Identifying immune signatures of sepsis to increase diagnostic accuracy in very preterm babies

A. Das; G. Ariyakumar; N. Gupta; S. Kamdar; A. Barugahare; D. Deveson-Lucas; S. Gee; K. Costeloe; M. S. Davey; P. Fleming; D. L. Gibbons

doi:10.1038/s41467-023-44387-5

Identifying immune signatures of sepsis to increase diagnostic accuracy in very preterm babies

A. Das
, G. Ariyakumar
, N. Gupta
, S. Kamdar
, A. Barugahare
, D. Deveson-Lucas
, S. Gee
, K. Costeloe
, M. S. Davey
, P. Fleming
, D. L. Gibbons

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

27 Citations (Scopus)

Abstract

Bacterial infections are a major cause of mortality in preterm babies, yet our understanding of early-life disease-associated immune dysregulation remains limited. Here, we combine multi-parameter flow cytometry, single-cell RNA sequencing and plasma analysis to longitudinally profile blood from very preterm babies (<32 weeks gestation) across episodes of invasive bacterial infection (sepsis). We identify a dynamically changing blood immune signature of sepsis, including lymphopenia, reduced dendritic cell frequencies and myeloid cell HLA-DR expression, which characterizes sepsis even when the common clinical marker of inflammation, C-reactive protein, is not elevated. Furthermore, single-cell RNA sequencing identifies upregulation of amphiregulin in leukocyte populations during sepsis, which we validate as a plasma analyte that correlates with clinical signs of disease, even when C-reactive protein is normal. This study provides insights into immune pathways associated with early-life sepsis and identifies immune analytes as potential diagnostic adjuncts to standard tests to guide targeted antibiotic prescribing.

Original language	English
Article number	388
Number of pages	15
Journal	Nature Communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-023-44387-5
Publication status	Published - 9 Jan 2024

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10.1038/s41467-023-44387-5Licence: CC BY

Cite this

@article{071e02aa39d44addb48222e47ef8cf82,

title = "Identifying immune signatures of sepsis to increase diagnostic accuracy in very preterm babies",

abstract = "Bacterial infections are a major cause of mortality in preterm babies, yet our understanding of early-life disease-associated immune dysregulation remains limited. Here, we combine multi-parameter flow cytometry, single-cell RNA sequencing and plasma analysis to longitudinally profile blood from very preterm babies (<32 weeks gestation) across episodes of invasive bacterial infection (sepsis). We identify a dynamically changing blood immune signature of sepsis, including lymphopenia, reduced dendritic cell frequencies and myeloid cell HLA-DR expression, which characterizes sepsis even when the common clinical marker of inflammation, C-reactive protein, is not elevated. Furthermore, single-cell RNA sequencing identifies upregulation of amphiregulin in leukocyte populations during sepsis, which we validate as a plasma analyte that correlates with clinical signs of disease, even when C-reactive protein is normal. This study provides insights into immune pathways associated with early-life sepsis and identifies immune analytes as potential diagnostic adjuncts to standard tests to guide targeted antibiotic prescribing.",

author = "A. Das and G. Ariyakumar and N. Gupta and S. Kamdar and A. Barugahare and D. Deveson-Lucas and S. Gee and K. Costeloe and Davey, \{M. S.\} and P. Fleming and Gibbons, \{D. L.\}",

note = "Funding Information: Our thanks are extended to the staff of the neonatal units at Homerton Healthcare and Guy{\textquoteright}s and St Thomas{\textquoteright} NHS Foundation Trusts, for their hard work in caring for these babies and assistance in sample and data collection, and to the families and babies who participated, for their willingness to contribute to research. We acknowledge the support of Monash Bioinformatics Platform for this work and Monash FlowCore for their assistance with cell sorting. We thank Y. Wu (KCL) for critical review of the manuscript. A.D. was supported by an Academy of Medical Sciences Starter Grant for Clinical Lecturers (SGL019\textbackslash{}1004) and a National Institute for Health Research (NIHR) Academic Clinical Lectureship. P.F. and K.C. were both supported by a strategic research grant from Barts Charity (Grant 764/2306); D.G. and S.K. by Cancer Research UK (Grant A20730) and D.G., P.F. and G.A by Action Medical Research (Grant GN2790). S.G. was also supported by an MRC-KCL Doctoral Training Partnership in Biomedical Sciences grant (MR/N013700/1). M.S.D. is supported by an Australian Research Council (ARC) Discovery Early Career Fellowship (DE200100292) and a Rebecca L. Cooper Medical Research Foundation Project Grant (PG2020668) and an ARC Discovery Project (DP210103327). Funding Information: Funding was granted by Barts Charity (Ref: 764/2306) for the undertaking of a study named {\textquoteleft}Investigating Microbial Colonisation and Immune Conditioning in Preterm Babies{\textquoteright} and funding from Action Medical Research (Ref:GN2790) for a study named {\textquoteleft}Identifying immune correlates of infection in preterm infants{\textquoteright}. Publisher Copyright: {\textcopyright} 2024, The Author(s).",

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doi = "10.1038/s41467-023-44387-5",

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T1 - Identifying immune signatures of sepsis to increase diagnostic accuracy in very preterm babies

AU - Das, A.

AU - Ariyakumar, G.

AU - Gupta, N.

AU - Kamdar, S.

AU - Barugahare, A.

AU - Deveson-Lucas, D.

AU - Gee, S.

AU - Costeloe, K.

AU - Davey, M. S.

AU - Fleming, P.

AU - Gibbons, D. L.

N1 - Funding Information: Our thanks are extended to the staff of the neonatal units at Homerton Healthcare and Guy’s and St Thomas’ NHS Foundation Trusts, for their hard work in caring for these babies and assistance in sample and data collection, and to the families and babies who participated, for their willingness to contribute to research. We acknowledge the support of Monash Bioinformatics Platform for this work and Monash FlowCore for their assistance with cell sorting. We thank Y. Wu (KCL) for critical review of the manuscript. A.D. was supported by an Academy of Medical Sciences Starter Grant for Clinical Lecturers (SGL019\1004) and a National Institute for Health Research (NIHR) Academic Clinical Lectureship. P.F. and K.C. were both supported by a strategic research grant from Barts Charity (Grant 764/2306); D.G. and S.K. by Cancer Research UK (Grant A20730) and D.G., P.F. and G.A by Action Medical Research (Grant GN2790). S.G. was also supported by an MRC-KCL Doctoral Training Partnership in Biomedical Sciences grant (MR/N013700/1). M.S.D. is supported by an Australian Research Council (ARC) Discovery Early Career Fellowship (DE200100292) and a Rebecca L. Cooper Medical Research Foundation Project Grant (PG2020668) and an ARC Discovery Project (DP210103327). Funding Information: Funding was granted by Barts Charity (Ref: 764/2306) for the undertaking of a study named ‘Investigating Microbial Colonisation and Immune Conditioning in Preterm Babies’ and funding from Action Medical Research (Ref:GN2790) for a study named ‘Identifying immune correlates of infection in preterm infants’. Publisher Copyright: © 2024, The Author(s).

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N2 - Bacterial infections are a major cause of mortality in preterm babies, yet our understanding of early-life disease-associated immune dysregulation remains limited. Here, we combine multi-parameter flow cytometry, single-cell RNA sequencing and plasma analysis to longitudinally profile blood from very preterm babies (<32 weeks gestation) across episodes of invasive bacterial infection (sepsis). We identify a dynamically changing blood immune signature of sepsis, including lymphopenia, reduced dendritic cell frequencies and myeloid cell HLA-DR expression, which characterizes sepsis even when the common clinical marker of inflammation, C-reactive protein, is not elevated. Furthermore, single-cell RNA sequencing identifies upregulation of amphiregulin in leukocyte populations during sepsis, which we validate as a plasma analyte that correlates with clinical signs of disease, even when C-reactive protein is normal. This study provides insights into immune pathways associated with early-life sepsis and identifies immune analytes as potential diagnostic adjuncts to standard tests to guide targeted antibiotic prescribing.

AB - Bacterial infections are a major cause of mortality in preterm babies, yet our understanding of early-life disease-associated immune dysregulation remains limited. Here, we combine multi-parameter flow cytometry, single-cell RNA sequencing and plasma analysis to longitudinally profile blood from very preterm babies (<32 weeks gestation) across episodes of invasive bacterial infection (sepsis). We identify a dynamically changing blood immune signature of sepsis, including lymphopenia, reduced dendritic cell frequencies and myeloid cell HLA-DR expression, which characterizes sepsis even when the common clinical marker of inflammation, C-reactive protein, is not elevated. Furthermore, single-cell RNA sequencing identifies upregulation of amphiregulin in leukocyte populations during sepsis, which we validate as a plasma analyte that correlates with clinical signs of disease, even when C-reactive protein is normal. This study provides insights into immune pathways associated with early-life sepsis and identifies immune analytes as potential diagnostic adjuncts to standard tests to guide targeted antibiotic prescribing.

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SN - 2041-1723

VL - 15

JO - Nature Communications

JF - Nature Communications

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ER -

Identifying immune signatures of sepsis to increase diagnostic accuracy in very preterm babies

Abstract

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Other files and links

Exploring the autoimmune properties of the γδ T cell receptor in myositis

Defining the basis of unconventional immune cell development

FlowCore (FLOW)

Monash Genomics & Bioinformatics Platform (MGBP)

Cite this

Identifying immune signatures of sepsis to increase diagnostic accuracy in very preterm babies

Abstract

Access to Document

Other files and links

Projects

Exploring the autoimmune properties of the γδ T cell receptor in myositis

Defining the basis of unconventional immune cell development

Equipment

FlowCore (FLOW)

Monash Genomics & Bioinformatics Platform (MGBP)

Cite this