From the Department of Genetics, § Center
of Molecular Medicine, ¶ Department of Neurology, Emory University
School of Medicine, Atlanta, Georgia 30322 and the
Geriatric
Research Educational and Clinical Center, Bedford Veterans
Administration Medical Center, Department of Neurology and Pathology,
Boston University School of Medicine, Boston, Massachusetts 02115
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ABSTRACT |
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Huntington's disease (HD) is caused by the expansion of a glutamine repeat in the protein huntingtin. The expanded glutamine repeat is thought to mediate a gain of function by causing huntingtin to abnormally interact with other proteins. We previously identified a rat huntingtin-associated protein (HAP1) that binds to huntingtin; HAP1 binds more tightly to huntingtin with an expanded glutamine repeat than to wild type huntingtin. Identification of the human homologue of HAP1 is necessary for investigation of the potential role of HAP1 in HD pathology. Here, we report the cloning of a human HAP1 homologue (hHAP) that shares 62% identity with rat HAP1 over its entire sequence and 82% amino acid identity in the putative huntingtin-binding region. The hHAP gene encodes a 4.1-kilobase transcript and a 75-kDa protein which are specifically expressed in human brain tissues. Its expression in Huntington's disease brains is reduced in parallel with a decreased expression of huntingtin. While two isoforms of rat HAP1 are expressed at similar levels in rat brain, only a single major form of hHAP is found in primate brains. In vitro binding, immunoprecipitation, and coexpression studies confirm the interaction of hHAP with huntingtin. The in vitro binding of hHAP to huntingtin is enhanced by lengthening the glutamine repeat. Despite similar binding properties of rat HAP1 and hHAP, differences in the sequences and expression of hHAP may contribute to a specific role for its interaction with huntingtin in humans.
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INTRODUCTION |
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Huntingtin is the protein product of the gene for Huntington's disease (HD).1 The N terminus of human huntingtin contains a glutamine stretch encoded by a CAG repeat (1). Expansion of the CAG/glutamine repeat (>37 units) causes HD (1) and the length of the CAG repeat is inversely correlated with the age of onset of HD (2-4).
Although the genetic basis of HD has been identified, its pathogenesis remains unclear. The widespread expression of huntingtin does not explain the selective neuropathology of HD, which is characterized by massive neuronal loss specifically in the basal ganglia (5-7). Since mice that lack huntingtin or express reduced levels of huntingtin display aberrant brain development and perinatal lethality (8), huntingtin is thought to be important for neurogenesis. However, loss of huntingtin activity is unlikely the cause of HD because heterozygous HD inactivation by translocation in man (9) or by targeted mutagenesis of the mouse HD gene (10, 11) does not cause any HD phenotype. A gain of function model for the disease is thus widely accepted. It has been proposed that the expanded glutamine repeat may induce an abnormal interaction between the mutant protein and other cellular proteins (12-14). Consistent with this idea, studies to date have shown that huntingtin interacts with several proteins including HAP1 (15), glyceraldehyde phosphate dehydrogenase (GAPDH) (16), an unidentified calmodulin-associated protein (17), and a protein homologous to the yeast cytoskeleton-associated protein Sla2p (HIP1) (18, 19). These huntingtin-associated proteins are likely involved in HD pathology because their interactions with huntingtin are affected by an expanded glutamine repeat.
HAP1 was first identified in rat brain and was found to bind to the N-terminal region of human huntingtin (15). It binds more tightly to mutant huntingtin than to normal huntingtin (15). Furthermore, rat HAP1 is specifically expressed in neurons (20), making it a good candidate to be involved in the neuropathology of HD. Recent studies also show that rat HAP1 associates with a number of intracellular organelles (20-22), moves with huntingtin in nerve fibers (23), and interacts with dynactin P150Glued (24, 25) which participates in dynein-mediated retrograde transport. It remains to be shown whether human brain also contains a HAP1 homologue with similar binding properties. Since mice with normal levels of mutant huntingtin do not display any abnormal phenotype (8), specific properties of the proteins which associate with human huntingtin may account for the HD phenotype that occurs in man. Therefore, it will be interesting to identify human proteins that associate with huntingtin.
In this study, we isolated a human HAP1 homologue (hHAP) by molecular cloning. hHAP shares 62% amino acid identity with rat HAP1-A. Although its binding to huntingtin is comparable to that of rat HAP1, hHAP only has a single major form expressed in primate brains, in contrast to two isoforms of HAP1 in rat brain. The different sequences and expression of hHAP could contribute to a specific role in the interaction of hHAP and huntingtin in human brain. Identification of the human HAP1 homologue will facilitate the study of the relevance of the interaction between HAP1 and huntingtin in the pathology of HD.
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EXPERIMENTAL PROCEDURES |
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cDNA Cloning-- PCR products (previously named hHAP1 and hHLP1) that encode sequences with homology to rat HAP1 (15) were used as probes to screen human brain cDNA libraries made from human brain stem, striatum, and cerebral cortex (Stratagene). Sixteen clones were obtained from screening 10 million recombinants with these probes using high stringency hybridization (50% formamide, 5 × SSC, 5 × Denhardt's, 25 mM sodium phosphate, 0.1% sodium pyrophosphate, 100 µg/ml yeast tRNA, and 1% SDS at 42 °C) and washing (0.2 × SSC at 55 °C). Sequencing revealed that they all contained partial sequences with about 80% amino acid identity to HAP1. We thus renamed them hHAP (human huntingtin-associated protein). To obtain the full-length hHAP cDNA, we used 5'-RACE with an antisense primer (5'-ttcctcttctgcctcctttt-3') that corresponds to rat HAP1's amino acids from 243 to 249. The sense primer was a 5'-RACE anchor primer (5'-ggccacgcgtcgactagtacgggngggngggng-3') from the RACE kit (Life Technologies, Inc.). First strand cDNA was generated from RNA of human caudate tissue (CLONTECH). PCR products were electrophoresed on a 1% agarose gel. PCR product of about 900 base pairs was observed and then isolated from the gel for subcloning and sequencing. The full-length cDNA was then assembled by ligation of this PCR product with a cDNA clone that contains the rest of the coding region of hHAP using a DraIII site. A cDNA with a full coding region of hHAP was subcloned into the expression vector pCIS (15) for sequencing and expression in human kidney embryonic 293 (HEK 293) cells.
Northern Blot Analysis--
Nitrocellulose membranes containing
poly(A)+ RNAs of human brain and peripheral tissues were
obtained from CLONTECH. A
[32P]dCTP-labeled hHAP cDNA fragment (1057-1440
nucleotides) that encodes the putative huntingtin-binding region was
used as a probe. The GAPDH cDNA probe was obtained from
CLONTECH. The blots were hybridized in 50%
formamide and 5 × SSC hybridization buffer at 42 °C and washed
with 0.1 × SSC at 65 °C. The blots were then exposed to x-ray
film for 2 days at 70 °C.
Antibody Production--
A hHAP fragment (amino acids 323-455)
was fused in-frame to the GST fusion protein vector pGEX4T (Pharmacia
Biotech) to produce GST-hHAP fusion proteins in bacteria BL21. GST-hHAP
fusion proteins were purified with glutathione-agarose beads (Sigma).
The purified GST-hHAP protein served as immunogen for Covance Inc.
(Denver, PA) to produce rabbit antisera. The antibody (EM39) was
purified by incubating whole serum with a nitrocellulose strip
containing GST-hHAP overnight. After multiple washes of the strip with
10 mM Tris-HCl, pH 7.5, antibodies were eluted with 0.2 M glycine, pH 2.1, for 5 min and immediately neutralized by
adding 0.1 volume of 2 M Tris-Cl, pH 8.8. The eluted
antibody was then dialyzed in PBS overnight. A truncated human
huntingtin cDNA that encodes the first 256 amino acids with 2 glutamine repeats was obtained by RT-PCR. This cDNA was inserted
into the pGEX vector to generate GST fusion protein. The antibody
(EM48) to this GST-huntingtin fusion protein was also produced and
purified using the same methods. The purified antibodies were used at
1:1000 dilution for Western blotting. The following antibodies were
also used in the study: antibodies to human huntingtin (amino acids
549-679) that are either rabbit polyclonal antibodies or rat
monoclonal antibodies described previously (26), an anti-HA epitope
antibody 12CA5 (1:100-500 dilution, Boehringer Mannheim), a mouse
monoclonal antibody to GAPDH (1:300 dilution, Chemicon), rabbit
anti-cathepsin D antibody (Calbiochem), mouse anti-LAMP-1 and LAMP-2
(lysosomal membrane glycoprotein) antibodies (Developmental Studies
Hybridoma Bank), rabbit antibody to Rab2 (Santa Cruz Biotechnology),
mouse antibody to -COP, and rabbit antibodies to M6-P-R or
PDI
antibodies (provided by Dr. Richard Kahn at Emory University).
Western Blot Analysis-- Frozen specimens of the striatum and frontal cortex from postmortem human tissues were used for Western blots. Two HD cases, A96-14 and A94-36, and two normal human brains were used. Molecular genetic studies have indicated that A96-14 and A94-36 had 44 and 48 CAG repeats, respectively. Monkey tissues were obtained from Yerkes Regional Primate Research Center at Emory University. Brain and peripheral tissues were homogenized in PBS buffer containing protease inhibitors (1 µg/ml pepstatin A, 1 µg/ml aprotinin, 1 mM phenylmethylsulfonyl fluoride, and 1 µg/ml leupeptin). Protein samples (100 µg) were denatured in SDS sample buffer at 100 °C for 5 min before loading onto a 7.5% acrylamide SDS gel. Western blot analysis was conducted using the purified anti-hHAP antibody (EM39, 1:1000 dilution) and the rabbit anti-huntingtin antibody (26). Control used the antibody preadsorbed with purified GST-HAP1 fusion protein or GST alone (20 µg/ml) overnight.
Yeast Two-hybrid Binding--
The N-terminal region of
huntingtin (amino acids 1-230) plus 23 (23Q) or 44 (44Q) glutamines
was fused in-frame to the GAL-4 DNA-binding domain in pPC97 vector
(27). The middle portion of hHAP (amino acids 323-416) was fused
in-frame to the GAL-4 activation domain of pPC86 vector. These plasmid
constructs were transformed into the yeast strain Y190. Colonies of
transformants were grown 48-72 h in Trp,
Leu
, and His
synthetic medium containing 50 mM 3-amino-1,2,4-triazole to ensure that cells contained
both pPC97 and pPC86 constructs. Liquid assays of
-galactosidase
activity were performed to assess protein-protein interactions (15,
24). Rat HAP1 (amino acids 278-370) fused to the pPC86 vector and
DRPLA (amino acids 450-712) fused to the pPC97 vector were used as
controls. DRPLA, the gene for dentatorubral and pallidoluysian atrophy
(28, 29), is an unrelated gene containing a 21 CAG/glutamine repeat;
the fragment used in this study was isolated previously (30). To detect
the expression of huntingtin in yeast, we conducted Western blot
analysis using the same yeast culture for liquid assay and the antibody
EM48 to N-terminal huntingtin.
In Vitro Binding-- Purified GST-hHAP was used for binding to the in vitro synthesized huntingtin or native huntingtin in HEK 293 cells. N-terminal huntingtin constructs containing 23 (23Q), 44 (44Q), or 73 (73Q) CAG repeats were used to synthesize [35S]methionine-labeled proteins with an in vitro TNT translation kit (Promega). The constructs with 23 or 44 CAG repeats were obtained previously (15). The construct with 73 CAG repeats was the result of repeat length instability during propagation of a phage clone containing exon 1 of the HD gene with 150 CAG repeats (provided by Dr. Gillian Bates (31)). Lysates containing radiolabeled huntingtin were incubated with 300 ng of GST-hHAP fusion protein or GST protein. After incubation for 1 h at 4 °C, the beads were washed with the lysis buffer (0.4% Triton in PBS and protease inhibitors: 100 µg/ml phenylmethylsulfonyl fluoride, 1 µg/ml leupeptin, 1 µg/ml aprotinin, 1 µg/ml pepstatin A) three times. Proteins bound to the washed beads were then eluted with SDS sample buffer, resolved by SDS-PAGE, and visualized by autoradiography. The beads containing GST-hHAP (300 ng) were also incubated with 1 ml of cell lysates of HEK 293 cells from a 10-cm culture dish for binding to native huntingtin. Huntingtin bound to the beads was detected by Western blotting with anti-huntingtin antibody (26).
Immunoprecipitation-- Immunoprecipitation was conducted using monkey brain tissues that were obtained from Yerkes Primate Center at Emory University. Fresh monkey tissues (1 g/2 ml) were homogenized in PBS buffer containing 0.4% Triton X-100 and protease inhibitors. Homogenates were centrifuged at 18,000 × g for 15 min at 4 °C. The supernatant was then centrifuged again at 120,000 × g for 30 min at 4 °C. The clarified supernatant (600 µl) was preincubated with protein A-Sepharose beads (50 µl of 1:1 slurry, Pharmacia) for 30 min at 4 °C. The beads were pelleted and the supernatant was then incubated with 50 µl of protein A-Sepharose beads linked with 5 µl of affinity purified anti-hHAP antibodies or rabbit anti-huntingtin antibody (26) for 1 h at 4 °C. Controls were immunoprecipitations with protein A-Sepharose beads alone or beads linked with an anti-rat HAP1 antibody that does not cross-react with hHAP on Western blot. The beads containing immunocomplexes were precipitated and washed twice with 1 ml of PBS containing 0.4% Triton X-100. The precipitated proteins were resuspended in 100 µl of SDS sample buffer and boiled for 5 min. The samples (50 µl) were resolved by SDS-PAGE and detected by Western blotting.
Coexpression and Double Labeling of Transfected Cells-- To assemble a full-length huntingtin construct, we ligated a partial cDNA containing 44 CAG repeats (15) with cDNAs encoding the middle and C-terminal regions of huntingtin. These cDNAs were isolated from screening human brain cDNA libraries and RT-PCR using primers derived from published sequences (1). The full-length cDNA of huntingtin was inserted into the pEBVHis vector (Invitrogen) for transfection of cells. Cells were transfected using LipofectAMINE (Life Technologies, Inc.) for 16-72 h, fixed in PBS containing 4% (w/v) paraformaldehyde for 15 min, permeabilized in 0.4% Triton X-100 in PBS, and preincubated with PBS containing 5% normal goat serum and 0.2% Triton X-100 for 1 h. Primary antibodies were added to these treated cells for incubation overnight. After washing the cells, secondary antibody conjugated with either fluorescent fluorescein isothiocyanate or rhodamine (Jackson Immunoresearch) was added to the cells for 1 h at room temperature. The subcellular localization of expressed proteins was examined using fluorescence microscopy. The expressed huntingtin was detected by rat monoclonal antibody to huntingtin (1:100 dilution) (26). The transfected hHAP was detected by the rabbit antibody EM39 (1:500 dilution). For labeling the expressed DRPLA (amino acids 450-712) in HEK 293 cells, DRPLA was tagged with a HA (human influenza hemagglutinin YPYDVPDYA) epitope on its C terminus so it could be detected by mouse antibody 12CA5.
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RESULTS |
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Cloning of hHAP cDNA-- We previously identified two human PCR products (hHAP1 and hHLP1) that encode amino acid sequences with 96 and 80% identity to rat HAP1, respectively (15). Although genomic Southern blot analysis suggests the existence of distinct human genes for these two PCR products, Northern blot analysis and screening of cDNA libraries only identified the expression of hHLP1 (data not shown). Whether the previously isolated hHAP1 cDNA is expressed at a very low level or is the result of PCR artifact remains to be studied. In this study we have obtained 16 hHLP1 clones which we have analyzed by enzymatic digestion and sequencing. All 16 clones contain a region encoding 93 amino acids (amino acids 323-416) which has 82% identity to the huntingtin-binding region of rat HAP1. We renamed these cDNA clones hHAP (human huntingtin-associated protein) based on their homology to rat HAP1, their expression on Northern blots (see below), and their binding to huntingtin. When compared with the rat HAP1 sequence, 12 of the 16 clones have one or more insertion or deletion after the 93 amino acids. The insertion or deletion introduces sequences without any homology to rat HAP1 or shifts the reading frame and gives rise to premature stop codons. These divergent sequences may be the result of alternative splicing or incomplete splicing of introns.
All 16 clones lacked sequences homologous to the N-terminal region of rat HAP1. We thus used 5'-RACE PCR to identify the sequences encoding the N terminus of hHAP. By RACE-PCR we cloned a 5' end which is similar to rat HAP1 and contains a likely initiating methionine (Fig. 1). By splicing together a 5' end fragment obtained from RACE and a cDNA clone containing the rest of the coding region, we assembled a full-length cDNA sequence. This sequence contains an open reading frame with 619 amino acids having 62% identity to rat HAP1 (Fig. 1b) and a predicted molecular mass of 68.8 kDa. Like rat HAP1, hHAP also has a region rich in acidic amino acids (Fig. 1). Some gaps and insertions also exist in hHAP's sequences when the sequences of hHAP and rat HAP1 are aligned. Rat HAP1 is expressed as two alternatively spliced isoforms, HAP1-A and HAP1-B, which differ at their C termini (15). The C-terminal sequence of hHAP is highly homologous to that of rat HAP1-A. We have not identified any human cDNA encoding the amino acid sequences homologous to the C terminus of rat HAP1-B during cDNA library screening and RT-PCR.
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Expression of hHAP mRNA-- Northern blot analysis shows a prominent transcript of approximately 4.1 kb in human brain (Fig. 2). Its size is equivalent to that of rat HAP1 (15) and its expression is also restricted to brain tissues, suggesting that it encodes a brain-enriched protein (Fig. 2). The hHAP transcript is most abundant in subthalamic nucleus and is also enriched in amygdala, thalamus, and substantia nigra. An intermediate level of this transcript was found in caudate nucleus and hippocampus. A lower level of hHAP transcript was found in corpus callosum. Several other minor bands were also found in human brain regions, including two upper bands (between 4.4 and 7.5 kb) that were visible in the subthalamic nucleus and a lower band of 3 kb that was present in all brain regions examined. These minor bands were also seen in human heart and skeletal muscle (Fig. 2). These minor bands could represent transcript variants, homologues of hHAP, or cross-hybridization to unrelated transcripts. The same blots were probed with GAPDH cDNA probe. Considering the amounts of RNA used for the blots and the ratio of the expression level of hHAP to that of GAPDH, hHAP mRNA appears to be expressed at a level similar to that of rat HAP1 mRNA (15).
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Expression of hHAP Protein-- To examine the protein expression of hHAP, we developed a rabbit antibody against GST-hHAP that contains the middle portion of hHAP (amino acids 323-455). We then examined the immunoreactivity of the purified antibody in transfected cells and brain tissues. Transfected proteins were produced by transfection of HEK 293 cells with hHAP, rat HAP1-A, or HAP1-B cDNA and brain regional tissues were obtained from monkey and human brains. Western blotting demonstrated that the antibody reacted with the transfected hHAP (75 kDa) in HEK 293 cells (Fig. 3a). The antibody also recognized transfected rat HAP1-A (75 kDa) and HAP1-B (85 kDa). In addition, the antibody cross-reacted with the doublet (75 and 85 kDa) in rat brain that corresponds to rat HAP1-A and HAP1-B. More important, the antibody recognized a single major band (75 kDa) in monkey brain. This brain protein and transfected hHAP have an equivalent molecular weight, suggesting that our cloned hHAP encodes the same hHAP seen in brain (Fig. 3a). Both transfected and native hHAP migrate a little slowly in SDS gels, appearing as a 75-kDa protein rather than the predicted 68.8-kDa protein. Similarly, rat HAP1-A is observed as a band at 75 kDa instead of 66.6 kDa as predicted by its amino acid sequences. hHAP and rat HAP1 may share the same structural properties that slow their migration in SDS gels. A weak immunoreactive product of 68 kDa in monkey brain was sometimes seen and this could be an isoform or a homologue of hHAP. Preabsorption of the antibody with GST-HAP1 fusion protein could eliminate these immunoreactive bands whereas preabsorption with GST alone did not (data not shown).
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Expression of hHAP in HD Brain-- Since the most affected areas in HD brain are the striatum and deep layers of the cerebral cortex (5-7), we analyzed the expression of hHAP in these two regions using Western blot analysis. Postmortem brain tissues obtained from two normal individuals and two adult HD patients were used. These two HD patients, HD-14 and HD-36, carried 44 and 48 CAG repeats of the huntingtin gene, respectively. We observed that the expression of huntingtin in HD-14 was significantly decreased in the striatum compared with that of the cerebral cortex (Fig. 4). This observation suggests that more neuronal loss had occurred in the striatum than in the cortex in HD-14. In HD-36, huntingtin was not detected in either the cortex or the striatum, indicating that these two brain regions had undergone severe neuronal degeneration. Similarly, the expression of hHAP was more remarkably reduced in the caudate than in the cortex in HD-14. It was also undetectable in both the cortex and the caudate in HD-36. In contrast, the expression of GAPDH was not significantly altered in HD brains compared with those in the control human brain (Fig. 4). In addition, the 98-kDa protein that reacted with anti-hHAP antibody was not significantly altered in the HD brains either (Fig. 4). Hence, the reduced expression of huntingtin and hHAP is unlikely to be the result of gross protein degradation in the postmortem tissues. These results suggest that both huntingtin and hHAP are expressed in neurons that are vulnerable in HD.
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Interaction of hHAP with N-terminal Huntingtin--
Because rat
HAP1 binds to the N terminus of huntingtin, N-terminal huntingtin
constructs containing the first 230 amino acids plus a normal repeat
(23 glutamines) or expanded repeats (44 or 73 glutamines) were used to
test the interaction of hHAP and huntingtin. The protein interactions
were examined using two different approaches: the yeast two-hybrid
system and in vitro binding assays. A previous study using a
PCR product that encodes hHAP amino acids 255-579 failed to show any
interaction between hHAP and huntingtin in yeast (15). As we found that
the middle region of rat HAP1 (amino acids 278-370) is a putative
binding region that is sufficient to bind to huntingtin in yeast (24),
we tested the binding of huntingtin to a shorter hHAP fragment (amino
acids 323-416) that shows 82% amino acid identity with the putative
binding region of rat HAP1. The yeast Y190 was co-transformed with this
hHAP construct and huntingtin containing 23 or 44 glutamine repeats. Western blot analysis of yeast lysates showed that huntingtin 23Q and
44Q were expressed at equivalent levels (Fig.
5a). To quantitatively assay
the protein interactions, we measured -galactosidase activity using
a liquid assay. We also included rat HAP1 as a positive control and
DRPLA as a negative control (15, 24). We observed that the interaction
of hHAP or rHAP1 with huntingtin 44Q yielded more
-galactosidase
activity (127.3 or 151 units/min/mg of protein) than with huntingtin
23Q (64.1 or 77.5 units/min/mg of protein) (Fig. 5b).
Examination of the interaction of hHAP with DRPLA or GAL-4-binding
domain vector showed only minor background levels (4.5-6.5
units/min/mg of protein). The ability of the shorter but not the longer
hHAP to interact with huntingtin suggests that these two polypeptides
may have different post-translational modifications or conformations
which affect their interactions with huntingtin in yeast. As huntingtin
44Q yielded more interaction with hHAP, the result also suggests that
the interaction of hHAP with huntingtin was increased by an expanded
glutamine repeat.
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Interaction of hHAP with Full-length Huntingtin-- To test the binding of hHAP to full-length huntingtin, we conducted an in vitro binding assay using HEK 293 cells that express native human huntingtin. The in vitro binding assay showed that GST-hHAP but not GST bound to native huntingtin (350 kDa) in HEK 293 cells (Fig. 6a).
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Co-localization of hHAP and Huntingtin in Transfected Cells-- Rat HAP1-A was found to co-localize with huntingtin in transfected cells (24). Thus, we co-transfected hHAP and huntingtin into HEK 293 cells and imaged the localization of hHAP and huntingtin in the transfected cells. We found that transfection of hHAP into HEK 293 cells resulted in perinuclear inclusions in many transfected cells. The inclusions were intensely labeled by anti-hHAP antibody (Fig. 7). hHAP immunoreactive inclusions vary in their size (Fig. 7a). We examined the cells that had been transfected for 16, 24, or 72 h. Although cells transfected for longer times usually have larger inclusions, not every cell overexpressing hHAP has the inclusion (Fig. 7b).
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DISCUSSION |
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Several lines of evidence in the present study demonstrate that hHAP is a human counterpart of rat HAP1. First, the sequence of hHAP shows a high degree of homology to that of rat HAP1. Second, like rat HAP1 (15, 20), primate HAP1 is enriched in monkey and human brains. In addition, hHAP appears to be expressed with huntingtin in the neurons that are vulnerable in HD. Third, in vitro binding, immunoprecipitation, and coexpression studies consistently show that hHAP specifically interacts with huntingtin, and its in vitro binding seems to be enhanced by an expanded glutamine repeat. Rat HAP1 has been also found to bind more tightly to huntingtin (15, 24). The similarity of hHAP and rat HAP1 in their sequences and binding to huntingtin suggests that hHAP and rat HAP1 bind to huntingtin in the same manner.
There are also differences between hHAP and rat HAP1. The amino acid sequences of hHAP display a number of insertions or deletions when compared with the sequences of rat HAP1. Unlike huntingtin which is highly conserved between humans and rodents (91% amino acid identity), hHAP and rat HAP1 share 62% amino acid identity overall. However, amino acids in the huntingtin-binding regions of both proteins are well conserved (82% identity), suggesting that their binding properties are similar while other functional aspects may not be identical. In addition, unlike rat HAP1 which is expressed as two isoforms (HAP1-A and HAP1-B), hHAP only displays a single major form in primate brains. The expression pattern of hHAP in transfected cells is also different from that of rat HAP1-A. These differences may reflect unique properties of hHAP that could confer a specific role of the interaction of HAP1 and huntingtin in human brain.
Several hHAP cDNA variants were found during cDNA screening. Most of them have insertions or deletions after the putative huntingtin-binding region. This may explain why no one has succeeded in isolating hHAP using yeast two-hybrid screening. However, the hHAP amino acid sequence presented in Fig. 1 is likely to represent the major protein product of the hHAP gene. This is because the cDNA probe and the antibody to the middle region of cloned hHAP consistently detect a major band on Northern and Western blots, respectively. Also, the mass of transfected hHAP is the same as that of native hHAP on Western blots. Several other weak bands are also seen. These weak bands could represent alternatively spliced products or other homologues of hHAP. Whether other hHAP cDNA variants are also expressed remains to be studied using antibodies specifically to their encoding amino acids.
Identification of hHAP further suggests a potential role of HAP1 in the pathology of HD. First, the parallel reduction in the expression of huntingtin and hHAP in the HD brains suggests that both proteins are expressed in the same neurons that are vulnerable in HD. However, the expression of hHAP is not restricted to the brain regions that can be affected in HD. The selective neurodegeneration in HD may also be associated with heterogeneous expression of huntingtin in the striatum (32) and/or other specific neuronal factors. Second, like rat HAP1, hHAP binds to the N-terminal region of huntingtin in vitro. Proteins that bind to the N-terminal region of huntingtin are especially interesting because the N-terminal fragment of huntingtin (amino acids 1-67) with an additional 150 glutamines has been found to cause neurological disorders in transgenic mice (31, 33). We observed that the binding of the N-terminal huntingtin (amino acids 1-230) with the glutamine repeat (23Q, 44Q, or 73Q) to GST-hHAP is increased by lengthening the repeat. Although the increase is not dramatic in vitro, it could contribute to cumulative effects of huntingtin mutation or late onset of pathophysiology if it also occurs in vivo. The interaction of hHAP and huntingtin is also supported by their co-localization in hHAP immunoreactive inclusions in transfected cells. Their co-localization is specific because DRPLA, another glutamine repeat protein, does not co-localize with hHAP on these distinct structures. Rat HAP1 has been found to associate with similar cytoplasmic structures in the rat brain.2 Whether human brain also contains hHAP immunoreactive cytoplasmic inclusions remains to be studied.
Unique components or specific properties of human huntingtin complexes may account for the neuropathology of HD in man. This is suggested by recent findings that transgenic mice expressing mutant human huntingtin do not display the graded loss of neurons in brain (8, 31, 33) that is the hallmark of human HD disease (5-7). It is possible that expansion of the huntingtin glutamine repeat may alter specific properties of human huntingtin-associated proteins, such as hHAP, and this alteration could contribute to the neuropathology of HD in man. Identification of hHAP will promote the study of the potential role of the interaction of HAP1 and huntingtin in the pathology of HD. hHAP may also be involved in the normal function of human huntingtin. This is suggested by recent studies showing that rat HAP1 associates with dynactin P150Glued (24, 25) and a variety of intracellular organelles (20-22). It will be interesting to investigate whether hHAP and huntingtin play roles in intracellular organelle transport.
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ACKNOWLEDGEMENTS |
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We are grateful to Dr. Gillian Bates for
providing a phage DNA containing exon 1 of the human HD gene with
150 CAG repeats. We thank Dr. Richard Kahn for providing antibodies and
Dr. Dean Danner for comments on the manuscript.
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FOOTNOTES |
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* This work was supported by the Hereditary Disease Foundation, the Wills Foundation, and the United States Public Hearth Service Grant NS36232 (to X. J. L.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
** To whom all correspondence should be addressed: Dept. of Genetics, Emory University School of Medicine, 1462 Clifton Rd., N. E., Atlanta, GA 30322. Tel.: 404-727-3290; Fax: 404-727-3949; E-mail: xiaoli{at}genetics.emory.edu.
2 C. A. Gutekunst, S-H. Li, X-J. Li, and S. M. Hersch, unpublished observations.
1 The abbreviations used are: HD, Huntington's disease; HAP1, huntingtin-associated protein; hHAP, human huntingtin-associated protein; GST, glutathione S-transferase; DRPLA, dentatorubral and pallidoluysian atrophy; GAPDH, glyceraldehyde-3-phosphate dehydrogenase; PCR, polymerase chain reaction; RACE, rapid amplification of cDNA ends; PBS, phosphate-buffered saline; RT, reverse transcriptase; PAGE, polyacrylamide gel electrophoresis; kb, kilobase(s).
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REFERENCES |
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