Updating the Wnt pathways

In the three decades since the discovery of the Wnt1 proto-oncogene in virus-induced mouse mammary tumours, our understanding of the signalling pathways that are regulated by the Wnt proteins has progressively expanded. Wnts are involved in an complex signalling network that governs multiple biological processes and cross-talk with multiple additional signalling cascades, including the Notch, FGF (fibroblast growth factor), SHH (Sonic hedgehog), EGF (epidermal growth factor) and Hippo pathways. The Wnt signalling pathway also illustrates the link between abnormal regulation of the developmental processes and disease manifestation. Here we provide an overview of Wnt-regulated signalling cascades and highlight recent advances. We focus on new findings regarding the dedicated Wnt production and secretion pathway with potential therapeutic targets that might be beneficial for patients with Wnt-related diseases.     

Mimicking GEFs: a common theme for bacterial pathogens

Small molecular weight GTPases are master regulators of eukaryotic signalling, making them prime targets for bacterial virulence factors. Here, we review the recent advances made in understanding how bacterial type III secreted effector proteins directly activate GTPase signalling cascades. Specifically we focus on the SopE/WxxxE family of effectors that functionally mimic guanine nucleotide exchange factors (GEFs): the endogenous activators of Rho-family GTPases. Recent structural and biochemical studies have provided keen insight into both the signalling potency and substrate specificity of bacterial GEFs. Additionally, these bacterial GEFs display fascinating cell biological properties that provide insight into both host cell physiology and infectious disease strategies.     

Ringing the alarm bells: signalling and apoptosis in influenza virus infected cells

Small RNA viruses such as influenza viruses extensively manipulate host-cell functions to support their replication. At the same time the infected cell induces an array of defence mechanisms to fight the invader. These processes are mediated by a variety of intracellular signalling cascades. Here we will review the current knowledge of functional kinase signalling and apoptotic events in influenza virus infected cells and how these viruses have learned to misuse these cellular responses for efficient replication.     

Auxin regulation of cell cycle and its role during lateral root initiation

The plant hormone auxin plays a crucial role in the upstream regulation of many processes, making the study of its action particularly interesting to understand plant development. In this review we will focus on the effects auxin exerts on cell cycle progression, more specifically, during the initiation of lateral roots. Auxin fulfils a dominant role in the initiation of a new lateral root primordium. How this occurs remains largely unknown. Here we try to integrate the classical auxin signalling mechanisms into recent findings on cell cycle regulation. How both signalling cascades are integrated appears to be complex and is far from understood. As a means to solve this problem we suggest the use of a lateral root-inducible system that allows investigation of the early signalling cascades initiated by auxin and leading to cell cycle activation.     

Coordinating developmental signaling: novel roles for the Hippo pathway

Genetic and biochemical studies have defined the Hippo pathway as a central mediator of developmental and pathogenic signals. By directing intracellular signaling events, the Hippo pathway fine-tunes cell proliferation, cell death, and cell-fate decisions, and coordinates these cues to specify animal organ size. Recent studies have revealed that Hippo pathway-mediated processes are interconnected with those of other key signaling cascades, such as those mediated by TGF-β and Wnt growth factors. Moreover, several reports have described a role for cell contact-mediated polarity proteins in Hippo pathway regulation. Emerging details suggest that crosstalk between these signals drives fundamental developmental processes, and deregulated intercellular communication influences disease progression, such as cancer. We review recent data with a focus on how the Hippo pathway integrates its activity with other signaling pathways.     

Regulation of Wnt signalling by receptor-mediated endocytosis

Wnts compromise a large family of secreted and hydrophobic glycoproteins that control a variety of developmental and adult processes in all metazoan organisms. Recent advances in the field of Wnt signalling have revealed that Wnt activates multiple intracellular cascades, resulting in the regulation of cellular proliferation, differentiation, migration and polarity. However, it is not clear how Wnt activates these pathways after it binds to the receptors. It has been shown that Wnt and its antagonist Dickkopf are internalized with their receptors. This review highlights distinct endocytic pathways correlate with specificity of Wnt signalling events.     

Regulation of developmental intercellular signalling by intracellular trafficking

Universal trafficking components within the cell can be recruited to coordinate and regulate the developmental signalling cascades. We will present ways in which the intracellular trafficking machinery is used to affect and modulate the outcome of signal transduction in developmental contexts, thus regulating multicellular development. Each of the signalling components must reach its proper intracellular destination, in a form that is properly folded and modified. In many instances, the ability to bring components together or segregate them into distinct compartments within the cell actually provides the switch mechanism to turn developmental signalling pathways on or off. The review will begin with a focus on the signal-sending cells, and the ways in which ligand trafficking can impinge on the signalling outcome, via processing, endocytosis and recycling. We will then turn to the signal-receiving cell, and discuss mechanisms by which endocytosis can affect the spatial features of the signal, and the compartmentalization of components downstream to the receptor.     

Kinetic mechanisms for overexpression insensitivity and oncogene cooperation

Minor (5-10 fold) activation of mitogenic signalling cascades typically induces cell division upon extracellular stimulation and is sufficient to support tumourigenesis when permanently triggered by activating mutations. Surprisingly, even strong signalling protein overexpression usually does not trigger deregulated cell proliferation, suggesting that basal state signalling is insensitive to wildtype protein overexpression. Using kinetic modelling of the core Ras cycle, we show that basal RasGTP signalling can be insensitive to Ras overexpression and thus identify a possible tumour suppression mechanism. We further show how phenotypically silent overexpression events within signalling cascades cooperate to bring about carcinogenesis. Our analyses underscore the need for a systems level understanding of tumour formation.     

Learning in honeybees: from molecules to behaviour

Studies in a variety of organisms as diverse as molluscs, insects, birds and mammals have shown that memories can exist in a variety of temporal domains ranging from short-term memories in the range of minutes to long-term memories lasting a lifetime. While transient covalent modifications of proteins underlie short-term memory, the formation of long-term memory requires gene expression and protein synthesis. Different intracellular signalling cascades have been implicated in distinct aspects of learning and memory formation. Little is known however, about how learning in intact animals is related to the modulation of these signalling cascades and how this contributes to distinct neuronal and behavioural changes in vivo. Associative learning in the honeybee provides the opportunity to study processes of memory formation by analysing its progression through different phases, across levels of behaviour, neural circuits, and cellular signalling pathways. The findings reveal evidence that various cellular signalling pathways in the neuronal circuit of distinct brain areas play a role in different processes during learning and memory formation.     

Cold stress signalling in female reproductive tissues

Cold stress is a significant threat for plant productivity and impacts on plant distribution and crop production, particularly so when it occurs during the growth phase. A developmental stage at risk is that of flowering, since a single stress event during sensitive stages, such as the full‐bloom stage of fruit trees can be fatal for reproductive success. Although pollen development and fertilization are widely viewed as the most critical reproductive phases, the development and function of female reproductive tissues, which in Angiosperms are embedded in the gynoecium, are also affected by cold stress. Today however, we have essentially no understanding of the cold stress response pathways that act during floral organogenesis. In this review, we briefly summarize our current knowledge of cold stress signalling modules active in vegetative tissues that may provide a framework of general principles also transferable to female reproductive tissues. We then align these signalling cascades with those that govern gynoecium development to identify factors that may act in both processes and could thereby contribute to cold stress responses in female reproductive tissues.     

Genetic disorders of the LRP5-Wnt signalling pathway affecting the skeleton

Osteoporosis is a common, increasingly prevalent and potentially debilitating condition of men and women. Genetic factors are major determinants of bone mass and the risk of fracture, but few genes have been definitively demonstrated to be involved. The identification of these factors will provide novel insights into the processes of bone formation and loss and thus the pathogenesis of osteoporosis, enabling the rational development of novel therapies. In this article, we present the extensive genetic and functional data indicating that the LRP5 gene and the Wnt signalling pathway are key players in bone formation and the risk of osteoporosis, and that LRP5 signalling is essential for normal morphology, developmental processes and bone health.     

On the role of the peroxisome in cell differentiation and carcinogenesis

This article reviews the currently available data on the role of peroxisomal function in relation to the processes of cell differentiation and carcinogenesis. In regard to tumourigenesis, both genotoxic and non-genotoxic processes have been considered, and the peroxisomal relationships with these phenomena and with differentiation are described at the level of organelle characteristics, enzyme contents, and the involvement of retinoids, steroid hormones, oxygen free radicals, growth factors, apoptosis, omega-3 polyunsaturated fatty acids and the cellular signalling networks. Overall these data serve to illustrate the unique and distinctive role of the peroxisome in differentiation and carcinogenesis, and point to the advantages of considering the peroxisomal involvement in the holistic context of the differentiation dedifferentiation continuum rather than the narrower focus of non-genotoxic carcinogenesis. The review also outlines the potential for medical benefit arising from a fuller understanding of these peroxisomal affiliations.     

To be or not to be planktonic? Self‐inhibition of biofilm development

The transition between planktonic growth and biofilm formation represents a tightly regulated developmental shift that has substantial impact on cell fate. Here, we highlight different mechanisms through which bacteria limit their own biofilm development. The mechanisms involved in these self‐inhibition processes include: (i) regulation by secreted small molecules, which govern intricate signalling cascades that eventually decrease biofilm development, (ii) extracellular polysaccharides capable of modifying the physicochemical properties of the substratum and (iii) extracellular DNA that masks an adhesive structure. These mechanisms, which rely on substances produced by the bacterium and released into the extracellular milieu, suggest regulation at the communal level. In addition, we provide specific examples of environmental cues (e.g. blue light or glucose level) that trigger a cellular response reducing biofilm development. All together, we describe a diverse array of mechanisms underlying self‐inhibition of biofilm development in different bacteria and discuss possible advantages of these processes.