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Incidence and Properties of Thermosensitive TRP Ion Channels in Cellular Models of Sensory Neurones
Loudová, Leona ; Vlachová, Viktorie (advisor) ; Boušová, Kristýna (referee)
Primary afferent sensory neurons enable all living organisms to survive in their environment and react to dangerous stimuli, including noxious and irritant chemicals, temperature, and pressure. These pseudo-unipolar neurons represent a heterologous population that, depending on functional properties, morphology, receptor equipment, degree of myelination, and conduction velocity, determines the intensity at which a stimulus is converted to an electrical signal that is then conducted to the central nervous system to elicit defensive response. The cell bodies of the peripheral sensory neurons are localized in the dorsal root ganglia (DRG) and cell lines derived from these neurons are intensively used not only to study the mechanisms of pain, but also to rationally search for substances with potential analgesic effect. The main goal of this bachelor's thesis is to summarize the current research on molecular mechanisms of nociception using cell lines derived from DRG neurons with a focus on a specific group of temperature-sensitive transient receptor potential (thermoTRP) ion channels. The aim is to present currently available studies focusing on cellular and molecular differences that result from different methodological approaches to the preparation and cultivation of cell cultures, especially in the...
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Molecular mechanisms of polymodal regulation of TRPA1 receptor
Sinica, Viktor ; Vlachová, Viktorie (advisor) ; Vondrášek, Jiří (referee) ; Holendová, Blanka (referee)
The TRPA1 channel is a universal, nociception-mediating cellular sensor activated by various environmental irritants, potentially harmful physical modalities and endogenous mediators of pathophysiological processes. The polymodality of TRPA1 channel allows the activation stimuli to further enhance or suppress each other's effect. While this modulation effect has its physiological importance in promoting the protective cellular and behavioral mechanisms, it may result into the unpleasant pain-related effects accompanying the chronical pain caused by aberrant TRPA1 channel activity. In order to effectively and selectively target the synergic properties of TRPA1 modulators, while preserving the sensitivity to the environmental threads, the knowledge of the mechanisms of polymodal regulation at the molecular level are required. This doctoral thesis aims at the elucidation of three main mechanisms of TRPA1 regulation: 1) the regulation via intracellular signaling cascades and phosphorylation, 2) the interaction with membrane phospholipids and 3) the temperature-driven gating. The results presented in the thesis show that the effects of the inflammatory mediator bradykinin are decreased by the low-frequency high-induction electromagnetic field used in magnetotherapy. We have identified a residue S602...
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Identification of changes in membrane properties of astrocytes in a mouse model of amyotrophic lateral sclerosis
Vaňátko, Ondřej ; Turečková, Jana (advisor) ; Vlachová, Viktorie (referee)
Amyotrophic lateral sclerosis (ALS) is a progressive neurological disorder of the central nervous system characterized by loss of motor neurons and voluntary muscle degeneration. Astrocytes play a major role in regulation of the disease onset and progression due to their intimate association with neurons. Regulation of ionic homeostasis is one of their key functions and its failure has been linked to several neurological diseases. The aim of this thesis was to explore differences in membrane properties of astrocytes in ALS. To fulfill this aim, a double transgenic mouse strain with ALS-like phenotype and a specific expression of enhanced green fluorescent protein in astrocytes was generated. To phenotype this strain, two sensorimotor tests, wire grid hang test and rotarod test, were conducted. Immunohistochemistry was used to characterize the strain on a cellular level and to explore changes of specific ion channels. Functional properties of astrocytes were explored using the patch clamp technique. The double transgenic strain has the characteristic ALS-like phenotype and is comparable to the original strain with differences in symptom onset and progression between models and sexes. On the cellular level, there are characteristic ALS features, specifically loss of motor neurons and astrogliosis....
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Cellular mechanisms of TRPA1 channel regulation
Barvíková, Kristýna ; Vlachová, Viktorie (advisor) ; Hudeček, Jiří (referee)
TRPA1 is a thermosensitive ion channel from the ankyrin subfamily of Transient Receptor Potential (TRP) receptors. These proteins play essential roles in the transduction of wide variety of environmental and endogenous signals. TRPA1, which is abundantly expressed in primary nociceptive neurons, is an important transducer of various noxious and irritant stimuli and is also involved in the detection of temperature changes. Similarly to other TRP channels, TRPA1 is comprised of four subunits, each with six transmembrane segments (S1-S6), flanked by the cytoplasmic N- and C-terminal ends. In native tissues, TRPA1 is supposed to be regulated by multiple phosphorylation sites that underlie TRPA1 activity under physiological and various pathophysiological conditions. Using mutational approach, we predicted and explored the role of potential phosphorylation sites for protein kinase C in TRPA1 functioning. Our results identify candidate residues, at which phosho-mimicking mutations affected the channel's ability to respond to voltage and chemical stimuli, whereas the phospho-null mutations to alanine or glycine did not affect the channel activation. Particularly, we identify the serine 602 within the N-terminal ankyrin repeat domain 16, the substitution of which to aspartate completely abolished the TRPA1...
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Cellular and molecular mechanisms of activation of thermally sensitive TRP ion channels
Máčiková, Lucie ; Vlachová, Viktorie (advisor) ; Anděrová, Miroslava (referee) ; Jakubík, Jan (referee)
The transient receptor potential (TRP) are cation channels mostly permeable to both monovalent and divalent cations. ThermoTRP is a specific group of directly thermally activated TRP channels. The vanilloid transient receptor potential 3 (TRPV3) is an ion channel widely expressed in keratinocytes, that is implicated in the regulation of skin homeostasis, thermo- sensing, nociception and development of itch sensation. Our results show the importance of the cytoplasmic inter-subunit interface in the heat sensitivity of TRPV3. As there is a structural analogy within the vanilloid receptors, our hypothesis of the identified important region is supposed to be valid also for other thermally activated TRPV receptors (TRPV1, TRPV2 and TRPV4). We have proved that TRPV3 is a substrate for ERK1/2 protein kinase (kinase regulated by extracellular signal 1 and 2) and we have identified TRPV3 phosphorylation sites that may be direct targets for ERK1/2. Of these residues, threonine 264 has been shown to be the main phosphorylation site responsible for TRPV3 sensitization mediated by ERK kinase. In human keratinocytes, the phosphorylation might be physiologically and pathophysiologically important in processes of TRPV3 sensitization mediated by MAPK signaling pathway. The transient receptor potential ankyrin 1...
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Mechanisms of Activation and Modulation of Ion Channels Specific for Nociceptive Neurones
Touška, Filip ; Vlachová, Viktorie (advisor) ; Paleček, Jiří (referee) ; Tureček, Rostislav (referee)
Human body detects potentially damaging stimuli by specialized sensory nerve endings in the skin, the nociceptors. Their membranes are equipped with ion channels, molecular sensors, coding the outside stimuli into the trains of action potentials and conducting them to the higher brain centers. The most prominent group of transduction ion channels is the transient receptor potential (TRP) channel family followed by ion channels responsible for generation and conduction of action potentials from the periphery to the brain, the voltage-gated sodium channels (VGSCs). Understanding the mechanisms how particular stimulus is encoded and processed is of particular importance to find therapeutics for various types of pain conditions. We characterized the properties of VGSC subtypes NaV1.9 and NaV1.8 at high temperatures. We showed that NaV1.9 undergo large increase in current with increasing temperatures and significantly contribute to the action potential generation in dorsal root ganglion (DRG) neurons. Ciguatoxins (CTXs) are sodium channels activator toxins causing ciguatera fish poisoning, a disease manifested by sensory and neurological disturbances. We elucidated the mechanism of CTX- induced cold allodynia, a pathological phenomenon where normally innocuous cool temperatures are perceived as pain. We...
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The role of nociceptive synaptic transmission modulation at the spinal cord level in different pain states
Adámek, Pavel ; Paleček, Jiří (advisor) ; Vaculín, Šimon (referee) ; Vlachová, Viktorie (referee)
Pain is a common symptom of many clinical syndromes and diseases. In particular, the treatment of neuropathic pain represents a serious public health issue because currently available analgesia is ineffective in many cases or it has adverse effects. Treatment of pain-related suffering requires knowledge of how pain signals are initially generated and subsequently transmitted by the nervous system. A nociceptive system plays a key role in this process of encoding and transmission of pain signals. Modulation of the nociceptive synaptic transmission in the spinal cord dorsal horn represents an important mechanism in the development and maintenance of different pathological pain states. This doctoral thesis has aimed to investigate and clarify some of the mechanisms involved in the modulation of the spinal nociceptive processing in different pain states. The main attention was paid to study the following issues: (I.) Which is the role of Transient Receptor Potential Vanilloid type 1 channels (TRPV1), Toll-Like Receptors 4 (TLR4), and phosphatidylinositol 3-kinase (PI3K) in the development of neuropathic pain induced by paclitaxel (PAC) chemotherapy in acute in vitro, and subchronic in vivo murine model of PAC-induced peripheral neuropathy (PIPN)? (II.) How is affected spinal inhibitory synaptic control...
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Functional and structural study of thermally activated TRP ion channels: The role evolutionarily conserved motifs in the TRPA1 modulation
Kádková, Anna ; Vlachová, Viktorie (advisor) ; Hudeček, Jiří (referee) ; Obšilová, Veronika (referee)
Ankyrin receptor TRPA1 is an ion channel widely expressed on primary afferent sensory neurons, where it acts as a polymodal sensor of nociceptive stimuli. Apart from pungent chemicals (e. g. isothiocyanates, cinnamaldehyde and its derivatives, acrolein, menthol), it could be activated by cold temperatures, depolarizing voltages or intracellular calcium ions. TRPA1 channel is a homotetramer in which each subunit consists of cytoplasmic N and C termini and a transmembrane region. The transmembrane part is organized into six alpha- helices connected by intra- and extracellular loops. The N terminus comprises a tandem set of 16 to 17 ankyrin repeats (AR), while the C terminus has a substantially shorter, dominantly helical structure. In 2015, a partial cryo-EM structure of TRPA1 was resolved; however, the functional roles of the individual regions of the receptor have not yet been fully understood. This doctoral thesis is concerned to elucidate the role of highly conserved sequence and structural motifs within the cytoplasmic termini and the S4-S5 region of TRPA1 in voltage- and chemical sensitivity of the receptor. The probable binding site for calcium ions that are the most important physiological modulators of TRPA1 was described by using homology modeling, molecular-dynamics simulations,...
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The role of charged residues in the activation and modulation of the TRPA1 ion channel
Zímová, Lucie ; Vlachová, Viktorie (advisor) ; Doležal, Vladimír (referee) ; Rokyta, Richard (referee)
Important receptor for sensing painful stimuli is ion channel TRPA1, which is expressed in peripheral endings of nociceptive neurons, where it serves as transducer of physical and chemical environmental signals to the language of the nervous system. The effort to understand the mechanisms of its activity on a molecular level is driven by the vision of progress in treatment of chronic pain in humans. Our work focused on C-terminal cytoplasmic domain of TRPA1 receptor, where we described i.a. the probable binding site for calcium, which is the most important TRPA1 modulator. Using the combination of homology modeling and molecular dynamic simulations with electrophysiological measurements we were able to explain molecular basis of familial pain syndrome caused by TRPA1 point mutation. We contributed to the understanding of the TRPA1 voltage-dependent activation mechanism by describing the amino acids in proximal C-terminus and in S4-S5 linker of transmembrane domain that are directly involved in voltage-dependent gating. Powered by TCPDF (www.tcpdf.org)
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