Carlos J. Ciudad

Glycogen synthase: a new activity ratio assay expressing a high sensitivity to the phosphorylation state.

Since its introduction [I] the -glucose 6-phosphate/t glucose 6-phosphate (-G6P/tG6P) activity ratio assay for glycogen synthase has been a very useful tool in the study of the activation state of this enzyme. The idea of glycogen synthase in two forms (one active in the absence of added G6P (I form), the other requiring it for activity (D form)) evolved from the first experiments in which the -G6P/tG6P assay was employed [ 11. Shortly afterwards changes in the -G6P/tG6P activity ratio were correlated with phosphorylation and dephosphorylation of the enzyme [2]. At concentrations of metabolites close to their physiological levels it was shown [3] that the D form would be inactive whereas the I form would be active. Therefore conversion between D and I forms (i.e., changes in the -G6P/+G6P activity ratio) would correspond to changes in the ‘in vivo’ activity. Nevertheless, in physiological experiments rather small changes in the -G6P/tG6P activity ratio had been observed in response to the administration of hormones. These modest changes in the -G6P/tG6P activity ratio were rather hard to reconcile with an on-off control of glycogen synthase activity (reviewed [41). The enzyme has been shown to have a multiple phosphorylated subunit [5-l I] and that phosphorylation produces pronounced effects on the apparent affinity of the enzyme for its substrate UDP-glucose and the activator glucose 6-phosphate [7,11-131. In [ 131 we have demonstrated that when glycogen

Pentose phosphate cycle oxidative and nonoxidative balance: A new vulnerable target for overcoming drug resistance in cancer.

The metabolic network of cancer cells confers adaptive mechanisms against many chemotherapeutic agents, but also presents critical constraints that make the cells vulnerable to perturbation of the network due to drug therapy. To identify these fragilities, combination therapies based on targeting the nucleic acid synthesis metabolic network at multiple points were tested. Results showed that cancer cells overcome single hit strategies through different metabolic network adaptations, demonstrating the robustness of cancer cell metabolism. Analysis of these adaptations also identified the maintenance of pentose phosphate cycle oxidative and nonoxidative balance to be critical for cancer cell survival and vulnerable to chemotherapeutic intervention. The vulnerability of cancer cells to the imbalance on pentose phosphate cycle was demonstrated by phenotypic phase plane analysis.

Inhibition of cancer cell growth by ruthenium(II) cyclopentadienyl derivative complexes with heteroaromatic ligands

Inhibition of the growth of LoVo human colon adenocarcinoma and MiaPaCa pancreatic cancer cell lines by two new organometallic ruthenium(II) complexes of general formula [Ru(eta(5)-C(5)H(5))(PP) L][CF(3)SO(3)], where PP is 1,2-bis(diphenylphosphino)ethane and L is 1,3,5-triazine (Tzn) 1 or PP is 2x triphenylphosphine and L is pyridazine (Pyd) 2 has been investigated. Crystal structures of compounds 1 and 2 were determined by X-ray diffraction studies. Atomic force microscopy (AFM) images suggest different mechanisms of interaction with the plasmid pBR322 DNA; while the mode of binding of compound 1 could be intercalation between base pairs of DNA, compound 2 might be involved in a covalent bond formation with N from the purine base.

Up-regulation of the Kv3.4 potassium channel subunit in early stages of Alzheimer's disease.

Gene expression throughout the different stages of Alzheimers disease was analysed in samples from cerebral cortex. The gene encoding the voltage‐gated potassium channel Kv3.4 was already overexpressed in early stages of the disease, and in advanced stages Kv3.4 was present at high levels in neurodegenerative structures. This subunit regulates delayed‐rectifier currents, which are primary determinants of spike repolarization in neurones. In unique samples from a patient with Alzheimers disease whose amount of amyloid plaques was decreased by β amyloid immunization, Kv3.4 was overexpressed. The channel subunit was expressed in the neuropil, in the remaining conventional plaques in the frontal cortex and in collapsed plaques in the orbitary cortex. Therefore, amyloid deposition in plaques does not seem to be responsible for the increase in Kv3.4 levels. Nevertheless, Kv3.4 up‐regulation is related to amyloid pathology, given that transgenic mice with the Swedish mutation of amyloid precursor protein showed increased expression of Kv3.4. Up‐regulation of voltage‐gated potassium channel subunits alters potassium currents in neurones and leads to altered synaptic activity that may underlie the neurodegeneration observed in Alzheimers disease. Thus, Kv3.4 likely represents a novel therapeutic target for the disease.

Use of siRNAs and Antisense Oligonucleotides Against Survivin RNA to Inhibit Steps Leading to Tumor Angiogenesis

The antiapoptotic protein survivin is an attractive target in cancer therapy because it is expressed differently in tumors and normal tissues and it is potentially required for cancer cells to remain viable. Given that survivin is also overexpressed in endothelial cells (ECs) of newly formed blood vessels found in tumors, its RNA targeting might compromise EC viability and interfere with tumor angiogenesis. We used two antisense strategies against survivin expression, antisense oligonucleotides (aODN) and small interfering RNA (siRNA), to study in ECs the contribution of survivin in various steps leading to tumor angiogenesis. A 21-mer phosphorothioate aODN and two siRNA oligonucleotides against survivin mRNA were designed to downregulate survivin expression. Survivin targeting caused (1) a strong growth-inhibitory effect, (2) a 4-fold increase in apoptosis, (3) an accumulation of cells in the S phase and a decrease in G2/M phase, (4) a dose-dependent inhibition of EC migration on Vitronectin, and (5) a decrease in capillary formation. Control oligonucleotides, an unrelated oligonucleotide, and one with four mismatches, had no significant effect. All these results show that survivin is a suitable target in cancer therapy because its inhibition in EC causes both a proapoptotic effect and an interruption of tumor angiogenesis. The two strategies used, classic aODN and siRNA technology, were very effective. Moreover, the latter can be used in the low nanomolar range, thus increasing the sensitivity of the treatment.

Retinoblastoma protein associates with SP1 and activates the hamster dihydrofolate reductase promoter

The dihydrofolate reductase (dhfr) promoter is powerfully activated by the transcription factor Sp1. It has been suggested that Sp1 is a potential target for transcriptional regulation by the cell cycle regulator retinoblastoma protein (Rb), and so we have explored this possibility using the hamster dhfr gene as a model. By the use of DNA probes from the hamster dhfr gene promoter, containing the most proximal GC box (minimal promoter), and nuclear extracts from cultured hamster cells (CHO K1), we show that polyclonal and monoclonal antibodies against Rb supershift the binding of Sp1. Nuclear extract immunoprecipitation with anti-Rb followed by Western analysis using anti-Sp1 also shows that Rb is complexed to Sp1. Complementary Immunoprecipitation/WB analysis shows both forms of Rb protein in the anti-Sp1 immunoprecipitates. Moreover, nuclear extract immunodepletion of Rb abolishes Sp1 gel-shift. The interaction between Rb and Sp1 is maintained in all the phases of the cell cycle. Transient overexpression of Rb in dhfr negative cells co-transfected with a dhfr minigene driven by its minimal promoter increases DHFR activity and potentiates transcription when overexpressing Sp1. Both effects are severely reduced when the co-transfections are performed with a homologous dhfr minigene containing a single point mutation in the GC box. Thus, the activation by Rb of the dhfr gene may be exerted through Sp1. Stable transfectants of pCMVRb in K1 cells show an increase in both mRNA and DHFR activity. It is concluded that Sp1 is physically associated with Rb, and that this association increases Sp1-mediated transcription of the hamster dhfr gene.

Glucose has to be phosphorylated to activate glycogen synthase, but not to inactivate glycogen phosphorylase in hepatocytes

2‐Deoxyglucose and 5‐thioglucose, in the same fashion as glucose, cause the inactivation of the rat hepatocyte glycogen phosphorylase and the activation of glycogen synthase. However, 6‐deoxyglucose and 1,5‐anhydroglucitol inactivate phosphorylase without increasing the activation state of glycogen synthase. With 3‐O‐methylglucose no changes in the activity or these enzymes occurred. These results prove that while glucose is the molecule that triggers the inactivation of phosphorylase, glucose 6‐phosphate is the signal for glucose synthase activation and that a metabolite control of the activation state of glycogen synthase is operative in hepatocytes.

Regulation of Sp1 by cell cycle related proteins.

Sp1 transcription factor regulates the expression of multiple genes, including the Sp1 gene itself. We analyzed the ability of different cell cycle regulatory proteins to interact with Sp1 and to affect Sp1 promoter activity. Using an antibody array, we observed that CDK4, SKP2, Rad51, BRCA2 and p21 could interact with Sp1 and we confirmed these interactions by co-immunoprecipitation. CDK4, SKP2, Rad51, BRCA2 and p21 also activated the Sp1 promoter. Among the known Sp1-interacting proteins, E2F-DP1, Cyclin D1, Stat3 and Rb activated the Sp1 promoter, whereas p53 and NFkB inhibited it. The proteins that regulated Sp1 gene expression were shown by positive chromatin immunoprecipitation to be bound to the Sp1 promoter. Moreover, SKP2, BRCA2, p21, E2F-DP1, Stat3, Rb, p53 and NFkB had similar effects on an artificial promoter containing only Sp1 binding sites. Transient transfections of CDK4, Rad51, E2F-DP1, p21 and Stat3 increased mRNA expression from the endogenous Sp1 gene in HeLa cells whereas overexpression of NFkB, and p53 decreased Sp1 mRNA levels . p21 expression from a stably integrated inducible promoter in HT1080 cells activated Sp1 expression at the promoter and mRNA levels, but at the same time it decreased Sp1 protein levels due to the activation of Sp1 degradation. The observed multiple effects of cell cycle regulators on Sp1 suggest that Sp1 may be a key mediator of cell cycle associated changes in gene expression.

Underexpression of miR-224 in methotrexate resistant human colon cancer cells

MicroRNAs (miRNAs) are small non-coding RNAs involved in RNA silencing that play a role in many biological processes. They are involved in the development of many diseases, including cancer. Extensive experimental data show that they play a role in the pathogenesis of cancer as well as the development of drug resistance during treatments. The aim of this work was to detect differentially expressed miRNAs in MTX-resistant cells. Thus, miRNA microarrays of sensitive and MTX-resistant HT29 colon cancer cells were performed. The results were analyzed using the GeneSpring GX11.5 software. Differentially expressed miRNAs in resistant cells were identified and miR-224, which was one of the most differentially expressed miRNAs and with high raw signal values, was selected for further studies. The underexpression of miR-224 was also observed in CaCo-2 and K562 cells resistant to MTX. Putative targets were predicted using TargetScan 5.1 software and integrated with the data from expression microarrays previously performed. This approach allowed us to identify miR-224 targets that were differentially expressed more than 2-fold in resistant cells. Among them CDS2, DCP2, HSPC159, MYST3 and SLC4A4 were validated at the mRNA level by qRT-PCR. Functional assays using an anti-miR against miR-224 desensitized the cells towards MTX, mimicking the resistant phenotype. On the other hand, siRNA treatment against SLC4A4 or incubation of Poly Purine Reverse Hoogsteen (PPRH) hairpins against CDS2 or HSPC159 increased sensitivity to MTX. These results revealed a role for miR-224 and its targets in MTX resistance in HT29 colon cancer cells.

Therapeutic Targeting of Tumor Growth and Angiogenesis with a Novel Anti-S100A4 Monoclonal Antibody

S100A4, a member of the S100 calcium-binding protein family secreted by tumor and stromal cells, supports tumorigenesis by stimulating angiogenesis. We demonstrated that S100A4 synergizes with vascular endothelial growth factor (VEGF), via the RAGE receptor, in promoting endothelial cell migration by increasing KDR expression and MMP-9 activity. In vivo overexpression of S100A4 led to a significant increase in tumor growth and vascularization in a human melanoma xenograft M21 model. Conversely, when silencing S100A4 by shRNA technology, a dramatic decrease in tumor development of the pancreatic MiaPACA-2 cell line was observed. Based on these results we developed 5C3, a neutralizing monoclonal antibody against S100A4. This antibody abolished endothelial cell migration, tumor growth and angiogenesis in immunodeficient mouse xenograft models of MiaPACA-2 and M21-S100A4 cells. It is concluded that extracellular S100A4 inhibition is an attractive approach for the treatment of human cancer.