Glycans are known as the third major class of biopolymers, next to DNA and proteins. They cover the surfaces of many cells, serving as the 'face' of cells, whereby other biomolecules and viruses ...interact. The structure of glycans, however, differs greatly from DNA and proteins in that they are branched, as opposed to linear sequences of amino acids or nucleotides. Therefore, the storage of glycan information in databases, let alone their curation, has been a difficult problem. This has caused many duplicated efforts when integration is attempted between different databases, making an international repository for glycan structures, where unique accession numbers are assigned to every identified glycan structure, necessary. As such, an international team of developers and glycobiologists have collaborated to develop this repository, called GlyTouCan and is available at http://glytoucan.org/, to provide a centralized resource for depositing glycan structures, compositions and topologies, and to retrieve accession numbers for each of these registered entries. This will thus enable researchers to reference glycan structures simply by accession number, as opposed to by chemical structure, which has been a burden to integrate glycomics databases in the past.
Heparinases, enzymes that cleave heparin and heparan sulfate, are implicated in physiological and pathological functions ranging from wound healing to tumor metastasis and are useful in ...deheparinization therapies. We report the cloning of the heparinase I (EC 4.2.2.7) gene from Flavobacterium heparinum using PCR. Two degenerate oligonucleotides, based on the amino acid sequences derived from tryptic peptides of purified heparinase, were used to generate a 600-bp probe by PCR amplification using Flavobacterium genomic DNA as the template. This probe was used to screen a Flavobacterium genomic DNA library in pUC18. The open reading frame of heparinase I is 1152 bp in length, encoding a precursor protein of 43.8 kDa. Eleven of the tryptic peptides (≈35% of the total amino acids) mapped onto the open reading frame. The amino acid sequence reveals a consensus heparin binding domain and a 21-residue leader peptide with a characteristic Ala-(Xaa)-Ala cleavage site. Recombinant heparinase was expressed in Escherichia coli as a soluble protein, using the T7 polymerase pET expression system. The recombinant heparinase cleavage of heparin was identical to that of native heparinase.
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