TY - JOUR
T1 - In vitro model to evaluate effect of acidic pepsin on vocal fold barrier function
AU - Kojima, Keisuke
AU - Katsuno, Tatsuya
AU - Kishimoto, Yo
AU - Mizuta, Masanobu
AU - Nakamura, Ryosuke
AU - Ohnishi, Hiroe
AU - Yamada, Koichiro
AU - Kawai, Yoshitaka
AU - Tateya, Ichiro
AU - Omori, Koichi
N1 - Publisher Copyright:
© 2024 Elsevier Inc.
PY - 2024/11/5
Y1 - 2024/11/5
N2 - The pathophysiology of laryngopharyngeal reflux (LPR) and its impact on the vocal fold is not well understood, but may involve acid damage to vocal fold barrier functions. Two different components encompass vocal fold barrier function: the mucus barrier and tight junctions. Mucus retained on epithelial microprojections protects the inside of the vocal fold by neutralizing acidic damage. Tight junctions control permeability between cells. Here we developed an in vitro experimental system to evaluate acidic injury and repair of vocal fold barrier functions. We first established an in vitro model of rat vocal fold epithelium that could survive at least one week after barrier function maturation. The model enabled repeated evaluation of the course of vocal fold repair processes. Then, an injury experiment was conducted in which vocal fold cells were exposed to a 5-min treatment with acidic pepsin that injured tight junctions and cell surface microprojections. Both of them healed within one day of injury. Comparing vocal fold cells treated with acid alone with cells treated with acidic pepsin showed that acidic pepsin had a stronger effect on intercellular permeability than acid alone, whereas pepsin had little effect on microprojections. This result suggests that the proteolytic action of pepsin has a larger effect on protein-based tight junctions than on phospholipids in microprojections. This experimental system could contribute to a better understanding of vocal fold repair processes after chemical or physical injuries, as well as voice problems due to LPR pathogenesis.
AB - The pathophysiology of laryngopharyngeal reflux (LPR) and its impact on the vocal fold is not well understood, but may involve acid damage to vocal fold barrier functions. Two different components encompass vocal fold barrier function: the mucus barrier and tight junctions. Mucus retained on epithelial microprojections protects the inside of the vocal fold by neutralizing acidic damage. Tight junctions control permeability between cells. Here we developed an in vitro experimental system to evaluate acidic injury and repair of vocal fold barrier functions. We first established an in vitro model of rat vocal fold epithelium that could survive at least one week after barrier function maturation. The model enabled repeated evaluation of the course of vocal fold repair processes. Then, an injury experiment was conducted in which vocal fold cells were exposed to a 5-min treatment with acidic pepsin that injured tight junctions and cell surface microprojections. Both of them healed within one day of injury. Comparing vocal fold cells treated with acid alone with cells treated with acidic pepsin showed that acidic pepsin had a stronger effect on intercellular permeability than acid alone, whereas pepsin had little effect on microprojections. This result suggests that the proteolytic action of pepsin has a larger effect on protein-based tight junctions than on phospholipids in microprojections. This experimental system could contribute to a better understanding of vocal fold repair processes after chemical or physical injuries, as well as voice problems due to LPR pathogenesis.
KW - Acidic-pepsin
KW - In vitro model
KW - Transepithelial electrical resistance
KW - Vocal fold epithelium
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U2 - 10.1016/j.bbrc.2024.150401
DO - 10.1016/j.bbrc.2024.150401
M3 - Article
AN - SCOPUS:85198936496
SN - 0006-291X
VL - 732
JO - Biochemical and Biophysical Research Communications
JF - Biochemical and Biophysical Research Communications
M1 - 150401
ER -