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Frontiers of Medicine Oct 2019Members of the fibroblast growth factor (FGF) family play pleiotropic roles in cellular and metabolic homeostasis. During evolution, the ancestor FGF expands into... (Review)
Review
Members of the fibroblast growth factor (FGF) family play pleiotropic roles in cellular and metabolic homeostasis. During evolution, the ancestor FGF expands into multiple members by acquiring divergent structural elements that enable functional divergence and specification. Heparan sulfate-binding FGFs, which play critical roles in embryonic development and adult tissue remodeling homeostasis, adapt to an autocrine/paracrine mode of action to promote cell proliferation and population growth. By contrast, FGF19, 21, and 23 coevolve through losing binding affinity for extracellular matrix heparan sulfate while acquiring affinity for transmembrane α-Klotho (KL) or β-KL as a coreceptor, thereby adapting to an endocrine mode of action to drive interorgan crosstalk that regulates a broad spectrum of metabolic homeostasis. FGF19 metabolic axis from the ileum to liver negatively controls diurnal bile acid biosynthesis. FGF21 metabolic axes play multifaceted roles in controlling the homeostasis of lipid, glucose, and energy metabolism. FGF23 axes from the bone to kidney and parathyroid regulate metabolic homeostasis of phosphate, calcium, vitamin D, and parathyroid hormone that are important for bone health and systemic mineral balance. The significant divergence in structural elements and multiple functional specifications of FGF19, 21, and 23 in cellular and organismal metabolism instead of cell proliferation and growth sufficiently necessitate a new unified and specific term for these three endocrine FGFs. Thus, the term "FGF Metabolic Axis," which distinguishes the unique pathways and functions of endocrine FGFs from other autocrine/paracrine mitogenic FGFs, is coined.
Topics: Animals; Calcium; Cell Proliferation; Endocrine System; Fibroblast Growth Factor-23; Fibroblast Growth Factors; Homeostasis; Humans; Liver; Metabolic Diseases; Neoplasms; Phosphates; Signal Transduction; Vitamin D
PubMed: 31495905
DOI: 10.1007/s11684-019-0711-y -
International Anesthesiology Clinics 2007Cytokines are small secreted proteins released by cells have a specific effect on the interactions and communications between cells. Cytokine is a general name; other... (Review)
Review
Cytokines are small secreted proteins released by cells have a specific effect on the interactions and communications between cells. Cytokine is a general name; other names include lymphokine (cytokines made by lymphocytes), monokine (cytokines made by monocytes), chemokine (cytokines with chemotactic activities), and interleukin (cytokines made by one leukocyte and acting on other leukocytes). Cytokines may act on the cells that secrete them (autocrine action), on nearby cells (paracrine action), or in some instances on distant cells (endocrine action). There are both pro-inflammatory cytokines and anti-inflammatory cytokines. There is significant evidence showing that certain cytokines/chemokines are involved in not only the initiation but also the persistence of pathologic pain by directly activating nociceptive sensory neurons. Certain inflammatory cytokines are also involved in nerve-injury/inflammation-induced central sensitization, and are related to the development of contralateral hyperalgesia/allodynia. The discussion presented in this chapter describes several key pro-inflammatory cytokines/chemokines and anti-inflammatory cytokines, their relation with pathological pain in animals and human patients, and possible underlying mechanisms.
Topics: Animals; Central Nervous System; Chemokines; Cytokines; Humans; Inflammation; Neuroglia; Pain; Peripheral Nervous System
PubMed: 17426506
DOI: 10.1097/AIA.0b013e318034194e -
American Journal of Physiology. Cell... Dec 2022The skin, which is comprised of the epidermis, dermis, and subcutaneous tissue, is the largest organ in the human body and it plays a crucial role in the regulation of... (Review)
Review
The skin, which is comprised of the epidermis, dermis, and subcutaneous tissue, is the largest organ in the human body and it plays a crucial role in the regulation of the body's homeostasis. These functions are regulated by local neuroendocrine and immune systems with a plethora of signaling molecules produced by resident and immune cells. In addition, neurotransmitters, endocrine factors, neuropeptides, and cytokines released from nerve endings play a central role in the skin's responses to stress. These molecules act on the corresponding receptors in an intra-, juxta-, para-, or autocrine fashion. The epidermis as the outer most component of skin forms a barrier directly protecting against environmental stressors. This protection is assured by an intrinsic keratinocyte differentiation program, pigmentary system, and local nervous, immune, endocrine, and microbiome elements. These constituents communicate cross-functionally among themselves and with corresponding systems in the dermis and hypodermis to secure the basic epidermal functions to maintain local (skin) and global (systemic) homeostasis. The neurohormonal mediators and cytokines used in these communications regulate physiological skin functions separately or in concert. Disturbances in the functions in these systems lead to cutaneous pathology that includes inflammatory (i.e., psoriasis, allergic, or atopic dermatitis, etc.) and keratinocytic hyperproliferative disorders (i.e., seborrheic and solar keratoses), dysfunction of adnexal structure (i.e., hair follicles, eccrine, and sebaceous glands), hypersensitivity reactions, pigmentary disorders (vitiligo, melasma, and hypo- or hyperpigmentary responses), premature aging, and malignancies (melanoma and nonmelanoma skin cancers). These cellular, molecular, and neural components preserve skin integrity and protect against skin pathologies and can act as "messengers of the skin" to the central organs, all to preserve organismal survival.
Topics: Humans; Skin; Epidermis; Keratinocytes; Neuropeptides; Signal Transduction; Cytokines
PubMed: 36317800
DOI: 10.1152/ajpcell.00147.2022 -
American Journal of Physiology. Renal... Jul 2005The vitamin D endocrine system plays an essential role in calcium homeostasis and bone metabolism, but research during the past two decades has revealed a diverse range... (Review)
Review
The vitamin D endocrine system plays an essential role in calcium homeostasis and bone metabolism, but research during the past two decades has revealed a diverse range of biological actions that include induction of cell differentiation, inhibition of cell growth, immunomodulation, and control of other hormonal systems. Vitamin D itself is a prohormone that is metabolically converted to the active metabolite, 1,25-dihydroxyvitamin D [1,25(OH)(2)D]. This vitamin D hormone activates its cellular receptor (vitamin D receptor or VDR), which alters the transcription rates of target genes responsible for the biological responses. This review focuses on several recent developments that extend our understanding of the complexities of vitamin D metabolism and actions: the final step in the activation of vitamin D, conversion of 25-hydroxyvitamin D to 1,25(OH)(2)D in renal proximal tubules, is now known to involve facilitated uptake and intracellular delivery of the precursor to 1alpha-hydroxylase. Emerging evidence using mice lacking the VDR and/or 1alpha-hydroxylase indicates both 1,25(OH)(2)D(3)-dependent and -independent actions of the VDR as well as VDR-dependent and -independent actions of 1,25(OH)(2)D(3). Thus the vitamin D system may involve more than a single receptor and ligand. The presence of 1alpha-hydroxylase in many target cells indicates autocrine/paracrine functions for 1,25(OH)(2)D(3) in the control of cell proliferation and differentiation. This local production of 1,25(OH)(2)D(3) is dependent on circulating precursor levels, providing a potential explanation for the association of vitamin D deficiency with various cancers and autoimmune diseases.
Topics: Animals; Biological Transport, Active; Endocrine System; Gene Expression Regulation; Humans; Models, Chemical; Molecular Structure; Receptors, Calcitriol; Signal Transduction; Vitamin D
PubMed: 15951480
DOI: 10.1152/ajprenal.00336.2004 -
The Journal of Clinical Investigation Apr 2022Dysfunction of protein trafficking has been intensively associated with neurological diseases, including neurodegeneration, but whether and how protein transport...
Dysfunction of protein trafficking has been intensively associated with neurological diseases, including neurodegeneration, but whether and how protein transport contributes to oligodendrocyte (OL) maturation and myelin repair in white matter injury remains unclear. ER-to-Golgi trafficking of newly synthesized proteins is mediated by coat protein complex II (COPII). Here, we demonstrate that the COPII component Sec13 was essential for OL differentiation and postnatal myelination. Ablation of Sec13 in the OL lineage prevented OPC differentiation and inhibited myelination and remyelination after demyelinating injury in the central nervous system (CNS), while improving protein trafficking by tauroursodeoxycholic acid (TUDCA) or ectopic expression of COPII components accelerated myelination. COPII components were upregulated in OL lineage cells after demyelinating injury. Loss of Sec13 altered the secretome of OLs and inhibited the secretion of pleiotrophin (PTN), which was found to function as an autocrine factor to promote OL differentiation and myelin repair. These data suggest that Sec13-dependent protein transport is essential for OL differentiation and that Sec13-mediated PTN autocrine signaling is required for proper myelination and remyelination.
Topics: Autocrine Communication; Carrier Proteins; Cell Differentiation; Cytokines; Demyelinating Diseases; Humans; Myelin Sheath; Oligodendroglia
PubMed: 35143418
DOI: 10.1172/JCI155096 -
The Journal of Experimental Medicine Feb 2021Macrophages help defend the host against Mycobacterium tuberculosis (Mtb), the major cause of tuberculosis (TB). Once phagocytized, Mtb resists killing by macrophages,...
Macrophages help defend the host against Mycobacterium tuberculosis (Mtb), the major cause of tuberculosis (TB). Once phagocytized, Mtb resists killing by macrophages, replicates inside them, and leads to their death, releasing Mtb that can infect other cells. We found that the death of Mtb-infected mouse macrophages in vitro does not appear to proceed by a currently known pathway. Through genome-wide CRISPR-Cas9 screening, we identified a critical role for autocrine or paracrine signaling by macrophage-derived type I IFNs in the death of Mtb-infected macrophages in vitro, and blockade of type I IFN signaling augmented the effect of rifampin, a first-line TB drug, in Mtb-infected mice. Further definition of the pathway of type I IFN-mediated macrophage death may allow for host-directed therapy of TB that is more selective than systemic blockade of type I IFN signaling.
Topics: Animals; Autocrine Communication; CRISPR-Cas Systems; Cell Death; Cell Line; HEK293 Cells; Humans; Interferon Type I; Macrophages; Mice; Mice, Inbred C57BL; Mycobacterium tuberculosis; Paracrine Communication; RAW 264.7 Cells; Rifampin; Signal Transduction; Tuberculosis
PubMed: 33125053
DOI: 10.1084/jem.20200887 -
Endocrine Connections Dec 2018The brain hosts a vast and diverse repertoire of neuropeptides, a class of signalling molecules often described as neurotransmitters. Here I argue that this description... (Review)
Review
The brain hosts a vast and diverse repertoire of neuropeptides, a class of signalling molecules often described as neurotransmitters. Here I argue that this description entails a catalogue of misperceptions, misperceptions that feed into a narrative in which information processing in the brain can be understood only through mapping neuronal connectivity and by studying the transmission of electrically conducted signals through chemical synapses. I argue that neuropeptide signalling in the brain involves primarily autocrine, paracrine and neurohormonal mechanisms that do not depend on synaptic connectivity and that it is not solely dependent on electrical activity but on mechanisms analogous to secretion from classical endocrine cells. As in classical endocrine systems, to understand the role of neuropeptides in the brain, we must understand not only how their release is regulated, but also how their synthesis is regulated and how the sensitivity of their targets is regulated. We must also understand the full diversity of effects of neuropeptides on those targets, including their effects on gene expression.
PubMed: 30352398
DOI: 10.1530/EC-18-0367 -
Frontiers in Endocrinology 2019G protein-coupled receptors (GPCRs) constitute the largest superfamily of integral membrane protein receptors. As signal detectors, the several 100 known GPCRs are... (Review)
Review
G protein-coupled receptors (GPCRs) constitute the largest superfamily of integral membrane protein receptors. As signal detectors, the several 100 known GPCRs are responsible for sensing the plethora of endogenous ligands that are critical for the functioning of our endocrine system. Although GPCRs are typically considered as detectors for first messengers in classical signal transduction pathways, they seldom operate in isolation in complex biological systems. Intercellular communication between identical or different cell types is often mediated by autocrine or paracrine signals that are generated upon activation of specific GPCRs. In the context of energy homeostasis, the distinct complement of GPCRs in each cell type bridges the autocrine and paracrine communication within an organ, and the various downstream signaling mechanisms regulated by GPCRs can be integrated in a cell to produce an ultimate output. GPCRs thus act as gatekeepers that coordinate and fine-tune a response. By examining the role of GPCRs in activating and receiving autocrine and paracrine signals, one may have a better understanding of endocrine diseases that are associated with GPCR mutations, thereby providing new insights for treatment regimes.
PubMed: 31354618
DOI: 10.3389/fendo.2019.00428 -
Neuroendocrinology 2023Extracellular vesicles (EVs) are membrane-enclosed nanoparticles that contain various biomolecules, including nucleic acids, proteins and lipids, and are manufactured... (Review)
Review
Extracellular vesicles (EVs) are membrane-enclosed nanoparticles that contain various biomolecules, including nucleic acids, proteins and lipids, and are manufactured and released by virtually all cell types. There is evidence that EVs are involved in intercellular communication, acting in an autocrine, paracrine or/and endocrine manner. EVs are released by the cells of the central nervous system (CNS), including neurons, astrocytes, oligodendrocytes and microglia, and have the ability to cross the blood-brain barrier (BBB) and enter the systemic circulation. Neuroendocrine cells are specialized neurons that secrete hormones directly into blood vessels, such as the hypophyseal portal system or the systemic circulation, a process that allows neuroendocrine integration to take place. In mammals, neuroendocrine cells are widely distributed throughout various anatomic compartments, with the hypothalamus being a central neuroendocrine integrator. The hypothalamus is a key part of the stress system (SS), a highly conserved neuronal/neuroendocrine system aiming at maintaining systemic homeostasis when the latter is threatened by various stressors. The central parts of the SS are the interconnected hypothalamic corticotropin-releasing hormone (CRH) and the brainstem locus caeruleus-norepinephrine (LC-NE) systems, while their peripheral parts are, respectively, the pituitary-adrenal axis and the sympathetic nervous/sympatho-adrenomedullary systems (SNS-SAM) as well as components of the parasympathetic nervous system (PSNS). During stress, multiple CNS loci show plasticity and undergo remodeling, partly mediated by increased glutamatergic and noradrenergic activity, and the actions of cytokines and glucocorticoids, all regulated by the interaction of the hypothalamic-pituitary-adrenal (HPA) axis and the LC-NE/SNS-SAM systems. In addition, there are peripheral changes due to the increased secretion of stress hormones and pro-inflammatory cytokines in the context of stress-related systemic (para)inflammation. We speculate that during stress, central and peripheral, cellular and molecular alterations take place, with some of them generated, communicated, and spread via the release of stress-induced neural/neuroendocrine cell-derived EVs.
Topics: Animals; Hypothalamo-Hypophyseal System; Neurosecretory Systems; Adrenocorticotropic Hormone; Norepinephrine; Extracellular Vesicles; Cytokines; Pituitary-Adrenal System; Stress, Physiological; Corticotropin-Releasing Hormone; Mammals
PubMed: 36137504
DOI: 10.1159/000527182 -
Frontiers in Immunology 2020Immune cells rely on cell-cell communication to specify and fine-tune their responses. They express an extensive network of cell communication modes, including a vast... (Review)
Review
Immune cells rely on cell-cell communication to specify and fine-tune their responses. They express an extensive network of cell communication modes, including a vast repertoire of cell surface and transmembrane receptors and ligands, membrane vesicles, junctions, ligand and voltage-gated ion channels, and transporters. During a crosstalk between the nervous system and the immune system these modes of cellular communication and the downstream signal transduction events are influenced by neurotransmitters present in the local tissue environments in an autocrine or paracrine fashion. Neurotransmitters thus influence innate and adaptive immune responses. In addition, immune cells send signals to the brain through cytokines, and are present in the brain to influence neural responses. Altered communication between the nervous and immune systems is emerging as a common feature in neurodegenerative and immunopathological diseases. Here, we present the mechanistic frameworks of immunostimulatory and immunosuppressive effects critical neurotransmitters - dopamine (3,4-dihydroxyphenethylamine), serotonin (5-hydroxytryptamine), substance P (trifluoroacetate salt powder), and L-glutamate - exert on lymphocytes and non-lymphoid immune cells. Furthermore, we discuss the possible roles neurotransmitter-driven neuroimmune networks play in the pathogenesis of neurodegenerative disorders, autoimmune diseases, cancer, and outline potential clinical implications of balancing neuroimmune crosstalk by therapeutic modulation.
Topics: Animals; Humans; Neuroimmunomodulation; Neurotransmitter Agents
PubMed: 32973771
DOI: 10.3389/fimmu.2020.01869