Erectile dysfunction (ED) is a serious medical condition in which current treatments are ineffective in
prostatectomy and diabetic patients, due to injury to the cavernous nerve (CN), which causes irreversible remodeling of the penis (decreased smooth muscle and increased
collagen), through a largely undefined mechanism. We propose that sonic hedgehog (SHH) and neural innervation, are indispensable regulators of
collagen in the penis, with decreased SHH
protein being an integral component of the fibrotic response to loss of innervation. We examined
collagen abundance and morphology in control (Peyronie's),
prostatectomy and diabetic patients, and in rat models of penile development, CN injury, SHH inhibition and under regenerative conditions, utilizing self-assembling
peptide amphiphile (PA) nanofiber
hydrogels for SHH delivery.
Collagen abundance increased in penis of ED patients. In rats,
collagen increased with CN injury in a defined time frame independent of injury severity. An inverse relationship between SHH and
collagen abundance was identified; SHH inhibition increased and SHH treatment decreased penile
collagen. SHH signaling in the pelvic ganglia (PG)/CN is important to maintain CN integrity and when inhibited, downstream
collagen induction occurs.
Collagen increased throughout penile development and with age, which is important when considering how to treat
fibrosis clinically. These studies show that SHH PA treatment reduces
collagen under regenerative post-
prostatectomy conditions, indicating broad application for ED prevention in
prostatectomy, diabetic and aging patients and in other
peripheral nerve injuries. The PA nanofiber
protein vehicle may be widely applicable as an in vivo delivery tool.
STATEMENT OF SIGNIFICANCE: We use self-assembling
peptide amphiphiles (PA) as biological delivery vehicles to prevent cavernous nerve (CN) injury induced
erectile dysfunction (ED). These versatile
hydrogels were molecularly pre-programmed for sonic hedgehog (SHH)
protein delivery, either from an
injectable solution with fast, in situ assembly into a soft
hydrogel, or by highly aligned monodomain nanofiber bundles. We used PAs to examine a novel neuronal component to
collagen regulation and the role of SHH in the fibrotic response to CN injury. SHH perturbation in the penis or the CN, selectively impacts
collagen, with SHH inhibition increasing and SHH treatment suppressing
collagen. These results suggest that SHH treatment by PA has translational potential to suppress
collagen induction and remodelling, an irreversible component of ED development.