Project description:New linker phosphoramidite reagents containing a cleavable 3'-ester linkage are used for attaching the first nucleoside to the surface of a solid- phase support. Inexpensive, underivatized amino supports, such as long chain alkylamine controlled-pore glass, can serve as universal supports. No modifications to phosphoramidite coupling conditions are required and, after synthesis, treatment with NH(4)OH releases the products with 3'-OH ends. No 3'-dephosphorylation is required. Phosphoramidite reagents containing a succinate and sulfonyl diethanol linkage between the nucleoside and phosphoramidite group are particularly advantageous and can be used to create both 3'-OH and 5'-phosphate ends on oligonucleotides. Reproducibility and quality of oligonucleotide synthesis is demonstrated for either column and 96-well plate formats on low-, medium- or high-loading CPG supports.

Project description:To develop a new form of DNA coupling under mild reaction and coupling conditions, DNA oligonucleotides were synthesized containing a 3' ribonucleotide. Upon reaction with millimolar sodium metaperiodate (NaIO4), the ribose is oxidized to a dialdehyde at pH 6.8. This reaction is complete in 30min, is quenched with millimolar sodium metabisulfite (Na2S2O5) and is then suitable for coupling to hydrazide-agarose supports. Coupling occurs with a half-time of 27min and 80% couples in 2h. The EP18 oligonucleotide which binds to the CAAT enhancer binding protein (C/EBP) was synthesized with a 3' ribose (rEP18) and coupled to hydrazide-agarose. The columns prepared show no significant loss of the oligonucleotide after 50 days. A crude bacterial extract from cells expressing a chimeric fusion protein of GFP-C/EBP was applied to the columns and eluted with different salt concentrations. The active protein elutes in 0.5M NaCl and SDS-PAGE/silver stained gels show a single major band which comigrates with GFP-C/EBP as well as three minor contaminants. This provides a new alternative way of coupling DNA to solid supports using mild chemistry which is non-detrimental to the DNA and can be performed if required in the presence of nuclear extract.

Project description:The SCAL linker, a safety catch linker, is amongst the most versatile linkers for solid phase synthesis. It was originally described in 1991 by Pátek and Lebl. Yet, its application has been hindered by the low yields of published synthetic routes. Over time, the exceptional versatility of this linker has been demonstrated in several applications of advanced solid phase synthesis of peptides and peptidomimetics. Recently, an updated synthesis of the original linker has also been presented at the 22nd American Peptide Symposium, comprising 10 steps. Herein, the design and synthesis of a next generation SCAL linker, SCAL-2, is reported. SCAL-2 features a simplified molecular architecture, which allows for a more efficient synthesis in 8 steps with superior yields. Both linkers, SCAL and SCAL-2 are compared in terms of their cleavage properties adding valuable information on how to best utilize the versatility of these linkers for solid phase synthesis.

Project description:Cancer immunosuppression involves cellular pathways appropriated by tumors to escape immune surveillance but are normally required for tissue homeostasis and repair, self-tolerance, and successful transplantation. Among these pathways, enzymes that degrade tryptophan and arginine are thought to suppress activated T cells in the tumor microenvironment and are therefore attractive drug targets. However, how amino acid metabolism controls the development and progression of cancer has remained elusive, since commonly used implantable tumor models may not faithfully recapitulate the complex cellular and biochemical interactions within tumor microenvironments. To address this, we generated a novel, penetrant autochthonous model of neuroblastoma to accurately quantify tumor growth non-invasively and simultaneously genetically manipulate the enzymes that mediate tryptophan and arginine metabolism, and the cells that express them. We established that tumor development and growth were dependent on infiltrating CCR2+ bone marrow-derived myeloid cells but independent of Stat6-dependent ‘M2’ macrophages. Macrophages can modulate CD4+ T cell activation, proliferation, and differentiation by consuming amino acids and forcing the T cells to remain in the G1 phase of the cell cycle. Indeed, we found that CD4+ T cells deprived of arginine increased Foxp3 expression and adopted a unique regulatory-like phenotype. Notably, depletion of CD4+ T cells like CCR2+ macrophages, virtually eliminated tumor formation. When rare tumors did form in CD4-depleted mice, they contained Foxp3+ CD8 T cells, suggesting regulatory T cell activity is a fundamental requirement for tumor development. When we ablated macrophage arginase 1 (Arg1), an enzyme that locally consumes arginine, in the tumor-prone background, almost no tumors were observed. Therefore, Arg1 and arginine metabolism form a pro-tumor pathway. We extended these findings to two pathways of programmed myeloid tryptophan metabolism (IDO1, IDO2, IL4i1). Like Arg1, expression of these enzymes was confined to myeloid cells in humans and mice, and each enzyme was independently essential for tumor formation and growth. The protective effects of genetic ablation of each myeloid amino acid pathways uniformly occurred early in tumor formation, arguing that a network of immune cells controlled by myeloid amino acid metabolism and CD4+ T cells is important for the origins of a pro-tumor environment. Our results establish an unappreciated potency of macrophage amino acid metabolism in promoting malignancy, and suggest that these pathways can be disabled by targeting of myeloid amino acid metabolism. OVA-specific CD4+ T cells were stimulated with peptide in the presence of APCs (CD3-depleted splenocytes) either in control complete RPMI-1640 (containing 10% dialyzed FBS) or in RPMI-1640 (containing 10% dialyzed FBS) containing 1% of the normal arginine levels (12uM) to characterize the effects of limited arginine availability on gene expression.

Project description:Quantitative real-time PCR represents a highly sensitive and powerful technology for the quantification of DNA. Although real-time PCR is well accepted as the gold standard in nucleic acid quantification, there is a largely unexplored area of experimental conditions that limit the application of the Ct method. As an alternative, our research team has recently proposed the Cy0 method, which can compensate for small amplification variations among the samples being compared. However, when there is a marked decrease in amplification efficiency, the Cy0 is impaired, hence determining reaction efficiency is essential to achieve a reliable quantification. The proposed improvement in Cy0 is based on the use of the kinetic parameters calculated in the curve inflection point to compensate for efficiency variations. Three experimental models were used: inhibition of primer extension, non-optimal primer annealing and a very small biological sample. In all these models, the improved Cy0 method increased quantification accuracy up to about 500% without affecting precision. Furthermore, the stability of this procedure was enhanced integrating it with the SOD method. In short, the improved Cy0 method represents a simple yet powerful approach for reliable DNA quantification even in the presence of marked efficiency variations.

Project description:N-glycosylation is a post-translational modification that plays a role in the trafficking and/or function of some membrane proteins. We have shown previously that N-glycosylation affected the function of some Kv1 voltage-gated potassium (K+) channels [Watanabe, Wang, Sutachan, Zhu, Recio-Pinto and Thornhill (2003) J. Physiol. (Cambridge, U.K.) 550, 51-66]. Kv1 channel S1-S2 linkers vary in length but their N-glycosylation sites are at similar relative positions from the S1 or S2 membrane domains. In the present study, by a scanning mutagenesis approach, we determined the allowed N-glycosylation sites on the Kv1.2 S1-S2 linker, which has 39 amino acids, by engineering N-glycosylation sites and assaying for glycosylation, using their sensitivity to glycosidases. The middle section of the linker (54% of linker) was glycosylated at every position, whereas both end sections (46% of linker) near the S1 or S2 membrane domains were not. These findings suggested that the middle section of the S1-S2 linker was accessible to the endoplasmic reticulum glycotransferase at every position and was in the extracellular aqueous phase, and presumably in a flexible conformation. We speculate that the S1-S2 linker is mostly a coiled-loop structure and that the strict relative position of native glycosylation sites on these linkers may be involved in the mechanism underlying the functional effects of glycosylation on some Kv1 K+ channels. The S3-S4 linker, with 16 amino acids and no N-glycosylation site, was not glycosylated when an N-glycosylation site was added. However, an extended linker, with an added N-linked site, was glycosylated, which suggested that the native linker was not glycosylated due to its short length. Thus other ion channels or membrane proteins may also have a high glycosylation potential on a linker but yet have similarly positioned native N-glycosylation sites among isoforms. This may imply that the native position of the N-glycosylation site may be important if the carbohydrate tree plays a role in the folding, stability, trafficking and/or function of the protein.

Project description:SNAP-25 is an essential component of SNARE complexes driving fast Ca2+-dependent exocytosis. Yet, the functional implications of the tandem-like structure of SNAP-25 are unclear. Here, we have investigated the mechanistic role of the acylated "linker" domain that concatenates the two SNARE motifs within SNAP-25. Refuting older concepts of an inert connector, our detailed structure-function analysis in murine chromaffin cells demonstrates that linker motifs play a crucial role in vesicle priming, triggering, and fusion pore expansion. Mechanistically, we identify two synergistic functions of the SNAP-25 linker: First, linker motifs support t-SNARE interactions and accelerate ternary complex assembly. Second, the acylated N-terminal linker segment engages in local lipid interactions that facilitate fusion triggering and pore evolution, putatively establishing a favorable membrane configuration by shielding phospholipid headgroups and affecting curvature. Hence, the linker is a functional part of the fusion complex that promotes secretion by SNARE interactions as well as concerted lipid interplay.

Project description:A new method for intramolecular oligosaccharide synthesis that is conceptually related to the general molecular clamp approach is introduced. Exceptional α-selectivity has been achieved in a majority of applications. Unlike other related concepts, this approach is based on the bisphenol A template, which allows one to connect multiple building blocks to perform templated oligosaccharide synthesis with complete stereoselectivity. This principle was demonstrated by the synthesis of an α,α-linked trisaccharide.

Project description:Compositions of pollutant-catabolic consortia and interactions between community members greatly affect the efficiency of pollutant catabolism. However, the relationships between community structure and efficiency of catabolic function in pollutant-catabolic consortia remain largely unknown. In this study, an original enrichment (AT) capable of degrading atrazine was obtained. And two enrichments - with a better/worse atrazine-degrading efficiency (ATB/ATW) - were derived from the original enrichment AT by continuous sub-enrichment with or without atrazine. Subsequently, an Arthrobacter sp. strain, AT5, that was capable of degrading atrazine was isolated from enrichment AT. The bacterial community structures of these three enrichments were investigated using high-throughput sequencing analysis of the 16S rRNA gene. The atrazine-degrading efficiency improved as the abundance of Arthrobacter species increased in enrichment ATB. The relative abundance of Arthrobacter was positively correlated with those of Hyphomicrobium and Methylophilus, which enhanced atrazine degradation via promoting the growth of Arthrobacter. Furthermore, six genera/families such as Azospirillum and Halomonas showed a significantly negative correlation with atrazine-degrading efficiency, as they suppressed atrazine degradation directly. These results suggested that atrazine-degrading efficiency was affected by not only the degrader but also some non-degraders in the community. The promotion and suppression of atrazine degradation by Methylophilus and Azospirillum/Halomonas, respectively, were experimentally validated in vitro, showing that shifts in both the composition and abundance in consortia can drive the change in the efficiency of catabolic function. This study provides valuable information for designing enhanced bioremediation strategies.

Project description:A simple and efficient synthetic glycosylation method suitable for use in solid-phase enzymic oligosaccharide synthesis and site-specific glycosylation of recombinant proteins to produce defined glycoforms is described. This strategy utilizes N-(beta-saccharide) haloacetamides for attaching oligosaccharides specifically to cysteine residues of proteins in solution to form neoglycoproteins. The alkylation reaction was tested using N-(beta-chitotriose) bromoacetamide and an unprotected synthetic hexapeptide containing a single cysteine residue. The glycosylated product was confirmed by amino acid and hexosamine analyses as well as laser desorption mass spectrometry. Similarly N-(beta-chitotriose) iodoacetamide was covalently linked to non-reduced BSA to produce a defined glycoform of this protein. The specific attachment of chitotriose at the single cysteine residue in non-reduced serum albumin was suggested by Ellman's assay for free thiols. This was verified by amino acid sequencing of tryptic glycopeptide derived from this neoglycoprotein. Multiple sugar attachment was accomplished using fully reduced serum albumin as demonstrated by the formation of two neoglycoproteins using iodoacetamide derivatives of galactose beta 1-3-N-acetylgalactosamine (Gal beta 1-3GalNAc) and the major xylose/fucose-class plant-type oligosaccharide of horseradish peroxidase. These two neoglycoproteins with an average of 18-21 sugar residues attached were assayed positively for binding to peanut agglutinin and a sugar-specific anti-(horseradish peroxidase) monoclonal antibody YZ1/2.23 respectively. Sialylation of the neoglycoprotein containing Gal beta 1-3GalNAc was accomplished using alpha-2,3-sialyltransferase and radiolabelled CMP-N-acetylneuraminic acid. Significantly, glycan attachment using this conjugation method is reversible as demonstrated by the release of oligosaccharides from these two neoglycoproteins using hydrazinolysis. Therefore this method could provide invaluable reagents for many glycobiological studies.