AI Article Synopsis
- The chapter discusses tumour hypoxia as a newly recognized hallmark of cancer, detailing its various classifications based on aetiology, exposure time, and intensity levels in tumours.
- It highlights the dual role of hypoxia in cancer, where it can lead to tumour regression (through processes like apoptosis) or promote adaptive progression, suggesting a complex relationship with cancer development.
- Key advancements in understanding hypoxia are attributed to techniques like polarographic pO microsensors for assessing oxygen levels and the discovery of hypoxia-inducible factors (HIFs), which impact cancer progression on genetic and protein levels and hinder treatment effectiveness.
Article Abstract
On the occasion of ISOTT's half-century, in this chapter, tumour hypoxia (i.e. critically reduced oxygen levels on macro- and microscopic scales), recently classified as an additional hallmark of cancer, its various aetiology-related classifications (diffusion- or perfusion-limitations, hypoxaemic), time-frames of exposure (acute, chronic, cyclic), and different levels (moderate, mild, severe) within and across tumours, and its Janus-face-like role ("dichotomy") in tumour regression (e.g. apoptosis, necrosis) versus "adaptive" tumour progression have been updated and summarised. This latter knowledge is, to a great extent, based on (a) direct, reliable assessments and mapping of the heterogeneous tumour oxygenation status using minimally invasive polarographic pO microsensors in clinical settings since the late 1980s, and (b) the discovery of the hypoxia-inducible factors (HIFs) in the early 1990s. These data have clarified the role of hypoxia in stimulating a variety of biologic responses that mediate cancer progression through changes (a) in the genome (associated with clonal selection and expansion), (b) in the transcriptome, and (c) in the proteome, as well as its role as a barrier to the effectiveness of anti-cancer therapies.
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| http://dx.doi.org/10.1007/978-3-031-67458-7_3 | DOI Listing |
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