Mitochondria are highly dynamic, double-membrane organelles that play integral roles beyond energy production. Mitochondria adapt their morphology to meet diverse cellular demands, and highly plastic mitochondrial networks interact and communicate with various cellular components to maintain cellular health. Advances in both light and electron microscopy (EM) have greatly enhanced our understanding of mitochondrial structure and function. However, the small diameter of mitochondrial tubules, often near the diffraction limit of light, poses challenges for visualizing submitochondrial structures and protein distributions with conventional microscopy. Recently, super-resolution microscopy has offered unprecedented insights into mitochondrial dynamics, interactions and architecture. In this Review, we discuss how imaging techniques have advanced our understanding of mitochondrial biology. We critically assess the contributions of two-dimensional EM to elucidating the native architecture of cristae and respiratory chain complexes. Additionally, we explore how three-dimensional EM and super-resolution methods have reshaped our comprehension of mitochondrial network dynamics, heterogeneity and interactions with other cellular components. Finally, we discuss the strengths and limitations of various approaches, considering their potential to overcome current challenges and open new avenues in mitochondrial research, and illuminate how advanced microscopy continues to drive discoveries in mitochondrial biology with implications for metabolic diseases and aging.
Katti et al. (Sun,) studied this question.