Abstract
ABSTRACTThe preBötzinger Complex (preBötC) of the lower brainstem generates two breathing-related rhythms: one for inspiration on a timescale of seconds and another that produces larger amplitude sighs on the order of minutes. Their underlying mechanisms and cellular origins remain incompletely understood. We resolve these problems via a joint experiment and modeling approach. Blocking purinergic gliotransmission does not perturb either rhythm and imaging experiments show that both rhythms emanate from the same glutamatergic neuron population. We hypothesized that these two disparate rhythms emerge in tandem wherein recurrent excitation gives rise to inspiratory rhythm while a calcium oscillator generates sighs; there is no obligatory role for gliotransmission, hyperpolarization activated mixed cationic current (Ih) in neurons, or synaptic inhibition-mediated coupling of separate populations. We developed a mathematical model that instantiates our working hypothesis. Tests of model predictions validate the single-population rhythmogenic framework, reproducing disparate breathing-related frequencies and the ability for inspiratory and sigh rhythms to be separately regulated in support of respiration under a wide array of conditions. Here we show how a single neuron population exploits two cellular tool-kits: one involving voltage-dependent membrane properties and synaptic excitation for inspiratory breathing (eupnea) and an intracellular biochemical oscillator for sighs, which ventilate and maintain optimal function in the compliant mammalian lung.SIGNIFICANCE STATEMENTBreathing consists of two vital rhythms: one for eupnea that serves periodic physiological gas exchange and the other for sighs, which are larger breaths that occur minutes apart and serve to optimize pulmonary function. These rhythms with disparate frequencies emerge via a mechanism that is simpler than previously envisaged: it results from one neuron population (not two as previously thought) without need for gliotransmission or synaptic inhibition-mediated coupling of neuronal populations. We show that a low-frequency intracellular calcium oscillation underlies sighs and functions in parallel with the higher-frequency voltage-dependent network oscillation that drives eupnea. Exploiting two separate cellular tool kits enables quasi-independent breathing rhythms, which are unique features of breathing in mammals with compliant lungs.
Publisher
Cold Spring Harbor Laboratory