PAGE)

analysis showed that H3 and H4 are almost fully acetylated,

while H2A contains a mixture of acetylated and

nonacet-ylated isoforms and H2B was not acetnonacet-ylated at all The

acetylation and AUT/PAGE analysis of histones was

carried out by G Lo´pez-Rodas, Dept of Biochemistry

and Molecular Biology, University of Valencia, Spain

Subcellular fractionation of pea embryonic axes

and DNase I digestion of nuclei

Pea embryonic axes were homogenized in buffer A [300 mM

sucrose, 8 mM CaCl2, 8 mM MgCl2, 10 mM

2-mercapto-ethanol, 50 mM NaHSO3, 0.7 mM phenylmethanesulfonyl

fluoride, 20% (v/v) glycerol and 10 mMMops pH 6.0] and

nuclei were prepared from the extracts and purified by

centrifugation through Percoll [29] The supernatant

obtained after sedimenting nuclei was further centrifuged

at 10 000 g for 10 min, and the 10 000 g supernatant was

centrifuged at 100 000 g for 1 h To investigate the presence

of p16 in the different subcellular fractions, the purified nuclear fraction and both the 10 000 g and 100 000 g sediments were acid-extracted with 0.25M HCl and the soluble proteins were recovered [31] The proteins present in the 100 000 g supernatant were recovered by precipitating with cold trichloroacetic acid (final concentration 25%, v/v) For DNase I digestion, Percoll-purified nuclei were washed twice by suspending and sedimenting (1100 g,

10 min) in digestion buffer (10 mM NaCl, 1 mM MgCl2,

5 mM 2-mercaptoethanol, 0.1 mM phenylmethanesulfonyl fluoride, 0.25Msucrose, 10 mMTris/HCl, pH 7.4) and they were finally suspended in this buffer to give an attenuance at

260 nm of about 20 units per mL DNase I digestion was then carried out as described elsewhere [31]

Electrophoresis of proteins and Western blots were carried out as described previously [28]

Electron microscopy Percoll-purified nuclei were fixed, infiltrated with Lowicryl K4M and polymerized in gelatin capsules Thin sections (94 nm) were processed for colloidal gold cytochemistry as described previously [32] The samples were treated with either p16 antiserum (diluted 1 : 5000), or with preimmune serum as a control, in immunostaining buffer (0.23MNaCl, 0.1% bovine serum albumin, 20 mM Tris/HCl, pH 7.4), containing 1% fetal bovine serum A goat anti-(rabbit IgG)

Ig gold-conjugate (10 nm, Sigma) 10-fold diluted in immu-nostaining buffer containing 0.05% Tween 20 and 5% fetal bovine serum was used After rinsing with immunostaining buffer, sections were further rinsed in distilled water and stained with uranyl acetate The preparations were exam-ined and photographed in a transmission electron micro-scope Philips model CM-10

Pull-down assays

To prepare the GST-p16 fusion protein, the cDNA encoding p16 was obtained from the psp54 (28) cDNA The oligonucleotides used as primers were: 5¢-CCCCTCGA GATGTCTAGACAAAAAAAGAGTAG-3¢ and 5¢-CCC

product was excised at the XhoI site present in the primer termini and the resulting DNA was purified and cloned in phase at the XhoI site of plasmid pGEX4T-1 (Pharmacia Biotech) Escherichia coli BL21(DE3)pLysS cells (Invitro-gen) were transformed with the recombinant plasmid and with the vector alone Proteins were expressed and immo-bilized on glutathione-Sepharose beads (Pharmacia Bio-tech), following the manufacturer’s indications After isopropyl thio-b-D-galactoside induction, the cells were lysed and 600 lL aliquots of the soluble fraction were incubated with 20 lL of glutathione-Sepharose beads for

1 h at room temperature The beads were then exhaustively rinsed with 140 mMNaCl, 2.7 mMKCl, 1.5 mMKH2PO4, 8.1 mM Na2HPO4, pH 7.3 and with buffer B [15 mM

MgCl2, 150 mM NaCl, 15 mM EDTA, 10% glycerol, 0.3% Triton X-100, 0.02% NaN3, 1 mM dithiothreitol, 0.2% protease inhibitor cocktail for bacterial cell extracts (Sigma), 25 mMTris/HCl, pH 7.5]

Total core histones either from chicken erythrocytes or from pea (20 lg) or individual histone fractions (5 lg),

dissolved in 65 lL of buffer B were mixed with immobilized

GST or GST-p16 The mixture was incubated for 15 min at

room temperature in an orbital shaker The beads were then

sedimented (3000 g, 1 min) and the supernatant (unbound

fraction) was saved The beads were then successively

washed with 65 lL of buffer B containing increasing

amounts of NaCl (150, 250, 500, 700, 1000 and

2000 mM) Proteins retained after the last washing were

released by boiling the beads in gel sample buffer

Far Western blot analysis

To obtain [35S]methionine-labelled His6-p16, the cDNA

encoding p16 was obtained as above and cloned into the

XhoI site of plasmid pRSETA (Invitrogen) In vitro

transcription-translation was carried out by using a TNT

T7 Quick Coupled Transcription/Translation System

(Pro-mega) Core histones from either chicken erythrocyte or pea

were resolved by SDS/PAGE and blotted into nitrocellulose

membranes in the presence of 192 mMglycine, 0.02% SDS,

25 mMTris/HCl, pH 8.3 The membranes were incubated

for 30 min at room temperature in binding buffer [75 mM

KCl, 75 mMNaCl, 1 mMEDTA, 0.25 mMMgCl2, 0.5 mM

dithiothreitol, 0.05% Nonidet NP-40, 0.4% bovine serum

albumin, 0.4% Ficoll 400, 0.4% poly(vinyl pyrrolidone),

20 mM Hepes, pH 7.7] The membranes were afterwards

incubated for 16 h at 4Cin 2 mL of binding buffer

containing the [35S]methionine-labelled His6-p16 and they

were washed three times (10 min each) with binding buffer

The binding of [35S]methionine-labelled His6-p16 was

monitored with a fluorescent image analyser FLA-3000

(Fujifilm)

R E S U L T S

P16 is present in nuclei

The presence of p16 in pea embryonic axes nuclei has been

checked by a variety of procedures, including

immunologi-cal and biochemiimmunologi-cal methods First, we performed a

subcellular fractionation in which we prepared four

frac-tions (see Materials and methods) Figure 1 shows the

results of a representative experiment, where a protein with

the mobility of p16 is clearly present in the nuclear fraction

as well as in the 10 000 g pellet and, to a lesser extent, in the

100 000 g pellet, but it is absent from the soluble fraction

(Fig 1A) The Western blot of Fig 1B allowed the

unambiguous identification of that protein as p16 It has

to be noted that the 1000 g pellet has been further purified

by centrifugation through a Percoll gradient (see Materials

and methods) and therefore it represents a bona fide nuclear

fraction Consequently, the high proportion of p16 in this

fraction, where the most abundant proteins are obviously

the histones, is an argument in favour of the actual presence

of p16 in nuclei The protein is also present in the 10 000 g

fraction, which mainly contains mitochondria, protein

bodies and other medium-sized organelles The abundance

of p16 in this fraction cannot be accounted for by the

residual presence of nuclei or nuclear debris and it should be

concluded that, apart from nuclei, p16 is also present in

other organelles, but it is clear that p16 is not a cytosolic

component (Fig 1B) The partitioning of p16 between

nuclei and other organelles will be further discussed below

Immunocytochemical analysis of Percoll-purified nuclei provides an additional proof as to the nuclear localization of p16 In the experiment of Fig 2, a 1 : 5000 dilution of the antiserum was used to minimize any possible unspecific reaction No detectable accumulation of gold grains was observed when using preimmune serum, so the presence of immunogold in nuclei treated with p16 antiserum reflects the presence of the protein Most of the grains are visible in perinuclear regions

It is known that digestion of nuclear DNA by DNase I results in the release of chromatin-bound proteins Histones, which are tightly bound to DNA, are usually released only after extensive DNA digestion We have therefore used digestion of pea embryo nuclei to analyse the tightness of p16 binding The results of a representative experiment are given in Fig 3 Several proteins were released simply by washing the nuclei with the low-ionic strength digestion medium, and their presence in the supernatant increased by incubating nuclei in the absence of added nuclease (Fig 3A, lanes T) Therefore, these proteins could hardly be consid-ered as chromatin components, and they are probably components of the nucleoplasm Some other proteins become soluble only after DNA digestion Apart from some histones, four major polypeptides with apparent Mrof

45 000, 29 000, 21 000 and 16 000, appeared in the supernatant after more or less prolonged digestion (Fig 3A) The first polypeptide to be released, with Mr

29 000, corresponds to the high mobility group protein 1P, previously identified in our laboratory [33] The other polypeptides began to be released from chromatin only after more prolonged digestion The Western blot in Fig 3B shows that the released protein with Mr16 000 is p16 It appears in the soluble fraction only after 45 min of

Fig 1 Presence of p16 in different subcellular fractions A purified nuclear fraction (lanes 1 and 5), the sediments of 10 000 g (lanes 2 and 6) and 100 000 g (lanes 3 and 7) centrifugation and a soluble fraction (lanes 4 and 8) were prepared as described under Materials and methods, and their proteins resolved by SDS/PAGE The gels were either stained with Coomassie Blue (A) or Western-blotted and probed with 1 : 500 diluted p16 antiserum (B) The migration of size markers

is shown on the right side of (A).

digestion, when 12–15% of DNA has been rendered acid

soluble, and its release from nuclei was not complete even

after 60 min (compare lanes S and P in Fig 3A)

It seems clear that a large destabilization of the

nucleo-some core occurred before p16 was released, as both H2A

and H2B, in addition to the linker H1 histone, were

detectable in the soluble fraction prior to the appearance of

p16 in the supernatants The identity of these histones was

also checked by their distinctive mobility in AUT/PAGE

(data not shown) This fact seems to indicate that p16 is tightly anchored to DNA, either directly bound or tethered through a histone We have previously found that treatment

of nuclei from pea embryonic axes with formaldehyde results in the cross-linking of p16 to core histones [28], which suggests that the latter possibility, i.e the existence of interactions between p16 and histones, is the primary cause for the occurrence of tightly bound p16 in nuclei

P16 binds histones in a specific manner

To explore the above possibility, we first analysed p16– histone interactions by Far Western blotting The results from a typical experiment are given in Fig 4, which shows that p16 binds chicken erythrocyte and pea histones in vitro Moreover, there is a preferential interaction with H3 and H4 and, to a lesser extent, with H2B No interaction with H2A

is detected The possibility of artifacts due to the denatur-ation-renaturation of the electrophoresed proteins in Far Western blotting limits the validity of the above data

To corroborate them, we carried out a pull-down assay with an immobilized fusion protein GST-p16 The experi-ments were performed with histones from chicken erythro-cytes and from pea Figure 5 shows that GST alone is unable to retain histones as all the input material appears in the unbound fraction In constrast, the fusion protein effectively retains chicken erythrocyte histones Most of H2A and H2B is present in both the 500 and 700 mMNaCl eluates, but H3 and H4 seem to be retained to a larger extent (Fig 5A) These results suggest a somewhat preferential binding of H3 and H4, in agreement with those of the Far Western assays (Fig 4) From a qualitative point of view, the experiment with pea histones (Fig 5C) gave similar

Fig 3 Release of p16 upon DNase I digestion Nuclei from ungermi-nated pea embryonic axes were digested for the indicated time periods (in minutes) and sedimented Proteins recovered from the supernatant (lanes S) after 25% (w/v) trichloroacetic acid precipitation and the acid-soluble proteins from the residual nuclear pellet (lanes P) were analysed by SDS/PAGE (A) shows a Coomassie Blue stained gel For control, nuclei were sham-digested without added DNase I (lanes T) The migration of histones, previously identified high mobility group proteins (1P and 2P) and p16 is indicated on the margin The poly-peptides with M r 45000 and 21000 (see the text) are marked by dots on lane S-60 In the lane marked st, molecular size markers (M r 94 000,

67 000, 43 000, 30 000, 20 100 and 14 400 from top to bottom) were run (B) shows a Western blot of the samples from the supernatant at

45 and 60 min revealed with the p16 antiserum.

Fig 2 Immunocytochemical detection of p16 in nuclei purified from pea

embryonic axes Percoll-purified nuclei were fixed, thin-sectioned,

treated with preimmune serum (A) or 1 : 5000 diluted p16 antiserum

(B) and with a goat anti-(rabbit IgG) Ig gold-conjugate as described

under Materials and methods Several areas with immunogold

deposits were seen, especially in the perinuclear regions, in nuclei

treated with p16 antiserum (B) One of these areas, marked B 1 , is

magnified and shown below For comparison, another area from (A),

marked A 1 , is also magnified to verify the absence of gold deposits The

bars in (A) and (B) represent 1 lm.

results, although the preferential interaction of p16 with H3

and H4 seems to be stronger than with chicken histones To

further explore this question, we carried out a similar

experiment with purified, individual histones from chicken

erythrocytes (Fig 5B) The results show that chicken H2A

and H2B are released from the immobilized fusion protein

at comparatively low ionic strength (500 mMNaCl) In fact,

no histones remain bound to the immobilized fusion protein

after 2MNaCl washing In contrast, neither H3 nor H4 are

substantially released with the saline washing (Fig 5B) and

most of them remained bound to the immobilized GST-p16

That the complex between p16 and either histone remains

stable even in high salt indicates that the strong binding of

p16 to H3 and H4 is not predominantly due to ionic

interactions (note that p16 has an isoelectric point of about

10 [28]) In contrast to the Far Western experiments,

interaction of p16 with H2A is detected in the pull-down

assays The already-mentioned variation in histone structure

due to the denaturation-renaturation processes in Far

Western blotting may account for these differences

Acetylation of the e-amino groups of lysyl residues in the

N-terminal tails often modulates the interaction of histones

with other protein factors [20] To check whether this occurs

in the p16-histone binding, we also carried out pull-down

assays with chicken erythrocyte histones acetylated in vitro

with recombinant yeast Esa1p The yield of the acetylation

reaction, as revealed by AUT/PAGE (not shown), was high,

but some nonacetylated isoforms still remain The

pull-down experiments (Fig 6) indicate that p16 displays a

certain preference for nonacetylated histones The

compari-son of input and unbound lanes in Fig 5A clearly shows

that a large proportion of nonacetylated histones is retained

on the immobilized fusion protein and most of the bound

proteins, especially H2A and H2B, are released in the saline

washing (predominantly at 500 and 700 mMNaCl) On the

contrary, when acetylated histones were used (Fig 6), the

proportion of unbound histones is much higher and no

proteins are detectable in the saline washing These

circum-stances are particularly clear in the autoradiogram (Fig 6B)

that, obviously, displays only the acetylated histones

In conclusion, the results given in this section reveal that p16 interacts with histone in vitro, with specificity towards H3 and H4, and that the nonacetylated isoforms are somewhat preferred

D I S C U S S I O N Several of the results reported in this paper show that a proportion of p16 is localized in nuclei Immunocytochem-ical evidence (Fig 2) clearly shows that p16 is present in purified nuclei and the results of the subcellular fraction-ation (Fig 1) point are consistent with this assertion The latter experiments added an interesting finding, namely, that p16 is not uniquely located in the nucleus in pea embryonic axes but it is also present in other particulate fractions When the cDNA of psp54, the gene encoding the p16 precursor, was sequenced, both nuclear localization signals

Fig 5 Pull-down assayto show the interaction in vitro between p16 and histones A GST-p16 fusion protein was immobilized on glutathione-Sepharose beads The gel was loaded with chicken erythrocyte core histones (A), purified chicken erythrocyte histone fractions (B), or pea core histones (C) The beads were washed successively with loading buffer to recover the nonretained fraction and with buffers of increasing salt concentration as indicated After the last saline washing, the beads were recovered, boiled in SDS/PAGE loading buffer and run These later results are shown only for the experiments in (B) and (C) The gels in (A) and (C) were stained with Coomassie Blue, while (B) shows a silver-stained gel I, input fractions; U, unbound fractions The concentration (m M ) of NaCl in the successive washing solutions is indicated by the numbers above the lanes.

Fig 4 Interactions between p16 and histones probed byFar Western

blotting Core histones from chicken erythrocytes (lanes c) and from

pea (lanes p) were separated by SDS/PAGE (A) shows a

Coomassie-stained gel and (B) a similar gel blotted and probed with [35

S]methio-nine-labelled p16 The migration of size markers is indicated on the

right.

and a leader peptide sequence, were detected [28] This may

account for the fact that p16 is partitioned between the

nuclei and some other subcellular organelles The temporal

relationship between this differential targeting and the

processing of p54, the precursor 54 kDa peptide, is not

known, but there are putative bipartite nuclear localization

signals both in p16 and in the N-terminal region of the

precursor polypeptide [28], so it is theoretically possible that

p16 enters the nucleus either in the form of a precursor or

after maturation We do not yet know the nature of the

non-nuclear organelles containing p16 As p16 and p54 share

homology with seed storage proteins, these extranuclear

organelles may be protein bodies Preliminary evidence

(J Castillo & M I Rodrigo, unpublished results) seems to

support this hypothesis

The presence of p16 in nuclei is the result of a strong

interaction with chromatin components The data of Fig 3

distinctly show that, in clear contrast with the behaviour of

other nuclear proteins, p16 is released only after a somewhat

extensive digestion of DNA We have carried out digestions

of pea embryo chromatin with micrococcal nuclease; the

nucleosomes were separated in a nucleoprotein gel and a

second dimension in SDS/PAGE was run to analyse the

protein complement In these experiments (M I Rodrigo,

J Castillo & L Franco, unpublished results), p16 appears as

a component of a subset of nucleosomes These results

support the idea that p16 is a component of chromatin

In a previous paper, we showed that most, if not all, of

nuclear p16 can be recovered bound to octameric histones

after formaldehyde cross-linking of chromatin Moreover,

part of p16 was found to be close enough to H3 to became

bound to the histone through a disulfide bridge when

reducing agents were avoided during p16 extraction [28]

This latter result does not provide evidence that p16 is

recruited to chromatin via disulfide bonds but both results

suggested that p16 lies in close vicinity of core particles and

that it may result bound to chromatin through some

interaction with histones The data presented in this paper

confirm this assumption and both the Far Western blotting

experiments and the pull-down assays (Figs 4 and 5) show

that p16 interacts in vitro with histones, particularly with H3 and H4 In this context it is noteworthy that the experiments

of Fig 3 show that the release of histones H2A and H2B is substantially easier than that of p16 This fact indicates that the presence of p16 in nuclei is due to a strong interaction that requires a large disorganization of chromatin to be broken down When the preference of p16 to interact with H3 and H4, which occupy a central position in the histone octamer [1] and in the core particle [2], is considered, it is reasonable to think that p16 is tethered to chromatin in vivo due to its ability to bind H3-H4

The physical basis for the histone-binding ability of p16 is not known, although the results reported here suggest that electrostatic forces are not fundamental in this process We have analysed the sequence of p16 in search of histone folds [22,23], but this motif seems not to be present in the protein

On the other hand, acetylation of histones influences to some extent the p16–histone interactions, so the N-terminal tails of histones are probably involved in binding, although the structured domains of the histones also might partici-pate In the literature there are several examples of proteins that bind sequences of the histones corresponding to their structured domains and yet do not seem to possess the histone fold Among them are Saccharomyces Spt6p [15], and the human proteins p46, a component of the histone acetyltransferase B complex, and the highly related p48, present in the chromatin assembly factor CAF-1 [34] It seems obvious that the mechanisms of p16–histone interac-tion would deserve further analysis

Finally, we wish to discuss on the possible function of p16 It is likely, in view of our previous results [28], that the role of p16 is related to the hydric stress accompanying seed desiccation The gene encoding p16, psp54, is expressed at a high rate during seed formation and, as a result, p16 accumulates to amount to about 8% of the histones It is possible that the cells dispose of the excess p16 by storing it

in the protein bodies We have to note that many cases of proteins partitioned between nuclei and other subcellular compartments have been described These include the well-known high mobility group B nonhistone proteins [35] and there are also other examples in plants [36]

It seems evident that the functional role of nuclear p16 involves a histone-mediated chromatin binding, which only occurs in vivo during seed dessication It may be speculated that p16 is involved in protection of chromatin structure or even in the silencing of genes in preparation for, or during dormancy

A second possibility for the role of nuclear p16 arises from the work of Galvez and de Lumen [37] These authors have cloned a cotyledon-specific cDNA from soybean encoding a 2-S albumin The primary polypeptide is processed to give lunasin, an acidic protein of 43 amino acids The temporal pattern of the protein expression is similar to that of p16 and it also has histone-binding capacity, with a preference for the hypoacetylated isoforms Interestingly, lunasin, when transfected into mammalian cells, causes an arrest of cell division and the authors suggest that the role of the protein may be related to the cessation of mitosis in the last stages of plant embryogenesis via chromatin binding [37] Although no sequence homology

is found between lunasin and p16, different genes may be employed along evolution for similar functions and plants offer many examples in this line

Fig 6 Influence of the acetylation of histones on their interaction with

p16 A pull-down experiment like that of Fig 5 was carried out with

chicken erythrocyte core histones acetylated in vitro with [ 14

C]acetyl-CoA in the presence of yeast recombinant Esa1p (A) shows the

Coomassie-stained gel and its autoradiogram is given in (B) All the

symbols are as in Fig 5.

It has been recently pointed out that although the

fundamental mechanisms involved in chromatin-dependent

gene regulation are common to all eukaryotes, the data

obtained from plants have revealed some interesting

pecu-liarities [38] In this context, we should mention that the

events accompanying seed dessication and germination are

unique in the eukaryote kingdoms and probably many

lessons could be learned by studying in detail their

molecular bases We are currently studying the role of

p16, in the hope that the results may give information about

the physiological function of a plant protein, but also to

throw some light on the mechanisms that govern the

structural changes of chromatin

A C K N O W L E D G E M E N T S

This work was supported by Grant PB97-1368 from the Ministry of

Education and Culture, Spain and by Grant BMC2001-2868 from the

Ministry of Science and Technology, Spain J C is the recipient of a

fellowship from the Conselleria de Cultura Educacio´ i C iencia

(Valencia, Spain) We are very indebted to G Lo´pez-Rodas for the

gift of acetylated histones, to E Ballestar for purified histones and for

his critical comments on the manuscript and to J Renau for his advice

in electron microscopy.

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