Throughout evolution, humans have lived in synchrony with the natural light-dark cycle. Our bodies were used to going to sleep a few hours after dark, and waking up just before dawn. However, in... Show moreThroughout evolution, humans have lived in synchrony with the natural light-dark cycle. Our bodies were used to going to sleep a few hours after dark, and waking up just before dawn. However, in modern society the unambiguous availability of artificial light has desynchronized our biological clock from the naturally occurring day and night, with large consequences for metabolic health. This thesis sheds light on the negative health consequences of a disturbed biological clock, and elucidates novel approaches to prevent disease associated with chronic rhythm disruption, as occurs in shift work. We have identified important mechanisms through which rhythm disruption contributes to (cardio)metabolic disease, namely by exacerbating vascular inflammation and by deregulating rhythm in glucocorticoid hormone, thereby affecting the metabolic activity of tissues such as brown fat and bone. We continued by investigating two main approaches to prevent diseases associated with circadian disturbances: (1) by limiting disruption of the circadian timing system, and (2) by directly targeting the affected tissues. We found that timed feeding (1) and stimulation of the metabolic activity of brown fat (2) are both promising strategies to prevent and/or reduce (cardio)metabolic disease risk in the ever-increasing population of individuals who suffer from circadian disturbances. Show less
MHC class I antigen-presentation plays a pivotal role in anti-tumor immunity. High surface expression of MHC-I molecules is generally correlated with high CD8 T cell infiltrate and improved overall... Show moreMHC class I antigen-presentation plays a pivotal role in anti-tumor immunity. High surface expression of MHC-I molecules is generally correlated with high CD8 T cell infiltrate and improved overall survival in many cancers. In contrast, partial or complete loss of MHC-I surface expression is associated with reduced survival and primary-resistance to immunotherapy in cancers. Expression of additional molecules in the tumor microenvironment (TME), such as PD-L1 and HLA-E, further shape immune responses. The presence of immune cells and the expression of immune-related genes together determine the ‘immune landscape’ of cancers, while the local production of interferons strongly impacts this environment. Although MHC-I and PD-L1 are both regulated by the IFN pathway, an in-depth study on immune escape of NSCLC showed that the expression of co-inhibitory markers and the loss of MHC-I expression are two independent mechanisms of immune evasion. This classifies tumors into different “types” depending on their MHC-I and PD-L1 expression. The differential expression of MHC-I and PD-L1 suggests that immune-escape of cancer cells occurs through a multitude of distinct “hard-wired” and “soft-wired” modifications and knowing which of the mechanisms underlie immune escape determines which immunotherapeutic strategy has the most potential for clinical success. Show less