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.

Activity-based automatic ROI generation (AARG) analysis of dendritic spine calcium transients reveals distance-dependent activity of voltage-gated calcium channels

Gilbride, Charlie Jonathan

21 February 2018

No description available.

570

Automatic ROI generation

Dendritic spines

Calcium transients

Synaptic plasticity

Biologie (PPN619462639)

MECHANISMS OF CALCIUM-MEDIATED ARRHYTHMOGENESIS IN HEART FAILURE

Hoeker, Gregory Scott

January 2008

No description available.

Engineering, Biomedical

SCR

Calcium

calcium transients

HF

calcium release

SCR Events

amplitude

Empreinte développementale des cellules sensorielles auditives / Developmental imprint of auditory sensory cells

Harrus, Anne-Gabrielle

30 November 2018

Les cellules ciliées internes (CCI) sont les cellules sensorielles de l'organe de l'audition, elles transforment les ondes sonores en messages nerveux. Avant l’entrée en fonction de la cochlée, les CCI émettent spontanément des potentiels d’action (PA) calciques, ce qui active la voie auditive ascendante et assure le développement de l’axe tonotopique, à savoir la représentation du codage en fréquence, dans chaque relais de la voie auditive. Le profil et les mécanismes à l’origine des PA des CCI sont fortement débattus. Nous nous sommes donc attachés à étudier l’empreinte développementale des cellules sensorielles, c'est à dire déterminer le profil et les mécanismes à l’origine de leur activité.Après avoir incubé l’épithélium neuro-sensoriel avec la sonde calcique Fura2-AM, nous avons observé des vagues calciques se propageant le long des cellules de soutien et des cellules sensorielles. Plus précisément, l’activité des cellules ciliées se caractérisait par des élévations transitoires de calcium (pics calciques) à intervalles de temps réguliers. Nous avons ensuite démontré que les pics calciques des CCI correspondaient bien à des bouffées de PA en mesurant simultanément les oscillations calciques et l’émission de PA en patch-clamp. La fréquence, la durée et la distribution temporelle des pics calciques des CCI étaient en grande partie invariantes le long de l’axe base-apex de la cochlée. Enfin, les cellules voisines montraient une activité fortement synchrone à l’inverse des cellules spatialement éloignées. Ces résultats indiquent donc que l’activité des CCI est majoritairement identique le long de l’axe tonotopique de la cochlée.Nous nous sommes ensuite intéressés au mécanisme responsable de l’activité spontanée, la dépendance à l’ATP. L’incubation d’apyrase, une ecto-nucléotidase, entraine une diminution de l’activité des cellules de soutien, à savoir une réduction de l’aire et de la vitesse de propagation des vagues calciques. En revanche, l'activité des CCI n'est pas altérée par la déplétion d’ATP. Ces résultats suggèrent 2 mécanismes distincts, le premier ATP-dépendant et le second ATP-indépendant dans les cellules de soutien et sensorielles, respectivement.L’ensemble de ces résultats indique que la maturation des centres supérieurs serait déterminée par l’activation synchrone d’un nombre limité de cellules sensorielles. / During development, the sensory cells of the cochlea, the inner hair cells (IHCs), fire spontaneous calcium action potentials. This spontaneous spiking activity at the pre-hearing stage allows the IHCs to automatically stimulate the auditory nerve fibers and hence, ensures the proper shaping of the tonotopic organization along the ascending auditory pathway. Spontaneous spiking patterns may depend on the IHCs position on the cochlea (the tonotopic axis). Those patterns may also rely on ATP secretion from neighboring supporting cells. In this study, we used calcium imaging in the immature neuro-sensory epithelium of the cochlea, the Kölliker´s organ, to gain insights in the IHCs spiking activity. After loading the Kölliker´s organ with the calcium dye fura-2 AM, propagation of spontaneous calcium waves was readily observed across supporting and sensory cells. Both basal and apical IHCs were characterized by similar spontaneous calcium transients interspaced with silent periods, reminiscent of bursts of action potential recorded in patch-clamp. In addition, neighboring cells show a strong degree of synchronous activity. Incubation with apyrase, which hydrolyzes ATP, prevents the spontaneous calcium increase that propagates across the supporting cells within the Kölliker's organ. However, it leaves the spontaneous calcium transients in IHCs mostly unaffected. All these results show that the tonotopic map refinement in higher auditory centers comes from a coordinated activity of neighboring sensory cells, whose activity seems to be independent of ATP

Cochlée

Potentiel d’action

Transitoires calciques

Imagerie calcique

Ecto-Nucléotidase

Cochlea

Action potential

Calcium transients

Calcium imaging

Ectonucleotidase

Optické měření elektromechanických projevů srdečních buněk / Optical Measurement of Electromechanical Characteristics of Heart Cells

Čmiel, Vratislav

January 2016

Dissertation is focused on the application of optical measurement methods using techniques of optical microscopy and fluorescence microscopy in measurements of electromechanical characteristics of isolated cardiac cells and clusters of differentiated cardiomyocytes. The first proposed method uses a practical combination of fluorescence microscopy equipped with fluorescent fast and high-resolution camera and atomic force microscopy for simultaneous measurement of calcium transients and contraction of cardiomyocyte clusters. The signals obtained undergoes filtration, processing and analysis. Result function parameters obtained by analyzing signals after application of caffeine are evaluated by comparison with functional parameters obtained during the control measurement. The second proposed method is applied to the cardiomyocyte clusters for the purpose of cardiomyocyte contraction signals measurement. The signals obtained by optical methods are analyzed and compared with the reference signal obtained using atomic force microscopy. Optical measurement method of cell contractins based on detection of cell ends using adjusting of microscopy images by re-sharpening and fluorescence method for cardiomyocyte contractions measurements were designed to increase realiability in simultaneous measurement of cell contractions simultaneously with calcium transients in isolated cardiomyocytes experiments.