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Difference between revisions of "Amoedo 2013 Abstract MiP2013"

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{{Abstract
{{Abstract
|title=Amoêdo ND, Rodrigues M, Pereira S, Melo F, Jasiulionis M, Galina A, Rumjanek F(2013) Comparative biochemistry of tumorigenesis: role of mitochondria in the metastatic process. Mitochondrial Physiology Network 18.08.
|title=Amoêdo ND, Rodrigues M, Pereira S, Melo F, Jasiulionis M, Galina A, Rumjanek FD(2013) Comparative biochemistry of tumorigenesis: role of mitochondria in the metastatic process. Mitochondrial Physiology Network 18.08.
|authors=Amoedo ND, Rodrigues M, Pereira S, Melo F, Jasiulionis M, Galina A, Rumjanek F
|authors=Amoedo ND, Rodrigues M, Pereira S, Melo F, Jasiulionis M, Galina A, Rumjanek FD
|year=2013
|year=2013
|event=MiP2013
|event=MiP2013

Revision as of 18:27, 6 July 2013

Amoêdo ND, Rodrigues M, Pereira S, Melo F, Jasiulionis M, Galina A, Rumjanek FD(2013) Comparative biochemistry of tumorigenesis: role of mitochondria in the metastatic process. Mitochondrial Physiology Network 18.08.

Link:

Amoedo ND, Rodrigues M, Pereira S, Melo F, Jasiulionis M, Galina A, Rumjanek FD (2013)

Event: MiP2013

The classic bioenergetic phenotype of cancer cells of enhanced glycolysis was described by Otto Warburg approximately 90 years ago. However, the Warburg hypothesis does not necessarily imply mitochondrial dysfunction. Current thinking envisages tumor cells as compliant to an oxygen gradient within the tumor mass. Those cells on the periphery utilize oxygen whereas those found in hypoxic regions display metabolic symbiosis with the adjacent stromal cells [1]. Essentially metabolic reprograming means up-regulation of pathways that increase the rate of ATP production, synthesis of lipids and redox balance. The process of carcinogenesis is guided by gene expression regulation that promote these metabolic changes in a different and complex way for each cancer cell, thus, the energy metabolism of cancer cells is very heterogeneous. For example, not all tumor cells display a high glycolytic flux as proposed by Warburg. Progression to metastasis appears to require mitochondrial function, a hypothesis that is compatible with the results obtained by our group.

In order to show this we resorted an experimental model of murine melanoma cells. A melanocyte cell line was subjected to several cycles of adhesion impediment, producing stable cell lines exhibiting phenotypes representing a progression from non-tumorigenic to metastatic cells. These were: non-tumorigenic cells melan-a (ma); non-tumorigenic cell line 4C (obtained after 4 cycles of adherence abrogation); non-metastatic 4C11- and metastatic 4C11+ melanoma cell lines. The metabolic profile of each of these different cell lines was investigated by evaluating enzyme activities and expression of members of the glycolytic and oxidative pathways [2].

Our results showed that only metastatic cell line (4C11+) released the highest amounts of lactate and exhibited high LDH activity related to glutamine catabolism. In contrast, high-resolution respirometry (HRR) showed that 4C11+ intact cells had increased (2.8-fold) oxidative metabolism, with enhanced (2.6-fold) oxygen flux coupled to ATP synthesis when compared to the other pre-malignant stages. Moreover, in 4C11+ cells, we observed an increase in succinate dehydrogenase (Complex II) activity confirmed by HRR in permeabilized cells. We did not observe an increase in mitochondrial content, mitochondrial biogenesis, but we observed an increase (2-fold) in fission process. These results suggest enhanced OXPHOS. This was thought to be associated to metastasis, a condition which would benefit from unrestricted supply of oxygen.

Detailed analysis of patterns in this and other models of tumor progression may reveal whether the modulation of the oxidative metabolism is a feature of the metastatic process. To test this hypothesis we produced 4C11+ Rho 0 cells. Preliminary results showed a decreased in proliferation.


Labels:

Stress:Cancer; Apoptosis; Cytochrome c"Cancer; Apoptosis; Cytochrome c" is not in the list (Cell death, Cryopreservation, Ischemia-reperfusion, Permeability transition, Oxidative stress;RONS, Temperature, Hypoxia, Mitochondrial disease) of allowed values for the "Stress" property. 


Preparation: Intact Cell; Cultured; Primary"Intact Cell; Cultured; Primary" is not in the list (Intact organism, Intact organ, Permeabilized cells, Permeabilized tissue, Homogenate, Isolated mitochondria, SMP, Chloroplasts, Enzyme, Oxidase;biochemical oxidation, ...) of allowed values for the "Preparation" property., Permeabilized cells  Enzyme: Complex II; Succinate Dehydrogenase"Complex II; Succinate Dehydrogenase" is not in the list (Adenine nucleotide translocase, Complex I, Complex II;succinate dehydrogenase, Complex III, Complex IV;cytochrome c oxidase, Complex V;ATP synthase, Inner mt-membrane transporter, Marker enzyme, Supercomplex, TCA cycle and matrix dehydrogenases, ...) of allowed values for the "Enzyme" property.  Regulation: Mitochondrial Biogenesis; Mitochondrial Density"Mitochondrial Biogenesis; Mitochondrial Density" is not in the list (Aerobic glycolysis, ADP, ATP, ATP production, AMP, Calcium, Coupling efficiency;uncoupling, Cyt c, Flux control, Inhibitor, ...) of allowed values for the "Respiration and regulation" property., Aerobic and Anaerobic Metabolism"Aerobic and Anaerobic Metabolism" is not in the list (Aerobic glycolysis, ADP, ATP, ATP production, AMP, Calcium, Coupling efficiency;uncoupling, Cyt c, Flux control, Inhibitor, ...) of allowed values for the "Respiration and regulation" property.  Coupling state: OXPHOS 

HRR: Oxygraph-2k 

Melanocyte 


Affiliations and author contributions

1 - Instituto de Bioquímica Médica, Universidade Federal do Rio de Janeiro, Brazil; 2 - Dept de Farmacologia, Universidade Federal de São Paulo, Brazil.


Email: amoedo@bioqmed.ufrj.br


References

  1. Sotgia F, Whitaker-Menezes D, Martinez-Outschoorn UE, Flomenberg N, Birbe RC, Witkiewicz AK, Howell A, Philp NJ, Pestell RG, Lisanti MP (2012) Mitochondrial metabolism in cancer metastasis: visualizing tumor cell mitochondria and the "reverse Warburg effect" in positive lymph node tissue. Cell Cycle 11: 1445-1454.
  1. Oba-Shinjo SM, Correa M, Ricca TI, Molognoni F, Pinhal MA, Neves IA, Marie SK, Sampaio LO, Nader HB, Chammas R, Jasiulionis MG (2006) Melanocyte transformation associated with substrate adhesion impediment. Neoplasia 8: 231-241.