Transplanted sweat glands from mature and aged donors determine cholinergic phenotype and altered density of host sympathetic nerves

Abstract

Contact with sweat gland acini causes sympathetic neurons to switch from a catecholaminergic to a cholinergic phenotype during development and following experimental manipulations. Substantial reductions of cholinergic innervation have been shown in the sweat glands of ageing rats and humans. Using in oculo transplantation, we have now studied whether sweat gland target tissues retain the capacity to regulate changes in the phenotype of sympathetic neurons observed in maturity and old age, including a switch from catecholaminergic to cholinergic characters. Markers have been used which indicate changes in nerve fibre morphology (the pan-neuronal marker, PGP9.5) as well as neurotransmitter expression (acetylcholinesterase (AChE), vasocative intestinal polypeptide (VIP) and tyrosine hydroxylase (TH). Sweat glands from young and old donor rats became reinnervated by an organotypic pattern of cholinergic host nerves. Surgical sympathectomy demonstrated that these cholinergic nerve fibres originate from sympathetic neurons of the host superior cervical ganglion (SCG). Retrograde tracing combined with staining for VIP (a marker associated with cholinergic phenotype in neurons supplying sweat glands) showed that SCG neurons projecting to irises with sweat gland implants may be induced to express VIP. We hypothesise that these neurons have been switched from their normal catecholaminergic phenotype to a cholinergic one by contact with the sweat gland implants. Transplants from old donors attracted a density of reinnervation by young host nerves which was appropriate to the age of the donor, thus old sweat glands received a significantly reduced density of innervation compared to young glands. Despite the reduced density of innervation, there was no obvious difference in the ability of young and old implants to induce the switch to a cholinergic phenotype, suggesting that different mechanisms regulate nerve growth and neurotransmitter phenotype.