Adult sleep GWAS-derived polygenic scores demonstrated comparable associations with corresponding sleep phenotypes in Adolescents, suggesting genetic influences on sleep persist across developmental stages.

Question Do genetic variants that are associated with adult sleep/circadian phenotypes influence sleep phenotypes in adolescents?

Findings In a population-based birth cohort study (N = 3903), genetic influences on all adult sleep phenotypes (sleep duration, insomnia, daytime sleepiness, napping, and chronotype as indexed by polygenic scores derived from adult genome-wide association studies) were associated with their corresponding sleep/circadian phenotypes in adolescents aged 15 years.

Meaning Genetic variants identified in adult genome-wide association studies may also be relevant to a variety of sleep phenotypes in adolescence, suggesting that these variants index sleep phenotypes during a key developmental stage in which sleep disturbances typically emerge.

Cancer development results from the selection of cells with mutation(s) that provide survival and proliferative advantages. Normal barriers to proliferation are overcome as clones adapt to an ever changing hostile microenvironment, where low oxygen tension, low glucose levels, and an acidic extracellular pH (all of which increase genetic instability) are found. The hypoxia inducible factors, HIF-1 and HIF-2, are upregulated in response to these conditions. This could occur by constitutive activation of PI3K signaling or inactivating mutations in, for example, the von Hippel–Lindau tumor suppressor, VHL [35-37], which normally deacetylates HIF-1α, leading to HIF-1α polyubiquitination and proteasomal degradation [38]. HIFs trans activate genes mediating proliferation, angiogenesis, intermediate metabolism (glycolysis) and pH regulation, which promote tumor development [39].

HIF-1α stimulates production of growth factors, such as transforming growth factor β (TGF-β), insulin-like growth factor 2, interleukin-6 (IL-6), interleukin-8, macrophage migration inhibitory factor (MIF), and growth factor receptors, such as the epidermal growth factor receptor (EGFR), resulting in continuous proliferative signaling. In the hypoxic environment, constitutive activation of these signaling pathways (e.g., Ras [1] and PI3K [2]) stabilizes HIF-1 and may result in “oncogene addiction” that persists through the transition from adenoma to carcinoma. In the case of PI3K, constitutive activation may result from the appearance of mutations in tumor suppressor genes (e.g., the phosphatase and tensin homolog [PTEN]), from activating mutations in the PI3K complex itself, or from aberrant signaling in receptor tyrosine kinases [40].

A single genetic “switch” may be the secret to how the body’s cleanup crew grows up and keeps our organs running smoothly.

Scientists at the University of Liège have identified a crucial genetic regulator that allows macrophages to fully mature and help maintain healthy organs. This regulator, known as MafB, acts as a “molecular switch” that turns specific genes on or off at the right time and in the right cells.

By carefully controlling this genetic activity, MafB enables the development of macrophages that defend the body and support normal organ function. When MafB is missing, macrophages do not work as they should and lose their ability to carry out their protective duties.

A single genetic “switch” may be the secret to how the body’s cleanup crew grows up and keeps our organs running smoothly.

“Monogenic” diseases, triggered by mutations in just one gene, may actually be more complex than scientists thought.