Species Differences in the Morphology of Transverse Tubule Openings in Cardiomyocytes

Overview

Journal Europace

Publisher Oxford University Press

Specialties Cardiology & Vascular Diseases
Physiology

Date 2018 Nov 27

PMID 30476062

Citations 12

Authors

Eva Alicja Rog-Zielinska

Cherrie Hei Ting Kong

Callum Michael Zgierski-Johnston

Paul Verkade

Judith Mantell

Mark Bryden Cannell

Peter Kohl

Affiliations

Soon will be listed here.

Abstract

Aims: The ultrastructure of ventricular cardiomyocyte T-tubule connections with the outer cell surface ('mouth' regions) has been reported to differ between mice and rabbits. In mice, T-tubule mouths form convoluted narrow spaces filled with electron-dense matter that impedes diffusion between T-tubular lumen and bulk extracellular space. Here, we explore whether T-tubule mouths are also constricted in rat (another murine model used frequently for cardiac research) and whether pig and human T-tubule mouth configurations are structurally more similar to mice or rabbits.

Methods And Results: We used chemically-fixed tissue and high-pressure frozen isolated cardiomyocytes to compare T-tubule mouth architecture using transmission electron microscopy and three-dimensional electron tomography. We find that rat T-tubular mouth architecture is more similar to that of rabbits than mice, lacking the marked tortuosity and electron-dense ground substance that obstructs access to deeper portions of the T-tubular system in mice. Pilot observations in larger mammals (pig, human) suggest that mouse may be the least representative animal model of T-tubule connectivity with the outer cell surface in larger mammals.

Conclusion: Rat T-tubular system architecture appears to be more similar in size and topology to larger mammals than mice. T-tubular mouth topology may contribute to differences in experimental model behaviour, underscoring the challenge of appropriate model selection for research into cell and tissue function.

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