Stephen John Ralph scite author profile

To develop new and more efficient anti-cancer strategies it will be important to characterize the products of transcription factor activity essential for tumorigenesis. One such factor is hypoxia-inducible factor-1alpha (HIF-1alpha), a transcription factor induced by low oxygen conditions and found in high levels in malignant solid tumors, but not in normal tissues or slow-growing tumors. In fast-growing tumors, HIF-1alpha is involved in the activation of numerous cellular processes including resistance against apoptosis, over-expression of drug efflux membrane pumps, vascular remodeling and angiogenesis as well as metastasis. In cancer cells, HIF-1alpha induces over-expression and increased activity of several glycolytic protein isoforms that differ from those found in non-malignant cells, including transporters (GLUT1, GLUT3) and enzymes (HKI, HKII, PFK-L, ALD-A, ALD-C, PGK1, ENO-alpha, PYK-M2, LDH-A, PFKFB-3). The enhanced tumor glycolytic flux triggered by HIF-1alpha also involves changes in the kinetic patterns of expressed isoforms of key glycolytic enzymes. The HIF-1alpha induced isoforms provide cancer cells with reduced sensitivity to physiological inhibitors, lower affinity for products and higher catalytic capacity (Vmax(f)) in forward reactions because of marked over-expression compared to those isoforms expressed in normal tissues. Some of the HIF1alpha-induced glycolytic isoforms also participate in survival pathways, including transcriptional activation of H2B histone (by LDH-A), inhibition of apoptosis (by HKII) and promotion of cell migration (by ENO-alpha). HIF-1alpha action may also modulate mitochondrial function and oxygen consumption by inactivating the pyruvate dehydrogenase complex in some tumor types, or by modulating cytochrome c oxidase subunit 4 expression to increase oxidative phosphorylation in other cancer cell lines. In this review, the roles of HIF-1alpha and HIF1alpha-induced glycolytic enzymes are examined and it is concluded that targeting the HIF1alpha-induced glucose transporter and hexokinase, important to glycolytic flux control, might provide better therapeutic targets for inhibiting tumor growth and progression than targeting HIF1alpha itself.

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The causes of cancer revisited: “Mitochondrial malignancy” and ROS-induced oncogenic transformation – Why mitochondria are targets for cancer therapy

Ralph

Rodrı́guez-Enrı́quez

Neužil

et al. 2010

Molecular Aspects of Medicine

311

267

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Two novel protein-tyrosine kinases, each with a second phosphotransferase-related catalytic domain, define a new class of protein kinase.

et al. 1991

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The protein-tyrosine kinases (PTKs) are a burgeoning family of proteins, each of which bears a conserved domain of 250 to 300 amino acids capable of phosphorylating substrate proteins on tyrosine residues. We recently exploited the existence of two highly conserved sequence elements within the catalytic domain to generate PTK-specific degenerate oligonucleotide primers (A. F. Wilks, Proc. Natl. Acad. Sci. USA 86: [1603][1604][1605][1606][1607] 1989). By application of the polymerase chain reaction, portions of the catalytic domains of several novel PTKs were amplified. We describe here the primary sequence of one of these new PTKs, JAK1 (from Janus kinase), a member of a new class of PTK characterized by the presence of a second phosphotransferase-related domain immediately N terminal to the PTK domain. The second phosphotransferase domain bears all the hallmarks of a protein kinase, although its structure differs significantly from that of the PTK and threonine/ serine kinase family members. A second member of this family (JAK2) has been partially characterized and exhibits a similar array of kinase-related domains. JAK1 is a large, widely expressed membrane-associated phosphoprotein of approximately 130,000 Da. The PTK activity of JAK1 has been located in the C-terminal PTK-like domain. The role of the second kinaselike domain is unknown.Protein-tyrosine kinases (PTKs) are structurally well suited to a role in intracellular signal transduction. Many growth factor receptors, for example, transduce the extracellular stimulus they receive through interaction with their cognate ligand via an intracellular tyrosine kinase domain (5, 33, 52; reviewed in reference 60). Members of the PTK family each bear a highly related "catalytic" domain. The phylogenetic relationships established by an amino acid sequence comparison of the catalytic domains (10) are borne out in the overall structure of the PTKs. For example, families of PTKs, such as those based on the structure of the colony-stimulating factor-1 growth factor receptor (38) (including the two types of the platelet-derived growth factor receptor [4,58]) and the protooncogene c-kit [59]) and those clustered around the cytoplasmic PTKs c-src (29) (including HCK/bmk [12], LCK [28], and c-yes [42], among others) and c-fes (37) (including c-FER/flk [11,25]) each share the highest degree of identity with other members of their cluster and, in respect to their overall topology, are structurally more related to each other than to members of other classes of PTK. Hence, the recombination of the PTK catalytic domain with a wide variety of regulatory and other interactive domains suggests a strong evolutionary drive toward the rapid expansion of the use of its physiologically powerful catalytic activity. This combinatorial approach to the evolution of multidomain proteins such as the PTIK family predicts the extensive utilization of the basic tyrosine kinase domain in other metabolic niches.Application of the polymerase chain reaction (PCR) (32, 40) using degenerate PTK-spec...

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α-Tocopheryl succinate induces apoptosis by targeting ubiquinone-binding sites in mitochondrial respiratory complex II

et al. 2008

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a-Tocopheryl succinate (a-TOS) is a selective inducer of apoptosis in cancer cells, which involves the accumulation of reactive oxygen species (ROS). The molecular target of a-TOS has not been identified. Here, we show that a-TOS inhibits succinate dehydrogenase (SDH) activity of complex II (CII) by interacting with the proximal and distal ubiquinone (UbQ)-binding site (Q P and Q D , respectively). This is based on biochemical analyses and molecular modelling, revealing similar or stronger interaction energy of a-TOS compared to that of UbQ for the Q P and Q D sites, respectively. CybL-mutant cells with dysfunctional CII failed to accumulate ROS and underwent apoptosis in the presence of a-TOS. Similar resistance was observed when CybL was knocked down with siRNA. Reconstitution of functional CII rendered CybL-mutant cells susceptible to a-TOS. We propose that a-TOS displaces UbQ in CII causing electrons generated by SDH to recombine with molecular oxygen to yield ROS. Our data highlight CII, a known tumour suppressor, as a novel target for cancer therapy.

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