COMMUNICATION
Human Homologs of Schizosaccharomyces pombe Rad1, Hus1, and Rad9 Form a DNA Damage-responsive Protein Complex*

Elias Volkmer and Larry M. KarnitzDagger

From the Division of Radiation Oncology and Department of Immunology, Mayo Foundation, Rochester, Minnesota 55905

    ABSTRACT
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Abstract
Introduction
Procedures
Results
Discussion
References

DNA damage activates cell cycle checkpoints in yeast and human cells. In the yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe checkpoint-deficient mutants have been characterized, and the corresponding genes have been cloned. Searches for human homologs of S. pombe rad1, rad9, and hus1 genes identified the potential human homologs hRad1, hRad9, and hHus1; however, little is known about the roles of these proteins in human cells. The present studies demonstrate that hRad1 and hHus1 associate in a complex that interacts with a highly modified form of hRad9, but hHus1 and hRad1 do not associate with hRad17. In addition to being a key participant in complex formation, hRad9 is phosphorylated in response to DNA damage. Together, these results suggest that hRad9, hRad1, and hHus1 are central components of a DNA damage-responsive protein complex in human cells.

    INTRODUCTION
Top
Abstract
Introduction
Procedures
Results
Discussion
References

DNA damage triggers a variety of cellular responses in eukaryotic cells, including the induction of a regulatory signaling network that activates checkpoint controls (1-3). Checkpoint activation transiently blocks cell cycle progression by arresting cells in G1 and G2/M and slowing progression through S phase. Genetic studies in the yeast Saccharomyces cerevisiae and Schizosaccharomyces pombe have identified many of the relevant players in DNA damage-induced checkpoint activation (4, 5). A common theme that emerges from these studies is that checkpoint-deficient yeast are dramatically more sensitive to genotoxins than their wild-type counterparts (1-3), suggesting that the checkpoint proteins play critical roles in cellular responses to DNA damage.

Recent studies suggest that key checkpoint regulators may be conserved between yeast and humans. Cloning of the human gene mutated in AT (ATM) revealed that the ATM gene exhibited significant homology with the S. pombe rad3 (sprad3) and S. cerevisiae MEC1 (scMEC1) checkpoint genes (6). The corresponding proteins scMec1, spRad3, and Atm are protein kinases that share large stretches of homology, including a phosphatidylinositol 3-kinase-related kinase (PIKK)1 domain. The PIKKs are also functionally conserved as mutation of scMEC1, sprad3, or ATM disrupts ionizing radiation (IR)-induced checkpoints and sensitizes the organisms to IR (7).

The PIKKs are integral players in a tentative DNA damage-inducible signaling pathway that interfaces with the cell cycle machinery (2, 3, 8). In this model, an unidentified sensor recognizes damaged DNA. Potential sensor candidates include the checkpoint proteins, spRad1, spRad9, spRad17, and spHus1. The sensor relays a signal to PIKK family members, which, at least in the case of ATM, are activated by IR (9, 10). In S. pombe, a PIKK-dependent pathway is required for DNA damage-induced activation of spChk1 (11), a protein kinase that phosphorylates Cdc25 and blocks its ability to activate Cdc2, thereby preventing cell cycle transition through the G2/M boundary.

The similarities between yeast and humans extend beyond these proteins, as human homologs of sprad1 (12-14), sprad9 (15), sprad17 (16), spchk1 (17), and sphus1 (18) genes have been identified, fueling speculation that the checkpoint pathways may be conserved. Despite these advances, the physical and functional roles of these proteins are largely unexplored, even in the well studied yeast systems. To gain insight into the functions of other human checkpoint proteins, we have undertaken a biochemical and cellular analysis of the novel human checkpoint proteins hRad1, hHus1, and hRad9. We show that hRad9 undergoes complex post-translational modifications in undamaged cells and is inducibly phosphorylated in response to DNA damage, suggesting that this protein participates in a DNA damage-inducible signaling pathway. We also demonstrate that fully modified hRad9 interacts selectively with hHus1 and hRad1 in a stable multimolecular complex that is present even in undamaged cells. Thus, these results demonstrate that hRad1, hRad9, and hHus1 form a stable radioresponsive checkpoint complex that actively participates in human cellular responses to DNA damage.

    EXPERIMENTAL PROCEDURES
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Abstract
Introduction
Procedures
Results
Discussion
References

Growth, Transfections, and Irradiation-- K562 cells were cultured in RPMI 1640 medium supplemented with 10% fetal calf serum and 2 mM L-glutamine. Cells were transiently transfected by electroporation using a 345-volt, 10-ms pulse delivered with a T 820 electoporator (BTX). All transfections used 40 µg of plasmid DNA, which included, if required, empty vector added to this amount. Cells were cultured for 16-24 h after transfection before use in experiments. Cells were irradiated at a dose rate of 11.4 Gy/min using a 137Cs gamma -irradiator.

Cloning and Epitope Tagging of hRad9, hHus1, and hRad1-- All PCR amplifications were performed with the Expand High Fidelity PCR System (Boehringer Mannheim). Cloned PCR products were sequenced, and plasmids without mutations were selected for use.

The hRad9, hHus1, and hRad1 cDNAs were amplified by PCR from a PCR-ready human testes cDNA library (CLONTECH). For hRad9, oligonucleotide primers were used that produced an amino-terminal in-frame fusion with a tandem AU1 epitope tag. The PCR fragment was cloned into pcDNA3 to yield pcDNA3-AU12-hRad9. hRad1 was amplified with PCR primers that appended an amino-terminal tandem FLAG epitope tag fused in-frame with hRad1. The resulting PCR fragment was cloned into pcDNA3 to yield pcDNA3-FLAG2-hRad1. The hHus1 expression vector was prepared by amplifying hHus1 using primers that added a tandem HA epitope tag to the carboxyl terminus of hHus1. The PCR-derived DNA fragment was cloned into pEF-BOS-Delta RI (19) to yield pEF-BOS-Delta RI-hHus1-HA2.

Antibodies-- Bacterial expression vectors for hexahistidine-tagged hRad1, hHus1, and hRad17 were generated by cloning PCR-amplified DNA fragments into pET24a+ (Novagen, Madison, WI). Histidine-tagged proteins were induced and purified according to manufacturer's instructions. The hRad9 cDNA was cloned into pGEX-KG (20) to generate an in-frame fusion with glutathione S-transferase. Bacterially produced GST-hRad9 was purified by affinity chromatography on glutathione agarose. The purified proteins were used to immunize rabbits with standard procedures. The anti-HA and anti-AU1 mAbs were from Babco (Berkeley, CA), and the anti-FLAG mAb was from Eastman Kodak Co.

Coimmunoprecipitation Experiments-- Exponentially growing K562 cells (1 × 107 per sample) were either transfected as indicated above or used directly for immunoprecipitation studies. Cells were washed in phosphate-buffered saline, and lysed in lysis buffer (50 mM HEPES, 1% Triton X-100, 10 mM NaF, 30 mM Na4P207, 150 mM NaCl, 1 mM EDTA, containing freshly added: 10 mM beta -glycerophosphate, 1 mM Na3VO4, 20 µg/ml pepstatin A, 10 µg/ml aprotinin, 20 µg/ml leupeptin, 40 µM microcystin-LR). The cell lysates were immunoprecipitated with the indicated mouse monoclonal antibodies and protein G-Sepharose (Sigma) or rabbit antisera and protein A-Sepharose (Sigma) for 1 h. The immunoprecipitates were washed three times with lysis buffer and fractionated by SDS-PAGE (10% gel). The gels were transferred to Immobilon-P (Millipore, Bedford, MA) and immunoblotted. All membranes were developed with SuperSignal chemiluminescent substrate (Pierce). Membranes that were sequentially blotted were stripped with two 30-min washes of 8 M guanidine hydrochloride prior to blocking and immunoblotting.

Mobility Shift Experiments and Phosphatase Treatment-- K562 cells (1 × 107 per assay point) were treated with the indicated stimuli, and hRad9 was immunoprecipitated. For the phosphatase experiments, immunoprecipitates were washed three times with lysis buffer and three times with 50 mM Tris, pH 8.5, 0.1 mM EDTA. Phosphatase-treated samples were incubated with 0.25 unit of calf intestinal alkaline phosphatase for 30 min at 30 °C, with or without 50 mM beta -glycerophosphate, following the manufacturer's directions (Life Technologies, Inc.). The immunoprecipitates were then washed once with lysis buffer, mixed with SDS-PAGE sample buffer, and fractionated by SDS-PAGE (10% gel).

    RESULTS
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Abstract
Introduction
Procedures
Results
Discussion
References

hRad1, hRad9, and hHus1 Associate in a Checkpoint Complex-- Comparisons of the predicted human and yeast protein sequences indicate that the human proteins are 25-30% identical and 53-57% similar to their respective homologs, with homologies extending over extensive portions of each protein (12-18). In S. pombe, spRad1 and spHus1 associate in wild-type, but not rad9, mutant yeast. One interpretation of this result is that spRad9 may physically link spRad1 to spHus1, although this hypothesis has not been validated experimentally (18). To address whether conservation extends to a functional level, we examined the ability of the human homologs to form biochemical complexes similar to those reported in yeast.

hHus1 immunoprecipitates (Fig. 1A, upper left panel) contained a 34-kDa protein, which is similar in size to hHus1's predicted mass of 32 kDa. The hHus1 immunoprecipitates also contained an anti-hRad1-reactive 33-kDa band (Fig. 1A, middle left panel), which comigrated with immunoprecipitated hRad1 (Fig. 1A, middle right panel), demonstrating that hRad1 associated with hHus1. Immunoblotting of the hHus1 immunoprecipitate with an anti-hRad9 antiserum revealed a 70-kDa band (Fig. 1A, bottom left panel) that comigrated with immunoprecipitated hRad9 (Fig. 1A, lower center panel). This was surprising, as hRad9 has a predicted molecular mass of 45 kDa, which is much smaller than the 70-kDa band we observed. However, as we show later, hRad9 undergoes extensive modification (see Figs. 2 and 3), which likely accounts for the discrepancy between the apparent and predicted molecular masses.


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Fig. 1.   hRad9, hHus1, and hRad1 associate in a stable complex. A, K562 cell lysates were immunoprecipitated with preimmune (PI) antisera, anti-hRad9, anti-hRad1, or anti-hHus1 rabbit antisera. Immunoprecipitates were immunoblotted with hRad9, hHus1, or hRad1. B, K562 cell lysates were immunoprecipitated with anti-hHus1 or anti-hRad17 (left panel) or anti-hRad1 or anti hRad17 (right panel). Immunoprecipitates were immunoblotted with anti-hRad17 (upper panels) or anti-hHus1 (lower left panel) or anti-hRad1 (lower right panel).


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Fig. 2.   Transiently overexpressed hRad9 undergoes complex modifications. K562 cells were transiently transfected with 40 µg of pcDNA3 empty vector only (lanes 1, 2, and 4), with 5 µg of pEF-BOS-Delta RI-hHus1-HA2, and 5 µg pcDNA3-FLAG2-hRad1 expression vectors (lane 3), with 20 µg AU1-hRad9 alone (lane 5) or with these amounts of all three checkpoint expression vectors (lane 6). The following day, cell lysates were immunoprecipitated with either preimmune serum (PI, lane 1), anti-hRad9 (lanes 2 and 3), or anti-AU1 mAb (lanes 4-6). Immunoprecipitations (IP) were immunoblotted with anti-hRad9. The arrows indicate apparent molecular masses of AU1-hRad9 calculated using commercially available protein standards.


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Fig. 3.   Transiently expressed, epitope-tagged hRad9, hHus1, and hRad1 interact. Cells were transfected with 40 µg of pcDNA3 (lanes 1, 5, 9, 13), 30 µg of pcDNA3-AU12-hRad9 (lanes 3, 4, 7, 8, 11, 12, 15, 16), 5 µg of pEF-BOS-Delta RI-hHus1-HA2 (lanes 2, 4, 6, 8, 10, 12, 14, 16), or 5 µg of pCDNA3-FLAG2-hRad1 expression vectors. Twenty hours after transfection, the cells were lysed, and an aliquot of each lysate was prepared for electrophoresis (Lysate). The lysates were immunoprecipitated with anti-FLAG, anti-HA, or anti-AU1 mAb and lysates, and the precipitates were immunoblotted sequentially with anti-hRad9 (C), anti-FLAG (A), followed by anti-HA (B). The apparent molecular mass of AU1-hRad9 was estimated by comparison with protein standards.

To further verify that these proteins associate, we immunoprecipitated hRad9. In these precipitates we readily observed a hHus1-reactive band (Fig. 1A, upper center panel) that comigrated with immunoprecipitated hHus1 (Fig. 1A, upper left panel). We also immunoprecipitated hRad1 and demonstrated that hHus1 (Fig. 1A, upper right panel) and hRad9 (Fig. 1A, lower right panel) were present in anti-hRad1 immunoprecipitates. However, we did not find hRad1 in anti-hRad9 immunoprecipitates (Fig. 1A, middle center panel), even though we did observe hRad9 in anti-hRad1 immunoprecipitates (Fig. 1A, lower right panel). One explanation for these discrepant results is that hRad1 and the immunodominant anti-hRad9 antibodies share an overlapping binding site, which precludes simultaneous interaction. In support of this Fig. 3 demonstrates that anti-epitope immunoprecipitates of AU1-tagged hRad9 contain hRad1. These results suggest that this group of human checkpoint proteins assembles into a multimolecular complex even in the absence of genotoxic stimuli.

hRad1 and hHus1 Do Not Interact with hRad17-- Epistasis studies identify genetic interactions and are frequently indicative of biochemical interactions as well. Studies in S. cerevisiae have shown genetic and biochemical interactions among the members of the scRAD24 epistasis group (21, 22), which includes S. cerevisiae homologs for HRAD1 (scRAD17), HRAD17 (scRAD24), and HRAD9 (partially homologous to scDDC1). Additionally, previous work demonstrated that hRad17 and hRad1 interacted in a two-hybrid system (16). Therefore, we addressed the possibility that hRad1 and hHus1 might interact with the checkpoint protein hRad17. We immunoprecipitated hHus1 and hRad17 (Fig. 1B, left panel) and hRad1 and hRad17 (Fig. 1B, right panel). The immunoprecipitates were immunoblotted first with anti-hHus1 (Fig. 1B, lower left panel) or anti-hRad1 (Fig. 1B, lower right panel), followed by anti-hRad17 (Fig. 1B, upper panels). We found no interactions between hRad17 and hRad1 or hHus1. Thus, these results suggest that the human checkpoint complexes may be differentially assembled in undamaged cells. Alternatively, the interactions may be transient and not detectable under our experimental conditions.

hRad9 Undergoes Complex Post-Translational Modifications-- To generate a system amenable to further biochemical analysis, we prepared epitope-tagged expression vectors for hRad1, hHus1, and hRad9. When analyzed by SDS-PAGE (Fig. 1), hRad9 migrated with an apparent molecular mass (70 kDa) that was much larger than predicted (45 kDa), suggesting that the cellular pool of hRad9 may undergo extensive post-translational modifications (Fig. 2, lanes 2 and 3). Consistent with this observation, overexpression of AU1-tagged hRad9 revealed multiple species when resolved by SDS-PAGE (Fig. 2, lane 5). The major detectable band had an apparent molecular mass of 55 kDa. This is significantly smaller than the 70-kDa endogenous hRad9 (Fig. 2, lanes 2 and 3), but still larger than the predicted molecular mass (45 kDa), even when the 2-kDa epitope tag is taken into account. Thus, the major 55-kDa may be either an unmodified form that migrates anomalously or a partially modified version. In addition to the 55-kDa form, multiple slower migrating bands were present above this band, suggesting several steps of post-translational modification (Fig. 2, lane 5). Remarkably, coexpression of hRad9 with hHus1 and hRad1 increased the amount of a highly modified, 72-kDa form of hRad9 (Fig. 2, lane 6). This slow-migrating form of hRad9 had an apparent molecular mass slightly greater than endogenous hRad9, which is due to the addition of the tandem AU1 tag on hRad9.

Epitope-tagged Checkpoint Proteins Associate in a Modification-dependent Manner-- To test whether the epitope-tagged checkpoint proteins recapitulate complex formation, K562 cells were transfected with empty vector, a combination of hHus1 and hRad1, hRad9 alone, or expression vectors for all three proteins. The anti-hRad9 immunoblots of cell lysates (Fig. 3, lanes 1-4) revealed that epitope-tagged hRad9 was highly overexpressed compared with the 70-kDa endogenous hRad9 (Fig. 3C, lanes 3 and 4), which was not visible on this exposure. Consistent with the results presented in Fig. 2, there were multiple forms of AU1-tagged hRad9, and coexpression of hRad1 and hHus1 enhanced the accumulation of the highly modified form (Fig. 3C, lane 15 versus lane 16).

To assess associations among the transfected proteins, we immunoprecipitated hRad1 (Fig. 3, lanes 5-8) and found epitope-tagged hRad1 (Fig. 3A), hHus1 (Fig. 3B), and both endogenous hRad9 (Fig. 3C, lane 6) and epitope-tagged hRad9 (Fig. 3C, lane 8) in these immunoprecipitates. We also immunoprecipitated with anti-HA (Fig. 3, lanes 9-12) and looked for associated hRad1 (Fig. 3A), hHus1 (Fig. 3B), and hRad9 (Fig. 3C). Again, as in the hRad1 (anti-FLAG) immunoprecipitates, endogenous and AU1-tagged hRad9 were present in the complex. Strikingly, in both the hRad1 and hHus1 precipitations, only the most highly modified form of transfected hRad9 associated with these proteins, suggesting that the modification is essential for interaction.

In the reciprocal experiment (Fig. 3, lanes 13-16) we observed that hRad1 (Fig. 3A) and hHus1 (Fig. 3B) coprecipitated with hRad9. Unlike our observations with the endogenous proteins, hRad1 (Fig. 3A) was detected readily in the anti-AU1-hRad9 immunoprecipitations, thus suggesting strongly that the rabbit anti-hRad9 antiserum indeed masks or disrupts the hRad1 interaction (see Fig. 1). Taken together, these results revealed that the human checkpoint proteins hRad1 and hHus1 associated selectively with modified hRad9 in a protein assembly that mimics the endogenous complex.

hRad9 Is Phosphorylated in Response to DNA Damage-- scDdc1 is a putative S. cerevisiae homolog of spRad9 and hRad9. Because scDdc1 is phosphorylated in response to DNA damage (22), we explored the possibility that hRad9 may also be phosphorylated in response to genotoxins. It is important to note that endogenous hRad9 (although highly modified) migrates as a single band when isolated from undamaged cells. However, we noticed that the single endogenous hRad9 band (70-kDa form) exhibited a progressively greater reduction in electrophoretic mobility when isolated from cells irradiated with increasing doses of IR (Fig. 4A). We also explored the time course of the mobility shift, which showed that hRad9 was modified within 30 min, was maximal at 2 h, and persisted for at least 6 h (Fig. 4B). To determine whether the mobility shift reflected DNA damage-induced phosphorylation, we treated hRad9 immunoprecipitates isolated from irradiated cells with calf intestinal phosphatase (Fig. 4C). As expected for phosphorylation, the DNA damage-induced mobility shift was readily reversed by treatment with the phosphatase. Moreover, the phosphatase inhibitor beta -glycerophosphate blocked the effects of the phosphatase, suggesting that effects of the phosphatase preparation are not the result of contaminating activities.


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Fig. 4.   hRad9 is phosphorylated in response to DNA damage. A, K562 cells were treated with nothing (-) or 5, 10, 20, or 50 Gy IR and cultured for 5 h after irradiation. Lysates were immunoprecipitated with anti-hRad9 and immunoblotted with anti-hRad9. B, K562 cells were treated with nothing (-) or 50 Gy IR and cultured for 0.5, 1, 2, 4.5, or 6.5 h. Samples were processed as in A. C, K562 cells were treated with nothing or 50 Gy IR and cultured for 5 h. hRad9 immunoprecipitates were washed with lysis buffer, followed by phosphatase buffer, and treated with nothing or with 0.25 unit of calf intestinal alkaline phosphatase (CIAP), in the absence and presence of 50 mM beta -glycerophosphate (beta -GP). The immunoprecipitates were washed once with lysis buffer and immunoblotted with anti-hRad9.


    DISCUSSION
Top
Abstract
Introduction
Procedures
Results
Discussion
References

The present results demonstrate that hRad9 undergoes extensive and quantitative modification even in the absence of exogenous genotoxic stimuli. This modification is significant, because it is crucial for hRad9 to interact with the checkpoint proteins hRad1 and hHus1. However, there is an intricate interplay between hRad9 modification and complex formation. Overexpression of hRad1 and hHus1 promote the appearance of fully modified hRad9. One possible explanation for this result is that hRad1 and hHus1 are required for hRad9 modification. Another, perhaps more plausible explanation is that hRad9 is not stable when overexpressed singly, but once modified it associates with hRad1 and hHus1 and forms a stable multimolecular complex.

In addition to the modification required for hHus1 and hRad1 interactions, hRad9 is phosphorylated in response to DNA damage, like its S. cerevisiae homolog scDdc1 (22). Phosphorylation of scDdc1 requires the Atm homolog scMec1 (23). However, in SV40-transformed AT fibroblasts, we observed DNA damage-induced hRad9 phosphorylation (data not shown), suggesting that other PIKKs, possibly Atr, may be key mediators of this signaling pathway. Although we do not yet know the significance of hRad9 phosphorylation, it has no effect on association with hRad1 or hHus1 (data not shown), suggesting that phosphorylation regulates interactions with other members of the checkpoint signaling cascade.

There is a precedent for other checkpoint proteins undergoing extensive modifications that dramatically alter their apparent molecular mass and regulate their interactions with other proteins. The unrelated scRad9 is phosphorylated in response to DNA damage, and this modification is essential for scRad9's interaction with the checkpoint protein kinase scRad53 (24). There are several potential molecular modifications that may contribute to hRad9's mobility shift, including phosphorylation that is resistant to phosphatase treatment, possibly due to protection by hHus1 and hRad1 interaction. Although the nature of the hRad9 modification is currently unknown, we are intensively investigating these and other possible molecular alterations of the protein.

Previous studies in yeast demonstrated that hRad1 and hHus1 genetically and biochemically interact and are required for activation of checkpoints in response to DNA damage and replication inhibitors (18). Although much genetic evidence attests to their importance in cell cycle arrest and survival, even in the well studied yeast models little is known about their functions. To add further complexity, spRad9, hRad9, spHus1, and hHus1 have no signature sequences or homologies with other proteins that yield clues to their functions. However, spRad1 and hRad1 have significant homology with Ustilago maydis Rec1 exonuclease (12-14, 25). Additionally, hRad1 may possess 3' right-arrow 5' exonuclease activity (13), although other groups could not confirm this hypothesis (12). The presence of a putative DNA-metabolizing protein in the multimolecular checkpoint complex, coupled with genetic data that place spRad1, spHus1, and spRad9, and their S. cerevisiae counterparts, early in the response pathway (2, 3, 21), suggests that the complex may function as a sensor that scans the genome for damaged DNA. Once damaged DNA is detected, this complex may initiate endonucleolytic processing of the lesions and trigger interactions with downstream signaling elements. Alternatively, the checkpoint complex may link unknown damage recognition components to downstream signal-transducing pathways that include ATM and hChk1, both of which are implicated in actively enforcing cell cycle arrest after DNA damage. Thus, the present data provide the first identification of a DNA damage-responsive human checkpoint complex that is fundamentally conserved between yeast and humans.

    FOOTNOTES

* 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.

Dagger To whom correspondence should be addressed: Mayo Foundation, 200 First Street Southwest, Oncology Research, 13 Guggenheim, Rochester, MN 55905. Tel.: 507-284-3124; E-mail: karnitz.larry{at}mayo.edu.

The abbreviations used are: PIKK, phosphatidylinositol 3-kinase-related kinase; IR, ionizing radiation; Gy, gray; PCR, polymerase chain reaction; HA, hemagglutinin; mAb, monoclonal antibody; PAGE, polyacrylamide gel electrophoresis.
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Abstract
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Results
Discussion
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