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Theranostics 2021As extracellular vesicles secreted by cells, exosomes are intercellular signalosomes for cell communication and pharmacological effectors. Because of their special... (Review)
Review
As extracellular vesicles secreted by cells, exosomes are intercellular signalosomes for cell communication and pharmacological effectors. Because of their special properties, including low toxicity and immunogenicity, biodegradability, ability to encapsulate endogenous biologically active molecules and cross the blood-brain barrier (BBB), exosomes have great therapeutic potential in cerebrovascular and neurodegenerative diseases. However, the poor targeting ability of natural exosomes greatly reduces the therapeutic effect. Using engineering technology, exosomes can obtain active targeting ability to accumulate in specific cell types and tissues by attaching targeting units to the membrane surface or loading them into cavities. In this review, we outline the improved targeting functions of bioengineered exosomes, tracing and imaging techniques, administration methods, internalization in the BBB, and therapeutic effects of exosomes in cerebrovascular and neurodegenerative diseases and further evaluate the clinical opportunities and challenges in this research field.
Topics: Animals; Bioengineering; Biological Transport; Blood-Brain Barrier; Cell Communication; Cerebrovascular Disorders; Drug Delivery Systems; Exosomes; Extracellular Vesicles; Humans; Neurodegenerative Diseases; Protein Engineering; Secretory Vesicles
PubMed: 34522219
DOI: 10.7150/thno.62330 -
Annual Review of Microbiology 2010Gram-negative bacteria produce outer membrane vesicles (OMVs) that contain biologically active proteins and perform diverse biological processes. Unlike other secretion... (Review)
Review
Gram-negative bacteria produce outer membrane vesicles (OMVs) that contain biologically active proteins and perform diverse biological processes. Unlike other secretion mechanisms, OMVs enable bacteria to secrete insoluble molecules in addition to and in complex with soluble material. OMVs allow enzymes to reach distant targets in a concentrated, protected, and targeted form. OMVs also play roles in bacterial survival: Their production is a bacterial stress response and important for nutrient acquisition, biofilm development, and pathogenesis. Key characteristics of OMV biogenesis include outward bulging of areas lacking membrane-peptidoglycan bonds, the capacity to upregulate vesicle production without also losing outer membrane integrity, enrichment or exclusion of certain proteins and lipids, and membrane fission without direct energy from ATP/GTP hydrolysis. Comparisons of similar budding mechanisms from diverse biological domains have provided new insight into evaluating mechanisms for outer membrane vesiculation.
Topics: Bacterial Proteins; Cell Membrane; Gram-Negative Bacteria; Secretory Vesicles
PubMed: 20825345
DOI: 10.1146/annurev.micro.091208.073413 -
Journal of Neurochemistry Jun 2016Regulated exocytosis is a multistage process involving a merger between the vesicle and the plasma membrane, leading to the formation of a fusion pore, a channel,... (Review)
Review
Regulated exocytosis is a multistage process involving a merger between the vesicle and the plasma membrane, leading to the formation of a fusion pore, a channel, through which secretions are released from the vesicle to the cell exterior. A stimulus may influence the pore by either dilating it completely (full-fusion exocytosis) or mediating a reversible closure (transient exocytosis). In neurons, these transitions are short-lived and not accessible for experimentation. However, in some neuroendocrine cells and astrocytes, initial fusion pores may reopen several hundred times, indicating their stability. Frequently, these pores are too narrow to pass luminal molecules to the extracellular space (unproductive exocytosis), but their diameter can dilate upon stimulation. To explain the stability of the initial narrow fusion pores, anisotropic membrane constituents with a non-axisymmetric shape were proposed to accumulate in the fusion pore membrane. Although the nature of these is unclear, they may consist of lipids and proteins, including SNAREs, which may facilitate and regulate the pre- and post-fusional stages of exocytosis. This review highlights models and experimental studies revealing mechanisms of fusion pore stabilization in a narrow, release unproductive state. The fusion pore is a channel that forms when the vesicle and the plasma membranes merge, and mediates the release of secretions from the vesicle lumen to the cell exterior. Frequently, these pores are too narrow to pass molecules to the extracellular space. Anisotropic membrane constituents with a non-axisymmetric shape were proposed to accumulate in the fusion pore membrane. This article is part of a mini review series on Chromaffin cells (ISCCB Meeting, 2015).
Topics: Animals; Calcium; Cell Membrane; Exocytosis; Humans; Hyperpolarization-Activated Cyclic Nucleotide-Gated Channels; Membrane Fusion; Secretory Vesicles
PubMed: 26841731
DOI: 10.1111/jnc.13561 -
Cells Jun 2020Cellular secretion depends on exocytosis of secretory vesicles and discharge of vesicle contents. Actin and myosin are essential for pre-fusion and post-fusion stages of... (Review)
Review
Cellular secretion depends on exocytosis of secretory vesicles and discharge of vesicle contents. Actin and myosin are essential for pre-fusion and post-fusion stages of exocytosis. Secretory vesicles depend on actin for transport to and attachment at the cell cortex during the pre-fusion phase. Actin coats on fused vesicles contribute to stabilization of large vesicles, active vesicle contraction and/or retrieval of excess membrane during the post-fusion phase. Myosin molecular motors complement the role of actin. Myosin V is required for vesicle trafficking and attachment to cortical actin. Myosin I and II members engage in local remodeling of cortical actin to allow vesicles to get access to the plasma membrane for membrane fusion. Myosins stabilize open fusion pores and contribute to anchoring and contraction of actin coats to facilitate vesicle content release. Actin and myosin function in secretion is regulated by a plethora of interacting regulatory lipids and proteins. Some of these processes have been first described in non-neuronal cells and reflect adaptations to exocytosis of large secretory vesicles and/or secretion of bulky vesicle cargoes. Here we collate the current knowledge and highlight the role of actomyosin during distinct phases of exocytosis in an attempt to identify unifying molecular mechanisms in non-neuronal secretory cells.
Topics: Actin Cytoskeleton; Actins; Animals; Exocytosis; Humans; Membrane Fusion; Myosins; Secretory Vesicles
PubMed: 32545391
DOI: 10.3390/cells9061455 -
Biochimica Et Biophysica Acta.... Dec 2020
Topics: Amino Acid Transport Systems; Animals; Humans; Lysosomes; Membrane Transport Proteins; Organelles; Secretory Vesicles
PubMed: 32861642
DOI: 10.1016/j.bbamem.2020.183458 -
Journal of Cell Science Apr 2017Real-time imaging of regulated exocytosis in secreting organs can provide unprecedented temporal and spatial detail. Here, we highlight recent advances in 3D time-lapse... (Review)
Review
Real-time imaging of regulated exocytosis in secreting organs can provide unprecedented temporal and spatial detail. Here, we highlight recent advances in 3D time-lapse imaging in salivary glands at single-granule resolution. Using fluorescently labeled proteins expressed in the fly, it is now possible to image the dynamics of vesicle biogenesis and the cytoskeletal factors involved in secretion. 3D imaging over time allows one to visualize and define the temporal sequence of events, including clearance of cortical actin, fusion pore formation, mixing of the vesicular and plasma membranes and recruitment of components of the cytoskeleton. We will also discuss the genetic tools available in the fly that allow one to interrogate the essential factors involved in secretory vesicle formation, cargo secretion and the ultimate integration of the vesicular and plasma membranes. We argue that the combination of high-resolution real-time imaging and powerful genetics provides a platform to investigate the role of any factor in regulated secretion.
Topics: Animals; Cytoskeleton; Drosophila; Exocytosis; Humans; Imaging, Three-Dimensional; Membrane Fusion; Microscopy, Fluorescence; Molecular Biology; Salivary Glands; Secretory Vesicles; Time-Lapse Imaging
PubMed: 28302911
DOI: 10.1242/jcs.193425 -
Platelets Mar 2017
Topics: Blood Platelets; Hematology; History, 20th Century; History, 21st Century; Humans; Secretory Vesicles; Workforce
PubMed: 28281920
DOI: 10.1080/09537104.2016.1277676 -
Nature Communications Jan 2024Membrane fusion and budding mediate fundamental processes like intracellular trafficking, exocytosis, and endocytosis. Fusion is thought to open a nanometer-range pore... (Review)
Review
Membrane fusion and budding mediate fundamental processes like intracellular trafficking, exocytosis, and endocytosis. Fusion is thought to open a nanometer-range pore that may subsequently close or dilate irreversibly, whereas budding transforms flat membranes into vesicles. Reviewing recent breakthroughs in real-time visualization of membrane transformations well exceeding this classical view, we synthesize a new model and describe its underlying mechanistic principles and functions. Fusion involves hemi-to-full fusion, pore expansion, constriction and/or closure while fusing vesicles may shrink, enlarge, or receive another vesicle fusion; endocytosis follows exocytosis primarily by closing Ω-shaped profiles pre-formed through the flat-to-Λ-to-Ω-shape transition or formed via fusion. Calcium/SNARE-dependent fusion machinery, cytoskeleton-dependent membrane tension, osmotic pressure, calcium/dynamin-dependent fission machinery, and actin/dynamin-dependent force machinery work together to generate fusion and budding modes differing in pore status, vesicle size, speed and quantity, controls release probability, synchronization and content release rates/amounts, and underlies exo-endocytosis coupling to maintain membrane homeostasis. These transformations, underlying mechanisms, and functions may be conserved for fusion and budding in general.
Topics: Cell Membrane; Calcium; Membrane Fusion; Exocytosis; Dynamins; Secretory Vesicles
PubMed: 38167896
DOI: 10.1038/s41467-023-44539-7 -
FEBS Letters Nov 2018Membrane fusion and fission are fundamental processes in living organisms. Membrane fusion occurs through the formation of a fusion pore, which is the structure that... (Review)
Review
Membrane fusion and fission are fundamental processes in living organisms. Membrane fusion occurs through the formation of a fusion pore, which is the structure that connects two lipid membranes during their fusion. Fusion pores can form spontaneously, but cells endow themselves with a set of proteins that make the process of fusion faster and regulatable. The fusion pore starts with a narrow diameter and dilates relatively slowly; it may fluctuate in size or can even close completely, producing a transient vesicle fusion (kiss-and-run), or can finally expand abruptly to release all vesicle contents. A set of proteins control the formation, dilation, and eventual closure of the fusion pore and, therefore, the velocity at which the contents of secretory vesicles are released to the extracellular medium. Thus, the regulation of fusion pore expansion or closure is key to regulate the release of neurotransmitters and hormones. Here, we review the phases of the fusion pore and discuss the implications in the modes of exocytosis.
Topics: Animals; Cell Membrane; Exocytosis; Extracellular Space; Hormones; Humans; Membrane Fusion; Neurotransmitter Agents; Secretory Vesicles
PubMed: 30169901
DOI: 10.1002/1873-3468.13234 -
The Journal of Neuroscience : the... Apr 2022ClC-3, ClC-4, and ClC-5 are electrogenic chloride/proton exchangers that can be found in endosomal compartments of mammalian cells. Although the association with genetic...
ClC-3, ClC-4, and ClC-5 are electrogenic chloride/proton exchangers that can be found in endosomal compartments of mammalian cells. Although the association with genetic diseases and the severe phenotype of knock-out animals illustrate their physiological importance, the cellular functions of these proteins have remained insufficiently understood. We here study the role of two splice variants, ClC-3b and ClC-3c, in granular exocytosis and catecholamine accumulation of adrenal chromaffin cells using a combination of high-resolution capacitance measurements, amperometry, protein expression/gene knock out/down, rescue experiments, and confocal microscopy. We demonstrate that ClC-3c resides in immature as well as in mature secretory granules, where it regulates catecholamine accumulation and contributes to the establishment of the readily releasable pool of secretory vesicles. The lysosomal splice variant ClC-3b contributes to vesicle priming only with low efficiency and leaves the vesicular catecholamine content unaltered. The related Cl/H antiporter ClC-5 undergoes age-dependent downregulation in wild-type conditions. Its upregulation in cells partially rescues the exocytotic mutant defect. Our study demonstrates how different CLC transporters with similar transport functions, but distinct localizations can contribute to vesicle functions in the regulated secretory pathway of granule secretion in chromaffin cells. Cl/H exchangers are expressed along the endosomal/lysosomal system of mammalian cells; however, their exact subcellular functions have remained insufficiently understood. We used chromaffin cells, a system extensively used to understand presynaptic mechanisms of synaptic transmission, to define the role of CLC exchangers in neurosecretion. Disruption of ClC-3 impairs catecholamine accumulation and secretory vesicle priming. There are multiple ClC-3 splice variants, and only expression of one, ClC-3c, in double Cl/H exchanger-deficient cells fully rescues the WT phenotype. Another splice variant, ClC-3b, is present in lysosomes and is not necessary for catecholamine secretion. The distinct functions of ClC-3c and ClC-3b illustrate the impact of expressing multiple CLC transporters with similar transport functions and separate localizations in different endosomal compartments.
Topics: Animals; Catecholamines; Chlorides; Chromaffin Cells; Exocytosis; Mammals; Mice; Mice, Knockout; Protons; Secretory Vesicles
PubMed: 35241492
DOI: 10.1523/JNEUROSCI.2439-21.2022