Peptides actively transported across the tympanic membrane: Functional and structural properties

Otitis media (OM) is the most common infectious disease of children under six, causing more antibiotic prescriptions and surgical procedures than any other pediatric condition. By screening a bacteriophage (phage) library genetically engineered to express random peptides on their surfaces, we discov...

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Bibliographic Details
Published in:PloS one 2017-02, Vol.12 (2), p.e0172158-e0172158
Main Authors: Kurabi, Arwa, Beasley, Kerry A, Chang, Lisa, McCann, James, Pak, Kwang, Ryan, Allen F
Format: Article
Language:English
Subjects:
Active transport
Amino Acid Motifs
Analysis
Animals
Antibiotics
Biological Transport
Biology and Life Sciences
C-Terminus
Care and treatment
Children
Drug delivery
Drug delivery systems
Drug therapy
Ear
Ear diseases
Ear, Middle - physiology
Ears & hearing
Expression vectors
Gene therapy
Genetic engineering
Hearing loss
Hydrogen-Ion Concentration
Hydrophobicity
Infectious diseases
Inner ear
Isoelectric Point
Lysine
Lysine - chemistry
Male
Medicine
Medicine and Health Sciences
Middle ear
Otitis media
Otitis Media - metabolism
Otitis Media - physiopathology
Otitis Media with Effusion - metabolism
Otitis Media with Effusion - physiopathology
Otolaryngology
Peptide Library
Peptides
Peptides - metabolism
Phages
Physiochemistry
Protein Domains
Rats
Rats, Sprague-Dawley
Research and Analysis Methods
Risk factors
Structure-function relationships
Surgery
Transport
Tympanic membrane
Tympanic Membrane - physiology
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Summary:Otitis media (OM) is the most common infectious disease of children under six, causing more antibiotic prescriptions and surgical procedures than any other pediatric condition. By screening a bacteriophage (phage) library genetically engineered to express random peptides on their surfaces, we discovered unique peptides that actively transport phage particles across the intact tympanic membrane (TM) and into the middle ear (ME). Herein our goals were to characterize the physiochemical peptide features that may underlie trans-TM phage transport; assess morphological and functional effects of phage peptides on the ME and inner ear (IE); and determine whether peptide-bearing phage transmigrate from the ME into the IE. Incubation of five peptide-bearing phage on the TM for over 4hrs resulted in demonstrably superior transport of one peptide, in level and in exponential increase over time. This suggests a preferred peptide motif for TM active transport. Functional and structural comparisons revealed unique features of this peptide: These include a central lysine residue, isoelectric point of 0.0 at physiological pH and a hydrophobic C-terminus. When the optimal peptide was applied to the TM independent of phage, similar transport was observed, indicating that integration into phage is not required. When 109 particles of the four different trans-TM phage were applied directly into the ME, no morphological effects were detected in the ME or IE when compared to saline or wild-type (WT) phage controls. Comparable, reversible hearing loss was observed for saline controls, WT phage and trans-TM peptide phage, suggesting a mild conductive hearing loss due to ME fluid. Perilymph titers after ME incubation established that few copies of trans-TM peptide phage crossed into the IE. The results suggest that, within the parameters tested, trans-TM peptides are safe and could be used as potential agents for noninvasive delivery of drugs, particles and gene therapy vectors to the ME.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0172158