Abstract
Complex diseases such as cancer and diabetes are underpinned by changes in metabolism, specifically by which and how nutrients are catabolized. Substrate utilization can be directly examined by measuring a metabolic endpoint rather than an intermediate (such as a metabolite in the tricarboxylic acid cycle). For instance, oxidation of specific substrates can be measured in vitro by incubation of live cultures with substrates containing radiolabeled carbon and measuring radiolabeled carbon dioxide. To increase throughput, we previously developed a miniaturized platform to measure substrate oxidation of both adherent and suspension cells using multiwell plates rather than flasks. This enabled multiple conditions to be examined simultaneously, ideal for drug screens and mechanistic studies. However, like many metabolic assays, this was not compatible with bicarbonate-buffered media, which is susceptible to alkalinization upon exposure to gas containing little carbon dioxide such as air. While other buffers such as HEPES can overcome this problem, bicarbonate has additional biological roles as a metabolic substrate and in modulating hormone signaling. Here, we create a bicarbonate-buffered well-plate platform to measure substrate oxidation. This was achieved by introducing a sealed environment within each well that was equilibrated with carbon dioxide, enabling bicarbonate buffering. As proof of principle, we assessed metabolic flux in cultured adipocytes, demonstrating that bicarbonate-buffered medium increased lipogenesis, glucose oxidation, and sensitivity to insulin in comparison to HEPES-buffered medium. This convenient and high-throughput method facilitates the study and screening of metabolic activity under more physiological conditions to aid biomedical research.
Highlights
Metabolic dysregulation is emerging as a common feature of numerous complex diseases such as cancer [1], inflammatory disorders (e.g., [2]), and cardiovascular disease [3]
Glucose and fatty acid utilisation are reciprocally regulated across multiple tissues to maintain energy homeostasis, with perturbations in this balance observed in metabolic diseases such as diabetes [6]
A microplate-based, bicarbonate-compatible method to measure substrate oxidation? To enable cell culture perturbation and drug testing, we previously developed a platform for measuring substrate oxidation in multi-well plates [14]
Summary
Metabolic dysregulation is emerging as a common feature of numerous complex diseases such as cancer [1], inflammatory disorders (e.g., [2]), and cardiovascular disease [3]. Keywords Gas trap, cell metabolism, oxidation, carbon dioxide, bicarbonate, glucose, adipocyte Applying this new protocol to cultured adipocytes, we demonstrate that bicarbonate increases glucose oxidation and lipogenesis, and the sensitivity to insulin. We applied our optimised gas-flow conditions to cultured adipocytes and measured lipogenesis, which utilises bicarbonate as a substrate for carboxylation.
Sign-in/Register to view highlights & summary Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a callDisclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.
