Project description:This dataset simply looks at various fractions pulled from an HPLC run to separate metabolites and find fraction(s) that contain our metallophore(s) of interest. Follow-up from previous job (MSV000100592) using a more concentrated extract.

Project description:This dataset simply looks at various fractions pulled from an HPLC run to separate metabolites and find fraction(s) that contain our metallophore(s) of interest. In preparation for sending fractions for 21 T FT-ICR analysis.

Project description:This dataset simply looks at various fractions pulled from an HPLC run to separate metabolites and find fraction(s) that contain our metallophore(s) of interest. Follow-up from previous job (MSV000100515) that used a different gradient.

Project description:This dataset simply looks at various fractions pulled from an HPLC run to separate metabolites and ideally find fraction(s) that contain our metallophore(s) of interest. Unfortunately, none of these fractions appeared to catch them.

Project description:This dataset simply looks at various fractions pulled from an HPLC run to separate metabolites and ideally find fraction(s) that contain our metallophore(s) of interest. Unfortunately, none of these fractions appeared to catch them.

Project description:This dataset looks at putative metallophore production using 4 different media recipes. All were MP-based, but with different additives (media 464, casamino acids, and L-Trp).

Project description:The total chemical synthesis of proteins is a tedious and time-consuming endeavour. The typical steps involve solid phase synthesis of peptide thioesters and cysteinyl peptides, native chemical ligation (NCL) in solution, desulfurization or removal of ligation auxiliaries in the case of extended NCL as well as many intermediary and final HPLC purification steps. With an aim to facilitate and improve the throughput of protein synthesis we developed the first method for the rapid chemical total on-resin synthesis of proteins that proceeds without a single HPLC-purification step. The method relies on the combination of three orthogonal protein tags that allow sequential immobilization (via the N-terminal and C-terminal ends), extended native chemical ligation and release reactions. The peptide fragments to be ligated are prepared by conventional solid phase synthesis and used as crude materials in the subsequent steps. An N-terminal His6 unit permits selective immobilization of the full length peptide thioester onto Ni-NTA agarose beads. The C-terminal peptide fragment carries a C-terminal peptide hydrazide and an N-terminal 2-mercapto-2-phenyl-ethyl ligation auxiliary, which serves as a reactivity tag for the full length peptide. As a result, only full length peptides, not truncation products, react in the subsequent on-bead extended NCL. After auxiliary removal the ligation product is liberated into solution upon treatment with mild acid, and is concomitantly captured by an aldehyde-modified resin. This step allows the removal of the most frequently observed by-product in NCL chemistry, i.e. the hydrolysed peptide thioester (which does not contain a C-terminal peptide hydrazide). Finally, the target protein is released with diluted hydrazine or acid. We applied the method in the synthesis of 46 to 126 amino acid long MUC1 proteins comprising 2-6 copies of a 20mer tandem repeat sequence. Only three days were required for the parallel synthesis of 9 MUC1 proteins which were obtained in 8-33% overall yield with 90-98% purity despite the omission of HPLC purification.

Project description:Synthesis of thiobarbituric acids by the reaction of 1,3-disubstituted thioureas and malonic acid in acetyl chloride-acetic acid medium and synthesis of cyclized pyrimidin-7-one by the interaction of 1-(2-hydroxyethyl)-aryl thioureas, with malonic acid in p-tolyl sulphonic acid and acetyl chloride-acetic acid medium at room temperature stirring has been reported. The present protocol is highly eco-friendly alternative to existing methods, reduces the excess use of acetyl chloride and purity of all synthesized molecules checked with the help of reverse phase high performance liquid chromatography with photo diode array (PDA) detection at 254 nm with spectral characterization by 1H, 13C NMR, and MS spectra.

Project description:While glycoscience has become well recognized as an indispensable area in biomedical research, studies on the function of individual glycans remains a great challenge due to the lack of tools and methods. One of the greatest impediments to progress in this area is the lack of biomedically relevant complex glycans in sufficient quantity and purity for structural and functional analysis. Despite recent advances in chemoenzymatic synthesis of complex glycans, generating significant amounts of pure glycans is limited to laboratories with specialized expertise. We have previously reported the oxidative release of natural glycans (ORNG) using household bleach, which provides large quantities of biologically relevant glycans that can be a source of glycans in quantities (>mg scale) suitable for functional studies. However, the preparative scale separation of complicated glycan mixtures has not been studied due largely to the fact that gram quantities of starting glycans have not been available until now. Here we report the adoption of closed-loop, recycle HPLC to resolve closely related glycan structures, including complex glycan isomers at preparative scale (10-100 mg).

Project description:This dataset looks at putative metallophore production under several conditions: large-scale culturing as well as smaller-scale comparing culture grown in minimal media vs culture grown in rich media then exchanged to minimal media 2 days prior to harvest.