Crown-ether-mediated crystal structures of the glycosyltransferase PaGT3 from Phytolacca americana.

Uridine diphosphate glycosyltransferases (UGTs) are ubiquitous enzymes that are involved in the glycosylation of small molecules. As glycosylation improves the water solubility and stability of hydrophobic compounds, interest in the use of UGTs for the synthesis of glycosides of poorly soluble compounds is increasing. While sugar-donor recognition in UGTs is conserved with the presence of a plant secondary product glycosyltransferase (PSPG) motif, the basis of the recognition of the sugar acceptor and the regioselectivity of the products is poorly understood owing to low sequence identity around the acceptor-binding region. PaGT3, a glycosyltransferase from the plant Phytolacca americana, can glycosylate a range of acceptors. To illustrate the structure-function relationship of PaGT3, its crystal structure was determined. The sugar-donor and sugar-acceptor binding pockets in PaGT3 were recognized by comparison of its structure with those of other UGTs. The key feature of PaGT3 was the presence of longer loop regions around the hydrophobic acceptor-binding pocket, which resulted in a flexible and wider acceptor binding pocket. In this study, PaGT3 crystals were grown by co-crystallization with 18-crown-6 ether or 15-crown-5 ether. The crown-ether molecule in the asymmetric unit was observed to form a complex with a metal ion, which was coordinated on two sides by the main-chain O atoms of Glu238 from two molecules of the protein. The crown ether-metal complex resembles a molecular glue that sticks two molecules of PaGT3 together to enhance crystal growth. Thus, this result provides an insight into the substrate-recognition strategy in PaGT3 for the study of glycosyltransferases. Additionally, it is shown that crown ether-metal ion complexes can be used as a molecular glue for the crystallization of proteins.

An Ambidextrous Polyphenol Glycosyltransferase PaGT2 from Phytolacca americana.

The glycosylation of small hydrophobic compounds is catalyzed by uridine diphosphate glycosyltransferases (UGTs). Because glycosylation is an invaluable tool for improving the stability and water solubility of hydrophobic compounds, UGTs have attracted attention for their application in the food, cosmetics, and pharmaceutical industries. However, the ability of UGTs to accept and glycosylate a wide range of substrates is not clearly understood due to the existence of a large number of UGTs. PaGT2, a UGT from Phytolacca americana, can regioselectively glycosylate piceatannol but has low activity toward other stilbenoids. To elucidate the substrate specificity and catalytic mechanism, we determined the crystal structures of PaGT2 with and without substrates and performed molecular docking studies. The structures have revealed key residues involved in substrate recognition and suggest the presence of a nonconserved catalytic residue (His81) in addition to the highly conserved catalytic histidine in UGTs (His18). The role of the identified residues in substrate recognition and catalysis is elucidated with the mutational assay. Additionally, the structure-guided mutation of Cys142 to other residues, Ala, Phe, and Gln, allows PaGT2 to glycosylate resveratrol with high regioselectivity, which is negligibly glycosylated by the wild-type enzyme. These results provide a basis for tailoring an efficient glycosyltransferase.

Structural analysis of a type 1 ribosome inactivating protein reveals multiple L­asparagine­N­acetyl­D­glucosamine monosaccharide modifications: Implications for cytotoxicity.

Pokeweed antiviral protein (PAP) belongs to the family of type I ribosome­inactivating proteins (RIPs): Ribotoxins, which function by depurinating the sarcin­ricin loop of ribosomal RNA. In addition to its antibacterial and antifungal properties, PAP has shown promise in antiviral and targeted tumor therapy owing to its ability to depurinate viral RNA and eukaryotic rRNA. Several PAP genes are differentially expressed across pokeweed tissues, with natively isolated seed forms of PAP exhibiting the greatest cytotoxicity. To help elucidate the molecular basis of increased cytotoxicity of PAP isoenzymes from seeds, the present study used protein sequencing, mass spectroscopy and X-ray crystallography to determine the complete covalent structure and 1.7 Å X­ray crystal structure of PAP­S1aci isolated from seeds of Asian pokeweed (Phytolacca acinosa). PAP­S1aci shares ~95% sequence identity with PAP­S1 from P. americana and contains the signature catalytic residues of the RIP superfamily, corresponding to Tyr72, Tyr122, Glu175 and Arg178 in PAP­S1aci. A rare proline substitution (Pro174) was identified in the active site of PAP­S1aci, which has no effect on catalytic Glu175 positioning or overall active­site topology, yet appears to come at the expense of strained main­chain geometry at the pre­proline residue Val173. Notably, a rare type of N­glycosylation was detected consisting of N­acetyl­D­glucosamine monosaccharide residues linked to Asn10, Asn44 and Asn255 of PAP­S1aci. Of note, our modeling studies suggested that the ribosome depurination activity of seed PAPs would be adversely affected by the N­glycosylation of Asn44 and Asn255 with larger and more typical oligosaccharide chains, as they would shield the rRNA­binding sites on the protein. These results, coupled with evidence gathered from the literature, suggest that this type of minimal N­glycosylation in seed PAPs and other type I seed RIPs may serve to enhance cytotoxicity by exploiting receptor­mediated uptake pathways of seed predators while preserving ribosome affinity and rRNA recognition.

[Antioxidative enzymes play key roles in cadmium tolerance of Phytolacca americana].

Phytolacca americana L. has the capacity to take up and accumulate to very high levels heavy metals such as Mn and Cd, and is used for phytoextraction of heavy metal contaminated soils. The role of antioxidative enzyme of Phytolacca americana in response to Cd stress is unknown. The 6-week-old seedlings of Phytolacca americana were exposed to half strength Hoagland solution with 200 micromol/L CdCl2 or 400 micromol/L CdCl2 for 4 days. The content of H2O2 and MDA, and electrolyte leakage increased, while the photosynthetic rate decreased, indicated that the oxidative damage induced by Cd stress in Phytolacca americana was one of the metal toxicity mechanism. The activities of SOD and POD increased rapidly with elevated Cd concentration and exposure time, CAT activity was stable in response to 200 micromol/L CdCl2 stress, and increased only at 3 d later upon 400 micromol/L CdCl2, treatment. Suggested that the enzymatic antioxidation capacity played important role in Cd tolerance of hyperaccumulator plant.