Calcium signalling regulating platelet adhesion and thrombus growth

Giuliano, Simon, 1975-

January 2002

Abstract not available

Thrombosis

Blood

Blood platelets -- Activation

Adhesion

Cellular signal transduction

Calcium -- Physiological effect

Calcium channels

STORE OPERATED Ca2+ CHANNELS IN LIVER CELLS: REGULATION BY BILE ACIDS AND A SUB-REGION OF THE ENDOPLASMIC RETICULUM

Castro Kraftchenko, Joel, kraf0005@flinders.edu.au

January 2008

Cholestasis is an important liver pathology. During cholestasis bile acids accumulate in the bile canaliculus affecting hepatocyte viability. The actions of bile acids require changes in the release of Ca2+ from intracellular stores and in Ca2+ entry. The target(s) of the Ca2+ entry pathway affected by bile acids is, however, not known. The overall objective of the work described in this thesis was to elucidate the target(s) and mechanism(s) of bile acids-induced modulation of hepatocytes calcium homeostasis. First, it was shown that a 12 h pre-incubation with cholestatic bile acids (to mimic cholestasis conditions) induced the inhibition of Ca2+ entry through store-operated Ca2+ channels (SOCs), while the addition of choleretic bile acids to the incubation medium caused the reversible activation of Ca2+ entry through SOCs. Moreover, it was shown that incubation of liver cells with choleretic bile acids counteracts the inhibition of Ca2+ entry caused by pre-incubation with cholestatic bile acids. Thus, it was concluded that SOCs are the target of bile acids action in liver cells. Surprisingly, despite the effect of choleretic bile acids in activating SOCs, the Ca2+ dye fura-2 failed to detect choleretic bile acid-induced Ca2+ release from intracellular stores in the absence of extracellular Ca2+. However, under the same conditions, when the sub-plasma membrane Ca2+ levels were measured using FFP-18 Ca2+ dye, choleretic bile acid induced a transient increase in FFP-18 fluorescence. This evidence suggested that choleretic bile acids-induced activation of Ca2+ entry through SOCs, involving the release of Ca2+ from a region of the endoplasmic reticulum (ER) located in the vicinity of the plasma membrane.

Liver cells

Store Operated Calcium Channels

Bile Acids

Endoplasmic Reticulum

STIM1

Orai1

TRPV1

Fura-2

Recovery of neuronal channel densities from calcium fluorescence

January 2011

Neurons have the ability to dynamically adjust their own membrane channel densities to modulate the strength of communication with other neurons. This process is integral to such neuronal functions as spatial recognition and memory but has been difficult to measure experimentally. Historically, neuroscientists have used changes in voltage to infer changes in neuronal channel densities. However, voltage is difficult to measure away from the soma. Many important functions in the neuron, like synaptic integration, take place in the dendritic tree where traditional voltage measurements can not be taken. To interrogate the neuron in the dendrites, experimentalists have come to rely on calcium fluorescence based microscopy to infer qualitative information about voltage changes in the dendrites. In these experiments, intracellular calcium changes due to voltage depolarizations are recorded at spatially distributed sites on the dendrites through the binding of calcium to a fluorescent buffer. The recovery of channel densities can be posed as a parameter identification problem in a coupled nonlinear partial differential equation that relates the responses of calcium, the fluorescent buffer and voltage to neuronal stimulation. We convert temporally and spatially distributed fluorescence data into quantitative measurements of voltage sensitive channel densities by inverting slow time-scaled calcium data into fast time-scaled voltage data. Our approach is to solve four interrelated inverse problems corresponding to three different proposed experiments to go from calcium fluorescence to channel densities. In the first experiment, we use subthreshold calcium dynamics to infer the reaction kinetics between calcium arid fluorescent buffer. From these kinetics, we can use suprathreshold voltage stimulation to infer calcium channel densities and recover distributed voltage data. Finally we use the voltage data to infer potassium channel densities in the dendrites. Our algorithm has been shown to recover channel densities for several different calcium channel models and the delayed rectifying potassium channel from simulated noisy fluorescence data in morphologically realistic neurons.

Applied sciences

Biological sciences

Calcium channels

Fluorescence

Channel densities

Dendrites

Neurosciences

Applied Mathematics

CA²⁺-selective TRPM channels regulate IP₃-dependent CA²⁺ oscillations in the C. elegans intestine

Xing, Juan,

January 2009

Thesis (Ph. D. in Pharmacology)--Vanderbilt University, Dec. 2009. / Title from title screen. Includes bibliographical references.

Calcium and sodium absorption across the small intestine of cystic fibrosis mice /

Gawenis, Lara Renee,

January 2001

Thesis (Ph. D.)--University of Missouri--Columbia, 2001. / "May 2001." Typescript. Vita. Includes bibliographical references (leaves 168-199). Also available on the Internet.

The endocytic protein Numb regulates APP metabolism and Notch signaling implications for Alzheimer's disease /

Kyriazis, George A.

January 2008

Thesis (Ph.D.)--University of Central Florida, 2008. / Adviser: Sic L. Chan. Includes bibliographical references (p. 74-84).

Calcium and sodium absorption across the small intestine of cystic fibrosis mice

Gawenis, Lara Renee,

January 2001

Thesis (Ph. D.)--University of Missouri--Columbia, 2001. / Typescript. Vita. Includes bibliographical references (leaves 168-199). Also available on the Internet.

Synaptic Transmission in the Leaner Mutant Mouse Calyx of Held/MNTB Synapse

Epps, Tina

20 January 2009

The effects of alpha1A subunit mutations on presynaptic Ca2+ channel activity and functional development of synaptic properties remain elusive. The calyx of Held/medial nucleus of the trapezoid body synapse is an ideal model for studying the developmental effects of presynaptic voltage-gated Ca2+ channel (VGCC) impairment on synaptic function since simultaneous voltage-clamp recordings can be made directly from the pre- and postsynapse. The alpha1A subunit leaner (tgla/la) mutation induced a profound reduction in synaptic transmission after hearing onset (> postnatal day 12; P12), with relatively preserved relationship between presynaptic Ca2+ current (Pre-ICa) and release and G-protein-mediated inhibition. Some synaptic properties were more reflective of an immature state, while other properties displayed a delay in maturation after P12. Direct presynaptic recordings from P15/16 tgla/la nerve terminals revealed a decrease in the density of Pre-ICa, elevated activation threshold and slowing in the kinetics of VGCCs, all of which contribute to the deficit in transmitter release. Fractional contribution of P/Q-type channels to total Pre-ICa and their role in vesicle release was markedly reduced. N-type Ca2+ channels and close association of VGCCs to release sites was not sufficient to fully compensate for impaired P/Q-type channel function. The extent to which compensatory mechanisms preserve synaptic transmission at tgla/la synapses was further constrained by the developmental narrowing of the action potential waveform. Activation of the cAMP pathway by forskolin or direct modulation of VGCCs by cdk inhibitors rescued deficits in transmitter release at P15/16 tgla/la synapses. The major effect of roscovitine was a slowing of presynaptic VGCC deactivation kinetics accompanied by a leftward shift in the activation curve. Activation of the cAMP pathway or direct modulation of presynaptic VGCCs may serve as two potential pathways to facilitate release and improve neuronal communication at synapses normally compromised by impaired P/Q-type channel function. While significant for the tgla/la mutant, these studies provide an important advancement in our understanding of the crucial developmental and functional roles of P/Q-type Ca2+ channels in driving the maturation of synaptic properties at central synapses. These findings may improve our understanding of the pathophysiology of presynaptic VGCCs and elucidate essential mechanisms underlying the tgla/la phenotype.

Calcium Channels

Leaner Mutant Mouse

Calyx of Held

Synaptic Transmission

Development

Presynaptic

Roscovitine

0317

Synaptic Transmission in the Leaner Mutant Mouse Calyx of Held/MNTB Synapse

Epps, Tina

20 January 2009

The effects of alpha1A subunit mutations on presynaptic Ca2+ channel activity and functional development of synaptic properties remain elusive. The calyx of Held/medial nucleus of the trapezoid body synapse is an ideal model for studying the developmental effects of presynaptic voltage-gated Ca2+ channel (VGCC) impairment on synaptic function since simultaneous voltage-clamp recordings can be made directly from the pre- and postsynapse. The alpha1A subunit leaner (tgla/la) mutation induced a profound reduction in synaptic transmission after hearing onset (> postnatal day 12; P12), with relatively preserved relationship between presynaptic Ca2+ current (Pre-ICa) and release and G-protein-mediated inhibition. Some synaptic properties were more reflective of an immature state, while other properties displayed a delay in maturation after P12. Direct presynaptic recordings from P15/16 tgla/la nerve terminals revealed a decrease in the density of Pre-ICa, elevated activation threshold and slowing in the kinetics of VGCCs, all of which contribute to the deficit in transmitter release. Fractional contribution of P/Q-type channels to total Pre-ICa and their role in vesicle release was markedly reduced. N-type Ca2+ channels and close association of VGCCs to release sites was not sufficient to fully compensate for impaired P/Q-type channel function. The extent to which compensatory mechanisms preserve synaptic transmission at tgla/la synapses was further constrained by the developmental narrowing of the action potential waveform. Activation of the cAMP pathway by forskolin or direct modulation of VGCCs by cdk inhibitors rescued deficits in transmitter release at P15/16 tgla/la synapses. The major effect of roscovitine was a slowing of presynaptic VGCC deactivation kinetics accompanied by a leftward shift in the activation curve. Activation of the cAMP pathway or direct modulation of presynaptic VGCCs may serve as two potential pathways to facilitate release and improve neuronal communication at synapses normally compromised by impaired P/Q-type channel function. While significant for the tgla/la mutant, these studies provide an important advancement in our understanding of the crucial developmental and functional roles of P/Q-type Ca2+ channels in driving the maturation of synaptic properties at central synapses. These findings may improve our understanding of the pathophysiology of presynaptic VGCCs and elucidate essential mechanisms underlying the tgla/la phenotype.

Calcium Channels

Leaner Mutant Mouse

Calyx of Held

Synaptic Transmission

Development

Presynaptic

Roscovitine

0317

THE CONTRIBUTION OF K+ ION CHANNELS AND THE Ca2+-PERMEABLE TRPM8 CHANNEL TO BREAST CANCER CELL PROLIFERATION.

Roy, Jeremy

26 October 2010

Breast cancer is the most prevalent cancer type among Canadian women. Breast cancers originate from the malignant transformation of mammary epithelial cells, which causes them to adopt an uncontrolled cell proliferation phenotype. My research suggests that the activity of specific ion channels (KV10.1, KCa3.1 and TRPM8) contribute to the proliferation of MCF-7 cells, a cell line commonly used to study breast cancer in vitro. Pharmacologically inhibiting the activities of KV10.1 or KCa3.1 channels decreased basal, but not estrogen-stimulated [3H]-thymidine incorporation, demonstrating that these channels contribute to MCF-7 cell proliferation. One way K+ channel activity is hypothesized to control cell proliferation is via regulation of membrane potential-dependent Ca2+ influx. Inhibition of KCa3.1 but not KV10.1 channel activity resulted in a membrane potential-dependent decrease in basal Ca2+ influx, suggesting that the way in which KCa3.1 channels contribute to cell proliferation is via regulating Ca2+ influx. In addition, my research also demonstrated that TRAM-34 increased or decreased cell proliferation depending on the concentration used and mitogenesis by TRAM-34 was blocked by estrogen receptor antagonists. TRAM-34 increased progesterone receptor mRNA expression, decreased estrogen receptor-alpha mRNA expression and reduced the binding of radiolabelled estrogen to estrogen receptor protein, in each case mimicking the effects of estrogen. Our finding that TRAM-34 is able to activate the estrogen receptor suggests a novel action of this supposedly specific K+ channel inhibitor and raises concerns of interpretation in its use. TRPM8 channels were also identified in MCF-7 cells, where they appeared to be important Ca2+ entry pathways. Inhibiting the activity of TRPM8 pharmacologically, as well as knocking down TRPM8 mRNA expression decreased cell proliferation, indicating that TRPM8 also contributed to MCF-7 cell proliferation. In conclusion, my research demonstrates that the activities of KV10.1, KCa3.1 and TRPM8 channels contribute to basal breast cancer cell proliferation. These findings suggest that the activity of specific ion channels may be potential targets for future therapeutic agents to treat breast cancer.