Plasma cell dependence on histone/protein deacetylase 11 reveals a therapeutic target in multiple myeloma
AGM Mostofa, Allison Distler, Mark B. Meads, Eva Sahakian, John J. Powers, Alexandra Achille, David Noyes, Gabriela Wright, Bin Fang, Victoria Izumi, John Koomen, Rupal Rampakrishnan, Tuan P. Nguyen, Gabriel De Avila, Ariosto S. Silva, Praneeth Sudalagunta, Rafael Renatino Canevarolo, Maria D. Coelho Siqueira Silva, Raghunandan Reddy Alugubelli, Hongyue A. Dai, Amit Kulkarni, William S. Dalton, Oliver A. Hampton, Eric A. Welsh, Jamie K. Teer, Alexandre Tungesvik, Kenneth L. Wright, Javier Pinilla-Ibarz, Eduardo M. Sotomayor, Kenneth H. Shain, Jason Brayer
AGM Mostofa, Allison Distler, Mark B. Meads, Eva Sahakian, John J. Powers, Alexandra Achille, David Noyes, Gabriela Wright, Bin Fang, Victoria Izumi, John Koomen, Rupal Rampakrishnan, Tuan P. Nguyen, Gabriel De Avila, Ariosto S. Silva, Praneeth Sudalagunta, Rafael Renatino Canevarolo, Maria D. Coelho Siqueira Silva, Raghunandan Reddy Alugubelli, Hongyue A. Dai, Amit Kulkarni, William S. Dalton, Oliver A. Hampton, Eric A. Welsh, Jamie K. Teer, Alexandre Tungesvik, Kenneth L. Wright, Javier Pinilla-Ibarz, Eduardo M. Sotomayor, Kenneth H. Shain, Jason Brayer
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Research Article Immunology Oncology

Plasma cell dependence on histone/protein deacetylase 11 reveals a therapeutic target in multiple myeloma

Abstract

The clinical utility of histone/protein deacetylase (HDAC) inhibitors in combinatorial regimens with proteasome inhibitors for patients with relapsed and refractory multiple myeloma (MM) is often limited by excessive toxicity due to HDAC inhibitor promiscuity with multiple HDACs. Therefore, more selective inhibition minimizing off-target toxicity may increase the clinical effectiveness of HDAC inhibitors. We demonstrated that plasma cell development and survival are dependent upon HDAC11, suggesting this enzyme is a promising therapeutic target in MM. Mice lacking HDAC11 exhibited markedly decreased plasma cell numbers. Accordingly, in vitro plasma cell differentiation was arrested in B cells lacking functional HDAC11. Mechanistically, we showed that HDAC11 is involved in the deacetylation of IRF4 at lysine103. Further, targeting HDAC11 led to IRF4 hyperacetylation, resulting in impaired IRF4 nuclear localization and target promoter binding. Importantly, transient HDAC11 knockdown or treatment with elevenostat, an HDAC11-selective inhibitor, induced cell death in MM cell lines. Elevenostat produced similar anti-MM activity in vivo, improving survival among mice inoculated with 5TGM1 MM cells. Elevenostat demonstrated nanomolar ex vivo activity in 34 MM patient specimens and synergistic activity when combined with bortezomib. Collectively, our data indicated that HDAC11 regulates an essential pathway in plasma cell biology establishing its potential as an emerging theraputic vulnerability in MM.

Authors

AGM Mostofa, Allison Distler, Mark B. Meads, Eva Sahakian, John J. Powers, Alexandra Achille, David Noyes, Gabriela Wright, Bin Fang, Victoria Izumi, John Koomen, Rupal Rampakrishnan, Tuan P. Nguyen, Gabriel De Avila, Ariosto S. Silva, Praneeth Sudalagunta, Rafael Renatino Canevarolo, Maria D. Coelho Siqueira Silva, Raghunandan Reddy Alugubelli, Hongyue A. Dai, Amit Kulkarni, William S. Dalton, Oliver A. Hampton, Eric A. Welsh, Jamie K. Teer, Alexandre Tungesvik, Kenneth L. Wright, Javier Pinilla-Ibarz, Eduardo M. Sotomayor, Kenneth H. Shain, Jason Brayer

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Figure 2

HDAC11 interacts with IRF4 and regulates IRF4 acetylation status.

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HDAC11 interacts with IRF4 and regulates IRF4 acetylation status. (A–D) ...
(AD) PLA was performed on MM1.S cells. (A) Parental MM1.S cells were conditioned with LPS (5 μg/mL) or elevenostat (ES; IC50 dose). (C) MM1.S cells were transfected with plasmid constructs containing WT or enzymatically inactive HDAC11 or an empty vector as a control. PLA signals (red fluorescence) were detected by confocal microscopy. DAPI provided nuclear counterstaining and Alexa Fluor 488–labeled α-tubulin provided cytoplasmic counterstain. (B and D) Quantitative analysis of PLA signals, analyzed by 2-way ANOVA reported as mean ± SD. (E) PLA on primary MM cells derived from patient samples. Cells were cultured with the serum collected from the same patient and incubated with LPS (5 μg/mL) and ES (1 μM) or combination of LPS and ES (24 hours), ×40 magnification. (F) Quantitative analysis of PLA signals in the primary MM cells presented as median with 95% CI. Statistical comparison was performed using a 2-way ANOVA test with data expressed as mean ± SD; **P < 0.005; ***P < 0.0005; ****P < 0.0001. (G) Reciprocal co-IP assays conducted on MM1.S cell lines stably transfected with an HA-tagged WT or enzyme-inactive version of HDAC11, empty vector–transfected cells were used as control. IP performed with anti-IRF4 and anti-HA antibody, rabbit IgG (rIgG) used as isotype control; gel image representative of experiment run in triplicate. (H) Western blot detection of acetylated lysine (AcK) after IP of IRF4. Cell lysates were immunoprecipitated with an anti-IRF4 antibody followed by immunoblotting with antibodies against AcK or IRF4; IRF4 acetylation was quantified based on the ratio of acetylated IRF4 to total IRF4 (AcIRF4/IRF4); image presents results of 1 of 3 independent experiments.