High-throughput phenotyping reveals expansive genetic and structural underpinnings of immune variation

Abeler-Dörner, Lucie; Laing, Adam; Lorenc, Anna; Ushakov, Dmitry S.; Clare, Simon; Speak, Anneliese O.; Duque-Correa, María A.; White, Jacqueline K.; Ramirez-Solis, Ramiro; Saran, Namita; Bull, Katherine; Morón, Belén; Iwasaki, Jua; Barton, P. J.; Caetano, Susana S.; Hng, Keng I.; Cambridge, Emma L.; Forman, Simon; Crockford, Tanya L.; Griffiths, Mark; Kane, Leanne; Harcourt, Katherine; Brandt, Cordelia; Notley, George; Babalola, Kola; Warren, Jonathan; Mason, Jeremy; Meeniga, Amrutha; Karp, Natasha A.; Melvin, David; Cawthorne, Eleanor; Weinrick, Brian; Rahim, Albina; Drissler, Sibyl; Meskas, Justin; Yue, Alice; Lux, Markus; Song-Zhao, George X.; Chan, Anna; Reviriego, Carmen Ballesteros; Abeler, Johannes; Wilson, Heather M.; Przemska-Kosicka, Agnieszka; Edmans, Matthew; Strevens, Natasha; Pasztorek, Markus; Meehan, Terrence F.; Powrie, Fiona; Brinkman, Ryan R.; Dougan, Gordon; Jacobs, William R.; Lloyd, Clare M.; Cornall, Richard J.; Maloy, Kevin J.; Grencis, Richard K.; Griffiths, Gillian M.; Adams, David J.; Hayday, Adrian

doi:10.1038/s41590-019-0549-0

Cited by 33 publications

(36 citation statements)

References 62 publications

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“…Considering the links previously suggested between immune cell development, immune homeostasis, and the microbiome 12 , we considered the developing intestinal microbiome as a potential driver of these changes in immune profile. Similarly, many immune parameters are sexually dimorphic, at least in mice 13 . Hence, we also considered the influence of sex on these developing immune profiles.…”

Section: Resultsmentioning

confidence: 99%

Perinatal inflammation influences but does not arrest rapid immune development in preterm babies

et al. 2020

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Infection and infection-related complications are important causes of death and morbidity following preterm birth. Despite this risk, there is limited understanding of the development of the immune system in those born prematurely, and of how this development is influenced by perinatal factors. Here we prospectively and longitudinally follow a cohort of babies born before 32 weeks of gestation. We demonstrate that preterm babies, including those born extremely prematurely (<28 weeks), are capable of rapidly acquiring some adult levels of immune functionality, in which immune maturation occurs independently of the developing heterogeneous microbiome. By contrast, we observe a reduced percentage of CXCL8producing T cells, but comparable levels of TNF-producing T cells, from babies exposed to in utero or postnatal infection, which precedes an unstable post-natal clinical course. These data show that rapid immune development is possible in preterm babies, but distinct identifiable differences in functionality may predict subsequent infection mediated outcomes.

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Section: Resultsmentioning

confidence: 99%

Perinatal inflammation influences but does not arrest rapid immune development in preterm babies

et al. 2020

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“…A smaller body size (and thus total blood volume) undoubtedly contributed to the increased pulmonary metastatic burden we observed, as well as the presence of extrapulmonary metastases (bone marrow, liver, kidney). However, it was recently shown that Duoxa2 mutant mice have alterations in key immune cell subsets (CD4+ T-cells, neutrophils, monocytes and NK cells) (Abeler-Dorner et al 2020), which could also account for their increased metastatic colonisation. Thus, generation of an inducible Duoxa2 mutant mouse, wherein Duoxa2 could be deleted in an adult mouse, will be required to disentangle any effects that loss of DUOXA2 may be having on metastatic colonisation aside from a smaller body size.…”

Section: Discussionmentioning

confidence: 99%

“…However, they do play an import role in mammalian cells as Dph1 null mice display multiple developmental defects that parallel Miller-Dieker syndrome (MDS) (Yu et al 2014), associated with deletions on chromosome 17p13.3, Dph3 null mice are embryonically lethal (Liu et al 2006) and Dnajc24 ( Dph4 ) null mice almost always die before birth with the few that do survive showing severe developmental defects reminiscent of Dph1 null mice (Webb et al 2008). Recently, Dph6 mutant mice were shown to have an immune phenotype with alterations in many innate and adaptive cell lineages (Abeler-Dorner et al 2020), and it is possible that these may be affecting metastatic colonisation. Thus, as very little is known about ABHD17A and DPH6 in the context of cancer, it is difficult to precisely speculate how they may be playing a role in tumour cell extrinsic regulation of metastatic colonisation.…”

Section: Discussionmentioning

confidence: 99%

A genome-wide screen in mice to identify cell-extrinsic regulators of pulmonary metastatic colonisation

Weyden

Swiatkowska

Iyer

et al. 2020

Preprint

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ABSTRACTMetastatic colonisation, whereby a disseminated tumour cell is able to survive and proliferate at a secondary site, involves both tumour cell-intrinsic and -extrinsic factors. To identify tumour cell-extrinsic (microenvironmental) factors that regulate the ability of metastatic tumour cells to effectively colonise a tissue, we performed a genome-wide screen utilising the experimental metastasis assay on mutant mice. Mutant and wildtype (control) mice were tail vein-dosed with murine metastatic melanoma B16-F10 cells and 10 days later the number of pulmonary metastatic colonies were counted. Of the 1,300 genes/genetic locations (1,344 alleles) assessed in the screen 34 genes were determined to significantly regulate pulmonary metastatic colonisation (15 increased and 19 decreased; P<0.005 and genotype effect <-60 or >+60). Whilst several of these genes have known roles in immune system regulation (Bach2, Cyba, Cybb, Cybc1, Id2, Igh-6, Irf1, Irf7, Ncf1, Ncf2, Ncf4 and Pik3cg) most are involved in a disparate range of biological processes, ranging from ubiquitination (Herc1) to diphthamide synthesis (Dph6) to Rho GTPase-activation (Arhgap30 and Fgd4), with no previous reports of a role in the regulation of metastasis. Thus, we have identified numerous novel regulators of pulmonary metastatic colonisation, which may represent potential therapeutic targets.

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“…However, they do play an import role in mammalian cells as Dph1 null mice display multiple developmental defects that parallel Miller-Dieker syndrome (MDS) (Yu et al 2014), associated with deletions on chromosome 17p13.3, Dph3 null mice are embryonically lethal (Liu et al 2006) and Dnajc24 (Dph4) null mice almost always die before birth with the few that do survive showing severe developmental defects reminiscent of Dph1 null mice (Webb et al 2008). Recently, Dph6 mutant mice were shown to have an immune phenotype with alterations in many innate and adaptive cell lineages (Abeler-Dorner et al 2020), and it is possible that these may be affecting metastatic colonisation. Thus, as very little is known about ABHD17A…”

Section: Protein Modificationmentioning

confidence: 99%

“…These genes regulate pulmonary metastatic colonisation primarily by impacting on the function of the haematopoietic/immune system (lymphocytes, granulocytes/monocytes and platelets). In addition, Bach2 was also a 'hit' in our screen, showing decreased metastatic colonisation, and Bach2 is a key regulator of CD4 + T-cell differentiation(Roychoudhuri et al 2013), with Bach2 mutant mice recently being shown to have increased CD8 + T-cell cytotoxic activity(Abeler-Dorner et al 2020). Indeed, phenotypic analysis of the 34 metastatic colonisation regulating genes detailed in this study show a strong enrichment for genes involved in immune/haematopoietic system development and function with phenotypes in those categories representing 88% of all the reported phenotypes associated with those genes.…”

mentioning

confidence: 95%

A Genome-Wide Screen in Mice To Identify Cell-Extrinsic Regulators of Pulmonary Metastatic Colonisation

Weyden

Swiaţkowska²,

Iyer³

et al. 2020

G3 Genes|Genomes|Genetics

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Metastatic colonization, whereby a disseminated tumor cell is able to survive and proliferate at a secondary site, involves both tumor cell-intrinsic and -extrinsic factors. To identify tumor cell-extrinsic (microenvironmental) factors that regulate the ability of metastatic tumor cells to effectively colonize a tissue, we performed a genome-wide screen utilizing the experimental metastasis assay on mutant mice. Mutant and wildtype (control) mice were tail vein-dosed with murine metastatic melanoma B16-F10 cells and 10 days later the number of pulmonary metastatic colonies were counted. Of the 1,300 genes/genetic locations (1,344 alleles) assessed in the screen 34 genes were determined to significantly regulate pulmonary metastatic colonization (15 increased and 19 decreased; P < 0.005 and genotype effect <-55 or >+55). While several of these genes have known roles in immune system regulation (Bach2, Cyba, Cybb, Cybc1, Id2, Igh-6, Irf1, Irf7, Ncf1, Ncf2, Ncf4 and Pik3cg) most are involved in a disparate range of biological processes, ranging from ubiquitination (Herc1) to diphthamide synthesis (Dph6) to Rho GTPase-activation (Arhgap30 and Fgd4), with no previous reports of a role in the regulation of metastasis. Thus, we have identified numerous novel regulators of pulmonary metastatic colonization, which may represent potential therapeutic targets.

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High-throughput phenotyping reveals expansive genetic and structural underpinnings of immune variation

Cited by 33 publications

References 62 publications

Perinatal inflammation influences but does not arrest rapid immune development in preterm babies

Perinatal inflammation influences but does not arrest rapid immune development in preterm babies

A genome-wide screen in mice to identify cell-extrinsic regulators of pulmonary metastatic colonisation

A Genome-Wide Screen in Mice To Identify Cell-Extrinsic Regulators of Pulmonary Metastatic Colonisation

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