Project description:The Toxicogenomics Project was a 5-year collaborative project (2002-2007) by a consortium comprising the Japanese government and several pharmaceutical companies. The project produced the 'Toxicogenomics Project-Genomics Assisted Toxicity Evaluation system' (TG-GATEs), a large-scale database of transcriptomics and pathology data potentially useful for predicting the toxicity of new chemical entities. Conventional in vivo toxicology data was collected from single dose and repeat dosing studies on rats, and gene expression measured for the liver (and kidney in some cases). To provide information on species differences, gene expression was also measured in rat and human hepatocytes treated with the chemicals in vitro. Approximately 130 chemicals, primarily medicinal compounds, were tested at multipe doses. Gene expression was analysed using Affymetrix GeneChip arrays. The gene expression data has been submitted in four parts: in vivo single dose (E-MTAB-799), in vivo repeat dosing, in vitro rat (E-MTAB-797) and in vitro human (E-MTAB-798). This submission comprises the in vivo, repeat dosing studies. If publishing results based on this data, please cite the full project name 'Toxicogenomics Project and Toxicogenomics Informatics Project', the database name 'Open TG-GATEs' and the URL 'http://toxico.nibio.go.jp'. Please note that the European Bioinformatics Institute (EBI) was not involved in the Toxicogenomics Project in any way, acting only to submit the transcriptomics data to Array Express. Queries about the project can be addressed to the consortium directly via 'opentggates@nibio.go.jp'. This dataset is part of the TransQST collection.

Project description:Autophagy is reported to be an important innate immune defense against the intracellular bacterial pathogen Group A Streptococcus (GAS). However, the GAS strains examined to date belong to serotypes infrequently associated with human disease. We find that the globally disseminated serotype M1T1 clone of GAS can evade autophagy and replicate efficiently in the cytosol of infected cells. Cytosolic M1T1 GAS (strain 5448), but not M6 GAS (strain JRS4), avoids ubiquitylation and recognition by the host autophagy marker LC3 and ubiquitin-LC3 adaptor proteins NDP52, p62, and NBR1. Expression of SpeB, a streptococcal cysteine protease, is critical for this process, as an isogenic M1T1 ΔspeB mutant is targeted to autophagy and attenuated for intracellular replication. SpeB degrades p62, NDP52, and NBR1 in vitro and within the host cell cytosol. These results uncover a proteolytic mechanism utilized by GAS to escape the host autophagy pathway that may underpin the success of the M1T1 clone.

Project description:Staphylococcus aureus infections exert a tremendous burden on the health-care system, and the threat of drug-resistant strains continues to grow. The bacteriolytic enzyme lysostaphin is a potent antistaphylococcal agent with proven efficacy against both drug-sensitive and drug-resistant strains; however, the enzyme's own bacterial origins cause undesirable immunogenicity and pose a barrier to clinical translation. Here, we deimmunized lysostaphin using a computationally guided process that optimizes sets of mutations to delete immunogenic T cell epitopes without disrupting protein function. In vitro analyses showed the methods to be both efficient and effective, producing seven different deimmunized designs exhibiting high function and reduced immunogenic potential. Two deimmunized candidates elicited greatly suppressed proliferative responses in splenocytes from humanized mice, while at the same time the variants maintained wild-type efficacy in a staphylococcal pneumonia model. Overall, the deimmunized enzymes represent promising leads in the battle against S. aureus.

Project description:Therapeutic proteins are powerful next-generation drugs able to effectively treat diverse and devastating diseases, but the development and use of biotherapeutics entails unique challenges and risks. In particular, protein drugs are subject to immune surveillance in the human body, and ensuing antidrug immune responses can cause a wide range of problems including altered pharmacokinetics, loss of efficacy, and even life-threating complications. Here we review recent progress in technologies for engineering deimmunized biotherapeutics, placing particular emphasis on deletion of immunogenic antibody and T cell epitopes via experimentally or computationally guided mutagenesis.

Project description:Purpose: Chinese hamster ovary (CHO) cells are a common tool utilized in bioproduction and directed genome engineering of CHO cells is of great interest to enhance recombinant cell lines. Until recently, this focus has been challenged by a lack of efficacious, high throughput, and low-cost gene editing modalities and screening methods. In this work, we demonstrate an improved method for gene editing in CHO cells using CRISPR RNPs and characterize the endpoints of Cas9 and ZFN mediated genetic engineering. Methods: Amplicons were first assayed for quality using an Invitrogen Quant-iT dsDNA (Thermo, Cat Q33120) assay and gel electrophoresis to determine DNA concentration and DNA quality. Samples were then used for Sanger sequence based decomposition or processed downstream using NGS. For NGS, libraries were generated using the Illumina TruSeq Nano DNA kit (Illumina, Cat: 20015964). The libraries were sequenced using the Illumina MiSeq platform, with read length of 2x150bp. 4.5Gb of sequencing data was generated per DNA sample. Results: There was a tendency for decomposition to underestimate editing as compared to NGS as the indel size became larger. Despite these results, sequence decomposition was able to reproduce next-generation data in the context of gene editing efficiency across a short amplicon. Conclusions: We took advantage of the differential Indel spectrums induced by both ZFN and CRISPR to validate metrics for assess gene editing and show how deconvolution-based methods, can be utilized in the context of cell line development.

Project description:Small-molecule inhibitors that block the MDM2-p53 protein-protein interaction (MDM2 inhibitors) are being intensely pursued as a new therapeutic strategy for cancer treatment. We previously published a series of spirooxindole-containing compounds as a new class of MDM2 small-molecule inhibitors. We report herein a reversible ring-opening-cyclization reaction for some of these spirooxindoles, which affords four diastereomers from a single compound. Our biochemical binding data showed that the stereochemistry in this class of compounds has a major effect on their binding affinities to MDM2, with >100-fold difference between the most potent and the least potent stereoisomers. Our study has led to the identification of a set of highly potent MDM2 inhibitors with a stereochemistry that is different from that of our previously reported compounds. The most potent compound (MI-888) binds to MDM2 with a Ki value of 0.44 nM and achieves complete and long-lasting tumor regression in an animal model of human cancer.

Project description:A high percentage of patients with the myeloproliferative disorder polycythemia vera (PV) harbor a Val617?Phe activating mutation in the Janus kinase 2 (JAK2) gene, and both cell culture and mouse models have established a functional role for this mutation in the development of this disease. We describe the properties of MRLB-11055, a highly potent inhibitor of both the WT and V617F forms of JAK2, that has therapeutic efficacy in erythropoietin (EPO)-driven and JAK2V617F-driven mouse models of PV. In cultured cells, MRLB-11055 blocked proliferation and induced apoptosis in a manner consistent with JAK2 pathway inhibition. MRLB-11055 effectively prevented EPO-induced STAT5 activation in the peripheral blood of acutely dosed mice, and could prevent EPO-induced splenomegaly and erythrocytosis in chronically dosed mice. In a bone marrow reconstituted JAK2V617F-luciferase murine PV model, MRLB-11055 rapidly reduced the burden of JAK2V617F-expressing cells from both the spleen and the bone marrow. Using real-time in vivo imaging, we examined the kinetics of disease regression and resurgence, enabling the development of an intermittent dosing schedule that achieved significant reductions in both erythroid and myeloid populations with minimal impact on lymphoid cells. Our studies provide a rationale for the use of non-continuous treatment to provide optimal therapy for PV patients.

Project description:Tuberculosis (TB) remains a deadly disease. The genetic diversity of Mycobacterium tuberculosis was neglected in the past, but is increasingly recognized as a determinant of immune responses and clinical outcomes of TB. However, how this bacterial diversity orchestrates immune responses to direct differences in TB severity remains unknown. We studied 681 patients with pulmonary TB and found that phylogenetically related M. tuberculosis isolates from cases with mild disease induced robust cytokine responses in macrophages. In contrast, isolates associated with severe TB cases failed to do so. Using representative isolates, we show that M. tuberculosis inducing a low cytokine response in macrophages also diminished activation of cytosolic surveillance systems, including cGAS and the inflammasome, suggesting a novel mechanism of immune escape. Isolates exhibiting this evasion strategy carried mutations in various components of the ESX-I secretion system. We conclude that host interactions with different M. tuberculosis strains results in variable TB severity.

Project description:Our previously reported Bcl-2/Bcl-xL inhibitor, 4, effectively inhibited tumor growth but failed to achieve complete regression in vivo. We have now performed extensive modifications on its pyrrole core structure, which has culminated in the discovery of 32 (BM-1074). Compound 32 binds to Bcl-2 and Bcl-xL proteins with K(i) values of <1 nM and inhibits cancer cell growth with IC50 values of 1-2 nM in four small-cell lung cancer cell lines sensitive to potent and specific Bcl-2/Bcl-xL inhibitors. Compound 32 is capable of achieving rapid, complete, and durable tumor regression in vivo at a well-tolerated dose schedule. Compound 32 is the most potent and efficacious Bcl-2/Bcl-xL inhibitor reported to date.

Project description:In response to a viral infection, the plant’s RNA silencing machinery processes viral RNAs into a huge number of small interfering RNAs (siRNAs). However, very few of these siRNAs actually interfere with viral replication. A reliable approach to define the characteristics underlying the activity of these immunologically effective siRNAs (esiRNAs) has not been available so far. We developed a novel screening approach that enables a rapid functional identification of antiviral esiRNAs. The approach is essentially based on the use of a cytoplasmic extract from Nicotiana tabacum BY-2 protoplasts (BY-2 lysate, BYL), that shows Dicer-like (DCL) activity and facilitates the assembly of active RNA-induced silencing complexes (RISC) with an in vitro-translated Argonaute (AGO) protein of choice. We exposed double-stranded (ds) RNA of Tomato bushy stunt virus (TBSV) to the BYL to generate viral siRNAs (DCL assay). Total RNA was isolated from the reactions and DCL-generated TBSV siRNAs were identified by NGS. In another approach, AGO1/RISC- or AGO2/RISC-associated siRNAs were isolated using FLAG-AGO immunoprecipitation (AGO-IP) and analyzed by NGS. Subsequently, the antiviral activity of siRNAs with high affinity to AGO proteins was characterized in vitro and in vivo.