Oral Presentation Lorne Infection and Immunity 2018

Non-capsular antibodies reduce pneumococcal colonisation density following therapeutic administration of a pneumococcal whole cell vaccine (#39)

Jayne Manning 1 2 , Viktoria R Bongcaron 1 3 , Eileen M Dunne 1 3 , Casey L Pell 1 , Polly Burbidge 4 , David Goldblatt 4 , E Kim Mulholland 1 5 , Roy M Robins-Browne 2 6 , Paul V Licciardi 1 3 , Richard Malley 7 , Odilia L Wijburg 1 2 , Catherine Satzke 1 2 3
  1. Pneumococcal Research, Murdoch Children's Research Institute , Parkville, Victoria, Australia
  2. Department of Microbiology and Immunology, The University of Melbourne at the Peter Doherty Institute for Infection and Immunity, Melbourne, Victoria, Australia
  3. Department of Paediatrics, The University of Melbourne, Parkville, Victoria, Australia
  4. Institute of Child Health, University College London, London, United Kingdom
  5. London School of Hygiene and Tropical Medicine, London, United Kingdom
  6. Infectious Diseases and Microbiology, Murdoch Children's Research Institute, Parkville, Victoria, Australia
  7. Division of Infectious Diseases, Boston Children’s Hospital, Boston, USA

Streptococcus pneumoniae (the pneumococcus) is an important paediatric pathogen that causes a range of respiratory tract diseases and commonly resides in the nasopharynx of young children. Over 90 pneumococcal serotypes exist, defined by their immunologically distinct capsular polysaccharide antigen. Current pneumococcal conjugate vaccines induce protection against only 10-13 serotypes. The pneumococcal whole cell vaccine (WCV) induces immunity against non-capsular antigens, and protects mice against nasopharyngeal colonisation via antibody-independent, TH17 mechanisms when administered before infectious challenge. In high disease-burden settings infants are exposed to pneumococci soon after birth. Therefore, we investigated the effect of WCV on colonisation when administered after established colonisation (“therapeutic” vaccination). Using an infant mouse model, we found that therapeutic WCV significantly reduced the density of pneumococcal colonisation in a dose dependent manner by 4.3-fold (one dose, p<0.001) and 8.6-fold (two doses, p=0.014) compared to therapeutic adjuvant (Mann-Whitney U Test). This reduction was dependent on non-capsular antibodies: therapeutic WCV did not affect colonisation in antibody-deficient μMT-/- mice compared to therapeutic adjuvant, and levels of plasma IgG specific for the WCV antigen (p=0.003), and pneumococcal antigens PspA (p=0.004), CbpA (p=0.022) and PiaA (p=0.028) were inversely correlated with colonisation density in wild type mice (Spearman’s correlation). No associations between systemic, local or splenic IL-17A responses and colonisation density were observed. In addition, significantly fewer pneumococci were shed from the upper respiratory tract of mice after each WCV dose. Our results demonstrate that WCV immunisation is also effective when given during colonisation, and indicate a novel role for non-capsular antibodies in controlling colonisation density. Given that WCV reduces colonisation density and shedding, it is likely that WCV could reduce pneumococcal transmission and contribute to herd protection. These data support further investigation of WCV in high disease-burden settings where children are more likely to carry pneumococci at the time of vaccination.