TY - JOUR
T1 - Sputum proteome signatures of mechanically ventilated intensive care unit patients distinguish samples with or without anti-pneumococcal activity
AU - Seinen, Jolien
AU - Engelke, Rudolf
AU - Abdullah, Mohammed R.
AU - Voß, Franziska
AU - Michalik, Stephan
AU - Dhople, Vishnu M.
AU - Dieperink, Willem
AU - de Smet, Anne Marie G.A.
AU - Völker, Uwe
AU - van Dijl, Jan Maarten
AU - Schmidt, Frank
AU - Hammerschmidt, Sven
N1 - Funding Information:
This work was supported by the Graduate School of Medical Sciences of the University of Groningen (to J.S. and J.M.V.D.), the Deutsche Forschungsgemeinschaft grant GRK1870 (to S.H.), the Bundesministerium für Bildung und Forschung (BMBF) - Zwanzig20 - InfectControl 2020 - project VacoME - FKZ 03ZZ0816A (to S.H. and U.V.) and BMBF - project PROGRESS A3 - FKZ 01KI1010D (to U.V. and S.H.) and the “Biomedical Research Program” fund at Weill Cornell Medicine in Qatar, a program funded by the Qatar Foundation (to R.E. and F.S.). We further thank Kirsten Bartels from the Department of Functional Genomics at the University Medicine Greifswald and Karsta Barnekow, Niamatullah Kakar, and Gustavo A. Gámez from the Department of Molecular Genetics and Infection Biology at the University of Greifswald for technical support.
Publisher Copyright:
© 2021 Seinen et al. This is an open-access article distributed under the terms of the Creative Commons Attribution 4.0 International license.
PY - 2021/3/2
Y1 - 2021/3/2
N2 - Mechanically ventilated patients are at risk of contracting pneumonia. Therefore, these patients often receive prophylactic systemic antimicrobial therapy. Intriguingly however, a previous study showed that antimicrobial activity in bronchoalveolar aspirates (here referred to as “sputa”) from ventilated patients was only partially explained by antibiotic therapy. Here we report that sputa from these patients presented distinct proteome signatures depending on the presence or absence of antimicrobial activity. Moreover, we show that the same distinction applied to antibodies against Streptococcus pneumoniae, which is a major causative agent of pneumonia. Specifically, the investigated sputa that inhibited growth of S. pneumoniae, while containing subinhibitory levels of the antibiotic cefotaxime, presented elevated levels of proteins implicated in innate immune defenses, including complement and apolipoprotein-associated proteins. In contrast, S. pneumoniae-inhibiting sputa with relatively high cefotaxime concentrations or noninhibiting sputa contained higher levels of proteins involved in inflammatory responses, such as neutrophil elastase-associated proteins. In an immunoproteomics analysis, 18 out of 55 S. pneumoniae antigens tested showed significantly increased levels of IgGs in inhibiting sputa. Hence, proteomics and immunoproteomics revealed elevated levels of antimicrobial host proteins or S. pneumoniae antigen-specific IgGs in pneumococcal growth-inhibiting sputa, thus explaining their anti-pneumococcal activity. IMPORTANCE Respiratory pathogens like Streptococcus pneumoniae can cause severe pneumonia. Nonetheless, mechanically ventilated intensive care patients, who have a high risk of contracting pneumonia, rarely develop pneumococcal pneumonia. This suggests the presence of potentially protective antimicrobial agents in their lung environment. Our present study shows for the first time that bronchoalveolar aspirates, “sputa,” of ventilated patients in a Dutch intensive care unit were characterized by three distinct groups of proteome abundance signatures that can explain their anti-pneumococcal activity. Importantly, this anti-pneumococcal sputum activity was related either to elevated levels of antimicrobial host proteins or to antibiotics and S. pneumoniae-specific antibodies. Further, the sputum composition of some patients changed over time. Therefore, we conclude that our study may provide a novel tool to measure changes that are indicative of infection-related conditions in the lungs of mechanically ventilated patients.
AB - Mechanically ventilated patients are at risk of contracting pneumonia. Therefore, these patients often receive prophylactic systemic antimicrobial therapy. Intriguingly however, a previous study showed that antimicrobial activity in bronchoalveolar aspirates (here referred to as “sputa”) from ventilated patients was only partially explained by antibiotic therapy. Here we report that sputa from these patients presented distinct proteome signatures depending on the presence or absence of antimicrobial activity. Moreover, we show that the same distinction applied to antibodies against Streptococcus pneumoniae, which is a major causative agent of pneumonia. Specifically, the investigated sputa that inhibited growth of S. pneumoniae, while containing subinhibitory levels of the antibiotic cefotaxime, presented elevated levels of proteins implicated in innate immune defenses, including complement and apolipoprotein-associated proteins. In contrast, S. pneumoniae-inhibiting sputa with relatively high cefotaxime concentrations or noninhibiting sputa contained higher levels of proteins involved in inflammatory responses, such as neutrophil elastase-associated proteins. In an immunoproteomics analysis, 18 out of 55 S. pneumoniae antigens tested showed significantly increased levels of IgGs in inhibiting sputa. Hence, proteomics and immunoproteomics revealed elevated levels of antimicrobial host proteins or S. pneumoniae antigen-specific IgGs in pneumococcal growth-inhibiting sputa, thus explaining their anti-pneumococcal activity. IMPORTANCE Respiratory pathogens like Streptococcus pneumoniae can cause severe pneumonia. Nonetheless, mechanically ventilated intensive care patients, who have a high risk of contracting pneumonia, rarely develop pneumococcal pneumonia. This suggests the presence of potentially protective antimicrobial agents in their lung environment. Our present study shows for the first time that bronchoalveolar aspirates, “sputa,” of ventilated patients in a Dutch intensive care unit were characterized by three distinct groups of proteome abundance signatures that can explain their anti-pneumococcal activity. Importantly, this anti-pneumococcal sputum activity was related either to elevated levels of antimicrobial host proteins or to antibiotics and S. pneumoniae-specific antibodies. Further, the sputum composition of some patients changed over time. Therefore, we conclude that our study may provide a novel tool to measure changes that are indicative of infection-related conditions in the lungs of mechanically ventilated patients.
KW - Antimicrobial peptides
KW - Immunoproteomics
KW - Mechanical ventilation
KW - Proteomics
KW - Sputum
KW - Streptococcus pneumoniae
KW - immunoproteomics
KW - mechanical ventilation
KW - proteomics
KW - sputum
KW - antimicrobial peptides
UR - http://www.scopus.com/inward/record.url?scp=85103656440&partnerID=8YFLogxK
U2 - 10.1128/MSYSTEMS.00702-20
DO - 10.1128/MSYSTEMS.00702-20
M3 - Article
C2 - 33653939
AN - SCOPUS:85103656440
VL - 6
JO - mSystems
JF - mSystems
IS - 2
M1 - e00702-20
ER -