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Molecular and Cellular Biology, April 2001, p. 2555-2569, Vol. 21, No. 7
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.7.2555-2569.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
The Hinge and Chromo Shadow Domain Impart Distinct
Targeting of HP1-Like Proteins
James F.
Smothers and
Steven
Henikoff*
Howard Hughes Medical Institute, Division of
Basic Sciences, Fred Hutchinson Cancer Research Center, Seattle,
Washington 98109-1024
Received 11 September 2000/Returned for modification 12 October
2000/Accepted 29 December 2000
 |
ABSTRACT |
Drosophila heterochromatin-associated protein 1 (HP1)
is an abundant component of heterochromatin, a highly condensed
compartment of the nucleus that comprises a major fraction of complex
genomes. Some organisms have been shown to harbor multiple HP1-like
proteins, each exhibiting spatially distinct localization patterns
within interphase nuclei. We have characterized the subnuclear
localization patterns of two newly discovered Drosophila
HP1-like proteins (HP1b and HP1c), comparing them with that of the
originally described fly HP1 protein (here designated HP1a). While HP1a
targets heterochromatin, HP1b localizes to both heterochromatin and
euchromatin and HP1c is restricted exclusively to euchromatin. All
HP1-like proteins contain an amino-terminal chromo domain, a connecting
hinge, and a carboxyl-terminal chromo shadow domain. We expressed
truncated and chimeric HP1 proteins in vivo to determine which of these segments might be responsible for heterochromatin-specific and euchromatin-specific localization. Both the HP1a hinge and chromo shadow domain independently target heterochromatin, while the HP1c
chromo shadow domain is implicated solely in euchromatin localization.
Comparative sequence analyses of HP1 homologs reveal a conserved
sequence block within the hinge that contains an invariant sequence
(KRK) and a nuclear localization motif. This block is not conserved in
the HP1c hinge, possibly accounting for its failure to function as an
independent targeting segment. We conclude that sequence variations
within the hinge and shadow account for HP1 targeting distinctions. We
propose that these targeting features allow different HP1 complexes to
be distinctly sequestered in organisms that harbor multiple HP1-like proteins.
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INTRODUCTION |
Heterochromatin associated protein 1 (HP1) homologs are nonhistone chromosomal proteins implicated in
heterochromatin packaging. The first HP1 protein described was found in
Drosophila, where immunolocalization experiments showed the
protein's targeting preference for heterochromatin (20).
Genetic studies in flies classify mutant HP1 alleles as
dosage-dependent suppressors of position-effect variegation, a
phenomenon wherein a gene's expression is variably repressed by
juxtaposed blocks of heterochromatin (41). It is thought
that this repression event occurs via direct binding of HP1 with
chromatin, as HP1 binds to nucleosomes and DNA in vitro
(44).
While published reports describe a single HP1 gene and protein in
Drosophila, recently released sequence data from the
Drosophila genome project indicate that the fly genome
harbors two other HP1 homologs (2). Mice and humans have
at least three confirmed HP1 proteins (HP1
, -
, and -
), and
immunolocalization studies reveal distinct heterochromatin targeting
patterns for each (25). In mouse cells, heterochromatin
enriched in HP1 and HP1 is separate from less well-characterized
nuclear regions enriched in HP1, which may correspond to euchromatin
(18). More diverse spatial patterns are evident in human
cells, where each HP1 homolog targets distinct heterochromatin domains
(25). All mammalian HP1 homologs repress euchromatic gene
expression in transcriptional assays (26), and increased
dosage of HP1 has been shown to silence pericentromeric transgenes
(14). Although the mechanisms by which HP1 proteins target
and operate in heterochromatin (or euchromatin) are uncertain,
candidate domains that may be largely responsible for these processes
have been described.
HP1 contains two chromo domains, protein interaction modules located
near the amino (amino chromo) and carboxyl (chromo shadow) termini of
the protein. A variety of studies implicate these domains in HP1
function. Mutations of HP1 that either suppress positive-effect variegation (12, 30) or fail to repress gene expression in transcriptional assays (24) often map within chromo
domains or lack them altogether. Artificially truncated forms of HP1
that nevertheless localize to heterochromatin contain at least one chromo domain (30, 32), and sequence swapping experiments demonstrate that chromo domains can mislocalize protein complexes in
vivo (30). The HP1 homolog Swi6 requires the amino chromo domain for heterochromatin targeting in Schizosaccharomyces
pombe (40). In vitro binding, yeast two-hybrid, and
colocalization studies demonstrate that the chromo shadow domain can
complex with a variety of proteins (7, 10, 21), and
peptide display experiments suggest that these interactions take place
via binding to peptide pentamers (37). Recent structural
studies suggest that such peptide pentamer binding occurs exclusively
through chromo shadow dimers (6, 8). Chromo domains are
also found in non-HP1 proteins that share a conserved block of amino
acids within the folded modular domain (5). Recent
evidence suggests that at least some chromo domain-containing proteins
act as ATP-dependent chromatin modifiers (38) and histone
H3-specific methyltransferases (33). The large number of
detailed studies on the role of chromo domains stands in contrast to
the minimal characterization of the HP1 hinge, which is thought to be
merely a linker that connects the chromo domain modules of HP1
(1, 42).
A few studies indicate that the hinge may function as more than just a
linker and might contribute more directly to HP1 function. First, the
in vitro binding capacity of the HP1 chromo shadow domain for lamin B
receptor is increased by addition of the hinge sequence, suggesting
that the hinge may cooperate with chromo domain modules or contribute
to their stability (42). Second, yeast two-hybrid
experiments map HP1's interaction with inner centromere protein to the
hinge, indicating that the segment may selectively interact with other
proteins in vivo (3). Third, artificially truncated forms
of HP1 that localize to heterochromatin and contain at least one chromo
domain also include a substantial portion of the hinge (30,
32), suggesting that the hinge might contribute to targeting.
Finally, recent studies in S. pombe describe a nuclear
localization signal (NLS) within the hinge that effectively targets the
HP1 homolog Swi6 to the nucleus (40). Despite these data,
a role for the hinge in animal HP1 proteins beyond that of a connector
for chromo domains remains speculative.
In this study, we characterize the subnuclear localization patterns of
two recently discovered HP1 homologs in Drosophila, HP1b and
HP1c. Surprisingly, we find that unlike the originally described HP1
protein (referred to here as HP1a), HP1b and HP1c localize to
euchromatin and HP1c does so exclusively. Expression of truncated and
domain-swapped chimeric HP1 proteins in vivo demonstrates that both the
hinge and chromo shadow domain of HP1a independently target
heterochromatin. Targeting of HP1c to euchromatin appears to be due to
key residues within the shadow alone. Comparative sequence analyses
highlight conserved residues within the hinge that conform to a
bipartite NLS sequence, in agreement with our expression studies. Our
results strongly suggest that a lack of sufficient sequence length and
residue conservation within the hinge region of HP1c prevents the
protein from localizing to heterochromatin, resulting in exclusive
euchromatin targeting by the shadow.
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MATERIALS AND METHODS |
Comparative sequence analyses.
The sequences of HP1b and
HP1c were retrieved from public domain databases containing the
published Drosophila melanogaster genome and determined to
be free of introns or other intervening sequences within the gene
coding regions (2). Similarly, HP1a cDNA and protein
sequences were retrieved, and BLAST programs (4) were
employed, using Drosophila HP1 primary sequence or embedded
sequences of HP1 found in the Blocks database (15) to find
HP1 homologs in other species. HP1 sequences were aligned using Clustal
W (http://dot.imgen.bcm.tmc.edu:9331/multi-align/multi-align.html) and Block Maker (http://www.blocks.fhcrc.org). Multiple alignments were
viewed directly using Boxshade
(http://www.ch.embnet.org/software/BOX_form.html) or converted to
sequence logos (35) using the Blosum 62 matrix scoring
(16). Alignments were also used to generate
neighbor-joining trees
(http://blocks.fhcrc.org/blocks/help/about_trees.html). The Prosite
database (http://expasy.ch/prosite) was searched for motifs within HP1 sequences.
Determination and cloning of HP1 sequences.
We designed
oligonucleotides corresponding to the precise beginning and end of each
open reading frame in the HP1a (originally described HP1), HP1b, and
HP1c genes. The limits of individual HP1 segments were estimated from
examining three-dimensional structures (5, 6, 8) and
sequence alignments (Fig. 1A).
Oligonucleotides flanking the open reading frames of these segments (or
full-length sequences) were used along with Klentaq polymerase
(Clontech) to amplify individual cDNA portions by PCR from genomic DNA
(HP1b and HP1c) or cDNA (HP1a). Combinations of these oligonucleotides were used to generate products that contained only the amino chromo domain and hinge segments or the hinge and chromo shadow domain of
HP1a. XbaI and EagI restriction sites were
included on upstream and downstream oligonucleotides, respectively, for
ease in subcloning. Alternatively, downstream primers that contained
both NheI and EagI sites were used to
sequentially ligate domain-swapped chimeras of HP1a and HP1c genes
(illustrated in Fig. 6C), introducing two amino acid linkers (AR)
between alternating segments. For these studies, amino acids 1 to 77 and 141 to 205 containing the HP1a amino chromo and chromo shadow
domains, respectively, were used, and amino acids 78 to 140 represent
the HP1a hinge. For HP1c, amino acids 1 to 62 and 79 to 139 containing
the HP1c amino chromo and chromo shadow domains, respectively, were
used, and amino acids 63 to 78 represent the HP1c hinge. PCR products
were digested, subcloned into either of two expression vectors (see
below), and transformed into DH5 cells (Gibco BRL).
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FIG. 1.
Sequence length and composition distinguish three
Drosophila HP1 homologs. The primary amino acid
sequences of HP1a, HP1b, and HP1c were aligned using Clustal W and
Blosum 62 substitution matrix scoring, followed by import into the
Boxshade program to highlight identities (dark shading) and
similarities (light shading) at each position (A). The amino chromo and
chromo shadow domains are indicated by brackets. The hinge sequence in
each protein is represented by the amino acids that lie between the
chromo domain modules. Each HP1 sequence is scaled to illustrate
sequence differences among individual homologs schematically (B).
Unlabeled segments of the schematic representations (dark grey boxes)
depict sequences that lie outside of characterized HP1 domains. Amino
acid sequences from HP1 homologs in Drosophila and other
species were examined using Block Maker to delineate regions of shared
conserved sequence and construct a neighbor-joining phylogenetic tree
(C). The Swi6 sequence is not included in the phylogeny because it is
not similar enough to animal homologs to survive the stringent sampling
protocol using Block Maker.
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Construction of truncated and chimeric gene expression
plasmids.
The green fluorescent protein (GFP) expression plasmid
pPgH2Bhs (17) was digested with XbaI and
EagI to remove histone H2B DNA, gel purified, and treated
with alkaline phosphatase to create a cloning vector for all
carboxyl-terminally tagged GFP fusion chimeric genes (pPghs). A sample
of one such plasmid, coding for the amino chromo domain alone (Ca-GFP),
was digested with XbaI and Bsu36I and treated
with alkaline phosphatase to remove both the chromo domain cDNA as well
as a majority of the GFP-coding sequence. Oligonucleotides were
designed to carry an upstream NheI endonuclease site, an
amino-terminal c-Myc epitope tag, a cloning site with XbaI
and EagI, and a downstream Bsu36I site. Following
primer extension with modified T7 polymerase (Sequenase; Amersham), the
double-stranded DNA insert was digested with NheI and
Bsu36I and cloned into the phosphatase-treated vector to
create a vector for all amino-terminally c-Myc-tagged subclones
(pPMychs). A Myc-GFP control plasmid was constructed by digesting the
double-stranded DNA insert bearing c-Myc with NheI and
EagI, followed by ligation into the GFP vector. DNA
sequencing was performed prior to transfection and expression studies.
Cell transfection and protein expression.
Drosophila Kc167 cell transfection, growth on coverslips,
and induction by heat shock were performed as described by Henikoff et
al. (17), with the following exceptions. Cells were heat shocked at 37°C for 2 h and allowed to recover at 25°C for
6 h. Twenty micrograms of plasmid was used for all single
transfections. The time intervals for both heat shock and recovery were
derived empirically using full-length HP1a fusions and the Myc-GFP
proteins as positive controls. Timing was designed to provide enough
protein for sufficient detection in situ without introducing detectable displacement of endogenous HP1 via overexpression. Comparison of
HP1a-staining intensity between transfected and untransfected cells was
used to monitor for these conditions.
Production of affinity-purified HP1 antibodies.
The peptide
amino-KDRPSSSAKAKETQGRASSSTSTASKR-carboxyl, corresponding to a portion
of the Drosophila HP1a hinge, was synthesized with
prephosphorylated serines at positions 7 and 25 to mimic predicted
sites of in vivo phosphorylation (11). This peptide was
used to immunize a rabbit as previously described (29). Antibodies from this serum were affinity purified using the immunizing peptide and an AminoLink affinity column (Pierce) to create
-HP1a-hinge antibodies. The same procedure was performed to produce
-HP1a-chromo antibodies from rabbit antiserum raised against a
portion of the Drosophila HP1 amino chromo domain
(29). The peptides amino-CASPIGSINQDENIKPDESSELDN-carboxyl and amino-CPNLIQKFEESRAKSKKRGEK-carboxyl, corresponding to portions of
the Drosophila HP1b and HP1c proteins, were synthesized and used to immunize rabbits (Biosource International/QCB Division, Hopkinton, Mass.). Affinity-purified antibodies were fractionated from
each rabbit antiserum and used for immunofluorescence.
Immunofluorescence and microscopy.
Indirect
immunolocalization of polytene chromosomes was performed as described
by Platero et al. (29). Indirect immunolocalization, microscopy, and image analysis of Kc cells were performed as described by Henikoff et al. (17), with the following exceptions. A
monoclonal mouse antibody raised against the human c-Myc epitope (Santa
Cruz Biotechnology) was used at a dilution of 1:200 in PBG
(phosphate-buffered saline with 0.5% bovine serum albumin and 0.2%
fish gelatin) for immunolocalization of Myc-tagged chimeric proteins.
-HP1a-chromo and -HP1a-hinge were used at dilutions of 1:100 and
1:300, respectively, in PBG. The mouse HP1-specific monoclonal antibody
C1A9 (20) was kindly provided by Sarah Elgin and used at a
dilution of 1:100. The Antibodies specific to HP1b (-HP1b) and HP1c
(-HP1c) were used at dilutions of 1:500 and 1:200, respectively.
Fluorescein isothiocyanate-conjugated goat anti-mouse and Texas
red-conjugated goat anti-rabbit and anti-mouse secondary antibodies
were used to detect primary sera, and all samples were stained with
4',6-diamidino-2-phenylindole (DAPI). Deconvolved images were imported
into Adobe Photoshop for quantitative analysis.
Comparative quantitation of expressed proteins.
Images were
acquired using identically timed exposures of at least 15 transfected
cells (selected at random) representing each expression plasmid.
Fluorescent signal strength at each pixel was determined using Adobe
Photoshop, where intensity can range from a value of 0 (no signal) to
255 (saturated). To alleviate background epifluorescence, a region far
removed from the transfected cell image was selected for a value of 0 in all color channels. For evaluation of HP1 staining, the mean pixel
intensity was determined for the HP1 staining area in untransfected and
transfected cells on the same acquired image. For GFP calculations, the
nuclear area was determined by selecting the perimeter of the
DAPI-staining region of a single cell in the blue channel. Next, GFP
signal was quantitatively assessed in the green channel. To determine cytoplasmic signal, the nuclear region was selected and deleted, followed by selection and quantitative assessment of GFP signal remaining in the cell image. The mean pixel intensity was used as the
unit of measure for both nuclear and cytoplasmic GFP quantitations. To
compare relative total expressed nuclear protein among various chimeras, the total pixel intensity (number of staining pixels × mean intensity) of either c-Myc staining or GFP fluorescence within
transfected nuclei was divided by the mean total pixel intensity
determined for the control protein Myc-GFP. Ratios expressing this
calculation represent the amount of protein expressed relative to the
control protein Myc-GFP. Ratios representing HP1 enrichment were
calculated by determining the mean pixel intensity of GFP fluorescence
within HP1-staining heterochromatin and dividing this value by the mean
value determined in the surrounding euchromatin of the same transfected
cell. The adjacent staining region found in nuclei transfected with
hinge-containing plasmids was avoided, although similar ratios were
obtained when this region was included in the analyses.
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RESULTS |
HP1-like proteins in D. melanogaster.
We verified
published D. melanogaster gene sequences corresponding to
HP1 homologs (2) via independent PCR cloning and sequencing using fly genomic DNA as template. The coding sequences of
HP1a, HP1b, and HP1c were also used to search expressed sequence tag
(EST) databases. Like other bona fide HP1 homologs, all three fly HP1
sequences are equally and extensively represented among EST data sets,
clearly distinguishing them from HP1 pseudogenes that do not express
functional proteins (28). EST representation also
indicates that HP1b and HP1c are expressed in Drosophila cell types as abundantly as HP1a.
We aligned all three full-length fly HP1 protein sequences for direct
comparison of previously characterized regions common
to all HP1
homologs and to identify any additional unique sequences
among them
(Fig.
1A). Differences are readily apparent when either
the HP1b or
HP1c sequence is compared to the HP1a primary amino
acid sequence.
First, while the amino chromo domain begins at
nearly 20 amino acids
from the N terminus in HP1a, this module
is located at the very N
termini of HP1b and HP1c. Second, a highly
acidic N-terminal portion of
the amino chromo domain is absent
from HP1b and HP1c. Third, the hinge
region is much smaller in
HP1b and HP1c (37 and 18 residues,
respectively) than in HP1a
(63 residues). Finally, extensive C-terminal
tails are present
in both HP1b and HP1c (88 and 99 residues,
respectively), compared
to the 5-residue tail of HP1a. We detect no
significant sequence
similarities for these C-terminal tails either to
each other or
to reported proteins or characterized motifs in current
databases.
These differences are summarized in Fig.
1B.
A phylogenetic tree was constructed based on the conserved amino chromo
and chromo shadow domains shared among all HP1 family
members (Fig.
1C). The phylogeny is inconsistent with orthology
between individual
fly (HP1a, HP1b, and HP1c) and vertebrate (HP1
,
HP1
, and HP1
)
proteins. Also, branch lengths are similar when
either HP1b or HP1c is
traced to a common node with known heterochromatin-specific
HP1
homologs (HP1
and HP1
) or homologs that are implicated in
euchromatin localization (HP1
;
Tetrahymena and
Planococcus homologs).
Ciliate HP1 localizes to discrete
chromatin compartments of nuclei
that excise most heterochromatic
sequences during development,
suggesting that their localization is not
entirely exclusive to
a heterochromatin compartment (
19).
The only characterized mealybug
HP1 homolog (Pchet 1) localizes to both
heterochromatin and euchromatin,
indicating that the protein has less
specificity for heterochromatin
(
13). We conclude that
HP1b and HP1c are no more closely related
to HP1a orthologs than to
homologs that do not show heterochromatin-specific
localization.
Endogenous HP1b and HP1c are expressed and localize to
euchromatin.
We raised antibodies to HP1b and HP1c to confirm
expression of the endogenous genes and to determine the localization of
their encoded proteins. Larval salivary glands were examined using a combination of mouse -HP1a and rabbit -HP1a, -HP1b, or
-HP1c (Fig. 2A). -HP1a colocalizes with the heterochromatin-rich
chromocenter (Fig. 2A), as expected from
previous studies (20). However, neither HP1b nor HP1c
colocalizes with HP1a at the chromocenter of polytene chromosomes.
Rather, both HP1b and HP1c appear to localize ubiquitously along the
euchromatic chromosome arms. This different localization behavior of
HP1 homologs from HP1a itself motivated a detailed characterization of
these proteins' subnuclear localization properties.
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FIG. 2.
HP1-like proteins are expressed in Drosophila
polytene and Kc cells. Salivary glands were removed from 2- to
4-day-old Drosophila larvae and subjected to indirect
immunofluorescence (A) using a mouse monoclonal antibody
[-HP1a(m)] raised against HP1a (green) and affinity-purified
rabbit antibodies raised against HP1a, HP1b, or HP1c (-HP1a/b/c)
(red). The DNA-specific dye DAPI was used to stain chromosomes in all
preparations (blue). Arrowheads denote the heterochromatin-rich
chromocenter. Drosophila Kc cells were transfected with
plasmid expressing HP1a (Myc-HP1a) fused to the c-Myc epitope (B).
Cells were probed with mouse monoclonal anti-Myc antibody (-Myc) and
affinity-purified rabbit antibodies raised against HP1a, HP1b, or HP1c
(-HP1a/b/c) (red). Numbers in panel B reflect mean fluorescent pixel
intensities and standard deviations for HP1a immunostaining in
transfected and untransfected cells. The scale bars are equivalent to
20 µm (A) and 2.5 µm (B).
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HP1a targets the heterochromatin-rich chromocenter of
Drosophila Kc cells.
We used Kc cells to characterize
the localization of an epitope-tagged HP1a protein and compare its
expression levels to that of endogenous HP1a. Cells were transfected
with a plasmid that codes for the c-Myc epitope N-terminally fused with
full-length HP1a (Myc-HP1a). Myc-HP1a targets efficiently to the
chromocenter, colocalizing with endogenous HP1a immunostaining (Fig.
2B, top row). HP1a staining is largely restricted to a single and
substantial region of the interphase nucleus. Identical results were
obtained when staining untransfected cells with mouse and rabbit HP1a
antibodies (not shown). Coalescence of heterochromatin has been
previously observed in various Drosophila cell types
(20, 32), including Kc cells (15, 39), and is
commonly referred to as the chromocenter. Unlike the case for polytene
nuclei, there is no underrepresentation of heterochromatin in the
chromocenter of Kc cell nuclei. The large and consistent chromocenter
makes Kc cells a favorable system in which to discriminate between
heterochromatin and euchromatin localization patterns of HP1-like
proteins. We detected no significant differences in mean HP1a staining
intensities between untransfected (109 ± 18.1) and transfected
(118 ± 15.2) cells, indicating that transfected HP1a levels are
lower than endogenous HP1a levels (Fig. 2B).
HP1b and HP1c localize to euchromatin in Kc cells.
We next
examined the localization patterns of native HP1b and HP1c in
untransfected Kc cells and those expressing Myc-HP1a (Fig. 2B). HP1b is
diffuse throughout the nucleoplasm of Kc cell nuclei, overlapping with
but not restricted to Myc-HP1a-decorated heterochromatin. An intense
region of HP1b staining lies adjacent to the heterochromatic
chromocenter. In contrast, HP1c staining is restricted to the
euchromatin compartment of Kc cells and does not colocalize with
Myc-HP1a at the heterochromatic chromocenter.
We next transfected cells with plasmids that express epitope-tagged
fusion proteins of HP1b (Myc-HP1b) and HP1c (Myc-HP1c)
to compare their
localization patterns to native proteins HP1a,
HP1b, HP1c, and Cid, a
centromere-specific antigen that resides
within the chromocenter
(
17). Myc-HP1b targets both euchromatin
and
heterochromatin, although the extra intensely stained region
seen with
-HP1b is not observed (Fig.
3A) and
may represent a
cross-reacting epitope. Myc-HP1c colocalizes with
-HP1c, being
restricted to euchromatin (Fig.
3B). These results
suggest that
sequence differences among
Drosophila HP1
homologs may confer
their distinct targeting.
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FIG. 3.
HP1a, HP1b, and HP1c localize to distinct regions of
Drosophila nuclei. Drosophila Kc cells were
transfected with plasmids expressing either HP1b (A) or HP1c (B) fused
to the c-Myc epitope. Samples were probed with mouse monoclonal
anti-Myc antibody (-Myc) and costained with affinity-purified rabbit
antibodies raised against HP1a (-HP1a), HP1b (-HP1b), HP1c
(-HP1c), or Cid (-Cid). Mean fluorescent pixel intensities for
-HP1b and -HP1c between nontransfected and transfected cells were
similar (data not shown). The scale bar is equivalent to 5 µm for all
micrographs.
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Heterochromatin targeting by the HP1a hinge.
To delineate the
segment(s) of HP1a sufficient for heterochromatin targeting, we
transfected cells with plasmids that express GFP fused to individual
segments of HP1a. Antibodies raised to epitopes that lie outside of
each segment were used to distinguish endogenous HP1a from the amino
chromo domain (Ca-GFP), hinge (Ha-GFP), or chromo shadow domain
(Sa-GFP) of HP1a tethered to GFP. As expected for our positive control,
HP1a-GFP targets the heterochromatin-rich chromocenter (Fig.
4A). However, Ca-GFP and Sa-GFP are
distributed uniformly throughout the nucleus, similar to a negative
control Myc-GFP fusion. Although the Ha-GFP protein also exhibits a
light uniform nuclear distribution, a higher concentration of the
protein that colocalizes with HP1a-staining heterochromatin is readily detected; this higher concentration is not entirely restricted to
heterochromatin and overlaps with a nearby region of the nucleus seemingly devoid of HP1a (Fig. 4). This may be the ribosomal DNA, which
is located within a large block of heterochromatin on the proximal
portion of the X chromosome.
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FIG. 4.
The HP1a hinge concentrates in
heterochromatin. Plasmids that code for GFP fused to the amino
chromo domain (Ca-GFP), hinge (Ha-GFP), chromo shadow domain (Sa-GFP),
or residues 18 to 200 of HP1a (HP1a-GFP) were expressed in cells (A).
Antibodies that recognize only the HP1a chromo domain were used to
detect endogenous HP1a in hinge-GFP-transfected cells. Hinge-specific
HP1a antibodies were used for the other samples shown. As a control,
cells expressing Myc-GFP were similarly fixed and processed for
microscopy. Closed arrowheads denote heterochromatin, and open
arrowheads indicate an area of intense GFP signal that lies adjacent to
HP1a-rich heterochromatin. Total fluorescent pixel intensity
(number of staining pixels × mean intensity) within
transfected nuclei was determined for each expressed protein and
divided by the mean total pixel intensity determined for the control
protein Myc-GFP and expressed as a ratio (B, left). This ratio
indicates the amount of total protein among expressed chimeras relative
to the Myc-GFP protein standard. The mean fluorescent pixel intensity
of GFP fluorescence overlapping HP1a-staining heterochromatin was
divided by the mean pixel intensity of GFP fluorescence overlapping
euchromatin and expressed as a ratio (B, right). This ratio indicates
the relative heterochromatic enrichment of each expressed protein
(i.e., 1 = no enrichment, 2 = 2 fold enrichment, etc.). Error
bars represent standard deviations from means. Bar = 5 µm.
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To quantify our observation that the hinge targets heterochromatin, we
compared GFP signal intensities of various HP1a segment
fusion proteins
within heterochromatin and euchromatin. First,
the total fluorescent
pixel intensity for each expressed protein
was determined and divided
by the value obtained for the control
Myc-GFP protein (Fig.
4B, left).
The results show no significant
difference in relative protein levels
for the various expressed
proteins in transfected cell nuclei. We next
calculated the mean
pixel intensity of GFP signal contained within
HP1a-rich heterochromatin
and divided this value by the value observed
in euchromatin of
transfected cells. As expected, a mean ratio close to
1 (no enrichment)
was observed for Myc-GFP, while nearly a fourfold
enrichment was
noted for HP1a-GFP (Fig.
4B, right) which readily
localizes to
HP1a-rich heterochromatin (Fig.
4A). Of all three
individual segments,
heterochromatin targeting (nearly 2.5-fold
enrichment) was seen
only for Ha-GFP, while Ca-GFP and Sa-GFP were more
similar to
the Myc-GFP negative
control.
To detect any influence that chromo domains might have on
heterochromatin targeting by the hinge, we expressed proteins
containing
multiple HP1a segments. Epitope-tagged proteins containing
either
the amino chromo domain and hinge (Myc-CHa and CHa-GFP) or the
hinge and chromo shadow domain (Myc-HSa and HSa-GFP) of HP1a were
expressed in transfected cells. Myc- and GFP-labeled proteins
show
similar localization patterns (compare Fig.
5A and
B). Concentrated
signal for all of these
proteins overlaps with HP1a-staining chromocenters;
however, expressed
protein is also detected in a region of the
nucleus adjacent to
HP1a-staining heterochromatin (Fig.
5). This
pattern resembles that
observed using the hinge alone (Fig.
4),
suggesting that chromo domains
do not significantly alter targeting
by the hinge. Quantitation of
total expressed protein levels and
heterochromatin enrichment of these
proteins reveal that targeting
by these truncated proteins is nearly
identical to that of the
hinge segment alone (Fig.
5C). We conclude
that the HP1a hinge
can target heterochromatin.
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FIG. 5.
Chromo domains localize to heterochromatin when tethered
to the HP1a hinge. Cells were transfected with plasmids that code
for either the amino chromo domain and hinge (Myc-CHa and CHa-GFP) or
the hinge and chromo shadow domain (Myc-HSa and HSa-GFP) of HP1a.
Following expression, cells were fixed and processed for indirect
immunofluorescence. Cells expressing c-Myc (A) or GFP (B) fusion
proteins are shown separately. Closed arrowheads denote
heterochromatin; open arrowheads indicate an area of intense
fluorescent signal that lies adjacent to HP1a-rich heterochromatin.
Bar = 5 µm. Relative nuclear protein and heterochromatin
enrichment ratios are shown along with negative (Myc-GFP) and positive
(HP1a-GFP) controls (C), all of which were determined as described in
the legend to Fig. 4. M, c-Myc fusion protein; G, GFP fusion protein.
|
|
Chromo shadow domains target HP1 homologs, independently of hinge
segments.
Our results showing heterochromatin targeting by the
HP1a hinge (summarized in Fig. 6A) appear
to conflict with studies that implicate chromo domains as targeting
modules (30, 32). To resolve this, we constructed HP1
chimeras to determine whether chromo domains can target HP1a
independently of the hinge. We first generated an HP1a chimera with a
polyglycine linker sequence swapped for the natural HP1a hinge region
(Ca-Sa). As a positive control for the ligation procedure used to
insert this linker, the entire HP1a coding sequence was reconstructed
from all three HP1 segments, using the same subcloning techniques
(CaHaSa). In agreement with published studies, the Ca-Sa protein
localizes as effectively and exclusively to heterochromatin as either
full-length HP1a or the reconstructed CaHaSa protein (Fig. 6B).
Therefore, HP1a chromo domains can target heterochromatin independently
of the hinge. However, these results do not indicate whether the amino
chromo, chromo shadow, or both modules are sufficient for heterochromatin targeting.
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FIG. 6.
The HP1a hinge and HP1c carboxyl-terminal tail are not
essential for targeting. (A) Diagram illustrating the results of
HP1a truncation and segment replacement studies. Plasmid nomenclature
is indicated next to bars representing each protein. Chimera diagrams
are grouped according to their subnuclear localization patterns,
illustrated to the right of each pattern set. The illustrations reflect
both euchromatin and heterochromatin (top) and heterochromatin only
(bottom) localization patterns. Cells were transfected with plasmids
that code for either all three HP1a segments ligated together artificially (CaHaSa) or only
the amino chromo and chromo shadow domains of HP1a joined by a
polyglycine linker sequence (Ca-Sa). Other cells were transfected to
express a subclone of HP1c that truncates after the chromo shadow
domain (CHSc). All expressed proteins contain N-terminal fusions to the
c-Myc epitope. Following expression, cells were fixed and processed for
indirect immunofluorescence using the antibodies indicated (B).
Bar = 5 µm. (C) Diagram illustrating the subcloning strategy for
c-Myc epitope-tagged (N-terminal) HP1 chimeric genes. PCR-amplified
segments from HP1a and HP1c were sequentially ligated to create the
chimeras illustrated. Bar color is used to distinguish segments of HP1a
(blue) from those of HP1c (yellow). Uncharacterized sequences are
shaded in grey. The illustrations reflect euchromatin only (top), both
euchromatin and heterochromatin (middle), and heterochromatin only
(bottom) localization patterns.
|
|
To delineate both heterochromatin and euchromatin targeting segments of
HP1 homologs, we swapped domains between heterochromatin-specific
HP1a and euchromatin-specific HP1c (Fig.
6C). As a control for
these chimeric protein studies, we expressed an epitope-tagged
HP1c
protein that is truncated upstream of its extensive C-terminal
tail
(CHSc). CHSc localizes identically to full-length HP1c, targeting
euchromatin exclusively (Fig.
6B). It is possible that a euchromatic
targeting determinant resides within the amino chromo, hinge,
or chromo
shadow segment of HP1c. Alternatively, a lack of heterochromatin
targeting segments might result in euchromatin deposition by
default.
The localization patterns of HP1a-HP1c chimeras fall into three
distinct categories: (i) euchromatin only, (ii) euchromatin
plus
heterochromatin, and (iii) heterochromatin only (Fig.
6C
and Table
1). The only chimera that localizes
exclusively to
euchromatin is the CaHSc protein, which contains the
HP1a amino
chromo domain and the HP1c hinge and chromo shadow domain
(Fig.
7A). This result suggests that if
HP1c directly targets euchromatin,
it does so via the hinge or chromo
shadow domain. This result
also indicates that the amino chromo
domain of HP1a is not involved
in heterochromatin targeting,
implicating the chromo shadow domain
alone in heterochromatin
localization of the Ca-Sa protein (Fig.
6B).
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FIG. 7.
Chimeric HP1 proteins exhibit distinct localization
patterns. Cells were transfected with plasmids that code for
various chimeric HP1 sequences described in Fig. 6C. Following
expression, cells were fixed and processed for indirect
immunofluorescence using the antibodies indicated. Euchromatin only
(A), both euchromatin and heterochromatin (B), and heterochromatin only
(C) localization patterns for chimeric proteins were observed. Bar = 5 µm.
|
|
Both the CHaSc and the CcHaSc proteins localize to both euchromatin and
heterochromatin (Fig.
7B). We also note a slight increase
in staining
of these two chimeras over heterochromatin in most
cells. While the
origin of the amino chromo domain differs between
these proteins, the
HP1a hinge is common to both and is the only
segment of HP1a in the
CcHaSc protein. CcHaSc is also identical
to the
euchromatin-specific CHSc protein except that the hinge
has been
switched to that of HP1a. This result confirms that the
HP1a hinge
targets heterochromatin, independently of other HP1
modules, and
further suggests that either the amino chromo domain
or the chromo
shadow domain of HP1c can target
euchromatin.
The chimeric proteins CaHcSa, CcHSa, and CHcSa all localize exclusively
to heterochromatin (Fig.
7C). CaHcSa is identical
to full-length HP1a
except that the hinge has been replaced with
the comparably shorter
hinge from HP1c. Unlike the HP1a hinge,
the short HP1c hinge does not
target its native chromatin environment.
Both the CcHSa and CHcSa
proteins contain the HP1c amino chromo
domain and the HP1a chromo
shadow domain, differing only by the
hinge sequences they carry. The
HP1c amino chromo domain in both
proteins fails to target these
chimeras to euchromatin. We find
that only HP1c chromo shadow-bearing
chimeras localize to euchromatin
(Table
1), indicating that euchromatin
targeting activity of
HP1c is attributable to the chromo shadow domain
alone. Moreover,
the HP1a hinge imparts partial heterochromatin
targeting to HP1c
shadow-bearing chimeras, demonstrating that the hinge
and chromo
shadow domain of HP1a independently target
heterochromatin.
Sequence differences between HP1c and other HP1 homologs.
Given the results obtained in our expression studies, we examined
conserved sequences within HP1 homologs that may help explain the
intrinsic localization properties of the hinge and chromo shadow
domains of Drosophila HP1-like proteins. Three-dimensional structural analyses reveal residues that may be responsible for stability and self-dimerization of chromo shadow domains (6, 8). We aligned the chromo shadow domains from HP1 homologs. A
portion of the alignment highlights differences and similarities between two fly HP1a sequences, D. melanogaster HP1b and
HP1c, and mammalian HP1 homologs (Fig.
8A). Residues that are critical for
three-dimensional structure formation and residues that participate directly in chromo shadow self-dimerization are 100% identical when
sequence from HP1b is compared with those from HP1a and mammalian proteins. In contrast, the same positions of HP1c are only 42% identical to the same HP1 homologs.
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FIG. 8.
Similarities and differences among HP1 homologs.
Primary amino acid sequences from HP1 homologs were examined using
Block Maker to delineate regions of conserved sequence. Segments from
selected homologs are represented, with amino acid positions indicated
to the right of all alignments. A block of sequences corresponding to
the chromo shadow domain is shown with amino acid positions critical
for three-dimensional architecture shaded in blue and residues involved
in self-dimerization shaded in green (A). A separate alignment
represents a conserved 25-amino-acid block of sequence that conforms to
the hinge in HP1 proteins (B). An invariant sequence within the block
is shaded and a region that conforms to a bipartite NLS is indicated by
brackets. The HP1 homolog Swi6 was aligned to the hinge block
separately due to low similarity scoring. Conservation within the
alignment is shown as a sequence logo, where color is used to
discriminate amino acids based on the chemistry of side chains (i.e.,
blue = basic and red = acidic) and letter size denotes a
residue's relative conservation among homologs. An alignment of
complete hinge sequences from selected HP1 homologs is shown with a
shaded region highlighting the conserved 25-amino-acid block similar to
other HP1 homologs (C). For full genus names, see Fig. 1.
|
|
Comparison of HP1 homologs also reveals a conserved block of 25 amino
acids contained within the hinge (Fig.
8B). Several
features of the
conserved block are readily apparent when the
block is displayed as a
sequence logo. First, unlike chromo domains
(
5), the hinge
sequence is largely hydrophilic, lacking hydrophobic
core residues that
could contribute to a globular tertiary structure.
This hydrophilic
segment of the hinge may be available to interact
with other cellular
components. Second, the hinge sequence KRK
is invariant among these HP1
proteins, suggesting a conserved
function for this portion of the hinge
sequence. Third, searches
of Prosite patterns reveals a bipartite NLS
contained within the
block that overlaps with the conserved KRK
sequence (Fig.
8B).
The NLS consists of two basic amino acids (K or R),
followed by
a 10-residue spacer region and another three basic amino
acids
within the next five positions (Prosite accession no. PS00015)
(
9). We note that the spacer between the two parts of the
NLS
varies from 10 to 13 residues. There is precedence for this,
because
a bipartite NLS that has a 13-amino-acid spacer and also
carries
the sequence KRK at the N-terminal portion of the signal has
been
reported (
45). Furthermore, the spacer residues found
within
bipartite NLS sequences are largely acidic (
9), and
we note
this bias in the hinge block of HP1 proteins. The recent report
of a functional bipartite NLS sequence in Swi6 (
40)
prompted
us to align this segment of the Swi6 sequence with the
conserved
hinge block (lower sequence in Fig.
8B). We find that not
only
the bipartite nature of the NLS is conserved but the invariant
KRK
sequence is also present. This conservation of motifs strengthens
the
assertion that the hinge includes a bipartite NLS (
40).
HP1b contains hinge sequence that overlaps completely with the
conserved hinge block, conforming to much of the sequence conservation
with the notable exception of the position of the KRK sequence
(Fig.
8C). Interestingly, another KRK sequence is present at the
other end of
the bipartite NLS in HP1b. The HP1b hinge, as noted
earlier, is
considerably shorter than that of HP1a (63 and 37
residues,
respectively). However, other heterochromatin-specific
HP1 proteins
have hinges shorter than that of
Drosophila HP1a
that are
closer in size to HP1b (i.e., 36 residues in HP1
), suggesting
that
some reduction in length is
tolerable.
| |
DISCUSSION |
We have characterized two new HP1 homologs in
Drosophila and compared their localization properties to
those of previously characterized HP1 proteins. All three
Drosophila HP1 forms exhibit different localization
patterns. Unlike heterochromatin-specific HP1a, HP1b localizes to both
heterochromatin and euchromatin and HP1c localizes exclusively to
euchromatin. Truncation and domain swapping experiments show that both
the HP1a hinge and chromo shadow domain can separately target
heterochromatin, whereas the chromo shadow domain alone targets HP1c to euchromatin.
The hinge NLS.
We detected a bipartite NLS contained within a
conserved block of hinge sequence, common to most HP1 homologs. We also
found support for hinge NLS function in our expression data. Our
truncation studies with GFP cannot be used to discriminate which
segment of HP1a localizes to the nucleus, owing to the weak nuclear
targeting activity of GFP itself in Drosophila and other
species (31). However, two of our c-Myc-tagged HP1a
truncations contain the hinge sequence (Myc-CHa and Myc-HSa), and each
localizes to the nucleus efficiently. We conclude that the hinge
contains a conserved block of sequence for importing HP1a and other HP1
homologs to the nucleus. Interestingly, the hinge of HP1c is only 18 amino acids long and lacks most of a conserved block that is found in other HP1 hinge sequences. This suggests that nuclear localization of
HP1c is attributable to another domain, possibly the chromo shadow,
given that independent studies identify a separate NLS in the shadow of
HP1a (32) (see below).
Targeting features of the hinge and chromo shadow domain.
Truncated forms of HP1a that contain partial hinge sequences have been
shown to localize to the nucleus and heterochromatin (30,
32). One of these truncation mutants, HP1a(1-95), is enriched
in the chromocenter of polytene cell nuclei and contains the amino
chromo domain and the N-terminal third of the hinge fused to an
artificial NLS (30). The block of conserved hinge sequence
that we report here lies further downstream (residues 105 to 129) and
contains a predicted NLS sequence, explaining the prerequisite for an
artificial NLS fused to HP1a(1-95). Unlike HP1a(1-95), our truncation
and domain-swapped HP1 proteins contain sequences that precisely
separate amino chromo domains from hinge segments, allowing independent
delineation of their effects on targeting. We conclude that amino
chromo domains from either HP1a or HP1c have no detectable targeting activities.
Other studies of truncated HP1a proteins suggest that an HP1a NLS lies
within the chromo shadow domain and that the module
is sufficient for
heterochromatin targeting (
32). Our domain
swapping
experiments support and extend these findings regarding
the chromo
shadow domains as a targeting module. In particular,
we have shown that
the chromo shadow domain of HP1a targets heterochromatin,
independently
of the hinge, and that the HP1c shadow targets euchromatin.
These
observations indicate that targeting differences between
HP1a and HP1c
depend on separate interactions of HP1 chromo shadow
domains with
heterochromatin- and euchromatin-specific complexes
in
Drosophila. Alternatively, dimerization of shadow domains
between
ectopic and endogenous HP1a and HP1c proteins might account for
targeting.
Hinge characterization adds resolution to HP1 functional
models.
Properties of the hinge can help explain distinct
localization patterns observed among different HP1 homologs. Previous
reports offer compelling evidence that HP1, and specifically chromo
shadow domains, interact with other proteins (7, 10, 21).
However, the mechanism by which HP1 targets heterochromatin is unknown. In fact, many of the proteins reported to interact with HP1 are not
restricted to the heterochromatin compartment (10, 21). Moreover, HP1-associated proteins have been shown to interact with the
chromo shadow domains of more than one mammalian HP1 homolog (3,
23, 27, 34, 36, 43). Unlike the sequences of HP1a and HP1c, the
chromo shadow domains of HP1, HP1, and HP1 are nearly
identical. The three mammalian HP1 proteins localize to regions of
heterochromatin that are spatially distinct (25), making
it difficult to reconcile how their localization could be entirely
dependent on interactions with the shadow alone.
Shadow-specific interactions are not sufficient to account for other
HP1 functions. For example, HP1
protein levels are significantly
depleted in metastatic breast cancer cells (
22). Despite
the
presence of normal HP1
and HP1
protein levels, an increase in
HP1
expression alone eliminates their invasive and metastatic
properties. As mentioned above, the chromo shadow domains of HP1
,
HP1
, and HP1
are almost indistinguishable, suggesting that
interactions
with these modules alone would be redundant unless
features outside
of the shadow help determine function. Interestingly,
the hinge
sequences among all of these homologs differ in their length
and
composition and might therefore function to discriminate these
proteins
in vivo. In general, independent hinge targeting
may
help restrict chromo domain interactions with other nuclear
components,
even those that are not confined to HP1-restricted
compartments.
| |
ACKNOWLEDGMENTS |
We thank Bas van Steensel for affinity-purified anti-HP1 amino
chromo domain antibodies and advice on transient transfection. We also
thank Joel Eissenberg for HP1 cDNA, Judith O'Brien and Peter Kim for
assistance with plasmid preparations, Suso Platero for useful
discussions regarding previous HP1 chimeric gene studies, and Harmit
Malik for advice on sequence analyses.
J.F.S. was supported by a fellowship from the National Institutes of
Health (F32 GM19849).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Howard Hughes
Medical Institute, Division of Basic Sciences, Fred Hutchinson Cancer Research Center, Seattle, WA 98109-1024. Phone: (206) 667-4515. Fax:
(206) 667-5889. E-mail: steveh{at}muller.fhcrc.org.
| |
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Molecular and Cellular Biology, April 2001, p. 2555-2569, Vol. 21, No. 7
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.7.2555-2569.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
