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Comprehensive Physiology Dec 2017Triglyceride molecules represent the major form of storage and transport of fatty acids within cells and in the plasma. The liver is the central organ for fatty acid... (Review)
Review
Triglyceride molecules represent the major form of storage and transport of fatty acids within cells and in the plasma. The liver is the central organ for fatty acid metabolism. Fatty acids accrue in liver by hepatocellular uptake from the plasma and by de novo biosynthesis. Fatty acids are eliminated by oxidation within the cell or by secretion into the plasma within triglyceride-rich very low-density lipoproteins. Notwithstanding high fluxes through these pathways, under normal circumstances the liver stores only small amounts of fatty acids as triglycerides. In the setting of overnutrition and obesity, hepatic fatty acid metabolism is altered, commonly leading to the accumulation of triglycerides within hepatocytes, and to a clinical condition known as nonalcoholic fatty liver disease (NAFLD). In this review, we describe the current understanding of fatty acid and triglyceride metabolism in the liver and its regulation in health and disease, identifying potential directions for future research. Advances in understanding the molecular mechanisms underlying the hepatic fat accumulation are critical to the development of targeted therapies for NAFLD. © 2018 American Physiological Society. Compr Physiol 8:1-22, 2018.
Topics: Biological Transport; Fatty Acids; Humans; Lipid Metabolism; Lipogenesis; Lipolysis; Liver; Non-alcoholic Fatty Liver Disease; Triglycerides
PubMed: 29357123
DOI: 10.1002/cphy.c170012 -
Seminars in Nephrology Jul 2019Although students initially learn of ionic buffering in basic chemistry, buffering and acid-base transport in biology often is relegated to specialized classes,... (Review)
Review
Although students initially learn of ionic buffering in basic chemistry, buffering and acid-base transport in biology often is relegated to specialized classes, discussions, or situations. That said, for physiology, nephrology, pulmonology, and anesthesiology, these basic principles often are critically important for mechanistic understanding, medical treatments, and assessing therapy effectiveness. This short introductory perspective focuses on basic chemistry and transport of buffers and acid-base equivalents, provides an outline of basic science acid-base concepts, tools used to monitor intracellular pH, model cellular responses to pH buffer changes, and the more recent development and use of genetically encoded pH-indicators. Examples of newer genetically encoded pH-indicators (pHerry and pHire) are provided, and their use for in vitro, ex vivo, and in vivo experiments are described. The continued use and development of these basic tools provide increasing opportunities for both basic and potentially clinical investigations.
Topics: Acid-Base Equilibrium; Animals; Biological Transport; Buffers; Humans; Hydrogen; Hydrogen-Ion Concentration; Intracellular Fluid
PubMed: 31300088
DOI: 10.1016/j.semnephrol.2019.04.002 -
Brain Research Aug 2022The blood-brain barrier (BBB) is a dynamic structure that protects the brain from harmful blood-borne, endogenous and exogenous substances and maintains the homeostatic... (Review)
Review
The blood-brain barrier (BBB) is a dynamic structure that protects the brain from harmful blood-borne, endogenous and exogenous substances and maintains the homeostatic microenvironment. All constituent cell types play indispensable roles in the BBB's integrity, and other structural BBB components, such as tight junction proteins, adherens junctions, and junctional proteins, can control the barrier permeability. Regarding the need to exchange nutrients and toxic materials, solute carriers, ATP-binding case families, and ion transporter, as well as transcytosis regulate the influx and efflux transport, while the difference in localisation and expression can contribute to functional differences in transport properties. Numerous chemical mediators and other factors such as non-physicochemical factors have been identified to alter BBB permeability by mediating the structural components and barrier function, because of the close relationship with inflammation. In this review, we highlight recently gained mechanistic insights into the maintenance and disruption of the BBB. A better understanding of the factors influencing BBB permeability could contribute to supporting promising potential therapeutic targets for protecting the BBB and the delivery of central nervous system drugs via BBB permeability interventions under pathological conditions.
Topics: Biological Transport; Blood-Brain Barrier; Brain; Humans; Permeability; Tight Junction Proteins; Tight Junctions
PubMed: 35568085
DOI: 10.1016/j.brainres.2022.147937 -
Nature Reviews. Molecular Cell Biology Jul 2023To coordinate, adapt and respond to biological signals, cells convey specific messages to other cells. An important aspect of cell-cell communication involves secretion... (Review)
Review
To coordinate, adapt and respond to biological signals, cells convey specific messages to other cells. An important aspect of cell-cell communication involves secretion of molecules into the extracellular space. How these molecules are selected for secretion has been a fundamental question in the membrane trafficking field for decades. Recently, extracellular vesicles (EVs) have been recognized as key players in intercellular communication, carrying not only membrane proteins and lipids but also RNAs, cytosolic proteins and other signalling molecules to recipient cells. To communicate the right message, it is essential to sort cargoes into EVs in a regulated and context-specific manner. In recent years, a wealth of lipidomic, proteomic and RNA sequencing studies have revealed that EV cargo composition differs depending upon the donor cell type, metabolic cues and disease states. Analyses of distinct cargo 'fingerprints' have uncovered mechanistic linkages between the activation of specific molecular pathways and cargo sorting. In addition, cell biology studies are beginning to reveal novel biogenesis mechanisms regulated by cellular context. Here, we review context-specific mechanisms of EV biogenesis and cargo sorting, focusing on how cell signalling and cell state influence which cellular components are ultimately targeted to EVs.
Topics: Proteomics; Biological Transport; Extracellular Vesicles; Protein Transport; Signal Transduction; Cell Communication
PubMed: 36765164
DOI: 10.1038/s41580-023-00576-0 -
Annual Review of Cell and Developmental... Oct 2019The vertebrate vasculature displays high organotypic specialization, with the structure and function of blood vessels catering to the specific needs of each tissue. A... (Review)
Review
The vertebrate vasculature displays high organotypic specialization, with the structure and function of blood vessels catering to the specific needs of each tissue. A unique feature of the central nervous system (CNS) vasculature is the blood-brain barrier (BBB). The BBB regulates substance influx and efflux to maintain a homeostatic environment for proper brain function. Here, we review the development and cell biology of the BBB, focusing on the cellular and molecular regulation of barrier formation and the maintenance of the BBB through adulthood. We summarize unique features of CNS endothelial cells and highlight recent progress in and general principles of barrier regulation. Finally, we illustrate why a mechanistic understanding of the development and maintenance of the BBB could provide novel therapeutic opportunities for CNS drug delivery.
Topics: Animals; Astrocytes; Basement Membrane; Biological Transport; Blood-Brain Barrier; Brain; Central Nervous System; Endothelial Cells; Homeostasis; Humans; Leukocytes; Neurovascular Coupling; Pericytes; Tight Junctions; Transcytosis; Wnt Signaling Pathway
PubMed: 31299172
DOI: 10.1146/annurev-cellbio-100617-062608 -
Physiological Reviews Oct 2015Aquaporins are membrane channels that facilitate the transport of water and small neutral molecules across biological membranes of most living organisms. In plants,... (Review)
Review
Aquaporins are membrane channels that facilitate the transport of water and small neutral molecules across biological membranes of most living organisms. In plants, aquaporins occur as multiple isoforms reflecting a high diversity of cellular localizations, transport selectivity, and regulation properties. Plant aquaporins are localized in the plasma membrane, endoplasmic reticulum, vacuoles, plastids and, in some species, in membrane compartments interacting with symbiotic organisms. Plant aquaporins can transport various physiological substrates in addition to water. Of particular relevance for plants is the transport of dissolved gases such as carbon dioxide and ammonia or metalloids such as boron and silicon. Structure-function studies are developed to address the molecular and cellular mechanisms of plant aquaporin gating and subcellular trafficking. Phosphorylation plays a central role in these two processes. These mechanisms allow aquaporin regulation in response to signaling intermediates such as cytosolic pH and calcium, and reactive oxygen species. Combined genetic and physiological approaches are now integrating this knowledge, showing that aquaporins play key roles in hydraulic regulation in roots and leaves, during drought but also in response to stimuli as diverse as flooding, nutrient availability, temperature, or light. A general hydraulic control of plant tissue expansion by aquaporins is emerging, and their role in key developmental processes (seed germination, emergence of lateral roots) has been established. Plants with genetically altered aquaporin functions are now tested for their ability to improve plant tolerance to stresses. In conclusion, research on aquaporins delineates ever expanding fields in plant integrative biology thereby establishing their crucial role in plants.
Topics: Animals; Aquaporins; Biological Transport; Humans; Hydrogen-Ion Concentration; Plants; Stress, Physiological
PubMed: 26336033
DOI: 10.1152/physrev.00008.2015 -
Neuron Aug 2015Microtubules are one of the major cytoskeletal components of neurons, essential for many fundamental cellular and developmental processes, such as neuronal migration,... (Review)
Review
Microtubules are one of the major cytoskeletal components of neurons, essential for many fundamental cellular and developmental processes, such as neuronal migration, polarity, and differentiation. Microtubules have been regarded as critical structures for stable neuronal morphology because they serve as tracks for long-distance transport, provide dynamic and mechanical functions, and control local signaling events. Establishment and maintenance of the neuronal microtubule architecture requires tight control over different dynamic parameters, such as microtubule number, length, distribution, orientations, and bundling. Recent genetic studies have identified mutations in a wide variety of tubulin isotypes and microtubule-related proteins in many of the major neurodevelopmental and neurodegenerative diseases. Here, we highlight the functions of the neuronal microtubule cytoskeleton, its architecture, and the way its organization and dynamics are shaped by microtubule-related proteins.
Topics: Animals; Biological Transport; Cell Differentiation; Cytoskeleton; Humans; Microtubules; Neurons
PubMed: 26247859
DOI: 10.1016/j.neuron.2015.05.046 -
The Journal of Experimental Medicine Apr 2020The blood vessels vascularizing the central nervous system exhibit a series of distinct properties that tightly control the movement of ions, molecules, and cells... (Review)
Review
The blood vessels vascularizing the central nervous system exhibit a series of distinct properties that tightly control the movement of ions, molecules, and cells between the blood and the parenchyma. This "blood-brain barrier" is initiated during angiogenesis via signals from the surrounding neural environment, and its integrity remains vital for homeostasis and neural protection throughout life. Blood-brain barrier dysfunction contributes to pathology in a range of neurological conditions including multiple sclerosis, stroke, and epilepsy, and has also been implicated in neurodegenerative diseases such as Alzheimer's disease. This review will discuss current knowledge and key unanswered questions regarding the blood-brain barrier in health and disease.
Topics: Animals; Biological Transport; Blood-Brain Barrier; Central Nervous System; Humans
PubMed: 32211826
DOI: 10.1084/jem.20190062 -
Current Biology : CB Apr 2018A fundamental hallmark of eukaryotic cells is their compartmentalization into functionally distinct organelles, including those of the secretory and endocytic pathways.... (Review)
Review
A fundamental hallmark of eukaryotic cells is their compartmentalization into functionally distinct organelles, including those of the secretory and endocytic pathways. Transport of cargo between these compartments and to/from the cell surface is mediated by membrane-bound vesicles and tubules. Delivery of cargo is facilitated by SNARE (soluble N-ethylmaleimide-sensitive factor attachment protein receptor)-mediated membrane fusion of vesicles with their target compartments. Vesicles contain a variety of cargos, including lipids, membrane proteins, signaling molecules, biosynthetic and hydrolytic enzymes, and the trafficking machinery itself. Proper function of membrane trafficking is required for cellular growth, division, movement, and cell-cell communication. Defects in these processes have been implicated in a variety of human diseases, such as cancer, diabetes, neurodegenerative disorders, ciliopathies, and infections. The elucidation of the mechanisms of SNARE assembly and disassembly is key to understanding how membrane fusion is regulated throughout eukaryotes. Here, we introduce the SNARE proteins, their structures and functions in eukaryotic cells, and discuss recent breakthroughs in elucidating the regulation of SNARE assembly and disassembly through the use of high-resolution structural biology and biophysical techniques.
Topics: Animals; Biological Transport; Cell Membrane; Humans; Membrane Fusion; Protein Binding; Protein Transport; SNARE Proteins
PubMed: 29689222
DOI: 10.1016/j.cub.2018.01.005 -
Frontiers in Bioscience (Landmark... Jan 2023Fatty acids (FAs) are critical nutrients that regulate an organism's health and development in mammal. Long-chain fatty acids (LCFAs) can be divided into saturated and... (Review)
Review
Fatty acids (FAs) are critical nutrients that regulate an organism's health and development in mammal. Long-chain fatty acids (LCFAs) can be divided into saturated and unsaturated fatty acids, depending on whether the carbon chain contains at least 1 double bond. The fatty acids that are required for humans and animals are obtained primarily from dietary sources, and LCFAs are absorbed from outside of cells in mammals. LCFAs enter cells through several mechanisms, including passive diffusion and protein-mediated translocation across the plasma membrane, the latter in which FA translocase (FAT/CD36), plasma membrane FA-binding protein (FABPpm), FA transport protein (FATP), and caveolin-1 are believed to have important functions. The LCFAs that are taken up by cells bind to FA-binding proteins (FABPs) and are transported to the specific organelles, where they are activated into acyl-CoA to target specific metabolic pathways. LCFA-CoAs can be esterified to phospholipids, triacylglycerol, cholesteryl ester, and other specialized lipids. Non-esterified free fatty acids are preferentially stored as triacylglycerol molecules. The main pathway by which fatty acids are catabolized is β-oxidation, which occurs in mitochondria and peroxisomes. stearoyl-CoA desaturase (SCD)-dependent and Fatty acid desaturases (FADS)-dependent fatty acid desaturation pathways coexist in cells and provide metabolic plasticity. The process of fatty acid elongation occurs by cycling through condensation, reduction, dehydration, and reduction. Extracellular LCFA can be mediated by membrane protein G protein-coupled receptor 40 (GPR40) or G protein-coupled receptor 120 (GPR120) to activate mammalian target of rapamycin complex 1 (mTORC1) signaling, and intracellular LCFA's sensor remains to be determined. The crystal structures of a phosphatidic acid phosphatase and a membrane-bound fatty acid elongase-condensing enzyme and other LCFA-related proteins provide important insights into the mechanism of utilization, increasing our understanding of the cellular uptake, metabolism and sensing of LCFAs.
Topics: Animals; Humans; Biological Transport; Cell Membrane; Fatty Acids; Membrane Proteins; Mitochondria; Protein Transport
PubMed: 36722264
DOI: 10.31083/j.fbl2801010