Optimizing Genetically Encoded Calcium Indicators to Measure Presynaptic Calcium Transients

Gilyan, Andrew

27 September 2012

Neurotransmitter release is modulated by multiple regulatory mechanisms that control several stages of synaptic vesicle (SV) exocytosis. At the final stage, SV fusion with the presynaptic membrane requires calcium influx through voltage-gated calcium channels, and regulatory mechanisms that alter the surface expression or conductance of calcium channels have large effects on neurotransmitter release. To determine how these mechanisms contribute to synapse-specific modulations of neurotransmitter release and synaptic strength, we require a means to monitor presynaptic calcium transients at individual synapses. Genetically encoded calcium indicators (GECIs), engineered proteins that change their fluorescence emission properties upon calcium binding, generally lack the sensitivity to measure such transients in response to isolated stimuli. Therefore, we modified the GECI, GCaMP3, by altering its sensitivity for calcium. Our results suggest the modified GCaMP-based presynaptically targeted GECIs are excellent tools to quantify presynaptic calcium transients at individual synapses in response to isolated action potentials.

Caracterização da apirase do parasita P. falciparum e análise do papel do Ca2+ no egresso de T. gondii. / Characterization of P. falciparum apyrase and analysis of the role of Ca2+ in T. gondii egress.

Pereira, Lucas Borges

18 February 2016

Plasmodium falciparum e Toxoplasma gondii são protozoários parasitas pertencentes ao filo Apicomplexa. Apirases são enzimas metabolizadoras de nucleotídeos extracelulares. Nesta tese mostramos pela primeira vez a presença de um membro desta família de enzimas em P. falciparum, o qual foi capaz de degradar ATP extracelular. Análises por RT-qPCR revelaram a expressão da apirase durante todo o ciclo intraeritrocítico. A adição de inibidores desta classe de enzimas foi capaz de prejudicar o desenvolvimento dos parasitas e a invasão de novas hemácias pelos merozoitos, sugerindo assim um papel da apirase nestes processos. A via de sinalização por Ca2+ é universal e vital para todas as células. Para melhor entender a fisiologia celular de P. falciparum construímos uma nova linhagem de parasitas transgênicos, PfGCaMP3, que nos tornam capazes de monitorar a dinâmica de Ca2+ sem o uso de protocolos invasivos de marcação. De modo semelhante utilizamos uma nova linhagem de T. gondii expressando de forma estável o indicador de Ca2+ GCaMP3 para estudar o papel deste íon na saída da célula. T. gondii possui o Ca2+ necessário para promover este processo, entretanto Ca2+ extracelular age como um fator intensificador neste passo essencial do ciclo lítico. / Plasmodium falciparum and Toxoplasma gondii are protozoan parasites that belong to phylum Apicomplexa. Apirases are metabolizing enzymes of extracellular nucleotides. In this work we show for the first time the presence of an apyrase in P. falciparum, which was able to degrade extracellular ATP. RTqPCR analysis revealed the expression of apyrase throughout the intraerythrocytic cycle. Addition of apyrase inhibitors was able to impair the development of the parasites and the invasion of new erythrocytes by merozoites, thus suggesting a role of apyrase in these processes. Calcium signaling is universal and vital to all cells. To better understand the cellular physiology of P. falciparum we construct a new strain of transgenic parasites, PfGCaMP3, which enable us to monitor the Ca2+ dynamics without using invasive protocols. Similarly we use a new strain of T. gondii that stably express the Ca2+ indicator GCaMP3 to study the role Ca2+ in parasite egress. T. gondii has the Ca2+ required to promote this process, however extracellular Ca2+ acts as an enhancer factor in this crucial step of the lytic cycle.

Plasmodium falciparum

Plasmodium falciparum

Toxoplasma gondii

Toxoplasma gondii

Apirase

Apyrase

Cálcio

Calcium

Egress

Egresso

GCaMP3

GCaMP3

Caracterização da apirase do parasita P. falciparum e análise do papel do Ca2+ no egresso de T. gondii. / Characterization of P. falciparum apyrase and analysis of the role of Ca2+ in T. gondii egress.

Lucas Borges Pereira

18 February 2016

Plasmodium falciparum e Toxoplasma gondii são protozoários parasitas pertencentes ao filo Apicomplexa. Apirases são enzimas metabolizadoras de nucleotídeos extracelulares. Nesta tese mostramos pela primeira vez a presença de um membro desta família de enzimas em P. falciparum, o qual foi capaz de degradar ATP extracelular. Análises por RT-qPCR revelaram a expressão da apirase durante todo o ciclo intraeritrocítico. A adição de inibidores desta classe de enzimas foi capaz de prejudicar o desenvolvimento dos parasitas e a invasão de novas hemácias pelos merozoitos, sugerindo assim um papel da apirase nestes processos. A via de sinalização por Ca2+ é universal e vital para todas as células. Para melhor entender a fisiologia celular de P. falciparum construímos uma nova linhagem de parasitas transgênicos, PfGCaMP3, que nos tornam capazes de monitorar a dinâmica de Ca2+ sem o uso de protocolos invasivos de marcação. De modo semelhante utilizamos uma nova linhagem de T. gondii expressando de forma estável o indicador de Ca2+ GCaMP3 para estudar o papel deste íon na saída da célula. T. gondii possui o Ca2+ necessário para promover este processo, entretanto Ca2+ extracelular age como um fator intensificador neste passo essencial do ciclo lítico. / Plasmodium falciparum and Toxoplasma gondii are protozoan parasites that belong to phylum Apicomplexa. Apirases are metabolizing enzymes of extracellular nucleotides. In this work we show for the first time the presence of an apyrase in P. falciparum, which was able to degrade extracellular ATP. RTqPCR analysis revealed the expression of apyrase throughout the intraerythrocytic cycle. Addition of apyrase inhibitors was able to impair the development of the parasites and the invasion of new erythrocytes by merozoites, thus suggesting a role of apyrase in these processes. Calcium signaling is universal and vital to all cells. To better understand the cellular physiology of P. falciparum we construct a new strain of transgenic parasites, PfGCaMP3, which enable us to monitor the Ca2+ dynamics without using invasive protocols. Similarly we use a new strain of T. gondii that stably express the Ca2+ indicator GCaMP3 to study the role Ca2+ in parasite egress. T. gondii has the Ca2+ required to promote this process, however extracellular Ca2+ acts as an enhancer factor in this crucial step of the lytic cycle.

Plasmodium falciparum

Toxoplasma gondii

Apirase

Cálcio

Egresso

GCaMP3

Plasmodium falciparum

Toxoplasma gondii

Apyrase

Calcium

Egress

GCaMP3

Investigation of spatiotemporal calcium transients in astrocytic soma and processes upon purinergic receptor activation using genetically encoded calcium sensors / Etude en microscopie biphotonique de l’activité calcique astrocytaire mesurée par des indicateurs protéiques et induite par des agonistes purinergiques

Schmidt, Elke

27 February 2015

Les astrocytes protoplasmiques de la matière grise corticale sont des cellules gliales dont les prolongements très fins et ramifiés sont en contact avec les éléments neuronaux pré- et post-synaptiques d’une part, et les vaisseaux sanguins d’autre part. Ils expriment plusieurs récepteurs des neurotransmetteurs, entre autres des récepteurs purinergiques dont l'activation facilite l’activité calcique astrocytaire et la libération de gliotransmitters (par exemple, le glutamate, le GABA, l'ATP, et la D sérine) qui régulent l’activité des neurones et des cellules gliales situées au voisinage. L’objectif de ma thèse était d’étudier in situ l’activité calcique des astrocytes et de leurs prolongements en réponse à l’application des agonistes purinergiques. Lors de ma thèse, j’ai tout d'abord testé la possibilité d’induire l’expression spécifique de gènes d’intérêt par les astrocytes corticaux de souris adultes par la technique de recombinaison Cre-LoxP. J’ai comparé les performances d’un virus adeno-associé de type 5 (AAV5) flexé (AAV5.FLEX.EGFP) et d’une souris qui exprime un indicateur calcique (GCaMP3) sous contrôle de la recombinase (souris Rosa-CAG-LSL-GCaMP3). L’injection d’AAV5.FLEX.EGFP dans le cortex d’une souris hGFAPcre n’a pas permis l’expression spécifique d’EGFP. La combinaison des souris exprimant le cre recombinase sous contrôle d’un promoteur sélectif des astrocytes (GLAST-CreERT2 et Cx30-CreERT2) avec le AAV5.FLEX.EGFP ou avec une lignée des souris Rosa-CAG-LSL-GCaMP3 permet l’expression spécifique des gènes d’intérêt (EGFP et GCaMP3) par les astrocytes corticaux. J’ai ensuite analysé l’activité calcique des astrocytes qui expriment GCaMP3. J’ai utilisé la microscopie biphotonique et enregistré l’activité calcique spontanée et évoquée par application d’agonistes purinergiques sur des tranches de cortex somatosensoriel primaire de souris adultes GLAST-CreERT2. L’activité calcique spontanée est complexe, généralement locale et désynchronisée, répartie dans les prolongements et la région somatique. Les régions actives ont été identifiées à partir d’une carte de corrélation temporale calculée en MATLAB, et leurs caractéristiques (amplitude, durée, position, fréquence) mesurées grâce à des routines établies sous IGOR. La fréquence et l’amplitude de l’activité calcique paraissent augmenter lors de l’enregistrement, ce qui suggère une sensibilité significative et une photoactivation des astrocytes, en imagerie biphotonique. La durée des impulsions laser modulerait ce phénomène. En présence d'adénosine (1-100 µM) et d’ATP (100 µM), et de façon marginale en présence d’un agoniste P2X7 non sélectif (BzATP 50-100 µM), une activité calcique synchronisée accrue est visible dans le soma et les prolongements astrocytaires en présence de tétrodotoxine qui bloque les potentiels d'action et minimise l’activité synaptique. Le mécanisme de ces réponses synchronisées reste à étudier. Aucun effet significatif n’a été observé en présence d’un agoniste spécifique P2Y1 (MRS2365 50 uM). Mon travail a permis le développement : i) de modèles murins pour l’adressage sélectif de protéines d’intérêt au niveau des astrocytes protoplasmiques ; ii) d’outils d’analyse des signaux calciques astrocytaires au niveau sub-cellulaire. Il a mis en évidence des limites possibles des protocoles standards d'enregistrement de l’activité calcique des astrocytes en imagerie biphotonique. Il confirme l’importance de l’ATP et de l’adénosine pour la signalisation astrocytaire. / Grey matter protoplasmic astrocytes are compact glial cells with highly branched processes, enwrapping synapses, and one or two endfeet contacting the blood vessels. Several neurotransmitter receptors are expressed by astrocytes, among them purinergic receptors. Upon activation of these receptors, intracellular calcium (Ca2+) transients can be induced, that, in turn, trigger gliotransmitter release (e.g. glutamate, GABA, ATP, D-serine) and participate in astrocyte-to-astrocyte signaling as well as in the communication between astrocytes and neurons or other glia. During my PhD work, I first implemented and validated several approaches for targeting transgene expression specifically to cortical astrocytes and employed them to study purinergic signaling in astrocytes. To achieve astrocyte-specific transgene expression, I used either floxed adeno-associated viral (AAV) vectors or a Cre-dependent mouse line and several mouse lines expressing the Cre recombinase under astrocyte-specific promoters. Intracerebral injections of a Cre-dependent AAV serotype 5 containing the ubiquitous CAG promoter and an enhanced green fluorescent protein (AAV5.CAG.flex.EGFP) in adult mice expressing Cre recombinase under the human glial fibrillary protein (hGFAP) promoter resulted in a non-astrocyte specific expression in the cortex. Combining inducible mouse lines expressing Cre recombinase under the glutamate aspartate transporter (GLAST) promoter with the same AAV vector resulted in a virtually astrocyte-specific expression of the reporter gene. As an alternative approach for astrocyte-specific transgene expression, we used a Cre-dependent mouse line expressing the genetically encoded Ca2+ indicator GCaMP3. Crossing this mouse line with the above described GLAST-CreERT2 mouse line or a Connexin30 (Cx30)-CreERT2 line led to selective GCaMP3 expression in cortical astrocytes. Second, I investigated both spontaneous and agonist-evoked Ca2+ transients in astrocytic processes, the investigation of which has presented a major challenge in earlier studies, due to the unspecific and weak labeling by membrane-permeable chemical Ca2+ indicators. Using the strategy developed in the first part of my work allowing an astrocyte-specific expression of the genetically encoded Ca2+ indicator GCaMP3. Using two-photon excitation fluorescence (2PEF) imaging in acute slices of the primary somatosensory cortex, I recorded Ca2+ transients in the astrocytic soma and processes. By aid of a custom-made MATLAB routine based on a temporal Pearson correlation coefficient, active regions could be identified in an unbiased manner. Evoked Ca2+ transients were quantified using custom IGOR routines. Spontaneous desynchronized Ca2+ transients occurred in the processes and rarely in the soma. Ca2+ signals appeared localized in distinct microdomains. Their frequency appeared to increase during long recordings of several hundred images, suggesting that fine astrocytes are vulnerable to photodamage under imaging conditions routine in 2PEF microscopy. The possibility to minimize photodamage, by varying the length of the femtosecond laser pulses is under investigation. Bath application of adenosine (1-100 µM) and adenosine-triphosphate (ATP, 100 µM), as well as the application of the non-selective P2X7 receptor agonist (2'(3')-O-(4-Benzoylbenzoyl)adenosine-5'-triphosphate, BzATP, 50-100 µM), in the presence of tetrodotoxin to block neuronal action potentials, evoked synchronized Ca2+ rises in the soma and the processes of astrocytes. The effect of adenosine was dose-dependent. No significant effect of the specific P2Y1 agonist (MRS2365, 50 µM) was seen. Altogether, my work sets up a powerful and versatile toolbox for studying astrocytic Ca2+ signaling at the sub-cellular level. It also pinpoints possible limits of standard two-photon recording protocols to investigate the local Ca2+ signals in fine astrocytic processes.

Astrocyte

Cre recombinase

Expression sélective des transgènes

ATP

Adénosine

Microscopie biphotonique

GCaMP3

GLAST

Cx30

Astrocyte

Cre recombinase

Astrocyte-specific transgene expression

ATP

Adenosine

Two-photon microscopy

GCaMP3

GLAST

Cx30

612.8

Investigation of spatiotemporal calcium transients in astrocytic soma and processes upon purinergic receptor activation using genetically encoded calcium sensors / Etude en microscopie biphotonique de l’activité calcique astrocytaire mesurée par des indicateurs protéiques et induite par des agonistes purinergiques

Schmidt, Elke

27 February 2015

Les astrocytes protoplasmiques de la matière grise corticale sont des cellules gliales dont les prolongements très fins et ramifiés sont en contact avec les éléments neuronaux pré- et post-synaptiques d’une part, et les vaisseaux sanguins d’autre part. Ils expriment plusieurs récepteurs des neurotransmetteurs, entre autres des récepteurs purinergiques dont l'activation facilite l’activité calcique astrocytaire et la libération de gliotransmitters (par exemple, le glutamate, le GABA, l'ATP, et la D sérine) qui régulent l’activité des neurones et des cellules gliales situées au voisinage. L’objectif de ma thèse était d’étudier in situ l’activité calcique des astrocytes et de leurs prolongements en réponse à l’application des agonistes purinergiques. Lors de ma thèse, j’ai tout d'abord testé la possibilité d’induire l’expression spécifique de gènes d’intérêt par les astrocytes corticaux de souris adultes par la technique de recombinaison Cre-LoxP. J’ai comparé les performances d’un virus adeno-associé de type 5 (AAV5) flexé (AAV5.FLEX.EGFP) et d’une souris qui exprime un indicateur calcique (GCaMP3) sous contrôle de la recombinase (souris Rosa-CAG-LSL-GCaMP3). L’injection d’AAV5.FLEX.EGFP dans le cortex d’une souris hGFAPcre n’a pas permis l’expression spécifique d’EGFP. La combinaison des souris exprimant le cre recombinase sous contrôle d’un promoteur sélectif des astrocytes (GLAST-CreERT2 et Cx30-CreERT2) avec le AAV5.FLEX.EGFP ou avec une lignée des souris Rosa-CAG-LSL-GCaMP3 permet l’expression spécifique des gènes d’intérêt (EGFP et GCaMP3) par les astrocytes corticaux. J’ai ensuite analysé l’activité calcique des astrocytes qui expriment GCaMP3. J’ai utilisé la microscopie biphotonique et enregistré l’activité calcique spontanée et évoquée par application d’agonistes purinergiques sur des tranches de cortex somatosensoriel primaire de souris adultes GLAST-CreERT2. L’activité calcique spontanée est complexe, généralement locale et désynchronisée, répartie dans les prolongements et la région somatique. Les régions actives ont été identifiées à partir d’une carte de corrélation temporale calculée en MATLAB, et leurs caractéristiques (amplitude, durée, position, fréquence) mesurées grâce à des routines établies sous IGOR. La fréquence et l’amplitude de l’activité calcique paraissent augmenter lors de l’enregistrement, ce qui suggère une sensibilité significative et une photoactivation des astrocytes, en imagerie biphotonique. La durée des impulsions laser modulerait ce phénomène. En présence d'adénosine (1-100 µM) et d’ATP (100 µM), et de façon marginale en présence d’un agoniste P2X7 non sélectif (BzATP 50-100 µM), une activité calcique synchronisée accrue est visible dans le soma et les prolongements astrocytaires en présence de tétrodotoxine qui bloque les potentiels d'action et minimise l’activité synaptique. Le mécanisme de ces réponses synchronisées reste à étudier. Aucun effet significatif n’a été observé en présence d’un agoniste spécifique P2Y1 (MRS2365 50 uM). Mon travail a permis le développement : i) de modèles murins pour l’adressage sélectif de protéines d’intérêt au niveau des astrocytes protoplasmiques ; ii) d’outils d’analyse des signaux calciques astrocytaires au niveau sub-cellulaire. Il a mis en évidence des limites possibles des protocoles standards d'enregistrement de l’activité calcique des astrocytes en imagerie biphotonique. Il confirme l’importance de l’ATP et de l’adénosine pour la signalisation astrocytaire. / Grey matter protoplasmic astrocytes are compact glial cells with highly branched processes, enwrapping synapses, and one or two endfeet contacting the blood vessels. Several neurotransmitter receptors are expressed by astrocytes, among them purinergic receptors. Upon activation of these receptors, intracellular calcium (Ca2+) transients can be induced, that, in turn, trigger gliotransmitter release (e.g. glutamate, GABA, ATP, D-serine) and participate in astrocyte-to-astrocyte signaling as well as in the communication between astrocytes and neurons or other glia. During my PhD work, I first implemented and validated several approaches for targeting transgene expression specifically to cortical astrocytes and employed them to study purinergic signaling in astrocytes. To achieve astrocyte-specific transgene expression, I used either floxed adeno-associated viral (AAV) vectors or a Cre-dependent mouse line and several mouse lines expressing the Cre recombinase under astrocyte-specific promoters. Intracerebral injections of a Cre-dependent AAV serotype 5 containing the ubiquitous CAG promoter and an enhanced green fluorescent protein (AAV5.CAG.flex.EGFP) in adult mice expressing Cre recombinase under the human glial fibrillary protein (hGFAP) promoter resulted in a non-astrocyte specific expression in the cortex. Combining inducible mouse lines expressing Cre recombinase under the glutamate aspartate transporter (GLAST) promoter with the same AAV vector resulted in a virtually astrocyte-specific expression of the reporter gene. As an alternative approach for astrocyte-specific transgene expression, we used a Cre-dependent mouse line expressing the genetically encoded Ca2+ indicator GCaMP3. Crossing this mouse line with the above described GLAST-CreERT2 mouse line or a Connexin30 (Cx30)-CreERT2 line led to selective GCaMP3 expression in cortical astrocytes. Second, I investigated both spontaneous and agonist-evoked Ca2+ transients in astrocytic processes, the investigation of which has presented a major challenge in earlier studies, due to the unspecific and weak labeling by membrane-permeable chemical Ca2+ indicators. Using the strategy developed in the first part of my work allowing an astrocyte-specific expression of the genetically encoded Ca2+ indicator GCaMP3. Using two-photon excitation fluorescence (2PEF) imaging in acute slices of the primary somatosensory cortex, I recorded Ca2+ transients in the astrocytic soma and processes. By aid of a custom-made MATLAB routine based on a temporal Pearson correlation coefficient, active regions could be identified in an unbiased manner. Evoked Ca2+ transients were quantified using custom IGOR routines. Spontaneous desynchronized Ca2+ transients occurred in the processes and rarely in the soma. Ca2+ signals appeared localized in distinct microdomains. Their frequency appeared to increase during long recordings of several hundred images, suggesting that fine astrocytes are vulnerable to photodamage under imaging conditions routine in 2PEF microscopy. The possibility to minimize photodamage, by varying the length of the femtosecond laser pulses is under investigation. Bath application of adenosine (1-100 µM) and adenosine-triphosphate (ATP, 100 µM), as well as the application of the non-selective P2X7 receptor agonist (2'(3')-O-(4-Benzoylbenzoyl)adenosine-5'-triphosphate, BzATP, 50-100 µM), in the presence of tetrodotoxin to block neuronal action potentials, evoked synchronized Ca2+ rises in the soma and the processes of astrocytes. The effect of adenosine was dose-dependent. No significant effect of the specific P2Y1 agonist (MRS2365, 50 µM) was seen. Altogether, my work sets up a powerful and versatile toolbox for studying astrocytic Ca2+ signaling at the sub-cellular level. It also pinpoints possible limits of standard two-photon recording protocols to investigate the local Ca2+ signals in fine astrocytic processes.

Astrocyte

Cre recombinase

Expression sélective des transgènes

ATP

Adénosine

Microscopie biphotonique

GCaMP3

GLAST

Cx30

Astrocyte

Cre recombinase

Astrocyte-specific transgene expression

ATP

Adenosine

Two-photon microscopy

GCaMP3

GLAST

Cx30

612.8

Investigation of spatiotemporal calcium transients in astrocytic soma and processes upon purinergic receptor activation using genetically encoded calcium sensors / Etude en microscopie biphotonique de l’activité calcique astrocytaire mesurée par des indicateurs protéiques et induite par des agonistes purinergiques

Schmidt, Elke

27 February 2015

Les astrocytes protoplasmiques de la matière grise corticale sont des cellules gliales dont les prolongements très fins et ramifiés sont en contact avec les éléments neuronaux pré- et post-synaptiques d’une part, et les vaisseaux sanguins d’autre part. Ils expriment plusieurs récepteurs des neurotransmetteurs, entre autres des récepteurs purinergiques dont l'activation facilite l’activité calcique astrocytaire et la libération de gliotransmitters (par exemple, le glutamate, le GABA, l'ATP, et la D sérine) qui régulent l’activité des neurones et des cellules gliales situées au voisinage. L’objectif de ma thèse était d’étudier in situ l’activité calcique des astrocytes et de leurs prolongements en réponse à l’application des agonistes purinergiques. Lors de ma thèse, j’ai tout d'abord testé la possibilité d’induire l’expression spécifique de gènes d’intérêt par les astrocytes corticaux de souris adultes par la technique de recombinaison Cre-LoxP. J’ai comparé les performances d’un virus adeno-associé de type 5 (AAV5) flexé (AAV5.FLEX.EGFP) et d’une souris qui exprime un indicateur calcique (GCaMP3) sous contrôle de la recombinase (souris Rosa-CAG-LSL-GCaMP3). L’injection d’AAV5.FLEX.EGFP dans le cortex d’une souris hGFAPcre n’a pas permis l’expression spécifique d’EGFP. La combinaison des souris exprimant le cre recombinase sous contrôle d’un promoteur sélectif des astrocytes (GLAST-CreERT2 et Cx30-CreERT2) avec le AAV5.FLEX.EGFP ou avec une lignée des souris Rosa-CAG-LSL-GCaMP3 permet l’expression spécifique des gènes d’intérêt (EGFP et GCaMP3) par les astrocytes corticaux. J’ai ensuite analysé l’activité calcique des astrocytes qui expriment GCaMP3. J’ai utilisé la microscopie biphotonique et enregistré l’activité calcique spontanée et évoquée par application d’agonistes purinergiques sur des tranches de cortex somatosensoriel primaire de souris adultes GLAST-CreERT2. L’activité calcique spontanée est complexe, généralement locale et désynchronisée, répartie dans les prolongements et la région somatique. Les régions actives ont été identifiées à partir d’une carte de corrélation temporale calculée en MATLAB, et leurs caractéristiques (amplitude, durée, position, fréquence) mesurées grâce à des routines établies sous IGOR. La fréquence et l’amplitude de l’activité calcique paraissent augmenter lors de l’enregistrement, ce qui suggère une sensibilité significative et une photoactivation des astrocytes, en imagerie biphotonique. La durée des impulsions laser modulerait ce phénomène. En présence d'adénosine (1-100 µM) et d’ATP (100 µM), et de façon marginale en présence d’un agoniste P2X7 non sélectif (BzATP 50-100 µM), une activité calcique synchronisée accrue est visible dans le soma et les prolongements astrocytaires en présence de tétrodotoxine qui bloque les potentiels d'action et minimise l’activité synaptique. Le mécanisme de ces réponses synchronisées reste à étudier. Aucun effet significatif n’a été observé en présence d’un agoniste spécifique P2Y1 (MRS2365 50 uM). Mon travail a permis le développement : i) de modèles murins pour l’adressage sélectif de protéines d’intérêt au niveau des astrocytes protoplasmiques ; ii) d’outils d’analyse des signaux calciques astrocytaires au niveau sub-cellulaire. Il a mis en évidence des limites possibles des protocoles standards d'enregistrement de l’activité calcique des astrocytes en imagerie biphotonique. Il confirme l’importance de l’ATP et de l’adénosine pour la signalisation astrocytaire. / Grey matter protoplasmic astrocytes are compact glial cells with highly branched processes, enwrapping synapses, and one or two endfeet contacting the blood vessels. Several neurotransmitter receptors are expressed by astrocytes, among them purinergic receptors. Upon activation of these receptors, intracellular calcium (Ca2+) transients can be induced, that, in turn, trigger gliotransmitter release (e.g. glutamate, GABA, ATP, D-serine) and participate in astrocyte-to-astrocyte signaling as well as in the communication between astrocytes and neurons or other glia. During my PhD work, I first implemented and validated several approaches for targeting transgene expression specifically to cortical astrocytes and employed them to study purinergic signaling in astrocytes. To achieve astrocyte-specific transgene expression, I used either floxed adeno-associated viral (AAV) vectors or a Cre-dependent mouse line and several mouse lines expressing the Cre recombinase under astrocyte-specific promoters. Intracerebral injections of a Cre-dependent AAV serotype 5 containing the ubiquitous CAG promoter and an enhanced green fluorescent protein (AAV5.CAG.flex.EGFP) in adult mice expressing Cre recombinase under the human glial fibrillary protein (hGFAP) promoter resulted in a non-astrocyte specific expression in the cortex. Combining inducible mouse lines expressing Cre recombinase under the glutamate aspartate transporter (GLAST) promoter with the same AAV vector resulted in a virtually astrocyte-specific expression of the reporter gene. As an alternative approach for astrocyte-specific transgene expression, we used a Cre-dependent mouse line expressing the genetically encoded Ca2+ indicator GCaMP3. Crossing this mouse line with the above described GLAST-CreERT2 mouse line or a Connexin30 (Cx30)-CreERT2 line led to selective GCaMP3 expression in cortical astrocytes. Second, I investigated both spontaneous and agonist-evoked Ca2+ transients in astrocytic processes, the investigation of which has presented a major challenge in earlier studies, due to the unspecific and weak labeling by membrane-permeable chemical Ca2+ indicators. Using the strategy developed in the first part of my work allowing an astrocyte-specific expression of the genetically encoded Ca2+ indicator GCaMP3. Using two-photon excitation fluorescence (2PEF) imaging in acute slices of the primary somatosensory cortex, I recorded Ca2+ transients in the astrocytic soma and processes. By aid of a custom-made MATLAB routine based on a temporal Pearson correlation coefficient, active regions could be identified in an unbiased manner. Evoked Ca2+ transients were quantified using custom IGOR routines. Spontaneous desynchronized Ca2+ transients occurred in the processes and rarely in the soma. Ca2+ signals appeared localized in distinct microdomains. Their frequency appeared to increase during long recordings of several hundred images, suggesting that fine astrocytes are vulnerable to photodamage under imaging conditions routine in 2PEF microscopy. The possibility to minimize photodamage, by varying the length of the femtosecond laser pulses is under investigation. Bath application of adenosine (1-100 µM) and adenosine-triphosphate (ATP, 100 µM), as well as the application of the non-selective P2X7 receptor agonist (2'(3')-O-(4-Benzoylbenzoyl)adenosine-5'-triphosphate, BzATP, 50-100 µM), in the presence of tetrodotoxin to block neuronal action potentials, evoked synchronized Ca2+ rises in the soma and the processes of astrocytes. The effect of adenosine was dose-dependent. No significant effect of the specific P2Y1 agonist (MRS2365, 50 µM) was seen. Altogether, my work sets up a powerful and versatile toolbox for studying astrocytic Ca2+ signaling at the sub-cellular level. It also pinpoints possible limits of standard two-photon recording protocols to investigate the local Ca2+ signals in fine astrocytic processes.

Astrocyte

Cre recombinase

Expression sélective des transgènes

ATP

Adénosine

Microscopie biphotonique

GCaMP3

GLAST

Cx30

Astrocyte

Cre recombinase

Astrocyte-specific transgene expression

ATP

Adenosine

Two-photon microscopy

GCaMP3

GLAST

Cx30

612.8

Phosphate starvation alters calcium signalling in roots of Arabidopsis thaliana

Matthus, Elsa

January 2019

Low bioavailability of phosphate (P) due to low concentration and high immobility in soils is a key limiting factor in crop production. Application of excess amounts of P fertilizer is costly and by no means sustainable, as world-wide P resources are finite and running out. To facilitate the breeding of crops adapted to low-input soils, it is essential to understand the consequences of P deficiency. The second messenger calcium (Ca2+) is known to signal in plant development and stress perception, and most recently its direct role in signalling nutrient availability and deficiency has been partially elucidated. The use of Ca2+ as a signal has to be tightly controlled, as Ca2+ easily complexes with P groups and therefore is highly toxic to cellular P metabolism. It is unknown whether Ca2+ signals P availability or whether signalling is altered under P starvation conditions. The aim of this PhD project was to characterise the use of Ca2+ ions, particularly cytosolic free Ca2+ ([Ca2+]cyt), in stress signalling by P-starved roots of the model plant Arabidopsis thaliana. The hypothesis was that under P starvation and a resulting decreased cellular P pool, the use of [Ca2+]cyt may have to be restricted to avoid cytotoxic complexation of Ca2+ with limited P groups. Employing a range of genetically encoded Ca2+ reporters in Arabidopsis, P starvation but not nitrogen starvation was found to strongly dampen the root [Ca2+]cyt increases evoked by mechanical, salt, osmotic, and oxidative stress as well as by extracellular nucleotides. The strongly altered root [Ca2+]cyt response to extracellular nucleotides was shown to manifest itself during seedling development under chronic P deprivation, but could be reversed by P resupply. Fluorescent imaging elucidated that P-starved roots showed a normal [Ca2+]cyt response to extracellular nucleotides at the apex, but a strongly dampened [Ca2+]cyt response in distal parts of the root tip, correlating with high reactive oxygen species (ROS) levels induced by P starvation. Excluding iron, as well as P, rescued the altered [Ca2+]cyt response, and restored ROS levels to those seen under nutrient-replete conditions. P availability was not signalled through [Ca2+]cyt. In another part of this PhD project, a library of 77 putative Ca2+ channel mutants was compiled and screened for aberrant root hair growth under P starvation conditions. No mutant line showed aberrant root hair growth. These results indicate that P starvation strongly affects stress-induced [Ca2+]cyt modulations. The data generated in this thesis further understanding of how plants can integrate nutritional and environmental cues, adding another layer of complexity to the use of Ca2+ as a signal transducer.