Alexander A. Minin

Thread-grain transition of mitochondrial reticulum as a step of mitoptosis and apoptosis

Association of mitochondrial population to a mitochondrial reticulum is typical of many types of the healthy cells. This allows the cell to organize a united intracellular power-transmitting system. However, such an association can create some difficulties for the cell when a part of the reticulum is damaged or when mitochondria should migrate from one cell region to another. It is shown that in these cases decomposition of extended mitochondria to small roundish organelles takes place (the thread-grain transition). As an intermediate step of this process, formation of bead-like mitochondria occurs when several swollen parts of the mitochondrial filament are interconnected with thin thread-like mitochondrial structures. A hypothesis is put forward that the thread-grain transition is used as a mechanism to isolate a damaged part of the mitochondrial system from its intact parts. If the injury is not repaired, spherical mitochondrion originated from the damaged part of the reticulum is assumed to convert to a small ultracondensed and presumably dead mitochondrion (this process is called ‘mitoptosis’). Then the dead mitochondrion is engulfed by an autophagosome. Sometimes, an ultracondensed mitoplast co-exists with a normal mitoplast, both of them being surrounded by a common outer mitochondrial membrane. During apoptosis, massive thread-grain transition is observed which, according to Youle et al. (S. Frank et al., Dev Cell 1: 515, 2002), is mediated by a dynamin-related protein and represents an obligatory step of the mitochondria-mediated apoptosis. We found that there is a lag phase between addition of an apoptogenic agent and the thread-grain transition. When started, the transition occurs very fast. It is also found that this event precedes complete de-energization of mitochondria and cytochrome c release to cytosol. When formed, small mitochondria migrate to (and in certain rare cases even into) the nucleus. It is suggested that small mitochondria may serve as a transportable form of organelles (‘cargo boats’ transporting some apoptotic proteins to their nuclear targets).

Regulation of mitochondria distribution by RhoA and formins.

The distribution of mitochondria is strictly controlled by the cell because of their vital role in energy supply, regulation of cytosolic Ca2+ concentration and apoptosis. We employed cultured mammalian CV-1 cells and Drosophila BG2-C2 neuronal cells with enhanced green fluorescent protein (EGFP)-tagged mitochondria to investigate the regulation of their movement and anchorage. We show here that lysophosphatidic acid (LPA) inhibits fast mitochondrial movements in CV-1 cells acting through the small GTPase RhoA. The action of RhoA is mediated by its downstream effectors: formin-homology family members mDia1 in mammalian cells and diaphanous in Drosophila. Overexpression of constitutively active mutant forms of formins leads to dramatic loss of mitochondrial motility and to their anchorage to actin microfilaments. Conversely, depletion of endogenous diaphanous protein in BG2-C2 cells by RNA interference (RNAi) stimulates the mitochondrial movement. These effects are not simply explained by increased cytoplasm viscosity resulting from an increased F-actin concentration since stimulators of Arp2/3-dependent actin polymerization and jasplakinolide do not cause inhibition. The observed effects are highly specific to mitochondria since perturbations of diaphanous or mDia1 have no effect on movement of other membrane organelles. Thus, mitochondrial movement is controlled by the small GTPase RhoA and this control is mediated by formins.

Vimentin Intermediate Filaments Modulate the Motility of Mitochondria

The vimentin N-terminal domain contains the sequence responsible for the interaction with mitochondria. The interaction of vimentin intermediate filaments with mitochondria causes the inhibition of their movements and contributes to their anchoring in cytoplasm.

Mitochondrial membrane potential is regulated by vimentin intermediate filaments

This study demonstrates that the association of mitochondria with vimentin intermediate filaments (VIFs) measurably increases their membrane potential. This increase is detected by quantitatively comparing the fluorescence intensity of mitochondria stained with the membrane potential‐sensitive dye tetramethylrhodamine‐ethyl ester (TMRE) in murine vimentin‐null fibroblasts with that in the same cells expressing human vimentin (~35% rise). When vimentin expression is silenced by small hairpin RNA (shRNA) to reduce vimentin by 90%, the fluorescence intensity of mitochondria decreases by 20%. The increase in membrane potential is caused by specific interactions between a subdomain of the non‐α‐helical N terminus (residues 40 to 93) of vimentin and mitochondria. In rho 0 cells lacking mitochondrial DNA (mtDNA) and consequently missing several key proteins in the mitochondrial respiratory chain (ρ0 cells), the membrane potential generated by an alternative anaerobic process is insensitive to the interactions between mitochondria and VIF. The results of our studies show that the close association between mitochondria and VIF is important both for determining their position in cells and their physiologic activity.—Chernoivanenko, I. S., Matveeva, E. A., Gelfand, V. I., Goldman, R. D., Minin, A. A., Mitochondrial membrane potential is regulated by vimentin intermediate filaments. FASEB J. 29, 820–827 (2015). www.fasebj.org

Intermediate Vimentin Filaments and Their Role in Intracellular Organelle Distribution

Intermediate filaments (IF) represent one of three main cytoskeletal structures in most animal cells. The human IF protein family includes about 70 members divided into five main groups. The characteristic feature of IF is that in various cells and tissues they are formed by proteins of different groups. Structures of all IF proteins follow a unique scheme: a central α-helical part is flanked at the N and C ends by positively charged polypeptide chains devoid of a clear secondary structure. The central part is highly conserved for all proteins in all animals, whereas the N and C termini strongly differ both in size and amino acid composition. This review covers the broad spectrum of recent investigations of IF structure and diverse functions. Special attention is paid to the regulatory mechanisms of IF functions, mainly to phosphorylation by different protein kinases whose role is well studied. The review gives examples of hereditary diseases associated with mutations of some IF proteins, which point to an important physiological role of these cytoskeletal structures.

Dynein is a motor for nuclear rotation while vimentin IFs is a “brake”

The positioning of the nucleus is achieved by two interconnected processes, anchoring and migration, both of which are controlled by cytoskeleton structures. Rotation is a special type of nuclear motility in many cell types, but its significance remains unclear. We used a vimentin‐null cell line, MFT‐16, which shows extensive nuclear rotation to study the phenomenon in detail. By selective disruption of cytoskeletal structures and video‐microscopic analysis, nuclear rotation was a microtubule‐dependent process that F‐actin partially impedes. The dynein–dynactin complex is responsible and inhibiting this motor by expression of a dominant negative mutant of its component P‐150 completely stops it. Nuclear rotation is powered by dynein associated with the nuclear envelope along stationary microtubules, centrosomes remaining immobile. We confirmed that vimentin IFs inhibit nuclear rotation, and variant proteins of the mutated wild type gene for vimentin that lacked considerable fragments of the N‐ and C‐terminal domains restored nuclear anchoring. Immunochemical analysis showed that these mutated IFs also bound plectin, arguing for a key role of this cytolinker protein in nuclear anchoring. It is proposed that this versatile machinery guarantees not only rotation and the correct location of a nucleus, but also its orientation in a cell.

Myosin-Va restrains the trafficking of Na+/K+-ATPase-containing vesicles in alveolar epithelial cells

Stimulation of Na+/K+-ATPase activity in alveolar epithelial cells by cAMP involves its recruitment from intracellular compartments to the plasma membrane. Here, we studied the role of the actin molecular motor myosin-V in this process. We provide evidence that, in alveolar epithelial cells, cAMP promotes Na+/K+-ATPase recruitment to the plasma membrane by increasing the average speed of Na+/K+-ATPase-containing vesicles moving to the cell periphery. We found that three isoforms of myosin-V are expressed in alveolar epithelial cells; however, only myosin-Va and Vc colocalized with the Na+/K+-ATPase in intracellular membrane fractions. Overexpression of dominant-negative myosin-Va or knockdown with specific shRNA increased the average speed and distance traveled by the Na+/K+-ATPase-containing vesicles, as well as the Na+/K+-ATPase activity and protein abundance at the plasma membrane to similar levels as those observed with cAMP stimulation. These data show that myosin-Va has a role in restraining Na+/K+-ATPase-containing vesicles within intracellular pools and that this restrain is released after stimulation by cAMP allowing the recruitment of the Na+/K+-ATPase to the plasma membrane and thus increased activity.

Vimentin is involved in regulation of mitochondrial motility and membrane potential by Rac1

ABSTRACT In this study we show that binding of mitochondria to vimentin intermediate filaments (VIF) is regulated by GTPase Rac1. The activation of Rac1 leads to a redoubling of mitochondrial motility in murine fibroblasts. Using double-mutants Rac1(G12V, F37L) and Rac1(G12V, Y40H) that are capable to activate different effectors of Rac1, we show that mitochondrial movements are regulated through PAK1 kinase. The involvement of PAK1 kinase is also confirmed by the fact that expression of its auto inhibitory domain (PID) blocks the effect of activated Rac1 on mitochondrial motility. The observed effect of Rac1 and PAK1 kinase on mitochondria depends on phosphorylation of the Ser-55 of vimentin. Besides the effect on motility Rac1 activation also decreases the mitochondrial membrane potential (MMP) which is detected by ∼20% drop of the fluorescence intensity of mitochondria stained with the potential sensitive dye TMRM. One of important consequences of the discovered regulation of MMP by Rac1 and PAK1 is a spatial differentiation of mitochondria in polarized fibroblasts: at the front of the cell they are less energized (by ∼25%) than at the rear part.

KINESIN-ASSOCIATED TRANSPORT IS INVOLVED IN THE REGULATION OF CELL ADHESION

It has been recently shown that depolymerization of microtubules induces the elongation of focal contacts at the leading edge. On the other hand, cell shape and pseudopodial activity were found to depend on the microtubule‐based motor kinesin. In this paper, we examine whether kinesin is involved in controlling the dynamics of adhesive structures at the cell surface. Microinjection of an antiblocking kinesin activityin vitrocauses focal contact elongation similar to the effect of microtubule‐depolymerizing drugs. Thus, the role of microtubules in cell adhesion lies in the supporting kinesin‐based transport to the adhesion sites.

Vimentin intermediate filaments protect mitochondria from oxidative stress

The role of intermediate filaments (IFs) in eukaryotic cells is still unclear. The disturbance of mitochondria distribution and function, in particular the enhanced production of reactive oxygen species (ROS) and decreased membrane potential, is observed in cells devoid of IFs. The aim of this work was to study the dependence of mitochondria sensitivity to oxidative stress on the presence of vimentin IFs. It was found that mitochondria are less sensitive to ROS in cells containing vimentin than in cells devoid of vimentin. Besides, mitochondrial membrane potential was demonstrated to increase upon regeneration of vimentin IFs in the cells. Substitution of Pro-57 by Arg in N-terminal part of the vimentin molecule abandoned its protective ability and the effect on mitochondrial membrane potential.