High Speed Two-Photon Imaging of Calcium Dynamics in Dendritic Spines: Consequences for Spine Calcium Kinetics and Buffer Capacity

Rapid calcium concentration changes in postsynaptic structures are crucial for synaptic plasticity. Thus far, the determinants of postsynaptic calcium dynamics have been studied predominantly based on the decay kinetics of calcium transients. Calcium rise times in spines in response to single action potentials (AP) are almost never measured due to technical limitations, but they could be crucial for synaptic plasticity. With high-speed, precisely-targeted, two-photon point imaging we measured both calcium rise and decay kinetics in spines and secondary dendrites in neocortical pyramidal neurons. We found that both rise and decay kinetics of changes in calcium-indicator fluorescence are about twice as fast in spines. During AP trains, spine calcium changes follow each AP, but not in dendrites. Apart from the higher surface-to-volume ratio (SVR), we observed that neocortical dendritic spines have a markedly smaller endogenous buffer capacity with respect to their parental dendrites. Calcium influx time course and calcium extrusion rate were both in the same range for spines and dendrites when fitted with a dynamic multi-compartment model that included calcium binding kinetics and diffusion. In a subsequent analysis we used this model to investigate which parameters are critical determinants in spine calcium dynamics. The model confirmed the experimental findings: a higher SVR is not sufficient by itself to explain the faster rise time kinetics in spines, but only when paired with a lower buffer capacity in spines. Simulations at zero calcium-dye conditions show that calmodulin is more efficiently activated in spines, which indicates that spine morphology and buffering conditions in neocortical spines favor synaptic plasticity.

[1]  Peter Saggau,et al.  New methods and uses for fast optical scanning , 2006, Current Opinion in Neurobiology.

[2]  Rafael Yuste,et al.  Imaging membrane potential in dendritic spines. , 2006, Proceedings of the National Academy of Sciences of the United States of America.

[3]  G. Ellis‐Davies,et al.  Structural basis of long-term potentiation in single dendritic spines , 2004, Nature.

[4]  Rafael Yuste,et al.  Calcium Microdomains in Aspiny Dendrites , 2003, Neuron.

[5]  Hartmut Schmidt,et al.  Mutational analysis of dendritic Ca2+ kinetics in rodent Purkinje cells: role of parvalbumin and calbindin D28k , 2003, The Journal of physiology.

[6]  Srdjan D Antic,et al.  Action Potentials in Basal and Oblique Dendrites of Rat Neocortical Pyramidal Neurons , 2003, The Journal of physiology.

[7]  H. Kasai,et al.  Structure–stability–function relationships of dendritic spines , 2003, Trends in Neurosciences.

[8]  Rafael Yuste,et al.  A two-photon and second-harmonic microscope. , 2003, Methods.

[9]  Maria Blatow,et al.  Ca2+ Buffer Saturation Underlies Paired Pulse Facilitation in Calbindin-D28k-Containing Terminals , 2003, Neuron.

[10]  J. Eilers,et al.  Diffusional mobility of parvalbumin in spiny dendrites of cerebellar Purkinje neurons quantified by fluorescence recovery after photobleaching. , 2003, Biophysical journal.

[11]  N. Kasthuri,et al.  Long-term dendritic spine stability in the adult cortex , 2002, Nature.

[12]  K. Svoboda,et al.  Long-term in vivo imaging of experience-dependent synaptic plasticity in adult cortex , 2002, Nature.

[13]  Terrence J Sejnowski,et al.  Complexity of calcium signaling in synaptic spines. , 2002, BioEssays : news and reviews in molecular, cellular and developmental biology.

[14]  Arthur Sherman,et al.  New and corrected simulations of synaptic facilitation. , 2002, Biophysical journal.

[15]  J. Lisman,et al.  The molecular basis of CaMKII function in synaptic and behavioural memory , 2002, Nature Reviews Neuroscience.

[16]  Arthur Konnerth,et al.  Postsynaptic Induction of BDNF-Mediated Long-Term Potentiation , 2002, Science.

[17]  K. Svoboda,et al.  The Life Cycle of Ca2+ Ions in Dendritic Spines , 2002, Neuron.

[18]  Rafael Yuste,et al.  Calcium Dynamics of Spines Depend on Their Dendritic Location , 2002, Neuron.

[19]  K. Svoboda,et al.  Ca2+ signaling in dendritic spines , 2001, Current Opinion in Neurobiology.

[20]  Rafael Yuste,et al.  A custom-made two-photon microscope and deconvolution system , 2000, Pflügers Archiv.

[21]  I. Módy,et al.  Binding kinetics of calbindin-D(28k) determined by flash photolysis of caged Ca(2+) , 2000, Biophysical journal.

[22]  Rafael Yuste,et al.  From form to function: calcium compartmentalization in dendritic spines , 2000, Nature Neuroscience.

[23]  Suk-Ho Lee,et al.  Kinetics of Ca2+ binding to parvalbumin in bovine chromaffin cells: implications for [Ca2+] transients of neuronal dendrites , 2000, The Journal of physiology.

[24]  K. Svoboda,et al.  Estimating intracellular calcium concentrations and buffering without wavelength ratioing. , 2000, Biophysical journal.

[25]  R. Yuste,et al.  Mechanisms of Calcium Decay Kinetics in Hippocampal Spines: Role of Spine Calcium Pumps and Calcium Diffusion through the Spine Neck in Biochemical Compartmentalization , 2000, The Journal of Neuroscience.

[26]  R. Zucker Calcium- and activity-dependent synaptic plasticity , 1999, Current Opinion in Neurobiology.

[27]  W. Denk,et al.  Mechanisms of Calcium Influx into Hippocampal Spines: Heterogeneity among Spines, Coincidence Detection by NMDA Receptors, and Optical Quantal Analysis , 1999, The Journal of Neuroscience.

[28]  A. Persechini,et al.  The Relationship between the Free Concentrations of Ca2+ and Ca2+-calmodulin in Intact Cells* , 1999, The Journal of Biological Chemistry.

[29]  B W Kooi,et al.  Diffusion barriers limit the effect of mobile calcium buffers on exocytosis of large dense cored vesicles. , 1999, Biophysical journal.

[30]  R. Zucker,et al.  Selective induction of LTP and LTD by postsynaptic [Ca2+]i elevation. , 1999, Journal of neurophysiology.

[31]  B. Sakmann,et al.  Calcium dynamics in single spines during coincident pre- and postsynaptic activity depend on relative timing of back-propagating action potentials and subthreshold excitatory postsynaptic potentials. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[32]  Henry Markram,et al.  Competitive Calcium Binding: Implications for Dendritic Calcium Signaling , 1998, Journal of Computational Neuroscience.

[33]  W G Regehr,et al.  Optical measurement of presynaptic calcium currents. , 1998, Biophysical journal.

[34]  M. Naraghi,et al.  T-jump study of calcium binding kinetics of calcium chelators. , 1997, Cell calcium.

[35]  B. Sakmann,et al.  Calcium dynamics associated with a single action potential in a CNS presynaptic terminal. , 1997, Biophysical journal.

[36]  E. Neher,et al.  Modeling buffered Ca2+ diffusion near the membrane: implications for secretion in neuroendocrine cells. , 1997, Biophysical journal.

[37]  W. Regehr,et al.  Timing of neurotransmission at fast synapses in the mammalian brain , 1996, Nature.

[38]  R. Nicoll,et al.  Ca2+ Signaling Requirements for Long-Term Depression in the Hippocampus , 1996, Neuron.

[39]  B. Sakmann,et al.  Ca2+ buffering and action potential-evoked Ca2+ signaling in dendrites of pyramidal neurons. , 1996, Biophysical journal.

[40]  WG Regehr,et al.  A quantitative analysis of presynaptic calcium dynamics that contribute to short-term enhancement , 1995, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[41]  W. Denk,et al.  Dendritic spines as basic functional units of neuronal integration , 1995, Nature.

[42]  J. Keizer,et al.  Effects of rapid buffers on Ca2+ diffusion and Ca2+ oscillations. , 1994, Biophysical journal.

[43]  B. Sakmann,et al.  Active propagation of somatic action potentials into neocortical pyramidal cell dendrites , 1994, Nature.

[44]  L. Stryer,et al.  Range of messenger action of calcium ion and inositol 1,4,5-trisphosphate. , 1992, Science.

[45]  E. Neher,et al.  Calcium gradients and buffers in bovine chromaffin cells. , 1992, The Journal of physiology.

[46]  C. Ashley,et al.  Fura‐2 diffusion and its use as an indicator of transient free calcium changes in single striated muscle cells , 1986, FEBS letters.

[47]  K. Sobue,et al.  Quantitative determinations of calmodulin in the supernatant and particulate fractions of mammalian tissues. , 1982, Journal of biochemistry.

[48]  R. Llinás,et al.  Transmission by presynaptic spike-like depolarization in the squid giant synapse. , 1982, Proceedings of the National Academy of Sciences of the United States of America.

[49]  William Holmes,et al.  Models of Calmodulin Trapping and CaM Kinase II Activation in a Dendritic Spine , 2004, Journal of Computational Neuroscience.

[50]  M. Pinter,et al.  Time courses of calcium and calcium-bound buffers following calcium influx in a model cell. , 1993, Biophysical journal.