Integrative multiomics analysis of neointima proliferation in human saphenous vein: implications for bypass graft disease

David Kim; Brandee Goo; Hong Shi; Philip Coffey; Praneet Veerapaneni; Ronnie Chouhaita; Nicole Cyriac; Ghaith Aboud; Stephen Cave; Jacob Greenway; Rohan Mundkur; Samah Ahmadieh; Ragheb Harb; Mourad Ogbi; David J Fulton; Yuqing Huo; Wei Zhang; Xiaochun Long; Avirup Guha; Ha Won Kim; Yang Shi; Robert D Rice; Dominic R Gallo; Vijay Patel; Richard Lee; Neal L Weintraub

doi:10.1101/2023.11.14.567053

Integrative multiomics analysis of neointima proliferation in human saphenous vein: implications for bypass graft disease

David Kim, Brandee Goo, Hong Shi, Philip Coffey, Praneet Veerapaneni, Ronnie Chouhaita, Nicole Cyriac, Ghaith Aboud, Stephen Cave, Jacob Greenway, Rohan Mundkur, Samah Ahmadieh, Ragheb Harb, Mourad Ogbi, David J Fulton, Yuqing Huo, Wei Zhang, Xiaochun Long, Avirup Guha, Ha Won KimYang Shi, Robert D Rice, Dominic R Gallo, Vijay Patel, Richard Lee, Neal L Weintraub

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

Abstract

INTRODUCTION: Human saphenous veins (SV) are widely used as grafts in coronary artery bypass (CABG) surgery but often fail due to neointima proliferation (NP). NP involves complex interplay between vascular smooth muscle cells (VSMC) and fibroblasts. Little is known, however, regarding the transcriptomic and proteomic dynamics of NP. Here, we performed multi-omics analysis in an ex vivo tissue culture model of NP in human SV procured for CABG surgery.

METHODS AND RESULTS: Histological examination demonstrated significant elastin degradation and NP (indicated by increased neointima area and neointima/media ratio) in SV subjected to tissue culture. Analysis of data from 73 patients suggest that the process of SV adaptation and NP may differ according to sex and body mass index. RNA sequencing confirmed upregulation of pro-inflammatory and proliferation-related genes during NP and identified novel processes, including increased cellular stress and DNA damage responses, which may reflect tissue trauma associated with SV harvesting. Proteomic analysis identified upregulated extracellular matrix-related and coagulation/thrombosis proteins and downregulated metabolic proteins. Spatial transcriptomics detected transdifferentiating VSMC in the intima on the day of harvesting and highlighted dynamic alterations in fibroblast and VSMC phenotype and behavior during NP. Specifically, we identified new cell subpopulations contributing to NP, including SPP1 + , LGALS3 + VSMC and MMP2 + , MMP14 + fibroblasts.

CONCLUSION: Dynamic alterations of gene and protein expression occur during NP in human SV. Identification of the human-specific molecular and cellular mechanisms may provide novel insight into SV bypass graft disease.

Original language	English (US)
Journal	BioRxiv
DOIs	https://doi.org/10.1101/2023.11.14.567053
State	Published - Nov 17 2023

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1101/2023.11.14.567053

Cite this

Kim, D., Goo, B., Shi, H., Coffey, P., Veerapaneni, P., Chouhaita, R., Cyriac, N., Aboud, G., Cave, S., Greenway, J., Mundkur, R., Ahmadieh, S., Harb, R., Ogbi, M., Fulton, D. J., Huo, Y., Zhang, W., Long, X., Guha, A., ... Weintraub, N. L. (2023). Integrative multiomics analysis of neointima proliferation in human saphenous vein: implications for bypass graft disease. BioRxiv. https://doi.org/10.1101/2023.11.14.567053

Kim, D, Goo, B, Shi, H, Coffey, P, Veerapaneni, P, Chouhaita, R, Cyriac, N, Aboud, G, Cave, S, Greenway, J, Mundkur, R, Ahmadieh, S, Harb, R, Ogbi, M, Fulton, DJ , Huo, Y , Zhang, W , Long, X , Guha, A , Kim, HW , Shi, Y, Rice, RD, Gallo, DR, Patel, V, Lee, R & Weintraub, NL 2023, 'Integrative multiomics analysis of neointima proliferation in human saphenous vein: implications for bypass graft disease', BioRxiv. https://doi.org/10.1101/2023.11.14.567053

@article{30d2cbb11a9747dab663e9cf6955fd76,

title = "Integrative multiomics analysis of neointima proliferation in human saphenous vein: implications for bypass graft disease",

abstract = "INTRODUCTION: Human saphenous veins (SV) are widely used as grafts in coronary artery bypass (CABG) surgery but often fail due to neointima proliferation (NP). NP involves complex interplay between vascular smooth muscle cells (VSMC) and fibroblasts. Little is known, however, regarding the transcriptomic and proteomic dynamics of NP. Here, we performed multi-omics analysis in an ex vivo tissue culture model of NP in human SV procured for CABG surgery. METHODS AND RESULTS: Histological examination demonstrated significant elastin degradation and NP (indicated by increased neointima area and neointima/media ratio) in SV subjected to tissue culture. Analysis of data from 73 patients suggest that the process of SV adaptation and NP may differ according to sex and body mass index. RNA sequencing confirmed upregulation of pro-inflammatory and proliferation-related genes during NP and identified novel processes, including increased cellular stress and DNA damage responses, which may reflect tissue trauma associated with SV harvesting. Proteomic analysis identified upregulated extracellular matrix-related and coagulation/thrombosis proteins and downregulated metabolic proteins. Spatial transcriptomics detected transdifferentiating VSMC in the intima on the day of harvesting and highlighted dynamic alterations in fibroblast and VSMC phenotype and behavior during NP. Specifically, we identified new cell subpopulations contributing to NP, including SPP1 + , LGALS3 + VSMC and MMP2 + , MMP14 + fibroblasts. CONCLUSION: Dynamic alterations of gene and protein expression occur during NP in human SV. Identification of the human-specific molecular and cellular mechanisms may provide novel insight into SV bypass graft disease.",

author = "David Kim and Brandee Goo and Hong Shi and Philip Coffey and Praneet Veerapaneni and Ronnie Chouhaita and Nicole Cyriac and Ghaith Aboud and Stephen Cave and Jacob Greenway and Rohan Mundkur and Samah Ahmadieh and Ragheb Harb and Mourad Ogbi and Fulton, {David J} and Yuqing Huo and Wei Zhang and Xiaochun Long and Avirup Guha and Kim, {Ha Won} and Yang Shi and Rice, {Robert D} and Gallo, {Dominic R} and Vijay Patel and Richard Lee and Weintraub, {Neal L}",

year = "2023",

month = nov,

day = "17",

doi = "10.1101/2023.11.14.567053",

language = "English (US)",

journal = "BioRxiv",

}

TY - JOUR

T1 - Integrative multiomics analysis of neointima proliferation in human saphenous vein

T2 - implications for bypass graft disease

AU - Kim, David

AU - Goo, Brandee

AU - Shi, Hong

AU - Coffey, Philip

AU - Veerapaneni, Praneet

AU - Chouhaita, Ronnie

AU - Cyriac, Nicole

AU - Aboud, Ghaith

AU - Cave, Stephen

AU - Greenway, Jacob

AU - Mundkur, Rohan

AU - Ahmadieh, Samah

AU - Harb, Ragheb

AU - Ogbi, Mourad

AU - Fulton, David J

AU - Huo, Yuqing

AU - Zhang, Wei

AU - Long, Xiaochun

AU - Guha, Avirup

AU - Kim, Ha Won

AU - Shi, Yang

AU - Rice, Robert D

AU - Gallo, Dominic R

AU - Patel, Vijay

AU - Lee, Richard

AU - Weintraub, Neal L

PY - 2023/11/17

Y1 - 2023/11/17

N2 - INTRODUCTION: Human saphenous veins (SV) are widely used as grafts in coronary artery bypass (CABG) surgery but often fail due to neointima proliferation (NP). NP involves complex interplay between vascular smooth muscle cells (VSMC) and fibroblasts. Little is known, however, regarding the transcriptomic and proteomic dynamics of NP. Here, we performed multi-omics analysis in an ex vivo tissue culture model of NP in human SV procured for CABG surgery. METHODS AND RESULTS: Histological examination demonstrated significant elastin degradation and NP (indicated by increased neointima area and neointima/media ratio) in SV subjected to tissue culture. Analysis of data from 73 patients suggest that the process of SV adaptation and NP may differ according to sex and body mass index. RNA sequencing confirmed upregulation of pro-inflammatory and proliferation-related genes during NP and identified novel processes, including increased cellular stress and DNA damage responses, which may reflect tissue trauma associated with SV harvesting. Proteomic analysis identified upregulated extracellular matrix-related and coagulation/thrombosis proteins and downregulated metabolic proteins. Spatial transcriptomics detected transdifferentiating VSMC in the intima on the day of harvesting and highlighted dynamic alterations in fibroblast and VSMC phenotype and behavior during NP. Specifically, we identified new cell subpopulations contributing to NP, including SPP1 + , LGALS3 + VSMC and MMP2 + , MMP14 + fibroblasts. CONCLUSION: Dynamic alterations of gene and protein expression occur during NP in human SV. Identification of the human-specific molecular and cellular mechanisms may provide novel insight into SV bypass graft disease.

AB - INTRODUCTION: Human saphenous veins (SV) are widely used as grafts in coronary artery bypass (CABG) surgery but often fail due to neointima proliferation (NP). NP involves complex interplay between vascular smooth muscle cells (VSMC) and fibroblasts. Little is known, however, regarding the transcriptomic and proteomic dynamics of NP. Here, we performed multi-omics analysis in an ex vivo tissue culture model of NP in human SV procured for CABG surgery. METHODS AND RESULTS: Histological examination demonstrated significant elastin degradation and NP (indicated by increased neointima area and neointima/media ratio) in SV subjected to tissue culture. Analysis of data from 73 patients suggest that the process of SV adaptation and NP may differ according to sex and body mass index. RNA sequencing confirmed upregulation of pro-inflammatory and proliferation-related genes during NP and identified novel processes, including increased cellular stress and DNA damage responses, which may reflect tissue trauma associated with SV harvesting. Proteomic analysis identified upregulated extracellular matrix-related and coagulation/thrombosis proteins and downregulated metabolic proteins. Spatial transcriptomics detected transdifferentiating VSMC in the intima on the day of harvesting and highlighted dynamic alterations in fibroblast and VSMC phenotype and behavior during NP. Specifically, we identified new cell subpopulations contributing to NP, including SPP1 + , LGALS3 + VSMC and MMP2 + , MMP14 + fibroblasts. CONCLUSION: Dynamic alterations of gene and protein expression occur during NP in human SV. Identification of the human-specific molecular and cellular mechanisms may provide novel insight into SV bypass graft disease.

U2 - 10.1101/2023.11.14.567053

DO - 10.1101/2023.11.14.567053

M3 - Article

C2 - 38014255

JO - BioRxiv

JF - BioRxiv

ER -

Integrative multiomics analysis of neointima proliferation in human saphenous vein: implications for bypass graft disease

Abstract

UN SDGs

Access to Document

Fingerprint

Cite this