Nasal Mucus Proteome and Immunotherapy

Allergic Rhinoconjunctivitis Clinical Trial

Official title: Seasonal Differences in Nasal Mucus Proteome and Impact of Immunotherapy

Status Recruiting

Clinical Trial Summary

Nasal mucus as first line defense barrier of the nasal mucosa contains a variety of proteins that act as functional units. We recently showed that the nasal mucus proteome between allergic rhinitis patients and healthy controls is significantly altered. The aim of the present project is to show changes in nasal mucus proteome between allergic rhinitis patients and healthy controls over the pollen and non pollen season and to further determine whether and if so how the proteome changes under immunotherapy. Patients and healthy controls will be enrolled at two time points namely during the pollen season and out of the pollen season. Statistical differences will be determined within the groups and between the groups as well as impact of immunotherapy on patients undergoing therapy. Mucus will be collected with a special suction device equipped with a mucus trap. Then, proteomic analysis will be performed by LC MS/MS mass spectrometry. Database search will identify distinct proteins and their function, origin etc. will be annotated. Protein groups will be analyzed through pathway enrichment and cluster analysis. Furthermore, mechanisms of immunotherapy in responders and success or failure of therapy could be determined. These could lead to the identification of potential biomarkers.

Clinical Trial Description

Nasal mucus as first line defense barrier of the nasal mucosa contains a variety of proteins that act as functional units. We recently showed that the nasal mucus proteome between allergic rhinitis patients and healthy controls is significantly altered. On protein level, immune response in allergic rhinitis is enhanced and barrier function is reduced as reflected by increased epithelial permeability. Moreover, there is an unfavorable imbalance in innate anti-proteases. Proteases in pollen grain could therefore not be adequately deactivated in the mucus further damaging the epithelium which leads to submucosal penetration of allergens and facilitated presentation to antigen presenting cells. The aim of the present project is to show changes in nasal mucus proteome between allergic rhinitis patients and healthy controls over the pollen and non pollen season and to further determine whether and if so how the proteome changes under immunotherapy. For the first aim patients and healthy controls will be enrolled at two time points namely during the pollen season and out of the pollen season. Statistical differences will be determined within the groups and between the groups. The protein changes over the time course reflect how allergics but also healthy controls react to allergen challenge. The results should give insight on possible biomarkers that could be used for diagnostics and therapy. Protein substitution or inhibition may be a future therapy to reinforce the barrier function of nasal mucus and treat allergic rhinitis symptoms. The effect of immunotherapy as sole causal therapy will be determined and therapy responders will be compared to non-responders. We hypothesize that responders will show proteome changes similar to healthy conditions. This further concretizes distinct proteins as biomarkers that could be used as therapeutic agents. Moreover proteome changes could be used to predict and monitor therapeutic success or failure and patients may be stratified to be subjected to other therapeutic strategies than immunotherapy saving time and money. Mucus will be collected with a special suction device equipped with a mucus trap. Then, proteomic analysis will be performed by LC MS/MS mass spectrometry. Database search will identify distinct proteins and their function, origin etc. will be annotated. Protein groups will be analyzed through pathway enrichment and cluster analysis. By this means complex proteomic data can be visualized for a better understanding of global changes in protein networks and functions. Investigating the nasal mucus proteome in diseased and healthy state leads to a better understanding of its barrier function and reaction to allergens. Distinct proteins and/or proteins groups could be used as biomarkers for novel diagnostic and therapeutic approaches. Furthermore, mechanisms of immunotherapy in responders and success or failure of therapy could be determined. ;

Related Conditions & MeSH terms

• Allergic Rhinoconjunctivitis

• NCT number: NCT02159404
• Study type: Observational
• Source: Medical University of Graz
• Contact: Peter V Tomazic, M.D.
• Phone: +4331638581347
• Email: peter.tomazic@medunigraz.at
• Status: Recruiting
• Start date: April 2015
• Completion date: January 1, 2025