Site-Specific Covalent Labeling of DNA Substrates by an RNA Transglycosylase

Bacterial tRNA guanine transglycosylases (TGTs) catalyze the exchange of guanine for the 7-deazaguanine queuine precursor, prequeuosine1 (preQ1). While the native nucleic acid substrate for bacterial TGTs is the anticodon loop of queuine-cognate tRNAs, the minimum recognition sequence for the enzyme is a structured hairpin containing the target G nucleobase in a "UGU" loop motif. Previous work has established an RNA modification system, RNA-TAG, in which Escherichia coli TGT exchanges the target G on an RNA of interest for chemically modified preQ1 substrates linked to a small-molecule reporter such as biotin or a fluorophore. While extending the substrate scope of RNA transglycosylases to include DNA would enable numerous applications, it has been previously reported that TGT is incapable of modifying native DNA. Here, we demonstrate that TGT can in fact recognize and label specific DNA substrates. Through iterative testing of rationally mutated DNA hairpin sequences, we determined the minimal sequence requirements for transglycosylation of unmodified DNA by E. coli TGT. Controlling steric constraint in the DNA hairpin dramatically affects labeling efficiency, and, when optimized, can lead to near-quantitative site-specific modification. We demonstrate the utility of our newly developed DNA-TAG system by rapidly synthesizing probes for fluorescent Northern blotting of spliceosomal U6 RNA and RNA FISH visualization of the long noncoding RNA, metastasis-associated lung adenocarcinoma transcript 1 (MALAT1). The ease and convenience of the DNA-TAG system will provide researchers with a tool for accessing a wide variety of versatile and affordable modified DNA substrates

Proteomics-based screening of the endothelial heparan sulfate interactome reveals that C-type lectin 14a (CLEC14A) is a heparin-binding protein.

Animal cells express heparan sulfate proteoglycans that perform many important cellular functions by way of heparan sulfate-protein interactions. The identification of membrane heparan sulfate-binding proteins is challenging because of their low abundance and the need for extensive enrichment. Here, we report a proteomics workflow for the identification and characterization of membrane-anchored and extracellular proteins that bind heparan sulfate. The technique is based on limited proteolysis of live cells in the absence of denaturation and fixation, heparin-affinity chromatography, and high-resolution LC-MS/MS, and we designate it LPHAMS. Application of LPHAMS to U937 monocytic and primary murine and human endothelial cells identified 55 plasma membrane, extracellular matrix, and soluble secreted proteins, including many previously unidentified heparin-binding proteins. The method also facilitated the mapping of the heparin-binding domains, making it possible to predict the location of the heparin-binding site. To validate the discovery feature of LPHAMS, we characterized one of the newly-discovered heparin-binding proteins, C-type lectin 14a (CLEC14A), a member of the C-type lectin family that modulates angiogenesis. We found that the C-type lectin domain of CLEC14A binds one-to-one to heparin with nanomolar affinity, and using molecular modeling and mutagenesis, we mapped its heparin-binding site. CLEC14A physically interacted with other glycosaminoglycans, including endothelial heparan sulfate and chondroitin sulfate E, but not with neutral or sialylated oligosaccharides. The LPHAMS technique should be applicable to other cells and glycans and provides a way to expand the repertoire of glycan-binding proteins for further study

Proteomics-based screening of the endothelial heparan sulfate interactome reveals that C-type lectin 14a (CLEC14A) is a heparin-binding protein.

Animal cells express heparan sulfate proteoglycans that perform many important cellular functions by way of heparan sulfate-protein interactions. The identification of membrane heparan sulfate-binding proteins is challenging because of their low abundance and the need for extensive enrichment. Here, we report a proteomics workflow for the identification and characterization of membrane-anchored and extracellular proteins that bind heparan sulfate. The technique is based on limited proteolysis of live cells in the absence of denaturation and fixation, heparin-affinity chromatography, and high-resolution LC-MS/MS, and we designate it LPHAMS. Application of LPHAMS to U937 monocytic and primary murine and human endothelial cells identified 55 plasma membrane, extracellular matrix, and soluble secreted proteins, including many previously unidentified heparin-binding proteins. The method also facilitated the mapping of the heparin-binding domains, making it possible to predict the location of the heparin-binding site. To validate the discovery feature of LPHAMS, we characterized one of the newly-discovered heparin-binding proteins, C-type lectin 14a (CLEC14A), a member of the C-type lectin family that modulates angiogenesis. We found that the C-type lectin domain of CLEC14A binds one-to-one to heparin with nanomolar affinity, and using molecular modeling and mutagenesis, we mapped its heparin-binding site. CLEC14A physically interacted with other glycosaminoglycans, including endothelial heparan sulfate and chondroitin sulfate E, but not with neutral or sialylated oligosaccharides. The LPHAMS technique should be applicable to other cells and glycans and provides a way to expand the repertoire of glycan-binding proteins for further study