Unexpected chronic lymphocytic leukemia B cell activation by bisphosphonates

Chronic Lymphocytic Leukemia (CLL) is the most common B-cell malignancy among European descent and is characterized by the monoclonal expansion of CD5 + B cells. The clinical course of CLL patients is highly heterogeneous with some cases surviving for decades without therapeutic intervention while others require treatment shortly after diagnosis. In the last decade, advancements in the therapeutic armamentarium have highly improved the clinical management of this disease. Despite that, CLL remains incurable [1]. Importantly, CLL is infrequent among individuals ≤ 40 years old, as the average diagnosis age ranges from 65 to 70 years [2, 3]. Consequently, CLL patients frequently exhibit concurrent health issues, which are linked to worse prognoses and necessitate simultaneous treatment for these diverse conditions [4, 5]. Osteoporosis, among the conceivable concurrent conditions, may also be prompted or exacerbated by the leukemic cells [6, 7]. As of now, there are not comprehensive investigations regarding the overall number of CLL patients undergoing treatment for osteoporosis. Nevertheless, it could range between 12.5 and 31% of the total CLL patients, as respectively found in two independent studies [8, 9].

Bisphosphonates (BPs), a class of drugs commonly prescribed for the treatment of osteoporosis, are stable analogues of pyrophosphates. BPs are divided into two classes, the N-containing and non-N-containing bisphosphonates, targeting osteoclast cells with different mechanisms of action [10]. Specifically, the N-containing bisphosphonates, like Zoledronate (ZOL) and Pamidronate (PAM), induce apoptosis in osteoclasts by inhibiting the mevalonate pathway, preventing protein prenylation, thus disrupting osteoclast cytoskeleton remodeling and inhibiting the resorptive function of osteoclast [10]. The non-N-containing bisphosphonates, like Clodronate (CLO) and Etidronate (HEDP), are metabolically converted to non-hydrolyzable toxic ATP analogues, which impair a variety of metabolic processes and thereby induce osteoclast apoptosis [10, 11].

However, BPs effects are likely not circumscribed to targeting bone loss, as they may affect tumor cells as well. Recent preclinical studies in various types of cancer indicate that BPs exhibit an antitumoral activity exerted, either directly, through the inhibition of the mevalonate pathway in cancer cells [12], or indirectly, through different mechanisms, including antiangiogenic activity [13], depletion of pro-tumoral macrophages from the microenvironment [14] and their polarization shift to antitumor M1 phenotype [15] and, for ZOL, increased cancer immune surveillance through activation of γδ T cells [13, 16]. In line with these studies, cytotoxic effects of both N-containing (ZOL) and non-N-containing (PAM) BPs were also documented in vitro on leukemic cells obtained ex vivo from patients with CLL [17].

Accordingly, a significant number of CLL patients presenting osteoporosis is likely undergoing treatment with BPs that could affect the leukemic clone as well. Of note, most of the previous studies, showing cytotoxicity in cancer cells, were conducted using BPs concentrations that are unlikely observable outside of calcified issues, such as lymph nodes and other secondary lymphoid tissues [18].

In this view, since the microenvironment plays a key role in the pathogenesis and clonal expansion of CLL B cells, by supporting the activation and proliferation of intraclonal subpopulation(s) of the leukemic clone [19‐21], identifying the effects of BPs in these proliferative CLL B subpopulations might improve our therapeutic abilities. For these reasons, we investigated the role of BPs in CLL B cells activated through microenvironment stimuli.

B cell chronic lymphocytic leukemia presents on average at 65–70 years of age at the time of diagnosis, and is uncommon in younger individuals (≤ 40 years of age) [2, 3]. Thus, patients with CLL often display comorbidities whose presence associates with poorer outcomes and requires co-treatment of the various conditions [4, 5]. Osteoporosis, among the possible co-existing conditions, may also be induced or aggravated by the leukemic cells [6, 7]. In this context, bisphosphonates represent a broad class of drugs commonly prescribed for the treatment of osteoporosis [10]. Despite comprehensive studies about the overall use of BPs in CLL are currently missing, a recent report showed that in a US Medicare cohort of 10,834 CLL patients at least 1450 (12.5%) received BP treatment associated with osteoporosis comorbidity [8] and a recent CLL database reports 31% CLL patients that received BP treatment for osteoporosis [9].

Some BPs (e.g., CLO, HEDP, ZOL, PAM, etc.), were shown, in various preclinical studies, to possess antitumor activity [12, 13, 16, 41‐43], including in vitro cytotoxicity effects of ZOL and PAM on CLL B cells [17].

Herein, investigating more deeply the effects of BPs on CLL B cells, we observed opposite cellular consequences upon treatment with different concentrations. Specifically, either cytotoxicity or survival/proliferative effects were observed on activated CLL B cells, respectively at higher or lower BP concentrations. BPs mediated cytotoxicity at drug concentrations above 100 μM for CLO, 10 mM for HEDP, and 30 μM for ZOL, in agreement with a previous study on ex vivo CLL cells treated with 50 to 100 μM of ZOL and PAM [17]. However, at lower doses, specifically in a limited range around 30 μM for CLO, 3 mM for HEDP, and 10 μM for ZOL, CLL B cells activated by microenvironmental stimuli responded with increased survival and enhanced proliferation.

These same BP concentrations increased chemoresistance; in particular, it decreased Fludarabine-induced cytotoxicity. A trend towards reduced efficacy during treatment with Venetoclax and Ibrutinib was also noted, and increased survival and cell proliferation mediated by BPs were directly associated with markers of aggressive clinical course.

This kind of response of CLL B cells to the BPs was associated with the presence of bystander cells (i.e., autologous Nurse-like cells or xenogenic fibroblasts). This is in line with the knowledge of CLL being a disease that requires support and cross-talk, by direct intercellular contacts or release of soluble elements, within the lymphoid microenvironment (e.g., lymph nodes and bone marrow). However, the observed effects were not due to a direct effect on cell growth of the stromal bystander cells present in the culture. To be specific, fibroblasts and NSCs treated with CLO, HEDP, and ZOL showed no significant alterations in cell cycle nor survival. Additionally, the depletion of autologous T or NK cells from BP-responding CLL samples did not alter the BP-induced effects on the CLL B cells. These data indicate that BPs do not act through direct modifications of the microenvironmental niche required to activate the leukemic cells. Rather, BPs induce the enhanced prosurvival/proliferation phenomenon by specifically targeting the activated CLL B cells previously primed by the crosstalk with fibroblasts or NSCs. These results agree with an in vivo study on B cell activation by CLO [44]. Administration of clinically relevant doses of the bisphosphonate in mice was able to increase activation of B cells in response to antigenic stimuli. Interestingly, this activity was independent of T cells, inflammatory monocytes, neutrophils, or dendritic cells, indicating that BPs directly targeted B cells [44].

Attempting to dissect the ongoing mechanism utilized by the CLL B cells to crosstalk with the microenvironment and acquire the BP-responsiveness characteristics, we found that enhanced survival and proliferation of CLL B cells in presence of BP, is likely mostly dependent on cell-to-cell contact but could also be triggered by soluble factors released in the medium by CLL cells when they interact with the stromal bystander cells or by the bystander cells themselves. In this context, we focused on targeted analysis based on the state-of-art knowledge of BPs mechanism of action in osteoblasts, and evaluating the role of RANK/RANKL and purinergic pathways, known for their importance both in CLL progression and osteoporosis [33‐40], we demonstrated that the BPs effects observed do not operate through these conventional pathways. Hence, the specific elements of the lymphoid microenvironment that may participate—by cellular contact, autocrine, and/or paracrine mechanisms—in mediating the in vitro observed pro-activation and pro-proliferation effects of BPs on CLL cells remain unsettled.

The BP concentrations described herein to promote increased CLL cell proliferation might have a clinical relevance. The available pharmacokinetic studies carried out on patients treated with BP for osteopenia/osteoporosis report that the bloodstream exhibits a brief peak BP concentration followed by rapid and consistent clearance [18, 45‐48]. While concentration ranges vary among different BPs, most share these pharmacokinetic features [18, 49‐51]. For example, ZOL reaches a peak blood concentration of approximately 1 mM, which rapidly declines to 3–10 μM [46, 52, 53]. CLO serum levels range from 2 to 10 μM [48]. Risedronate levels never exceed 3–10 μM [54], while pamidronate levels remain below the μM range [51, 55]. In contrast, BPs tend to accumulate in calcified tissues at high concentrations, reaching levels of up to 100–1000 μM depending on the specific BP and method of administration [18, 49‐51]. In summary, non-calcified tissues have significantly lower BP concentrations compared to bone tissues [18, 47]. This suggests that most of the time, BP levels in the blood remain in a steady-state 'low' range. It is also reasonable to hypothesize that in other non-calcified tissue where CLL B cells reside and interact with their microenvironment, such as lymph nodes [20, 56], BP concentrations are like those in the blood.

Thus, accordingly with the previous studies that used high BP concentrations, the cytotoxic effects on neoplastic cells are likely achievable for treatment of bone cancers and/or bone metastasis (e.g., multiple myeloma, breast cancer) [57, 58] and not for malignancies that preferentially reside in non-calcified tissues.

While unable to identify the molecular mechanism of action of BPs on the CLL B cells, this study shows potentially important pro-leukemia effects in the context of BP concentrations that are likely achievable in lymph nodes where CLL cells reside and receive microenvironment stimuli, and identify the role of the microenvironment and stimulatory pathways in the survival/proliferation of CLL B cells exposed to BPs. The portray of this phenomenon could be important to prompt further studies on this issue. Given that both disease and treatment courses have a very heterogeneous outcome among CLL patients, these future studies should include a broad cohort of CLL patients for multicenter clinical trials and/or retrospective metanalysis.