Laurent Schwartz at Assistance Publique – Hôpitaux de ParisLaurent Schwartz
[sg_popup id= »6″ event= »hover »]38.09 Assistance Publique – Hôpitaux de Paris[/sg_popup]

 

Khalid Omer Alfarouk at University of California, San FranciscoKhalid Omer Alfarouk
[sg_popup id= »8″ event= »hover »]20.56 University of California, San Francisco[/sg_popup]

 

Claudiu T Supuran at University of Florencelaudiu T Supuran
[sg_popup id= »9″ event= »hover »]54.3 University of Florence[/sg_popup]

 

Table of Contents

Abstract 3
Introduction..4
1) Decrease energy yield of the cancer cells and compensatory fermentation..5
2) Oncogenes and carcinogens increase the Warburg’s effect 6
3) The Warburg’s effect explains intracellular alkalosis and cell proliferation..7
4) Tumor anabolism (the Warburg’s effect) explains the increased pressure and the invasion of surrounding tissue.9
5) Impact of the Warburg’s effect and subsequent increased pressure on the surrounding normal cells and immune response.10
6) Human cancer growth is nonlinear, because of progressively decreasing oxidative phosphorylation 12
7) Metabolic rewiring: the combination of alpha Lipoic acid and hydroxycitrate slows cancer growth, whatever the primary site.13
Conclusion: 15

Abstract

 

It is a longstanding debate whether cancer is one disease or a set of very diverse diseases. The goal of this paper is to suggest strongly that most (if not all) the hallmarks of cancer could be the consequence of the Warburg‘s effect. As a result of the metabolic impairment of the oxidative phosphorylation, there is a decrease in ATP concentration. To compensate the reduced energy yield, there is massive glucose uptake, anaerobic glycolysis, with an up-regulation of the Pentose Phosphate Pathway resulting in increased biosynthesis leading to increased cell division and local pressure. This increased pressure is responsible for the fractal shape of the tumor, the secretion of collagen by the fibroblasts and plays a critical role in metastatic spread. The massive extrusion of lactic acid contributes to the extracellular acidity and the activation of the immune system. The decreased oxidative phosphorylation leads to impairment in CO2 levels inside and outside the cell, with increased intracellular alkalosis and contribution of carbonic acid to extracellular acidosis-mediated by at least two cancer-associated carbonic anhydrase isoforms. The increased intracellular alkalosis is a strong mitogenic signal, which bypasses most inhibitory signals. Mitochondrial disappearance (such as seen in very aggressive tumors or following chemotherapy) is a consequence of impaired mitochondrial yield. Mitochondrial swelling, itself a result of decreased ATP concentration.

The hallmarks of cancer are the consequence of the Warburg effect. Accordingly treatment should aim at restoring the oxidative phosphorylation 

Keywords: Warburg’s effect, unification theory, ATP, metabolic treatment, alpha lipoïc acid.

Introduction

 

Cancer is widely considered as a large variety of diseases with different prognoses, sites of origin, patterns of spread, and kinetics. The goal of this paper is to address the possible underlying unity of this very diverse disease. There is always arguing about the very nature of cancer. “The Hallmarks of Cancer” [1] is a seminal article published in Cell by Hanahan and Weinberg.The authors believe that the complexity of cancer can be reduced to a small number of underlying principles. The paper argues that all cancers share six common traits (“hallmarks”) that govern the transformation of normal cells to cancer cells (malignant or tumor) [2]. These hallmarks stipulate that cancer cells [2]:

  1. Stimulate their own growth.
  2. Resist inhibitory signals that might otherwise stop their growth.
  3. Resist their own programmed cell death.
  4. Stimulate the growth of blood vessels to supply nutrients to tumors [3].
  5. Can multiply forever [3].
  6. Invade local tissue and spread to distant sites
    In an update published in 2011, Hanahan and Weinberg [2] proposed two new hallmarks:
  7. Abnormal metabolic pathways.
  8. Evading the immune system.

The goal of this paper is to suggest strongly that these eight features, as diverse as they may appear, may have a common cause, a decreased oxidative phosphorylation [4].

In the early 1920’s Otto Warburg had demonstrated a unique feature of cancer cells, namely an increased uptake of glucose and secretion of lactic acid by cancer cells, even in the presence of oxygen. This aerobic fermentation is the signature of cancer. Warburg also noticed a concomitant decreased number of mitochondria (grana) [4].The goal of this paper is to link the Warburg‘s effect with some of the hallmarks of cancer (See figure 1).

 

1) Decrease energy yield of the cancer cells and compensatory fermentation

 

pite increased glucose uptake, there is a 50% drop in ATP level in human colon cancer cells compared to adjacent benign cells [5]. This decrease in ATP is a consequence of impairment of the oxidative phosphorylation [4,6]. In normal, differentiated cells, the yield of a molecule of glucose is 34 ATP. In cells with functional mitochondria, this energy is derived mostly from oxidative phosphorylation were approximately 88% of total cellular energy is produced [7,8].The other approximate 12% of energy is produced about equally from substrate level phosphorylation through glycolysis in the cytoplasm and the TCA cycle in the mitochondrial matrix [7,8].

This yield drops to 2 ATP when the mitochondrion is turned off (anaerobic glycolysis).To compensate for the decreased energy yield, the cell increases the glucose uptake [7,9]. A consequence of the decreased activity of the mitochondrion is an increased secretion of lactic acid and an activation of the pentose phosphate pathway (PPP).

The activation of the Pentose Phosphate Pathway results from an increase in glucose uptake with a concomitant obstacle downstream of the pentose phosphate shunt, most probably at the level of the pyruvate dehydrogenase[7]and/or of the pyruvate kinase[10]. The increased flux in the pentose phosphate pathway results in:

  • A shift toward anabolism due to increased synthesis of NADPH that plays a crucial role in NDPH/NADP+ ratio that determines the redox state of the cell via removal of reactive oxygen species (ROS) and so prevents the cellular death, and so it controls the cellular fate[11–13].
  • The shift toward the pentose pathway also results in the production of ribose-5-phosphate, required for the synthesis of nucleic acids [14].

2) Oncogenes and carcinogens increase the Warburg’s effect

 

When Rous discovered that a virus could transmit cancer, one may have thought that cancer was a viral disease [4,9]. It appeared later that the virus had only transmitted a gene (Src), encoding a non-receptor tyrosine kinase, captured by the virus from a previous host. When it was found that the captured and then retransmitted gene could cause cancer, like many other cellular genes (proto- oncogenes), only because they were up-regulated, one may have thought that cancer was a genetic disease, linked to the oncogenic cellular concept.

However, the Src gene; like all the later discovered oncogenes encode proteins associated with signaling routes, regulating specific metabolic pathways[7]. Since then, some thirty different oncogenes all target and stimulate the anabolic pathways [7].

However, as Warburg wrote in 1956 [4,15], “The chicken Rous sarcoma, which is labeled today as a virus tumor, ferments glucose, and lives as a partial anaerobe like all tumors.” In 2000, Reshkin et al. did transfect the Human Papilloma Virus (HPV) to normal cells, and they found that those cells did overexpress the NHE1 protein which was accompanied by intracellular alkalinity which was first even of malignant transformation [16] while intracellular alkalinity does invest on Warburg Effect [17]

Carcinogenesis, whether arising from viral infection, oncogene activation or chemical agent, produces similar impairment in respiratory enzyme activity and mitochondrial function [8,18,19]. Thus, viruses can potentially cause cancer through displacement of respiration with substrate level phosphorylation in the infected cells [7,8,18,20].

Infection by an oncogenic virus or exposure to a carcinogen inhibits the mitochondria and causes the Warburg’s effect[21–25]. This Warburg’s effect is responsible for the activation of the Pentose phosphate pathway and subsequent anabolism [6,9,20].

As stated by Seyfried [20],” any unspecific condition that damages a cell’s respiratory capacity but is not severe enough to kill the cell can potentially initiate the path to cancer [26]. Some of the many unspecific conditions that can diminish a cell’s respiratory capacity thus initiating carcinogenesis include inflammation, carcinogens, radiation, intermittent hypoxia, rare germline mutations, viral infections, and age”[26].

3) The Warburg’s effect explains intracellular alkalosis and cell proliferation

 

The inhibition of the oxidative phosphorylation results in the activation of the anabolic pathway such as the pentose phosphate pathway that is necessary for DNA and RNA synthesis [27]. It reduces NADP+ into NADPH required for lipid synthesis and membrane elongation. The decreased mitochondrial activity has a second consequence: cytoplasm alkalinization because of decreased CO2 secretion [28].

Deregulated pH is emerging as another hallmark of cancer because tumors show a ‘reversed’ pH gradient with a constitutively increased intracellular pH that is higher than the extracellular pH. This gradient enables cancer progression by promoting proliferation, the evasion of apoptosis, metabolic adaptation, migration, and invasion [29–32].

Most research has focused on the extracellular acidosis. It is caused by massive lactic acid extrusion and activity of at least two carbonic anhydrases which hydrate CO2 to bicarbonate (shuttled back to the cytosol through NBCs, AEs, etc.) and protons (which remain in the extracellular space) [33]. There is evidence that an acidic extracellular pH promotes invasiveness and metastatic behavior in several tumor models [34–36], proteolytic enzyme activation and matrix destruction [37,38]. Interference with pH regulation in tumors was proposed as an anticancer strategy with at least a Mab and one small molecule sulfonamide (SLC-0111) in clinical trials for the treatment of metastatic solid tumors [39,40].

In normal cells, the intracellular pH oscillates during the cell cycle between 6.8 and 7.3 [41]. The pH is maximum (7.3) before mitosis and decreases to a minimum at S phase (6.8). The oscillation of the pH during the cell cycle matches the value of the decompaction of the histones, the RNA polymerase activation, the DNA polymerase activation and the DNA compaction before mitosis. The main reason for this oscillation is ATP hydrolysis [42] and the subsequent release of proton ions. This oscillation is buffered by several mechanisms such as the Na+/H+ exchanger (NHE-1), the carbonic anhydrases, the proton-linked monocarboxylate transporter, the Cl/HCO3exchangers [35,36,42–50]. The increased activity of these transporters buffers the change of pH caused mostly by ATP synthesis and hydrolysis [36].

The intracellular pH of the cancer cells has been less studied. During the cell cycle, it oscillates between 7.2 and 7.5.  Intracellular alkalosis is probably a consequence of the decreased oxidative phosphorylation and a decreased secretion of CO2. Carbon dioxide reacts with water to create carbonic acid.Cell transformation or enhanced cancer cell division and resistance to chemotherapy are associated with a more alkaline pH [47–51].

Several effective cancer treatments decrease the intracellular pH. There is extensive literature on increased survival support for the combined use of antacids (which prevent the extrusion proton from the tumor cells) with standard chemotherapy [46,49,52]. Hyperthermia [53] decreases the intracellular pH. Chemotherapy and radiation therapy result in decreased ATP/ADP ratio and intracellular acidification [49,52].

The calorie restricted ketogenic diet [26] will reduce the availability of glucose, the principal metabolite for glycolysis and the PPP. It results in increased level of acidic ketone bodies that cannot be metabolized by the cancer cells (to the difference of normal cells) and probably decrease the intracellular pH. Similarly, acid diet, in general, exogenous lactate, regresses tumor growth [54]. Exogenous lactate leads to spontaneous regression of cancer [55], one of the possible explanation is that lactate might prevent further efflux of the intracellularly produced lactate; therefore lactate will accumulate intracellularly that push the reversible reaction towards formation of TCA. In other words, based on the reversible reaction kinetics, the exogenous lactate might force the activation of mitochondrial respiration.

4) Warburg’s effect is consistent with explaining the increasing pressure and the invasion of surrounding tissue

 

The word “cancer” comes from the Greek word carcinos (crab). Unlike benign tumors, cancer is harder and irregular. It has a stellar, fractal shape and Cancer invades the surrounding tissue.

In the confined environment of an organ, anabolic growth of cancer cells results in increased pressure [9,56–59]. This increased pressure results in the invasion of surrounding tissues, destruction of blood vessels and distant metastasis [9,56–59].

During a liver biopsy, Coldwell [56] measured the interstitial pressure of the normal hepatic parenchyma, as well as cirrhosis and liver cancer with a needle, advanced to the tumor under CT guidance. The pressure was then obtained when the needle entered the periphery of the tumor. The pressure measured by biopsy demonstrates that the pressure in the normal liver parenchyma is 4 mm Hg. The pressure increases to between 16 and 25 in liver tumors (either primary or metastatic). This increased pressure in the tumor explains the peculiar drainage. The tumors are fed by the hepatic artery and not from the portal vein as the rest of the liver parenchyma. The intra-arterial pressure being 137 mm Hg, it is markedly higher than the mean portal pressure: 4 mm Hg. Only the arterial flow and not the portal flow can reach the liver tumor [56].

Normal cells and especially epithelial cells are organized along a structural axis [57], which allows for cell adhesion to the mesenchyme on one side and the epithelium function on the lumen side [60]. Cancer cells have decreased levels of cadherins and annexins resulting in the loss of cell polarity. They can change plane and thus, escape the physical constraints [57]. Cancer cells can diffuse in areas of lesser physical constraints and invade soft tissue. Cancer cells, unlike normal cells, escape the physical constraints [58,59].

The stellar shape of cancer, such as seen on mammography, can only be explained by increased pressure and the loss of cell polarity [57].

5) Impact of the Warburg’s effect and subsequent increased pressure on the surrounding normal cells and immune response

 

Inflammation is characterized by tumor, dolor, rubor, and color, as stated by Galen two thousand years ago. Inflammation can be caused by factors as diverse as heat, freezing temperature, trauma or various chemicals [61,62].

Inflammation is a key risk factor for cancer [63]. For example, a virus, alcoholic liver disease, antitrypsin deficiency, hemochromatosis, and tyrosinemia [64] or a direct trauma all can cause hepatitis. Cirrhosis is the complication of untreated hepatitis. Liver cancer is frequently associated with such pre-existing inflammation and fibrosis. Between 60% and 90% of hepatocellular carcinoma occurs in patients with hepatic macronodular cirrhosis[7,56,63].

When a foreign body, such as a splinter, is inserted into the epidermis, there is no inflammation. When this splinter reaches the dermis where the capillaries lay, there is inflammation. Vascular leakage is a common feature of inflammation. It can be caused by direct damage, resulting from a foreign body, burn or necrosis. Whatever the reason for the leakage may be, this results in the leakage of red blood cells, leukocytes, and plasmatic proteins. These proteins will, in turn, be broken down into smaller pieces by the metabolic enzymes. This partial digestion will release a larger amount of osmoles, further increasing the extracellular osmolarity [61,62,65].

Similarly, a high concentration of protein occurs in ascites during inflammation, such as tuberculosis or pancreatitis [7,61,65–71]. The same goes for pericarditis [67,68], atherosclerosis, arthritis or asthma and pneumonia [66–71]. Whenever inflammation occurs, there appears to be an increase of protein in the extracellular space.

The increased pressure induces the secretion of proteases, growth factors, and growth factor receptors. It results in oncogene activation and shifts the cellular metabolism toward anabolism [61,65,72,73].

Anabolism occurs in cancer, just like in inflammation. But, unlike inflammation, cancer also involves neoangiogenesis[7]. Cancer development leads to the formation of an extensive network of new blood vessels. The growth is promoted by growth factors such as VEGF, which in turn is a possible consequence of increased osmolarity[74]. Unlike normal blood angiogenesis during embryogenesis[75], these blood vessels are leaky and hence increase the osmotic pressure as well as the harshness of the tumor. Also, these vessels are synthesized by incorporation of normal endothelial cell with malignant cells « tumor blood vessels mosaicism » [76,77] The increased pressure has an impact on the surrounding normal cells (stroma). It is responsible for extracellular matrix deposition and fibroblast proliferation [74,75,78].

Increased pressure controls the NF-KB activity through the methylation of PP2A [61,67]. More specifically, NF-KB controls the transcription of cytokines and genes that regulate cellular differentiation, survival, and proliferation, thereby controlling various aspects of innate and adaptive immune responses [79]. Increased pressure is responsible for chemokine-cytokine secretion thus contributing to the immune response of cancer [79]. The half-life of monocytes exposed to hyperosmolarity (as seen in the tumor interstitial fluid) doubled the half-life of monocytes and macrophages [61,67].

The secretion of lactic acid results in an extracellular acidicpH.Investigations on polymorphonuclear leukocytes demonstrate mainly inhibition of chemotaxis, respiratory activity, and bactericidal capacity at reduced pH. Evidence of impaired lymphocyte cytotoxicity and proliferation at acidic pH is also beginning to emerge [80–82].

6) Progressive decreasing oxidative phosphorylation might explain why cancer growth is nonlinear

 

Cancer often arises from the transformation of a benign disease such as polyps. It can also start as a low-grade disease such as chronic myeloid leukemia or a low-grade glioma to a more aggressive acute leukemia or a glioblastoma. These more aggressive cancers have a higher glucose uptake such as seen on PET scan[7,83–85].It is probable that this change in pattern is linked to a decreased mitochondrial activity.

Cytotoxic chemotherapy also influences human cancer growth. Cytotoxic drugs have been selected “in vivo” to kill cancer cells. The antineoplastic drugs are capable of generating a variety of free radical species in subcellular systems, and this capacity has been considered critical for its antitumor action [86–88].

Chemotherapy has had tremendous benefits for pediatric or Hodgkin’s patients. However, for most solid tumors, there is a sizable response rate (complete and partial regression) but limited gain in survival.

At the time of failure of chemotherapy, there is a sharply increased glucose uptake such as seen on PET scan [83]. Resistance to chemotherapy has been correlated with decreased oxidative phosphorylation[7,87–89]and alkaline pH [55].

Cytotoxic drugs injure or even destroy the mitochondria [90,91]. The oxidative phosphorylation is further reduced; the pH is more alkaline, and the PPP is activated. Cancer grows unrelentlessly, and further chemotherapy is usually ineffective[55].

Elliott analyzed, using an electron microscope, the presence of mitochondria in 346 human breast cancer samples. The mitochondria were present in low-grade cancer but spare or absent in the most aggressive tumors [85].

It is probable that this change of behavior from slow-growing, low-grade to high-grade cancer or from cancer that is inhibited by chemotherapy to resistant to cytotoxic drugs is the consequence of increased oxidative phosphorylation.

Mitochondria are fragile. Decrease in ATP result in further mitochondrial damages. The decrease concentration of ATP (4) may result in further damage and swelling of the mitochondria [91,92]. The mitochondria increase in size and the cristae disappear[93–95].

7) Metabolic rewiring: the combination of alpha- lipoïc acid and hydroxycitrate slows cancer growth, whatever the primary site

 

The decrease in concentration of ATP can be the consequence of decreased availability of acetyl-CoA to the mitochondria and the subsequent rewiring of the metabolic fluxes upstream of the mitochondria [6,9].

Michelakis [96] reported that dichloroacetate (DCA), an inhibitor of pyruvate dehydrogenase kinase, resulted in the activation of the mitochondria [64], in vitro and tumor regression in three out of five patients with glioblastoma.

The most likely mechanism of action for α-lipoic acid for its inhibition of tumor growth is the inhibition of pyruvate dehydrogenase kinase (the same target that DCA). This enzyme inhibits the activity of pyruvate dehydrogenase and is known to be up-regulated in cancer cells expressing the aerobic glycolytic phenotype. Pyruvate dehydrogenase (PDH) catalyzes the conversion of pyruvate to acetyl-CoA, the initial step of the ultimate conversion of glucose to carbon dioxide and water, with the concomitant production of ATP, in the TCA cycle. Therefore, it is reasonable to suggest that blocking the activity of pyruvate dehydrogenase kinase will at least partially restore the activity of pyruvate dehydrogenase, thereby increasing the flux of pyruvate through the TCA cycle in the mitochondria, while simultaneously reducing the production of lactic acid and most importantly decreasing the flux in the pentose pathway shunt[64].

A combination of alpha lipoïc acid and hydroxycitrate (an inhibitor of the citrate lyase) [64,97–99] has been reported to slow cancer growth, in murine xenografts. This inhibition appears to be universal (i.e. independent of the primary site) and has been reproduced in different laboratories. Similar data have been obtained with CPI 613 a novel alpha lipoïc acid analog [100]

The first patient diagnosed with a large peritoneal metastasis of a colon carcinoma survived five years after a treatment combining chemotherapy with hydroxycitrate and alpha lipoïc acid [101,102]. 

Starting January 2013, compassionate metabolic treatment (alpha lipoic acid hydroxycitrate and low dose Naltrexone) was offered to patients sent home after the failure of conventional cytotoxic chemotherapy for metastatic cancer (whatever the primary site) but with a Karnovsky status above 70. Of the first unselected eleven patients, five are alive and reasonably well 30 months after the start of treatment [102]. The second group of patients, having failed first and second line chemotherapy were treated with metabolic treatment and conventional chemotherapy. Survival at one year was 70% [102–104].

These results are in line with recent molecular biology experiments. The introduction of normal mitochondria into cancer cells restore mitochondrial function and inhibit cancer cell growth, and reverse chemoresistance [105–107]. The fusion of cancer cells with normal mitochondria results in increased ATP synthesis, oxygen consumption, and respiratory chain activities [63], marked decrease in cancer growth, resistance to the anti-cancer drug, invasion, and colony formation in soft agar, and « in vivo » tumor growth in nude mice [5,106].

Conclusion:

 

Today, cancer is thought to be a set of very complex diseases with thousands of different mutations. That apparent complexity has led to personalized medicine. The fact that the combination of alpha lipoïc acid and hydroxycitrate slows down cancer growth in every tumor model suggests that at least some targets are the same in a large spectrum of tumors.

“Cancer, above all other diseases, has countless secondary causes. But, even for cancer, there is only one prime cause. Summarized in a few words, the prime cause of cancer is the replacement of the respiration of oxygen in normal body cells by a fermentation of sugar. All normal body cells meet their energy needs by respiration of oxygen, whereas cancer cells meet their energy needs in great part by fermentation. All normal body cells are thus obligate aerobes, whereas all cancer cells are partial anaerobes [18,108].”

To decrease anabolism, glucose uptake should be reduced, and the oxidative phosphorylation should be restored.

 

Declarations

Authors’ Contribution:

LS conceived the study and drafted and LS KO and CS designed the manuscript. All authors read and approved the final manuscript.

Conflict of Interest statement:

The authors declare that they have no competing interests.

 

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Figure and Legend:

 Figure1: show the possible correlation between Warburg Effect and Hallmarks of Cancer

Figure 2: Shows the chemical structure of α-lipoic acid

Figure 2: Shows the chemical structure of Hydroxycitric acid