The role of pulmonary mast cells in neurotrophin 4 mediated cholinergic neuroplasticity in neonatal asthma

Patel, Kruti Rajan

15 June 2016

Asthma is a chronic inflammatory lung disease characterized by recurrent wheezing, coughing and difficulties in breathing. Asthma affects 25.7 million people in the USA including 8 million children. Asthma is often associated with early-life exposure to environmental insults. However, mechanisms that link early-life insults to persistent airway dysfunction are unknown. Our previous studies in mice showed that early-life allergen exposure increases the levels of neurotrophin 4 (NT4) causing airway smooth muscle (ASM) hyper innervation and persistent airway hyper reactivity (AHR). I show that early-life allergen exposure selectively increases cholinergic innervation. Notably, cholinergic nerves release acetylcholine, a potent airway constrictor that signals through the M3 receptor in ASM. Building upon these findings, my thesis encompasses two components. Firstly, how is NT4 expression aberrantly up regulated following early-life allergen exposure? Secondly, what is the effect of enhanced cholinergic innervation on the neonatal ASM? I find that NT4 is selectively expressed by ASM and mast cells in mice, nonhuman primates and humans. We show in mice that while NT4 expression in ASM remains unchanged upon allergen exposure, mast cells expand in number and degranulate to release NT4 thereby increasing NT4 levels in the lung. Adoptive transfer of wild-type mast cells, but not NT4-/- mast cells restores ASM innervation and AHR in KitW-sh/W-sh mice following early-life insults. In an infant primate model of asthma, the increased ASM innervation is also associated with the expansion and degranulation of mast cells. Therefore, pulmonary mast cells are a key source of aberrant NT4 expression following early-life insults in both mice and possibly primates. Next, I speculated that an increased cholinergic output in the neonatal lung might lead to persistent AHR. Using recurrent methacholine exposure and M3 receptor blocker, 4-DAMP, I show that enhanced cholinergic signaling in neonatal mice leads to persistent AHR without inflammation. In contrast, methacholine exposure in adult mice has no prolonged effects on airway reactivity. Together, my findings support a model in which deregulated neural activities following early-life insults cause persistent ASM hyper contractility. Thus, early-life interventions to block mast cell degranulation and the cholinergic pathway may benefit children with recurrent wheezing. / 2016-12-15T00:00:00Z

Immunology

NT4

Airway smooth muscle

Childhood asthma

Cholinergic innervation

Mast cells

Development of Cardiac Parasympathetic Neurons, Glial Cells, and Regional Cholinergic Innervation of the Mouse Heart

Fregoso, S. P., Hoover, D. B.

27 September 2012

Very little is known about the development of cardiac parasympathetic ganglia and cholinergic innervation of the mouse heart. Accordingly, we evaluated the growth of cholinergic neurons and nerve fibers in mouse hearts from embryonic day 18.5 (E18.5) through postnatal day 21(P21). Cholinergic perikarya and varicose nerve fibers were identified in paraffin sections immunostained for the vesicular acetylcholine transporter (VAChT). Satellite cells and Schwann cells in adjacent sections were identified by immunostaining for S100β calcium binding protein (S100) and brain-fatty acid binding protein (B-FABP). We found that cardiac ganglia had formed in close association to the atria and cholinergic innervation of the atrioventricular junction had already begun by E18.5. However, most cholinergic innervation of the heart, including the sinoatrial node, developed postnatally (P0.5-P21) along with a doubling of the cross-sectional area of cholinergic perikarya. Satellite cells were present throughout neonatal cardiac ganglia and expressed primarily B-FABP. As they became more mature at P21, satellite cells stained strongly for both B-FABP and S100. Satellite cells appeared to surround most cardiac parasympathetic neurons, even in neonatal hearts. Mature Schwann cells, identified by morphology and strong staining for S100, were already present at E18.5 in atrial regions that receive cholinergic innervation at later developmental times. The abundance and distribution of S100-positive Schwann cells increased postnatally along with nerve density. While S100 staining of cardiac Schwann cells was maintained in P21 and older mice, Schwann cells did not show B-FABP staining at these times. Parallel development of satellite cells and cholinergic perikarya in the cardiac ganglia and the increase in abundance of Schwann cells and varicose cholinergic nerve fibers in the atria suggest that neuronal-glial interactions could be important for development of the parasympathetic nervous system in the heart.

cardiac ganglia

cholinergic innervation

heart

parasympathetic

satellite cells

schwann cells

Biomedical Sciences