03812oam 2200601 450 991013640440332120230621135826.09782889193448(ebook)(CKB)3710000000612056(oapen)https://directory.doabooks.org/handle/20.500.12854/46349(EXLCZ)99371000000061205620191103h20152015 fy 0engur||#||||||||txtrdacontentcrdamediacrrdacarrierEndoplasmic reticulum - shape and function in stress translation /topic editors, Lorenzo Frigerio, Federica Brandizzi, Stephen H. Howell and Patrick SchäferFrontiers Media SA2015[Lausanne, Switzerland] :Frontiers Media SA,[2015]©20151 online resource (110 pages) illustrations (black and white, and colour); digital file(s)Frontiers Research Topics"Published in: Frontiers in Plant Science" -- front cover.Print version: 2889193446 Includes bibliographical references.The endoplasmic reticulum (ER) is a manufacturing unit in eukaryotic cells required for the synthesis of proteins, lipids, metabolites and hormones. Besides supporting cellular signalling networks by its anabolic function, the ER on its own or in communication with other organelles directly initiates signalling processes of physiological significance. Based on the intimate and immediate involvement in stress signalling the ER is considered as sensory organelle on which cells strongly rely to effectively translate environmental cues into adaptive stress responses. The transcellular distribution of the ER providing comprehensive cell-to-cell connections in multicellular organisms probably allows a concerted action of cell alliances and tissue areas towards environmental constraints. At the cellular level, stress adaptation correlates with the capability of the ER machinery to synthesise proteins participating in stress signalling as well as in the activation of ER membrane localised proteins to start cell-protective signalling processes. Importantly, depending on the stress insult, the ER either supports protective strategies or initiates cell death programmes. Recent, genetic, molecular and cell biological studies have drawn an initial picture of underlying signalling events activated by ER membrane localised proteins. In this Research Topic, we will provide a platform for articles describing research on ER morphology and metabolism with a focus on stress translation. The Research Topic will be sub-divided into the following sections: 1. ER in stress signalling and adaptation; 2. ER structure and biosynthetic functions; 3. Regulation of protein processing; 4. Regulation of programmed cell death.Frontiers research topics.Endoplasmic reticulumBotanyEndoplasmic Reticulum StressMyosinscysteine endopeptidaseER associated degradationUnfolded Protein ResponseER bodiesprogrammed cell deathbZIP transcription factorscaspaseEndoplasmic reticulum.Botany.Endoplasmic Reticulum Stress.EFederica Brandizziauth1366879Schäfer PatrickFrigerio LorenzoBrandizzi FedericaHowell Stephen H(Stephen Herbert),1941-UkMaJRUBOOK9910136404403321Endoplasmic reticulum - shape and function in stress translation3389398UNINA03826nam 2200901z- 450 9910404076003321202102113-03928-737-0(CKB)4100000011302378(oapen)https://directory.doabooks.org/handle/20.500.12854/56379(oapen)doab56379(EXLCZ)99410000001130237820202102d2020 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierPlasma Technology for Biomedical ApplicationsMDPI - Multidisciplinary Digital Publishing Institute20201 online resource (174 p.)3-03928-736-2 There is growing interest in the use of physical plasmas (ionized gases) for biomedical applications, especially in the framework of so-called "plasma medicine", which exploits the action of low-power, atmospheric pressure plasmas for therapeutic purposes. Such plasmas are "cold plasmas", in the sense that only electrons have a high temperature, whereas ions and the neutral gas particles are at or near room temperature. As a consequence, the "plasma flame" can be directly applied to living matter without appreciable thermal load. Reactive chemical species, charged particles, visible and UV radiation, and electric fields are interaction channels of the plasma with pathogens, cells, and tissues, which can trigger a variety of different responses. Possible applications include disinfection, wound healing, cancer treatment, non-thermal blood coagulation, just to mention some. The understanding of the mechanisms of plasma action on living matter requires a strongly interdisciplinary approach, with competencies ranging from plasma physics and technology to chemistry, to biology and finally to medicine. This book is a collection of work that explores recent advances in this field.History of engineering and technologybicsscantimicrobial activityapoptosisatmospheric pressure plasmaatmospheric pressure plasma jet (APPJ)bio-decontaminationbio-targetbiofilmblood coagulationcold argon plasmacold atmospheric plasma (CAP)cold atmospheric plasma jetcold atmospheric plasmasdecontaminationdentistrydevelopmental plasticitydielectric barrier dischargeEscherichia colifear-free dentistryhead and neck squamous cell carcinomainductively-limited dischargeinfectionjet plasmakeratinocyteskINPenlow-current arclymphocytesmacrophagesmetamorphosismitochondrian/anon-thermal plasmaoxygen plasmaplasmaplasma deviceplasma medicineplasma-activated mediumplasma-surface interactionplasma-treated waterreactive oxygen speciesreactive speciesregenerationRONStadpolestap watertissue damagetooth whiteningultrastructurewater treatmentHistory of engineering and technologyMartines Emilioauth1323724BOOK9910404076003321Plasma Technology for Biomedical Applications3035775UNINA