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Limits of aerobic metabolism in cancer cells

Scientific Reportsvolume 7, Article number: 13488 (2017) | Download Citation

Abstract

Cancer cells exhibit high rates of glycolysis and glutaminolysis. Glycolysis can provide energy and glutaminolysis can provide carbon for anaplerosis and reductive carboxylation to citrate. However, all these metabolic requirements could be in principle satisfied from glucose. Here we investigate why cancer cells do not satisfy their metabolic demands using aerobic biosynthesis from glucose. Based on the typical composition of a mammalian cell we quantify the energy demand and the OxPhos burden of cell biosynthesis from glucose. Our calculation demonstrates that aerobic growth from glucose is feasible up to a minimum doubling time that is proportional to the OxPhos burden and inversely proportional to the mitochondria OxPhos capacity. To grow faster cancer cells must activate aerobic glycolysis for energy generation and uncouple NADH generation from biosynthesis. To uncouple biosynthesis from NADH generation cancer cells can synthesize lipids from carbon sources that do not produce NADH in their catabolism, including acetate and the amino acids glutamate, glutamine, phenylalanine and tyrosine. Finally, we show that cancer cell lines have an OxPhos capacity that is insufficient to support aerobic biosynthesis from glucose. We conclude that selection for high rate of biosynthesis implies a selection for aerobic glycolysis and uncoupling biosynthesis from NADH generation.

Introduction

Cancer cells exhibit high rates of glucose fermentation to lactate even when growing in aerobic conditions, a phenotype known as aerobic glycolysis or the Warburg effect. The Warburg effect is accompanied by other metabolic alterations, particularly increased glutamine utilization1,2,3,4 and reductive carboxylation of glutamine to the lipid precursor AcCoA5. More recently, acetate has been shown to be another important source of AcCoA in cancer cells6,7,8,9 and its contribution increases under oxygen limitation6.

Given that fermentation of glucose is the default pathway under anaerobic growth, Warburg originally thought that aerobic glycolysis should be rooted on mitochondrial defects10,11. However, cells from healthy mammalian tissues also manifest aerobic glycolysis and glutaminolysis during fast growth12,13,14,15. Furthermore, aerobic glycolysis is observed with concomitant high rates of respiratory metabolism in cancer15 and muscle16 cells.

Quantitative models of cell metabolism have been used to investigate the cause of aerobic glycolysis and related metabolic phenotypes. The postulation of a maximum oxygen consumption rate results in model predictions mimicking aerobic glycolysis in yeast17 and the Warburg effect (unpublished data). However, under aerobic conditions, further increase of the oxygenation level does not abrogate aerobic glycolysis16,18. Simulations of genome scale models of mammalian cell metabolism also predict the utilization of glutamine at high proliferation rates19,20. However, we do not understand what aspects of the model are responsible for that prediction.

Results

OxPhos burden of aerobic growth from glucose

To gain a better understanding of cell metabolism as a function of the growth metabolic demand we performed a back-of-the-envelope calculation focusing on the major biomass components of mammalian cells. The dry weight of mammalian cells is mostly composed of protein, lipids and polysaccharides (Table 1). Based on this composition we can estimate the biosynthetic demand for precursor metabolites and the energy that is necessary to duplicate the cell content. The duplication of a typical mammalian cell requires about 1.1 mol/L of amino acids for protein synthesis, 1.2 mol/L of AcCoA for lipid synthesis and an energy demand of b demand = 6.0 mol/L of ATP (Table 1).

Table 1 Growth requirements.

The synthesis of biomass precursors from glucose makes use of different dehydrogenases producing/consuming NADH (Fig. 1). The synthesis of some amino acids involves transamination coupled with glutamate to α-ketoglutarate conversion. α-ketoglutarate can be converted back to glutamate via reverse glutamate dehydrogenase consuming NADH. When all these contributions are taken into account we obtain a net production of NADH coupled to the biosynthesis of precursor metabolites from glucose. The NADH produced can be oxidized in the mitochondria coupled to ATP generation. Assuming a 2.5 ATP/NADH yield we obtain that mammalian cells can produce b coupled = 7.6 mol ATP/L coupled to NADH production by biosynthetic pathways (NADH OxPhos, Table 1).

Figure 1
Figure 1

Biosynthesis from glucose. Synthesis of precursor metabolites from glucose. The text in italics represents the precursor requirements to duplicate a cell, using the one letter nomenclature for amino acids and x for AcCoA. Dehydrogenase steps are highlighted with red arrows (solid forward and dashed reverse) and transaminase steps with blue arrows. ATP and other cofactors have been omitted for simplicity.

The aerobic biosynthesis of a cell from glucose relies on the capacity of mitochondria to generate the energy required for biosynthesis and to oxidize the NADH generated through biosynthesis. In the following we calculate how fast a cell can proliferate given a specified mitochondrial content. If a is the growth-independent energy demand for cell maintenance, b is the OxPhos demand to duplicate the cell content, T is the cell doubling time, r M is the OxPhos capacity of mitochondria (mol ATP/L of mitochondria) and ϕ M is the mitochondria volume fraction (L mitochondria/L cell) then the following constraint must be satisfied

$$a+b\frac{\mathrm{ln}\,2}{T}\le {r}_{M}{\varphi }_{M}$$
(1)

If cells proliferate too fast, shortening the doubling time (left hand side of equation 1), they will overcome the maximum OxPhos capacity (right hand side of equation 1). From equation 1 we can determine the minimum doubling time that is supported by aerobic biosynthesis from glucose

$${T}_{{\rm{\min }}}=\frac{b\,\mathrm{ln}\,2}{{r}_{M}{\varphi }_{M}-a}$$
(2)

The mitochondria OxPhos capacity (r M) has been measured for isolated mitochondria (Fig. 2 and Supplementary Table S2). It can be as high as 0.38 mol ATP/L mitochondria/min in muscle cells. The mitochondria of yeast cells is as efficient, with r M = 0.29 mol ATP/L mitochondria/min. However, the mitochondria of cancer cells is 10 fold less efficient, wit r M = 0.042–0.068 mol ATP/L mitochondria/min.

Figure 2
Figure 2

Mitochondria capacity. Mitochondria intrinsic capacity (per volume of mitochondria) for ATP generation, based on data reported in the literature (Supplementary Table S2). Red represents data for different mammalian tissues and cell lines. Green represents data for yeast. As a reference, in dashed-blue we highlight the intrinsic capacity of glycolysis.

Growth phases

As discussed above, even with mitochondria working at maximum capacity, a limited mitochondria content results in a limited oxidative phosphorylation capacity for both energy generation and NADH oxidation. What remains to be determined is whether such limitation is relevant when the actual mitochondria content and energy demand of cells are taken into consideration. To this end in Fig. 3 we depict the different scenarios that can occur depending on mitochondria content, maintenance energy and doubling time, as implied by equation (2). The top right corner corresponds with to a growth phase where cells can proliferate producing all the energy from OxPhos and can synthesize precursor metabolites from glucose (facultative OxPhos and facultative coupling of biosynthesis to NADH production, FF phase). We notice that “they can” does not imply “they must”. A cell line may have a doubling time and mitochondria content in that region, but it may have up-regulated aerobic glycolysis due to genetic alterations. Cells may also utilize alternative carbon sources due to overexpression of transport systems, reducing the NADH production coupled to biosynthesis. In such cases we can truly speak of an inefficient/wasteful/accidental phenotype. The other extreme is the grey zone highlighted in Fig. 3, where the energy demand associated with cell maintenance exceeds the OxPhos capacity (a > r M φ M in equation 2). In this region cells cannot survive without activating aerobic glycolysis.

Figure 3
Figure 3

Growth phase diagram. Different growth phases as a function of the cell doubling time and mitochondrial content. The black-solid line is obtained using equation 2, setting the OxPhos demand equal to the energy demand of cell duplication (b = b demand). The red dashed line is obtained using equation 2, setting the OxPhos demand equal to the NADH OxPhos of cell duplication (b = b coupled). The grey area demarks the region where the OxPhos capacity is insufficient to satisfy the energy demand for cell maintenance, with solid and dashed patterns indicating the certain area average minus one standard deviation and uncertain are (average plus minus two standard deviations) given our current estimates of the cell maintenance. The plusses represent 60 cancer cell lines from the NCI60 panel.

In mammalian cells the energy that can be generated from OxPhos of the NADH produced in biosynthetic pathways exceeds the energy demand of biosynthesis (b demand < b coupled, Table 1). As cells decrease their doubling time and/or decrease their mitochondrial content, they will first be limited by the inability of mitochondria to turnover the NADH produced coupled to the biosynthesis of precursor metabolites (Fig. 3, red-dashed line). To proliferate faster, shortening the doubling time, mammalian cells need to uncouple NADH production from the synthesis of precursor metabolites (facultative OxPhos and obligatory uncoupling of biosynthesis from NADH production, FO phase). In the FO phase mammalian cells can satisfy their energy demand from OxPhos, until the energy demand of biosynthesis reaches the OxPhos capacity (Fig. 3, black-solid line). Below the black-solid line mammalian cells cannot satisfy their energy demand using OxPhos and they must switch on aerobic glycolysis (obligatory aerobic glycolysis and obligatory uncoupling of biosynthesis from NADH production, OO phase). In this case aerobic glycolysis is not an inefficient/wasteful/accidental phenotype, it is the only choice left to proliferate faster.

To determine the location of cancer cells in the growth phase diagram of Fig. 3, we focus on the NCI60 panel of tumour derived cell lines. The doubling times for these cell lines has been reported by the NCI Developmental Therapeutics Program and we have estimated their mitochondrial content. Each cross in Fig. 3 represents a cell line in the NCI60 panel. Most cell lines fall in the grey area, where OxPhos cannot supply the energy requirements of cell maintenance and aerobic glycolysis must be activated. Indeed, these cell lines convert approximately 70% of the imported glucose to lactate21,22. For these cancer cells we can conclude that aerobic glycolysis is a consequence of a limited OxPhos capacity. Metabolic flux estimations indicate that these cells generate ATP from OxPhos in amounts comparable to aerobic glycolysis22. The observation of this mixed aerobic-glycolysis/OxPhos phenotype does not contradict our conclusion that aerobic glycolysis is obligatory for these cells. Simply the energy generated from OxPhos falls short of the energy demand.

Uncoupling NADH production from biosynthesis

Biosynthesis can be uncoupled from NADH generation in different ways. NADH can be turnover (NADH → NAD+) coupled to NADPH production (NADP+ → NADPH), using combinations of cytosolic/mitochondrial NAD+ and NADP+ dehydrogenases and the mitochondria transhydrogenase. We notice that the conversion of NADH to NADPH by the transhydrogenase transports protons from the mitochondria matrix to the cytosol, uncoupling OxPhos from ATP generation. Therefore, the NADH turnover by the transhydrogenase comes at expenses of exacerbating the limited OxPhos for energy production.

As an alternative, cells can switch to other carbon sources to reduce NADH production. The limited OxPhos capacity dictates which carbon sources are more suitable to uncouple NADH production from biosynthesis. Certainly for each amino acid the amino acid itself is a suitable alternative carbon source. The choice is in principle more redundant for AcCoA (Fig. 4a). Acetate can be used with the extra cost of 1 ATP for the acetyl CoA ligase step. On the other hand, the β-oxidation of fatty acids generates NADH and FADH2 and therefore it does not reduce the NADH generation burden. AcCoA could also be produced from amino acids. However, in most cases NADH is generated (Fig. 4a, grey lines). The catabolism of isoleucine, leucine, lysine, methionine, tryptophan, and valine requires one or more dehydrogenase steps generating NADH. Alanine, cysteine, glycine, threonine and serine can be converted to pyruvate, which still requires pyruvate dehydrogenase to produce AcCoa (Fig. 1). Aspartate and asparagine can be converted to oxaloacetate, which still requires a source of AcCoA for citrate synthesis or conversion to pyruvate, again requiring pyruvate dehydrogenase to produce AcCoa. Finally, arginine and proline can be converted to glutamate but NADH is generated in the process.

Figure 4
Figure 4

Metabolism under a limited OxPhos capacity. (a) Synthesis of AcCoA from alternative carbon sources. In grey we highlight carbon sources that result in NADH production. The boxes highlight the carbon sources that uncouple AcCoA synthesis from NADH production. (b) Compartmentalization of eukaryote aerobic cell metabolism in the context of a limited OxPhos capacity.

There are only two groups of amino acids that can be converted to citrate without NADH production. The first group includes glutamate and glutamine. Glutamate can be converted to citrate via reductive carboxylation. In this pathway the NAD(P)H production by glutamate dehydrogenase is compensated by the reverse activity of the NAD(P) isocitrate dehydrogenase (Fig. 1). Glutamate can be taken from the medium or generated from glutamine by glutaminase. Interestingly, arginine and proline can be produced from glutamate with concomitant consumption of NADH (Fig. 4a). This could provide an additional mechanism for NADH turnover. The second group is composed of the amino acids phenylalanine and tyrosine, which are converted to acetoacetate and fumarate (Fig. 4a). Acetoacetate yields 2 AcCoa via the combined activity of acetoacetate CoA ligase (consuming one ATP) and acetyl-CoA transferase. Fumarate on the other hand is better excreted to avoid additional OxPhos burden. We notice that the catabolism of phenylalanine and tyrosine to acetoacetate consumes 3 and 2 oxygen molecules respectively. Therefore, these amino acids are not suitable to uncouple NADH production from biosynthesis under hypoxia.

NADPH production

For the sake of simplicity we have omitted the balance of some key co-factors that are also required for cell proliferation. NADPH is a free energy source required in the biosynthesis of some amino acids and of lipids. The pentose phosphate pathway (PPP) is a major source of NADPH production. The PPP is interconnected with the upper part of glycolysis, above the glyceraldehyde 3-phosphate dehydrogenase step. Therefore, the PPP does not change the pyruvate/NADH yield ratio of glycolysis, which is the only feature of glycolysis used to calculate the biosynthetic requirements reported in Table 1. The increase in the NADPH yield just reduces the percentage of glucose carbons incorporated into biomass (1 CO2 molecule is released per every 2 NADPH).

NADPH can also be produced via one-carbon metabolism using serine as the one-carbon source23,24. The synthesis of serine from glucose generates NADH (Fig. 1). Therefore the glucose → serine → one-carbon pathway of NADPH generation is only suitable when cells have not reached their maximum OxPhos capacity. When cells have overcome their OxPhos capacity they could import serine from the media to uncouple NADH production from NADPH production via one-carbon metabolism. To donate the one-carbon unit serine is converted to glycine and glycine could also donate a one-carbon unit via the glycine cleavage system. The glycine cleavage system generates NADH and therefore this pathway is only suitable when cells have not reached their maximum OxPhos capacity. Otherwise, glycine is better excreted to avoid additional NADH production.

Discussion

When the metabolic demand exceeds the limited OxPhos capacity mammalian cells split their metabolism into two major components (Fig. 4b). There is a component of high NADH flux from aerobic glycolysis (Fig. 4b, black background box). The function of this component is to satisfy the energy demand beyond the OxPhos capacity. There is another component of low NADH flux where precursor metabolites are produced from glucose and other carbon sources (Fig. 4b, white background box). The function of this component is to generate precursor metabolites with the minimal NADH generation that can be absorbed by the limited OxpHos capacity. The choice of alternative carbon sources is restricted to those that do not generate NADH in their conversion to precursor metabolites. For generation of AcCoA, this constraint leave cells with the choice of acetate and the amino acids glutamate, glutamine, phenylalanine and tyrosine.

In the context of cancer metabolism it has been often claimed that aerobic glycolysis is a consequence of an increased demand of carbon atoms for biosynthesis of precursor metabolites25,26. A more precise statement is that the increased demand for carbon atoms results in an increased demand for NADH turnover when glucose is the carbon source. However, the excretion of lactate does not solve the problem of NADH production coupled to biosynthesis. While it is true that lactate dehydrogenase converts NADH back to NAD+, the carbon atoms associated with this conversion are excreted as lactate and they do not contribute to the formation of biomass precursors. We conclude, as originally postulated by Warburg and supported by previous calculations27, that the role of aerobic glycolysis is to satisfy the energy demand in the context of limited mitochondria OxPhos capacity.

These conclusions will hold up to small variations in the parameter values required for the analysis. Imprecisions in the demand of energy and NADH turnover may cause a change in the order of the continuous and dashed lines in Fig. 3, but the two phases at the top-right and bottom-left corners will remain. The intrinsic mitochondria efficiency of cancer cells may be larger than the values obtained for PC-3 and HeLa cells, causing some cell lines to fall in the growth phase where aerobic glycolysis is not obligatory. Therefore, our conclusion of aerobic glycolysis being obligatory may not necessarily hold for all cancer cells. In spite of these potential issues, this analysis provides a conceptual framework that brings together apparently disconnected metabolic phenotypes of cancer cells.

Methods

Cell composition

The typical biomass composition of mammalian cells was obtained from ref.28. The typical composition in terms of precursor metabolites (mol of precursor/L cell) was calculated using the equation

$$c=\frac{\pi }{\mu {v}_{s,cell}}$$
(3)

where π is the dry weight fraction of the biomass component, μ is the molecular weight of the precursor metabolite and v s,cell is the cell specific volume (L cell/g dry weight). Amino acids are the precursor metabolites of proteins. The average molecular weight of an amino acid in expressed proteins is μ aa = 109 g/mol in mammalian cells29. The acetyl group of AcCoA is the precursor of lipids. Its average molecular weight in lipids was estimated as two times the molecular weight of CH2 (μ ac = 28 g/mol). Ribonucleotides are the precursor metabolites of RNA. The average molecular weight of a ribonucleotide in expressed RNAs is μ rn = 331 g/mol in mammalian cells29. Deoxyribonucleotides are the precursor metabolites of DNA. The average molecular weight of a deoxyribonucleotide in expressed DNA is μ dn = 332 g/mol in mammalian cells29. Finally, the cell specific volume is 5 mL/gDW for mammalian cells30.


Energy requirements of biosynthesis

The mammalian cell energy requirement for synthesis of each biomass component from glucose was estimated as the number of ATP molecules required to synthesize the precursor from glucose, based on reported biosynthesis pathways31, plus the energy required for polymerization29, times the precursor concentration (Supplementary Table S1).


NADH OxPhos

The number of NADH molecules produced coupled to the synthesis of each precursor metabolite from glucose was calculated from reported biosynthesis pathways31. This value was multiplied by a yield of 2.5 ATP/NADH times the precursor concentration reported in Table 1 (see also Supplementary Table S1).


Mitochondria OxPhos capacity

The mitochondria OxPhos capacity r M was obtained from literature reports (Supplementary Table S2).


Maintenance energy

We have estimated the cell maintenance energy of cancer cells using literature reports of extracellular acidification rates (ECAR) and oxygen consumption rates (OCR) quantified using the Seahorse instrument (Table S3). The ECAR and OCR measurements where then converted to energy production from glycolysis and OxPhos using the protocol reported in reference {Mookerjee, 2017 #7479}. The energy maintenance was estimated as the total energy production (glycolysis + OxpHos) minus the energy requirements of growth (6 mol ATP/L cell × ln2/T d ). The average and standard deviation across cell lines was used to calculate the shadow areas in Fig. 3. The average value across cell lines was 5 mmol ATP/L cell/min, no far from an estimated based on data reported for the LS mouse cell line32. LS mouse cells require 17 pmol ATP/cell/day for cell maintenance. Dividing by the LS cell volume (3.4 pL/cell) we obtain the cell maintenance energy demand per cell volume a mammalian = 3.5 mmol ATP/L cell/min.


NCI60

The doubling times for each cell line are reported by the NCI Developmental Therapeutics Program https://dtp.cancer.gov/discovery_development/nci-60/cell_list.htm. Their mitochondrial content was estimated as

$${\varphi }_{M}=\frac{{P}_{cell}}{{V}_{cell}}{v}_{s,mitochondria}\,\frac{\sum _{i}{p}_{i}{l}_{i}}{\sum _{i}{p}_{i}}$$
(4)

where P cell is the protein content (g/cell), V cell is the cell volume (L/cell), v s,mitochondria is the mitochondrial specific volume (L/g mitochondrial protein), the sums run over all expressed proteins, p i is the abundance of each protein and l i  = 1 if the protein localizes to the mitochondria and 0 otherwise. P cell and V cell are reported in ref.22. The mitochondria specific volume is v s,mitochondria  = 2.6 mL/g mitochondrial protein33. The relative protein abundances where obtained from reported proteomic data34. The protein localization we obtained from the NCBI annotations. l i was set to 1 for every protein that is annotated to localize to the mitochondria. The estimated mitochondria content is reported in the Supplementary Table S4.

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Acknowledgements

This work was supported by Cancer Research UK C596/A21140. This project has received funding from the European Union’s Horizon 2020 research and innovation programme MSCA-RISE-2016 under grant agreement No. 734439 INFERNET.

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Affiliations

  1. Center of Molecular Immunology, Havana, Cuba

    • Jorge Fernandez-de-Cossio-Diaz
  2. Cancer Research UK Beatson Institute, Glasgow, UK

    • Alexei Vazquez
  3. Institute for Cancer Sciences, University of Glasgow, Glasgow, UK

    • Alexei Vazquez

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Contributions

J.F.C.D. and A.V. performed the calculations and wrote the manuscript.

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The authors declare that they have no competing interests.

Corresponding author

Correspondence to Alexei Vazquez.

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https://doi.org/10.1038/s41598-017-14071-y

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