Differential roles for the oxygen sensing enzymes PHD1 and PHD3 in the regulation of neutrophil metabolism and function

Emily Watts; Joseph Willison; Simone Arienti; Pranvera Sadiku; Patricia Coelho; Manuel Sanchez-Garcia; Ailiang Zhang; Fiona Murphy; Rebecca Dickinson; Ananda Mirchandani; Tyler Morrison; Amy Lewis; Wesley Vermaelen; Bart Ghesquiere; Peter Carmeliet; Massimilliano Mazzone; Patrick Maxwell; Christopher Pugh; David Dockrell; Moira Whyte; Sarah Walmsley

doi:10.12688/wellcomeopenres.19915.2

Differential roles for the oxygen sensing enzymes PHD1 and PHD3 in the regulation of neutrophil metabolism and function

Emily Watts^*, Joseph Willison, Simone Arienti, Pranvera Sadiku, Patricia Coelho, Manuel Sanchez-Garcia, Ailiang Zhang, Fiona Murphy, Rebecca Dickinson, Ananda Mirchandani, Tyler Morrison, Amy Lewis, Wesley Vermaelen, Bart Ghesquiere, Peter Carmeliet, Massimilliano Mazzone, Patrick Maxwell, Christopher Pugh, David Dockrell, Moira WhyteSarah Walmsley

^*Corresponding author for this work

Strathclyde Institute Of Pharmacy And Biomedical Sciences

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

2 Citations (Scopus)

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Abstract

Background
Neutrophils are essential in the early innate immune response to pathogens. Harnessing their antimicrobial powers, without driving excessive and damaging inflammatory responses, represents an attractive therapeutic possibility. The neutrophil population is increasingly recognised to be more diverse and malleable than was previously appreciated. Hypoxic signalling pathways are known to regulate important neutrophil behaviours and, as such, are potential therapeutic targets for regulating neutrophil antimicrobial and inflammatory responses.

Methods
We used a combination of in vivo and ex vivo models, utilising neutrophil and myeloid specific PHD1 or PHD3 deficient mouse lines to investigate the roles of oxygen sensing prolyl hydroxylase enzymes in the regulation of neutrophilic inflammation and immunity. Mass spectrometry and Seahorse metabolic flux assays were used to analyse the role of metabolic shifts in driving the downstream phenotypes.

Results
We found that PHD1 deficiency drives alterations in neutrophil metabolism and recruitment, in an oxygen dependent fashion. Despite this, PHD1 deficiency did not significantly alter ex vivo neutrophil phenotypes or in vivo outcomes in mouse models of inflammation. Conversely, PHD3 deficiency was found to enhance neutrophil antibacterial properties without excessive inflammatory responses. This was not linked to changes in the abundance of core metabolites but was associated with increased oxygen consumption and increased mitochondrial reactive oxygen species (mROS) production.

Conclusions
PHD3 deficiency drives a favourable neutrophil phenotype in infection and, as such, is an important potential therapeutic target.

Original language	English
Article number	569
Number of pages	29
Journal	Wellcome Open Research
Volume	8
Early online date	11 Dec 2023
DOIs	https://doi.org/10.12688/wellcomeopenres.19915.2
Publication status	Published - 2 Sept 2024

Funding

This work was supported by the Wellcome Trust through a Clinical Training Fellowship (108717) and Clinical Research Career Development Fellowship (224637) to ERW. ERW was also supported through an Academy of Medical Sciences Starter Grant for Clinical Lecturers (SGL024\\1056). JAW was supported by an Engineering and Physical Sciences Research Council and MRC Centre for Doctoral Training in Optical Medical Imaging studentship. SA was supported by a Medical Research Foundation National program in Antimicrobial Resistance studentship. SRW. and SA are also supported by the MRC SHIELD consortium (MRNO2995X/1). RSD was supported by a Medical Research Council (MRC) Clinical Training Fellowship (MR/K023845/1). SRW is supported by a Wellcome Trust Senior Clinical Fellowship Award (209220) and a Wellcome Trust Discovery Award (225778).

Keywords

neutrophil
hypoxia
prolyl hydroxylase
PHD1, PHD3
inflammation

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Cite this

Watts, E., Willison, J., Arienti, S., Sadiku, P., Coelho, P., Sanchez-Garcia, M., Zhang, A., Murphy, F., Dickinson, R., Mirchandani, A., Morrison, T., Lewis, A., Vermaelen, W., Ghesquiere, B., Carmeliet, P., Mazzone, M., Maxwell, P., Pugh, C., Dockrell, D., ... Walmsley, S. (2024). Differential roles for the oxygen sensing enzymes PHD1 and PHD3 in the regulation of neutrophil metabolism and function. Wellcome Open Research, 8, Article 569. https://doi.org/10.12688/wellcomeopenres.19915.2

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title = "Differential roles for the oxygen sensing enzymes PHD1 and PHD3 in the regulation of neutrophil metabolism and function",

abstract = "Background Neutrophils are essential in the early innate immune response to pathogens. Harnessing their antimicrobial powers, without driving excessive and damaging inflammatory responses, represents an attractive therapeutic possibility. The neutrophil population is increasingly recognised to be more diverse and malleable than was previously appreciated. Hypoxic signalling pathways are known to regulate important neutrophil behaviours and, as such, are potential therapeutic targets for regulating neutrophil antimicrobial and inflammatory responses. Methods We used a combination of in vivo and ex vivo models, utilising neutrophil and myeloid specific PHD1 or PHD3 deficient mouse lines to investigate the roles of oxygen sensing prolyl hydroxylase enzymes in the regulation of neutrophilic inflammation and immunity. Mass spectrometry and Seahorse metabolic flux assays were used to analyse the role of metabolic shifts in driving the downstream phenotypes. Results We found that PHD1 deficiency drives alterations in neutrophil metabolism and recruitment, in an oxygen dependent fashion. Despite this, PHD1 deficiency did not significantly alter ex vivo neutrophil phenotypes or in vivo outcomes in mouse models of inflammation. Conversely, PHD3 deficiency was found to enhance neutrophil antibacterial properties without excessive inflammatory responses. This was not linked to changes in the abundance of core metabolites but was associated with increased oxygen consumption and increased mitochondrial reactive oxygen species (mROS) production. Conclusions PHD3 deficiency drives a favourable neutrophil phenotype in infection and, as such, is an important potential therapeutic target.",

keywords = "neutrophil, hypoxia, prolyl hydroxylase, PHD1, PHD3, inflammation",

author = "Emily Watts and Joseph Willison and Simone Arienti and Pranvera Sadiku and Patricia Coelho and Manuel Sanchez-Garcia and Ailiang Zhang and Fiona Murphy and Rebecca Dickinson and Ananda Mirchandani and Tyler Morrison and Amy Lewis and Wesley Vermaelen and Bart Ghesquiere and Peter Carmeliet and Massimilliano Mazzone and Patrick Maxwell and Christopher Pugh and David Dockrell and Moira Whyte and Sarah Walmsley",

year = "2024",

month = sep,

day = "2",

doi = "10.12688/wellcomeopenres.19915.2",

language = "English",

volume = "8",

journal = "Wellcome Open Research",

issn = "2398-502X",

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Watts, E, Willison, J, Arienti, S, Sadiku, P, Coelho, P, Sanchez-Garcia, M, Zhang, A, Murphy, F, Dickinson, R, Mirchandani, A, Morrison, T, Lewis, A, Vermaelen, W, Ghesquiere, B, Carmeliet, P, Mazzone, M, Maxwell, P, Pugh, C, Dockrell, D, Whyte, M & Walmsley, S 2024, 'Differential roles for the oxygen sensing enzymes PHD1 and PHD3 in the regulation of neutrophil metabolism and function', Wellcome Open Research, vol. 8, 569. https://doi.org/10.12688/wellcomeopenres.19915.2

TY - JOUR

T1 - Differential roles for the oxygen sensing enzymes PHD1 and PHD3 in the regulation of neutrophil metabolism and function

AU - Watts, Emily

AU - Willison, Joseph

AU - Arienti, Simone

AU - Sadiku, Pranvera

AU - Coelho, Patricia

AU - Sanchez-Garcia, Manuel

AU - Zhang, Ailiang

AU - Murphy, Fiona

AU - Dickinson, Rebecca

AU - Mirchandani, Ananda

AU - Morrison, Tyler

AU - Lewis, Amy

AU - Vermaelen, Wesley

AU - Ghesquiere, Bart

AU - Carmeliet, Peter

AU - Mazzone, Massimilliano

AU - Maxwell, Patrick

AU - Pugh, Christopher

AU - Dockrell, David

AU - Whyte, Moira

AU - Walmsley, Sarah

PY - 2024/9/2

Y1 - 2024/9/2

N2 - Background Neutrophils are essential in the early innate immune response to pathogens. Harnessing their antimicrobial powers, without driving excessive and damaging inflammatory responses, represents an attractive therapeutic possibility. The neutrophil population is increasingly recognised to be more diverse and malleable than was previously appreciated. Hypoxic signalling pathways are known to regulate important neutrophil behaviours and, as such, are potential therapeutic targets for regulating neutrophil antimicrobial and inflammatory responses. Methods We used a combination of in vivo and ex vivo models, utilising neutrophil and myeloid specific PHD1 or PHD3 deficient mouse lines to investigate the roles of oxygen sensing prolyl hydroxylase enzymes in the regulation of neutrophilic inflammation and immunity. Mass spectrometry and Seahorse metabolic flux assays were used to analyse the role of metabolic shifts in driving the downstream phenotypes. Results We found that PHD1 deficiency drives alterations in neutrophil metabolism and recruitment, in an oxygen dependent fashion. Despite this, PHD1 deficiency did not significantly alter ex vivo neutrophil phenotypes or in vivo outcomes in mouse models of inflammation. Conversely, PHD3 deficiency was found to enhance neutrophil antibacterial properties without excessive inflammatory responses. This was not linked to changes in the abundance of core metabolites but was associated with increased oxygen consumption and increased mitochondrial reactive oxygen species (mROS) production. Conclusions PHD3 deficiency drives a favourable neutrophil phenotype in infection and, as such, is an important potential therapeutic target.

AB - Background Neutrophils are essential in the early innate immune response to pathogens. Harnessing their antimicrobial powers, without driving excessive and damaging inflammatory responses, represents an attractive therapeutic possibility. The neutrophil population is increasingly recognised to be more diverse and malleable than was previously appreciated. Hypoxic signalling pathways are known to regulate important neutrophil behaviours and, as such, are potential therapeutic targets for regulating neutrophil antimicrobial and inflammatory responses. Methods We used a combination of in vivo and ex vivo models, utilising neutrophil and myeloid specific PHD1 or PHD3 deficient mouse lines to investigate the roles of oxygen sensing prolyl hydroxylase enzymes in the regulation of neutrophilic inflammation and immunity. Mass spectrometry and Seahorse metabolic flux assays were used to analyse the role of metabolic shifts in driving the downstream phenotypes. Results We found that PHD1 deficiency drives alterations in neutrophil metabolism and recruitment, in an oxygen dependent fashion. Despite this, PHD1 deficiency did not significantly alter ex vivo neutrophil phenotypes or in vivo outcomes in mouse models of inflammation. Conversely, PHD3 deficiency was found to enhance neutrophil antibacterial properties without excessive inflammatory responses. This was not linked to changes in the abundance of core metabolites but was associated with increased oxygen consumption and increased mitochondrial reactive oxygen species (mROS) production. Conclusions PHD3 deficiency drives a favourable neutrophil phenotype in infection and, as such, is an important potential therapeutic target.

KW - neutrophil

KW - hypoxia

KW - prolyl hydroxylase

KW - PHD1, PHD3

KW - inflammation

UR - https://doi.org/10.6084/m9.figshare.24106686.v3

UR - https://doi.org/10.12688/wellcomeopenres.19915.1

UR - https://www.scopus.com/pages/publications/85203446240

U2 - 10.12688/wellcomeopenres.19915.2

DO - 10.12688/wellcomeopenres.19915.2

M3 - Article

SN - 2398-502X

VL - 8

JO - Wellcome Open Research

JF - Wellcome Open Research

M1 - 569

ER -

Differential roles for the oxygen sensing enzymes PHD1 and PHD3 in the regulation of neutrophil metabolism and function

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Keywords

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