Premium
Functional Characterization of Developmental Whole Rhombomere Brainstem Populations in Adult Respiratory Physiology
Author(s) -
Sun Jenny Jia,
Ray Russell S
Publication year - 2017
Publication title -
the faseb journal
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.709
H-Index - 277
eISSN - 1530-6860
pISSN - 0892-6638
DOI - 10.1096/fasebj.31.1_supplement.727.6
Subject(s) - brainstem , rhombomere , biology , hindbrain , neuroscience , respiratory system , respiration , respiratory rate , microbiology and biotechnology , anatomy , central nervous system , endocrinology , heart rate , gene , genetics , hox gene , transcription factor , blood pressure
The perpetual rhythm of breathing is essential for survival and emerges through the interactions of a highly redundant and anatomically complex array of brainstem neuronal networks. Previous studies suggest that proper partitioning of the hindbrain into transient, genetically‐defined segments called rhombomeres (r) is required for normal respiratory development. However, because most studies of rhombomeric mispatterning result in embryonic or neonatal lethality, it remains unclear if rhombomeres ultimately play a role in adult circuit modules that regulate unique aspects of respiration. Further, gross loss or perturbation of a whole rhombomeric domain during development likely results in cell non‐autonomous effects such as the mis‐patterning of neighboring rhombomeric segments or neuronal populations. To bypass embryonic lethality and avoid non‐autonomous developmental perturbations, we used conditional mouse lines crossed to rhombomeric specific Cre drivers to express pharmaco‐genetic DREADD receptors in adult cell populations derived from one or more rhombomeric domains. We expressed two different DREADD receptors for acute and non‐invasive perturbation ( RC::FP_hM4D ) and stimulation ( RC::FP_hM3D ) of targeted adult brainstem neurons in the conscious and unrestrained mouse. In combination with whole‐body plethysmography and ECG, we are able to accurately measure respiratory parameters under room air, hypercapnic (5% CO 2 ), and hypoxic (10% O 2 ) conditions in conscious and unrestrained mice while observing heart rate in a subset of experiments. Our data demonstrate that distinct adult rhombomere derived populations (r1, r2, r3&5, r4, and r7&8) differentially affect respiratory rate, tidal volume, minute ventilation, oxygen consumption, and waveform patterns when they are perturbed or stimulated under various respiratory conditions. For example, perturbation of r2 neurons resulted in no significant changes under room air (n=24) or 5% CO 2 (n=12) conditions, but under 10% O 2 after CNO administration, experimental animals (n=12) showed a reduced V f (−36.54 breaths/min, p=0.000035), V T (−0.0012 mL/breath/g, p=0.0134), V E (−0.6435 mL/min/g, p=0.00043), and V E /V O2 (−10.6826, p=0.0212) as compared to sibling controls (n=12). On the other hand, perturbation of r3&5 neurons resulted in significant changes under all three ventilatory conditions: under room air (n=24) we saw reduced V T (−0.0011 mL/breath/g, p=0.0016), V E (−0.2639 mL/min/g, p=0.0043), and V E /V O2 (−6.3370, p=0.003); under hypercapnic conditions (n=12) we saw lower V f (−58.046 breaths/min, p=0.73), V T (−0.1110 mL/breath/g, p=0.59), V E (−1.9847 mL/min/g, p=0.13), V O2 (−0.0030 mL/min/g, p=0.0355), and V E /V O2 (−40.8103, p=0.17); and under hypoxic conditions (n=12) we saw reduced V f (−38.5233 breaths/min, p=0.0018), V T (−0.0010 mL/breath/g, p=0.048), V E (−0.5992 mL/min/g, p=0.56), and V E /V O2 (−12.5255, p=0.0054). Finally, DREADD mediated excitation of targeted rhombomeric domains all resulted in rapid death, with unique differences in the patterns of cardio‐respiratory failure. These data show the contribution of early embryonic patterning in defining the functional organization of the adult respiratory network, and set the stage to use intersectional genetics to further identify neuron subtypes within each rhombomere that are involved in specific aspects of respiratory homeostasis. Support or Funding Information NHLBI R01 HL130249, BCM McNair Scholar Program, March of Dimes Basil O'Connor Research Award, Parker B. Francis Fellowship, Dunn Collaborative Research Award, CJ Foundation for SIDS, American Heart Association