Monoclonal antibody 4C5 prevents activation of MMP2 and MMP9 by disrupting their interaction with extracellular HSP90 and inhibits formation of metastatic breast cancer cell deposits

Background  

Heat shock protein 90 (HSP90) is a molecular chaperone that is considered a new target for the treatment of cancer. Increasing data reveal an extracellular chaperoning activity for HSP90. Here we investigate the interaction of the secreted isoforms of HSP90 with matrix metalloproteinases (MMP) MMP2 and MMP9. Moreover we examine the role of a monoclonal antibody (mAb) against HSP90, mAb 4C5, regarding these interactions and its value as a potential inhibitor of human breast cancer cell invasion and metastasis.     

Cell Surface Cdc37 Participates in Extracellular HSP90 Mediated Cancer Cell Invasion

Cdc37 is a 50 kDa molecular chaperone which targets intrinsically unstable protein kinases to the molecular chaperone HSP90. It is also an over-expressed oncoprotein that mediates carcinogenesis and maintenance of the malignant phenotype by stabilizing the compromised structures of mutant and/or over-expressed oncogenic kinases. Here we report that Cdc37 is not restricted intracellularly but instead it is also present on the surface of MDA-MB-453 and MDA-MB-231 human breast cancer cells, where it is shown to participate in cancer cell motility processes. Furthermore, we demonstrate using an anti-Cdc37 cell impermeable antibody, that similarly to its intracellular counterpart, this surface pool of Cdc37 specifically interacts with HSP90 as well as the kinase receptors HER2 and EGFR on the cell surface, probably acting as a co-factor in HSP90's extracellular chaperoning activities. Finally, we show that functional inhibition of surface HSP90 using mAb 4C5, a cell impermeable monoclonal antibody against this protein, leads not only to disruption of the Cdc37/HSP90 complex but also to inhibition of the Cdc37/ErbB receptors complexes. These results support an essential role for surface Cdc37 in concert with HSP90 on the cell surface during cancer cell invasion processes and strengthen the therapeutic potential of mAb 4C5 for the treatment of cancer.     

A critical role for HSP90 in cancer cell invasion involves interaction with the extracellular domain of HER-2

HSP90 is a ubiquitously expressed molecular chaperone that controls the folding, assembly, intracellular disposition, and proteolytic turnover of many proteins, most of which are involved in signal transduction processes. Recently, a surface form of HSP90 has been identified and associated with cell migration events. In this paper, we explore the interaction of surface HSP90 with HER-2, a receptor-like glycoprotein and member of the ErbB family of receptor tyrosine kinases that play central roles in cellular proliferation, differentiation, and migration as well as in cancer progress. The involvement of HSP90 in the regulation of HER-2 has been attributed so far to receptor stabilization via interaction with its cytoplasmic kinase domain. Here we present evidence, using glutathione S-transferase pull-down and transfection assays, for a novel interaction between surface HSP90 and the extracellular domain of HER-2. Specific disruption of this interaction using mAb 4C5, a function-blocking monoclonal antibody against HSP90, inhibits cell invasion accompanied by altered actin dynamics in human breast cancer cells under ligand stimulation conditions with heregulin. Additionally, disruption of surface HSP90/HER-2 interaction leads to inhibition of heregulin-induced HER-2-HER-3 heterodimer formation, reduced HER-2 phosphorylation, and impaired downstream kinase signaling. Interestingly, this disruption does not affect HER-2 internalization. Our data suggest that surface HSP90 is involved in heregulin-induced HER-2 activation and signaling, leading to cytoskeletal rearrangement, essential for cell invasion.     

A chimeric mouse-human antibody that retains specificity for HIV gp120 and mediates the lysis of HIV-infected cells

Murine mAb BAT123, which was made against the envelope glycoprotein gp120 of HTLV-IIIB strain of HIV type 1 (HIV-1), is capable of neutralizing HTLV-IIIB in vitro. It also inhibits the fusion between uninfected CD4+ cells and HIV-1-infected cells to form syncytia. As a step to explore the potential utility of the anti-HIV antibody in vivo, we have constructed a mouse-human chimeric antibody by rDNA techniques. The chimeric antibody, which bears the variable domains of mouse antibody BAT123 and constant domains Cr1 and C kappa of human Ig retains the Ag specificity of BAT123 as determined by its reactivity with HIV-1-infected H9 cells, gp120 in Western blot analysis, and the oligopeptide recognized by BAT123. The antiviral activities of the chimeric antibody in neutralizing HIV-1 infection as well as inhibiting the syncytia formation are also found identical to those of the parent murine antibody. Moreover, in the presence of human blood mononuclear cells, the chimeric antibody but not BAT123 (mouse IgG1) induces antibody-dependent cellular cytotoxicity. The findings point to the potential usefulness of the chimeric antibody in treating patients infected with HIV-1.     

Construction, expression, and biologic activity of murine/human chimeric antibodies with specificity for the human alpha/beta T cell receptor.

Murine/human chimeric antibodies with specificity for the human TCR-alpha/beta have been produced by genetic engineering. The L and H chain V region exons encoding the murine mAb BMA 031 were isolated and inserted into mammalian expression vectors containing the human kappa and gamma 1 or gamma 4 C region exons. The chimeric genes were transfected into murine Sp2/O hybridoma cells by electroporation and transfectomas secreting chimeric antibody were isolated. Secretion levels ranged from 1 to 7 pg/cell/24 h. The chimeric antibodies bound specifically to T cells and competed effectively with the parental murine mAb for binding to these sites. The ability to promote antibody-dependent cell-mediated cytolysis was significantly enhanced in the chimeric antibodies as compared with murine BMA 031. C-dependent cytolysis, however, was not detectable with any of the antibodies. Chimeric BMA 031 is a clinically relevant, genetically engineered antibody with potential uses in transplantation, graft-vs-host disease, autoimmune diseases and other T cell-related disorders.     

Molecular characterization of anti-idiotype antibody-resistant variants of a murine B cell lymphoma

We have previously identified Id- tumor vaiants that emerge after anti-Id mAb therapy of the murine B cell lymphoma 38C13. This report characterizes the molecular basis for these variants. By using a modification of the polymerase chain reaction (PCR), mu and kappa Ig loci were sequenced from nine Id- variants derived directly by anti-Id immunoselection in vivo. Ig kappa loci sequence analysis was also performed from 10 additional variants amplified directly from tumor cells in vitro without immunoselection. We demonstrate that the molecular mechanism underlying tumor cell escape in this model is the spontaneous emergence of variants that have undergone kappa L chain gene "re-rearrangement" before positive selection by the anti-Id antibody. A second round of re-rearrangement was also demonstrated to occur within primary tumor variants. Re-rearrangement of the 38C13 tumor cell Ig kappa locus is strongly biased toward use of variable kappa genes within the conserved V kappa-Ox1 gene family, although their use is not exclusive. With the use of RNA PCR re-rearrangement was documented to occur in vitro at a frequency of approximately 1.0 x 10(-5)/cell. These findings may have important implications for the application of anti-Id antibodies as a therapeutic approach for human lymphomas and for understanding of the Ig gene rearrangement process.     

Cloning and expression of a chimeric antibody directed against the human transferrin receptor

The cloning, construction and expression of chimeric Ig genes, encoding a mAb directed against the human transferrin receptor, is described. From a mouse hybridoma cell line, secreting an antitransferrin receptor antibody, mRNA was prepared and converted into cDNA using Ig-specific oligonucleotides. H and L chain encoding cDNA fragments were isolated and sequenced. Chimeric genes were constructed by linking the murine V region cDNA fragments to human C region exons. After sequential transfection of nonproducing mouse hybridoma cells with the expression vectors containing the chimeric H and L chain genes, antibody secreting transfectomas were obtained. ELISA and immunoblot analysis clearly demonstrate the secretion of human kappa- and gamma-1 chain. Flow microfluorimetry analysis of the chimeric antibody shows that the Ag-binding capacity has been retained. The chimeric antibody most likely will be less immunogenic then the original mouse antibody when used in human cancer therapy.     

The design, construction and function of a new chimeric anti-CD20 antibody

A novel murine IgM-type anti-human CD20 monoclonal antibody (mAb) 1-28 was prepared in our Lab, which can induce apoptosis and inhibit proliferation of Daudi and Raji cells. However, the efficacy of 1-28mAb in human cancer therapy is likely to be limited by human anti-mouse antibody responses. A chimeric antibody, C1-28, containing 1-28mAb variable region genes fused to human constant region genes (gamma 1, kappa) was constructed. However, C1-28 lost the antigen-binding activity. Here, using sequence similarity and known 3D structure of antibody variable regions as template, the spatial conformations of 1-28 variable regions (i.e. V(H) and V(L)) were analyzed with computer-guided homology modeling methods. According to the surface electrostatic distribution and interaction free energy analysis, the relationship between structure and stability of 1-28 variable regions was studied theoretically and a new chimeric anti-CD20 antibody scFv-Ig named 5S was designed. Expression level of 5S in the culture supernatant was determined to be around 50mug/mL using sandwich ELISA method with chimeric antibody Rituxan as reference. 5S retained its murine counterpart's binding activity by fluorescence-activated cell-sorting analysis. Furthermore, it could kill CD20 positive Daudi and Raji cells by complement-dependent cytotoxicity. For binding affinity often decreased even lost when IgM antibody was constructed into chimeric IgG1 form, our success give a hint about how to construct a IgG1-type chimeric antibody from IgM-type murine antibody to preserve its binding activity.     

Comparison of GK1.5 and chimeric rat/mouse GK1.5 anti-CD4 antibodies for prolongation of skin allograft survival and suppression of alloantibody production in mice.

GK1.5 is a rat mAb that recognizes the mouse CD4 Ag. It has been shown to deplete CD4+ cells in vivo and to be immunosuppressive. To evaluate the effect of the C region of this antibody in achieving cell depletion, chimeric antibodies, each having the rat GK1.5 V regions and one of the four mouse IgG C region isotypes, were compared with the native rat antibody. The chimeric antibodies and the native antibody were tested for their ability to mediate in vitro C-dependent cytotoxicity, in vivo cell depletion, and prolongation of allogeneic skin graft survival and suppression of alloantibody production. In vitro C-dependent cytotoxicity assays revealed that rat IgG2b and the chimeric antibodies containing mouse IgG2a, mouse IgG2b, and mouse IgG3 were effective in lysing CD4+ lymphocytes whereas mouse IgG1 was ineffective. In vivo studies of CD4+ cell depletion showed that mouse IgG2a, rat IgG2b, and mouse IgG2b were effective isotypes, mouse IgG1 was less effective, and mouse IgG3 did not deplete CD4+ cells. A correlation was found between the ability of an isotype to deplete CD4+ cells in vivo and its ability to prolong the survival of skin allografts and to suppress alloantibody production. The nondepleting mouse IgG3 was ineffective in these assays. Overall the most effective mouse isotype was IgG2a which was as effective as rat IgG2b. These results indicate 1) that syngeneic isotypes of mAb can cause cell depletion and consequently the prolongation of allograft rejection and suppression of alloantibody production; 2) that not all isotypes are equally effective; and 3) that the ability of a given isotype to deplete cells in vivo does not correlate with its ability to mediate C-dependent lysis in vitro. Our results are consistent with the hypothesis that in vivo depletion of cells is mediated by opsonization and binding through the FcR.     

Characterization of a human T cell-specific chimeric antibody (CD7) with human constant and mouse variable regions

A chimeric human-mouse anti-T lymphocyte mAb (CHT2; SDZ 214-380) has been constructed by cloning the variable region exons of both the L and H chains from the murine hybridoma RFT2 which have CD7 specificity and reactivity with a 40-kDa Ag. The variable L chain exon was joined to the human C kappa, and the variable H chain exon was joined to the human IgG1 region exon encoding the human allotype nGlm(z), nGlm(a). The gene constructs were introduced by electroporation into SP2/0, a non-Ig-producing murine myeloma. The identical tissue reactivity of the newly made CHT2 and the original murine RFT2 mAb (CD7) was confirmed by blocking experiments as well as by immunohistology and flow cytometry. Because this new mAb may have clinical use, the CD7 Ag expression of T lineage cells has also been quantitated in double and triple immunofluorescence assays in combinations with mAb to restricted forms of leukocyte common Ag that designate unprimed (CD45R+) and primed T lymphocyte populations (UCHL1+). CHT2 shows very strong reactivity with large thymic blast cells and cortical thymocytes from which T-ALL originates. Strong staining is seen on CD45R+ unprimed "virgin" T lymphocytes, whereas the expression on UCHL1+ primed "memory" cell types is weaker unless these cells are reactivated by mitogens or Ag. Thus CHT2 may spare a substantial population of resting memory T cells which is relevant to its potential therapeutic use. In addition the chimeric antibody had a greater in vitro antibody dependent cytotoxicity and a prolonged half-life (4.2 to 5.0 days) in Rhesus monkeys.     

Improvement of antigen binding ability of human antibodies by light chain shifting

Human HB4C5 hybridoma cells produce a lung cancer-specific IgM human monoclonal antibody (mAb). HB4C5 human mAb cross-reacts with Candida cytochrome c (Cyt c) and carboxypeptidase (Cpase). Concanavalin A (ConA)-resistant variants of HB4C5 cells loss the original light chain followed by expression of various new light chains at a high incidence (light chain shifting) (Tachibana et al., 1996). HTD8 cells, one of the ConA-resistant variant subclones of HB4C5 cells, undergo the active light chain shifting and produce various sublines, each of which stably secretes new mAb consisting of a new light chain and a HB4C5 heavy chain. The new mAb exhibits altered antigen binding ability from that of the original antibody. We could expect that HTD8 cells can be used as ‘a light chain stem cell line’ to improve antigen binding ability and specificity of established human mAbs. A BD9D12 IgG human mAb recognizes lung cancer cells and cross-reacts with cytokeratin 8. Introduction of the heavy chain gene of BD9D12 mAb into HTD8 cells resulted in establishment of various sublines which secreted various kinds of hybrid antibodies consisting of different light chains derived from HTD8 subclones which underwent light chain shifting and a common IgG heavy chain derived from BD9D12. These hybrid antibodies exhibited different or improved reactivities to Cyt, Cpase, cytokeratin 8 and various cancer cells from those of parental mAb, demonstrating that light chain shifting can be applied to improve the affinity and specificity of human mAb. This revised version was published online in June 2006 with corrections to the Cover Date.     

HSP90 modulates actin dynamics: Inhibition of HSP90 leads to decreased cell motility and impairs invasion

HSP90, a major molecular chaperone, plays an essential role in the maintenance of several signaling molecules. Inhibition of HSP90 by inhibitors such as 17-allylamino-demethoxy-geldanamycin (17AAG) is known to induce apoptosis in various cancer cells by decreasing the activation or expression of pro-survival molecules such as protein kinase B (Akt). While we did not observe either decrease in expression or activation of pro-survival signaling molecules in human breast cancer cells upon inhibiting HSP90 with 17AAG, we did observe a decrease in cell motility of transformed cells, and cell motility and invasion of cancer cells. We found a significant decrease in the number of filopodia and lamellipodia, and in the F-actin bundles upon HSP90 inhibition. Our results show no change in the active forms or total levels of FAK and Pax, or in the activation of Rac-1 and Cdc-42; however increased levels of HSP90, HSP90α and HSP70 were observed upon HSP90 inhibition. Co-immuno-precipitation of HSP90 reveals interaction of HSP90 with G-actin, which increases upon HSP90 inhibition. FRET results show a significant decrease in interaction between actin monomers, leading to decreased actin polymerization upon HSP90 inhibition. We observed a decrease in the invasion of human breast cancer cells in the matrigel assay upon HSP90 inhibition. Over-expression of αB-crystallin, known to be involved in actin dynamics, did not abrogate the effect of HSP90 inhibition. Our work provides the molecular mechanism by which HSP90 inhibition delays cell migration and should be useful in developing cancer treatment strategies with known anti-cancer drugs such as cisplatin in combination with HSP90 inhibitors.     

Novel chimeric anti-ricin antibody C4C13 with neutralizing activity against ricin toxicity

So far, no specific therapeutic agent is available for the treatment of ricin intoxication. Here, V_H and V_L genes were cloned from a hybridoma cell line secreting anti-ricin mAb 4C13, which could neutralize the toxicity of ricin. A chimeric antibody, c4C13, containing 4C13 mAb variable region genes fused to human constant region genes (gamma 1, kappa), was constructed. C4C13 retained the binding activity and recognized the same, or a closely related, epitope as the original mouse antibody. Furthermore, c4C13 blocked ricin-induced cytotoxicity to SP2/0 cells. Compared with its parental mouse antibody, c4C13 will be safer when used in human body to reverse clinical ricin intoxication. Yugang Wang and Leiming Guo contributed equally to this work.     

Transfectomas expressing both secreted and membrane-bound forms of chimeric IgE with anti-viral specificity.

Because of the lack of a cell line expressing on surface and secreting human IgE of known Ag specificity, the construction of a transfectoma line possessing such properties would be useful for studying the roles of surface IgE and the effects of anti-IgE antibodies on IgE-producing B cells. Toward this goal, the human genomic DNA segment encompassing the two exons encoding the membrane anchor peptide of epsilon-chain and their flanking regions was sequenced. Hybrid epsilon and kappa genomic DNA comprising the C regions of human epsilon- and kappa-chains and the H and L chain V regions of the murine mAb BAT123, which reacts with the gp120 envelope protein of HIV-1, were constructed. Mammalian expression vectors containing these fusion genes were used to transfect murine myeloma Sp2/0 cells, and transfectants stably expressing on surface and secreting into culture medium chimeric IgE were obtained. The chimeric IgE showed identical Ag-binding properties as the murine mAb BAT123. Acting in concert with the specific peptide Ag polyvalently coupled to a protein carrier, the chimeric antibody could induce histamine release from human blood basophils. These results demonstrate the potential utility of the transfectoma cells and the chimeric IgE in studying the roles of membrane-bound IgE and effects of anti-IgE antibodies on IgE-producing B cells.     

Construction and characterization of the chimeric antibody 8C11 to the hepatitis E virus

Homodimers of the truncated hepatitis E virus (HEV) capsid proteins, E2 and p239, were conformed to model the dominant antigenic determinants of HEV. Using E2 as an immunogen, two neutralizing monoclonal antibodies (mAbs), namely 8C11 and 8H3, were produced. We constructed a mouse-human chimeric antibody derived from 8C11 and its expression in Chinese hamster ovary (CHO) cells. cDNAs encoding variable regions of heavy and light chains were isolated from hybridoma cells and inserted into mammalian expression vectors containing cDNA of human gamma-1 and kappa constant regions, respectively. The vectors were then cotransfected into CHO cells, and a stable cell line was established. Results from indirect enzyme-linked immunosorbent assay (ELISA) and Western blot analysis showed that the chimeric antibody was assembled correctly to the native IgG molecule and could be secreted from the cells. Similar to the original mAb, the expressed chimeric antibody displayed HEV antigen-binding activity and an enhancement effect on 8H3 binding to HEV antigen. The chimeric antibody could specifically inhibit the binding of p239 to HepG2 cells and compete with HEV IgG in positive serum by antibody-competitive ELISA. The chimeric antibody is expected to be less immunogenic in human and more suitable for antibody therapy of hepatitis E.     

A murine–human chimeric IgG antibody against vascular endothelial growth factor receptor 2 inhibits angiogenesis in vitro

Vascular endothelial growth factor receptor 2 (VEGFR2) has been reported to play an important role in angiogenesis and tumorigenesis. A murine anti-VEGFR2 mAb (A8H1) has been established in a previous study. To reduce the incompatibility of the murine mAb for human use, the chimeric anti-VEGFR2-IgG was developed by genetic recombination of the variable regions of the A8H1 antibody and the constant regions of human IgG, and was expressed in Sp2/0 cells transfected with the two recombinant vectors containing the heavy chain and the light chain regions. After screening, clone 2F12 was selected and was found to stably secrete the murine–human chimeric anti-VEGFR2-IgG (coded 2F12). This chimeric IgG maintained the specificity and the affinity of the parental murine antibody against VEGFR2, and effectively identified VEGFR2 expressed on the surface of HUVECs and BEL-7402 cells. Furthermore, the 2F12 antibody demonstrated inhibition of angiogenesis in vitro, such as proliferation, migration, invasion and tube formation of HUVECs. This murine–human chimeric IgG may be considered for further development as an anti-angiogenesis and anti-tumor agent.     

A genetically engineered murine/human chimeric antibody retains specificity for human tumor-associated antigen

Chimeric immunoglobulin genes were constructed by fusing murine variable region exons to human constant region exons. The ultimate goal was to produce an antibody capable of escaping surveillance by the human immune system while retaining the tumor specificity of a murine monoclonal. The murine variable regions were isolated from the functionally expressed kappa and gamma 1 immunoglobulin genes of the murine hybridoma cell line B6.2, the secreted monoclonal antibody of which reacts with a surface antigen from human breast, lung, and colon carcinomas. The kappa and gamma 1 chain fusion genes were co-introduced into non-antibody producing murine myeloma cells by electroporation. Transfectants that produced murine/human chimeric antibody were obtained at high frequency as indicated by immunoblots probed with an antisera specific for human immunoglobulin. Enzyme-linked immunoabsorbent assay analysis demonstrated that this chimeric antibody was secreted from the myeloma cells and retained the ability to bind selectively to membrane prepared from human tumor cells. The chimeric immunoglobulin was also shown by indirect fluorescence microscopy to bind to intact human carcinoma cells with specificity expected of B6.2. The ability of chimeric antibody to recognize human tumor-associated antigen makes feasible a novel approach to cancer immunotherapy.     

CD44/chondroitin sulfate proteoglycan and alpha 2 beta 1 integrin mediate human melanoma cell migration on type IV collagen and invasion of basement membranes.

Tumor cell invasion of basement membranes (BM) represents one of the critical steps in the metastatic process. Tumor cell recognition of individual BM matrix components may involve individual cell adhesion receptors, such as integrins or cell surface proteoglycans, or may involve a coordinate action of both types of receptors. In this study, we have focused on the identification of a cell surface CD44/chondroitin sulfate proteoglycan (CSPG) and alpha 2 beta 1 integrin on human melanoma cells that are both directly involved in the in vitro invasion of reconstituted BM via a type IV collagen-dependent mechanism. Interfering with cell surface expression of human melanoma CSPG with either p-nitro-phenyl-beta-D-xylopyranoside treatment or anti-CD44 monoclonal antibody (mAb) preincubation (mAb) preincubation inhibits melanoma cell invasion through reconstituted BM. These treatments also strongly inhibit melanoma cell migration on type IV collagen, however, they are ineffective at inhibiting cell adhesion to type IV collagen. Purified melanoma cell surface CD44/CSPG, or purified chondroitin sulfate, bind to type IV collagen affinity columns, consistent with a role for CD44/CSPG-type IV collagen interactions in mediating tumor cell invasion. In contrast, melanoma cell migration on laminin (LM) does not involve CD44/CSPG, nor does CD44/CSPG bind to LM, suggesting that CD44/CSPG-type IV collagen interactions are specific in nature. Additionally, anti-alpha 2 and anti-beta 1 integrin mAbs are capable of blocking melanoma cell invasion of reconstituted BM. Both of these anti-integrin mAbs inhibit melanoma cell adhesion and migration on type IV collagen, whereas only anti-beta 1 mAb inhibits cell adhesion to LM. Collectively, these results indicate that melanoma cell adhesion to type IV collagen is an important consideration in invasion of reconstituted BM in vitro, and suggest that CD44/CSPG and alpha 2 beta 1 integrin may collaborate to promote human melanoma cell adhesion, migration, and invasion in vivo.     

Silence of HDAC6 suppressed esophageal squamous cell carcinoma proliferation and migration by disrupting chaperone function of HSP90

Esophageal carcinoma is aggressive in nature and its prognosis is largely dependent on the degree of invasion. Histone deacetylase 6 (HDAC6), as the most unique member of HDACs family, has the positive activity to promote initiation and progression of various cancers via targeting multiple non‐histone proteins in cytoplasm. In this study, we found that HDAC6 was over‐expressed in three esophageal cancer cell lines (KYSE140, KYSE170, KYSE180) when compared to non‐carcinoma esophageal epithelial cell HEEC‐1. Then two HDAC6 specific siRNAs and HDAC6 inhibitor tubastatin A greatly suppressed KYSE140 and KYSE180 cells proliferation and migration, and the inhibition of cell motility was accompanied by elevated acetylation of α‐tubulin, a target of HDAC6. Consistently, the microtubulin skeleton was stabilized after HDAC6 knockdown or inhibition. In addition, acetylation status of HSP90, another HDAC6 target, was also increased towards HDAC6 knockdown or inhibition by co‐immunoprecipitation assay. Besides, co‐treatment of HSP90 inhibitor (PU‐H71) and HDAC6 inhibitor (tubastatin A) induced a stronger cell migration inhibition compared to administration of either drug alone. Furthermore, cell proliferation of KYSE140 and KYSE180 were also compromised in response to combination of HDAC6 and HSP90 inhibitors. Additionally, co‐administration of HSP90 inhibitor and HDAC6 inhibitor strongly inhibited tumor growth in vivo. Taken together, our results indicated that HDAC6 is a promising target by inhibiting HSP90 function in ESCC.