One of the most rapidly advancing areas in neuroscience is the detection of nutrients. This has been assisted greatly by the de-orphaning of receptors, and the study of their function by disabling or deleting their expression. Progress in understanding nutrient detection by the tongue, in the form of taste, has translated quickly into studies of similar processes in the gut epithelium. Articles covering different nutrients and other ingested compounds, mechanisms of sensory transduction and neural/behavioral responses to exogenous toxins and pathogens are all encouraged. There are different viewpoints on chemosensory mechanisms in the gut lumen, and commentary and discussion of these is most welcome.

The University of Melbourne

Queen Mary University of London

Frontiers in Neuroscience

Autonomic Neuroscience

Frontiers in Physiology

Frontiers in Neurology

Sensing of luminal nutrients and toxins

Alpha7 nicotinic receptors (a7nAChR) are widely distributed throughout the central nervous system (CNS) and are found at particularly high levels in the hippocampus and cortex. Several lines of evidence indicate that pharmacological enhancement of a7nAChRs function could be a potential therapeutic route to alleviate disease-related cognitive deficits. A recent pharmacological approach adopted to increase a7nAChR activity has been to identify selective positive allosteric modulators (PAMs). a7nAChR PAMs have been divided into two classes: type I PAMs increase agonist potency with only subtle effects on kinetics, whereas type II agents produce additional dramatic effects on desensitization and deactivation kinetics. Here we report novel observations concerning the pharmacology of the canonical type II PAM, PNU120596. Using patch clamp analysis of acetylcholine (ACh)-mediated currents through recombinant rat a7nAChR we show that positive allosteric modulation measured in two different ways is greatly attenuated when the temperature is raised to near physiological levels. Furthermore, PNU120596 largely removes the strong inward rectification usually exhibited by a7nAChR-mediated responses.

Obesity, characterised by excessive fat accumulation, is a complex chronic condition that results from dysfunctional adipose tissue expansion due to prolonged calorie surplus. This leads to rapid adipocyte enlargement that exceeds the support capacity of the surrounding neurovascular network, resulting in increased hypoxia, inflammation, and insulin resistance. Intermittent fasting (IF), a dietary regimen that cycles between periods of fasting and eating, has emerged as an effective strategy to combat obesity and improve metabolic homeostasis by promoting healthy adipose tissue remodeling. However, the precise molecular and cellular mechanisms behind the metabolic improvements and remodeling of white adipose tissue (WAT) driven by IF remain elusive. This review aims to summarise and discuss the relationship between IF and adipose tissue remodeling and explore the potential mechanisms through which IF induces alterations in WAT. This includes several key structural changes, including angiogenesis and sympathetic innervation of WAT. We will also discuss the involvement of key signalling pathways, such as PI3K, SIRT, mTOR, and AMPK, which potentially play a crucial role in IF-mediated metabolic adaptations.