A new metabolic signature to predict melanoma recurrence

Ngan K. Vu, Rachel J. Perry
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In particular, 50%–75% of melanoma cases metastasize to the brain, accounting for 54% of all melanoma-related deaths.<span><sup>2, 3</sup></span> It is thus critical to diagnose melanoma at earlier stages to limit metastasis and more widespread invasion, allowing for complete surgical removal of the tumour.</p><p>While excision of early-stage melanoma results in a favourable prognosis, recurrence can occur in many of these patients, being responsible for a large proportion of melanoma-related deaths. The mechanisms underlying melanoma recurrence remain incompletely understood. Recent evidence points toward the critical influence of the tumour microenvironment (TME) on melanoma recurrence. The TME is composed of the extracellular matrix, immune cells, mesenchymal cells, and blood vessels that surround the tumour cells, communicating their behaviour and response to treatment. Dissecting the melanoma TME therefore may give rise to diagnostic markers and mechanistic insights into its recurrence patterns, opening avenues for the development of targeted therapies that can lower the risk of melanoma recurrence.</p><p>Recent development in artificial intelligence (AI)-driven histopathology introduces important tools that can be leveraged to investigate the spatial organization and molecular markers in the TME. The application of AI technology has been proven to objectively and consistently produce valuable clinical information that provides molecular markers and predicts cancer outcomes. The utilization of AI in cancer histopathology is not just limited to its predictive and prognostic usage. This technology can be used to profile and map tumour immune cell networks and dissect molecular pathways within the TME, revealing critical mechanistic insights into response to treatments, recurrence patterns, and metastatic potential.</p><p>In a recent study, Szadai et al.<span><sup>4</sup></span> employed AI-powered histopathology and spatial proteomics to explore and compare the tumour cells and TME interplay between recurrent and non-recurrent primary melanoma samples. This AI-driven methodology proved to be effective in distinguishing normal tissue from stromal and tumour regions across both groups. Notably, these authors integrated laser-microdissection technology and quantitative proteomic analysis with digital pathology readouts. This unique approach produced critical spatial proteomics data that sheds light on the molecular interplay between mitochondrial functions and immune response in the tumour and stromal components of recurrent melanoma.</p><p>In particular, Szadai et al. found that tumour cells in recurrent melanoma showed higher expression of components of the DNA synthesis pathway and mitochondrial translation as compared to stromal cells. Vice versa, recurrent melanoma stromal cells displayed higher expression of mediators of the epithelial-mesenchymal transition and programmed death 1 signalling pathways. These findings contrast with the enriched pathways between the tumour and stromal components from non-recurrent melanoma, with higher expression of keratinization and mitophagy pathways in tumour cells and interleukin signalling and collagen degradation in stromal cells. The dichotomous findings between the tumour and stromal compartments suggest that elevated mitochondrial functions in tumour cells may alter the TME toward a pro-recurrent and immune-evasive phenotype. To bolster the evidence of the interplay between mitochondrial activity and immune dysregulation in melanoma recurrence, Szadai et al. compared the proteome differences between recurrent and non-recurrent melanoma in both tumour and stromal compartments. In both cell groups, the recurrent melanoma specimens exhibited an upregulation in mitochondrial pathways and cellular proliferation, while also displaying a downregulation in immune response pathways.</p><p>The findings of Szadai et al. pose yet another paradox to the constitutional Warburg effect theory, positing that glycolytic metabolism is the main driver for cancer cell proliferation and metastasis.<span><sup>5</sup></span> Accumulating evidence suggests that mitochondrial function is essential in all aspects of tumour progression, from cellular growth to immune evasion and invasion.<span><sup>6, 7</sup></span> In the context of melanoma, numerous studies have identified the critical role of oxidative phosphorylation (OxPHOS) in promoting tumour cell proliferation, survival, chemo- and immunotherapy resistance, and metastasis.<span><sup>8</sup></span> These findings allude to the metabolic plasticity of melanoma cells, readily shifting between glycolysis and OxPHOS in response to changes in the TME that include biofuel availability, immune response, and the presence of anti-tumour molecules. Furthermore, mitochondria can be transferred from the stromal cells of the TME to the tumour cells to meet the demand for mitochondrial OxPHOS,<span><sup>9</sup></span> depicting a dynamic landscape of the metabolic interactions between stromal and tumour cells in melanoma. The findings from Szadai et al. thus provide a spatial visualization of this mitochondrial network and open an avenue for the development of therapy pertinent to the molecular pathways involved in melanoma recurrence. Indeed, recent studies have begun to explore the therapeutic potential of mitochondrial targeting agents and uncouplers in treating treatment-naive and resistant melanomas.<span><sup>10</sup></span></p><p>The integration of quantitative proteomics with AI-powered histopathology by Szadai et al. is a unique and powerful tool for spatial analyses of molecular networks in recurrent melanoma and other types of cancer. There are still, however, limitations regarding the incorporation of this methodology with other omics approaches such as genomic and transcriptomic analyses. Indeed, Szadai et al. attempted to assess the protein-level upregulation of the two mitochondrial pathways that are highly associated with lower survival rates at the transcriptomic level. Interestingly, their proteome analysis did not reveal upregulation in these two pathways. This finding suggests a dissociation between transcriptomic and proteomic analysis, thus emphasizing the convention that RNA expression is not equivalent to protein expression and activity. Indeed, multiple post-transcriptional and post-translational modifications can precipitate the disconnect between the two types of omics analyses, adding complexity to deciphering the mechanisms of melanoma recurrence. This underscores the need for a multi-omics approach that integrates spatial proteomics data with other forms of spatial and/or single-cell level omics such as spatial transcriptomics and single-cell RNA sequencing. This multi-level approach can help unravel the convoluted molecular networks pertinent to the recurrence of melanoma across different levels of molecular products and modifications.</p><p>In conclusion, Szadai et al. demonstrated a proof of concept for the combination of AI-driven histopathology and quantitative proteomics to produce a spatial proteomics approach that depicts the interplay between mitochondrial functions and immune evasion in melanoma recurrence. 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引用次数: 0

Abstract

Melanoma is one of the most prevalent cancers in the United States, accounting for 5% of all new cancer cases, and has been increasing worldwide.1 Melanoma arises from the malignant proliferation of melanocytes, cells that produce melanin that provides skin pigmentation. The high metastatic potential of melanoma drastically affects the prognosis of patients diagnosed at later stages. In particular, 50%–75% of melanoma cases metastasize to the brain, accounting for 54% of all melanoma-related deaths.2, 3 It is thus critical to diagnose melanoma at earlier stages to limit metastasis and more widespread invasion, allowing for complete surgical removal of the tumour.

While excision of early-stage melanoma results in a favourable prognosis, recurrence can occur in many of these patients, being responsible for a large proportion of melanoma-related deaths. The mechanisms underlying melanoma recurrence remain incompletely understood. Recent evidence points toward the critical influence of the tumour microenvironment (TME) on melanoma recurrence. The TME is composed of the extracellular matrix, immune cells, mesenchymal cells, and blood vessels that surround the tumour cells, communicating their behaviour and response to treatment. Dissecting the melanoma TME therefore may give rise to diagnostic markers and mechanistic insights into its recurrence patterns, opening avenues for the development of targeted therapies that can lower the risk of melanoma recurrence.

Recent development in artificial intelligence (AI)-driven histopathology introduces important tools that can be leveraged to investigate the spatial organization and molecular markers in the TME. The application of AI technology has been proven to objectively and consistently produce valuable clinical information that provides molecular markers and predicts cancer outcomes. The utilization of AI in cancer histopathology is not just limited to its predictive and prognostic usage. This technology can be used to profile and map tumour immune cell networks and dissect molecular pathways within the TME, revealing critical mechanistic insights into response to treatments, recurrence patterns, and metastatic potential.

In a recent study, Szadai et al.4 employed AI-powered histopathology and spatial proteomics to explore and compare the tumour cells and TME interplay between recurrent and non-recurrent primary melanoma samples. This AI-driven methodology proved to be effective in distinguishing normal tissue from stromal and tumour regions across both groups. Notably, these authors integrated laser-microdissection technology and quantitative proteomic analysis with digital pathology readouts. This unique approach produced critical spatial proteomics data that sheds light on the molecular interplay between mitochondrial functions and immune response in the tumour and stromal components of recurrent melanoma.

In particular, Szadai et al. found that tumour cells in recurrent melanoma showed higher expression of components of the DNA synthesis pathway and mitochondrial translation as compared to stromal cells. Vice versa, recurrent melanoma stromal cells displayed higher expression of mediators of the epithelial-mesenchymal transition and programmed death 1 signalling pathways. These findings contrast with the enriched pathways between the tumour and stromal components from non-recurrent melanoma, with higher expression of keratinization and mitophagy pathways in tumour cells and interleukin signalling and collagen degradation in stromal cells. The dichotomous findings between the tumour and stromal compartments suggest that elevated mitochondrial functions in tumour cells may alter the TME toward a pro-recurrent and immune-evasive phenotype. To bolster the evidence of the interplay between mitochondrial activity and immune dysregulation in melanoma recurrence, Szadai et al. compared the proteome differences between recurrent and non-recurrent melanoma in both tumour and stromal compartments. In both cell groups, the recurrent melanoma specimens exhibited an upregulation in mitochondrial pathways and cellular proliferation, while also displaying a downregulation in immune response pathways.

The findings of Szadai et al. pose yet another paradox to the constitutional Warburg effect theory, positing that glycolytic metabolism is the main driver for cancer cell proliferation and metastasis.5 Accumulating evidence suggests that mitochondrial function is essential in all aspects of tumour progression, from cellular growth to immune evasion and invasion.6, 7 In the context of melanoma, numerous studies have identified the critical role of oxidative phosphorylation (OxPHOS) in promoting tumour cell proliferation, survival, chemo- and immunotherapy resistance, and metastasis.8 These findings allude to the metabolic plasticity of melanoma cells, readily shifting between glycolysis and OxPHOS in response to changes in the TME that include biofuel availability, immune response, and the presence of anti-tumour molecules. Furthermore, mitochondria can be transferred from the stromal cells of the TME to the tumour cells to meet the demand for mitochondrial OxPHOS,9 depicting a dynamic landscape of the metabolic interactions between stromal and tumour cells in melanoma. The findings from Szadai et al. thus provide a spatial visualization of this mitochondrial network and open an avenue for the development of therapy pertinent to the molecular pathways involved in melanoma recurrence. Indeed, recent studies have begun to explore the therapeutic potential of mitochondrial targeting agents and uncouplers in treating treatment-naive and resistant melanomas.10

The integration of quantitative proteomics with AI-powered histopathology by Szadai et al. is a unique and powerful tool for spatial analyses of molecular networks in recurrent melanoma and other types of cancer. There are still, however, limitations regarding the incorporation of this methodology with other omics approaches such as genomic and transcriptomic analyses. Indeed, Szadai et al. attempted to assess the protein-level upregulation of the two mitochondrial pathways that are highly associated with lower survival rates at the transcriptomic level. Interestingly, their proteome analysis did not reveal upregulation in these two pathways. This finding suggests a dissociation between transcriptomic and proteomic analysis, thus emphasizing the convention that RNA expression is not equivalent to protein expression and activity. Indeed, multiple post-transcriptional and post-translational modifications can precipitate the disconnect between the two types of omics analyses, adding complexity to deciphering the mechanisms of melanoma recurrence. This underscores the need for a multi-omics approach that integrates spatial proteomics data with other forms of spatial and/or single-cell level omics such as spatial transcriptomics and single-cell RNA sequencing. This multi-level approach can help unravel the convoluted molecular networks pertinent to the recurrence of melanoma across different levels of molecular products and modifications.

In conclusion, Szadai et al. demonstrated a proof of concept for the combination of AI-driven histopathology and quantitative proteomics to produce a spatial proteomics approach that depicts the interplay between mitochondrial functions and immune evasion in melanoma recurrence. Future applications of this methodology can be integrated with other high-powered omics tools to dissect these molecular networks in melanoma and other cancer types, allowing for risk stratification of disease recurrence and metastasis and the development of more effective targeted therapies.

N.K.V. and R.J.P. drafted and edited the piece.

Not Applicable

预测黑色素瘤复发的新代谢特征
黑色素瘤是美国发病率最高的癌症之一,占所有新发癌症病例的 5%,并且在全球范围内呈上升趋势。1 黑色素瘤是由黑色素细胞恶性增殖引起的,黑色素细胞产生黑色素,从而形成皮肤色素沉着。1 黑色素瘤是由黑色素细胞恶性增生引起的,黑色素细胞产生的黑色素可提供皮肤色素。黑色素瘤的高转移潜力严重影响晚期确诊患者的预后。尤其是,50%-75%的黑色素瘤病例会转移到脑部,占黑色素瘤相关死亡病例总数的54%。2, 3 因此,在早期阶段诊断黑色素瘤以限制转移和更广泛的侵袭至关重要,这样才能通过手术彻底切除肿瘤。虽然切除早期黑色素瘤会带来良好的预后,但许多患者会出现复发,这也是黑色素瘤相关死亡病例的主要原因。人们对黑色素瘤复发的机制仍不完全清楚。最近的证据表明,肿瘤微环境(TME)对黑色素瘤复发有着至关重要的影响。肿瘤微环境由围绕肿瘤细胞的细胞外基质、免疫细胞、间充质细胞和血管组成,影响着肿瘤细胞的行为和对治疗的反应。人工智能(AI)驱动的组织病理学的最新发展引入了一些重要工具,可用于研究TME的空间组织和分子标记。事实证明,应用人工智能技术可以客观、持续地生成有价值的临床信息,提供分子标记并预测癌症结果。人工智能在癌症组织病理学中的应用不仅限于预测和预后。在最近的一项研究中,Szadai 等人4 利用人工智能驱动的组织病理学和空间蛋白质组学来探索和比较复发性和非复发性原发性黑色素瘤样本之间的肿瘤细胞和组织病理学之间的相互作用。事实证明,这种人工智能驱动的方法能有效区分两组样本中的正常组织、基质和肿瘤区域。值得注意的是,这些作者将激光微切片技术和定量蛋白质组分析与数字病理学读数结合在一起。Szadai 等人特别发现,与基质细胞相比,复发性黑色素瘤的肿瘤细胞在 DNA 合成途径和线粒体翻译方面的表达更高。反之亦然,复发性黑色素瘤基质细胞在上皮-间质转化和程序性死亡 1 信号通路介质中的表达更高。这些发现与非复发性黑色素瘤的肿瘤和基质成分之间的丰富通路形成了鲜明对比,肿瘤细胞中角质化和有丝分裂通路的表达较高,而基质细胞中白细胞介素信号和胶原降解的表达较高。肿瘤和基质之间的二分法研究结果表明,肿瘤细胞中线粒体功能的升高可能会改变TME,使其向有利于复发和免疫侵袭的表型发展。为了进一步证明黑色素瘤复发过程中线粒体活性和免疫失调之间的相互作用,Szadai 等人比较了复发和非复发黑色素瘤在肿瘤和基质两部分蛋白质组的差异。在这两组细胞中,复发性黑色素瘤标本的线粒体通路和细胞增殖都出现了上调,同时免疫反应通路也出现了下调。Szadai 等人的研究结果为沃堡效应理论提出了另一个悖论,该理论认为糖代谢是癌细胞增殖和转移的主要驱动力。越来越多的证据表明,线粒体功能在肿瘤进展的各个方面都至关重要,从细胞生长到免疫逃避和侵袭都是如此。6, 7 在黑色素瘤方面,大量研究发现氧化磷酸化(OxPHOS)在促进肿瘤细胞增殖、存活、化疗和免疫疗法抗性以及转移方面起着关键作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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