Figures and data
Components of the sympathetic reflex.
Schematic of the components of the sympathetic autonomic reflex: Sensory neurons send information to the central component (pre-ganglionic neurons), where information is processed. Then, sympathetic motor neurons receive information from pre-ganglionic neurons to transmit it to the target organ. This research was focused on evaluating the age-related changes in the function of sympathetic motor neurons.
Sympathetic motor neurons from old mice are healthy in culture.
(A) Diagram of the experimental approach: Sympathetic motor neurons were isolated from the superior cervical ganglia (SCG) of 12- and 115-week-old mice. The ganglia did not show morphological differences between ages. (B) Differential Interference Contrast images of sympathetic motor neurons in culture for 18 h and 72 h. Right images at 72 h outline the dendritic area measured. w, weeks. (C) Comparison of soma diameter between neurons isolated from 12 or 115 weeks of age at two-time points in culture. Orange circles showed single cells from 12-week-old mice while purple triangles show single cells from 115-week-old mice. (D) Comparison of the total dendritic area as a proxy for neurite regeneration in culture. Data points are from N = 3 animals, n = 38 cells, from 12 weeks old, and N = 3 animals, n = 39 cells, from 115 weeks old. p-values are shown at the top of the graphs. Red values indicate p-values < 0.05 while black values indicate p-values > 0.05.
Sympathetic motor neurons from old mice fire action potentials spontaneously.
(A) Schematic of ages in mice, and equivalent in humans, that were used to compare the functional responses of sympathetic motor neurons.(B)Representative membrane potential recordings of spontaneous activity from neurons isolated from 12-, 64-, and 115-week-old mice. (C) Comparison of the Resting Membrane Potential (RMP) between different ages. (D) Comparison of percentage of silent and firing neurons between different ages. (E) Comparison of the number of action potentials (AP) fired spontaneously in one minute between different ages. (F) Top: Representative passive responses to hyperpolarizing stimuli from neurons isolated from 12-, 64-, and 115-week-old mice. Blue traces correspond to 0 pA injection, red traces to -10 pA, and black traces to -40 pA. Bottom: voltage-current relationship of top recordings. (G) Comparison of the input resistance between different ages. Data points are from N = 4 animals, n = 35 cells, from 12-week old, N = 6 animals, n = 65 cells, from 64-week old, and N = 4 animals, n = 32 cells, from 115-week old. p-values are shown at the top of the graphs. Red p-values indicate p-values < 0.05, while black p-values indicate p-values > 0.05.
Sympathetic motor neurons from old mice are more responsive to electrical stimulation.
(A) In the context of the sympathetic reflex, motor neurons increase their firing frequency in response to inputs from the sympathetic nuclei in the brain. In this study, motor neuron responses were measured using electrical stimulation at different ages. (B) Stimulation protocol to mimic preganglionic input. (C-E). Representative voltage responses of sympathetic motor neurons from 12-(C), 64-(D), and 115-week-old mice (E). Blue, red, and black traces are in response to 0, 10, and 40 pA current injection respectively. The dotted line shows 0 mV as reference. (F). Comparison of stimulation-response curves of the number of APs vs. injected current between different ages. (G) Comparison of the minimum current injected that elicited at least one AP (Rheobase) between different ages. (H) Comparison of the number of APs fired at the maximum stimulus (100 pA) between different ages. Data were collected from N = 4 animals, n = 34 cells, from 12 weeks old, N = 6 animals, n = 68 cells, from 64 weeks old, and N = 4 animals, n = 30 cells, from 115 weeks old. p-values are shown at the top of the graphs.
Analysis of neuronal subpopulations. Aging shifts neuronal population toward tonic firing.
(A) Representative recordings from three different neurons illustrate the variability in the response to show the method used to classify cells by their firing pattern as adapting (left), phasic (center), or tonic (right). Responses to stimulation of 0 (top), 20 pA above the rheobase (middle), and 100 pA (bottom). The classification was based on the response 20 pA above the rheobase. (B) Comparison of the number of APs elicited by current injections of 20 pA more than rheobase or 100 pA between classes. Data are from 64-week-old mice. (C)Comparison of the stimulus-frequency curves between classes. Data are from 64-week-old mice. (D) Comparison of RMP, (left), number of spontaneous APs (middle), and input resistance (right) between classes. All data are from 64-week-old mice. (E) Comparison of the percentage of neuronal firing subtypes between different ages. (F) Comparison of the RMP between ages and divided into neuronal subpopulations. (G) Comparison of the input resistance between ages and divided into neuronal subpopulations. (H) Comparison of the number of spontaneous APs between ages and neuronal subpopulations. (I) Comparison of the number of APs in response to maximum stimulation (100 pA) between ages and neuronal subpopulations. Data points are from N = 4 animals, n = 9, 7, and 3 from single, phasic, and old cells from 12-week-old mice. Data points are from N = 6 animals, n = 17, 38, and 11 from single, phasic, and old cells from 64-week-old mice. Data points are from N = 4 animals, n = 5, 23, and 11 from single, phasic, and old cells from 64-week-old mice. Red values indicate p-values < 0.05 while black values indicate p-values > 0.05.
Sympathetic motor neurons from old mice show a KCNQ current reduction.
(A) Recordings illustrating the relevance of KCNQ current for controlling membrane potential and firing in sympathetic motor neurons. Top: voltage response to inhibition of KCNQ channels with 10 μM Oxo-M, bottom: normalized KCNQ current recording in response to oxo-M in the same cell after going whole cell. (B) Schematic representation of the hypothesis that aged cells show reduced activity of KCNQ channels. (C) KCNQ current recordings from neurons isolated from mice of different ages (orange 12 weeks old, pink 64 weeks old, and purple 115 weeks old) in response to a voltage step (top). The inset shows an expanded view of the current tail. (D) Comparison of KCNQ current density between different ages. Data points are from N = 5 animals, n = 27 cells, from 12 weeks old, N = 8 animals, n = 62 cells, from 64 weeks old, and N = 5 animals, n = 24 cells, from 115 weeks old. (E) Comparison of capacitance between ages. (F) blot stained for total and KCNQ2 protein collected from superior cervical ganglia from 12- and 115-weeks-old mice. (G) Comparison of fold change of KCNQ2 abundance relative to total protein between ages (n = 5 blots from different mice). (H-J) Linear correlation between RMP and KCNQ current density in 12-weeks old (H), 64-weeks old (I), and 115-weeks old mice (J). (K) Comparison of the determination coefficient for the RMP and KCNQ current between ages. (L-N). Linear correlation between the number of APs at 100 pA and KCNQ current density in 12-week-old (L), 64-week-old (M), and 115-week-old mice (N). (O) Comparison of the determination coefficient for the maximum #AP and KCNQ current between ages. Data points are from N = 4 animals, n = 26 cells, from 12 weeks old, N = 6 animals, n = 58 cells, from 64 weeks old, and N = 4 animals, n = 24 cells, from 115 weeks old.
Sympathetic motor neurons from old mice did not show changes in sodium currents or XE-991-insensitive potassium currents.
(A) Left: Schematic of the hypothesis that KVchannels insensitive to XE-991 are reduced in aged cells. Right: Family of outward currents in the presence of KCNQ channel blocker, 100 nM XE-991, in 12-week-old, and 115-week-old mice. Magnitude of voltage step to elicit each trace is shown in black. (B) Current-voltage relationship of the steady-state KV currents insensitive to XE-991 from cells isolated from 12-week-old and 115-week-old mice. (C) Left: Schematic of the hypothesis that KV2 (Guangxitoxin-1E sensitive, Gtx) and KV4 (Phrixotoxin-1 sensitive, Ptx) channels are reduced in aged cells. Right: Family of Ptx- and Gtx-sensitive outward currents, and in the presence of XE-991, in 12-week-old and 115-week-old mice. Magnitude of stimulus to elicit each trace is shown in black. (D) Current-voltage relationship of the steady-state KV currents sensitive to Ptx- and Gtx from cells isolated from 12-week-old and 115-week-old mice. Data points of KV currents are from N = 3 animals, n = 12 cells, from 12 weeks old, N = 3 animals, n = 8 cells, from 115 weeks old. (E) Left: Schematic of the hypothesis that NaV channels sensitive to TTX are increased in aged cells. Right: Representative sodium current recordings from neurons isolated from mice of different ages (orange 12-week-old, pink 64-week-old, and purple 115-week-old) in response to a voltage step (top). (F) Current-voltage relationship of the peak sodium current for different ages. (G) Comparison of sodium current density between different ages. Data points of KV currents are from N = 3 animals, n = 12 cells, from 12-weeks old, N = 3 animals, n = 14 cells, from 64-weeks old, N = 3 animals, n = 14 cells, from 64-weeks old, and N = 3 animals, n = 13 cells, from 115-weeks old. p-values are shown at the top of the graphs.
Rapamycin treatment reverts age-related hyperexcitability and KCNQ current decrease.
(A) Schematic of the hypothesis that rapamycin treatment reverses the development of hyperexcitability. Mice were fed ad libitum with food containing rapamycin for 10-12 weeks. (B) Comparison of the RMP in cells isolated from 90-week-old mice fed with or without rapamycin. A paired 12-week-old mouse group was used for reference as young behavior. Data points are from N = 4 animals, n = 25 cells, from 90-week-old mice fed without rapamycin, N = 4 animals, n = 21 cells, from 90-week-old mice fed with rapamycin, and N = 3 animals, n = 17 cells, from 12 weeks old. (C) Comparison of the percentage of silent and firing neurons in 90-week-old mice fed with or without rapamycin, and a paired 12-week-old mice group. (D) Comparison of the stimulus-response curve between neurons isolated from 90-week-old mice fed with or without rapamycin. The stimulus-response curve from a 12-week-old mice group is shown for comparison. (E) Comparison of the rheobase in 90-week-old mice fed with or without rapamycin, and a paired 12-week-old mice group. (F) Comparison of the number of APs elicited with a maximum stimulation (100 pA) in mice fed with or without rapamycin, and a paired 12-week-old mice group. (G) Comparison of the capacitance in 90-week-old mice fed with or without rapamycin, and a paired 12-week-old mice group. (H) Comparison of the input resistance in 90-week-old mice fed with or without rapamycin, and a paired 12-week-old mice group. (I) Schematic of the hypothesis that rapamycin treatment reverses the KCNQ current reduction. (J) KCNQ2/3 current recordings from neurons isolated from 90-week-old mice fed with or without rapamycin. (K) Comparison of KCNQ current density in 90-week-old mice fed with or without rapamycin, and a paired 12-week-old mice group. Data points are from N = 4 animals, n = 23 cells, from 90-week-old mice fed without rapamycin, N = 4 animals, n = 22 cells, from 90-week-old mice fed with rapamycin, and N = 3 animals, n = 13 cells, from 12 weeks old. Red values indicate p-values < 0.05 while black values indicate p-values > 0.05.
Rapamycin-induced improvement is mediated by a direct effect sympathetic motor neurons.
(A) Schematic of the hypothesis that rapamycin treatment reverses hyperexcitability of aged neurons through a direct effect on sympathetic motor neurons. Isolated cells from 115-week-old mice were divided into two batches, one of them was treated with rapamycin overnight. (B) Comparison of the RMP from neurons treated with or without rapamycin from 115-week-old mice. (C) Comparison of the percentage of silent and firing neurons treated with or without rapamycin. (D) Comparison of the stimulus-response curve between neurons treated with or without rapamycin. (E) Comparison of the number of APs elicited with a maximum stimulation (100 pA). (F) Comparison of the rheobase. (G) Comparison of KCNQ current density. (H) Time course of KCNQ current amplitude during acute application of 100 nM rapamycin. Red values indicate p-values < 0.05 while black values indicate p-values > 0.05.
