Intrinsic bioenergetic adaptations compensate for reduced mitochondrial content in HER2-driven mammary tumors

  1. Sara M Frangos
  2. Henver S Brunetta
  3. Dongdong Wang
  4. Maria Joy Therese Jabile
  5. David WL Ma
  6. William J Muller
  7. Cezar M Khursigara
  8. Kelsey H Fisher-Wellman
  9. Gregory R Steinberg
  10. Graham P Holloway

  • Curated by eLife

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    eLife Assessment

    This useful study uses the MMTV-Neu-YD5 mouse model for HER2-dependent breast cancer to generate transcriptomic and proteomic datasets from extracted primary tumour samples. The data sets generated appear to be solid and will be of interest to the community. However, mechanistic studies to support the conclusion that mitochondrial function is increased in the tumours remain incomplete and would benefit from experiments that would directly interrogate aspects such as cellular heterogeneity, and signalling.

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Abstract

It is now recognized that mitochondria play a crucial role in tumorigenesis, however, it has become clear that tumor metabolism varies significantly between cancer types. The failure of recent clinical trials attempting to directly target tumor respiration with inhibitors of oxidative phosphorylation has highlighted the critical need for additional studies comprehensively assessing mitochondrial bioenergetics. Therefore, we systematically assessed the bulk tumor and mitochondrial metabolic phenotype between murine HER2-driven mammary cancer tumors and paired benign mammary tissue. Transcriptomic and proteomic profiling revealed that HER2-driven mammary tumors are characterized by a downregulation of mitochondrial genes/proteins compared to benign mammary tissue, including a general downregulation of OXPHOS subunits comprising Complexes I-IV. Despite this observation, mitochondrial respiration supported by both carbohydrate-derived substrates (pyruvate) and lipids (palmitoyl-carnitine) was several-fold higher in HER2-driven tumors which persisted regardless of normalization method (i.e. wet weight, total protein content and when corrected for mitochondrial content). This upregulated respiratory capacity could not be explained by OXPHOS uncoupling; however, several subunits/regulators of Complex V function were not downregulated in the tumors, suggesting possible compensatory effects may contribute to high respiratory rates. Furthermore, tumor mitochondria displayed a smaller and more punctate morphology, aligning with a general reduction in mitochondrial fusion and increase in mitochondrial fission markers, which could contribute to improved OXPHOS efficiency. Together, this data highlights that the typical correlation of mitochondrial content and respiratory capacity may not apply to all tumor types and implicates the activation of mitochondrial respiration supporting tumorigenesis in this model.

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  1. Version published to 10.7554/elife.104079.1 on eLife
  2. Version published to 10.7554/elife.104079 on eLife
  3. eLife

    eLife Assessment

    This useful study uses the MMTV-Neu-YD5 mouse model for HER2-dependent breast cancer to generate transcriptomic and proteomic datasets from extracted primary tumour samples. The data sets generated appear to be solid and will be of interest to the community. However, mechanistic studies to support the conclusion that mitochondrial function is increased in the tumours remain incomplete and would benefit from experiments that would directly interrogate aspects such as cellular heterogeneity, and signalling.

  4. eLife

    Reviewer #1 (Public review):

    Summary:

    In this manuscript, Frangos et al. used a transcriptomic and proteomic approach to characterise changes in HER2-driven mammary tumours compared to healthy mammary tissue in mice. They observed that mitochondrial genes, including OXPHOS regulators, were among the most down-regulated genes and proteins in their datasets. Surprisingly, these were associated with higher mitochondrial respiration, in response to a variety of carbon sources. In addition, there seems to be a reduction in mitochondrial fusion and an increase in fission in tumours compared to healthy tissues.

    Strengths:

    The data are clearly presented and described.

    The author reported very similar trends in proteomic and transcriptomic data. Such approaches are essential to have a better understanding of the changes in cancer cell metabolism associated with tumourigenesis

    Weaknesses:

    This study, despite being a useful resource (assuming all the data will be publicly available and not only upon request) is mainly descriptive and correlative and lacks mechanistic links.

    It would be important to determine the cellular composition of the tumour and healthy tissue used. Do the changes described here apply to cancer cells only or do other cell types contribute to this?

    Are the changes in metabolic gene expression a consequence of HER2 signalling activation? Ex-vivo experiments could be performed to perturb this pathway and determine cause-effects.

    The data of fission/fusion seem quite preliminary and the gene/protein expression changes are not so clear cut to be a convincing explanation that this is the main reason for the increased mitochondria respiration in tumours.

  5. eLife

    Reviewer #2 (Public review):

    Frangos et al present a set of studies aiming to determine mechanisms underlying initiation and tumour progression. Overall, this work provides some useful insights into the involvement of mitochondrial dysfunction during the cellular transformation process. This body of work could be improved in several possible directions to establish more mechanistic connections.

    (1) The interesting point of the paper: the contrast between suppressed ETC components and activated OXPHOS function is perplexing and should be resolved. It is still unclear if activated mitochondrial function triggers gene down-regulation vs compensatory functional changes (as the title suggests). Have the authors considered reversing the HER2-derived signals e.g. with PI3K-AKT-MTOR or ERK inhibitors to potentially separate the expression vs. functional phenotypes? The root of the OXPHOS component down-regulation should also be traced further, e.g. by probing into levels of core mitochondrial biogenesis factors. Are transcript levels of factors encoded by mtDNA also decreased?

    (2) The second interesting aspect of this study is the implication of mitochondrial activation in tumours, despite the downregulation of expression signatures, suggestive of a positive role for mitochondria in this tumour model. To address if this is correlative or causal, have the authors considered testing an OXPHOS inhibitor for suppression of tumorigenesis?

    (3) A number of issues concerning animal/ tumour variability and further pathway dissection could be explored with in vitro approaches. Have the authors considered deriving tumour-derived cell cultures, which could enable further confirmations, mechanistic drug studies and additional imaging approaches? Culture systems would allow alternative assessment of mitochondrial function such as Seahorse or flow cytometry (mitochondrial potential and ROS levels).

    (4) The study could be greatly improved with further confirmatory studies, eg immunoblotting for mitochondrial components with parallel blots for phospho-signalling in the same samples. It would be interesting if trends could be maintained in tumour-derived cell cultures. It is notable that OXPHOS protein/transcript changes are more consistent (Figure 5, Supplementary Figure 4) than mitochondrial dynamics /mitophagy factors (Figure 8). Core regulatory factors in these pathways should be confirmed by conventional immunoblotting.

  6. Version published to 10.1101/2024.11.03.621754v1 on bioRxiv