Your search keyword '"Moritz Armbruster"' showing total 20 results

1. Kir4.1 channels contribute to astrocyte CO2/H+-sensitivity and the drive to breathe

Author

Colin M. Cleary, Jack L. Browning, Moritz Armbruster, Cleyton R. Sobrinho, Monica L. Strain, Sarvin Jahanbani, Jaseph Soto-Perez, Virginia E. Hawkins, Chris G. Dulla, Michelle L. Olsen, and Daniel K. Mulkey

Subjects

Biology (General), QH301-705.5

Abstract

Abstract Astrocytes in the retrotrapezoid nucleus (RTN) stimulate breathing in response to CO2/H+, however, it is not clear how these cells detect changes in CO2/H+. Considering Kir4.1/5.1 channels are CO2/H+-sensitive and important for several astrocyte-dependent processes, we consider Kir4.1/5.1 a leading candidate CO2/H+ sensor in RTN astrocytes. To address this, we show that RTN astrocytes express Kir4.1 and Kir5.1 transcripts. We also characterized respiratory function in astrocyte-specific inducible Kir4.1 knockout mice (Kir4.1 cKO); these mice breathe normally under room air conditions but show a blunted ventilatory response to high levels of CO2, which could be partly rescued by viral mediated re-expression of Kir4.1 in RTN astrocytes. At the cellular level, astrocytes in slices from astrocyte-specific inducible Kir4.1 knockout mice are less responsive to CO2/H+ and show a diminished capacity for paracrine modulation of respiratory neurons. These results suggest Kir4.1/5.1 channels in RTN astrocytes contribute to respiratory behavior.

Published

2024

2. Effects of fluorescent glutamate indicators on neurotransmitter diffusion and uptake

Author

Moritz Armbruster, Chris G Dulla, and Jeffrey S Diamond

Subjects

diffusion, iGluSnFR, glutamate transport, astrocytes, Medicine, Science, Biology (General), QH301-705.5

Abstract

Genetically encoded fluorescent glutamate indicators (iGluSnFRs) enable neurotransmitter release and diffusion to be visualized in intact tissue. Synaptic iGluSnFR signal time courses vary widely depending on experimental conditions, often lasting 10–100 times longer than the extracellular lifetime of synaptically released glutamate estimated with uptake measurements. iGluSnFR signals typically also decay much more slowly than the unbinding kinetics of the indicator. To resolve these discrepancies, here we have modeled synaptic glutamate diffusion, uptake and iGluSnFR activation to identify factors influencing iGluSnFR signal waveforms. Simulations suggested that iGluSnFR competes with transporters to bind synaptically released glutamate, delaying glutamate uptake. Accordingly, synaptic transporter currents recorded from iGluSnFR-expressing astrocytes in mouse cortex were slower than those in control astrocytes. Simulations also suggested that iGluSnFR reduces free glutamate levels in extrasynaptic spaces, likely limiting extrasynaptic receptor activation. iGluSnFR and lower affinity variants, nonetheless, provide linear indications of vesicle release, underscoring their value for optical quantal analysis.

Published

2020

3. Dynamin phosphorylation controls optimization of endocytosis for brief action potential bursts

Author

Moritz Armbruster, Mirko Messa, Shawn M Ferguson, Pietro De Camilli, and Timothy A Ryan

Subjects

endocytosis, synaptic vesicle, dynamin, phosphorylation, Medicine, Science, Biology (General), QH301-705.5

Abstract

Modulation of synaptic vesicle retrieval is considered to be potentially important in steady-state synaptic performance. Here we show that at physiological temperature endocytosis kinetics at hippocampal and cortical nerve terminals show a bi-phasic dependence on electrical activity. Endocytosis accelerates for the first 15–25 APs during bursts of action potential firing, after which it slows with increasing burst length creating an optimum stimulus for this kinetic parameter. We show that activity-dependent acceleration is only prominent at physiological temperature and that the mechanism of this modulation is based on the dephosphorylation of dynamin 1. Nerve terminals in which dynamin 1 and 3 have been replaced with dynamin 1 harboring dephospho- or phospho-mimetic mutations in the proline-rich domain eliminate the acceleration phase by either setting endocytosis at an accelerated state or a decelerated state, respectively.

Published

2013

4. Cortical Parvalbumin-Positive Interneuron Development and Function Are Altered in the APC Conditional Knockout Mouse Model of Infantile and Epileptic Spasms Syndrome

Author

Rachael F. Ryner, Isabel D. Derera, Moritz Armbruster, Anar Kansara, Mary E. Sommer, Antonella Pirone, Farzad Noubary, Michele Jacob, and Chris G. Dulla

Subjects

General Neuroscience

Abstract

Infantile and epileptic spasms syndrome (IESS) is a childhood epilepsy syndrome characterized by infantile or late-onset spasms, abnormal neonatal EEG, and epilepsy. Few treatments exist for IESS, clinical outcomes are poor, and the molecular and circuit-level etiologies of IESS are not well understood. Multiple human IESS risk genes are linked to Wnt/β-catenin signaling, a pathway that controls developmental transcriptional programs and promotes glutamatergic excitation via β-catenin’s role as a synaptic scaffold. We previously showed that deleting adenomatous polyposis coli (APC), a component of the β-catenin destruction complex, in excitatory neurons (APC cKO mice, APCfl/flx CaMKIIαCre) increased β-catenin levels in developing glutamatergic neurons and led to infantile behavioral spasms, abnormal neonatal EEG, and adult epilepsy. Here, we tested the hypothesis that the development of GABAergic interneurons (INs) is disrupted in APC cKO male and female mice. IN dysfunction is implicated in human IESS, is a feature of other rodent models of IESS, and may contribute to the manifestation of spasms and seizures. We found that parvalbumin-positive INs (PV+INs), an important source of cortical inhibition, were decreased in number, underwent disproportionate developmental apoptosis, and had altered dendrite morphology at P9, the peak of behavioral spasms. PV+INs received excessive excitatory input, and their intrinsic ability to fire action potentials was reduced at all time points examined (P9, P14, P60). Subsequently, GABAergic transmission onto pyramidal neurons was uniquely altered in the somatosensory cortex of APC cKO mice at all ages, with both decreased IPSC input at P14 and enhanced IPSC input at P9 and P60. These results indicate that inhibitory circuit dysfunction occurs in APC cKOs and, along with known changes in excitation, may contribute to IESS-related phenotypes.SIGNIFICANCE STATEMENTInfantile and epileptic spasms syndrome (IESS) is a devastating epilepsy with limited treatment options and poor clinical outcomes. The molecular, cellular, and circuit disruptions that cause infantile spasms and seizures are largely unknown, but inhibitory GABAergic interneuron dysfunction has been implicated in rodent models of IESS and may contribute to human IESS. Here, we use a rodent model of IESS, the APC cKO mouse, in which β-catenin signaling is increased in excitatory neurons. This results in altered parvalbumin-positive GABAergic interneuron development and GABAergic synaptic dysfunction throughout life, showing that pathology arising in excitatory neurons can initiate long-term interneuron dysfunction. Our findings further implicate GABAergic dysfunction in IESS, even when pathology is initiated in other neuronal types.

Published

2023

5. Neuronal activity drives pathway-specific depolarization of peripheral astrocyte processes

Author

Moritz Armbruster, Saptarnab Naskar, Jacqueline P. Garcia, Mary Sommer, Elliot Kim, Yoav Adam, Philip G. Haydon, Edward S. Boyden, Adam E. Cohen, and Chris G. Dulla

Subjects

General Neuroscience

Published

2022

6. Neuronal activity drives pathway-specific depolarization of peripheral astrocyte processes

Author

Moritz, Armbruster, Saptarnab, Naskar, Jacqueline P, Garcia, Mary, Sommer, Elliot, Kim, Yoav, Adam, Philip G, Haydon, Edward S, Boyden, Adam E, Cohen, and Chris G, Dulla

Subjects

Neurons, Mice, Astrocytes, Synapses, Animals, Glutamic Acid, Neuroglia

Abstract

Astrocytes are glial cells that interact with neuronal synapses via their distal processes, where they remove glutamate and potassium (K

Published

2021

7. Neuronal activity drives pathway-specific depolarization of astrocyte distal processes

Author

Yoav Adam, Mary E. Sommer, Naskar S, Adam E. Cohen, Garcia J, Moritz Armbruster, Edward S. Boyden, Philip G. Haydon, Kim E, and Chris G. Dulla

Subjects

Glutamate uptake, Membrane potential, medicine.anatomical_structure, Chemistry, Glutamate receptor, Extracellular, medicine, Premovement neuronal activity, Depolarization, Efflux, Astrocyte, Cell biology

Abstract

Astrocytes are glial cells that interact with neuronal synapses via their distal processes, where they remove glutamate and potassium (K+) from the extracellular space following neuronal activity. Astrocyte clearance of both glutamate and K+is voltage-dependent, but astrocyte membrane potential (Vm) has been thought to be largely invariant. As a result, these voltage-dependencies have not been considered relevant to astrocyte function. Using genetically encoded voltage indicators enabling the measurement of Vmat distal astrocyte processes (DAPs), we report large, rapid, focal, and pathway-specific depolarizations in DAPs during neuronal activity. These activity-dependent astrocyte depolarizations are driven by action potential-mediated presynaptic K+efflux and electrogenic glutamate transporters. We find that DAP depolarization inhibits astrocyte glutamate clearance during neuronal activity, enhancing neuronal activation by glutamate. This represents a novel class of sub-cellular astrocyte membrane dynamics and a new form of astrocyte-neuron interaction.One Sentence SummaryGenetically encoded voltage imaging of astrocytes shows that presynaptic neuronal activity drives focal astrocyte depolarization, contributing to activity-dependent inhibition of glutamate uptake.

Published

2021

8. Tonic Activation of GluN2C/GluN2D-Containing NMDA Receptors by Ambient Glutamate Facilitates Cortical Interneuron Maturation

Author

Lauren A. Lau, Chris G. Dulla, Jayashree Chadchankar, Elizabeth Hanson, Farzad Noubary, Moritz Armbruster, Zin-Juan Klaft, Sharon A. Swanger, Mary E. Sommer, Stephen J. Moss, and Stephen F. Traynelis

Subjects

0301 basic medicine, Interneuron, biology, musculoskeletal, neural, and ocular physiology, General Neuroscience, Glutamate receptor, Inhibitory postsynaptic potential, Tonic (physiology), 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, nervous system, medicine, biology.protein, GABAergic, NMDA receptor, Premovement neuronal activity, Neuroscience, 030217 neurology & neurosurgery, Parvalbumin

Abstract

Developing cortical GABAergic interneurons rely on genetic programs, neuronal activity, and environmental cues to construct inhibitory circuits during early postnatal development. Disruption of these events can cause long-term changes in cortical inhibition and may be involved in neurological disorders associated with inhibitory circuit dysfunction. We hypothesized that tonic glutamate signaling in the neonatal cortex contributes to, and is necessary for, the maturation of cortical interneurons. To test this hypothesis, we used mice of both sexes to quantify extracellular glutamate concentrations in the cortex during development, measure ambient glutamate-mediated activation of developing cortical interneurons, and manipulate tonic glutamate signaling using subtype-specific NMDA receptor antagonistsin vitroandin vivo. We report that ambient glutamate levels are high (≈100 nm) in the neonatal cortex and decrease (to ≈50 nm) during the first weeks of life, coincident with increases in astrocytic glutamate uptake. Consistent with elevated ambient glutamate, putative parvalbumin-positive interneurons in the cortex (identified usingG42:GAD1-eGFPreporter mice) exhibit a transient, tonic NMDA current at the end of the first postnatal week. GluN2C/GluN2D-containing NMDA receptors mediate the majority of this current and contribute to the resting membrane potential and intrinsic properties of developing putative parvalbumin interneurons. Pharmacological blockade of GluN2C/GluN2D-containing NMDA receptorsin vivoduring the period of tonic interneuron activation, but not later, leads to lasting decreases in interneuron morphological complexity and causes deficits in cortical inhibition later in life. These results demonstrate that dynamic ambient glutamate signaling contributes to cortical interneuron maturation via tonic activation of GluN2C/GluN2D-containing NMDA receptors.SIGNIFICANCE STATEMENTInhibitory GABAergic interneurons make up 20% of cortical neurons and are critical to controlling cortical network activity. Dysfunction of cortical inhibition is associated with multiple neurological disorders, including epilepsy. Establishing inhibitory cortical networks requiresin uteroproliferation, differentiation, and migration of immature GABAergic interneurons, and subsequent postnatal morphological maturation and circuit integration. Here, we demonstrate that ambient glutamate provides tonic activation of immature, putative parvalbumin-positive GABAergic interneurons in the neonatal cortex via high-affinity NMDA receptors. When this activation is blocked, GABAergic interneuron maturation is disrupted, and cortical networks exhibit lasting abnormal hyperexcitability. We conclude that temporally precise activation of developing cortical interneurons by ambient glutamate is critically important for establishing normal cortical inhibition.

Published

2019

9. Effects of fluorescent glutamate indicators on neurotransmitter diffusion and uptake

Author

Jeffrey S. Diamond, Chris G. Dulla, and Moritz Armbruster

Subjects

Male, 0301 basic medicine, Mouse, QH301-705.5, Excitatory Amino Acids, Science, Diffusion, Kinetics, Glutamic Acid, General Biochemistry, Genetics and Molecular Biology, Mice, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, glutamate transport, Extracellular, Animals, Biology (General), Diffusion (business), Neurotransmitter, iGluSnFR, Fluorescent Dyes, 030304 developmental biology, Neurotransmitter Agents, Stochastic Processes, 0303 health sciences, General Immunology and Microbiology, Chemistry, General Neuroscience, Vesicle, diffusion, astrocytes, Glutamate receptor, Transporter, General Medicine, Fluorescence, Mice, Inbred C57BL, 030104 developmental biology, Synapses, Biophysics, Medicine, Female, Monte Carlo Method, 030217 neurology & neurosurgery, Research Article, Neuroscience

Abstract

Genetically encoded fluorescent glutamate indicators (iGluSnFRs) enable neurotransmitter release and diffusion to be visualized in intact tissue. Synaptic iGluSnFR signal time courses vary widely depending on experimental conditions and often last 10-100 times longer than the extracellular lifetime of synaptically released glutamate estimated with uptake measurements. iGluSnFR signals typically also decay much more slowly than the unbinding kinetics of the indicator. To resolve these discrepancies, here we have modeled synaptic glutamate diffusion, uptake and iGluSnFR activation to identify factors influencing iGluSnFR signal waveforms. Simulations suggested that iGluSnFR competes with transporters to bind synaptically released glutamate, delaying glutamate uptake. Accordingly, synaptic transporter currents recorded in iGluSnFR-expressing cortical astrocytes were slower than those in control astrocytes. Simulations also suggested that iGluSnFR reduces free glutamate levels in extrasynaptic spaces, likely limiting extrasynaptic receptor activation. iGluSnFR and lower-affinity variants nonetheless provide linear indications of vesicle release, underscoring their value for optical quantal analysis.

Published

2020

10. Author response: Effects of fluorescent glutamate indicators on neurotransmitter diffusion and uptake

Author

Jeffrey S. Diamond, Moritz Armbruster, and Chris G. Dulla

Subjects

chemistry.chemical_compound, Chemistry, Biophysics, Glutamate receptor, Diffusion (business), Neurotransmitter, Fluorescence

Published

2020

11. Astrocytic glutamate uptake is slow and does not limit neuronal NMDA receptor activation in the neonatal neocortex

Author

Lauren Andresen, Moritz Armbruster, Niels C. Danbolt, Chris G. Dulla, David Cantu, Elizabeth Hanson, and Amaro Taylor

Subjects

Neocortex, Synaptogenesis, Glutamate receptor, Hippocampus, Biology, Neurotransmission, Cellular and Molecular Neuroscience, Electrophysiology, medicine.anatomical_structure, nervous system, Neurology, Extracellular, medicine, NMDA receptor, Neuroscience

Abstract

Glutamate uptake by astrocytes controls the time course of glutamate in the extracellular space and affects neurotransmission, synaptogenesis, and circuit development. Astrocytic glutamate uptake has been shown to undergo post-natal maturation in the hippocampus, but has been largely unexplored in other brain regions. Notably, glutamate uptake has never been examined in the developing neocortex. In these studies, we investigated the development of astrocytic glutamate transport, intrinsic membrane properties, and control of neuronal NMDA receptor activation in the developing neocortex. Using astrocytic and neuronal electrophysiology, immunofluorescence, and Western blot analysis we show that: (1) glutamate uptake in the neonatal neocortex is slow relative to neonatal hippocampus; (2) astrocytes in the neonatal neocortex undergo a significant maturation of intrinsic membrane properties; (3) slow glutamate uptake is accompanied by lower expression of both GLT-1 and GLAST; (4) glutamate uptake is less dependent on GLT-1 in neonatal neocortex than in neonatal hippocampus; and (5) the slow glutamate uptake we report in the neonatal neocortex corresponds to minimal astrocytic control of neuronal NMDA receptor activation. Taken together, our results clearly show fundamental differences between astrocytic maturation in the developing neocortex and hippocampus, and corresponding changes in how astrocytes control glutamate signaling.

Published

2015

12. WONOEP appraisal: Molecular and cellular imaging in epilepsy

Author

Kyle P. Lillis, Istvan Mody, Jokūbas Žiburkus, Moritz Armbruster, Douglas A. Coulter, Uwe Heinemann, Atul Maheshwari, and Chris G. Dulla

Subjects

Pathology, medicine.medical_specialty, Population, Biology, Electroencephalography, Article, Epilepsy, Calcium imaging, medicine, Biological neural network, Animals, Humans, education, Fluorescent Dyes, education.field_of_study, medicine.diagnostic_test, Magnetic resonance imaging, medicine.disease, Molecular Imaging, Microscopy, Fluorescence, Multiphoton, Neurology, Positron emission tomography, Positron-Emission Tomography, Neurology (clinical), Molecular imaging, Neuroscience

Abstract

Great advancements have been made in understanding the basic mechanisms of ictogenesis using single-cell electrophysiology (e.g., patch clamp, sharp electrode), large-scale electrophysiology (e.g., electroencephalography [EEG], field potential recording), and large-scale imaging (magnetic resonance imaging [MRI], positron emission tomography [PET], calcium imaging of acetoxymethyl ester [AM] dye-loaded tissue). Until recently, it has been challenging to study experimentally how population rhythms emerge from cellular activity. Newly developed optical imaging technologies hold promise for bridging this gap by making it possible to simultaneously record the many cellular elements that comprise a neural circuit. Furthermore, easily accessible genetic technologies for targeting expression of fluorescent protein-based indicators make it possible to study, in animal models of epilepsy, epileptogenic changes to neural circuits over long periods. In this review, we summarize some of the latest imaging tools (fluorescent probes, gene delivery methods, and microscopy techniques) that can lead to the advancement of cell- and circuit-level understanding of epilepsy, which in turn may inform and improve development of next generation antiepileptic and antiepileptogenic drugs.

Published

2015

13. Control and Plasticity of the Presynaptic Action Potential Waveform at Small CNS Nerve Terminals

Author

Géraldine Gouzer, Michael B. Hoppa, Moritz Armbruster, and Timothy A. Ryan

Subjects

Neurons, Neuronal Plasticity, Potassium Channels, Voltage-dependent calcium channel, General Neuroscience, Neuroscience(all), Regulator, Presynaptic Terminals, Hippocampus, Action Potentials, Biology, Exocytosis, Potassium channel, Article, Rats, Rats, Sprague-Dawley, Modulation, Neuroplasticity, Synapses, Waveform, Animals, Calcium, Calcium Channels, Neuroscience

Abstract

The steep dependence of exocytosis on Ca(2+) entry at nerve terminals implies that voltage control of both Ca(2+) channel opening and the driving force for Ca(2+) entry are powerful levers in sculpting synaptic efficacy. Using fast, genetically encoded voltage indicators in dissociated primary neurons, we show that at small nerve terminals K(+) channels constrain the peak voltage of the presynaptic action potential (APSYN) to values much lower than those at cell somas. This key APSYN property additionally shows adaptive plasticity: manipulations that increase presynaptic Ca(2+) channel abundance and release probability result in a commensurate lowering of the APSYN peak and narrowing of the waveform, while manipulations that decrease presynaptic Ca(2+) channel abundance do the opposite. This modulation is eliminated upon blockade of Kv3.1 and Kv1 channels. Our studies thus reveal that adaptive plasticity in the APSYN waveform serves as an important regulator of synaptic function.

Published

2014

14. Glutamate Clearance Is Locally Modulated by Presynaptic Neuronal Activity in the Cerebral Cortex

Author

Chris G. Dulla, Elizabeth Hanson, and Moritz Armbruster

Subjects

0301 basic medicine, Male, Glutamic Acid, Neurotransmission, In Vitro Techniques, Receptors, Presynaptic, Receptors, N-Methyl-D-Aspartate, 03 medical and health sciences, Mice, 0302 clinical medicine, medicine, Premovement neuronal activity, Animals, Cerebral Cortex, Neurons, Chemistry, General Neuroscience, Glutamate receptor, Glutamic acid, Articles, Cell biology, Electrophysiological Phenomena, Mice, Inbred C57BL, 030104 developmental biology, medicine.anatomical_structure, Excitatory Amino Acid Transporter 2, Astrocytes, Synaptic plasticity, NMDA receptor, Female, Synaptic signaling, 030217 neurology & neurosurgery, Astrocyte

Abstract

Excitatory amino acid transporters (EAATs) are abundantly expressed by astrocytes, rapidly remove glutamate from the extracellular environment, and restrict the temporal and spatial extent of glutamate signaling. Studies probing EAAT function suggest that their capacity to remove glutamate is large and does not saturate, even with substantial glutamate challenges. In contrast, we report that neuronal activity rapidly and reversibly modulates EAAT-dependent glutamate transport. To date, no physiological manipulation has shown changes in functional glutamate uptake in a nonpathological state. Using iGluSnFr-based glutamate imaging and electrophysiology in the adult mouse cortex, we show that glutamate uptake is slowed up to threefold following bursts of neuronal activity. The slowing of glutamate uptake depends on the frequency and duration of presynaptic neuronal activity but is independent of the amount of glutamate released. The modulation of glutamate uptake is brief, returning to normal within 50 ms after stimulation ceases. Interestingly, the slowing of glutamate uptake is specific to activated synapses, even within the domain of an individual astrocyte. Activity-induced slowing of glutamate uptake, and the increased persistence of glutamate in the extracellular space, is reflected by increased decay times of neuronal NR2A-mediated NMDA currents. These results show that astrocytic clearance of extracellular glutamate is slowed in a temporally and spatially specific manner following bursts of neuronal activity ≥30 Hz and that these changes affect the neuronal response to released glutamate. This suggests a previously unreported form of neuron–astrocyte interaction.SIGNIFICANCE STATEMENTWe report the first fast, physiological modulation of astrocyte glutamate clearance kinetics. We show that presynaptic activity in the cerebral cortex increases the persistence of glutamate in the extracellular space by slowing its clearance by astrocytes. Because of abundant EAAT expression, glutamate clearance from the extracellular space has been thought to have invariant kinetics. While multiple studies report experimental manipulations resulting in altered EAAT expression, our findings show that astrocytic glutamate uptake is dynamic on a fast time-scale. This shows rapid plasticity of glutamate clearance, which locally modulates synaptic signaling in the cortex. As astrocytic glutamate uptake is a fundamental and essential mechanism for neurotransmission, this work has implications for neurotransmission, extrasynaptic receptor activation, and synaptic plasticity.

Published

2016

15. Calcium Control of Endocytic Capacity at a CNS Synapse

Author

Timothy A. Ryan, Moritz Armbruster, and J. Balaji

Subjects

Endocytic cycle, Presynaptic Terminals, Action Potentials, Nerve Tissue Proteins, Biology, Neurotransmission, Endocytosis, Hippocampus, Synaptic Transmission, Synaptic vesicle, Article, Calcium in biology, Rats, Sprague-Dawley, Synapse, Animals, Calcium Signaling, Cells, Cultured, Fluorescent Dyes, Calcium signaling, Neurotransmitter Agents, Microscopy, Confocal, General Neuroscience, Vesicle, Rats, Cell biology, Animals, Newborn, Synapses, Calcium, Synaptic Vesicles

Abstract

The ability to recycle synaptic vesicles is a crucial property of nerve terminals that allows maintenance of synaptic transmission. Using high-sensitivity optical approaches at hippocampal nerve terminals in dissociated neurons in culture, we show that modulation of endocytosis can be achieved by expansion of the endocytic capacity. Our experiments indicate that the endocytic capacity, the maximum number of synaptic vesicles that can be internalized in parallel at individual synapses, is tightly controlled by intracellular calcium levels. Increasing levels of intracellular calcium, which occurs as firing frequency increases, significantly increases the endocytic capacity. At physiological temperature after 30 Hz firing, these synapses are capable of endocytosing at least approximately 28 vesicles in parallel, each with a time constant of approximately 6 s. This calcium-dependent control of endocytic capacity reveals a potentially useful adaptive response to high-frequency activity to increase endocytic rates under conditions of vesicle pool depletion.

Published

2008

16. Synaptic vesicle retrieval time is a cell-wide rather than individual-synapse property

Author

Timothy A. Ryan and Moritz Armbruster

Subjects

Time Factors, Green Fluorescent Proteins, Models, Neurological, Endocytic cycle, Adaptor Protein Complex 2, Biophysics, Presynaptic Terminals, Tetrodotoxin, Hippocampal formation, Biology, Neurotransmission, Transfection, Endocytosis, Hippocampus, Synaptic Transmission, Synaptic vesicle, Article, Rats, Sprague-Dawley, Synapse, chemistry.chemical_compound, medicine, Animals, Anesthetics, Local, RNA, Small Interfering, Neurotransmitter, Cells, Cultured, 6-Cyano-7-nitroquinoxaline-2,3-dione, Neurons, General Neuroscience, Valine, Electric Stimulation, Markov Chains, Rats, medicine.anatomical_structure, Animals, Newborn, nervous system, chemistry, Synapses, Vesicular Glutamate Transport Protein 1, Synaptic Vesicles, Neuron, Excitatory Amino Acid Antagonists, Neuroscience

Abstract

Although individual nerve terminals from the same neuron often differ in neurotransmitter release characteristics, the extent to which endocytic retrieval of synaptic vesicle components differs is unknown. We used high-fidelity optical recordings to undertake a large-scale analysis of endocytosis kinetics of individual boutons in hippocampal rat neurons. Our data indicate that endocytosis kinetics do not differ substantially across boutons from the same cell but instead appear to be controlled at a cell-wide level.

Published

2011

17. Laser-scanning astrocyte mapping reveals increased glutamate-responsive domain size and disrupted maturation of glutamate uptake following neonatal cortical freeze-lesion

Author

Yongjie Yang, Chris G. Dulla, David Hampton, and Moritz Armbruster

Subjects

Synaptogenesis, glutamate, Biology, GLAST, lcsh:RC321-571, Lesion, Cellular and Molecular Neuroscience, chemistry.chemical_compound, astrocyte, medicine, Extracellular, Original Research Article, Neurotransmitter, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, freeze lesion, Glutamate receptor, Cortex (botany), GLT-1, medicine.anatomical_structure, chemistry, Cortex, glutamate transporters, Astrocytosis, medicine.symptom, Neuroscience, Astrocyte

Abstract

Astrocytic uptake of glutamate shapes extracellular neurotransmitter dynamics, receptor activation, and synaptogenesis. During development, glutamate transport becomes more robust. How neonatal brain insult affects the functional maturation of glutamate transport remains unanswered. Neonatal brain insult can lead to developmental delays, cognitive losses, and epilepsy; the disruption of glutamate transport is known to cause changes in synaptogenesis, receptor activation, and seizure. Using the neonatal freeze-lesion (FL) model, we have investigated how insult affects the maturation of astrocytic glutamate transport. As lesioning occurs on the day of birth, a time when astrocytes are still functionally immature, this model is ideal for identifying changes in astrocyte maturation following insult. Reactive astrocytosis, astrocyte proliferation, and in vitro hyperexcitability are known to occur in this model. To probe astrocyte glutamate transport with better spatial precision we have developed a novel technique, Laser Scanning Astrocyte Mapping (LSAM), which combines glutamate transport current (TC) recording from astrocytes with laser scanning glutamate photolysis. LSAM allows us to identify the area from which a single astrocyte can transport glutamate and to quantify spatial heterogeneity in the rate of glutamate clearance kinetics within that domain. Using LSAM, we report that cortical astrocytes have an increased glutamate-responsive area following FL and that TCs have faster decay times in distal, as compared to proximal processes. Furthermore, the developmental shift from GLAST- to GLT-1-dominated clearance is disrupted following FL. These findings introduce a novel method to probe astrocyte glutamate uptake and show that neonatal cortical FL disrupts the functional maturation of cortical astrocytes.

Published

2014

18. Dynamin phosphorylation controls optimization of endocytosis for brief action potential bursts

Author

Shawn M. Ferguson, Pietro De Camilli, Timothy A. Ryan, Moritz Armbruster, and Mirko Messa

Subjects

Dynamins, Mouse, QH301-705.5, Science, Action Potentials, Biology, Stimulus (physiology), Hippocampal formation, Endocytosis, Synaptic vesicle, General Biochemistry, Genetics and Molecular Biology, Bulk endocytosis, synaptic vesicle, Dephosphorylation, 03 medical and health sciences, 0302 clinical medicine, dynamin, endocytosis, Humans, Biology (General), 030304 developmental biology, Dynamin, 0303 health sciences, General Immunology and Microbiology, phosphorylation, General Neuroscience, General Medicine, Cell Biology, Cell biology, Phosphorylation, Medicine, Rat, 030217 neurology & neurosurgery, Research Article, Neuroscience

Abstract

Modulation of synaptic vesicle retrieval is considered to be potentially important in steady-state synaptic performance. Here we show that at physiological temperature endocytosis kinetics at hippocampal and cortical nerve terminals show a bi-phasic dependence on electrical activity. Endocytosis accelerates for the first 15–25 APs during bursts of action potential firing, after which it slows with increasing burst length creating an optimum stimulus for this kinetic parameter. We show that activity-dependent acceleration is only prominent at physiological temperature and that the mechanism of this modulation is based on the dephosphorylation of dynamin 1. Nerve terminals in which dynamin 1 and 3 have been replaced with dynamin 1 harboring dephospho- or phospho-mimetic mutations in the proline-rich domain eliminate the acceleration phase by either setting endocytosis at an accelerated state or a decelerated state, respectively. DOI: http://dx.doi.org/10.7554/eLife.00845.001, eLife digest Neurons communicate with each other at specialized junctions called synapses. When signals travelling along a neuron reach the presynaptic cell, this triggers small packages (vesicles) containing neurotransmitter molecules to release their contents into the synapse, and these molecules then cross the gap and bind to receptors on the postsynaptic neuron. To release their cargo, individual vesicles fuse with the plasma membrane of the presynaptic neuron and form a ‘pore’ through which neurotransmitter molecules can leave the cell. However, to avoid running out of vesicles, the neuron must recycle and rebuild them through a process known as endocytosis. This involves recapturing the proteins that make up the synaptic vesicle and internalizing them back into the presynaptic terminal. Exactly how endocytosis is regulated has been the subject of much debate in recent years. Now, Armbruster et al. have used fluorescent markers to study the timing of endocytosis in unprecedented detail. Observations of individual synapses reveal that when a series of action potentials (spikes of electrical activity) occurs in a neuron, endocytosis accelerates during the first few action potentials, and then slows. However, this acceleration was only detectable at a physiological temperature of 37°C—markedly higher than the 30°C at which synaptic endocytosis is typically studied. The new study showed that acceleration of endocytosis depends on the phosphorylation status of dynamin, a mechano-chemical enzyme long known to be crucial for endocytosis, which helps to sever the connection between the endocytosing membrane and the surface of the cell. Phosphorylation is a common mechanism for controlling enzyme activity, and involves the addition of phosphate groups to specific amino acids by enzymes called kinases. Phosphatase enzymes reverse the process by removing the phosphate groups. Dynamin is usually phosphorylated at two specific amino acids, but when levels of calcium in the cell increase (as occurs during action potentials), a phosphatase called calcineurin dephosphorylates these sites. Using versions of dynamin that were either permanently phosphorylated or never phosphorylated, Armbruster et al. showed that a decrease in dynamin phosphorylation was required for the initial acceleration of endocytosis. This type of regulation seems to optimize the recycling of vesicles to enable neurons to respond effectively to brief bursts of stimulation. Given that dynamin phosphorylation is conserved in evolution, it is likely that regulation of synaptic endocytosis is a key mechanism for ensuring the efficient functioning of the nervous system. Future research will investigate how calcium influx mediates the later slowing of endocytosis, and help to further unravel this previously unknown regulatory process. DOI: http://dx.doi.org/10.7554/eLife.00845.002

Published

2013

19. Author response: Dynamin phosphorylation controls optimization of endocytosis for brief action potential bursts

Author

Pietro De Camilli, Moritz Armbruster, Timothy A. Ryan, Shawn M. Ferguson, and Mirko Messa

Subjects

Action (philosophy), Chemistry, Phosphorylation, Endocytosis, Dynamin, Cell biology

Published

2013

20. Overlapping role of dynamin isoforms in synaptic vesicle endocytosis

Author

Mirko Messa, Valentina Cappello, Shawn M. Ferguson, Timothy A. Ryan, Silvia Giovedì, Summer Paradise, Eileen T. O'Toole, Nao Kono, Andrea Raimondi, Xuelin Lou, Moritz Armbruster, Junko Takasaki, and Pietro De Camilli

Subjects

endocrine system, Neuroscience(all), Endocytic cycle, GTPase, macromolecular substances, Neurotransmission, Biology, Endocytosis, Bulk endocytosis, Article, 03 medical and health sciences, Mice, 0302 clinical medicine, Postsynaptic potential, Animals, Protein Isoforms, Cells, Cultured, Dynamin I, 030304 developmental biology, Dynamin, Synaptic vesicle endocytosis, Mice, Knockout, Neurons, 0303 health sciences, General Neuroscience, Brain, Cell biology, Synaptic Vesicles, biological phenomena, cell phenomena, and immunity, Dynamin III, 030217 neurology & neurosurgery

Abstract

SummaryThe existence of neuron-specific endocytic protein isoforms raises questions about their importance for specialized neuronal functions. Dynamin, a GTPase implicated in the fission reaction of endocytosis, is encoded by three genes, two of which, dynamin 1 and 3, are highly expressed in neurons. We show that dynamin 3, thought to play a predominantly postsynaptic role, has a major presynaptic function. Although lack of dynamin 3 does not produce an overt phenotype in mice, it worsens the dynamin 1 KO phenotype, leading to perinatal lethality and a more severe defect in activity-dependent synaptic vesicle endocytosis. Thus, dynamin 1 and 3, which together account for the overwhelming majority of brain dynamin, cooperate in supporting optimal rates of synaptic vesicle endocytosis. Persistence of synaptic transmission in their absence indicates that if dynamin plays essential functions in neurons, such functions can be achieved by the very low levels of dynamin 2.

Published

2011