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Recent years have seen spectacular advances in the field of circadian biology. These have attracted the interest of researchers in many fields, including endocrinology, neurosciences, cancer, and behavior. By integrating a circadian view within the fields of endocrinology and metabolism, researchers will be able to reveal many, yet-unsuspected aspects of how organisms cope with changes in the environment and subsequent control of homeostasis. This field is opening new avenues in our understanding of metabolism and endocrinology. A panel of the most distinguished investigators in the field gathered together to discuss the present state and the future of the field. The editors trust that this volume will be of use to those colleagues who will be picking up the challenge to unravel how the circadian clock can be targeted for the future development of specific pharmacological strategies toward a number of pathologies.

Human Physiology, Endocrinology, Cell Biology, Neurosciences

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Ethylene is a simple gaseous phytohormone with multiple roles in regulation of metabolism at cellular, molecular, and whole plant level. It influences performance of plants under optimal and stressful environments by interacting with other signaling molecules. Understanding the ethylene biosynthesis and action through the plant’s life can contribute to improve the knowledge of plant functionality and use of this plant hormone may drive adaptation and defense of plants from the adverse environmental conditions. The action of ethylene depends on its concentration in cell and the sensitivity of plants to the hormone. In recent years, research on ethylene has been focused, due to its dual action, on the regulation of plant processes at physiological and molecular level. The involvement of ethylene in the regulation of transcription needs to be widely explored involving the interaction with other key molecular regulators. The aim of the current research topic was to explore and update our understanding on its regulatory role in plant developmental mechanisms at cellular or whole plant level under optimal and changing environmental conditions. The present edited volume includes original research papers and review articles describing ethylene’s regulatory role in plant development during plant ontogeny and also explains how it interacts with biotic and abiotic stress factors. This comprehensive collection of researches provide evidence that ethylene is essential in different physiological processes and does not always work alone, but in coordinated manner with other plant hormones. This research topic is also a source of tips for further works that should be addressed for the biology and molecular effects on plants.

Ethylene --- Physiology --- Metaboilsm --- Phytohormones --- Signaling molecules --- Tolerance

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The mesothelium is composed by a single layer of mesothelial cells that vest the serosal cavities (pleural, peritoneal and pericardial) and internal organs of the body. The mesothelial cells have a mixed phenotype of epithelial cells and fibroblasts rendering them remarkable plasticity. Besides providing a slippery surface for the frictionless movement of internal organs, the mesothelium participates in a wide range of physiological and pathophysiological processes. Some of its functions include lung development, trans-cellular and para-cellular transport of ions and water, secretion of glycoproteins (mainly hyaluronan), secretion of cytokines and growth factors, wound healing, response to inflammatory stimuli and induction of inflammation, mesothelial to mesenchymal transition and formation of tunneling nanotubes. Many of these functions are pivotal to physiological conditions such as respiratory development, maintenance of steady volume of serosal fluids and serosal permeability, cell-to-cell communication, re-mesotheliazation of serosal membranes after mechanical (e.g. by asbestos or nanoparticles) or inflammatory injury and participation in immune responses. Deviation from the physiological threshold of these functions results in the development of serosal effusions, induction of serosal and lung fibrosis, induction of mesothelial tumorigenesis, leading thus to devastating pathologies. Treatment of pathologies like mesothelioma, pleural and peritoneal fibrosis (in cases of patients under Peritoneal Dialysis) or lung fibrosis still pose a great challenge for researchers.

Mesothelium --- Pleura --- Peritoneum --- Pericardium --- Physiology --- Serosal Membranes

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From the preface: “Critical Care Physiology, as the companion piece to The Michigan Critical Care Handbook…provides the explanations, references, methods, and other supportive information to flesh out the essentials presented in the handbook. Critical Care Physiology is limited to discussion of four organ systems (cardiovascular, respiratory, renal, and neurologic) and four topics in integrative physiology (oxygen kinetics, fluids and electrolytes, host defenses, and metabolism and nutrition).”

Critical care medicine --- Physiology, Pathological --- Critical Care --- Monitoring, Physiologic

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The adrenal gland plays essential roles in the control of body homeostasis, stress and immune responses. The adrenal cortex represents up to 90% of the gland and is specialised in the production of mineralocorticoids, glucocorticoids and adrenal androgens. This production is tightly coordinated and results from a unique zonal organisation. Although our knowledge of the molecular mechanisms controlling adrenal steroidogenesis is quite extensive, for decades, the mechanisms of adrenal cortex development, cellular homeostasis and renewal have remained elusive. The advent of new high-throughput technologies and sophisticated genetic approaches has brought tremendous progress in our understanding of how the adrenal cortex achieves and maintains its particular organisation. The aim of this Frontiers in Endocrinology Topic is to provide readers with a snapshot of our current knowledge on adrenal physiology and how deregulations of these processes result in adrenal diseases. This includes but is not limited to, basic research on adrenal development, cell lineage identification, progenitor cells, tissue renewal, control of differentiation and zonation and clinical research on the identification of disease-related genes.

adrenal --- development --- Physiology --- zonation --- Disease --- Adenoma --- Hyperplasia --- Cancer --- Insufficiency