Jump to Main Contents
ncc en
HOME > Publication & Reports > Annual Report 2022 > Research Institute

Annual Report 2022

Division of Cancer Biology

Hirofumi Arakawa, Yasuyuki Nakamura, Naoki Ikari, Yoko Sagami, Katsuko Honjo

Research Activities

p53/Mieap-regulated mitochondrial quality control

 Mitochondria-eating protein (Mieap, also designated as SPATA18) was originally identified as a p53-inducible protein; its mRNA expression is directly regulated by the tumor suppressor p53 in response to various cellular stresses, including DNA damage (PLoS ONE 6: e16054, 2011). Mieap expression is lost in nearly 50% of human cancer cell lines due to promoter methylation. Mieap-deficient LS174T colorectal cancer cells exhibit increased mitochondrial reactive oxygen species (ROS) generation and decreased mitochondrial ATP synthesis. The mitochondrial ROS in Mieap-deficient colorectal cancer and gastric cancer cells enhance the migration and invasion activities of cancer cells under hypoxic conditions (Oncogenesis 5: e181, 2016; Scientific Reports 9: 2822, 2019). Mieap-deficient ApcMin/+ mice exhibit the promotion of intestinal tumor initiation and malignant transformation (Scientific Reports 5: 12472, 2015). Tumors in Mieap-deficient ApcMin/+ mice have revealed abnormal morphology of the mitochondria, such as enlarged size, round shape, and a decrease in the cristae structure. Recently, Mieap expression was reported to be defective in thyroid oncocytic cell tumors, which exhibit accumulation of abnormal mitochondria in tumor cells (Cancer Sci. 111: 2814–2823, 2020). Mieap-regulated mitochondrial quality control is inactivated in the tumor tissues of nearly 70% of colorectal cancer, 25% of breast cancer, 70% of gastric cancer, and 83% of esophageal cancer patients (Oncogenesis 5: e181, 2016; Cancer Sci. 109: 3910–3920, 2018; Biochem Biophys Res Commun. 529: 582-589, 2020). Mieap is associated with better survival in breast cancer patients (Am J Cancer Res. 11: 6060-6073, 2021). These observations suggest that Mieap plays a critical role in tumor suppression via its mitochondrial quality control function. However, the mechanism underlying the regulation of mitochondrial quality control by Mieap remains unclear.

Liquid droplets function as membrane-less organelles in cells

 Liquid droplets (LDs) in cells are protein condensates, which are composed of proteins, nucleic acids, and other macromolecular components (Droplets of life, 2022, Elsevier). LDs are formed by proteins with an intrinsically disordered region(s) (IDR) via liquid-liquid phase separation (LLPS) (Figure 1). Importantly, LDs function as membraneless organelles that compartmentalize and facilitate cellular biological reactions. LDs are not surrounded by a lipid bilayer structure, which enables the dynamic exchange of reactants and products with their surroundings, facilitating biological reactions in cells. Furthermore, theoretically, LDs can appear and disappear anywhere within a cell in response to cellular stress and/or subcellular circumstances, exhibiting spatiotemporal dynamic properties. On the basis of these features, the concept of membraneless organelles is fundamentally different from the long-standing concept of membrane-bound organelles, such as the nucleus, lysosome, mitochondria, and endoplasmic reticulum, which stably exist and strictly segregate biomolecules and biological reactions in a lipid bilayer structure. It has been suggested that a number of membraneless organelles might exist within a cell, which could regulate various cellular biological reactions and activities, including transcriptional regulation, signal transduction, immunity, centrosome activity, and mitosis. This list is now rapidly growing.

Figure 1. Liquid droplets are induced by liquid-liquid phase separation
Figure 1. Liquid droplets are induced by liquid-liquid phase separation

Figure 1. Liquid droplets are induced by liquid-liquid phase separation
Figure 1. Liquid droplets are induced by liquid-liquid phase separation

Cardiolipin (CL) is a unique and important phospholipid that is specific to mitochondria

 CL is a phospholipid dimer, which has two phosphate residues and four fatty acyl chains. Because of this unique structure, it forms a cone shape, which plays a critical role in forming the curvature of the lipid membrane, contributing to maintenance of the mitochondrial cristae structure. CL is the only phospholipid that is specific to the mitochondria and is mainly located at the inner mitochondrial membrane and contact sites. CL interacts with many mitochondrial membrane proteins, including the electron transport chain complexes involved in oxidative phosphorylation and the ADP/ATP carrier; the interaction with CL promotes the activity of these proteins. CL stabilizes the structural assembly and activity of the respiratory super-complexes at the inner mitochondrial membrane. CL interacts with cytochrome c at the outer surface of the inner mitochondrial membrane, which plays a pivotal role in the life and death of cells by maintaining stable respiratory ATP production and inducing apoptosis, respectively. Therefore, altered CL metabolism and/or deterioration of CL quality causes various mitochondrial dysfunctions and diseases via abnormal cristae structures, decreased ATP synthesis activity, and increased ROS generation (Figure 2).

Figure 2. Role of cardiolipin in mitochondrial proteins
Figure 2. Role of cardiolipin in mitochondrial proteins

Figure 2. Role of cardiolipin in mitochondrial proteins
Figure 2. Role of cardiolipin in mitochondrial proteins

Mieap forms membraneless organelles to compartmentalize and facilitate cardiolipin metabolism

 This year, we reported that Mieap is an IDR-containing protein that drives the formation of liquid droplets in the mitochondria (bioRxiv doi: 10.1101/2020.10.26.354365). Mieap liquid droplets (MLDs) specifically phase separate the mitochondrial phospholipid cardiolipin. Lipidomic analysis of cardiolipin suggests that Mieap promotes enzymatic reactions involved in cardiolipin metabolism, including biosynthesis and remodeling. Accordingly, four cardiolipin biosynthesis enzymes, TAMM41, PGS1, PTPMT1, and CRLS1, and two remodeling enzymes, PLA2G6 and TAZ, are phase separated by MLDs. Mieap-deficient mice exhibited altered cristae structure in the liver and kidney mitochondria and a trend of obesity. These results suggest that Mieap drives the formation of membraneless organelles to compartmentalize and promotes cardiolipin metabolism at the inner mitochondrial membrane, thereby playing a possible role in mitochondrial quality control (Figure 3).

Figure 3. Mieap liquid droplets function as membrane-less organelles to compartmentalize and facilitate cardiolipin metabolism
Figure 3. Mieap liquid droplets function as membrane-less organelles to compartmentalize and facilitate cardiolipin metabolism

Figure 3. Mieap liquid droplets function as membrane-less organelles to compartmentalize and facilitate cardiolipin metabolism
Figure 3. Mieap liquid droplets function as membrane-less organelles to compartmentalize and facilitate cardiolipin metabolism

Future Prospects

 Autophagy and proteostasis are two major mechanisms in mitochondrial quality control. In addition to these, we suggest that the Mieap-regulated pathway is the third mechanism for mitochondrial quality control, in which Mieap maintains the integrity of mitochondria by regulating CL metabolism. Mieap maintains mitochondrial quality through homeostasis of the inner mitochondrial membrane by regulating CL metabolism, stabilizing oxidative phosphorylation, and suppressing mitochondrial ROS generation (Figure 4). Considering the role of Mieap in p53 function, we suggest that Mieap could act as a spatiotemporal and dynamic regulator/modulator in CL metabolism to suppress tumor initiation and progression.

Figure 4. p53/Mieap suppresses tumors by regulating CL metabolism
Figure 4. p53/Mieap suppresses tumors by regulating CL metabolism

Figure 4. p53/Mieap suppresses tumors by regulating CL metabolism
Figure 4. p53/Mieap suppresses tumors by regulating CL metabolism

List of papers published in 2022

Journal

1. Ikari N, Arakawa H. Identification of a mitochondrial targeting sequence in cathepsin D and its localization in mitochondria. Biochemical and biophysical research communications, 655:25-34, 2023

2. Hamada K, Kurashige T, Shimamura M, Arakawa H, Nakamura Y, Nagayama Y. MIEAP and ATG5 are tumor suppressors in a mouse model of BRAF(V600E)-positive thyroid cancer. Frontiers in endocrinology, 13:932754, 2022

Book

1. Arakawa H. Chapter 14 - MLOs and control of metabolic pathways. In: Uversky VN (ed), Droplets of Life, US, Academic Press, pp 431-446, 2023