Eight studies have implicated BMAs as essential mediators of the development of prostate cancer bone metastases. In 2013, Herroon et al. (31) demonstrated in experimental models of intraosseous tumor growth and diet-induced obesity that marrow fat promotes the growth and progression of skeletal prostate tumors. Exposure to BMAs resulted in the induction of fatty acid-binding protein 4 (FABP4), controlled by fatty acids, peroxisome proliferator-activated receptor γ (PPARγ), insulin, interleukin 1 β (IL-1β), and heme oxygenase 1 (HMOX-1) in PC3 cells (human prostate cancer cells derived from bone metastasis). This stimulation of growth and invasiveness was also observed in obese mice with prostate cancer bone metastasis and in samples from prostate cancer patients with bone metastasis. The study highlighted the functional role of FABP4 in bone metastasis and the bi-directional interaction between FABP4 and PPARγ pathways (31). A subsequent study by the same research group (32) demonstrated that tumor-supplied IL-1β contributes to adipocyte lipolysis and regulates the pro-inflammatory phenotype in adipocytes by upregulating cyclooxygenase-2 (COX-2) and macrophage chemoattractant protein (MCP-1). This was associated with increased hypoxia signaling and activation of pro-survival pathways in PC3 cells. In another study, RNA sequencing analysis showed that exposure to adipocytes controls endoplasmic reticulum (ER) stress and the unfolded protein response signature in metastatic prostate cancer cells, partially through coordination by BIP/HSPA5, an ER chaperone (33). These findings were consistent with the overexpression of ER stress-associated genes in prostate cancer patients with bone metastasis. Diedrich et al. (34) demonstrated a functional relationship between BMA and cancer cells in bone in vitro and in vivo models of marrow adiposity. They showed that adipocyte-exposed cancer cells (PC3) exhibit increased expression of glycolytic enzymes, higher lactate production, and reduced mitochondrial oxidative phosphorylation, indicative of the Warburg phenotype. They also revealed that PC3 induces lipolysis of adipocytes as a potential maintenance mechanism. Additionally, adipocytes were found to drive the metabolic reprogramming of cancer cells through the oxygen-independent mechanism of hypoxia-inducible factor 1α (HIF-1α). Importantly, the metabolic signature observed in adipocyte-exposed cancer cells mimics the expression patterns observed in patients with metastatic bone disease. Another study demonstrated that soluble factors released by human primary BMAs can sustain the migration of prostate cancer cells in a CCR3-dependent manner, suggesting the potential involvement of the CCR3 pathway in prostate cancer cells homing to bone (35). This effect was enhanced by obesity and aging, which are known to increase the aggressiveness and the metastatic potential of prostate cancer cells. In humans, an improvement in CCR3 mRNA levels in prostate cancer bone metastatic samples vs. primary prostate cancer samples was also detected (35). These data were further confirmed by immunohistochemical evaluations that displayed overexpression of CCR3 in bone vs. visceral metastases. The study clearly underlined 1) the implication of the directed migration of CCR3 in vitro to the BMA production and 2) the enhancement of CCR3 that expresses cells in different human bone metastatic sites. These results suggested that the CCR3 pathway might be potentially implicated in prostate cancer cells homing to the bone. Wang et al. (36) highlighted the association between increased numbers of BMAs and the progression of prostate cancer cells in the bone marrow niche using in vitro and in vivo models. They demonstrated that a high-fat diet (HFD) in nude mice leads to dyslipidemia and specific alterations in the bone marrow, including increased adipocyte area and number, elevated level of free fatty acids (FFAs), and a decline in osteoblasts’ area and number. Furthermore, HFD stimulated COX2 expression and suppressed osteoprotegerin (OPG) expression in the bone marrow microenvironment. In a small cohort of patients, caprylic acid was identified as a specific FFA with higher levels in patients with prostate cancer bone metastases (n = 8) when compared to those without bone metastases (n = 8) or healthy controls (n = 16) (36). In vivo treatment of bone mesenchymal stem cells (BMSCs) with caprylic acid resulted in increased adipocyte differentiation and PPARγ expression, along with a subsequent reduction in osteoblast number. Treatment of BMAs with caprylic acid in vitro promoted BMSC-derived adipocyte differentiation, COX2 expression, PGE2 production, and antagonized osteoblastic differentiation and OPG release (36). These findings suggested that elevated caprylic acid levels may promote prostate cancer bone metastasis by stimulating adipogenesis over osteoblastogenesis. Higher FFA levels due to HFD may also influence prostate cancer bone metastasis by supporting a pro-tumor microenvironment through the increased numbers of BMAs (36). Additionally, utilizing an in vivo diet-induced models of BMA, Hardaway et al. (37), demonstrated a positive relationship between enhanced marrow fat content, bone degradation by ARCaP(M) and PC3 prostate cancer cells, and increased levels of host-derived CXCL1 and CXCL2, ligands of CXCR2 receptor. By also using an in vitro assay of osteoclastogenesis, it was shown that BMA conditioned media represented a significant source of CXCL1 and CXCL2 proteins and that both the conditioned media by adipocyte and the recombinant CXCL1 and CXCL2 ligands proficiently increase the maturation and differentiation of osteoclast (37). They further confirmed these data by stopping fat cell-induced osteoclast differentiation with CXCR2 antagonist or neutralizing antibodies. Finally, a recent study by Sanchis et al. (38), using a co-culture between PC3 and bone progenitor cells (MC3T3) or pre-osteoclastic cell line (Raw264.7), evaluated the PC3 cell transcriptome modulated by soluble factors secreted by bone precursors. By using transcriptomic data from human prostate cancer samples, the in vitro changes of metabolic genes allowed us to divide prostate cancer patients into two groups: primary prostate cancer and bone metastatic. Thus, the initial transcriptional profile activated the in vitro correlation with the clinical scenario. Furthermore, the expression levels of VDR, PPARA, SLC16A1, GPX1, and PAPSS2 metabolic genes resulted in independent risk-predictors of death in the SU2C-PCF dataset, and a risk score model constructed using this lipid-related signature can classify a subgroup of bone metastatic prostate cancer patients with a 23-fold higher risk of death. Comparing MDA-PCa-183 growing intrafemorally vs. subcutaneously in a patient-derived xenograft (PDX) model permitted us to authenticate this signature. Conditional media secretome analyses demonstrated that fibronectin and collagen type 1 were critical bone-secreted factors able to regulate tumor protein kinase A (PKA) (38).

Four studies have evaluated the interaction between BMAs and breast and melanoma cancer bone metastases. Gaculenko et al. (39) explored the influence of an HFD on tumor volume in an in vivo model of breast and melanoma cancer bone metastases. They initially characterized the effects of BMAs using the MDA-MB-231 breast cancer cell line in male immunocompromised RNU rats and established a malignant melanoma B16F10 model in male C57BL/6 mice. To translate their findings to patients, they used typical diagnostic techniques such as computed tomography (CT) and magnetic resonance imaging (MRI) combined with molecular analysis. The results demonstrated that breast and melanoma cancer bone metastases exhibited greater bone destruction in animals with high body weight, which is associated with a distinctive bone marrow environment characterized by enhanced bone marrow fat. In humans, BMAs were found to be co-localized with growing cancer cells. In addition, by analyzing the antagonization of PPARγ as a treatment for inhibiting bone tumor metastasis growth, they showed that targeting adipocytes through the inhibition of PPARγ, especially in overweight individuals, could reduce skeletal metastasis spreading and protect against cancer-associated bone loss. Similarly, Gregoric et al. (40) injected MDA-MB 231 breast cancer and B16F10 melanoma cells into the bones of nude rats or C57BL/6 mice treated with HFD and/or with the PPARγ antagonist bisphenol-A-diglycidyl ether (BADGE) to assess functional and metabolic parameters in the bone marrow. They characterized the pathophysiologic activities of bone metastases in obese and non-obese individuals. Using MRI, PET/CT, immunohistochemistry, and gene expression analysis, they highlighted that HFD in rats and mice resulted in enhanced tumor cell proliferation (Ki-67), glucose metabolism (LDHA, Gpi1, Slc16a3, and Angptl3), and angiogenic activity (CD31) in metastatic bone lesions. Wang et al. (42) demonstrated the importance of BMAs in bone metastasis using a bone metastasis mouse model obtained by an intracardiac injection of B16-F10 melanoma cells into immunocompetent C57BL/6 mice. They showed that the number of BMAs rapidly increased in the melanoma metastatic bone marrow niche. In addition, when co-cultured with melanoma cells in vitro, adipocytes were found to de-differentiate, and this process was dependent on the number of tumor cells (42). Delipidation of mature adipocytes was induced more at the highest density of melanoma cells than at lower densities. The expression of genetic markers of adipocytes, such as CCAAT/enhancer binding protein beta (CEBPβ), PPARγ, FABP4, and leptin, were decreased, while delta-like non-canonical Notch ligand 1 (Pref-1, IL-1β, IL-6, and C-C Motif chemokine ligand 2 (MCP-1)) was increased at the higher densities of melanoma cells. Using metastatic breast cancer cells, Templeton et al. (41) studied migration and colonization patterns of MDA-MB-231-fLuc-EGFP (luciferase-enhanced green fluorescence protein) and MCF-7-fLuc-EGFP breast cancer cells co-cultured with bone fragments isolated from 14 non-cancer patients. Breast cancer cell migration into tissues and toward tissue-conditioned medium was evaluated in Transwell migration chambers using bioluminescence imaging and analyzed in terms of secreted factors. Patterns of breast cancer cell colonization were also evaluated. The study observed higher migration of MDA-MB-231-fLuc-EGFP to bone in 12 samples compared to the control. These data were associated with a significant increase in adipokines/cytokines leptin and IL-1β. Fluorescence microscopy and immunohistochemistry of the bone fragments confirmed the colonization of breast cancer cells within the marrow adipose tissue compartment. The authors concluded that bone marrow adipose tissue and its molecular signals may play important roles as components of the breast cancer metastatic niche.

Regarding the interactions between BMA and myeloma cells, Liu et al. (43) demonstrated that BMA contributes to the persistence of myeloma-induced osteolytic lesions in patients in remission. This phenomenon is controlled by the secretion of adipokines that stimulate bone resorption and inhibit bone formation. Furthermore, they showed that myeloma cells can reprogram fat cells through PPARγ methylation, resulting in bone damage even after the successful elimination of myeloma. Adipocytes exhibit reduced PPARγ expression and a modified adipokine secretion profile after reprogramming by myeloma cells, leading to increased osteoclastogenesis and inhibition of osteoblastogenesis. This effect is regulated through the recruitment of specificity protein 1 (SP1) and polycomb repressive complex 2 (PRC2) proteins to the promoter region of PPARγ, inducing histone methylation of PPARγ at histone H3 lysine-27 trimethylation (H3K27me3) by the co-repressor complex.

In a recent preclinical in vitro and in vivo study, Luo et al. (44) investigated the effects of BMAs on bone metastases from lung cancer by comparing the mRNA expression level of bone metastatic SBC5 cells and non-bone metastatic SBC3 cells. The in vitro study revealed that the BMAs promote the invasion of bone metastatic SBC5 cells, but not non-bone metastatic SBC3 cells. SBC5 cells also stimulated the differentiation of osteoblasts and osteoclasts, as well as de-differentiation of mature BMAs. In an in vivo model of bone metastasis in NSG mice, rosiglitazone-induced bone marrow adiposity significantly enhanced SBC5-induced osteolytic lesion. RNA-seq analysis showed that S100A9 and S100A8 genes were upregulated in SBC5 cells compared to SBC3 cells. These findings suggest that the expression levels of S100A9/A8 may be critical for bone tropism in certain lung cancers. The elevated expression of S100A8/9 in SBC5 could play a role in the crosstalk between lung cancer cells and BMAs. Additionally, BMAs were found to significantly regulate the expression of the IL-6 receptor (IL6R), which is located adjacent to S100A8/A9 genes on chromosome 1q21.3.

In a recent study by Sato et al. (45), the role of BMAs on cancer cells was investigated in the context of bone metastasis from different primary sites (breast, kidney, lung, prostate, thyroid, uterus, colorectal, bladder, and others). The researchers compared the invasive fronts in bone metastasis with adipocyte-rich bone marrow (adipo-BM) to those with hematopoietic cell-rich bone marrow (hemato-BM). They found that the invasive front with adipo-BM had higher morphological complexity and an increased area of cancer-associated fibroblast (CAF) markers, suggesting a potential influence of adipocytes on cancer progression. Additionally, the adipo-BM invasive front exhibited a lower density of CD8+ lymphocytes and higher Ki-67 positivity, indicating increased cancer cell proliferation when compared to the tumor center. Interestingly, p21 positivity, a cell cycle regulatory protein, was significantly higher in cancer cells at the adipo-BM invasive front. The study also revealed that bone metastasized cancer cells acquired drug resistance-related gene expression profiles, suggesting a favorable tumor microenvironment provided by BMAs for cancer invasion and therapeutic resistance through CAF induction and immune evasion. These findings highlight the potential of targeting BMAs in the treatment of bone metastasis.