Deep evolutionary analysis reveals the design principles of fold A glycosyltransferases

Taujale, Rahil; Venkat, Aarya; Huang, Liang-Chin; Yeung, Wayland; Rasheed, Khaled; Edison, Arthur S.; Moremen, Kelley W.; Kannan, Natarajan

doi:10.1101/2019.12.31.891697

Cited by 15 publications

(50 citation statements)

References 48 publications

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“…The use of unique acceptor binding loop insertions in GT-B fold fucosyltransferases is highly reminiscent of hypervariable substrate binding loops in the evolution of GT-A fold glycosyltransferases (32,102,103). In contrast to the two Rossmann domains in GT-B fold enzymes, GT-A fold glycosyltransferases have a single, conserved Rossmann fold core and employ proximal residues for donor interactions, while more divergent extended loop insertions are free to rapidly evolve and diversify novel acceptor specificities (32,102,103). This rapid evolution of the loop insertions is constrained by the necessity of positioning the acceptor nucleophile for attack and access to a catalytic base for nucleophile activation relative to the C1 of the sugar donor.…”

Section: Catalytic Mechanism and Evolution Of Modular Substrate Recogmentioning

confidence: 99%

“…While a general understanding of GT-A fold glycosyltransferase evolution is emerging (32,102,103), a parallel understanding of GT-B fold enzymes has lagged behind largely because of their more complex domain architectures and fewer determined protein structures in complex with substrate analogs. However, evolutionary parallels between the two protein fold classes are now evident and further insights into selective substrate recognition among the broader collection of GT-B glycosyltransferases will expand our understanding of how diverse glycan structures are elaborated in biological systems.…”

Section: Catalytic Mechanism and Evolution Of Modular Substrate Recogmentioning

confidence: 99%

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Characterizing human α-1,6-fucosyltransferase (FUT8) substrate specificity and structural similarities with related fucosyltransferases

Boruah

Kadirvelraj

Liu

et al. 2020

Journal of Biological Chemistry

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Mammalian Asn-linked glycans are extensively processed as they transit the secretory pathway to generate diverse glycans on cell surface and secreted glycoproteins. Additional modification of the glycan core by α-1,6-fucose addition to the innermost GlcNAc residue (core fucosylation) is catalyzed by an α-1,6-fucosyltransferase (FUT8). The importance of core fucosylation can be seen in the complex pathological phenotypes of FUT8 null mice, which display defects in cellular signaling, development, and subsequent neonatal lethality. Elevated core fucosylation has also been identified in several human cancers. However, the structural basis for FUT8 substrate specificity remains unknown. Here, using various crystal structures of FUT8 in complex with a donor substrate analog, and with four distinct glycan acceptors, we identify the molecular basis for FUT8 specificity and activity. The ordering of three active site loops corresponds to an increased occupancy for bound GDP, suggesting an induced-fit folding of the donor binding subsite. Structures of the various acceptor complexes were compared with kinetic data on FUT8 active site mutants and with specificity data from a library of glycan acceptors to reveal how binding site complementarity and steric hindrance can tune substrate affinity. The FUT8 structure was also compared with other known fucosyltransferases to identify conserved and divergent structural features for donor and acceptor recognition and catalysis. These data provide insights into the evolution of modular templates for donor and acceptor recognition among GT-B fold glycosyltransferases in the synthesis of diverse glycan structures in biological systems.

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Section: Catalytic Mechanism and Evolution Of Modular Substrate Recogmentioning

confidence: 99%

Section: Catalytic Mechanism and Evolution Of Modular Substrate Recogmentioning

confidence: 99%

Characterizing human α-1,6-fucosyltransferase (FUT8) substrate specificity and structural similarities with related fucosyltransferases

Boruah

Kadirvelraj

Liu

et al. 2020

Journal of Biological Chemistry

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“…However, in the 3D structure, the G residue of motif III is located far from the active site. The fourth conserved motif GxxYxxS (motif IV) found in all GT31 (Figure 3) constitutes the C-terminus part of a flexible G-loop, and the conserved glycine residue is involved in donor binding (Taujale et al 2020), and the first G residue of motif IV is located near the active site. In addition, the conserved aromatic aa residues in GT31 motifs II, III and IV were found to be well aligned in the MFNG structures (PDB 2J0A and 2J0B with UDP and Mn) suggesting their structural importance.…”

Section: First Criterion: Genomic Organization Of Vertebrate Gt31 Genesmentioning

confidence: 99%

“…The last conserved motif (motif V) (E/D)DVxxGx(W/C) is located at the C-terminus part of the GT31, except for the CH sequences. This conserved motif together with the DxD motif is involved in catalytic functions of GT-A fold inverting GTs (Taujale et al 2020). The MFNG structure (PDB 2J0B) was solved with UDP but without the substrate.…”

Section: First Criterion: Genomic Organization Of Vertebrate Gt31 Genesmentioning

confidence: 99%

A phylogenetic view and functional annotation of the animal β1,3-glycosyltransferases of the GT31 CAZy family

2020

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The formation of β1,3-linkages on animal glycoconjugates is catalyzed by a subset of β1,3-glycosyltransferases grouped in the CAZy family GT31. This family represents an extremely diverse set of β1,3-N-acetylglucosaminyltransferases (B3GNTs and FNGs), β1,3-N-acetylgalactosaminyltransferases (B3GALNTs), β1,3-galactosyltransferases (B3GALTs and C1GALTs), β1,3-glucosaminyltransferase (B3GLCT), and β1,3-glucuronyl acid transferases (B3GLCATs or CHs). The mammalian enzymes were particularly well-studied and shown to use a large variety of sugar donors and acceptor substrates leading to the formation of β1,3-linkages in various glycosylation pathways. In contrast, there are only a few studies related to other metazoan and lower vertebrates GT31 enzymes and the evolutionary relationships of these divergent sequences remain obscure. In this study, we used bioinformatics approaches to identify more than 920 of putative GT31 sequences in Metazoa, Fungi, and Choanoflagellata revealing their deep ancestry. Sequence-based analysis shed light on conserved motifs and structural features that are signatures of all the GT31. We leverage pieces of evidence from gene structure, phylogenetic and sequence-based analyses to identified two major subgroups of GT31 named FR and BGR and demonstrate the existence of ten orthologue groups in the Urmetazoa, the hypothetical last common ancestor of all animals. Finally, synteny and paralogy analysis unveiled the existence of 30 subfamilies in vertebrates, among which 5 are new and were named C1GALT2, C1GALT3, B3GALT8, B3GNT10, and B3GNT11. Altogether, these various approaches enabled us to propose the first comprehensive analysis of the metazoan GT31 disentangling their evolutionary relationships.

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“…New high-throughput experimental capabilities, including modular GTase expression systems [ 18 ], improved inference methods for determining enzymatic activity from mass spectrometry [ 11 , 19 , 20 ], and standardized glycan bioinformatic resources [ 21 , 22 , 23 ], are poised to yield comprehensive data on GTase substrate preferences. However, at present the most reliable data on GTases come from detailed studies of individual enzymes.…”

Section: Introductionmentioning

confidence: 99%

Promiscuity and specificity of eukaryotic glycosyltransferases

Biswas

Thattai

2020

Biochemical Society Transactions

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Glycosyltransferases are a large family of enzymes responsible for covalently linking sugar monosaccharides to a variety of organic substrates. These enzymes drive the synthesis of complex oligosaccharides known as glycans, which play key roles in inter-cellular interactions across all the kingdoms of life; they also catalyze sugar attachment during the synthesis of small-molecule metabolites such as plant flavonoids. A given glycosyltransferase enzyme is typically responsible for attaching a specific donor monosaccharide, via a specific glycosidic linkage, to a specific moiety on the acceptor substrate. However these enzymes are often promiscuous, able catalyze linkages between a variety of donors and acceptors. In this review we discuss distinct classes of glycosyltransferase promiscuity, each illustrated by enzymatic examples from small-molecule or glycan synthesis. We highlight the physical causes of promiscuity, and its biochemical consequences. Structural studies of glycosyltransferases involved in glycan synthesis show that they make specific contacts with ‘recognition motifs’ that are much smaller than the full oligosaccharide substrate. There is a wide range in the sizes of glycosyltransferase recognition motifs: highly promiscuous enzymes recognize monosaccharide or disaccharide motifs across multiple oligosaccharides, while highly specific enzymes recognize large, complex motifs found on few oligosaccharides. In eukaryotes, the localization of glycosyltransferases within compartments of the Golgi apparatus may play a role in mitigating the glycan variability caused by enzyme promiscuity.

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Deep evolutionary analysis reveals the design principles of fold A glycosyltransferases

Cited by 15 publications

References 48 publications

Characterizing human α-1,6-fucosyltransferase (FUT8) substrate specificity and structural similarities with related fucosyltransferases

Characterizing human α-1,6-fucosyltransferase (FUT8) substrate specificity and structural similarities with related fucosyltransferases

A phylogenetic view and functional annotation of the animal β1,3-glycosyltransferases of the GT31 CAZy family

Promiscuity and specificity of eukaryotic glycosyltransferases

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