Thermogenesis | EPFL Graph Search

Thermogenesis is the process of heat production in organisms. It occurs in all warm-blooded animals, and also in a few species of thermogenic plants such as the Eastern skunk cabbage, the Voodoo lily (Sauromatum venosum), and the giant water lilies of the genus Victoria. The lodgepole pine dwarf mistletoe, Arceuthobium americanum, disperses its seeds explosively through thermogenesis. Depending on whether or not they are initiated through locomotion and intentional movement of the muscles, thermogenic processes can be classified as one of the following: Exercise-associated thermogenesis (EAT) Non-exercise activity thermogenesis (NEAT), energy expended for everything that is not sleeping, eating or sports-like exercise. Diet-induced thermogenesis (DIT) One method to raise temperature is through shivering. It produces heat because the conversion of the chemical energy of ATP into kinetic energy causes almost all of the energy to show up as heat. Shivering is the process by which the body temperature of hibernating mammals (such as some bats and ground squirrels) is raised as these animals emerge from hibernation. Non-shivering thermogenesis occurs in brown adipose tissue (brown fat) that is present in almost all eutherians (swine being the only exception currently known). Brown adipose tissue has a unique uncoupling protein (thermogenin, also known as uncoupling protein 1) that allows the uncoupling of protons (H+) moving down their mitochondrial gradient from the synthesis of ATP, thus allowing the energy to be dissipated as heat. The atomic structure of human uncoupling protein 1 UCP1 has been solved by cryogenic-electron microscopy. The structure has the typical fold of a member of the SLC25 family. UCP1 is locked in a cytoplasmic-open state by guanosine triphosphate in a pH-dependent manner, preventing proton leak. In this process, substances such as free fatty acids (derived from triacylglycerols) remove purine (ADP, GDP and others) inhibition of thermogenin, which causes an influx of H+ into the matrix of the mitochondrion and bypasses the ATP synthase channel.

Deciphering the astrocyte-neuron metabolic cooperation in vivo

Manuel Raphael Zenger

Brain energy consumption is high and a very tightly regulated energy metabolism ensures correct performance. Neurons, the cells responsible for transmitting information via synapses, interact very closely with star shaped glial cells called astrocytes. Astrocytes play a pivotal role in the regulation of brain energy metabolism and for neurotransmission. Especially, in the case of glutamate, the main excitatory neurotransmitter in the brain, astrocytes are contributing to the clearing of otherwise potentially toxic levels of glutamate in the synaptic cleft. In addition, astrocytes are capable of providing neurons with lactate, which can be used as an additional source of energy in periods of increased demand, such as during neurotransmission. Lactate released by astrocytes is also a signal for neuronal plasticity. In this work, we addressed different aspects of the astrocyte-neuron metabolic coupling. Uncoupling proteins (UCPs) are proteins of the inner mitochondrial membrane that are capable of dissipating a proton gradient (uncoupling ATP production from respiration). Five different UCP isoforms have been described. UCP1 is essentially found in brown adipose tissue and is implicated in non-shivering thermogenesis, UCP2 is widely expressed and protecting against reactive oxygen species and UCP3 is mainly expressed in skeletal muscle tissue where a possible role in fatty acid metabolism has been described. UCP4 and 5 are essentially expressed in the brain, but their precise function still needs to be determined. In the present study, we showed that in neurons, UCP4 and UCP5 are predominantly expressed, as compared to the other UCPs. In astrocytes, UCP5 is the most abundant isoform, but also UCP2 and 4 are significantly expressed indicating an important role for these three UCPs in astrocytes. The role of UCP4 was further elucidated. For this purpose, a lentiviral overexpressing UCP4 construct was produced and characterized. This construct overexpressing UCP4 at the mitochondria allowed to demonstrate a neuro-protective role of UCP4 expression in astrocytes. In a complementary approach to study neuron-astrocyte metabolic coupling, the role of different astrocytic and neuronal genes in memory and learning was explored in a spatial learning paradigm. Mice were trained 1 to 9 days in a radial maze. The gene analysis showed that genes involved in lactate production and utilization such as lactate dehydrogenases were highly increased. A gene involved in the shuttling of lactate from astrocytes to neurons, such as monocarboxylate transporter 1 was also upregulated. An unexpected decrease in glucose transporter 1 and decrease in hexokinase 2 expression were observed. Finally, genes involved in glycogen metabolism were upregulated. Na+/K+-ATPase alpha2 isoform (ATP1A2), which plays a key role in re-establishing Na+ homeostasis disrupted by the co-transport of Na+ along with glutamate during glutamate uptake, was upregulated following spatial learning. Using a lentiviral transgenesis method, an attempt was made to downregulate the expression of the ATP1A2 in vivo. However, this technique did not allow us to produce sufficient knock down to study the role of ATP1A2 in vivo. Preliminary data for an alternative method are shown. Overall, the set of results presented here provides additional support for the existence of a dynamically regulated neuron-astrocyte metabolic coupling.

EPFL2015

Lentiviral Transgenesis as a Tool to Study the Role of Uncoupling Protein Isoforms in the Nervous System

Hélène Danielle Perreten Lambert

A tight coupling exists between synaptic activity and glucose utilization by astrocytes. Metabolic cooperation between neurons and astrocytes mediates this coupling. During synaptic activation, glutamate that is released in the synaptic cleft as a neurotransmitter by neurons is rapidly cleared by an active uptake into astrocytes. One glutamate is co-transported with three Na+. Intracellular astrocytic Na+ homeostasis is re-established by the Na+/K+-ATPase which requires ATP provided mainly by glycolysis. The resulting lactate is released in extracellular space and contributes to the energetic balance of activated neurons. This coupling between astrocytes and neurons is known as the astrocyte-neuron lactate shuttle hypothesis (ANLSH). The role of mitochondria in this coupling remains to be determined and more specifically the role of uncoupling proteins (UCP) which have been recently identified in neural tissues. UCPs belong to a family of mitochondrial carriers which are present in the inner mitochondrial membrane. There are five isoforms named UCP1 to UCP5. The well-known characterized is UCP1, also named thermogenin, which is present in the brown adipose tissue (BAT) of the small rodents and is responsible of non-shivering thermogenesis. It dissipates the proton gradient across the inner mitochondrial membrane, thereby producing heat instead of ATP. UCP2 is ubiquitous and is implicated in protection against excessive reactive oxygen (ROS) production. The expression of UCP3 is restricted to skeletal muscle where it is linked to fatty acid metabolism. The role of the brain isoforms UCP4 and UCP5 is still poorly understood. Initially, we set out to evaluate their function in energy metabolism of astrocytes and neurons. We used the lentiviral strategy to overexpress or silence the UCPs isoforms in primary cultures of astrocytes and neurons. We found that only UCP4 and UCP5 had an uncoupling activity in brain cells. Indeed, we observed a reduced mitochondrial potential and a reduced ATP/ADP ratio in astrocytes as well as in neurons overexpressing UCP4 or UCP5. UCP4 reduced the oxidative pathway of astrocytes without modifying the basal glucose metabolism and without having a lethal effect on the cell. Oxygen consumption rate (OCR) of brain cells ovexpressing UCPs was reduced. Moreover, UCP4 increased lactate release by astrocytes, suggesting an implication in the astrocyte-neuron coupling. We also brought evidence that both UCP4 and UCP5 partially protect brain cells from oxidative damage. All these results were confirmed by experiments on UCPs silencing. In a second step, we used a co-culture model to study the impact of astrocytic uncoupling protein on neuronal survival and we demonstrated that the presence of uncoupling protein in astrocytes prevents neuronal death after glutamate excitotoxicity. Taken together, all these results support an important role of uncoupling proteins in the regulation of astrocytic energy production, thus promoting local export of lactate which can be used by neurons.

EPFL2011