Intrinsic Differences in Adipocyte Precursor Cells From Different White Fat Depots

Obesity and body fat distribution are important risk factors for the development of type 2 diabetes and metabolic syndrome. Evidence has accumulated that this risk is related to intrinsic differences in behavior of adipocytes in different fat depots. In the current study, we demonstrate that adipocyte precursor cells (APCs) isolated from visceral and subcutaneous white adipose depots of mice have distinct patterns of gene expression, differentiation potential, and response to environmental and genetic influences. APCs derived from subcutaneous fat differentiate well in the presence of classical induction cocktail, whereas those from visceral fat differentiate poorly but can be induced to differentiate by addition of bone morphogenetic protein (BMP)-2 or BMP-4. This difference correlates with major differences in gene expression signature between subcutaneous and visceral APCs. The number of APCs is higher in obesity-prone C57BL/6 mice than obesity-resistant 129 mice, and the number in both depots is increased by up to 270% by exposure of mice to high-fat diet. Thus, APCs from visceral and subcutaneous depots are dynamic populations, which have intrinsic differences in gene expression, differentiation properties, and responses to environmental/genetic factors. Regulation of these populations may provide a new target for the treatment and prevention of obesity and its metabolic complications

TRB3 Blocks Adipocyte Differentiation through the Inhibition of C/EBPβ Transcriptional Activity▿

TRB3 has been implicated in the regulation of several biological processes in mammalian cells through its ability to influence Akt and other signaling pathways. In this study, we investigated the role of TRB3 in regulating adipogenesis and the activity of adipogenic transcription factors. We find that TRB3 is expressed in 3T3-L1 preadipocytes, and this expression is transiently suppressed during the initial days of differentiation concomitant with induction of C/EBPβ. This event appears to be a prerequisite for adipogenesis. Overexpression of TRB3 blocks differentiation of 3T3-L1 cells at a step downstream of C/EBPβ. Ectopic expression of TRB3 in mouse fibroblasts also inhibits the C/EBPβ-dependent induction of PPARγ2 and blocks their differentiation into adipocytes. This inhibition of preadipocyte differentiation by TRB3 appears to be the result of two complementary effects. First, TRB3 inhibits extracellular signal-regulated kinase activity, which prevents the phosphorylation of regulatory sites on C/EBPβ. Second, TRB3 directly interacts with the DR1 domain of C/EBPβ in the nucleus, further inhibiting both its ability to bind its response element and its ability to transactivate the C/EBPα and a-FABP promoters. Thus, TRB3 is an important negative regulator of adipogenesis that acts at an early step in the differentiation cascade to block the C/EBPβ proadipogenic function

Intrinsic differences in adipocyte precursor cells from different white fat depots

Obesity and body fat distribution are important risk factors for the development of type 2 diabetes and metabolic syndrome. Evidence has accumulated that this risk is related to intrinsic differences in behavior of adipocytes in different fat depots. In the current study, we demonstrate that adipocyte precursor cells (APCs) isolated from visceral and subcutaneous white adipose depots of mice have distinct patterns of gene expression, differentiation potential, and response to environmental and genetic influences. APCs derived from subcutaneous fat differentiate well in the presence of classical induction cocktail, whereas those from visceral fat differentiate poorly but can be induced to differentiate by addition of bone morphogenetic protein (BMP)-2 or BMP-4. This difference correlates with major differences in gene expression signature between subcutaneous and visceral APCs. The number of APCs is higher in obesity-prone C57BL/6 mice than obesity-resistant 129 mice, and the number in both depots is increased by up to 270% by exposure of mice to high-fat diet. Thus, APCs from visceral and subcutaneous depots are dynamic populations, which have intrinsic differences in gene expression, differentiation properties, and responses to environmental/genetic factors. Regulation of these populations may provide a new target for the treatment and prevention of obesity and its metabolic complications

Abstract 2328: Interrogating the anti-cancer effects of co-enzyme Q10 (CoQ10) identifies metabolic and mitochondrial apoptotic responses as primary mechanisms in squamous cell carcinoma model

Abstract Targeting mitochondrial function as a therapeutic modality in cancer has been extensively investigated. BPM 31510 is a proprietary drug-lipid nanoconjugate formulation enabling delivery of supra-physiological concentrations of oxidized CoQ10 specifically into mitochondria. In this study, the anti-cancer properties of CoQ10 in squamous cell carcinoma (SCC) and its mechanism of action were investigated in in vivo xenograft and in vitro model systems. Nude mice were inoculated with a squamous carcinoma cell line isolated from tongue, SCC-25, and treated with a topical formulation containing 1.5% or 5% CoQ10. Treatment was associated with a dose-dependent delay in the detection of palatable tumors (14 ± 3 days vehicle control, 27 ± 7 days 1.5% cream, 39 ± 9 days 5% cream), (p<0.05). Histology and immunostaining analysis demonstrated a decrease in expression of VEGF in the treatment groups (p<0.05). The anti-cancer mechanism of action of CoQ10 was further investigated by interrogating the influence of CoQ10 exposure on molecular profiles using SCC-25 cells in vitro. Cell based assays, mRNA-based RT-PCR assays, and protein-based antibody chip microarrays confirmed an apoptotic response as a major anti-cancer effect in SCC-25 cells in response to CoQ10 exposure. The change in anti- and pro-apoptotic markers (Bcl-2 and caspase families) was independently confirmed by western blotting. In addition, global proteomic analysis revealed alterations in key metabolic proteins in the Pentose Phosphate Pathway (PPP). For example, expression of Transaldolase 1, an enzyme involved in the cellular protection against oxidative stress, resistance/susceptibility to apoptosis, and SCC tumor development and progression, was reduced 1.5 fold at both 6 and 24 hour time point in response to CoQ10 treatment. Together, the data suggests that CoQ10 influences cancer metabolism and redox pathway in activating apoptosis in SCC cancer model. Citation Format: Niven R. Narain, Shiva Kazerounian, Shivani Khatu, Anne R. Diers, John McCook, Stephane Gesta, Robert S. Kirsner, Brian Berman, Rangaprasad Sarangarajan. Interrogating the anti-cancer effects of co-enzyme Q10 (CoQ10) identifies metabolic and mitochondrial apoptotic responses as primary mechanisms in squamous cell carcinoma model [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr 2328

Abstract 208: BPM 31510-induced alteration in Complex II activity is functionally linked to cell death activation pathway in a preclinical model of triple-negative breast cancer

Abstract Although only 15-20% of total breast cancer diagnoses are of the triple-negative breast cancer (TNBC) subtype, they account for a significant portion of the mortality rate due to their more aggressive phenotype and a high risk of reoccurrence. Metabolic rewiring supports breast cancer progression and metastasis, particularly in ER-negative and triple-negative (TNBC) breast tumors. Thus, we examined the effects of BPM 31510, a metabolic-modulating agent in clinical trials for solid tumors, in in vitro and in vivo ER-negative and TNBC models. BPM 31510 EC50/EC&amp;gt;90 values were determined for a panel of the breast cancer cell lines and compared to non-tumorigenic MCF12A cells in vitro, and the MDA-MB231 and SkBr-3, TNBC and ER-negative models respectively, were found to be the most sensitive to BPM 31510. Treatment with BPM 31510 (EC50 and EC&amp;gt;90 doses) resulted in a time- and dose-dependent decrease the viable cell population (PI- and Annexin V-negative) and a concomitant increase in cells in early and late apoptosis (PI-negative and PI-positive Annexin V-positive cells, respectively), suggesting that BPM 31510 activates regulated cell death pathways. Consistent with the in vitro data, MDA-MB231 tumor-bearing mice had smaller tumors after 30 days of treatment with BPM 31510 and increased cleaved caspase 3 staining in resected tumors. In vitro, BPM 31510-dependent breast cancer cell death was preceded by mitochondrial membrane potential depolarization (TMRE flow cytometry) and alterations in mitochondrial respiration characterized by a consistent, dose-dependent decrease in succinate (Complex II)-fueled respiration with more varied responses to BPM 31510 in cells provided the Complex I substrates (pyruvate or palmitoyl carnitine). To investigate the role of Complex II in BPM 31510-mediated cell death, pharmacological inhibitors of the dicarboxylate site (malonate) and Qp site (atpenin A5) of Complex II were used in combination with BPM 31510 to assess the resultant effects on cell death in MDA-MB231 cells. Co-treatment with malonate significantly attenuated BPM 31510-mediated cell death while atpenin A5 did not affect BPM 31510-induced cell death, indicating succinate oxidation at the dicarboxylate site of Complex II is required, in part, for induction of cell death by BPM 31510. Together, these data demonstrate BPM 31510 has a potent anti-cancer activity in preclinical breast cancer models and define a functional link between Complex II activity and the mechanism of action for BPM 31510. Citation Format: Tulin Dadali, Anne R. Diers, Arleide Lee, Ezer Benaim, Joaquin J. Jimenez, Stephane Gesta, Vivek K. Vishnudas, Rangaprasad Sarangarajan, Niven R. Narain. BPM 31510-induced alteration in Complex II activity is functionally linked to cell death activation pathway in a preclinical model of triple-negative breast cancer. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 208.</jats:p