Identification of a human neonatal immune-metabolic network associated with bacterial infection

Claire L Smith; Paul Dickinson; Thorsten Forster; Marie Craigon; Alan Ross; Mizanur R. Khondoker; Rebecca France; Alasdair Ivens; David J Lynn; Judith Orme; Allan Jackson; Paul Lacaze; K. L. Flanagan; Benjamin J Stenson; Peter Ghazal

doi:10.1038/ncomms5649

Identification of a human neonatal immune-metabolic network associated with bacterial infection

Claire L Smith, Paul Dickinson, Thorsten Forster, Marie Craigon, Alan Ross, Mizanur R. Khondoker, Rebecca France, Alasdair Ivens, David J Lynn, Judith Orme, Allan Jackson, Paul Lacaze, K. L. Flanagan, Benjamin J Stenson, Peter Ghazal

Research output: Contribution to journal › Article › peer-review

Abstract

Understanding how human neonates respond to infection remains incomplete. Here, a system-level investigation of neonatal systemic responses to infection shows a surprisingly strong but unbalanced homeostatic immune response; developing an elevated set-point of myeloid regulatory signalling and sugar-lipid metabolism with concomitant inhibition of lymphoid responses. Innate immune-negative feedback opposes innate immune activation while suppression of T-cell co-stimulation is coincident with selective upregulation of CD85 co-inhibitory pathways. By deriving modules of co-expressed RNAs, we identify a limited set of networks associated with bacterial infection that exhibit high levels of inter-patient variability. Whereas, by integrating immune and metabolic pathways, we infer a patient-invariant 52-gene-classifier that predicts bacterial infection with high accuracy using a new independent patient population. This is further shown to have predictive value in identifying infection in suspected cases with blood culture-negative tests. Our results lay the foundation for future translation of host pathways in advancing diagnostic, prognostic and therapeutic strategies for neonatal sepsis.

Original language	English
Article number	4649
Number of pages	15
Journal	Nature Communications
Volume	5
Early online date	14 Aug 2014
DOIs	https://doi.org/10.1038/ncomms5649
Publication status	Published - 14 Aug 2014

Keywords

Biological Sciences
Immunology
Neonates
Medical Research

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10.1038/ncomms5649Licence: Creative Commons: Attribution-NonCommercial-NoDerivatives (CC BY-NC-ND)

Identification of a human neonatal immune-metabolic network associated with bacterial infection
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3 Finished

HIGH ACCURACY, LOW VOLUME HOST DIRECTED DETECTION OF NEONATAL SEPSIS
Ghazal, P. & Dickinson, P.
UK central government bodies/local authorities, health and hospital authorities
1/07/12 → 31/12/13
Project: Research
Molecular profiling consortium: biomarker identification & interaction
Ghazal, P. & Dickinson, P.
MRC
1/04/08 → 31/03/11
Project: Research
SynthSys; formerly CSBE: Centre for Systems Biology at Edinburgh
Millar, A., Beggs, J., Ghazal, P., Goryanin, I., Hillston, J., Plotkin, G., Tollervey, D., Walton, A. & Robertson, K.
BBSRC
8/01/07 → 31/12/12
Project: Research

1 Article

Whole blood gene expression profiling of neonates with confirmed bacterial sepsis
Dickinson, P., Smith, C. L., Forster, T., Craigon, M., Ross, A., Khondoker, M. R., Ivens, A., Lynn, D. J., Orme, J., Jackson, A., Lacaze, P., Flanagan, K. L., Stenson, B. & Ghazal, P., Mar 2015, In: Genomics Data. 3, p. 41-48
Research output: Contribution to journal › Article › peer-review

Open Access
File

Whole blood mRNA expression profiling of host molecular networks in neonatal sepsis
Smith, C. (Creator), Ghazal, P. (Creator), Dickinson, P. (Creator), Craigon, M. (Creator), Forster, T. (Hosting Institution) & Ross, A. (Creator), National Center for Biotechnology Information (Gene Expression Omnibus), 12 Aug 2014
http://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE25504
Dataset

Cite this

Smith, C. L., Dickinson, P., Forster, T., Craigon, M., Ross, A., Khondoker, M. R., France, R., Ivens, A., Lynn, D. J., Orme, J., Jackson, A., Lacaze, P., Flanagan, K. L., Stenson, B. J., & Ghazal, P. (2014). Identification of a human neonatal immune-metabolic network associated with bacterial infection. Nature Communications, 5, [4649 ]. https://doi.org/10.1038/ncomms5649

Smith, Claire L ; Dickinson, Paul ; Forster, Thorsten ; Craigon, Marie ; Ross, Alan ; Khondoker, Mizanur R. ; France, Rebecca ; Ivens, Alasdair ; Lynn, David J ; Orme, Judith ; Jackson, Allan ; Lacaze, Paul ; Flanagan, K. L. ; Stenson, Benjamin J ; Ghazal, Peter. / Identification of a human neonatal immune-metabolic network associated with bacterial infection. In: Nature Communications. 2014 ; Vol. 5.

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title = "Identification of a human neonatal immune-metabolic network associated with bacterial infection",

abstract = "Understanding how human neonates respond to infection remains incomplete. Here, a system-level investigation of neonatal systemic responses to infection shows a surprisingly strong but unbalanced homeostatic immune response; developing an elevated set-point of myeloid regulatory signalling and sugar-lipid metabolism with concomitant inhibition of lymphoid responses. Innate immune-negative feedback opposes innate immune activation while suppression of T-cell co-stimulation is coincident with selective upregulation of CD85 co-inhibitory pathways. By deriving modules of co-expressed RNAs, we identify a limited set of networks associated with bacterial infection that exhibit high levels of inter-patient variability. Whereas, by integrating immune and metabolic pathways, we infer a patient-invariant 52-gene-classifier that predicts bacterial infection with high accuracy using a new independent patient population. This is further shown to have predictive value in identifying infection in suspected cases with blood culture-negative tests. Our results lay the foundation for future translation of host pathways in advancing diagnostic, prognostic and therapeutic strategies for neonatal sepsis.",

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Identification of a human neonatal immune-metabolic network associated with bacterial infection. / Smith, Claire L; Dickinson, Paul; Forster, Thorsten; Craigon, Marie; Ross, Alan; Khondoker, Mizanur R.; France, Rebecca; Ivens, Alasdair; Lynn, David J; Orme, Judith; Jackson, Allan; Lacaze, Paul; Flanagan, K. L.; Stenson, Benjamin J; Ghazal, Peter.

In: Nature Communications, Vol. 5, 4649 , 14.08.2014.

Research output: Contribution to journal › Article › peer-review

TY - JOUR

T1 - Identification of a human neonatal immune-metabolic network associated with bacterial infection

AU - Smith, Claire L

AU - Dickinson, Paul

AU - Forster, Thorsten

AU - Craigon, Marie

AU - Ross, Alan

AU - Khondoker, Mizanur R.

AU - France, Rebecca

AU - Ivens, Alasdair

AU - Lynn, David J

AU - Orme, Judith

AU - Jackson, Allan

AU - Lacaze, Paul

AU - Flanagan, K. L.

AU - Stenson, Benjamin J

AU - Ghazal, Peter

PY - 2014/8/14

Y1 - 2014/8/14

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AB - Understanding how human neonates respond to infection remains incomplete. Here, a system-level investigation of neonatal systemic responses to infection shows a surprisingly strong but unbalanced homeostatic immune response; developing an elevated set-point of myeloid regulatory signalling and sugar-lipid metabolism with concomitant inhibition of lymphoid responses. Innate immune-negative feedback opposes innate immune activation while suppression of T-cell co-stimulation is coincident with selective upregulation of CD85 co-inhibitory pathways. By deriving modules of co-expressed RNAs, we identify a limited set of networks associated with bacterial infection that exhibit high levels of inter-patient variability. Whereas, by integrating immune and metabolic pathways, we infer a patient-invariant 52-gene-classifier that predicts bacterial infection with high accuracy using a new independent patient population. This is further shown to have predictive value in identifying infection in suspected cases with blood culture-negative tests. Our results lay the foundation for future translation of host pathways in advancing diagnostic, prognostic and therapeutic strategies for neonatal sepsis.

KW - Biological Sciences

KW - Immunology

KW - Neonates

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VL - 5

JO - Nature Communications

JF - Nature Communications

SN - 2041-1723

M1 - 4649

ER -

Identification of a human neonatal immune-metabolic network associated with bacterial infection

Abstract

Keywords

Access to Document

Fingerprint

Projects

HIGH ACCURACY, LOW VOLUME HOST DIRECTED DETECTION OF NEONATAL SEPSIS

Molecular profiling consortium: biomarker identification & interaction

SynthSys; formerly CSBE: Centre for Systems Biology at Edinburgh

Research output

Whole blood gene expression profiling of neonates with confirmed bacterial sepsis

Datasets

Whole blood mRNA expression profiling of host molecular networks in neonatal sepsis

Cite this