Universal Dynamics of Mitochondrial Networks: a Finite-size Scaling Analysis

Overview

Journal Sci Rep

Specialty Science

Date 2022 Oct 12

PMID 36224243

Authors

Nahuel Zamponi

Emiliano Zamponi

Sergio A Cannas

Dante R Chialvo

Affiliations

Soon will be listed here.

Abstract

Evidence from models and experiments suggests that the networked structure observed in mitochondria emerges at the critical point of a phase transition controlled by fission and fusion rates. If mitochondria are poised at criticality, the relevant network quantities should scale with the system's size. However, whether or not the expected finite-size effects take place has not been demonstrated yet. Here, we first provide a theoretical framework to interpret the scaling behavior of mitochondrial network quantities by analyzing two conceptually different models of mitochondrial dynamics. Then, we perform a finite-size scaling analysis of real mitochondrial networks extracted from microscopy images and obtain scaling exponents comparable with critical exponents from models and theory. Overall, we provide a universal description of the structural phase transition in mammalian mitochondria.

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