Intestinal
Mucin Induces More Endocytosis but Less
Transcytosis of Nanoparticles across Enterocytes by Triggering Nanoclustering
and Strengthening the Retrograde Pathway
Mucus, which is secreted by the goblet
cells of enterocytes, constitutes
the first obstacle encountered for the intestinal absorption of nanomedicines.
For decades, mucus has simply been regarded as a physical barrier
that hinders the permeation and absorption of drugs, because of its
high viscosity and reticular structure, whereas the interaction of
mucus ingredients with nanomedicines is usually neglected. It is unclear
whether glycoproteins, as the main components of mucus, interact with
nanomedicines. We also do not know how the potential interaction affects
the subsequent transportation of nanomedicines through the intestinal
epithelium. In this study, mucin as the key element of mucus was investigated
to characterize the interaction of nanomedicines with mucus. PEG-modified
gold nanoparticles (PGNPs) were fabricated as model nanoparticles.
Mucin was found to adhere to the nanoparticle surface to form a corona
structure and induce the clustering of PGNPs by joining particles
together, demonstrating the interaction between mucin and PGNPs. In
addition, two intestinal epithelia, Caco-2 (non- mucus secretion)
and HT-29 (high mucus secretion), were compared to evaluate the influence
of mucin on the cellular interaction of PGNPs. Amazingly, mucin altered
the trafficking characteristic of PGNPs in intestinal epithelium.
Both in vitro and in vivo investigations demonstrated more nanoparticles
being internalized by cells due to the mucin coverage. However, mucin
induced a significant reduction in the transcytosis of PGNPs across
epithelial monolayers. The mechanism exploration further revealed
that the “more endocytosis but less transcytosis (MELT)”
effect was mainly attributed to the strengthened retrograde pathway
in which more PGNPs were transported to Golgi apparatus and exocytosed
back to the apical but not the basolateral side of the epithelial
monolayers. The “MELT” effect endowed mucin with duality
in the nanoparticle transportation. Therefore, the rational regulation
based on the “MELT” effect will provide new insight
into overcoming the mucus obstacle as a barrier and enhancing the
oral absorption rate of nanomedicines.