Browse Articles

Amino acids are required for cell survival and growth. However, the different requirements of amino acid metabolic pathways in normal haematopoiesis and leukaemogenesis have not been explored. Here the authors focus on the transporter of neutral amino acids and show that malignant blood cells rely more on ASCT2-mediated amino acid metabolism than normal cells.

The oxidative pentose-phosphate pathway (oxPPP) is a major NADPH producer. Here the authors show that malic enzyme or isocitrate dehydrogenase can support the growth of cells lacking the oxPPP, but the oxPPP is necessary to maintain a normal NADPH/NADP ratio, DHFR activity and folate metabolism.

The protein kinase complex mechanistic target of rapamycin complex 1 (mTORC1) is a key cellular nutrient and energy sensor that integrates several inputs to regulate cell growth. Here, the authors discuss the molecular logic of the mTORC1 signalling network and its importance in coupling growth signals to the control of cellular metabolism.

Activation of tissue-resident myeloid cells in the brain, known as microglia, is thought to drive obesity-associated hypothalamic dysfunction. The authors of this Perspective present a more nuanced view of microglia, echoing lessons learned from the field of adipose macrophage biology: instead of simply responding to diet-induced damage, microglia are proposed to act as nutrient and environmental sensors that regulate hypothalamic physiology, a role that, if hijacked by chronic overnutrition, can produce disease.

Obesity is associated with an increased risk of colitis-associated cancer (CAC). Here Ostermann et al. show that a high-fat diet induces insulin resistance in intestinal epithelial cells (IECs) and that genetic inactivation of insulin and IGF1 signalling in IECs impairs intestinal regeneration and enhances tumour formation in a CAC mouse model.

Patients with severe diabetes rely on insulin injections to control their blood glucose. A study now provides evidence that human cells that normally do not release insulin can be converted into insulin-producing cells that are able to normalize glycaemia in diabetic mice.

The senescence-associated secretory phenotype (SASP) is responsible for the deleterious effects of senescent cells in ageing and cancer. A new study shows that NAD⁺ metabolism can regulate the pro-inflammatory SASP, thereby promoting tumorigenesis.

AMPK is a master regulator of cellular metabolism. Here the authors show that a constitutively active AMPK mutation protects mice fed a high-fat diet from obesity by increasing energy expenditure in subcutaneous white adipocytes, possibly as a result of the emergence of a hitherto-unknown type of adipocyte.

Creatine can be used for thermogenesis in adipocytes. Here Kazak et al. show that creatine uptake is required to sustain this thermogenic pathway. Knockdown of the creatine transporter, CrT, in adipocytes decreases thermogenesis and energy expenditure, whereas creatine supplementation increases energy expenditure in mice fed a high-fat diet.

A new study in C. elegans identifies a microRNA-dependent mechanism that enables olfactory neurons to rapidly regulate protein degradation in the intestine and therefore organismal ageing.

Olfactory food perception is known to extend lifespan in C. elegans. Here the authors demonstrate food-odour-dependent brain-to-gut communication that extends lifespan in worms. Food odour downregulates tir-1 mRNA in AWC neurons, in a manner dependent on the miRNA miR-71, which triggers downstream effects in the gut, due to neuropeptide secretion, that promote proteostasis and longevity.

Like stem cells, cancer cells can rapidly proliferate but, unlike stem cells, they are mostly locked into a malignant identity. Here, Finley and Intlekofer highlight commonalities in anabolic pathways that support proliferation in cancer and stem cells, and point out unique metabolic features that influence self-renewal and differentiation.

Many beneficial effects of exercise are mediated by factors secreted from the exercising muscle, so-called myokines. Here, the authors identify what might be the first exercised-induced adipokine, TGF-β2, which is secreted from subcutaneous fat in response to exercise-induced increases in serum lactate levels and has beneficial metabolic effects in mice.

Neurons and astrocytes cooperate metabolically but differ in key aspects of their metabolism, including the production of mitochondrial reactive oxygen species (ROS). Here, the authors show that mitochondrial ROS produced in astrocytes affect neuronal metabolism and mouse memory and behaviour.

Hypothalamic neuronal diversity is at the core of whole-body energy-homeostasis control, but the molecular mechanisms governing neuronal neuropeptide specification remain incompletely understood. A new study in Nature Metabolism adds a relevant piece to the puzzle of how key hypothalamic neuronal populations maintain their peptidergic identity throughout the lifespan.

Hypothalamic melanocortin neurons control energy homoeostasis by modulating appetite. Here, the authors reveal a role for the transcription factor Tbx3 as a regulator of the peptidergic identity and function of immature and mature mouse melanocortin neurons.

The circulatory system in long bones is incompletely understood. A new study published in Nature Metabolism unveils the presence of dense vascular networks in long bones that facilitate the egress of bone marrow cells and potentially the exchange of nutrients between the bone marrow and the systemic circulation.

Bone marrow-derived cells can rapidly enter the systemic circulation, but how this is achieved is unclear. Grüneboom et al. identify tiny capillaries, termed trans-cortical vessels (TCVs), that connect the bone marrow cavity to the systemic vasculature, and show that the majority of blood in long bones passes through TCVs.