Temporal change in groundwater level following the 1999 (Mw = 7.5) Chi-Chi earthquake, Taiwan

We examine the post-seismic change in the groundwater level following the 1999 (Mw = 7.5) Chi-Chi earthquake in central Taiwan, as recorded by a network of 70 evenly distributed hydrological stations over a large alluvial fan near the epicenter. Four types of post-seismic responses may be distinguished: In type 1, the groundwater level declined exponentially with time following a coseismic rise. This was the most common response in the study area and occurred in unconsolidated sediments on the Choshui River fan. In type 2, the groundwater level rose exponentially with time following a coseismic fall. This occurred in the deformed and fractured sedimentary rocks in the foothills near the Chelungpu fault that ruptured in the Chi-Chi earthquake. In type 3, the groundwater level continued to decline with time following a coseismic fall. This also occurred in the deformed and fractured sedimentary rocks near the ruptured fault. Finally, in type 4, the groundwater level, following a coseismic rise, stayed at the same level or even rose with time before it eventually declined. This occurred mostly in unconsolidated sediments along the coast of central Taiwan and along the Peikang Stream. We analyze these post-seismic responses by using a one-dimensional model. Together with the results from well test, the analysis show that the type 1 response may be explained by an aquifer model with coseismic recharge and post-seismic subhorizontal discharge across a length of 500-5,000 m; the type 2 response may be explained by a model of coseismic discharge and post-seismic recharge from surface water; the type 3 response may be explained by a model of coseismic discharge and post-seismic subhorizontal discharge across a length of 500-5,000 m; and the type 4 response may be explained by a model of coseismic recharge and sustained post-seismic recharge from surface water. The characteristic time for the post-seismic changes is similar to that for the groundwater-level decline during dry seasons before the earthquake, suggesting that there was no earthquake-induced changes in the aquifer properties (i.e., hydraulic conductivity), confirming the earlier results from recession analyses of the post-seismic streamflow elsewhere after several earthquakes

Epidermal growth factor suppresses induction by progestin of the adhesion protein desmoplakin in T47D breast cancer cells

INTRODUCTION: Although the effects of progesterone on cell cycle progression are well known, its role in spreading and adhesion of breast cancer cells has not attracted much attention until recently. Indeed, by controlling cell adhesion proteins, progesterone may play a direct role in breast cancer invasion and metastasis. Progesterone has also been shown to modulate epidermal growth factor (EGF) effects in neoplasia, although EGF effects on progesterone pathways and targets are less well understood. In the present study we identify an effect of EGF on a progesterone target, namely desmoplakin. METHODS: Initially flow cytometry was used to establish the growing conditions and demonstrate that the T47D breast cancer cell line was responding to progesterone and EGF in a classical manner. Differential display RT-PCR was employed to identify differentially expressed genes affected by progesterone and EGF. Western and Northern blotting were used to verify interactions between EGF and progesterone in three breast cancer cell lines: T47D, MCF-7, and ZR-75. RESULTS: We found the cell adhesion protein desmoplakin to be upregulated by progesterone – a process that was suppressed by EGF. This appears to be a general but not universal effect in breast cancer cell lines. CONCLUSION: Our findings suggest that progesterone and EGF may play opposing roles in metastasis. They also suggest that desmoplakin may be a useful biomarker for mechanistic studies designed to analyze the crosstalk between EGF and progesterone dependent events. Our work may help to bridge the fields of metastasis and differentiation, and the mechanisms of steroid action

Identification of a possible role of thymine DNA glycosylase (TDG) in epigenome maintenance

Thymine DNA glycosylase (TDG) was discovered as an enzyme capable of removing uracil (U) and thymine (T) from G/U and G/T mispairs, respectively. Owing to this ability, TDG was proposed to initiate restoration of C/G pairs at sites of cytosine or 5-methycytosine (5-meC) deamination. In addition to products of base deamination, the substrate spectrum of TDG covers a wide range of DNA base damages resulting from base oxidation and alkylation. TDG was also found to engage in physical and functional interactions with transcription factors, and more recent evidence supports additional interactions with the de novo DNA methyltransferases Dnmt3a and 3b in the context of gene transcription. Together with its biochemical properties, these observations suggest that TDG might be targeted to gene regulatory sequences as part of a macromolecular assembly to control their functional integrity. TDG may counteract the mutagenic effects of C and 5-meC deamination in CG-rich regions and/or be involved in the maintenance of CpG promoter methylation patterns. A tight regulation of CpG methylation at gene regulatory regions is critical for accurate gene expression, proper cellular differentiation and embryonic development. A somewhat surprising but in this context consistent finding was that, in contrast to other DNA glycosylases, TDG is essential for proper fetal development since a targeted knockout of the gene leads to embryonic lethality. To gain insights into the biological functions of TDG, we aimed to establish and apply biochemical fractionation procedures for high affinity purification and structural and functional characterization of TDG containing proteins complexes. The first part of the thesis was concerned with biochemical characterization of the protein interaction network of TDG in living mammalian cells. To this end, I applied different approaches allowing high affinity isolation of protein complexes from mammalian cells, such as the tandem affinity purification (TAP) method as well as immunoprecipitation of endogenous protein and of the TDGa isoform from TdgA overexpressing embryonic stem (ES) cells. These efforts, however, did not reveal any TDG interacting partners in subsequent mass spectrometry (MS) analyses. These results were surprising, as TDG was previously reported to interact with transcription factors and DNA methyltransferases. Remarkably, however, all previously identified protein interactors of TDG were discovered in screen with the respective partner proteins, and under conditions of simultaneous overexpression of both interacting proteins. The only proteins ever identified in screen with TDG were Sumo1 and Sumo3, which turned out to covalently modify the glycosylase. For this reason, we decided to pursue our search with classical cell fractionation experiments. We first did gel filtration experiments from total cell lysates and showed that TDG is indeed able to form distinct multiprotein complexes in undifferentiated mouse embryonic stem cells that may also contain the RNA helicase p68. Further subcellular fractionation experiments then revealed that TDG is present in all cell compartments, with a significant fraction of nuclear TDG being associated with chromatin, together with p68 and de novo DNA methyltransferases. Together with published findings, these results suggested that protein complexes containing TDG might act in a chromatin-associated context, at gene regulatory regions. The developmental phenotype of Tdg-/- knockout mice and the interactions of TDG with factors involved in developmental gene regulation (e.g. retinoic acid receptors RAR/RXR) implicate a function of TDG during early development and cell differentiation, at times governed by dynamic changes in gene expression, DNA methylation and histone modifications. Such changes have been studied using a well-established during in vitro differentiation of ES cells to lineage committed neuronal progenitors (NPs). We thus aimed to address the function of TDG as part of chromatin associated protein complexes during the process of retinoic acid induced differentiation of ES cells to NPs. In the second part of the thesis we made use of a this well-established in vitro differentiation system to examine the genome-wide localization of TDG to chromatin by TDG chromatin immunoprecipitation (ChIP) and to correlate TDG association to chromatin with gene expression and DNA methylation changes linked to cellular differentiation. TDG ChIP combined with high throughput sequencing showed that TDG associates with high preference to CpG islands in promoters of actively transcribed genes or genes poised for transcriptional activation. Such CpG rich sequences are normally unmethylated in mammalian genomes. Interestingly, we found TDG to localize to promoters of many genes controlling pluripotency (e.g. Oct4, Nanog) and developmental processes (e.g. Sfrp2, Tgfb2, Gata6), thus, supporting a function of TDG in cell differentiation and/or embryonic development. As different lines of circumstantial evidence have associated TDG with changes in CpG methylation following activation of hormone responsive gene promoters, we went on to further test genome-wide promoter methylation in Tdg+/- and Tdg-/- NPs making use of a combination of methylated DNA immunoprecipitation (MeDIP) and microarray technology. This showed that the loss of TDG does not affect global promoter DNA methylation. Nevertheless, there were a number of significant differences, suggesting that TDG might affect the CpG methylation pattern at some promoters. Also, owing to the limited resolution of the MeDIP method, however, we could not exclude an involvement of TDG in the control of DNA methylation of specific promoter CpGs. Additional bisulfite sequencing of promoters of TDG bound developmental genes (e.g. Sfrp2, Tgfb2) in NPs and differentiated mouse embryonic fibroblasts (MEFs) have indeed proved that loss of TDG affects local changes in DNA methylation at particular CpGs. Subsequent analysis of genome-wide gene expression profiles of ES cells and differentiated Tdg+/- and Tdg-/- NPs revealed that a limited number of genes (229) are differentially regulated in ES, whereas substantial differences in gene expression in were observed in NPs (1022 genes). This implicated a specific function of TDG in the regulation of cell differentiation triggered gene expression changes. Detailed analysis of the expression of the Pax6 gene, accurate regulation of which is essential for proper neuron development, showed that its promoter is bound by TDG and that its transcription is inappropriately regulated upon further differentiation of Tdg-/- NPs into the neuronal lineage. Whereas Tdg+/- NPs efficiently downregulated Pax6 (50x) and further differentiated into neuron-like cells, Tdg-/- NPs only partially downregulated Pax6 gene expression (6x) and underwent apoptosis at day 2 after plating in neuronal medium. This phenotype was complemented by expression of TDGa, clearly implicating TDG in the regulation of Pax6 expression during differentiation of ES cells to terminal neurons. We further observed misregulation of pluripotency genes (e.g. Oct4) regulated by TDG bound promoters during early differentiation of ES cells. In the absence of TDG, ES cells showed the tendency to enter spontaneous and/or RA induced differentiation, suggesting a role for TDG in the regulation of pluripotency. During RA induced differentiation we further observed the activation of the neuron specific gene Lrrtm2 exclusively in TDG proficient cells. In addition, ChIP experiments showed that transcription factors involved in the activation of the Lrrtm2 gene (e.g. COUP-TFI, RAR) are not recruited to the respective promoter in Tdg-/- cells, suggesting that TDG might act passively as a scaffold factor important for the recruitment of transcription factors to promoter regions. I set out to clarify the biological function of TDG by investigating its molecular interactions in mammalian cells. I found that TDG, as a DNA repair enzyme, associates tightly with chromatin, where it localizes with high preference to CpG island promoters of active genes and genes poised to be expressed. I also found that the loss of TDG causes misregulation of genes during cell differentiation and that this appears to be related to a function of TDG in establishing and/or maintaining CpG methylation pattern in gene regulatory sequences. These discoveries implicate a novel function of DNA repair, in the maintenance not only of the genome, but also the epigenome

Microbial sulfate reduction and metal attenuation in pH 4 acid mine water

Sediments recovered from the flooded mine workings of the Penn Mine, a Cu-Zn mine abandoned since the early 1960s, were cultured for anaerobic bacteria over a range of pH (4.0 to 7.5). The molecular biology of sediments and cultures was studied to determine whether sulfate-reducing bacteria (SRB) were active in moderately acidic conditions present in the underground mine workings. Here we document multiple, independent analyses and show evidence that sulfate reduction and associated metal attenuation are occurring in the pH-4 mine environment. Water-chemistry analyses of the mine water reveal: (1) preferential complexation and precipitation by H2S of Cu and Cd, relative to Zn; (2) stable isotope ratios of 34S/32S and 18O/16O in dissolved SO4 that are 2–3 ‰ heavier in the mine water, relative to those in surface waters; (3) reduction/oxidation conditions and dissolved gas concentrations consistent with conditions to support anaerobic processes such as sulfate reduction. Scanning electron microscope (SEM) analyses of sediment show 1.5-micrometer, spherical ZnS precipitates. Phospholipid fatty acid (PLFA) and denaturing gradient gel electrophoresis (DGGE) analyses of Penn Mine sediment show a high biomass level with a moderately diverse community structure composed primarily of iron- and sulfate-reducing bacteria. Cultures of sediment from the mine produced dissolved sulfide at pH values near 7 and near 4, forming precipitates of either iron sulfide or elemental sulfur. DGGE coupled with sequence and phylogenetic analysis of 16S rDNA gene segments showed populations of Desulfosporosinus and Desulfitobacterium in Penn Mine sediment and laboratory cultures

Malignant inflammation in cutaneous T-cell lymphoma: a hostile takeover

Cutaneous T-cell lymphomas (CTCL) are characterized by the presence of chronically inflamed skin lesions containing malignant T cells. Early disease presents as limited skin patches or plaques and exhibits an indolent behavior. For many patients, the disease never progresses beyond this stage, but in approximately one third of patients, the disease becomes progressive, and the skin lesions start to expand and evolve. Eventually, overt tumors develop and the malignant T cells may disseminate to the blood, lymph nodes, bone marrow, and visceral organs, often with a fatal outcome. The transition from early indolent to progressive and advanced disease is accompanied by a significant shift in the nature of the tumor-associated inflammation. This shift does not appear to be an epiphenomenon but rather a critical step in disease progression. Emerging evidence supports that the malignant T cells take control of the inflammatory environment, suppressing cellular immunity and anti-tumor responses while promoting a chronic inflammatory milieu that fuels their own expansion. Here, we review the inflammatory changes associated with disease progression in CTCL and point to their wider relevance in other cancer contexts. We further define the term "malignant inflammation" as a pro-tumorigenic inflammatory environment orchestrated by the tumor cells and discuss some of the mechanisms driving the development of malignant inflammation in CTCL

Why Functional Pre-Erythrocytic and Bloodstage Malaria Vaccines Fail: A Meta-Analysis of Fully Protective Immunizations and Novel Immunological Model

Background: Clinically protective malaria vaccines consistently fail to protect adults and children in endemic settings, and at best only partially protect infants. Methodology/Principal Findings: We identify and evaluate 1916 immunization studies between 1965-February 2010, and exclude partially or nonprotective results to find 177 completely protective immunization experiments. Detailed reexamination reveals an unexpectedly mundane basis for selective vaccine failure: live malaria parasites in the skin inhibit vaccine function. We next show published molecular and cellular data support a testable, novel model where parasite-host interactions in the skin induce malaria-specific regulatory T cells, and subvert early antigen-specific immunity to parasite-specific immunotolerance. This ensures infection and tolerance to reinfection. Exposure to Plasmodium-infected mosquito bites therefore systematically triggers immunosuppression of endemic vaccine-elicited responses. The extensive vaccine trial data solidly substantiate this model experimentally. Conclusions/Significance: We conclude skinstage-initiated immunosuppression, unassociated with bloodstage parasites, systematically blocks vaccine function in the field. Our model exposes novel molecular and procedural strategies to significantly and quickly increase protective efficacy in both pipeline and currently ineffective malaria vaccines, and forces fundamental reassessment of central precepts determining vaccine development. This has major implications fo

Why does corporate governance matter for international business?

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