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NMDA spikes enhance action potential generation during sensory input

Abstract

Recent evidence in vitro suggests that the tuft dendrites of pyramidal neurons are capable of evoking local NMDA receptor–dependent electrogenesis, so-called NMDA spikes. However, it has so far proved difficult to demonstrate their existence in vivo. Moreover, it is not clear whether NMDA spikes are relevant to the output of pyramidal neurons. We found that local NMDA spikes occurred in tuft dendrites of layer 2/3 pyramidal neurons both spontaneously and following sensory input, and had a large influence on the number of output action potentials. Using two-photon activation of an intracellular caged NMDA receptor antagonist (tc-MK801), we found that isolated NMDA spikes typically occurred in multiple branches simultaneously and that sensory stimulation substantially increased their probability. Our results demonstrate that NMDA receptors have a vital role in coupling the tuft region of the layer 2/3 pyramidal neuron to the cell body, enhancing the effectiveness of layer 1 input.

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Figure 1: Large NMDA receptor–dependent Ca2+ transients occur spontaneously in the tuft dendrites of L2/3 pyramidal neurons.
Figure 2: Global, but not local, block of NMDA receptor–dependent Ca2+ transients in tuft dendrites decreases sensory-evoked neuronal output.
Figure 3: Simultaneous NMDA receptor–dependent Ca2+ transients cause a large voltage event at the soma.
Figure 4: Spontaneous Ca2+ transients occur in both single and multiple tuft branches.
Figure 5: Dendritic Ca2+ activity can also be spatially restricted in the awake state.
Figure 6: Tuft Ca2+ events report coincident input.
Figure 7: Synaptic input location and NMDA conductance are crucial for NMDA spikes and action potentials.

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References

  1. Hubel, D.H. Cortical neurobiology: a slanted historical perspective. Annu. Rev. Neurosci. 5, 363–370 (1982).

    Article  CAS  PubMed  Google Scholar 

  2. Gilbert, C.D. & Sigman, M. Brain states: top-down influences in sensory processing. Neuron 54, 677–696 (2007).

    Article  CAS  PubMed  Google Scholar 

  3. Boly, M. et al. Preserved feedforward but impaired top-down processes in the vegetative state. Science 332, 858–862 (2011).

    Article  CAS  PubMed  Google Scholar 

  4. Self, M.W., van Kerkoerle, T., Super, H. & Roelfsema, P.R. Distinct roles of the cortical layers of area V1 in figure-ground segregation. Curr. Biol. 23, 2121–2129 (2013).

    Article  CAS  PubMed  Google Scholar 

  5. Williams, S.R. & Stuart, G.J. Dependence of EPSP efficacy on synapse location in neocortical pyramidal neurons. Science 295, 1907–1910 (2002).

    Article  CAS  PubMed  Google Scholar 

  6. Larkum, M.E., Nevian, T., Sandler, M., Polsky, A. & Schiller, J. Synaptic integration in tuft dendrites of layer 5 pyramidal neurons: a new unifying principle. Science 325, 756–760 (2009).

    Article  CAS  PubMed  Google Scholar 

  7. Schiller, J., Major, G., Koester, H.J. & Schiller, Y. NMDA spikes in basal dendrites of cortical pyramidal neurons. Nature 404, 285–289 (2000).

    Article  CAS  PubMed  Google Scholar 

  8. Self, M.W., Kooijmans, R.N., Super, H., Lamme, V.A. & Roelfsema, P.R. Different glutamate receptors convey feedforward and recurrent processing in macaque V1. Proc. Natl. Acad. Sci. USA 109, 11031–11036 (2012).

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  9. Antic, S.D., Zhou, W.L., Moore, A.R., Short, S.M. & Ikonomu, K.D. The decade of the dendritic NMDA spike. J. Neurosci. Res. 88, 2991–3001 (2010).

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  10. Jia, H., Rochefort, N.L., Chen, X. & Konnerth, A. Dendritic organization of sensory input to cortical neurons in vivo. Nature 464, 1307–1312 (2010).

    Article  CAS  PubMed  Google Scholar 

  11. Chen, X., Leischner, U., Rochefort, N.L., Nelken, I. & Konnerth, A. Functional mapping of single spines in cortical neurons in vivo. Nature 475, 501–505 (2011).

    Article  CAS  PubMed  Google Scholar 

  12. Hill, D.N., Varga, Z., Jia, H., Sakmann, B. & Konnerth, A. Multibranch activity in basal and tuft dendrites during firing of layer 5 cortical neurons in vivo. Proc. Natl. Acad. Sci. USA 110, 13618–13623 (2013).

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  13. Lavzin, M., Rapoport, S., Polsky, A., Garion, L. & Schiller, J. Nonlinear dendritic processing determines angular tuning of barrel cortex neurons in vivo. Nature 490, 397–401 (2012).

    Article  CAS  PubMed  Google Scholar 

  14. Smith, S.L., Smith, I.T., Branco, T. & Hausser, M. Dendritic spikes enhance stimulus selectivity in cortical neurons in vivo. Nature 503, 115–120 (2013).

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  15. Branco, T., Clark, B.A. & Hausser, M. Dendritic discrimination of temporal input sequences in cortical neurons. Science 329, 1671–1675 (2010).

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  16. Branco, T. & Hausser, M. Synaptic integration gradients in single cortical pyramidal cell dendrites. Neuron 69, 885–892 (2011).

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  17. Schiller, J. & Schiller, Y. NMDA receptor-mediated dendritic spikes and coincident signal amplification. Curr. Opin. Neurobiol. 11, 343–348 (2001).

    Article  CAS  PubMed  Google Scholar 

  18. Major, G., Larkum, M.E. & Schiller, J. Active properties of neocortical pyramidal neuron dendrites. Annu. Rev. Neurosci. 36, 1–24 (2013).

    Article  CAS  PubMed  Google Scholar 

  19. Mayer, M.L., Westbrook, G.L. & Guthrie, P.B. Voltage-dependent block by Mg2+ of NMDA responses in spinal cord neurones. Nature 309, 261–263 (1984).

    Article  CAS  PubMed  Google Scholar 

  20. Mel, B.W. Synaptic integration in an excitable dendritic tree. J. Neurophysiol. 70, 1086–1101 (1993).

    Article  CAS  PubMed  Google Scholar 

  21. Rhodes, P. The properties and implications of NMDA spikes in neocortical pyramidal cells. J. Neurosci. 26, 6704–6715 (2006).

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  22. Larkum, M.E. & Nevian, T. Synaptic clustering by dendritic signaling mechanisms. Curr. Opin. Neurobiol. 18, 321–331 (2008).

    Article  CAS  PubMed  Google Scholar 

  23. Rodríguez-Moreno, A. et al. Presynaptic induction and expression of timing-dependent long-term depression demonstrated by compartment-specific photorelease of a use-dependent NMDA receptor antagonist. J. Neurosci. 31, 8564–8569 (2011).

    Article  PubMed  PubMed Central  Google Scholar 

  24. Reeve, J.E., Kohl, M.M., Rodríguez-Moreno, A., Paulsen, O. & Anderson, H.L. Caged intracellular NMDA receptor blockers for the study of subcellular ion channel function. Commun. Integr. Biol. 5, 240–242 (2012).

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  25. Svoboda, K., Denk, W., Kleinfeld, D. & Tank, D.W. In vivo dendritic calcium dynamics in neocortical pyramidal neurons. Nature 385, 161–165 (1997).

    Article  CAS  PubMed  Google Scholar 

  26. Svoboda, K., Helmchen, F., Denk, W. & Tank, D.W. Spread of dendritic excitation in layer 2/3 pyramidal neurons in rat barrel cortex in vivo. Nat. Neurosci. 2, 65–73 (1999).

    Article  CAS  PubMed  Google Scholar 

  27. Waters, J., Larkum, M., Sakmann, B. & Helmchen, F. Supralinear Ca2+ influx into dendritic tufts of layer 2/3 neocortical pyramidal neurons in vitro and in vivo. J. Neurosci. 23, 8558–8567 (2003).

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  28. Larkum, M.E., Waters, J., Sakmann, B. & Helmchen, F. Dendritic spikes in apical dendrites of neocortical layer 2/3 pyramidal neurons. J. Neurosci. 27, 8999–9008 (2007).

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  29. Polsky, A., Mel, B.W. & Schiller, J. Computational subunits in thin dendrites of pyramidal cells. Nat. Neurosci. 7, 621–627 (2004).

    Article  CAS  PubMed  Google Scholar 

  30. Gordon, U., Polsky, A. & Schiller, J. Plasticity compartments in basal dendrites of neocortical pyramidal neurons. J. Neurosci. 26, 12717–12726 (2006).

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  31. Ledergerber, D. & Larkum, M.E. Properties of layer 6 pyramidal neuron apical dendrites. J. Neurosci. 30, 13031–13044 (2010).

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  32. Xu, N.L. et al. Nonlinear dendritic integration of sensory and motor input during an active sensing task. Nature 492, 247–251 (2012).

    Article  CAS  PubMed  Google Scholar 

  33. Chen, X., Rochefort, N.L., Sakmann, B. & Konnerth, A. Reactivation of the same synapses during spontaneous up states and sensory stimuli. Cell Rep. 4, 31–39 (2013).

    Article  CAS  PubMed  Google Scholar 

  34. Plotkin, J.L., Day, M. & Surmeier, D.J. Synaptically driven state transitions in distal dendrites of striatal spiny neurons. Nat. Neurosci. 14, 881–888 (2011).

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  35. Taylor, R.E. Effect of procaine on electrical properties of squid axon membrane. Am. J. Physiol. 196, 1071–1078 (1959).

    Article  CAS  PubMed  Google Scholar 

  36. Connors, B.W. & Prince, D.A. Effects of local anesthetic QX-314 on the membrane properties of hippocampal pyramidal neurons. J. Pharmacol. Exp. Ther. 220, 476–481 (1982).

    CAS  PubMed  Google Scholar 

  37. Perkins, K.L. & Wong, R.K. Intracellular QX-314 blocks the hyperpolarization-activated inward current Iq in hippocampal CA1 pyramidal cells. J. Neurophysiol. 73, 911–915 (1995).

    Article  CAS  PubMed  Google Scholar 

  38. Talbot, M.J. & Sayer, R.J. Intracellular QX-314 inhibits calcium currents in hippocampal CA1 pyramidal neurons. J. Neurophysiol. 76, 2120–2124 (1996).

    Article  CAS  PubMed  Google Scholar 

  39. Andrade, R. Blockade of neurotransmitter-activated K+ conductance by QX-314 in the rat hippocampus. Eur. J. Pharmacol. 199, 259–262 (1991).

    Article  CAS  PubMed  Google Scholar 

  40. Chen, T.W. et al. Ultrasensitive fluorescent proteins for imaging neuronal activity. Nature 499, 295–300 (2013).

    CAS  PubMed  PubMed Central  Google Scholar 

  41. Felleman, D.J. & Van Essen, D.C. Distributed hierarchical processing in the primate cerebral cortex. Cereb. Cortex 1, 1–47 (1991).

    Article  CAS  PubMed  Google Scholar 

  42. Zador, A.M., Agmon-Snir, H. & Segev, I. The morphoelectrotonic transform: a graphical approach to dendritic function. J. Neurosci. 15, 1669–1682 (1995).

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  43. Stuart, G. & Spruston, N. Determinants of voltage attenuation in neocortical pyramidal neuron dendrites. J. Neurosci. 18, 3501–3510 (1998).

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  44. Nevian, T., Larkum, M.E., Polsky, A. & Schiller, J. Properties of basal dendrites of layer 5 pyramidal neurons: a direct patch-clamp recording study. Nat. Neurosci. 10, 206–214 (2007).

    Article  CAS  PubMed  Google Scholar 

  45. Major, G., Polsky, A., Denk, W., Schiller, J. & Tank, D.W. Spatiotemporally graded NMDA spike/plateau potentials in basal dendrites of neocortical pyramidal neurons. J. Neurophysiol. 99, 2584–2601 (2008).

    Article  CAS  PubMed  Google Scholar 

  46. Williams, S.R. & Stuart, G.J. Mechanisms and consequences of action potential burst firing in rat neocortical pyramidal neurons. J. Physiol. (Lond.) 521, 467–482 (1999).

    Article  CAS  Google Scholar 

  47. Larkum, M.E. & Zhu, J.J. Signaling of layer 1 and whisker-evoked Ca2+ and Na+ action potentials in distal and terminal dendrites of rat neocortical pyramidal neurons in vitro and in vivo. J. Neurosci. 22, 6991–7005 (2002).

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  48. Ledergerber, D. & Larkum, M.E. The time window for generation of dendritic spikes by coincidence of action potentials and EPSPs is layer specific in somatosensory cortex. PLoS ONE 7, e33146 (2012).

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  49. Cauller, L.J. & Connors, B.W. Synaptic physiology of horizontal afferents to layer I in slices of rat SI neocortex. J. Neurosci. 14, 751–762 (1994).

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  50. Larkum, M.E. A cellular mechanism for cortical associations: an organizing principle for the cerebral cortex. Trends Neurosci. 36, 141–151 (2013).

    Article  CAS  PubMed  Google Scholar 

  51. Hines, M.L. The Neurosimulator NEURON. in Methods in Neuronal Modeling (eds. Koch, C. & Segev, I.) 129–136 (MIT Press, Cambridge, Massachusetts, 1998).

  52. Hay, E., Hill, S., Schurmann, F., Markram, H. & Segev, I. Models of neocortical layer 5b pyramidal cells capturing a wide range of dendritic and perisomatic active properties. PLoS Comput. Biol. 7, e1002107 (2011).

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  53. Connors, B.W., Gutnick, M.J. & Prince, D.A. Electrophysiological properties of neocortical neurons in vitro. J. Neurophysiol. 48, 1302–1320 (1982).

    Article  CAS  PubMed  Google Scholar 

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Acknowledgements

We thank F. Haiss and B. Weber for designing the custom-made two-photon microscope, and D. Langer and F. Helmchen for the imaging software Helioscan. We also thank S. Murphy and R. Min for their comments on the manuscript. We further acknowledge the GENIE Program and the Janelia Farm Research Campus for the use of GCaMP6. This work was supported by SystemsX.ch (NeuroChoice), Swiss National Science Foundation (31003A_130694), the Whitaker International Program and the DFG (EXC 257 NeuroCure).

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Authors

Contributions

L.M.P. and M.E.L. designed, performed and analyzed the experiments. A.S.S. performed the computer simulations. J.E.R., H.L.A. and O.P. synthesized and provided the caged-MK801. L.M.P. and M.E.L. wrote the paper.

Corresponding author

Correspondence to Lucy M Palmer.

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The authors declare no competing financial interests.

Integrated supplementary information

Supplementary Figure 1 Tuft Ca2+ transients are spatially restricted, have a distinct bimodal distribution, and are not graded in amplitude.

In principle, NMDA spikes in multiple branches could be an indication of many NMDA spikes or one very spatially distributed NMDA event. We therefore measured the spatial extent of tuft Ca2+ transients. (a) Two-photon image of a tuft dendrite with spatially restricted regions of interest (ROIs; 5 mm length; colored boxes). (b) Spontaneous Ca2+ transients recorded in the dendritic ROIs shown in (a) and somatic APs indicated by dashes. To compare different dendritic regions, transients are reported as ΔG/R. (c) Overlay of the transients in (b) illustrating the spread of a Ca2+ event along a tuft dendrite. (d) Gaussian distribution of the normalized Ca2+ transient amplitudes at different locations along tuft dendrites. (e) The spatial spread of Ca2+transients within a tuft dendrite was not related to the somatic AP firing frequency. (f-h) Since NMDA spikes have a clear threshold, plotting Ca2+ fluorescence amplitudes would result in a bimodal distribution whereas boosted potentials would have a graded distribution. We therefore plotted the Ca2+ fluorescence amplitude distributions from two example tuft dendrites (I and II). (f) Two-photon image of two example tuft dendrites. (g) Example fluorescence traces with two Ca2+ transients above the noise from tuft dendrites shown in (f). (h) Histograms of the peak amplitude of Ca2+ fluorescence from the tuft dendrites shown in (f) illustrating bimodal distributions. Ca2+transients were included in the analysis if they had an amplitude larger than 3x the standard deviation of the noise (middle, grey bar; right, dashed line). This criteria separated the reported Ca2+ transients (red) from the fluorescence background noise (black).

Supplementary Figure 2 Tuft Ca2+ transients are not from bAPs.

Backpropagating action potentials (bAPs) cause Ca2+ influx into the dendrites of layer 2/3 pyramidal neurons in a distance-dependent manner (Svoboda et al, 1999; Waters et al, 2003). We tested the possibility that bAPs cause Ca2+ transients in distal tuft dendrites. (a) Tuft Ca2+ trace (top) and simultaneous somatic voltage (bottom). Bars highlight somatic APs with (green) and without (grey) associated tuft Ca2+ influx. APs truncated. (b) Only 26 ± 4 % of all somatic APs were associated with a Ca2+ transient in control tuft dendrites (n = 28). Although there were still spontaneous APs when all NMDA channels were blocked by internal MK801, there were no tuft Ca2+ transients illustrating the requirement of active NMDA channels (n = 6 dendrites). (c) Histogram of firing frequency recorded during tuft Ca2+ transients. The average firing frequency (60 ± 3 Hz) during tuft Ca2+ transients is considerably lower than the reported critical frequency (CF; red arrow) for evoking Ca2+ spikes in layer 2/3 pyramidal neurons (Larkum et al, 2007). Therefore bAPs alone could not evoke Ca2+ spikes which would cause Ca2+ influx into the tuft dendrites. (d) To investigate the timing of APs with dendritic Ca2+ activity, imaging frequency was increased to a maximum of 100 Hz. Typical tuft Ca2+ transients recorded at 50 Hz and somatic APs (black dashes). Grey bars, timing of Ca2+ transients compared to APs. Box, magnification of Ca2+ transient (top) and simultaneous somatic voltage (bottom) from the region marked with a red bar (left). Red markers on Ca2+ transient, data points (3 data points on the rising phase of the Ca2+ transient). (e) Histogram of the timing of Ca2+ transients recorded at 50-100 Hz compared to the timing of somatic APs. Timing was determined as the difference in time (ms) between the first data point on the rising phase of the tuft Ca2+ transient and the time at 10 % of the AP threshold for the first AP. On average, the onset of the tuft Ca2+ transient was 16 ± 6 ms before the somatic AP (n=17). (f) Overlay of spontaneous Ca2+ transients from a single tuft dendrite illustrating their stereotypic waveform (n=9). The amplitude of Ca2+ transients recorded in all dendrites were within one standard deviation of the mean.

Supplementary Figure 3 NMDA spikes occur in tuft dendrites of layer 2/3 pyramidal neurons in vitro.

NMDA spikes have been shown in the basal dendrites of layer 2/3 pyramidal neurons but not in the tuft dendrite. (a) Experimental paradigm. Somatic recordings were made from layer 2/3 pyramidal neurons filled with Alexa Fluor 594 (50 μM) to aid the placement of an extracellular stimulation pipette in close proximity to a tuft dendrite. (b) Sequentially increasing the intensity of paired pulses (2x 1 ms pulses at 50 Hz) applied to the tuft dendrite shown in (a) resulted in a supralinear voltage response (top; black) which was blocked by bath application of APV (100 μM; bottom; green). Inset, overlay of somatic voltage during supralinear stimulation during control (black) and APV (green). (c) Integral of the somatic voltage during sequential increase in stimulus intensity for the neuron shown in (a) and (b). Block of NMDA channels by APV significantly decreased the integral of the somatic voltage during a NMDA spike by on average 69 ± 10 % (2nd pulse; n =3; p < 0.05; Data not shown). Data fitted with linear regression. Red arrows indicate suprathreshold response.

Supplementary Figure 4 Two-photon uncaging of tc-MK801 blocks NMDA spikes in vitro and in vivo.

(a) Somatic voltage responses to sequentially increasing intensity of extracellular stimulation (2x 1 ms pulses at 50 Hz) before (black; top) and after (red; bottom) two-photon activation (710-730 nm) of a caged NMDA channel agonist (tc-MK801) at the stimulated branch in vitro. Arrow indicates suprathreshold response. (b) Overlay of a NMDA spike before (black) and after (red) uncaging tc-MK801 for the dendrite in (a). (c) Integral of the voltage response to increasing stimulus strength for the example shown in (a) and (b) before (black) and after (red) two-photon uncaging. Data fitted with linear regression. (d) Normalized integral after two-photon uncaging during a NMDA spike (red solid; n = 5), EPSP (red empty; n = 11) and control (laser exposure in neurons without tc-MK801; light red; n = 8). (e) Example of extracellularly stimulated potentials from a control neuron (no tc-MK801) before (black) and after (red) two-photon exposure (730 nm for ~3 min) and during bath application of APV (100 μM; green). (f) Normalized integral during bath application of APV after two-photon exposure in neurons filled with tc-MK801 (empty bar; n = 3) and in control (solid bar; n = 5). (g) Amplitude of Ca2+ responses to local extracellular stimulation (2x 1ms pulses at 50 Hz) normalized to the maximum evoked response before (black; left) and after (red; right) two-photon activation of the caged NMDA channel agonist tc-MK801 in vivo (n = 6 dendrites from 3 neurons). Uncaging tc-MK801 abolishes the supralinear response to increasing extracellular stimulation intensity. (h) Here, we show that exposure to two-photon excitation alone had no measureable adverse effects on the dendritic morphology or amplitude of Ca2+transients. Dendritic morphology before (top) and after (bottom) two-photon laser exposure (690 nm, ~ 3 min). Scale bar, 2 mm. (i) Ca2+ transients before (black; top) and after (red; bottom) exposure to two-photon light (690 nm for ~3 min) from a control layer 2/3 pyramidal neuron filled with OGB1 and Alexa Fluor 594 (and not tc-MK801). Inset, there was no difference in the peak amplitudes of Ca2+ transients before (black) and after (red) exposure to two-photon excitation in control layer 2/3 pyramidal neuron dendrites. * indicates p < 0.05. Error bars represent S.E.M.

Supplementary Figure 5 Hindpaw airpuff reliably evokes dendritic and somatic responses which are dependent on NMDA receptors.

Despite the different modes of hindpaw stimulation, brief electrical (Figure 2) and air puff stimulation (40 psi) evoked similar dendritic and somatic responses - approximately one action potential (AP) per stimulation and a dendritic Ca2+response in approximately 20 % of stimulations. (a) Dendritic Ca2+ fluorescence (top) and somatic voltage (bottom) during airpuff stimulation of the hindpaw. Inset; two-photon image of the imaged tuft dendrite. (b) Percentage of hindpaw stimulation trials which resulted in a measurable Ca2+ transient during control (black; n=16) and NMDA block by cortical application of APV (red; n = 15). (c) Number of APs evoked by hindpaw stimulation during control (black; n = 5) and NMDA block by cortical application of APV (red; n = 15). Error bars represent S.E.M.

Supplementary Figure 6 Uncaging of tc-MK801 locally blocks NMDA channels.

Here, we show that two-photon uncaging of tc-MK801 locally blocked NMDA channels by comparing the frequency of Ca2+ transients (a and b) and the occurrence of isolated Ca2+ transients (c - e) after subsequent uncaging at a neighboring branch. (a) Neurons were filled with the caged NMDA channel blocker tc-MK801. Ca2+ transients were recorded in both naive dendrites (no prior two-photon uncaging anywhere in the neuron; green; n = 8 dendrites) and exposed dendrites (neighboring dendrites had local NMDA channels blocked by uncaging tc-MK801; orange; n = 16 dendrites). Insets, control (pre uncaging) Ca2+ transients; scale, 0.2 DF/F, 1 s. The local block of NMDA channels by two-photon uncaging of tc-MK801 did not affect the frequency of spontaneous control Ca2+ transients in neighboring tuft dendrites (naive, 0.06 ± 0.02 Hz; exposed, 0.06 ± 0.03 Hz). (b) The frequency of spontaneous Ca2+ transients after local NMDA channel block (normalized to the control frequency) in naive dendrites (green) compared to exposed dendrites (orange). Note, block of NMDA channels does not affect the effectiveness of uncaging tc-MK801 in neighboring tuft dendrites. (c) Reconstruction of a L2/3 pyramidal neuron filled with tc-MK801. (d) and (e), Dendritic Ca2+ trace and simultaneous somatic voltage from two different tuft dendrites from the neuron shown in (c). Both dendrites have Ca2+ transients in the absence of somatic APs (indicated by colored dots). APs are indicated by dashes and are truncated. Both dendrites had Ca2+ transients (ie not correlated with a somatic AP) before (color) but not after (red) activation of tc-MK801 with two-photon laser. Error bars represent S.E.M.

Supplementary Figure 7 Ca2+ transients in the presence of the Na+ channel blocker QX-314 are similar to control - they are spatially restricted and occur in both single and multiple branches.

In theory, backpropagating APs from the cell body can invade the tuft dendrite and influence dendritic electrogenesis. We therefore tested whether tuft Ca2+ transients were influenced by somatic activity by adding the Na+ channel blocker QX-314 to the patch pipette. (a) Two-photon image illustrating a tuft branch with 5 mm regions of interest. Inset, red fluorescence. (b) Spontaneous Ca2+ transients from the dendrite shown in (a). Note the different spatial spread of the two transients. To compare different dendritic regions, transients are reported as DG/R. (c) Average Ca2+ transient spatial spread along dendritic tuft branches (5 mm regions of interest; n = 40 transients). Data fitted with Gaussian fit; dashed line. Grey line; threshold for events (> 3x standard deviation of the noise). (d) Reconstruction of layer 2/3 pyramidal neuron filled with QX-314 and two-photon image of two tuft dendrites. (e) Spontaneous Ca2+ transients which occurred in only one (single) or both (multiple) of the dendrites shown in (d). (f) Average peak amplitudes of the Ca2+transients which occurred in single (light green) and multiple (dark green) branches (n = 508 transients in 41 branches). (g) Average somatic voltage during Ca2+ transients which occurred in single (light green) and multiple (dark green) branches (n = 9 branches) corrected for the increase in input resistance during QX-314 (see Fig. 3 and S9). Error bars represent S.E.M.

Supplementary Figure 8 Extracellular stimulation evokes large Ca2+ transients in tuft dendrites which is dependent on NMDA and not voltage-sensitive channels nor internal stores.

Action potential (AP) initiation was blocked by including QX-314 in the patch pipette which completely or partially blocks Na+, Ih, K+ and Ca2+ channels (Perkins and Wong, 1995; Talbot and Sayer, 1996). (a) Reconstruction of a layer 2/3 (L2/3) pyramidal neuron illustrating the experimental design. Neurons were filled with QX-314 and the caged NMDA channel blocker tc-MK801, and an extracellular stimulating pipette was placed in close proximity to a branch of interest in vivo. (b) Overlay (spatially shifted for display purposes) of Ca2+ transients in response to increasing stimulus intensity from the tuft dendrite boxed in (a). (c) Average Ca2+ transient amplitude during focal extracellular stimulation of increasing intensity (black, n = 7) during spontaneous activity (blue; n = 7). Linear regression for subthreshold responses is shown by grey line. (d) Overlay (spatially shifted for display purposes) of Ca2+ transients in response to increasing stimulus intensity after (bottom) block of NMDA receptors by two-photon (690 nm) uncaging of tc-MK801 from the boxed tuft dendrite in (a). (e) The evoked Ca2+ transient amplitude to the same suprathreshold stimulation strength was significantly larger before (black) than after (red) block of NMDA receptors by two-photon (690 nm) uncaging of tc-MK801. (f) Two-photon laser alone doesn't affect Ca2+ activity. Here, we show that exposure to two-photon excitation alone had no measureable adverse effect on the amplitude or width of Ca2+ transients in neurons filled with QX-314. Ca2+ transients before (black) and after (red) exposure to two-photon light (690 nm for ~3 min) from a L2/3 pyramidal neuron filled with QX-314 (and not tc-MK801). (g) Peak amplitudes (left) and width (right) of Ca2+ transients before (black) and after (red) exposure to two-photon excitation from control L2/3 pyramidal neurons (n = 9). (h) Average frequency of spontaneous tuft Ca2+ transients during QX-314 alone (blue; n=40 dendrites) and QX-314 and MK801 (red; n=11 dendrites) in the patch pipette. (i) In addition to synaptic input, large Ca2+ events in the apical dendrites of L2/3 neurons have also been shown in vitro to be due to Ca2+ release from ryanodine-sensitive intracellular stores (Larkum et al, 2003). We therefore tested whether the large Ca2+ events we measured in vivo were ryanodine sensitive. Reconstruction of L2/3 pyramidal neuron filled with ryanodine (10 μM) and QX-314 (1 mM). (j) Spontaneous (black) and evoked (hindlimb stimulation; red) Ca2+ transients recorded from the neuron shown in (i). The location of the imaged tuft dendrite is indicated by a red circle in (i). (k) Average peak amplitude and (l) frequency of the Ca2+ transients in neurons filled with QX-314 alone (blue; n = 465 transients from 8 dendrites) and both QX-314 and ryanodine (fuchsia; n = 117 transients from 42 dendrites). * p < 0.05. Error bars represent S.E.M.

Supplementary Figure 9 QX-314 increases the amplitude of the somatic voltage during NMDA spikes in tuft dendrites of layer 2/3 pyramidal neurons in vitro and in silico.

Intracellular application of QX-314 blocks Na+ channels as well as partially blocks Ca2+, Ih and K+ channels (Perkins and Wong, 1995; Talbot and Sayer, 1996). The effect of QX-314 on NMDA spikes was tested using somatic recordings from layer 2/3 pyramidal neurons which were initially patched with control intracellular solution and then repatched with intracellular solution containing QX-314. Neurons were filled with Alexa Fluor 594 (50 μM) to aid the placement of an extracellular stimulation pipette in close proximity to a tuft dendrite. (a) Somatic voltage response to somatic current step injections (100 pA steps) before (black) and after (blue) QX-314. Note the lack of action potentials in the presence of QX-314. (b) Sequentially increasing the intensity of paired pulses (2x 1 ms pulses at 50 Hz) to the tuft dendrite resulted in a supralinear voltage response both before (black) and after QX-314 (blue). A subthreshold and suprathreshold response is shown for each condition. (c) Amplitude of the somatic voltage during sequential increase in stimulus intensity for the example shown in (b). (d) QX-314 significantly increased the amplitude of the voltage response by approximately two-fold (2nd pulse; n =5; p < 0.05). (e) There was no significant influence of QX-314 on the stimulus intensity (threshold) required to evoke a spike (n = 5) nor the resting membrane potential (n = 6). (f) However, QX-314 significantly increased the input resistance by on average 48 ± 15 % (n = 6). (g) Bath application of the NMDA channel agonist APV (50 μM; bottom; green) significantly decreased the voltage response. (h) The effects of intracellular QX-314 on synaptic input (location; orange dot) was modeled by completely or partially blocking Na+, Ih, K+ and Ca2+ conductances (see supplemental methods). (i) Subthreshold and suprathreshold somatic responses to increasing NMDA/AMPA input in control (black) and QX-314 (blue) simulations at the synapse shown in (h). Note, the computer simulations are comparable to the experimental data in (b). In the presence of QX-314, the computational model shows no effect on threshold or resting membrane potential (j), an increase in the input resistance (k) and an increase in the amplitude of the second pulse of the paired pulse stimulation which was decreased during bath application of APV in control (l). These computer simulation results are comparable to the in vitro data shown in (a) - (g) and the increase in voltage during QX-314 can be entirely explained by the decrease in input resistance. * indicates p < 0.05. Error bars represent S.E.M.

Supplementary Figure 10 Details of the layer 2/3 computational model.

(a) A reconstructed layer 2/3 (L2/3) pyramidal neuron from the experimental part of this study was used for simulations in NEURON. (b) Top-down synaptic inputs (red) were placed with uniform probability distribution across the tuft dendrites and a further 100 synaptic inputs were distributed with uniform probability across the entire neuron to simulate background synaptic input (blue). Inset, background membrane potential. Red line: 17.3 mV from rest. Scale, 1 mV; 150 ms. (c) Table of conductance values used in the simulated neuron. All values are in units of nS. (d) A reconstructed L2/3 pyramidal neuron. (e) Computer simulations of the voltage response at the soma (green) and dendrite (blue) during current injection (1 s) into the soma (left) and dendrite (right) for the modeled neuron shown in (d). (f) Comparison of in vitro experiments (n = 6) and the model neuron for input resistance and resting membrane potential. Error bars are standard deviation. (g) (left) Nonlinear NMDA conductance used in the model. Note that the conductance is a function of the local membrane potential. Plots are shown at –40, –60, and –80 mV. (Right) Linear AMPA conductance used in the model. Note that the AMPA conductance is voltage independent. (h) Simulated voltage response to paired pulse stimulation (50 Hz) with increasing intensity with (red) and without (black; 'APV') NMDA conductance recorded at the soma (left) and at the site of stimulation (tuft dendrite; right). Inset, maximum voltage response at the soma as synaptic conductance increases. The non linearity in the control condition establishes the event as an NMDA spike, as described in previous work (Schiller et al., 2000, Schiller and Schiller, 2001, Rhodes, 2006, Major et al., 2008, Larkum et al., 2009).

Supplementary Figure 11 Blocking distributed NMDA conductances in the majority of the tuft affects AP generation.

The experimental data showed that locally blocking NMDA channels in a single tuft branch does not affect somatic action potentials (APs). To further investigate this, we used computer simulations in the NEURON simulation platform to manipulate the extent of the tuft experiencing NMDA block and measure the resulting effect on neuronal output. Top-down synaptic inputs were randomly distributed across the tuft dendrites and a further 100 synaptic inputs were distributed with uniform probability across the entire neuron to simulate background synaptic input (see Fig. S10). (a) A model layer 2/3 pyramidal neuron had NMDA conductances blocked in varying numbers of tuft branches. Synaptic input was randomly distributed for each trial and branches shown in red had both background and top-down NMDA conductances blocked. (b) Membrane potential traces in response to 60 synaptic inputs randomly distributed onto the tuft dendrite in neurons where NMDA conductances were removed from no (grey), one (brown), five (fuchsia) and all (green) tuft branches. During this simulation, NMDA block in five tuft dendrites is sufficient to substantially change neuronal output. (c) The total number of synapses needed to generate an AP compared to the number of branches with NMDA conductances removed. Colored dots refer to data shown in (b).

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Palmer, L., Shai, A., Reeve, J. et al. NMDA spikes enhance action potential generation during sensory input. Nat Neurosci 17, 383–390 (2014). https://doi.org/10.1038/nn.3646

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