Loss of Hippo signaling in Drosophila leads to tissue overgrowth as a result of increased cell proliferation and decreased cell death. YAP (a homolog of Drosophila Yorkie and target of the Hippo pathway) was recently implicated in control of organ size, epithelial tissue development, and tumorigenesis in mammals. However, the role of the mammalian Hippo pathway in such regulation has remained unclear. We now show that mice with liver-specific ablation of WW45 (a homolog of Drosophila Salvador and adaptor for the Hippo kinase) manifest increased liver size and expansion of hepatic progenitor cells (oval cells) and eventually develop hepatomas. Moreover, ablation of WW45 increased the abundance of YAP and induced its localization to the nucleus in oval cells, likely accounting for their increased proliferative capacity, but not in hepatocytes. Liver tumors that developed in mice heterozygous for WW45 deletion or with liver-specific WW45 ablation showed a mixed pathology combining characteristics of hepatocellular carcinoma and cholangiocarcinoma and seemed to originate from oval cells. Together, our results suggest that the mammalian Hippo-Salvador pathway restricts the proliferation of hepatic oval cells and thereby controls liver size and prevents the development of oval cellderived tumors.T he mammalian Hippo signaling pathway has been implicated in regulation of contact inhibition, organ size, and tumorigenesis (1-4). Such regulation is thought to be mediated by control of the expression level or localization of YAP, a major target of the Hippo pathway. YAP is overexpressed in certain mammalian cancers, and YAP transgenic mice show increased liver size and intestinal dysplasia and eventually develop liver tumors. The role of YAP in control of organ size and tumorigenesis prompted us to examine whether upstream components of the Hippo pathway indeed function to regulate YAP in this context. However, embryonic mortality (WW45 −/− , LATS2 −/− , MST1 −/− MST2 −/− , or YAP −/− ) or the absence of any overt enlargement of specific organs (LATS1 −/− ) in mice lacking such components has hampered this investigation (5-9). The generation of conditional knockout mice would thus seem to be warranted for investigation of the role of the mammalian Hippo pathway in the control of liver size and tumorigenesis.Primary liver tumors have been categorized into two major types: hepatocellular carcinoma (HCC) and cholangiocarcinoma (CC), which originate from hepatocytes and cholangiocytes, respectively. However, some primary hepatomas exhibit an intermediate or combined (HCC/CC) phenotype and are thought to be derived from transformed progenitor (oval) cells or by dedifferentiation of mature cells (10-16). Oval cells are thought to be bipotential progenitor cells that can differentiate into either hepatocytes or ductal cholangiocytes but do so only if proliferation of hepatocytes is inhibited (17-19). However, the precise mechanism responsible for regulation of oval cell proliferation and how its deregulation contributes to tumor ...
The role and molecular mechanisms of a new Hippo signalling pathway are not fully understood in mammals. Here, we generated mice that lack WW45 and revealed a crucial role for WW45 in cell-cycle exit and epithelial terminal differentiation. Many organs in the mutant mouse embryos displayed hyperplasia accompanied by defects in terminal differentiation of epithelial progenitor cells owing to impaired proliferation arrest rather than intrinsic acceleration of proliferation during differentiation. Importantly, the MST1 signalling pathway is specifically activated in differentiating epithelial cells. Moreover, WW45 is required for MST1 activation and translocation to the nucleus for subsequent LATS1/2 activation upon differentiation signal. LATS1/2 phosphorylates YAP, which, in turn, translocates from the nucleus into the cytoplasm, resulting in cell-cycle exit and terminal differentiation of epithelial progenitor cells. Collectively, these data provide compelling evidence that WW45 is a key mediator of MST1 signalling in the coordinate coupling of proliferation arrest with terminal differentiation for proper epithelial tissue development in mammals.
An accurate mathematical representation of particle‐size distributions (PSDs) is required to estimate soil hydraulic properties or to compare texture measurements from different classification systems. The objective of this study was to evaluate the ability of seven models (i.e., five lognormal models, the Gompertz model, and the Fredlund model) to fit PSD data sets from a wide range of soil textures. Special attention was given to the effect of texture on model performance. Several criteria were used to determine the optimum model with the least number of fitting parameters when other conditions are equal. The Fredlund model with four parameters showed the best performance with the majority of soils studied, even when three criteria that impose a penalty for additional fitting parameters were used. Especially, the relative performance of the Fredlund model in regard to other models increased with increase of clay content. Among all soil classes, the lognormal models with two or three parameters showed better fits for silty clay, silty clay loam, and silt loam soils, and worse fit for sandy clay loam soil.
Skeletal muscle degenerates progressively, losing mass (sarcopenia) over time, which leads to reduced physical ability and often results in secondary diseases such as diabetes and obesity. The regulation of gene expression by microRNAs is a key event in muscle development and disease. To understand genome-wide changes in microRNAs and mRNAs during muscle aging, we sequenced microRNAs and mRNAs from mouse gastrocnemius muscles at two different ages (6 and 24 months). Thirty-four microRNAs (15 up-regulated and 19 down-regulated) were differentially expressed with age, including the microRNAs miR-206 and -434, which were differentially expressed in aged muscle in previous studies. Interestingly, eight microRNAs in a microRNA cluster at the imprinted Dlk1-Dio3 locus on chromosome 12 were coordinately down-regulated. In addition, sixteen novel microRNAs were identified. Integrative analysis of microRNA and mRNA expression revealed that microRNAs may contribute to muscle aging through the positive regulation of transcription, metabolic processes, and kinase activity. Many of the age-related microRNAs have been implicated in human muscular diseases. We suggest that genome-wide microRNA profiling will expand our knowledge of microRNA function in the muscle aging process.
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