Rottlerin

Rottlerin (mallotoxin) is a polyphenol natural product isolated from the Asian tree Mallotus philippensis. Rottlerin displays a complex spectrum of pharmacology.^[1]

Rottlerin has been shown to be an uncoupler of mitochondrial oxidative phosphorylation.^[2][3][4]

Rottlerin is a potent large conductance potassium channel (BKCa++) opener.^[5] BKCa++ is found in the inner mitochondrial membrane of cardiomyocytes.^[6] Opening these channels is beneficial for post-ischemic changes in vasodilation.^[7] Other BKCa++ channel openers are reported to limit the mitochondrial calcium overload due to ischemia.^[8][9] Rottlerin is also capable of reducing oxygen radical formation.^[1]

Other BKCa++ channel openers (NS1619, NS11021 and DiCl-DHAA) have been reported to have cardio-protective effects after ischemic-reperfusion injury.^[9][10][11] There were reductions in mitochondrial Ca++ overload, mitochondrial depolarization, increased cell viability and improved function in the whole heart.^[9][10][11]

Mallotoxin is also a hERG potassium channel activator.^[12]

Clements et al.^[5] reported that rottlerin improves the recovery of isolated rat hearts perfused with buffer after cold cardioplegic arrest. A majority of patients recover but some develop a cardiac low-output syndrome attributable in part to depressed left ventricular or atrial contractility, which increases chance of death.^[5]

Rottlerin increases in isolated heart contractility independent of its vascular effects, as well as enhanced perfusion through vasomotor activity.^[5] The activation of BKCa++ channels by rottlerin relaxes coronary smooth muscle and improves myocardial perfusion after cardioplegia.^[5]

Myocardial stunning is associated with oxidant radical damage and calcium overload.^[5] Contractile abnormalities can occur through oxidant-dependent damage and also through calcium overload in the mitochondria resulting in mitochondrial damage.^[13][14][15] BKCa++ channels reside in the inner mitochondrial membrane^[6] and their activation is proposed to increase K+ accumulation in mitochondria.^[8][9] This limits Ca²⁺
influx into mitochondria, reducing mitochondrial depolarization and permeability transition pore opening.^[8][9] This may result in less mitochondrial damage and therefore greater contractility since there is a decrease in apoptosis compared to no stimulation of BKCa++ channels.^[5]

Rottlerin also enhances the cardioplegia-induced phosphorylation of Akt on the activation residue Thr308.^[5] Akt activation modulates mitochondrial depolarization and the permeability transition pore.^[16][17] Clements et al.^[5] found that Akt functions downstream of the BKCa++ channels and its activation is considered beneficial after ischemic-reperfusion injury. It is unclear what the specific role of Akt may play in modulating of myocardial function after rottlerin treatment of cardioplegia.^[5] More research needs to be done to examine if Akt is necessary to improve cardiac function when rottlerin is administered.^[5]

The antioxidant properties of rottlerin have been demonstrated but it is unclear whether the effects are because of BKCa++ channel opening or an additional mechanism of rottlerin.^[1][5][18] There was no oxygen dependent damage found by rottlerin in the study conducted by Clements et al.^[5]

Rottlerin has been reported to be a PKCδ inhibitor.^[19] PKCδ has been implicated in depressing cardiac function and cell death after ischemia-reperfusion injury as well as promoting vascular smooth muscle contraction and decreasing perfusion.^[5] However, the role of rottlerin as a specific PKCδ inhibitor has been questioned. There have been several studies using rottlerin as a PKCδ selective inhibitor based on in vitro studies, but some studies showed it did not block PKCδ activity and did block other kinase and non-kinase proteins in vitro.^[1][20][21] Rottlerin also uncouples mitochondria at high doses and results in depolarization of the mitochondrial membrane potential.^[1] It was found to reduce ATP levels, activate 5'-AMP-activated protein kinase and affect mitochondrial production of reactive oxygen species (ROS).^[1][6][22] It is difficult to say that rottlerin is a selective inhibitor of PKCδ since there are biological and biochemical processes that are PKCδ –independent that may affect outcomes.^{[1][5][6][22]} A proposed mechanism of why rottlerin was found to inhibit PKCδ is that it decreased ATP levels and can block PKCδ tyrosine phosphorylation and activation.^[1]

The Kamala tree, also known as Mallotus philippensis, grows in Southeast Asia.^[19] The fruit of this tree is covered with a red powder called kamala, and is used locally to make dye for textiles, syrup and used as an old remedy for tape-worm, because it has a laxative effect.^[23] Other uses include afflictions with the skin, eye diseases, bronchitis, abdominal disease, and spleen enlargement but scientific evidence is not present.^[24]