Pharmacologic targeting of the p62 ZZ domain enhances both anti-tumor and bone-anabolic effects of bortezomib in multiple myeloma

Multiple myeloma (MM) is a malignancy of plasma cells whose antibody secretion creates proteotoxic stress relieved by the N-end rule pathway, a proteolytic system that degrades N-arginylated proteins in the proteasome. When the proteasome is inhibited, protein cargo is alternatively targeted for autophagic degradation by binding to the ZZ-domain of p62/ sequestosome-1. Here, we demonstrate that XRK3F2, a selective ligand for the ZZ-domain, dramatically improved two major responses to the proteasome inhibitor bortezomib (Btz) by increasing: i) killing of human MM cells by stimulating both Btz-mediated apoptosis and necroptosis, a process regulated by p62; and ii) preservation of bone mass by stimulating osteoblast differentiation and inhibiting osteoclastic bone destruction. Co-administration of Btz and XRK3F2 inhibited both branches of the bimodal N-end rule pathway exhibited synergistic anti-MM effects on MM cell lines and CD138+ cells from MM patients, and prevented stromal-mediated MM cell survival. In mice with established human MM, co-administration of Btz and XRK3F2 decreased tumor burden and prevented the progression of MM-induced osteolytic disease by inducing new bone formation more effectively than either single agent alone. The results suggest that p62-ZZ ligands enhance the anti- MM efficacy of proteasome inhibitors and can reduce MM morbidity and mortality by improving bone health.

Single-cell Transcriptome Analysis Identifies Senescent Osteocytes as Contributors to Bone Destruction in Breast Cancer Metastasis

Breast cancer bone metastases increase fracture risk and are a major cause of morbidity and mortality among women. Upon colonization by tumor cells, the bone microenvironment undergoes profound reprogramming to support cancer progression that disrupts the balance between osteoclasts and osteoblasts, leading to bone lesions. Whether such reprogramming affects matrix-embedded osteocytes remains poorly understood. Here, we demonstrate that osteocytes in breast cancer bone metastasis develop premature senescence and a distinctive senescence-associated secretory phenotype (SASP) that favors bone destruction. Single-cell RNA sequencing identified osteocytes from mice with breast cancer bone metastasis enriched in senescence and SASP markers and pro-osteoclastogenic genes. Using multiplex in situ hybridization and AI-assisted analysis, we detected osteocytes with senescence-associated distension of satellites, telomere dysfunction, and p16Ink4a expression in mice and patients with breast cancer bone metastasis. In vitro and ex vivo organ cultures showed that breast cancer cells promote osteocyte senescence and enhance their osteoclastogenic potential. Clearance of senescent cells with senolytics suppressed bone resorption and preserved bone mass in mice with breast cancer bone metastasis. These results demonstrate that osteocytes undergo pathological reprogramming by breast cancer cells and identify osteocyte senescence as an initiating event triggering bone destruction in breast cancer metastases.

A NOTCH3-CXCL12-driven myeloma-tumor niche signaling axis promotes chemoresistance in multiple myeloma

Multiple myeloma (MM) remains incurable due to disease relapse and drug resistance. Notch signals from the tumor microenvironment (TME) confer chemoresistance, but the cellular and molecular mechanisms are not entirely understood. Using clinical and transcriptomic datasets, we found that NOTCH3 is upregulated in CD138+ cells from newly diagnosed MM (NDMM) patients compared to healthy individuals and increased in progression/relapsed MM (PRMM) patients. Further, NDMM patients with high NOTCH3 expression exhibited worse responses to Bortezomib (BOR)-based therapies. Cells of the TME, including osteocytes, upregulated NOTCH3 in MM cells and protected them from apoptosis induced by BOR. NOTCH3 activation (NOTCH3OE) in MM cells decreased BOR anti-MM efficacy and its ability to improve survival in in vivo myeloma models. Molecular analyses revealed that NDMM and PRMM patients with high NOTCH3 exhibit CXCL12 upregulation. TME cells upregulated CXCL12 and activated the CXCR4 pathway in MM cells in a NOTCH3-dependent manner. Moreover, genetic or pharmacologic inhibition of CXCL12 in NOTCH3OE MM cells restored sensitivity to BOR regimes in vitro and in human bones bearing NOTCH3OE MM tumors cultured ex vivo. Our clinical and preclinical data unravel a novel NOTCH3-CXCL12 pro-survival signaling axis in the TME and suggest that osteocytes transmit chemoresistance signals to MM cells.

Abstract 5672: Notch3 signaling between myeloma cells and osteocytes in the tumor niche promotes tumor growth and bone destruction

In multiple myeloma (MM), Notch signaling, a pathway mediating cell-to-cell communication between cells in the tumor niche, promotes MM proliferation and bone destruction. We previously reported that osteocytes (Ots), the most abundant bone cells, provide a microenvironment conducive for MM progression and bone destruction. Ots activate Notch signaling, increase Notch3 expression, and stimulate proliferation in MM cells. We detected Notch3 in CD138+ cells from MM patients and human and murine MM cell lines. Yet, the role of Notch3 in MM is unknown. Here, we used a shRNA approach to knockdown Notch3 to study its role in MM cells and their communication with Ots. The protein levels of active Notch3 (NICD3) were decreased by 80% in 5TGM1 MM cells transduced with shRNA against Notch3 compared to control shRNA-control cells. In contrast, Notch1, 2, and 4 NICD protein levels remained unchanged compared to controls. Notch3 knockdown decreased Notch target gene and cyclinD1 expression, reduced proliferation by 35%, and modestly increased apoptosis in MM cells. Additionally, Notch3 knockdown decreased Rankl expression and the ability of MM cells to promote osteoclastogenesis in vitro. Consistent with these observations, bioinformatic analysis of the transcriptome of CD138+ cells from newly diagnosed patients revealed upregulated processes related to positive regulation of cell proliferation and osteoclastogenesis in MM patients with high vs. low Notch3 expression. Next, we examined the role of Notch3 in MM-Ots communication. Notch3 knockdown in MM cells partially prevented the upregulation of Notch target genes and cyclinD1 expression and proliferation induced by direct contact with Ots. Inhibition of all Notch receptors with GSI fully prevented osteocyte-induced proliferation and Notch activation, suggesting that in addition to Notch3, other Notch receptors mediate MM-osteocyte communication. Remarkably, shRNA-mediated Notch2 inhibition did not alter MM cell proliferation or communication with osteocytes. Lastly, we analyzed the effects of Notch3 knockdown in MM cells in ex vivo and in vivo models. Using ex vivo bone organ cultures, we found less MM proliferation and lower levels of the resorption marker CTX in conditioned media from bones cultured with shRNA-Notch3 MM cells compared to control bones cultured alone. We injected mice intratibially with shRNA-Notch3 or shRNA-control 5TGM1 MM cells. After 5 weeks, mice bearing shRNA-Notch3 cells had a 50% decrease in tumor burden, 50% reduction in osteolytic lesions, and exhibited 30% more cancellous bone compared to mice bearing control MM cells. Together, these preclinical and clinical findings support that Notch3 signaling is a crucial mediator of homotypic and heterotypic communication in the MM tumor niche. Future studies are needed to evaluate Notch3 in the tumor microenvironment as a therapeutic target for the treatment of MM.

Citation Format: Hayley M. Sabol, Tania Amorim, Cody Ashby, David Halladay, Judith Anderson, Meloney Cregor, Megan Sweet, Intawat Nookaew, Noriyoshi Kurihara, G. David Roodman, Teresita Bellido, Jesus Delgado-Calle. Notch3 signaling between myeloma cells and osteocytes in the tumor niche promotes tumor growth and bone destruction [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 5672.

Notch3 signaling between myeloma cells and osteocytes in the tumor niche promotes tumor growth and bone destruction

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Notch3 promotes proliferation and enhances the osteoclastogenic potential of multiple myeloma cells.

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Notch3 mediates the communication between myeloma cells and osteocytes that leads to tumor proliferation.

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Newly diagnosed MM patients with high Notch3 expression exhibit upregulation of gene signatures associated with cell proliferation and osteoclast formation.

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Genetic inhibition of Notch3 in MM cells markedly decreases tumor growth and bone destruction in an immunocompetent mouse model of MM disease.

In multiple myeloma (MM), communication via Notch signaling in the tumor niche stimulates tumor progression and bone destruction. We previously showed that osteocytes activate Notch, increase Notch3 expression, and stimulate proliferation in MM cells. We show here that Notch3 inhibition in MM cells reduced MM proliferation, decreased Rankl expression, and abrogated the ability of MM cells to promote osteoclastogenesis. Further, Notch3 inhibition in MM cells partially prevented the Notch activation and increased proliferation induced by osteocytes, demonstrating that Notch3 mediates MM-osteocyte communication. Consistently, pro-proliferative and pro-osteoclastogenic pathways were upregulated in CD138⁺ cells from newly diagnosed MM patients with high vs. low NOTCH3 expression. These results show that NOTCH3 signaling in MM cells stimulates proliferation and increases their osteoclastogenic potential. In contrast, Notch2 inhibition did not alter MM cell proliferation or communication with osteocytes. Lastly, mice injected with Notch3 knock-down MM cells had a 50% decrease in tumor burden and a 50% reduction in osteolytic lesions than mice bearing control MM cells. Together, these findings identify Notch3 as a mediator of cell communication among MM cells and between MM cells and osteocytes in the MM tumor niche and warrant future studies to exploit Notch3 as a therapeutic target to treat MM.

Targeting Notch inhibitors to the myeloma bone marrow niche decreases tumor growth and bone destruction without gut toxicity

Systemic inhibition of Notch with γ-secretase inhibitors (GSI) decreases multiple myeloma (MM) tumor growth, but the clinical use of GSI is limited due to its severe gastrointestinal toxicity. In this study, we generated a GSI Notch inhibitor specifically directed to the bone (BT-GSI). BT-GSI administration decreased Notch target gene expression in the bone marrow, but it did not alter Notch signaling in intestinal tissue or induce gut toxicity. In mice with established human or murine MM, treatment with BT-GSI decreased tumor burden and prevented the progression of MM-induced osteolytic disease by inhibiting bone resorption more effectively than unconjugated GSI at equimolar doses. These findings show that BT-GSI has dual anti-myeloma and anti-restorative properties, supporting the therapeutic approach of bone-targeted Notch inhibition for the treatment of MM and associated bone disease.

The multifunctional role of Notch signaling in multiple myeloma

Multiple myeloma (MM) is a hematologic cancer characterized by uncontrolled growth of malignant plasma cells in the bone marrow and currently is incurable. The bone marrow microenvironment plays a critical role in MM. MM cells reside in specialized niches where they interact with multiple marrow cell types, transforming the bone/bone marrow compartment into an ideal microenvironment for the migration, proliferation, and survival of MM cells. In addition, MM cells interact with bone cells to stimulate bone destruction and promote the development of bone lesions that rarely heal. In this review, we discuss how Notch signals facilitate the communication between adjacent MM cells and between MM cells and bone/bone marrow cells and shape the microenvironment to favor MM progression and bone disease. We also address the potential and therapeutic approaches used to target Notch signaling in MM.