Transfer learning in a biomaterial fibrosis model identifies in vivo senescence heterogeneity and contributions to vascularization and matrix production across species and diverse pathologies

Christopher Cherry; James I. Andorko; Kavita Krishnan; Joscelyn C. Mejías; Helen Hieu Nguyen; Katlin B. Stivers; Elise F. Gray-Gaillard; Anna Ruta; Jin Han; Naomi Hamada; Masakazu Hamada; Ines Sturmlechner; Shawn Trewartha; John H. Michel; Locke Davenport Huyer; Matthew T. Wolf; Ada J. Tam; Alexis N. Peña; Shilpa Keerthivasan; Claude Jordan Le Saux; Elana J. Fertig; Darren J. Baker; Franck Housseau; Jan M. van Deursen; Drew M. Pardoll; Jennifer H. Elisseeff

doi:10.1007/s11357-023-00785-7

Transfer learning in a biomaterial fibrosis model identifies in vivo senescence heterogeneity and contributions to vascularization and matrix production across species and diverse pathologies

Christopher Cherry, James I. Andorko, Kavita Krishnan, Joscelyn C. Mejías, Helen Hieu Nguyen, Katlin B. Stivers, Elise F. Gray-Gaillard, Anna Ruta, Jin Han, Naomi Hamada, Masakazu Hamada, Ines Sturmlechner, Shawn Trewartha, John H. Michel, Locke Davenport Huyer, Matthew T. Wolf, Ada J. Tam, Alexis N. Peña, Shilpa Keerthivasan, Claude Jordan Le SauxElana J. Fertig, Darren J. Baker, Franck Housseau, Jan M. van Deursen, Drew M. Pardoll, Jennifer H. Elisseeff

Pediatric and Adolescent Medicine

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

Abstract

Cellular senescence is a state of permanent growth arrest that plays an important role in wound healing, tissue fibrosis, and tumor suppression. Despite senescent cells’ (SnCs) pathological role and therapeutic interest, their phenotype in vivo remains poorly defined. Here, we developed an in vivo–derived senescence signature (SenSig) using a foreign body response–driven fibrosis model in a p16-CreER^T2;Ai14 reporter mouse. We identified pericytes and “cartilage-like” fibroblasts as senescent and defined cell type–specific senescence-associated secretory phenotypes (SASPs). Transfer learning and senescence scoring identified these two SnC populations along with endothelial and epithelial SnCs in new and publicly available murine and human data single-cell RNA sequencing (scRNAseq) datasets from diverse pathologies. Signaling analysis uncovered crosstalk between SnCs and myeloid cells via an IL34–CSF1R–TGFβR signaling axis, contributing to tissue balance of vascularization and matrix production. Overall, our study provides a senescence signature and a computational approach that may be broadly applied to identify SnC transcriptional profiles and SASP factors in wound healing, aging, and other pathologies.

Original language	English (US)
Pages (from-to)	2559-2587
Number of pages	29
Journal	GeroScience
Volume	45
Issue number	4
DOIs	https://doi.org/10.1007/s11357-023-00785-7
State	Published - Aug 2023

Keywords

Fibrosis
RNA sequencing
Senescence

ASJC Scopus subject areas

Aging
veterinary (miscalleneous)
Complementary and alternative medicine
Geriatrics and Gerontology
Cardiology and Cardiovascular Medicine

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10.1007/s11357-023-00785-7

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Cherry, C., Andorko, J. I., Krishnan, K., Mejías, J. C., Nguyen, H. H., Stivers, K. B., Gray-Gaillard, E. F., Ruta, A., Han, J., Hamada, N., Hamada, M., Sturmlechner, I., Trewartha, S., Michel, J. H., Davenport Huyer, L., Wolf, M. T., Tam, A. J., Peña, A. N., Keerthivasan, S., ... Elisseeff, J. H. (2023). Transfer learning in a biomaterial fibrosis model identifies in vivo senescence heterogeneity and contributions to vascularization and matrix production across species and diverse pathologies. GeroScience, 45(4), 2559-2587. https://doi.org/10.1007/s11357-023-00785-7

Transfer learning in a biomaterial fibrosis model identifies in vivo senescence heterogeneity and contributions to vascularization and matrix production across species and diverse pathologies. / Cherry, Christopher; Andorko, James I.; Krishnan, Kavita et al.
In: GeroScience, Vol. 45, No. 4, 08.2023, p. 2559-2587.

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

Cherry, C, Andorko, JI, Krishnan, K, Mejías, JC, Nguyen, HH, Stivers, KB, Gray-Gaillard, EF, Ruta, A, Han, J, Hamada, N, Hamada, M, Sturmlechner, I, Trewartha, S, Michel, JH, Davenport Huyer, L, Wolf, MT, Tam, AJ, Peña, AN, Keerthivasan, S, Le Saux, CJ, Fertig, EJ, Baker, DJ, Housseau, F, van Deursen, JM, Pardoll, DM & Elisseeff, JH 2023, 'Transfer learning in a biomaterial fibrosis model identifies in vivo senescence heterogeneity and contributions to vascularization and matrix production across species and diverse pathologies', GeroScience, vol. 45, no. 4, pp. 2559-2587. https://doi.org/10.1007/s11357-023-00785-7

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title = "Transfer learning in a biomaterial fibrosis model identifies in vivo senescence heterogeneity and contributions to vascularization and matrix production across species and diverse pathologies",

abstract = "Cellular senescence is a state of permanent growth arrest that plays an important role in wound healing, tissue fibrosis, and tumor suppression. Despite senescent cells{\textquoteright} (SnCs) pathological role and therapeutic interest, their phenotype in vivo remains poorly defined. Here, we developed an in vivo–derived senescence signature (SenSig) using a foreign body response–driven fibrosis model in a p16-CreERT2;Ai14 reporter mouse. We identified pericytes and “cartilage-like” fibroblasts as senescent and defined cell type–specific senescence-associated secretory phenotypes (SASPs). Transfer learning and senescence scoring identified these two SnC populations along with endothelial and epithelial SnCs in new and publicly available murine and human data single-cell RNA sequencing (scRNAseq) datasets from diverse pathologies. Signaling analysis uncovered crosstalk between SnCs and myeloid cells via an IL34–CSF1R–TGFβR signaling axis, contributing to tissue balance of vascularization and matrix production. Overall, our study provides a senescence signature and a computational approach that may be broadly applied to identify SnC transcriptional profiles and SASP factors in wound healing, aging, and other pathologies.",

keywords = "Fibrosis, RNA sequencing, Senescence",

author = "Christopher Cherry and Andorko, {James I.} and Kavita Krishnan and Mej{\'i}as, {Joscelyn C.} and Nguyen, {Helen Hieu} and Stivers, {Katlin B.} and Gray-Gaillard, {Elise F.} and Anna Ruta and Jin Han and Naomi Hamada and Masakazu Hamada and Ines Sturmlechner and Shawn Trewartha and Michel, {John H.} and {Davenport Huyer}, Locke and Wolf, {Matthew T.} and Tam, {Ada J.} and Pe{\~n}a, {Alexis N.} and Shilpa Keerthivasan and {Le Saux}, {Claude Jordan} and Fertig, {Elana J.} and Baker, {Darren J.} and Franck Housseau and {van Deursen}, {Jan M.} and Pardoll, {Drew M.} and Elisseeff, {Jennifer H.}",

note = "Publisher Copyright: {\textcopyright} 2023, The Author(s), under exclusive licence to American Aging Association.",

year = "2023",

month = aug,

doi = "10.1007/s11357-023-00785-7",

language = "English (US)",

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T1 - Transfer learning in a biomaterial fibrosis model identifies in vivo senescence heterogeneity and contributions to vascularization and matrix production across species and diverse pathologies

AU - Cherry, Christopher

AU - Andorko, James I.

AU - Krishnan, Kavita

AU - Mejías, Joscelyn C.

AU - Nguyen, Helen Hieu

AU - Stivers, Katlin B.

AU - Gray-Gaillard, Elise F.

AU - Ruta, Anna

AU - Han, Jin

AU - Hamada, Naomi

AU - Hamada, Masakazu

AU - Sturmlechner, Ines

AU - Trewartha, Shawn

AU - Michel, John H.

AU - Davenport Huyer, Locke

AU - Wolf, Matthew T.

AU - Tam, Ada J.

AU - Peña, Alexis N.

AU - Keerthivasan, Shilpa

AU - Le Saux, Claude Jordan

AU - Fertig, Elana J.

AU - Baker, Darren J.

AU - Housseau, Franck

AU - van Deursen, Jan M.

AU - Pardoll, Drew M.

AU - Elisseeff, Jennifer H.

PY - 2023/8

Y1 - 2023/8

N2 - Cellular senescence is a state of permanent growth arrest that plays an important role in wound healing, tissue fibrosis, and tumor suppression. Despite senescent cells’ (SnCs) pathological role and therapeutic interest, their phenotype in vivo remains poorly defined. Here, we developed an in vivo–derived senescence signature (SenSig) using a foreign body response–driven fibrosis model in a p16-CreERT2;Ai14 reporter mouse. We identified pericytes and “cartilage-like” fibroblasts as senescent and defined cell type–specific senescence-associated secretory phenotypes (SASPs). Transfer learning and senescence scoring identified these two SnC populations along with endothelial and epithelial SnCs in new and publicly available murine and human data single-cell RNA sequencing (scRNAseq) datasets from diverse pathologies. Signaling analysis uncovered crosstalk between SnCs and myeloid cells via an IL34–CSF1R–TGFβR signaling axis, contributing to tissue balance of vascularization and matrix production. Overall, our study provides a senescence signature and a computational approach that may be broadly applied to identify SnC transcriptional profiles and SASP factors in wound healing, aging, and other pathologies.

AB - Cellular senescence is a state of permanent growth arrest that plays an important role in wound healing, tissue fibrosis, and tumor suppression. Despite senescent cells’ (SnCs) pathological role and therapeutic interest, their phenotype in vivo remains poorly defined. Here, we developed an in vivo–derived senescence signature (SenSig) using a foreign body response–driven fibrosis model in a p16-CreERT2;Ai14 reporter mouse. We identified pericytes and “cartilage-like” fibroblasts as senescent and defined cell type–specific senescence-associated secretory phenotypes (SASPs). Transfer learning and senescence scoring identified these two SnC populations along with endothelial and epithelial SnCs in new and publicly available murine and human data single-cell RNA sequencing (scRNAseq) datasets from diverse pathologies. Signaling analysis uncovered crosstalk between SnCs and myeloid cells via an IL34–CSF1R–TGFβR signaling axis, contributing to tissue balance of vascularization and matrix production. Overall, our study provides a senescence signature and a computational approach that may be broadly applied to identify SnC transcriptional profiles and SASP factors in wound healing, aging, and other pathologies.

KW - Fibrosis

KW - RNA sequencing

KW - Senescence

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JF - GeroScience

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ER -

Transfer learning in a biomaterial fibrosis model identifies in vivo senescence heterogeneity and contributions to vascularization and matrix production across species and diverse pathologies

Abstract

Keywords

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