RHOT2

Mitochondrial Rho GTPase 2 is an is_associated_with::enzyme that in humans is encoded by the RHOT2 is_associated_with::gene. As a Miro protein is_associated_with::isoform, the protein facilitates mitochondrial transport by attaching the is_associated_with::mitochondria to the motor/adaptor complex. Through its key role in mitochondrial transport, RHOT2 is involved in mitochondrial is_associated_with::homeostasis and is_associated_with::apoptosis, as well as is_associated_with::Parkinson’s disease (PD).

Structure
In mammals, RHOT2 is one of two Miro isoforms. Both isoforms share a structure consisting of two EF-hand motifs linking two GTP-binding domains and a C-terminal transmembrane domain that attaches the protein to the is_associated_with::outer mitochondrial membrane (OMM). The EF-hand motifs serve as binding sites for the adaptor protein Milton and the kinesin heavy chain. These domains can also bind calcium ions, and the binding results in a conformational change that dissociates the mitochondrial surface from kinesin.

Function
RHOT2 is a member of the Rho GTPase family and one of two isoforms of the protein Miro: is_associated_with::RHOT1 (Miro1) and RHOT2 (Miro2). Compared to the rest of the Rho GTPase family, the Miro isoforms are considered atypical due to their different regulation. Moreover, the Miro isoforms are only expressed in the mitochondria.

Miro associates with Milton (is_associated_with::TRAK1/2) and the motor proteins is_associated_with::kinesin and is_associated_with::dynein to form the mitochondrial motor/adaptor complex. Miro functions to tether the complex to the mitochondrion while the complex transports the mitochondrion via is_associated_with::microtubules within cells. Though Miro has been predominantly studied in is_associated_with::neurons, the protein has also been observed to participate in the transport of mitochondria in is_associated_with::lymphocytes toward inflamed endothelia.

The motor/adaptor complex is regulated by calcium ion levels. At high concentrations, calcium ions arrest mitochondrial transport by binding Miro, causing the complex to detach from the organelle. Considering that physiological factors such as activation of is_associated_with::glutamate receptors in dendrites, is_associated_with::action potentials in axons, and neuromodulators may elevate calcium ion levels, this regulatory mechanism likely serves to keep mitochondria in such areas to provide calcium ion buffering and active export and, thus, maintain homeostasis.

In addition, Miro regulates is_associated_with::mitochondrial fusion and is_associated_with::mitophagy in conjunction with is_associated_with::mitofusin. According to one model, damaged mitochondria are sequestered from healthy mitochondria by the degradation of Miro and mitofusin. Miro degradation halts their movement while mitofusin degradation prevents them from fusing with healthy mitochondria, thus facilitating their clearance by autophagosomes.

Clinical significance
Studies indicate that Miro may be involved in PD. In neurons, Miro interacts with two key proteins involved in PD, PINK1 and Parkin. Following depolarization of the mitochondria, PINK1 phosphorylates Miro at multiple sites, including S156, and Parkin ubiquitinates Miro, targeting it for proteasomal degradation. Degradation of Miro then halts mitochondrial transport.

Though the Rho GTPase family is closely associated with is_associated_with::cancer progression, there are few studies demonstrating such association with the atypical Miro proteins.

Interactions
RHOT1 has been shown to interact with:
 * ALEX3,
 * is_associated_with::DISC1,
 * is_associated_with::Dynein,
 * HUMMR,
 * kinesin heavy chain (KHC),
 * Mitofusin (is_associated_with::MFN1/is_associated_with::MFN2),
 * Milton (is_associated_with::TRAK1/is_associated_with::TRAK2),
 * Parkin,
 * is_associated_with::PINK1, and
 * OGT.