Project description:Understanding the regulation of lysosomal proteolytic/hidrolytic capacity has been recently advanced in a huge manner by the discovery of the lysosome-mTOR-TFEB pathway connecting nutrient sensing, autophagy and de novo lysosome generation. But, how lysosomes can adjust their proteolytic/hidrolytic capacity to meet varying conditions (more or less substrate) under normal fed conditions is not known. We have used AEP as a proxy to understand how lysosomes can compensate the lack of a key lysosomal protease to meet the requirements under physiological, fed conditions. To do this, we did compare cytoplasmic, membrane and nuclear fractions of WT and AEP MEFs that were expanded in SILAC media. AEP knock-out mice show pale kidney, with abnormal proliferation of the epithelial proximal tubular cells. In an attempt to understand the role of AEP in the kidney, we did compare kidney obtained from WT and AEP mice using kidneys from WT mice that were fed with SILAC food. Also, in an attempt to reproduce the changes observed in the absence of AEP in kidney and MEFs, we treated WT MEFs grown in SILAC media with MVO26630, specific inhibitor of AEP, for 12 and 48 hours.

Project description:This project aims to identify proteins that interact with DHX9.

Project description:In the rapidly advancing field of synthetic biology, there is a critical need for technology to discover targeting moieties for therapeutic biologics. We developed INSPIRE-seq, an approach that utilizes a nanobody library and next-generation sequencing to identify nanobodies selected for complex environments. INSPIRE-seq enables the parallel enrichment of immune cell-binding nanobodies that penetrate the tumor microenvironment. Clone enrichment and specificity varies across immune cell subtypes in the tumor, lymph node, and spleen. INSPIRE-seq identified a dendritic cell binding clone that binds PHB2. Single-cell RNA sequencing revealed a connection with cDC1s, and immunofluorescence confirmed nanobody-PHB2 colocalization along cell membranes. Structural modeling and docking studies assisted binding predictions and will guide nanobody selection. In this work, we demonstrate that INSPIRE-seq offers an unbiased approach to examine complex microenvironments and assist in the development of nanobodies, which could serve as active drugs, modified to become drugs, or used as targeting moieties.

Project description:Actin, spectrin, and associated proteins form a membrane-associated periodic skeleton (MPS) in neurons. The molecular composition and functions of the MPS remain incompletely understood. Here, we combined co-immunoprecipitation and mass spectrometry analyses to identify candidate MPS-interacting proteins from cultured hippocampal neurons and adult mouse brains. In addition, we also used quantitative mass spectrometry analysis based on Tandem Mass Tag (TMT) isobaric labeling to determine how the expression levels of proteins are differentially regulated at the proteomic scale upon depletion of βII-spectrin, an important molecular component of the MPS. These results provide a systematic picture of the interactome of the MPS, and new insights into new functions of the MPS in neurons.

Project description:15-keto-PGE2 is proposed as an endogenous ligand of PPAR gamma. The modification of 15-keto-PGE2 can induce PPAR gamma transcriptional activation. This project aims to identify the binding site of 15-keto-PGE2 on PPAR gamma.

Project description:Artificial evolvable genetic information systems (AEGIS) are DNA-like molecules that can be copied, support laboratory in vitro evolution (LIVE), and evolve to give AegisBodies, analogs of antibodies. However, unlike DNA aptamers built from four different nucleotides, AegisBodies are built from six. Thus, 6-letter AEGIS-LIVE delivers AegisBodies with greater stability in biological mixtures, more folds, and enhanced binding and catalytic potential. However, AEGIS has not benefitted from four billion years of biological evolution. To learn whether AEGIS can nevertheless perform as well as natural DNA, we compare two 6-letter AegisBodies (LZH5b and LZH8) with a standard 4-letter aptamer. Both were evolved to bind cancer cells after ~10 cycles of LIVE. Both have ~ 50 nM affinities. Both discovered proteins on their cancer cell surfaces thought to function only inside of cells. Both can be internalized. Internalizing of LZH5b attached to an AEGIS nanotrain brings attached drugs into the cell. These data show that AEGIS-LIVE can do what 4-letter LIVE can do at its limits of performance after four billion years of evolution. However, synthetic biologists continue to improve AEGIS, suggesting that AEGIS not be dismissed as an avenue for future biotechnology.

Project description:Artificial evolvable genetic information systems (AEGIS) are DNA-like molecules that can be copied, support laboratory in vitro evolution (LIVE), and evolve to give AegisBodies, analogs of antibodies. However, unlike DNA aptamers built from four different nucleotides, AegisBodies are built from six. Thus, 6-letter AEGIS-LIVE delivers AegisBodies with greater stability in biological mixtures, more folds, and enhanced binding and catalytic potential. However, AEGIS has not benefitted from four billion years of biological evolution. To learn whether AEGIS can nevertheless perform as well as natural DNA, we compare two 6-letter AegisBodies (LZH5b and LZH8) with a standard 4-letter aptamer. Both were evolved to bind cancer cells after ~10 cycles of LIVE. Both have ~ 50 nM affinities. Both discovered proteins on their cancer cell surfaces thought to function only inside of cells. Both can be internalized. Internalizing of LZH5b attached to an AEGIS nanotrain brings attached drugs into the cell. These data show that AEGIS-LIVE can do what 4-letter LIVE can do at its limits of performance after four billion years of evolution. However, synthetic biologists continue to improve AEGIS, suggesting that AEGIS not be dismissed as an avenue for future biotechnology.

Project description:In vitro kinase assay with human filamin C domain 18-21 recombinantly expressed in E.coli, purified by Ni2+-NTA beads and incubated with PKC alpha, Akt or a combination of both to identify kinase specific phosphorylation sites.

Project description:Across the spectrum of human disease there are significant changes in the composition and organisation of extracellular matrix (ECM). Furthermore, disease severity can vary according to race and sex, yet mechanisms for these variations are unclear. Using the kidney glomerulus as a model system, we tested the hypothesis that genetic background and sex influence composition and organisation of ECM. We characterised ECM from healthy mice with different predisposition to glomerular disease using global microarray, discovery proteomics and electron microscopy. Transcriptomic and proteomic analyses revealed unique strain and sex dependent glomerular ECM signatures with novel ECM proteins, which relate to glomerular dysfunction with leakage of macromolecules into the glomerular filtrate. In addition, we found striking structural changes in basement membranes in disease-susceptible mice. These findings were not explained by mutations in known ECM or glomerular genes. Pathway analysis of merged transcriptomic and proteomic datasets identified potential ECM regulatory pathways involving inhibition of matrix metalloproteinases, LXR/RXR, NRF2, notch and CDK5. These pathways may therefore alter ECM and confer susceptibility to disease.

Project description:We performed proteomics analysis to discover effector proteins for the post-transcriptional regulation of PD-L1 onhuman macrophages stimulated by adenosine signal.