Lactate dehydrogenase | EPFL Graph Search

Lactate dehydrogenase (LDH or LD) is an enzyme found in nearly all living cells. LDH catalyzes the conversion of pyruvate to lactate and back, as it converts NAD+ to NADH and back. A dehydrogenase is an enzyme that transfers a hydride from one molecule to another. LDH exists in four distinct enzyme classes. This article is specifically about the NAD(P)-dependent L-lactate dehydrogenase. Other LDHs act on D-lactate and/or are dependent on cytochrome c: D-lactate dehydrogenase (cytochrome) and L-lactate dehydrogenase (cytochrome). LDH is expressed extensively in body tissues, such as blood cells and heart muscle. Because it is released during tissue damage, it is a marker of common injuries and disease such as heart failure. Reaction Lactate dehydrogenase catalyzes the interconversion of pyruvate and lactate with concomitant interconversion of NADH and NAD+. It converts pyruvate, the final product of glycolysis, to lactate when oxygen is absent or in short supply, an

Multidisciplinary Analysis of the Metabolic Shift to Lactate Consumption in CHO Cell Culture

Francesca Zagari

Mammalian cells represent the most widely used host system for the industrial production of recombinant therapeutic proteins. In order to increase productivity, chemically defined media are often used and optimized to provide the cells with the necessary nutrients. However, a deregulated cell metabolism is often observed in these culture conditions. In particular, carbon sources are fast and inefficiently consumed with a consequent accumulation of byproducts, mainly lactate and ammonia. Lactate, in particular, causes a decrease of the medium pH which can be detrimental for cells growth and productivity. Its metabolic profile is normally characterized by a first production phase, which is associated to the cells exponential growth. Afterwards, when the cells enter into the stationary phase, a shift to net lactate consumption can occur under optimal culture conditions. However, such a metabolic shift is not easily controlled, since the mechanisms modulating lactate production in cell culture are still under investigation. This work aims to understand which factors could influence the lactate metabolic shift in CHO cell culture, focusing, in particular, on the mitochondrial role. To this purpose, cell lines with opposite lactate profiles were compared. The initial lactate production phase was common to all the fast growing cultures and was concomitant to a rapid glutamine consumption. After glutamine depletion, two different scenario occurred. In one case, the cells started to consume lactate until complete depletion. Alternatively, lactate continued to be accumulated, causing a decrease of media pH. The mitochondrial oxidative capacity was hypothesized as a possible cause of the different lactate profile. Indeed, mitochondrial membrane potential and oxygen consumption measurements highlighted a correlation between a reduced oxidative metabolism and a state of high lactate production. This correlation was confirmed by evaluating other cell lines or media compositions which resulted in the same divergence of lactate metabolism. Afterwards, the expression of selected genes was analysed in correlation with the observed lactate profile. Among 22 genes, two were identified as significantly downregulated (absolute fold change ≥2) in conditions of high lactate accumulation; namely, the mitochondrial aspartate-glutamate carrier (aralar1) and the translocase of the inner mitochondrial membrane 8 (timm8a). Aralar1, in particular, is an important component of the malate-aspartate shuttle (MAS). This system promotes the recycling of the cytosolic NADH pool, which is necessary for maintaining the glycolytic flux. Alternatively, NADH can be oxidised through pyruvate conversion into lactate, catalysed by the lactate dehydrogenase enzyme. Therefore, an inefficient MAS activity can engender an increased lactate accumulation. Finally, stable cell lines, which overexpressed aralar1 or timm8a, were generated. Clones derived from a lactate-producing cell line showed an improvement of lactate metabolism. In particular, they switched more easily to lactate consumption compared to the untransfected control, while maintaining a similar glucose consumption rate. On the other hand, no impact of the transgene expression was observed in the clones derived from the lactate-consuming cell line, since the switch to lactate consumption was maintained and no other effect on cell growth or glucose metabolism was detected. The data obtained indicate that lactate consumption was most likely promoted by a better NADH oxidation through the malate-aspartate shuttle, which resulted in a more efficient link between glycolysis and the mitochondrial oxidative metabolism. In conclusion, the results presented in this thesis indicate that the mitochondrial oxidative capacity plays a central role in the control of lactate production. Media composition and intrinsic cell characteristics have both an impact on mitochondrial activity. Moreover, the expression of specific genes can also be influenced by the culture media. In particular, aralar1 and timm8a have been identified as promising targets for the generation of a host cell line with an improved lactate metabolism.

EPFL2012

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

Modulation of astrocytic metabolic phenotype by proinflammatory cytokines

Igor Allaman, Pierre Magistretti

Astrocytes play an important role in nervous system homeostasis. In particular, they contribute to the regulation of local energy metabolism and to oxidative stress defence. In previous experiments, we showed that long-term treatment with interleukin 1alpha (IL-1alpha) or tumor necrosis factor-alpha (TNFalpha) alone increases glucose utilization in primary culture of mouse astrocytes. In our study, we report that a combination of IL-1beta and TNFalpha exerts a synergistic effect on glucose utilization and markedly modifies the metabolic phenotype of astrocytes. Thus, IL-1beta+TNFalpha treated astrocytes show a marked decrease in glycogen levels, a slight but not significant decrease in lactate release as well as a massive increase in both the pentose phosphate pathway and TCA cycle activities. Glutamate-stimulated glucose utilization and lactate release, a typical feature of astrocyte energy metabolism, are altered after pretreatment with IL-1beta+TNFalpha. As far as mechanisms for oxidative stress defence are concerned, we observed that treatment with IL-1beta+TNFalpha decreases cellular glutathione content and increases glutathione release into the extracellular space while stimulating superoxide anion and nitric oxide production as well as H(2)O(2) release. Interestingly, stimulation of glucose utilization by IL-1beta+TNFalpha is not affected by the antioxidant N-acetyl-L-cysteine, suggesting that cellular stress does not account for this effect. Finally, the effects of cytokines on glucose utilization appear to involve multiple signaling cascades including the phosphoinositide 3-kinase and mitogen-activated protein kinases. Taken together these results establish that a proinflammatory environment such as observed in several neuropathological conditions including Alzheimer's disease, markedly modifies the metabolic phenotype of astrocytes.

2008