Human T-lymphotropic Virus Type 1 p30 Interacts with REGγ and Modulates ATM (Ataxia Telangiectasia Mutated) to Promote Cell Survival*

Human T-lymphotropic virus type 1 (HTLV-1) is a causative agent of adult T cell leukemia/lymphoma and a variety of inflammatory disorders. HTLV-1 encodes a nuclear localizing protein, p30, that selectively alters viral and cellular gene expression, activates G2-M cell cycle checkpoints, and is essential for viral spread. Here, we used immunoprecipitation and affinity pulldown of ectopically expressed p30 coupled with mass spectrometry to identify cellular binding partners of p30. Our data indicate that p30 specifically binds to cellular ATM (ataxia telangiectasia mutated) and REGγ (a nuclear 20 S proteasome activator). Under conditions of genotoxic stress, p30 expression was associated with reduced levels of ATM and increased cell survival. Knockdown or overexpression of REGγ paralleled p30 expression, suggesting an unexpected enhancement of p30 expression in the presence of REGγ. Finally, size exclusion chromatography revealed the presence of p30 in a high molecular mass complex along with ATM and REGγ. On the basis of our findings, we propose that HTLV-1 p30 interacts with ATM and REGγ to increase viral spread by facilitating cell survival.

Human T-lymphotropic virus type 1 (HTLV-1) 2 is a complex deltaretrovirus and the first reported human retrovirus linked to malignancy (1,2). It is estimated that ϳ20 million people worldwide are infected with HTLV-1 (3). Approximately five percent of these infected individuals will develop one of a variety of immunopathologic or neoplastic conditions (reviewed in Ref. 4). Two well characterized pathological conditions associated with HTLV-1 infection are adult T cell leukemia/lymphoma, a highly aggressive T cell malignancy, and HTLV-1-associated myelopathy/tropical spastic paraparesis, an immune-mediated neurodegenerative condition (5,6). The prolonged latency between acquisition of infection and disease expression indicates a highly regulated host-virus relationship that promotes survival of HTLV-1-infected cell reservoirs.
HTLV-1 p30 is a nuclear and nucleolar localizing protein encoded by a doubly spliced mRNA from ORF II of the pX region of the viral genome (13,14) that modulates viral and cellular gene expression by transcriptional and post-translational mechanisms (14,15). HTLV-1-infected individuals produce cytotoxic T cells and antibodies to p30 peptides (16,17). We reported that p30 differentially modulates the activity of HTLV-1 promoter-driven reporter genes (18) through its interaction with the transcriptional coactivator p300 (19). In Jurkat T cells, p30 alters the expression of a variety of cellular genes and also enhances signal pathways important for T cell growth and survival (20). Ectopically expressed p30 leads to the retention of tax/rex mRNA in the nucleus (15,21). The switch between viral latency and replication has been postulated to occur by the interaction of p30 and Rex, with Rex rescuing p30-mediated nuclear retention of tax/rex mRNA to promote replication and p30 suppressing Rex expression to maintain latency (23). In addition, interaction of p30 with the Myc-Tip60 complex modifies Tip60-mediated transcription and may promote cellular transformation (24). Importantly, p30 is necessary for establishment and maintenance of HTLV-1 infection in rabbit and a non-human primate model (9,7,25) and causes the accumulation of cells in the G 2 -M phase of the cell cycle (27). Collectively, these studies support the role of p30 as a multifunctional protein with transcriptional and post-transcriptional activities that balance the influence of Tax to regulate viral gene expression and modulate host cell factors to promote survival of infected cells. Identification of host protein-p30 interactions and their influence on the host cell-virus relationship is essential to understand how this unique viral protein influences cell survival to promote HTLV-1 transmission and spread.
In this study, we have used immunoprecipitation, affinity pulldown, and mass spectrometry to demonstrate specific interaction of p30 with ATM (ataxia telangiectasia mutated) and REG␥. The functional significance of p30 and ATM interaction is reflected in modulation of the levels of ATM and increased cell survival after irradiation-induced genotoxic stress. Surprisingly, knockdown and overexpression experiments indicated that REG␥, which is typically known to target nuclear proteins to proteasomal degradation, is associated with enhanced p30 protein expression. Our data are the first to demonstrate p30 in high molecular mass fractions together with cellular ATM and REG␥, suggesting a functional significance through multiprotein complex formation. We propose that interaction of p30 with ATM and REG␥ modulates cellular pathways to promote survival of infected cells, thereby enhancing viral transmission and spread.
Reporter Gene p30 Functional Assay-The p30 functional assay was performed as described with slight modifications (28). Briefly, 0.1 g of HTLV-1 LTR-luciferase reporter was cotransfected with or without 0.1 g of a Tax expression plasmid in 293T cells, keeping the total DNA concentration constant. Increasing amounts (1.2 and 2.4 g) of S-p30-HA were cotransfected to analyze the repression activity. After 24 h, the luciferase activity was determined. The transfection efficiency was normalized using Renilla luciferase activity.
S-Tag Affinity Purification and Immunoprecipitation-Cell lysates were prepared with passive lysis buffer (Promega, Madison, WI) in the presence of protease inhibitor mixture (Roche Applied Science). S-Tag purification was performed by rocking cell lysates with S-beads (Novagen) overnight at 4°C. Immunoprecipitation was performed by rocking cell lysates overnight at 4°C with protein A-agarose beads (Pierce) that were equilibrated with specific antibodies for 45 min at room temperature. The S-beads or protein A-agarose beads were washed once with high salt (1 M NaCl)-containing radioimmunoprecipitation assay buffer (150 mM NaCl, 0.01 M sodium pyrophosphate, 10 mM EDTA, 10 mM sodium fluoride, 50 mM Tris, 0.1% SDS, 12.8 mM deoxycholic acid, 10% glycerol, and 1% Nonidet P-40 (pH 8.0)), three times with radioimmunoprecipitation assay buffer, and once with PBS. Samples evaluated for ATM binding were washed three times with 50 mM Tris (pH 7.4) and 150 mM NaCl prior to protein elution by boiling the beads in SDS loading buffer and immunoblotting.
Irradiation Experiments and Cell Survival Studies-293T cells transduced with lentivirus (pWPT-p30-HA-IRES-GFP) to stably express p30 or mock pWPT-IRES-GFP were exposed to 10-gray (Gy) ␥-irradiation. Cell lysates were prepared in the presence of phosphatase (Sigma) and protease (Roche Applied Science) inhibitor mixtures after 30, 60, and 120 min of recovery time prior to immunoblotting. To test cell survival in the presence of p30, 293T cells and Jurkat T cells transduced with lentivirus (pWPT-p30-HA-IRES-GFP) to stably express p30 or mock pWPT-IRES-GFP were exposed to 10-Gy irradiation. Cell survival was monitored using CellTiter 96 AQ ueous One solution reagent (Promega) according to the manufacturer's instructions.
Mass Spectrometry and Proteomics-For MALDI-TOF analysis, the protein band of interest was excised from SDS-PAGE, destained, dehydrated, and digested with 1 g of trypsin in 50 mM NH 4 HCO 3 at 25°C overnight. Small molecular mass peptides were analyzed by a MALDI-TOF AXIMA-CFR instrument (Shimadzu Scientific Instruments) using an ␣-cyano-4hydroxycinnamic acid as a matrix. Protein Prospector v5.6.1 was used to identify detected peptide peaks.

HTLV-1 p30 Promotes Cell Survival in the Presence of Genotoxic Stress-HTLV-1 infection is characterized by lympho-
cyte-mediated diseases, and the virus has well documented properties that promote the proliferation of infected cells through cell cycle alterations or cell signaling pathways (29,30). HTLV-1 p30 has been reported by our laboratory and others to modulate cell cycle parameters to favor cell survival or potentially contribute to cellular transformation (24,27). In this study, we tested the ability of p30 to promote cell survival following genotoxic stress. 293T cells and Jurkat T cells were transduced with lentivirus vectors to stably express p30 (pWPT-p30-HA-IRES-GFP) or mock pWPT-IRES-GFP vectors and then exposed to 10-Gy ␥-irradiation. Cell survival was monitored using a tetrazolium dye-based method. Cells expressing p30 exhibited significantly higher cell survival compared with mock-transduced cells (Fig. 1). This effect was more pronounced in Jurkat T cells (62% increase) compared with 293T cells (11% increase), reflecting the natural tropism of HTLV-1 for T cells. These data suggested a role for p30 in protecting HTLV-1-infected cells in circumstances associated with DNA damage, such as Tax expression (31).
ATM Levels Are Modulated in the Presence of p30 upon DNA Damage-Depending on the extent of DNA damage, cells exhibit a variety of physiological responses, including cell cycle checkpoint activation, DNA repair, and apoptosis. In these circumstances, evolutionarily conserved checkpoint kinases are rapidly induced to prevent replication or segregation of damaged DNA before repair is completed. Upon DNA damage, ATM is activated by autophosphorylation on Ser-1981 (pATM) to recruit and phosphorylate downstream DNA repair proteins (32). ATM also activates cell cycle checkpoints or apoptosis by Cell survival was tested in 293T and Jurkat T cells transduced with lentivirus vectors to stably express p30 or mock (GFP vector) prior to exposure to 10-Gy irradiation. Cell survival was monitored using CellTiter 96 AQ ueous One solution reagent according to the manufacturer's instructions. Data points represent the mean absorbance values of six independent trials plotted over time. Statistical differences were compared using analysis of variance. In 293T cells, statistically significant (asterisk) higher cell survival was noted in the presence of p30 compared with the control (GFP) at day 3 (p Յ 0.0004), at the time the cells reached confluence. In Jurkat T cells, statistically significant (asterisk) higher cell survival was observed in the presence of p30 compared with the control (GFP) at days 3, 4, and 5 (p Յ 0.0044, 0.0003, and 0.0185, respectively). FIGURE 2. p30 binds to ATM and modulates the levels of ATM after genotoxic stress. A, 293T cells were transduced with lentivirus vectors to stably express p30 or mock (GFP vector) prior to exposure to 10-Gy irradiation and were allowed to recover for different times as indicated. Cell lysates were prepared at defined time points and tested by immunoblotting for pATM, ATM, p30-HA, and ␥H2AX. Equal protein loading was confirmed by testing cell lysates for amounts of ␤-actin. Base amounts of each evaluated protein were visualized from cells not subjected to DNA damage (denoted by ø). Data represent a minimum of three independent trials. B, cell lysates from Jurkat T cells transduced with lentivirus vectors to stably express p30 or mock (GFP vector) prior to exposure to 10-Gy irradiation were immunoprecipitated (IP) using normal IgG (normal serum (NS)) or rabbit anti-HA antibodies and probed with mouse anti-ATM and anti-ATR monoclonal antibodies. The reverse immunoprecipitation was performed by immunoprecipitation of cell lysates of Jurkat T cells stably expressing p30-HA with normal IgG or rabbit anti-ATM antibody and probed with mouse anti-HA monoclonal antibody. Data represent a minimum of three independent trials for each immunoprecipitation assay. IP, immunoprecipitation. FIGURE 3. Expression, S-Tag affinity purification, and function of S-p30-HA. A, 293T cells were transfected with pME-p30-HA or pTriEx4-Neo-S-p30-HA expression plasmid. p30 was detected using mouse anti-HA monoclonal antibody after resolving cell lysates by 4 -20% gradient SDS-PAGE. B, the functional activity of p30 was determined by an HTLV-1 LTR-reporter gene assay as described (28). 293T cells were transfected with a luciferase reporter gene driven by an HTLV-1 LTR-Tax expression plasmid and increasing concentrations of S-p30-HA (1.2 and 2.4 g). The luciferase (Luc) activity was optimized for transfection efficiency using Renilla luciferase as an internal control. Luciferase activity data represent the means of three independent trials.
phosphorylating p53 at Ser-15 (33). To test the potential interaction of p30 with ATM, 293T cells transduced with lentivirus vectors to stably express p30 (pWPT-p30-HA-IRES-GFP) or mock pWPT-IRES-GFP vectors were subjected to DNA damage (10-Gy irradiation), and the levels of ATM and pATM were monitored ( Fig. 2A). Elevated levels of ␥H2AX, a marker of double-stranded DNA breaks, confirmed initiation of the DNA repair pathway. In the absence of p30, the levels of ATM remained constant, and pATM appeared by 30 min and peaked by 120 min. In the presence of p30, the phosphorylation of ATM peaked by 60 min to levels comparable with that at 120 min in the control. The maximum phosphorylation of ATM in cells expressing p30 was achieved at least 60 min earlier than in control cells. The levels of both ATM and pATM were reduced by 120 min after DNA damage, whereas no such decrease was observed in control cells. Coupled with the observation that p30 enhanced cell survival following genotoxic stress (Fig. 1), we hypothesized that p30 expression may modulate levels of pATM to prevent triggering apoptosis, promoting cell survival of viral infected cells (34,35). Our data suggest a role for p30 in modifying cellular response to DNA damage, influencing the amount of ATM available to induce apoptosis.
HTLV-1 p30 Interacts with ATM-To test if p30 modulation of ATM was due to interaction between the two proteins, immunoprecipitation experiments were performed. Cell lysates from p30-or mock vector-expressing Jurkat T cells were immunoprecipitated and probed for ATM. ATM and not ATR (ATM-and Rad3-related), another key kinase in the DNA FIGURE 4. Affinity pulldown of p30 and mass spectrometric analysis of interacting proteins. A, schematic of p30 purification using the S-Tag pulldown approach coupled with mass spectrometric analysis. 293T cell lysates were prepared 24 h after transfection with expression plasmids (S-p30-HA, mock, or S-GFP). Each cell lysate was incubated overnight with S-beads at 4°C. To minimize nonspecific protein binding, beads were washed prior to shotgun proteomics or SDS-PAGE separation. B, S-Tag affinity purification of p30 using S-beads resulted in enrichment of p30 as detected by immunoblotting. C, the proteins from the beads were denatured by boiling in SDS loading dye in the presence of ␤-mercaptoethanol. The proteins were separated by 14% SDS-PAGE and Coomassie Blue-stained. Lane 1 shows the molecular mass marker, and lane 2 shows the S-Tag affinity-purified p30. The S-p30-HA band indicated by the arrow was excised and subjected to mass spectrometric analysis. D, MALDI-TOF spectrum. The protein band migrating near the 31-kDa marker on SDS-PAGE (indicated by the arrow in C) was cut out and subjected to in-gel proteolysis with trypsin. The resulting peptides were analyzed by a MALDI-TOF AXIMA-CFR instrument. Multiple peptide peaks corresponding to p30 and REG␥ proteins have been identified and are indicated. The start and end amino acid positions of peptides are depicted in parentheses. The sequence coverage for p30 and REG␥ was 30 and 44%, respectively, enabling unequivocal identification of these proteins.
repair pathway, was immunoprecipitated using antibodies against HA (Fig. 2B, left panel), indicating that p30 interacts directly with ATM. The interaction between ATM and p30 was also demonstrated using a reverse immunoprecipitation assay in which p30 was immunoprecipitated with antibodies against ATM (Fig. 2B, right panel). Our data are the first to demonstrate a retroviral protein that specifically interacts with and modulates ATM.
REG␥ Co-purifies with HTLV-1 p30-To identify other cellular proteins that interact with p30 and could explain the ability of p30 to modulate ATM, we employed affinity pulldown coupled with mass spectrometry. For these experiments, p30 was expressed with an N-terminal S-Tag and a C-terminal HA tag (S-p30-HA) under the control of the CMV promoter from the pTriEx4-Neo expression plasmid. The expression of S-p30-HA was comparable with that of p30-HA expressed from the pME-p30-HA plasmid in 293T cells reported previously (Fig. 3A) (28). We reported that p30 represses Tax-driven HTLV-1 LTR transcription (28). The ability of S-p30-HA to repress Tax-driven HTLV-1 LTR transcription indicated that S-p30-HA functioned similarly to other forms of the protein (Fig. 3B). The S-Tag was utilized for affinity purification and the HA tag for immunoblot detection. Affinity pulldown of p30 from whole cell lysates was performed according to the protocol shown in Fig. 4A. Immunoblot analysis validated that p30 was enriched in the S-Tag pulldown fraction (Fig. 4B). A protein band corresponding to the molecular mass of p30 was readily detected by Coomassie Blue staining of the S-Tag pulldown fraction in an SDS gel (Fig. 4C). MALDI-TOF analysis of the protein band indicated that it contained two proteins: HTLV-1 p30 and cellular REG␥ (Fig. 4D).
To perform a more comprehensive analysis of cellular proteins interacting with p30, 293T cells transfected with S-p30-HA, pTriEx4-Neo (mock), and S-GFP (GFP with an S-Tag on the C terminus expressed from pTriEx4-Neo-S-GFP) were subjected to S-Tag affinity purification (Fig. 4A), followed by shotgun proteomics (LC/MS/MS) analysis of the pulled-down proteins. Quadruplicate experiments with S-p30-HA with two mock and two GFP-negative controls were performed. REG␥ consistently co-purified with p30 in four S-p30-HA experiments and was not detected in any of the negative controls. The proteins identified in both controls and p30-expressing samples were considered to be nonspecific bead-interacting proteins. Thus, both MALDI-TOF and LC/MS/MS data indicated that REG␥ selectively co-purified with p30. We could not detect ATM in these experiments, likely because ATM is less abundant than REG␥ in p30 pulled-down fractions or is contained in lower affinity protein complexes, with p30 requiring the more sensitive immunoblot analyses.
HTLV-1 p30 Specifically Interacts with REG␥-The REG (regulators) family of 20 S proteasome activators includes REG␣, REG␤, and REG␥. Despite the fact that REG␥ has ϳ25% amino acid similarity to REG␣ and REG␤, the latter proteins were not identified in our MALDI-TOF or LC/MS/MS analysis, indicating that p30 selectively interacts with REG␥. The 20 S proteasome is an inherently latent protease, and the binding of REG proteins activates and modifies protease activity by forming the REG-20 S proteasome complex (36,37). The protea-some complex is critical in controlling a variety of cellular processes such as cell cycle and transcriptional regulation through regulated proteolysis. REG␣ and REG␤ are cytoplasmic and are involved in antigen processing, whereas REG␥ is localized in the nucleus (38).
To further confirm the specificity of p30 and REG␥ interaction, S-Tag affinity-purified samples were immunoblotted for REG␥. 293T cells were transfected with mock, S-p30-HA, or S-GFP plasmids, and cell lysates were subjected to S-Tag affinity purification and immunoblotted with anti-REG␥ antibodies. REG␥ co-purified only with p30 and not with GFP or from mock-transfected cell lysates (Fig. 5A), indicating that p30 specifically interacts with REG␥. Both REG␣ and REG␤ did not co-purify with p30, indicating the specificity of the p30 interaction with REG␥ (Fig. 5A). To further confirm the specificity of p30 and REG␥ interaction, REG␥ was immunoprecipitated from 293T cells transfected with mock, S-p30-HA, or S-GFP. p30 was co-immunoprecipitated with REG␥, whereas GFP was not (Fig. 5B), indicating a specific interaction between p30 and REG␥. To demonstrate the interaction in physiologically relevant T cells, Jurkat T cells were transduced with a p30-HA-expressing lentivirus vector and tested for REG␥ binding. Antibodies against HA were able to specifically immunoprecipitate REG␥ but not REG␣ or REG␤, whereas nonspecific IgG was unable to immunoprecipitate any REG proteins (Fig. 5C). This also eliminated the possibility of the S-Tag influencing the interaction. Collectively, these data provide further evidence for a novel and specific interaction between HTLV-1 p30 and REG␥.  MARCH 4, 2011 • VOLUME 286 • NUMBER 9

HTLV-1 p30, REG␥, ATM, and Cell Survival
REG␥ was thought to be involved in the hydrolysis of small peptides (38). However, recent studies have demonstrated that REG␥ specifically interacts and directs full-length folded cellular proteins to proteasomal degradation (39). The significant feature of the REG␥-20 S proteasome complex is its ability to degrade proteins in an ATP-and ubiquitin-independent manner (40). The cellular proteins degraded via REG␥ interaction independent of ATP and ubiquitination include SRC-3 (steroid receptor coactivator-3) and p21 waf/cip1 (41,42). However, REG␥ also functions as a cofactor in ubiquitin-dependent MDM2-mediated degradation of p53 by facilitating the interaction between MDM2 and p53 (43). REG␥ is also involved in the pathogenesis of hepatitis C virus by influencing the turnover of the hepatitis C virus core protein (44,45). Similarly, the interaction of p30 with REG␥ could play an important role in turnover of p30 and thus contribute to the function of p30 in HTLV-1 infection.
REG␥ Enhances Detection of HTLV-1 p30-To investigate the influence of p30 and REG␥ interaction on the ability to detect p30, REG␥ was knocked down using siRNA in 293T cells stably expressing p30-HA. The levels of REG␥ and not REG␣ or REG␤ were decreased, indicating that the siRNA knockdown was specific (data not shown). Considering the role of REG␥ in 20 S proteasome activation, one would expect the levels of p30 to increase. For example, the amounts of hepatitis C virus core protein, SRC-3, and p21 waf/cip1 were shown to increase upon reduction of the levels of REG␥. In contrast, the levels of p30 decreased upon knocking down REG␥ (Fig. 6A), suggesting that the interaction with REG␥ stabilizes p30. To further confirm these results, REG␥ was overexpressed in 293T cells stably expressing p30-HA. Overexpression of REG␥ resulted in increased amounts of p30 (Fig. 6B), again suggesting that REG␥ stabilizes p30. Bioinformatic analysis suggests that p30 is a labile and unstable protein with a very high pI value of 11.7; thus, the interaction with REG␥ may be important for the stabilization and function of p30.
It is noteworthy that REG␥ is involved in the degradation of both p21 waf/cip1 and p53, which play critical roles in cell cycle regulation (46,47). In addition, REG␥ Ϫ/Ϫ mouse embryonic fibroblasts show slow growth and accumulation in the S phase and are more susceptible to apoptosis (48,49). The biological role of REG␥ in cell cycle regulation and cell survival is underlined by these observations. Our laboratory has reported previously that p30 causes an activation of the G 2 -M checkpoint (27). On the basis of the current data, we hypothesize that interaction of p30 with REG␥ could alter cell cycle regulation to benefit early viral spread or replication. Our data demonstrate for the first time that REG␥ stabilizes a key retroviral protein, p30, known to be important in early viral spread (7,9,25).
HTLV-1 p30 Is Associated with ATM and REG␥ in High Molecular Mass Multiprotein Complexes-REG␥ and ATM function as a heptamer (ϳ225 kDa) (50) and a dimer (ϳ600 kDa) (22), respectively. To investigate whether p30 associates with these high molecular mass species, we subjected lysates of 293T cells stably expressing p30-HA to size exclusion chromatography. No p30 band was detected in the fractions corresponding to monomeric p30. Instead, two distinct peaks of p30 were observed in higher molecular mass fractions. The first weaker peak was observed at ϳ1546 kDa, and the second strong peak was at ϳ330 kDa (Fig. 7). REG␥, which exists as a heptamer in cells, co-eluted with the second peak of p30 (Fig. 7).
The molecular mass of ATM is ϳ350 kDa, and it exists in a non-activated state as a dimer associated with DNA. Consistent with these properties of ATM, we detected ATM in FIGURE 6. HTLV-1 p30 appears to be stabilized by interaction with REG␥. A, SMARTpool siRNA-mediated knockdown of REG␥ in stably transduced 293T cells expressing p30-HA resulted in reduced levels of p30. siRNA against REG␥ and nonspecific control siRNA are indicated as ϩ and Ϫ, respectively. Immunoblotting for REG␣ and REG␤ indicates specific REG␥ knockdown. B, overexpression of REG␥ using the REG␥ expression plasmid in 293T cells stably expressing p30-HA resulted in increased amounts of p30 detected. In A and B (minimum of two independent trials), ␤-actin immunoblotting served as a loading control, and 293T cells stably expressing only GFP were used as a control. FIGURE 7. p30, REG␥, and ATM co-elute, consistent with a multiprotein complex. Cell lysate of 293T cells with no expression or with stable expression p30-HA was subjected to size exclusion chromatography (representative of two independent trials). Different fractions as indicated were subjected to immunoblotting and probed with anti-HA, anti-REG␥, and anti-ATM antibodies. The molecular mass fractions of the protein peak elution are indicated. The chromatograph of the protein standard with different molecular masses is shown and was used to plot the standard curve to derive molecular masses of relevant fractions.
two separate elution peaks. The first ATM peak was at ϳ1546 kDa and exhibited a high absorbance at 260 nm, indicating that this peak likely corresponds to DNA-associated ATM (Fig. 7). The DNA-associated ATM peak coincided with the first weaker peak of p30 (Fig. 7), indicating that a small portion of p30 is associated with ATM that is bound to DNA. The second peak of ATM at ϳ679 kDa corresponded to the dimeric form of the protein. This peak exhibited a broad shoulder overlapping with p30 and REG␥ peaks (Fig.  7), suggesting that these three proteins assemble into a multiprotein complex. The elution profiles of REG␥ and ATM did not change in the absence of p30 (Fig. 7).
The association of p30 together with REG␥ and ATM in a high molecular mass complex supports a possible mechanism for the reduced levels of ATM/pATM after DNA damage. These reduced levels ATM/pATM could help the cell to avoid apoptosis under DNA damage conditions and promote cell survival. The kinase activity of ATM is activated by acetylation of ATM by Tip60, a histone acetyltransferase (26), and it has been reported that p30 interacts with Tip60 (24). The other possible mechanism for reduced levels of pATM may be due to the ability of p30 to interfere with Tip60 to acetylate ATM, which is required for its autophosphorylation and activation.
In summary, we have reported the interaction of HTLV-1 p30 with two cellular host proteins, ATM and REG␥, which are involved in DNA damage repair and proteasomal degradation machinery, respectively. Both ATM and REG␥ are involved in cell survival in different ways, and the interaction of HTLV-1 p30 with these proteins could lead to enhanced survival of normal and DNA-damaged cells. Our size exclusion chromatography experiments suggest that these proteins assemble into multiprotein complexes. Our data indicate that p30 modulates the survival of infected cells through modulation of ATM and provide a plausible mechanism for how the retroviral protein facilitates early viral spread by enhancing cell survival during the critical phases of early mucosal transmission. Further studies are also needed to investigate the functional significance of these interactions to extend our understanding of DNA damage repair mechanisms in retroviral transmission and the biological role of REG␥ in cell survival.