Region and cell-type resolved quantitative proteomic map of the human heart.
PMID:29133944
|
IF: 17.694
|
Cited by: 179
|
Download citation

Abstract

The heart is a central human organ and its diseases are the leading cause of death worldwide, but an in-depth knowledge of the identity and quantity of its constituent proteins is still lacking. Here, we determine the healthy human heart proteome by measuring 16 anatomical regions and three major cardiac cell types by high-resolution mass spectrometry-based proteomics. From low microgram sample amounts, we quantify over 10,700 proteins in this high dynamic range tissue. We combine copy numbers per cell with protein organellar assignments to build a model of the heart proteome at the subcellular level. Analysis of cardiac fibroblasts identifies cellular receptors as potential cell surface markers. Application of our heart map to atrial fibrillation reveals individually distinct mitochondrial dysfunctions. The heart map is available at maxqb.biochem.mpg.de as a resource for future analyses of normal heart function and disease.

Keywords

Omics
OrbiSIMS
Anatomic

MeSH terms

Cells, Cultured
Coronary Vessels
Endothelial Cells
Heart
Heart Atria
Heart Ventricles
Humans
Male
Myocardium
Myocytes, Cardiac
Myocytes, Smooth Muscle
Proteome
Proteomics

Authors

Doll, Sophia
Dreßen, Martina
Geyer, Philipp E
Itzhak, Daniel N
Braun, Christian
Doppler, Stefanie A
Meier, Florian
Deutsch, Marcus-Andre
Lahm, Harald
Lange, Rüdiger
Krane, Markus
Mann, Matthias

Recommend literature

1. Region-resolved proteomics profiling of monkey heart.
2. Spatially and cell-type resolved quantitative proteomic atlas of healthy human skin.
3. Profiling of the plasma proteome across different stages of human heart failure.
4. Myeloid zinc finger 1 (Mzf1) differentially modulates murine cardiogenesis by interacting with an Nkx2.5 cardiac enhancer.
5. Single-Cell Resolution of Temporal Gene Expression during Heart Development.

Similar data

1. Dissecting cell composition and cell-cell interaction network of normal human heart tissue by single-cell sequencing
2. Dissecting cell composition and cell-cell interaction network of human disease heart tissue by single-cell sequencing