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Create physiologically relevant cell culture models with HPLM

 

Gibco Human Plasma-like Medium (HPLM) is formulated to resemble the natural cellular environment found in the body, mimicking the metabolic profile of human plasma. 

 

Widely used, synthetic cell culture media, including MEM, DMEM, RPMI 1640, and DMEM/F-12 contain glucose, amino acids, vitamins, and salts at concentrations that, in large part, do not reflect those found in human plasma. These media also lack additional plasma components needed to mimic the metabolic profile of human plasma. When studying cancer and other diseases, results with more physiological relevance will enable researchers to help improve their understanding of human function and illness.

The HPLM solution

Gibco HPLM contains the same salt concentrations found in human plasma, as well as the same concentrations of over 60 polar metabolites, such as amino acids, nucleic acids, sugars, and small organic acids. In resembling the natural cellular environment found in the body, HPLM helps provide researchers the ability to study the impact of physiologically relevant cell media on their specific applications.

 

HPLM supplemented with fetal bovine serum (FBS) can support cell growth and viability comparable to those of conventional FBS-supplemented basal media formulations. For most cell lines, adaptation is not required to transition from conventional medium to HPLM.

 

HPLM is beneficial to your cell culture experiments in several ways:

  • Physiologically relevant—formulated with more than 60 polar metabolites and salt concentrations that resemble the natural cellular environment found in the body
  • Peer reviewed—extensive research publications completed using HPLM formulation
  • Easy to use—direct replacement for your current media when supplemented with FBS

Meet the inventor of HPLM

The inventor of human plasma-like medium is Jason R. Cantor.

 

As a postdoc at the Whitehead Institute/MIT in Cambridge, Jason set out to create what would become human plasma-like medium (HPLM), a physiologic medium designed to more closely reflect the metabolic composition of human blood, thus permitting the study of cultured cells in biochemical conditions with greater relevance to human physiology.

 

Cantor reported his development and initial studies using HPLM in early 2017 (Cell). Read his publication here: Physiologic Medium Rewires Cellular Metabolism and Reveals Uric Acid as an Endogenous Inhibitor of UMP Synthase.

We are proud to work with Jason to bring this innovation to market, and excited by the immense possibilities that HPLM could bring across diverse areas of the scientific community. As Jason notes, "The recent development of physiologic media, like other efforts designed to address the modeling capacity of cell culture, holds immense potential to improve understanding and interpretation of diverse biological and pharmacological studies." Read more from his 2019 commentary here: The Rise of Physiologic Media .

 

Jason is listed as an inventor on a patent application for HPLM assigned to Whitehead Institute.


Research results using HPLM

Research has shown that cellular performance is impacted by the use of HPLM, indicating that physiologic media can help increase the relevance of results from physiological studies.

 

HPLM rewires cellular metabolism

Graphical abstract summary: “Among the most prominent was an inhibition of de novo pyrimidine synthesis—an effect traced to uric acid, which is 10-fold higher in the blood of humans than of mice and other non-primates. We find that uric acid directly inhibits uridine monophosphate synthase (UMPS) and consequently reduces the sensitivity of cancer cells to the chemotherapeutic agent 5-fluorouracil. Thus, media that better recapitulates the composition of human plasma reveals unforeseen metabolic wiring and regulation, suggesting that HPLM should be of broad utility.”

 

Reproduced with permission from: Cantor JR, Abu-Remaileh M, Kanarkek N et al. (2017) Physiologic medium rewires cellular metabolism and reveals uric acid as an endogenous inhibitor of UMP synthase. Cell 169: 258–272.E17. doi: 10.1016/j.cell.2017.03.023

HPLM improves T lymphocyte activation

Graphical abstract summary: “Among the most prominent was an inhibition of de novo pyrimidine synthesis—an effect traced to uric acid, which is 10-fold higher in the blood of humans than of mice and other non-primates. We find that uric acid directly inhibits uridine monophosphate synthase (UMPS) and consequently reduces the sensitivity of cancer cells to the chemotherapeutic agent 5-fluorouracil. Thus, media that better recapitulates the composition of human plasma reveals unforeseen metabolic wiring and regulation, suggesting that HPLM should be of broad utility.”

 

Reproduced with permission from: Cantor JR, Abu-Remaileh M, Kanarkek N et al. (2017) Physiologic medium rewires cellular metabolism and reveals uric acid as an endogenous inhibitor of UMP synthase. Cell 169: 258–272.E17. doi: 10.1016/j.cell.2017.03.023

The functional characteristics of cells, including morphology and growth, in HPLM are comparable to those in conventional basal media formulations.

 

Human plasma-like medium maintains cell morphology

Figure 1. Gibco HPLM supports MCF7 cell culture. MCF7 breast adenocarcinoma cells were cultured in DMEM (Cat. No. 10566016) or Human Plasma-Like Medium (HPLM, Cat. No. A4899101) supplemented with 10% FBS (Cat. No. A3840101).

Figure 2. Gibco HPLM supports HeLa cell culture. HeLa human cervical adenocarcinoma cells were cultured in DMEM (Cat. No. 11965092) or Human Plasma-Like Medium (HPLM, Cat. No. A4899101) supplemented with 10% FBS (Cat. No. A3840101).

Figure 3. Gibco HPLM supports LNCaP cell culture. LNCaP human metastatic prostate carcinoma cells were cultured in RPMI 1640 (left; Cat. No. 61870036) or HPLM (right; Cat. No. A4899101) supplemented with 10% FBS (Cat. No. A3840101).

Human plasma-like medium maintains cell growth

Figure 4. Gibco HPLM supports comparable growth rates in continuous culture. Tumor cell lines MCF7, HeLa, A549, and THP-1 were grown in DMEM (blue) or HPLM (red) supplemented with 10% FBS (Cat. No. A3840101) for five passages. Cell number was assessed at the end of each passage and used to calculate the average population doubling time for each culture.

Human plasma-like medium supports cell growth in multiple cell types

The following customer stories feature the work of our Gibco HPLM product testers

“We used the HPLM media with cancer cell lines from different tissues and different mutation background. Our overall impression of HPLM is quite positive. HPLM media was suitable for all the tested cancer cell lines. Cells were easily and quickly adapted to the HPLM without affecting viability and cell culture performance. However, we detected relevant impact of cell proliferation, metabolism and mitochondrial function in cells grown in HPLM as compared with classical media. After our experience using HPLM in cancer cell models we consider it as the best choice to get more physiological data.”

Omar Torres-Quesada

PhD, Postdoctoral Researcher at University of Innsbruck

Austria


“Immunometabolism is an exciting area of scientific investigation that has immense potential for the development of new therapeutics. It is becoming clear that how immune cells rewire their metabolism after activation depends on what nutrients are available and in what quantities. Since we study metabolite transport in primary human immune cells, we find HPLM media to be essential for modeling metabolic flux in the most physiologically relevant way possible. We have extensively vetted the use of HPLM across CD4 T helper cell lineages and find that it supports both proliferation and effector function."

Justin Rettenmaier,

Associate Director at Jnana Therapeutics

Boston, MA


"Standard cell culture media, including the Dulbecco’s Modified Eagle Medium (DMEM), contain a non-physiological excess of nutrients, including glucose and glutamine. At the same time, they are low on uric acid. Nutrient availability, however, is a most critical factor for the regulation of mTOR calling for a careful consideration of culture conditions. Therefore, we employed Human Plasma Like Medium (HPLM) to gain a better understanding of mTORC1 regulation under physiological nutrient abundance. In line with mTOR’s intricate connection to nutrient sensing pathways, mTORC1 activity, as measured by Thr389 phosphorylation of S6K, was lower when U2OS cells were cultured in HPLM instead of DMEM. In HPLM media and irrespective of any treatment, AKT and the glucose-sensing AMPK were activated. Most importantly, however, we found that p53 was required to sustain low mTORC1 activity under HPLM culture conditions irrespective of Nutlin-3a treatment. Together, our investigation using HPLM revealed a nutrient-dependent role of p53 in mTORC1 inhibition."

Martin Fischer

Principal Investigator at Leibniz Institute on Aging

Germany

Webinar: Physiologic medium to study human cell biology

 

Environmental factors influence human cell physiology and can also affect drug efficacy, but existing model systems used to study human cells have limitations for understanding these contributions. In this webinar, Dr. Jason Cantor will discuss the initial development and use of human plasma-like medium (HPLM), a physiologic medium designed to more closely reflect the metabolic composition of human blood. By examining human cancer cell lines in HPLM versus traditional media, Dr. Cantor and colleagues have recently shown that HPLM has widespread effects on metabolism and gene essentiality, and further, that HPLM can be used to reveal new insights into metabolic regulation and drug efficacy.

 

Speaker: Jason R. Cantor, Investigator, Morgridge Institute for Research, Assistant Professor of Biochemistry, University of Wisconsin-Madison

Webinar highlights:

  • Complete media, the workhorses of cell culture studies, typically consist of a basal medium that poorly resembles conditions encountered in the human body and a largely undefined serum supplement
  • Human Plasma-Like Medium (HPLM) is a relatively new physiologic basal medium designed to more closely reflect the metabolic composition of human blood
  • The development of physiologic media, like other efforts designed to address the modeling capacity of cell culture, holds immense potential to improve understanding and interpretation of biological and pharmacological studies

Assessment of cancer spheroid formation in Human Plasma-Like Medium

 

Human Plasma-Like Medium (HPLM) is a cell growth formulation designed to mimic the metabolic profile of human plasma to help maintain the physiological state of cells.

We demonstrate the capability of HPLM to support the growth of cancer spheroids in several well-studied cancer cell lines

Figure 5. HPLM supports 3D spheroid formation. Representative images of spheroids from various cell types cultured in RPMI standard medium and Human Plasma-Like Medium (HPLM) that were grown for five days. Images were captured using the Invitrogen EVOS M7000 Imaging System. Scale bar = 650 µm.

Recent publications using HPLM

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