The characterization of glycoprotein structure is becoming increasingly sophisticated, as regulatory agencies require multiple attributes to be measured during development, production, and formulation of biological drugs. Precise determination of N- and O-glycosylation, site occupancy, disulfide shuffling, misassembly, deamidation, oxidation, etc, require robust methods for sample preparation, to facilitate mass spectrometry analysis. Enzymes for glycan removal, along with specific proteases, are critical to these studies. Improved methods where glycosidases are combined, and/or coupled with labeling reactions or protease digestion, maximize reproducibility by eliminating handling errors. These methods, in turn, permit a more stringent definition of an original, biosimilar, or biobetter, facilitating formulation and process development innovations. We present in this poster new glycan removal protocols, including fast deglycosylation (using Rapid PNGase F) and deglycosylation of intact plant-derived glycoproteins (using PNGase Ar). These reactions were coupled with a simplified and versatile glycan labeling reaction by reductive amination, suitable for glycans lacking a glycosylamine end group. Also, glycosidase combinations were tested for complete N- and O-glycan removal, to facilitate proteomic analysis for glycoproteins that are heavily glycosylated. Finally, an enzyme mix containing PNGase F and Trypsin was used to prepare an IgG sample for peptide mapping. This abbreviated workflow maintained sensitivity and reproducibility
During replication, Okazaki fragment maturation is a fundamental process that joins discontinuously synthesized DNA fragments into a contiguous lagging strand. Efficient maturation prevents repeat sequence expansions, small duplications and generation of doublestranded DNA breaks.To address the components required for the process, Okazaki fragment maturation was reconstituted in vitro using purified proteins from Thermococcus species 9°N. The similarities to both bacterial and eukaryotic systems and evolutionary implications of archaeal Okazaki fragment maturation are discussed.
Uses hemimethylated DNA as substrate.
Recombinant His-tagged proteins expressed in Escherichia coli and purified by immobilized metal affinity chromatography (IMAC) are commonly co-eluted with native E. coli proteins, especially if the recombinant protein is expressed at a low level. The E. coli contaminants display high affinity to divalent nickel or cobalt ions, mainly due to the presence of clustered histidine residues or biologically relevant metal binding sites. To improve the final purity of expressed His-tagged protein, we engineered E. coli BL21(DE3) expression strains in which the most recurring contaminants are either expressed with an alternative tag or mutated to decrease their affinity to divalent cations. The current study presents the design, engineering and characterization of two E. coli BL21(DE3) derivatives, NiCo21(DE3) and NiCo22(DE3), which express the endogenous proteins SlyD, Can, ArnA and optionally AceE fused at their C-terminus to a chitin binding domain (CBD), and the protein GlmS with six surface histidines replaced by alanines. We show that each E. coli CBD-tagged protein remains active and can be efficiently eliminated from an IMAC elution fraction using a chitin column flow-through step, while the modification of GlmS results in loss of affinity for nickel-containing resin. The “NiCo” strains uniquely complement existing methods for improving the purity of recombinant His-tagged protein.
SwaI, a Type IIP restriction enzyme from Staphylococcus warneri cleaves the symmetric sequence ATTT|AAAT, producing fragments with blunt ends (‘|’ = cleavage site). We solved the crystal structure of SwaI alone, of SwaI bound to uncleaved DNA in the presence of Ca2+ ions, and of SwaI bound to cleaved DNA in the presence of Mg2+ ions. We describe these structures, and compare them to that of PacI, which cleaves the related 8-bp sequence, TTAAT|TAA.
Transmitted by insect vectors, human nematode-based filariasis causes debilitating diseases affecting nearly 150 million people with 1.2 billion individuals at risk in 80 countries. Genomic sequencing has revealed that many human filarial nematodes, such as Wuchereria bancrofti, Brugia malayi and B. timori, (causative agents of lymphatic filariasis (LF)) and Onchocerca volvulus (causative agent of onchocerciasis (river blindness)) contain the obligate endosymbiont, Wolbachia. Genome sequencing of B. malayi (Bm) and its Wolbachia (wBm) identified a number of metabolites implicated in the host-endosymbiont interaction, one of which was heme, a co-factor in a number of enzymes and essential to many biological processes. Although the Bm genome encodes a functional ferrochelatase gene (the final step in the heme biosynthetic pathway and a product of lateral gene transfer), like other nematodes, it is incapable of synthesizing heme. However, the wBm genome contains a functional heme synthesis pathway, leading to the hypothesis that wBm may supply Bm with heme
Help us celebrate our 50th anniversary! We have hidden 1,000 golden butterflies and are waiting for you to find them. They can be anywhere that you find NEB! Beginning April 15th, be sure to visit our website and tables at tradeshows and events you are attending. Visit our social media channels frequently for tips on where we have hidden the butterflies – and once you find one, either click or scan the code to be eligible for a 50th anniversary prize pack, as well as a grand prize trip to NEB headquarters in Ipswich, MA!.
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