High-Resolution 3D Heart Models of Cardiomyocyte Subpopulations in Cleared Murine Heart

Huiying Ren; Zhaoli Pu; Tianyi Sun; Tangting Chen; Leiying Liu; Zhu Liu; Christopher O’Shea; Davor Pavlovic; Xiaoqiu Tan; Ming Lei

doi:10.3389/fphys.2022.779514

High-Resolution 3D Heart Models of Cardiomyocyte Subpopulations in Cleared Murine Heart

Huiying Ren, Zhaoli Pu, Tianyi Sun^*, Tangting Chen, Leiying Liu, Zhu Liu, Christopher O’Shea, Davor Pavlovic, Xiaoqiu Tan^*, Ming Lei^*

^*Corresponding author for this work

Cardiovascular Sciences

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Abstract

Biological tissues are naturally three-dimensional (3D) opaque structures, which poses a major challenge for the deep imaging of spatial distribution and localization of specific cell types in organs in biomedical research. Here we present a 3D heart imaging reconstruction approach by combining an improved heart tissue-clearing technique with high-resolution light-sheet fluorescence microscopy (LSFM). We have conducted a three-dimensional and multi-scale volumetric imaging of the ultra-thin planes of murine hearts for up to 2,000 images per heart in x-, y-, and z three directions. High-resolution 3D volume heart models were constructed in real-time by the Zeiss Zen program. By using such an approach, we investigated detailed three-dimensional spatial distributions of two specific cardiomyocyte populations including HCN4 expressing pacemaker cells and Pnmt⁺ cell-derived cardiomyocytes by using reporter mouse lines Hcn4^{DreER/tdTomato} and Pnmt^{Cre/ChR2−tdTomato}. HCN4 is distributed throughout right atrial nodal regions (i.e., sinoatrial and atrioventricular nodes) and the superior-inferior vena cava axis, while Pnmt⁺ cell-derived cardiomyocytes show distinct ventral, left heart, and dorsal side distribution pattern. Our further electrophysiological analysis indicates that Pnmt + cell-derived cardiomyocytes rich left ventricular (LV) base is more susceptible to ventricular arrhythmia under adrenergic stress than left ventricular apex or right ventricle regions. Thus, our 3D heart imaging reconstruction approach provides a new solution for studying the geometrical, topological, and physiological characteristics of specific cell types in organs.

Original language	English
Article number	779514
Number of pages	12
Journal	Frontiers in Physiology
Volume	13
DOIs	https://doi.org/10.3389/fphys.2022.779514
Publication status	Published - 18 May 2022

Bibliographical note

Funding Information:
This study was supported by MRC (G10002647, G1002082, ML), BHF (PG/14/80/31106, PG/16/67/32340, PG/12/21/29473, PG/11/59/29004ML), BHF CRE at Oxford (ML) grants, the Chinese Nature Science Foundation Grant (31871181: ML, 81670310: XT), 221650/Z/20/Z Sir Henry Wellcome Trust Fellowship, The Wellcome Trust (CO'S, DP) and Collaborative Innovation Center for Prevention and Treatment of Cardiovascular Disease Grant (XT, ML).

Publisher Copyright:
Copyright © 2022 Ren, Pu, Sun, Chen, Liu, Liu, O’Shea, Pavlovic, Tan and Lei.

Keywords

3D volume heart models
HCN4 expression (HCN4+) pacemaker cells
heart tissue-clearing
light-sheet fluorescence microscopy
optogenetics
Pnmt+ cell-derived cardiomyocytes (PdCMs)

ASJC Scopus subject areas

Physiology
Physiology (medical)

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Cite this

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title = "High-Resolution 3D Heart Models of Cardiomyocyte Subpopulations in Cleared Murine Heart",

abstract = "Biological tissues are naturally three-dimensional (3D) opaque structures, which poses a major challenge for the deep imaging of spatial distribution and localization of specific cell types in organs in biomedical research. Here we present a 3D heart imaging reconstruction approach by combining an improved heart tissue-clearing technique with high-resolution light-sheet fluorescence microscopy (LSFM). We have conducted a three-dimensional and multi-scale volumetric imaging of the ultra-thin planes of murine hearts for up to 2,000 images per heart in x-, y-, and z three directions. High-resolution 3D volume heart models were constructed in real-time by the Zeiss Zen program. By using such an approach, we investigated detailed three-dimensional spatial distributions of two specific cardiomyocyte populations including HCN4 expressing pacemaker cells and Pnmt+ cell-derived cardiomyocytes by using reporter mouse lines Hcn4DreER/tdTomato and PnmtCre/ChR2−tdTomato. HCN4 is distributed throughout right atrial nodal regions (i.e., sinoatrial and atrioventricular nodes) and the superior-inferior vena cava axis, while Pnmt+ cell-derived cardiomyocytes show distinct ventral, left heart, and dorsal side distribution pattern. Our further electrophysiological analysis indicates that Pnmt + cell-derived cardiomyocytes rich left ventricular (LV) base is more susceptible to ventricular arrhythmia under adrenergic stress than left ventricular apex or right ventricle regions. Thus, our 3D heart imaging reconstruction approach provides a new solution for studying the geometrical, topological, and physiological characteristics of specific cell types in organs.",

keywords = "3D volume heart models, HCN4 expression (HCN4+) pacemaker cells, heart tissue-clearing, light-sheet fluorescence microscopy, optogenetics, Pnmt+ cell-derived cardiomyocytes (PdCMs)",

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note = "Funding Information: This study was supported by MRC (G10002647, G1002082, ML), BHF (PG/14/80/31106, PG/16/67/32340, PG/12/21/29473, PG/11/59/29004ML), BHF CRE at Oxford (ML) grants, the Chinese Nature Science Foundation Grant (31871181: ML, 81670310: XT), 221650/Z/20/Z Sir Henry Wellcome Trust Fellowship, The Wellcome Trust (CO'S, DP) and Collaborative Innovation Center for Prevention and Treatment of Cardiovascular Disease Grant (XT, ML). Publisher Copyright: Copyright {\textcopyright} 2022 Ren, Pu, Sun, Chen, Liu, Liu, O{\textquoteright}Shea, Pavlovic, Tan and Lei.",

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day = "18",

doi = "10.3389/fphys.2022.779514",

language = "English",

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AU - Ren, Huiying

AU - Pu, Zhaoli

AU - Sun, Tianyi

AU - Chen, Tangting

AU - Liu, Leiying

AU - Liu, Zhu

AU - O’Shea, Christopher

AU - Pavlovic, Davor

AU - Tan, Xiaoqiu

AU - Lei, Ming

N1 - Funding Information: This study was supported by MRC (G10002647, G1002082, ML), BHF (PG/14/80/31106, PG/16/67/32340, PG/12/21/29473, PG/11/59/29004ML), BHF CRE at Oxford (ML) grants, the Chinese Nature Science Foundation Grant (31871181: ML, 81670310: XT), 221650/Z/20/Z Sir Henry Wellcome Trust Fellowship, The Wellcome Trust (CO'S, DP) and Collaborative Innovation Center for Prevention and Treatment of Cardiovascular Disease Grant (XT, ML). Publisher Copyright: Copyright © 2022 Ren, Pu, Sun, Chen, Liu, Liu, O’Shea, Pavlovic, Tan and Lei.

PY - 2022/5/18

Y1 - 2022/5/18

N2 - Biological tissues are naturally three-dimensional (3D) opaque structures, which poses a major challenge for the deep imaging of spatial distribution and localization of specific cell types in organs in biomedical research. Here we present a 3D heart imaging reconstruction approach by combining an improved heart tissue-clearing technique with high-resolution light-sheet fluorescence microscopy (LSFM). We have conducted a three-dimensional and multi-scale volumetric imaging of the ultra-thin planes of murine hearts for up to 2,000 images per heart in x-, y-, and z three directions. High-resolution 3D volume heart models were constructed in real-time by the Zeiss Zen program. By using such an approach, we investigated detailed three-dimensional spatial distributions of two specific cardiomyocyte populations including HCN4 expressing pacemaker cells and Pnmt+ cell-derived cardiomyocytes by using reporter mouse lines Hcn4DreER/tdTomato and PnmtCre/ChR2−tdTomato. HCN4 is distributed throughout right atrial nodal regions (i.e., sinoatrial and atrioventricular nodes) and the superior-inferior vena cava axis, while Pnmt+ cell-derived cardiomyocytes show distinct ventral, left heart, and dorsal side distribution pattern. Our further electrophysiological analysis indicates that Pnmt + cell-derived cardiomyocytes rich left ventricular (LV) base is more susceptible to ventricular arrhythmia under adrenergic stress than left ventricular apex or right ventricle regions. Thus, our 3D heart imaging reconstruction approach provides a new solution for studying the geometrical, topological, and physiological characteristics of specific cell types in organs.

AB - Biological tissues are naturally three-dimensional (3D) opaque structures, which poses a major challenge for the deep imaging of spatial distribution and localization of specific cell types in organs in biomedical research. Here we present a 3D heart imaging reconstruction approach by combining an improved heart tissue-clearing technique with high-resolution light-sheet fluorescence microscopy (LSFM). We have conducted a three-dimensional and multi-scale volumetric imaging of the ultra-thin planes of murine hearts for up to 2,000 images per heart in x-, y-, and z three directions. High-resolution 3D volume heart models were constructed in real-time by the Zeiss Zen program. By using such an approach, we investigated detailed three-dimensional spatial distributions of two specific cardiomyocyte populations including HCN4 expressing pacemaker cells and Pnmt+ cell-derived cardiomyocytes by using reporter mouse lines Hcn4DreER/tdTomato and PnmtCre/ChR2−tdTomato. HCN4 is distributed throughout right atrial nodal regions (i.e., sinoatrial and atrioventricular nodes) and the superior-inferior vena cava axis, while Pnmt+ cell-derived cardiomyocytes show distinct ventral, left heart, and dorsal side distribution pattern. Our further electrophysiological analysis indicates that Pnmt + cell-derived cardiomyocytes rich left ventricular (LV) base is more susceptible to ventricular arrhythmia under adrenergic stress than left ventricular apex or right ventricle regions. Thus, our 3D heart imaging reconstruction approach provides a new solution for studying the geometrical, topological, and physiological characteristics of specific cell types in organs.

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High-Resolution 3D Heart Models of Cardiomyocyte Subpopulations in Cleared Murine Heart

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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