Ullah G , Demuro A , Parker I , Pearson JE .

R01 GM065830 NIGMS NIH HHS , P50-AG16573 NIA NIH HHS , R37-GM48071 NIGMS NIH HHS , R37 GM048071 NIGMS NIH HHS , P50 AG016573 NIA NIH HHS

             amyloid-beta formation
             calcium ion homeostasis
             regulation of amyloid-beta clearance
             cellular response to amyloid-beta
             calcium ion export across plasma membrane

                neurodegenerative disease
                tauopathy

	Fig 2. Average statistics of Aβ42 pores.Mean open probability (A), open time (B), and closed time (C) as a function of SPLM (maximum permeability in units of SPLs) for all pores. The symbols represent the experimental data. The thick solid and thin dotted lines are the fits from the simplest and best models respectively presented below. The bars represent standard error of the mean.
	Fig 3. Model fits to the distributions from type 1 pore.(A) The simplest (BIC = -926) and (B) best (BIC = -1071) models. Closed (C) and open (D) dwell-time distributions (probability density functions (PDF)): bars (experimental data), thick solid line (simplest model), and thin dotted line (best model). Experimental data taken from 217 type 1 pores in three oocytes.
	Fig 4. Model fits to type 2 pores.(A) The simplest (BIC = -16495) and (B) best (BIC = -17039) models. Dwell-time distribution (PDF) in closed state (C), SPL 1 (D), and SPL 2 (E): bars (experimental data), thick solid line (simplest model), and thin dotted line (best model). Experimental data taken from 232 type 2 pores in three oocytes.
	Fig 5. Model fits to type 3 Aβ pores.(A) The simplest (BIC = -21844) and (B) best (BIC = -22887) models. Dwell-time distribution (PDF) in closed level (C), SPL 1 (D), SPL 2 (E), and SPL 3 (F): bars (experimental data), thick solid line (simplest model), and thin dotted line (best model). Experimental data taken from 146 type 3 pores in three oocytes.
	Fig 6. Model fits to type 4 Aβ pores.(A) The simplest (BIC = -8619) and (B) best (BIC = -9449) model. Dwell-time distribution (PDF) in closed level (C), SPL 1 (D), SPL 2 (E), SPL 3 (F), and SPL 4 (G): bars (experimental data), thick solid line (simplest model), and thin dotted line (best model). Experimental data taken from 35 type 4 pores in three oocytes.
	Fig 7. Model fits to type 5 Aβ pores.(A) The simplest (BIC = -4738) and (B) best (BIC = -5229) models. Dwell-time distribution (PDF) in closed level (C), SPL 1 (D), SPL 2 (E), SPL 3 (F), SPL 4 (G), and SPL 5 (H): bars (experimental data), thick solid line (simplest model), and thin dotted line (best model). Experimental data taken from 13 type 5 pores in three oocytes.
	Fig 8. The normalized mean occupancies of all conductance levels in all five groups of Aβ42 pores.The squares, circles, diamonds, up, and down triangles represent the experimental data and dotted lines are the fits from the best models. Black, red, blue, green, and pink represent pores with SPLM 1, 2, 3, 4, and 5 respectively.
	Fig 9. Peak intracellular Ca2+ concentration at the pore location during a single opening of type 1 (black), 2 (blue), 3 (red), 4 (purple), and 5 (green) Aβ1–42 pore during the simulation in S3 Fig.Here we show Ca2+ concentration along X-axis at the center of Y-axis passing through the pore.
	Fig 10. A measure of Aβ pore toxicity in terms of effect on the gating of other channels in the neighborhood.The open probability of IP3R at [IP3] = 100nM (A), normalized current through Ca2+-activated Cl- channel at membrane potential, V = -40mV (B), and open probability of BK channel at V = -60mV (C) and 40mV (D) respectively as a function of distance from the center of an active Aβ pore of type 1 (black), 2 (blue), 3 (red), 4 (purple), and 5 (green).
	Fig 1. Idealizing the fluorescence time-series data from a single Aβ pore.Fluorescence profile from a region of interest (1μm2) centered on an Aβ42 pore, representing the Ca2+ flux through the pore without (A) and with background subtraction (B). (C) Idealized trace, where the vertical axis represents the SPL to which the pore opens at a given time and zero represents the closed state. The two insets show two events on extended time-scale (Ca2+ flux through the pore with background subtraction (top) and idealized traces (bottom)).

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