Inhibition of lactic dehydrogenase: a possible strategy to improve the pharmacological treatment of hepatocellular carcinoma

Il lavoro svolto nel corso del mio dottorato ha avuto per oggetto lo studio dell’ inibizione della glicolisi aerobia (il principale processo metabolico utilizzato dalle cellule neoplastiche per produrre energia) ottenuta mediante il blocco dell’enzima lattato deidrogenasi (LDH). La mia attività si è concentrata sulla possibilità di utilizzare questo approccio allo scopo di migliorare l’efficacia della terapia antitumorale, valutandone gli effetti su colture di carcinoma epatocellulare umano Inizialmente, per valutare gli effetti della inibizione della LDH, è stato usato l’acido ossamico ( OXA). Questo composto è l’unico inibitore noto specifico per LDH ; è una molecola non tossica in vivo, ma attiva a concentrazioni troppo elevate per consentirne un uso terapeutico. Un importante risultato ottenuto è stata la dimostrazione che l’ inibizione della LDH ottenuta con OXA non è solo in grado di innescare una risposta di morte nelle cellule trattate, ma, associata alla somministrazione di sorafenib, aumenta fortemente l’efficacia di questo farmaco, determinando un effetto di sinergismo. Questo forte effetto di potenziamento dell’azione del farmaco è stato spiegato con la dimostrazione che il sorafenib ha la capacità di inibire il consumo di ossigeno delle cellule trattate, rendendole più dipendenti dalla glicolisi. Grazie alla collaborazione con il Dipartimento di Scienze Farmaceutiche il nostro gruppo di ricerca è arrivato alla identificazione di un composto (galloflavina) che inibisce la LDH con una efficienza molto maggiore di OXA. I risultati preliminari ottenuti sulle cellule di epatocarcinoma suggeriscono che la galloflavina potrebbe essere un composto promettente nel campo degli inibitori metabolici tumorali e inducono a una sua valutazione più approfondita come potenziale farmaco antineoplastico.The aim of this work was to study the inhibition of aerobic glycolysis (the main metabolic pathway used by cancer cells to produce energy) achieved by blocking the enzyme lactate dehydrogenase (LDH). My activity has focused on the possibility of using this approach in order to improve the efficacy of anticancer therapy, evaluating its effects on cultured human hepatocellular carcinoma. In order to evaluate the effects of LDH inhibition, in a first set of experiments, we used oxamic acid (OXA). This compound is the only known specific inhibitor of LDH; it is a non-toxic molecule in vivo, but it is active at too high concentrations to allow its therapeutic use. An important result was the demonstration that LDH inhibition achieved by OXA not only triggers cell death signals but, when combined with the administration of sorafenib, also greatly increases the efficacy of this drug, leading to a synergistic effect. This strong potentiating effect of the drug action has been explained with the demonstration that sorafenib has the ability to inhibit the oxygen consumption of the treated cells, making them more dependent on glycolysis for ATP generation. In collaboration with the Department of Pharmaceutical Sciences our research group has identified a compound (galloflavin) that inhibits LDH with much higher efficacy than OXA. To our knowledge, inhibition of LDH is the only biochemical effect described for galloflavin. According to the results obtained on hepatocarcinoma cultured cells, galloflavin might be a promising lead candidate in the field of tumor metabolic inhibitors, deserving a more exhaustive evaluation as a potential anticancer agent

LDH inhibition impacts on heat shock response and induces senescence of hepatocellular carcinoma cells

In normal cells, heat shock response (HSR) is rapidly induced in response to a variety of harmful conditions and represents one of the most efficient defense mechanism. In cancer tissues, constitutive activation converts HSR into a life-threatening process, which plays a major role in helping cell survival and proliferation. Overexpression of heat shock proteins (HSPs) has been widely reported in human cancers and was found to correlate with tumor progression. Hepatocellular carcinoma is one of the conditions in which HSR activation was shown to have the highest clinical significance. Transcription of HSPs is induced by HSF-1, which also activates glycolytic metabolism and increases the expression of LDH-A, the master regulator of the Warburg effect. In this paper, we tried to explore the relationship between HSR and LDH-A. In cultured hepatocellular carcinoma cells, by using two enzyme inhibitors (oxamate and galloflavin), we found that the reduction of LDH-A activity led to decreased level and function of the major HSPs involved in tumorigenesis. Galloflavin (a polyphenol) also inhibited the ATPase activity of two of the examined HSPs. Finally, hindering HSR markedly lowered the alpha-fetoprotein cellular levels and induced senescence. Specific inhibitors of single HSPs are currently under evaluation in different neoplastic diseases. However, one of the effects usually observed during treatment is a compensatory elevation of other HSPs, which decreases treatment efficacy. Our results highlight a connection between LDH and HSR and suggest LDH inhibition as a way to globally impact on this tumor promoting process

Altered glycosylation profile of purified plasma ACT from Alzheimer’s disease

Background Alzheimer\u2019s disease (AD) is one of the most frequent cause of neurodegenerative disorder in the elderly. Inflammation has been implicated in brain degenerative processes and peripheral markers of brain AD related impairment would be useful. Plasma levels of alpha-1-antichymotrypsin (ACT), an acute phase protein and a secondary component of amyloid plaques, are often increased in AD patients and high blood ACT levels correlate with progressive cognitive deterioration. During inflammatory responses changes in the micro-heterogeneity of ACT sugar chains have been described. Methods N-Glycanase digestion from Flavobacterium meningosepticum (PNGase F) was performed on both native and denatured purified ACT condition and resolved to Western blot with the purpose to revealed the ACT de-glycosylation pattern. Further characterization of the ACT glycan profile was obtained by a glycoarray; each lectin group in the assay specifically recognizes one or two glycans/epitopes. Lectin-bound ACT produced a glyco-fingerprint and mayor differences between AD and controls samples were assessed by a specific algorithms. Results Western blot analysis of purified ACT after PNGase F treatment and analysis of sugar composition of ACT showed significantly difference in \u201cglyco-fingerprints\u201d patterns from controls (CTR) and AD; ACT from AD showing significantly reduced levels of sialic acid. A difference in terminal GlcNac residues appeared to be related with progressive cognitive deterioration. Conclusions Low content of terminal GlcNac and sialic acid in peripheral ACT in AD patients suggests that a different pattern of glycosylation might be a marker of brain inflammation. Moreover ACT glycosylation analysis could be used to predict AD clinical progression and used in clinical trials as surrogate marker of clinical efficacy

Inhibition of lactate dehydrogenase activity as an approach to cancer therapy

In the attempt of developing innovative anticancer treatments, growing interest has recently focused on the peculiar metabolic properties of cancer cells. In this context, lactate dehydrogenase (LDH), which converts pyruvate to lactate at the end of glycolysis, is emerging as one of the most interesting molecular targets for the development of new inhibitors. In fact, because LDH activity is not needed for pyruvate metabolism through TCA cycle, inhibitors of this enzyme should spare glucose metabolism of normal non-proliferating cells, which usually completely degrade the glucose molecule to CO2. This review is aimed at summarizing the available data on LDH biology in normal and neoplastic cells, which are in support of the anticancer therapeutic approach based on LDH inhibition. These data encouraged Pharmaceutical Industries and Academic Institutions in the search of small molecule inhibitors and promising candidates have recently been identified. The availability of inhibitors with drug-like properties will allow to evaluate in the near future the real potential of LDH inhibition in anticancer treatment, also making possible the identification of the most responsive neoplastic conditions

Lactate dehydrogenase inhibition: Exploring possible applications beyond cancer treatment

Lactate dehydrogenase (LDH) inhibition is considered a worthwhile attempt in the development of innovative anticancer strategies. Unfortunately, in spite of the involvement of several research institutions and pharma-companies, the discovery of LDH inhibitors with drug-like properties seems a hardly resolvable challenge. While awaiting new advancements, in the present review we will examine other pathologic conditions characterized by increased glycolysis and LDH activity, which could potentially benefit from LDH inhibition. The rationale for targeting LDH activity in these contexts is the same justifying the LDH-based approach in anticancer therapy: because of the enzyme position at the end of glycolytic pathway, LDH inhibitors are not expected to hinder glucose metabolism of normal cells. Moreover, we will summarize the latest contributions in the discovery of enzyme inhibitors and try to glance over the reasons underlying the complexity of this research

The activation of lactate dehydrogenase induced by mTOR drives neoplastic change in breast epithelial cells.

mTOR kinase and the A isoform of lactate dehydrogenase (LDH-A) are key players controlling the metabolic characteristics of cancer cells. By using cultured human breast cells as a "metabolic tumor" model, we attempted to explore the correlation between these two factors. "Metabolic tumors" are defined as neoplastic conditions frequently associated with features of the metabolic syndrome, such as hyper-insulinemia and hyper-glycemia. MCF-7 cells (a well differentiated carcinoma) and MCF-10A cells (a widely used model for studying normal breast cell transformation) were used in this study. These cells were exposed to known factors triggering mTOR activation. In both treated cultures, we evaluated the link between mTOR kinase activity and the level of LDH expression / function. Furthermore, we elaborated the metabolic changes produced in cells by the mTOR-directed LDH-A up-regulation. Interestingly, we observed that in the non-neoplastic MCF-10A culture, mTOR-directed up-regulation of LDH-A was followed by a reprogramming of cell metabolism, which showed an increased dependence on glycolysis rather than on oxidative reactions. As a consequence, lactate production appeared to be enhanced and cells began to display increased self-renewal and clonogenic power: signals suggestive of neoplastic change. Enhanced clonogenicity of cells was abolished by rapamycin treatment, and furthermore heavily reduced by LDH enzymatic inhibition. These results highlighted a mechanistic link between metabolic alterations and tumorigenesis, whereby suggesting LDH inhibition as a possible chemo-preventive measure to target the metabolic alterations driving neoplastic change

Lactate dehydrogenase inhibitors can reverse inflammation induced changes in colon cancer cells

The inflammatory microenvironment is an essential component of neoplastic lesions and can significantly impact on tumor progression. Besides facilitating invasive growth, inflammatory cytokines were also found to reprogram cancer cell metabolism and to induce aerobic glycolysis. Previous studies did not consider the possible contribution played in these changes by lactate dehydrogenase (LDH). The A isoform of LDH (LDH-A) is the master regulator of aerobic glycolysis; it actively reduces pyruvate and causes enhanced lactate levels in tumor tissues. In cancer cells, lactate was recently found to directly increase migration ability; moreover, when released in the microenvironment, it can facilitate matrix remodeling. In this paper, we illustrate that treatment of human colon adenocarcinoma cells with TNF-α and IL-17, two pro-inflammatory cytokines, modifies LDH activity, causing a shift toward the A isoform which results in increased lactate production. At the same time, the two cytokines appeared to induce features of epithelial-mesenchymal transition in the treated cells, such as reduction of E-cadherin levels and increased secretion of metalloproteinases. Noteworthy, oxamate and galloflavin, two inhibitors of LDH activity which reduce lactate production in cells, were found to relieve the inflammation-induced effects. These results suggest LDH-A and/or lactate as common elements at the cross-road between cancer cell metabolism, tumor progression and inflammation. At present, LDH inhibitors suitable for clinical use are actively searched as possible anti-proliferative agents; our data lead to hypothesize for these compounds a wider potential in anticancer treatment

Altered glycosylation profile of purified plasma ACT from Alzheimer’s disease

Abstract Background Alzheimer’s disease (AD) is one of the most frequent cause of neurodegenerative disorder in the elderly. Inflammation has been implicated in brain degenerative processes and peripheral markers of brain AD related impairment would be useful. Plasma levels of alpha-1-antichymotrypsin (ACT), an acute phase protein and a secondary component of amyloid plaques, are often increased in AD patients and high blood ACT levels correlate with progressive cognitive deterioration. During inflammatory responses changes in the micro-heterogeneity of ACT sugar chains have been described. Methods N-Glycanase digestion from Flavobacterium meningosepticum (PNGase F) was performed on both native and denatured purified ACT condition and resolved to Western blot with the purpose to revealed the ACT de-glycosylation pattern. Further characterization of the ACT glycan profile was obtained by a glycoarray; each lectin group in the assay specifically recognizes one or two glycans/epitopes. Lectin-bound ACT produced a glyco-fingerprint and mayor differences between AD and controls samples were assessed by a specific algorithms. Results Western blot analysis of purified ACT after PNGase F treatment and analysis of sugar composition of ACT showed significantly difference in “glyco-fingerprints” patterns from controls (CTR) and AD; ACT from AD showing significantly reduced levels of sialic acid. A difference in terminal GlcNac residues appeared to be related with progressive cognitive deterioration. Conclusions Low content of terminal GlcNac and sialic acid in peripheral ACT in AD patients suggests that a different pattern of glycosylation might be a marker of brain inflammation. Moreover ACT glycosylation analysis could be used to predict AD clinical progression and used in clinical trials as surrogate marker of clinical efficacy.</p

Metabolic activation triggered by cAMP in MCF-7 cells generates lethal vulnerability to combined oxamate/etomoxir

Altered energy metabolism is a biochemical fingerprint of cancer cells, widely recognized as one of the "hallmarks of cancer". Cancer cells show highly increased rates of glucose uptake and glycolysis, after which the resulting pyruvate is converted to lactate. The maintenance of this metabolic asset is warranted by lactate dehydrogenase A (LDH-A) and for this reason the development of novel LDH-targeted anticancer therapeutics is underway. However, possible interference in cancer cell metabolism could also arise from cAMP signaling pathway, which could be activated by either oncogenic induction or exogenously, as a result of microenvironment-derived stimuli, increasing cellular cAMP levels. This study aimed at evaluating the impact of activated cAMP signaling pathway on the efficacy of an LDH-targeted anticancer approach