Molecular mechanisms of arsenic carcinogenesis

Arsenic is a metalloid compound that is widely distributed in the environment. Human exposure of this compound has been associated with increased cancer incidence. Although the exact mechanisms remain to be investigated, numerous carcinogenic pathways have been proposed. Potential carcinogenic actions for arsenic include oxidative stress, genotoxic damage, DNA repair inhibition, epigenetic events, and activation of certain signal transduction pathways leading to abberrant gene expression. In this article, we summarize current knowledge on the molecular mechanisms of arsenic carcinogenesis with an emphasis on ROS and signal transduction pathways.     

Metal-induced cell signaling and gene activation in lung diseases

Chronic environmental and occupational exposures to low levels of metals are associated with increased incidence of pulmonary and cardiopulmonary diseases. The cellular and molecular mechanisms of action of metals in the lung are unresolved and involve complex pleiotrophic effects. These effects are mediated by direct reaction of the metals with cellular macromolecules and indirect effects of reactive oxygen species generated when cells are exposed to metals. This review focuses on cell signaling pathways activated by two metals, chromium and nickel, that are known to promote a variety of lung diseases, including fibrosis, obstructive disease, and cancer. These signaling pathways are discussed in relation to the inclusion or exclusion of reactive oxygen in mediating cellular activation following metal exposures.     

Metal interaction with redox regulation: an integrating concept in metal carcinogenesis?

The carcinogenicity of cadmium, arsenic, and chromium(VI) compounds has been recognized for some decades. However, the underlying molecular mechanisms seem to be complex and are not completely understood at present. Although, with the exception of chromium(VI), direct DNA damage seems to be of minor importance, interactions with DNA repair processes, tumor suppressor functions, and signal transduction pathways have been described in diverse biological systems. In addition to the induction of damage to cellular macromolecules by reactive oxygen species, the interference with cellular redox regulation by reaction with redox-sensitive protein domains or amino acids may provide one plausible mechanism involved in metal carcinogenicity. Consequences are the distortion of zinc-binding structures and the activation or inactivation of redox-regulated signal transduction pathways, provoking metal-induced genomic instability. Nevertheless, the relevance of the respective mechanisms depends on the actual metal or metal species under consideration and more research is needed to further strengthen this hypothesis.     

Signaling networks in cancer--an interview with Christian Gespach. Interview by Olivier De Wever

The dynamic, innovative temperament of Christian Gespach is ideally suited to unraveling some aspects of the complex molecular networks connected with signal transduction, cancer progression and treatment. He is one of the pioneers who opened, in the early 1980s, new insights into the signaling mechanisms of G-protein coupled receptor (GPCR) activation, desensitization, internalisation and crosstalks. Twenty five years later and in collaboration with Gespach, IPSEN pharmaceuticals designed pan-inhibitors of GPCR signaling, targeting Gα subunits in breast cancer progression and other epithelial cancers. Creativity is of vital importance to understand signal transduction pathways engaged in cancer cell motility, invasion and drug resistance. Christian Gespach has published more than 200 papers in cancer research, a true signal transduction tale.     

Ethylene signal perception and transduction: multiple paradigms?

Current progress on the mechanisms of ethylene signal perception and transduction are reviewed with an emphasis on reconciling data from molecular genetics and from biochemical approaches. It is proposed that there exist two or more interacting transduction pathways.     

Chemopreventive actions of polyphenolic compounds in cancer

Oxidative stress and associated mechanisms involving inflammation, aberrant signaling pathways and gap junction intercellular communication is increasingly associated with the pathogenesis of various chronic degenerative disorders such as atherosclerosis, neurodegeneration and cancer. Consumption of fruits, vegetables and beverages like teas continues to be suggested to have the capacity to reduce the incidence of cancer. The bioactive compounds including phenolics may be responsible for the chemopreventive effects. While the free radical scavenging and antioxidant properties of phenolics are well established, emerging literature reports suggest that their chemopreventive effects may also be ascribed to their ability to modulate components of cell signaling pathways. This paper reviews the potential chemoprevention role of phenolics with a focus on cellular signal transduction mechanisms and prevention of gap junction intercellular communication relevant to cancer.     

心肌细胞肥大的信号转导通路

心肌肥厚是肥大刺激诱导核内基因异常表达的结果,细胞内信号转导通路是肥大刺激与核内基因转录活化的偶联环节。然而,淡同刺激诱导的心肌肥大可能具有不同的“分子表型”,这主要取决于它们启动的信号转导通路。对心肌肥大信号转导通路的深入认识,不仅胡助于阐明心肌肥厚的细胞分子机制,而且可为药物干预防治心肌肥厚提供新思路。     

Aging of signal transduction pathways, and pathology

The major cell signaling pathways, and their specific mechanisms of transduction, have been a subject of investigation for many years. As our understanding of these pathways advances, we find that they are evolutionarily well-conserved not only individually, but also at the level of their crosstalk and signal integration. Productive interactions within the key signal transduction networks determine success in embryonic organogenesis, and postnatal tissue repair throughout adulthood. However, aside from clues revealed through examining age-related degenerative diseases, much remains uncertain about imbalances within these pathways during normal aging. Further, little is known about the molecular mechanisms by which alterations in the major cell signal transduction networks cause age-related pathologies. The aim of this review is to describe the complex interplay between the Notch, TGFβ, WNT, RTK-Ras and Hh signaling pathways, with a specific focus on the changes introduced within these networks by the aging process, and those typical of age-associated human pathologies.     

肿瘤浸润转移分子机制的研究进展

肿瘤浸润转移是多因素参与、多步骤完成的生物化学变化过程。人们已经逐渐认识到浸润转移不仅与肿瘤细胞有关,更是肿瘤细胞和肿瘤组织微环境复杂的相互作用的结果,其过程涉及多个分子作用机制和信号转导途径,包括细胞和细胞的黏附分子、细胞外基质降解、生长因子、趋化因子和淋巴血管生成因子等。本文综述了肿瘤浸润转移的分子机制。     

Molecular regulation of inflammation and cell death

Cell death and innate immunity are ancient evolutionary conserved processes that utilize a dazzling number of related molecular effectors and parallel signal transduction mechanisms. The investigation of the molecular mechanisms linking the sensing of a danger signal (pathogens or tissue damage) to the induction of an inflammatory response has witnessed a renaissance in the last few years. This was initiated by the identification of pattern recognition receptors (PRRs), including Toll-like receptors (TLRs) and more recently cytosolic Nod-like receptors (NLRs), that brought innate immunity to center stage and opened the field to the study of signal transduction pathways, adaptors and central effectors linked to PRRs. This led to the characterization of the inflammasome, a macromolecular complex, scaffolded by NLRs, that recruits and activates inflammatory caspases, which are essential effectors in inflammation and cell death responses. In this review, we describe the molecular pathways of cell death and innate immunity with a focus on recent advancements in both fields and an emphasis on the striking analogies between NLR innate immunity and mitochondrial apoptosis pathways.     

Modulation of molecular mechanisms involved in protein synthesis machinery as a new tool for the control of cell proliferation.

In the past years, the attention of scientists has focused mainly on the study of the genetic information and alterations that regulate eukaryotic cell proliferation and that lead to neoplastic transformation. All therapeutic strategies against cancer are, to date, directed at DNA either with cytotoxic drugs or gene therapy. Little or no interest has been aroused by protein synthesis mechanisms. However, an increasing body of data is emerging about the involvement of translational processes and factors in control of cell proliferation, indicating that protein synthesis can be an additional target for anticancer strategies. In this paper we review the novel insights on the biochemical and molecular events leading to protein biosynthesis and we describe their involvement in cell proliferation and tumorigenesis. A possible mechanistic explanation is given by the interactions that occur between protein synthesis machinery and the proliferative signal transduction pathways and that are therefore suitable targets for indirect modulation of protein synthesis. We briefly describe the molecular tools used to block protein synthesis and the attempts made at increasing their efficacy. Finally, we propose a new multimodal strategy against cancer based on the simultaneous intervention on protein synthesis and signal transduction.     

Mechanisms for species differences in receptor-mediated carcinogenesis

Species differences resulting from a number of mechanisms are common in receptor-mediated chemical carcinogenesis. In this review, examples of possible mechanisms underlying these differences are discussed, including ligand metabolism, receptor polymorphisms, receptor isoforms, receptor levels, and crosstalk between signal transduction pathways. In addition, a number of other mechanisms also are likely to be important. The developmental state of the animal will determine the expression of receptors in different tissues. The regulatory pathways for cell proliferation and cell death and cell cycle check point controls can vary among species and tissues. Adaptation or potentiation of responses during chronic exposures to chemicals can greatly influence species differences. The mechanisms of adaptive processes are poorly understood but probably highly important for chronic toxicities such as cancer. Finally, different species may have different stem cell populations that are the targets for neoplastic transformation, and this will influence receptor-mediated carcinogenic responses. The implications of species differences in receptor-mediated responses for risk assessment are discussed.     

Understanding allocation to shoot and root growth will require molecular information about which compounds act as signals for the plant nutrient status,and how meristem activity and cellular growth are regulated: Opinion

Most previous analyses of shoot-root allocation have investigated correlations between changes in putative signals and shoot-root allocation. It is argued that studies of shoot-root allocation need to be extended to include investigations of mutants with specific lesions in nutrient metabolism, to identify the compounds that are sensed as indicators for the plant nutrient status and act as the starting point for specific transduction pathways. The mechanisms of nutrient sensing can then be investigated using molecular and genetic strategies analogous to those that have been successfully used to investigate other signal transduction events. Investigations of shoot-root allocation should also pay more attention to the way in which root architecture is modified in response to nutrient supply, and need to be designed and interpreted in the light of molecular and genetic analyses of root development.     

Deregulated signalling networks in human brain tumours

Despite the variety of modern therapies against human brain cancer, in its most aggressive form of glioblastoma multiforme (GBM) it is a still deadly disease with a median survival of approximately 1 year. Over the past 2 decades, molecular profiling of low- and high-grade malignant brain tumours has led to the identification and molecular characterisation of mechanisms leading to brain cancer development, maintenance and progression. Genetic alterations occurring during gliomagenesis lead to uncontrolled tumour growth stimulated by deregulated signal transduction pathways. The characterisation of hyperactivated signalling pathways has identified many potential molecular targets for therapeutic interference in human gliomas. Overexpressed or mutated and constitutively active kinases are attractive targets for low-molecular-weight inhibitors. Although the first attempts with mono-therapy using a single targeted kinase inhibitor were not satisfactory, recent studies based on the simultaneous targeting of several core hyperactivated pathways show great promise for the development of novel therapeutic approaches. This review focuses on genetic alterations leading to the activation of key deregulated pathways in human gliomas.     

Metal‐responsive RNA polymerase extracytoplasmic function (ECF) sigma factors

In order to survive, bacteria must adapt to multiple fluctuations in their environment, including coping with changes in metal concentrations. Many metals are essential for viability, since they act as cofactors of indispensable enzymes. But on the other hand, they are potentially toxic because they generate reactive oxygen species or displace other metals from proteins, turning them inactive. This dual effect of metals forces cells to maintain homeostasis using a variety of systems to import and export them. These systems are usually inducible, and their expression is regulated by metal sensors and signal‐transduction mechanisms, one of which is mediated by extracytoplasmic function (ECF) sigma factors. In this review, we have focused on the metal‐responsive ECF sigma factors, several of which are activated by iron depletion (FecI, FpvI and PvdS), while others are activated by excess of metals such as nickel and cobalt (CnrH), copper (CarQ and CorE) or cadmium and zinc (CorE2). We focus particularly on their physiological roles, mechanisms of action and signal transduction pathways.