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Current metabolomics approaches utilize cellular metabolite extracts, are destructive, and require high cell numbers. We introduce here an approach that enables the monitoring of cellular metabolism at lower cell numbers by observing the consumption/production of different metabolites over several kinetic data points of up to 48 hours. Our approach does not influence cellular viability, as we optimized the cellular matrix in comparison to other materials used in a variety of in‐cell NMR spectroscopy experiments. We are able to monitor real‐time metabolism of primary patient cells, which are extremely sensitive to external stress. Measurements are set up in an interleaved manner with short acquisition times (approximately 7 minutes per sample), which allows the monitoring of up to 15 patient samples simultaneously. Further, we implemented our approach for performing tracer‐based assays. Our approach will be important not only in the metabolomics fields, but also in individualized diagnostics.
Current metabolomics approaches utilize cellular metabolite extracts, are destructive, and require high cell numbers. We introduce here an approach that enables the monitoring of cellular metabolism at lower cell numbers by observing the consumption/production of different metabolites over several kinetic data points of up to 48 hours. Our approach does not influence cellular viability, as we optimized the cellular matrix in comparison to other materials used in a variety of in‐cell NMR spectroscopy experiments. We are able to monitor real‐time metabolism of primary patient cells, which are extremely sensitive to external stress. Measurements are set up in an interleaved manner with short acquisition times (approximately 7 minutes per sample), which allows the monitoring of up to 15 patient samples simultaneously. Further, we implemented our approach for performing tracer‐based assays. Our approach will be important not only in the metabolomics fields, but also in individualized diagnostics.
Systematic protein localization and protein-protein interaction studies to characterize specific protein functions are most effectively performed using tag-based assays. Ideally, protein tags are introduced into a gene of interest by homologous recombination to ensure expression from endogenous control elements. However, inefficient homologous recombination makes this approach difficult in mammalian cells. Although gene targeting efficiency by homologous recombination increased dramatically with the development of designer endonuclease systems such as CRISPR/Cas9 capable of inducing DNA double-strand breaks with unprecedented accuracy, the strategies still require synthesis or cloning of homology templates for every single gene. Recent developments have shown that endogenous protein tagging can be achieved efficiently in a homology independent manner. Hence, combinations between CRISPR/Cas9 and generic tag-donor plasmids have been used successfully for targeted gene modifications in mammalian cells. Here, we developed a tool kit comprising a CRISPR/Cas9 expression vector with several EGFP encoding plasmids that should enable tagging of almost every protein expressed in mammalian cells. By performing protein-protein interaction and subcellular localization studies of mTORC1 signal transduction pathway-related proteins expressed in HEK293T cells, we show that tagged proteins faithfully reflect the behavior of their native counterparts under physiological conditions.
Autophagy is the highly conserved catabolic process, which enables the survival of a cell under unfavorable environmental conditions. In a constantly changing environment, cells must be capable of dynamically oscillating between anabolism and catabolism in order to maintain cellular homeostasis. In this context, the activity of the mechanistic Target Of Rapamycin Complex 1 (mTORC1) is of major importance. As a central signaling node, it directly controls the process of macroautophagy and thus cellular metabolism. Thereby, the control of mTORC1 is equally crucial as the regulation of cellular homeostasis itself, whereby particular importance is attributed to amino acid sensory proteins. In this review, we describe the recent findings of macroautophagy and mTORC1 regulation by upstream amino acid stimuli in different subcellular localizations. We highlight in detail which proteins of the sensor complexes play a specific role in this regulation and point out additional non-canonical functions, e.g. in the regulation of macroautophagy, which have received little attention so far.
Myelodysplastic syndrome (MDS) and acute myeloid leukemia (AML) are clonal hematopoietic stem cell diseases leading to an insufficient formation of functional blood cells. Disease-immanent factors as insufficient erythropoiesis and treatment-related factors as recurrent treatment with red blood cell transfusions frequently lead to systemic iron overload in MDS and AML patients. In addition, alterations of function and expression of proteins associated with iron metabolism might are increasingly recognized to be pathogenetic factors and potential vulnerabilities of these diseases. Iron is known to be involved in multiple intracellular and extracellular processes. It is essential for cell metabolism as well as for cell proliferation and closely linked to the formation of reactive oxygen species. Therefore, iron can influence the course of clonal myeloid disorders, the leukemic environment and the occurrence as well as the defense of infections. Imbalances of iron homeostasis may induce cell death of normal but also of malignant cells. New potential treatment strategies utilizing the importance of the iron homeostasis include iron chelation, modulation of proteins involved in iron metabolism, induction of leukemic cell death via ferroptosis and exploitation of iron proteins for the delivery of antileukemic drugs.
Here, we provide a summary of some of the latest findings about the function, the prognostic impact and potential treatment strategies of iron in patients with MDS and AML.
Cell-cell adhesion is an essential process during the development of multicellular organisms. It is based on various cellular junctions and ensures a tight contact between neighboring cells, enabling interactive exchanges necessary for morphological and functional differentiation and maintaining the homeostasis of healthy tissue organization. Two important types of cell-cell adhesions are the adherens junction (AJ) and the desmosome which link the actin cytoskeleton and intermediate filaments to cadherin-based adhesion sites. The core of these structures is composed of single-span transmembrane proteins of the cadherin superfamily which include, among other members, the classical cadherins, e.g. E-cadherin, as well as the desmosomal cadherins, e.g. desmoglein-3. The cytoplasmic domains of the desmosomal and classical cadherins enable interactions with proteins of the catenin family. Classical cadherins preferentially associate with β-catenin and p120-catenin, whereas desmosomal cadherins bind to γ-catenin and plakophilins. Intriguingly, γ-catenin, also known as plakoglobin, is so far the only protein known to be present both in the AJ and the desmosome.
In this study, we showed that the two homologous, membrane raft-associated proteins flotillin-1 and flotillin-2 associate with core proteins of the AJ and the desmosome in vitro and in vivo. In confluent human, non-malignant epithelial MCF10A cells and human skin cryosections, flotillin-2 colocalized with E-cadherin, desmoglein-3 and γ-catenin at cell-cell contact sites, whereas flotillin-1 showed barely any overlap with these proteins. In addition, we detected a colocalization of both flotillins with the actin-binding protein α-actinin in membrane ruffles in subconfluent and at cell-cell contact sites in confluent MCF10A cells as well as in human skin cryosections. The interaction with α-actinin was later shown to be flotillin-1 dependent by performing indirect GST pulldown experiments with purified α-actinin-1-GST in MCF10A cell lysates.
Since flotillin-2 strongly colocalized with cell-cell junctions, this suggested that flotillins might be found in complex with cell adhesion proteins. Thus, we performed coimmunoprecipitation experiments in murine skin lysates and various cell lines of epithelial origin, such as human breast cancer MCF7 cells, human keratinocyte HaCaT cells and primary mouse keratinocytes. These experiments demonstrated that flotillins, especially flotillin-2, coprecipitated with E-cadherin, desmosomal cadherins and γ-catenin in relation to the respective cell type and the maturation status of these cell-cell adhesion structures. However, since γ-catenin is so far the only protein known to be present in the AJ and the desmosome, we further assumed that the complex formation of flotillins with cell adhesion structures is mediated by γ-catenin. For this, we performed indirect GST pulldown experiments in MCF10A cell lysates with bacterially expressed, purified flotillin-1-GST, flotillin-2-GST and γ-catenin-GST and were able to verify the complex formation of adhesion proteins and flotillins in vitro. To further test if the interaction of γ-catenin and flotillins is a direct one, we used purified flotillin-1-GST or flotillin-2-GST and γ-catenin-MBP fusion proteins. Both flotillins directly interacted with γ-catenin in this in vitro assay. In addition, mapping of the interaction domains in γ-catenin by using GST fusion proteins carrying different parts of γ-catenin suggested that flotillins bind to a discontinuous γ-catenin binding domain which consists of a Major determinant around ARM domains 6-12, most likely with a major contribution of the ARM domain 7, and possibly including the NT part of γ-catenin.
To study the effect of flotillin depletion on cell-cell adhesion, we generated stable MCF10A cell lines in which flotillins were knocked down by means of lentiviral shRNAs. Staining of E-cadherin and γ-catenin in these cells showed that the localization at the cell-cell borders was significantly altered after flotillin-2 depletion, which pointed to a role for flotillin-2 in the formation of cell-cell adhesion structures in epithelial cells. Furthermore, isolation of detergent resistant membranes (DRMs) from these cells demonstrated that upon depletion of flotillin-2, a significant amount of E-cadherin and γ-catenin shifted into raft fractions. On the contrary, no change was detected in flotillin-1 knockdown cells. These observations point to a functional role of flotillin-2 in the regulation of raft association of cell-cell adhesion proteins. To gain more insight into the in vivo relevance of our findings, we next studied the function of flotillins in the skin of Flot2-/- knockout mice. Analysis of lysates prepared from the skin of one year old female animals revealed an increased expression of E-cadherin, desmoglein-1 and γ-catenin but not β-catenin, implicating that specific adhesion proteins are upregulated in flotillin-2 knockout skin.
Since flotillins are tightly associated with membrane microdomains we next studied the interaction of flotillin-2 with membrane cholesterol. Using the photoreactive cholesterol analog azocholestanol, we were able to show that flotillin-2 and cholesterol directly interacted. In addition, previous studies speculated that flotillin-2 interacts with cholesterol via two putative cholesterol recognition/interaction amino acid consensus (CRAC) motifs. Analysis of the flotillin-2 sequence revealed that flotillin-2 actually contains four putative CRAC motifs. However, using various flotillin-2 CRAC mutant GFP fusion proteins, we were able to show that none of the putative CRAC motifs is functional, which suggested that flotillin-2 interacts with membrane cholesterol, e.g., via posttranslational modifications, such as myristoylation and palmitoylation which were previously shown to be essential for membrane association of flotillin proteins.
Cell–matrix adhesion and cell migration are physiologically important processes that also play a major role in cancer spreading. In cultured cells, matrix adhesion depends on integrin-containing contacts such as focal adhesions. Flotillin-1 and flotillin-2 are frequently overexpressed in cancers and are associated with poor survival. Our previous studies have revealed a role for flotillin-2 in cell–matrix adhesion and in the regulation of the actin cytoskeleton. We here show that flotillins are important for cell migration in a wound healing assay and influence the morphology and dynamics of focal adhesions. Furthermore, anchorage-independent growth in soft agar is enhanced by flotillins. In the absence of flotillins, especially flotillin-2, phosphorylation of focal adhesion kinase and extracellularly regulated kinase is diminished. Flotillins interact with α-actinin, a major regulator of focal adhesion dynamics. These findings are important for understanding the molecular mechanisms of how flotillin overexpression in cancers may affect cell migration and, especially, enhance metastasis formation.
Tyrosine kinase inhibitors (TKIs) are currently the standard chemotherapeutic agents for the treatment of chronic myeloid leukemia (CML). However, due to TKI resistance acquisition in CML patients, identification of new vulnerabilities is urgently required for a sustained response to therapy. In this study, we have investigated metabolic reprogramming induced by TKIs independent of BCR-ABL1 alterations. Proteomics and metabolomics profiling of imatinib-resistant CML cells (ImaR) was performed. KU812 ImaR cells enhanced pentose phosphate pathway, glycogen synthesis, serine-glycine-one-carbon metabolism, proline synthesis and mitochondrial respiration compared with their respective syngeneic parental counterparts. Moreover, the fact that only 36% of the main carbon sources were utilized for mitochondrial respiration pointed to glycerol-phosphate shuttle as mainly contributors to mitochondrial respiration. In conclusion, CML cells that acquire TKIs resistance present a severe metabolic reprogramming associated with an increase in metabolic plasticity needed to overcome TKI-induced cell death. Moreover, this study unveils that KU812 Parental and ImaR cells viability can be targeted with metabolic inhibitors paving the way to propose novel and promising therapeutic opportunities to overcome TKI resistance in CML.
Measuring NADPH oxidase (Nox)-derived reactive oxygen species (ROS) in living tissues and cells is a constant challenge. All probes available display limitations regarding sensitivity, specificity or demand highly specialized detection techniques. In search for a presumably easy, versatile, sensitive and specific technique, numerous studies have used NADPH-stimulated assays in membrane fractions which have been suggested to reflect Nox activity. However, we previously found an unaltered activity with these assays in triple Nox knockout mouse (Nox1-Nox2-Nox4-/-) tissue and cells compared to wild type. Moreover, the high ROS production of intact cells overexpressing Nox enzymes could not be recapitulated in NADPH-stimulated membrane assays. Thus, the signal obtained in these assays has to derive from a source other than NADPH oxidases. Using a combination of native protein electrophoresis, NADPH-stimulated assays and mass spectrometry, mitochondrial proteins and cytochrome P450 were identified as possible source of the assay signal. Cells lacking functional mitochondrial complexes, however, displayed a normal activity in NADPH-stimulated membrane assays suggesting that mitochondrial oxidoreductases are unlikely sources of the signal. Microsomes overexpressing P450 reductase, cytochromes b5 and P450 generated a NADPH-dependent signal in assays utilizing lucigenin, L-012 and dihydroethidium (DHE). Knockout of the cytochrome P450 reductase by CRISPR/Cas9 technology (POR-/-) in HEK293 cells overexpressing Nox4 or Nox5 did not interfere with ROS production in intact cells. However, POR-/- abolished the signal in NADPH-stimulated assays using membrane fractions from the very same cells. Moreover, membranes of rat smooth muscle cells treated with angiotensin II showed an increased NADPH-dependent signal with lucigenin which was abolished by the knockout of POR but not by knockout of p22phox. In conclusion: the cytochrome P450 system accounts for the majority of the signal of Nox activity chemiluminescence based assays.
Hypoxia poses a stress to cells and decreases mitochondrial respiration, in part by electron transport chain (ETC) complex reorganization. While metabolism under acute hypoxia is well characterized, alterations under chronic hypoxia largely remain unexplored. We followed oxygen consumption rates in THP-1 monocytes during acute (16 h) and chronic (72 h) hypoxia, compared to normoxia, to analyze the electron flows associated with glycolysis, glutamine, and fatty acid oxidation. Oxygen consumption under acute hypoxia predominantly demanded pyruvate, while under chronic hypoxia, fatty acid- and glutamine-oxidation dominated. Chronic hypoxia also elevated electron-transferring flavoproteins (ETF), and the knockdown of ETF–ubiquinone oxidoreductase lowered mitochondrial respiration under chronic hypoxia. Metabolomics revealed an increase in citrate under chronic hypoxia, which implied glutamine processing to α-ketoglutarate and citrate. Expression regulation of enzymes involved in this metabolic shunting corroborated this assumption. Moreover, the expression of acetyl-CoA carboxylase 1 increased, thus pointing to fatty acid synthesis under chronic hypoxia. Cells lacking complex I, which experienced a markedly impaired respiration under normoxia, also shifted their metabolism to fatty acid-dependent synthesis and usage. Taken together, we provide evidence that chronic hypoxia fuels the ETC via ETFs, increasing fatty acid production and consumption via the glutamine-citrate-fatty acid axis.