OGT (O-GlcNAc Transferase) Selectively Modifies Multiple Residues Unique to Lamin A.

The LMNA gene encodes lamins A and C with key roles in nuclear structure, signaling, gene regulation, and genome integrity. Mutations in LMNA cause over 12 diseases ('laminopathies'). Lamins A and C are identical for their first 566 residues. However, they form separate filaments in vivo, with apparently distinct roles. We report that lamin A is ß-O-linked N-acetylglucosamine-(O-GlcNAc)-modified in human hepatoma (Huh7) cells and in mouse liver. In vitro assays with purified O-GlcNAc transferase (OGT) enzyme showed robust O-GlcNAcylation of recombinant mature lamin A tails (residues 385⁻646), with no detectable modification of lamin B1, lamin C, or 'progerin' (Δ50) tails. Using mass spectrometry, we identified 11 O-GlcNAc sites in a 'sweet spot' unique to lamin A, with up to seven sugars per peptide. Most sites were unpredicted by current algorithms. Double-mutant (S612A/T643A) lamin A tails were still robustly O-GlcNAc-modified at seven sites. By contrast, O-GlcNAcylation was undetectable on tails bearing deletion Δ50, which causes Hutchinson⁻Gilford progeria syndrome, and greatly reduced by deletion Δ35. We conclude that residues deleted in progeria are required for substrate recognition and/or modification by OGT in vitro. Interestingly, deletion Δ35, which does not remove the majority of identified O-GlcNAc sites, does remove potential OGT-association motifs (lamin A residues 622⁻625 and 639⁻645) homologous to that in mouse Tet1. These biochemical results are significant because they identify a novel molecular pathway that may profoundly influence lamin A function. The hypothesis that lamin A is selectively regulated by OGT warrants future testing in vivo, along with two predictions: genetic variants may contribute to disease by perturbing OGT-dependent regulation, and nutrient or other stresses might cause OGT to misregulate wildtype lamin A.

New insights: A role for O-GlcNAcylation in diabetic complications.

Diabetes is a debilitating metabolic disease that is riddled with complications that can cause blindness, renal failure, nerve damage, and cardiovascular disease. Poor glycemic control is thought to be a key initiator in the progression of diabetic complications. Hyperglycemia has been shown to increase flux through the hexosamine biosynthetic pathway (HBP) to initiate many of the toxic effects of glucose. The major endpoint of the HBP is the formation of uridine diphosphate ß-D-N-acetylglucosamine (UDP-GlcNAc), the donor for protein O-GlcNAcylation, and complex extracellular glycosylation. O-GlcNAcylation is a dynamic nutrient sensitive post-translational modification that is characterized by the addition of single ß-D-N-acetylglucosamine to the serine and/or threonine residues of almost every functional class of protein. O-GlcNAc is extremely abundant and cycles on and off proteins by the concerted action of a transferase and a hydrolase. O-GlcNAc serves as a nutrient/stress sensor regulating several processes, such as signaling, transcription, cytoskeletal dynamics, and cell division. Altered O-GlcNAc signaling is directly involved in the pathogenesis of diabetes and new insights are revealing the importance of O-GlcNAc in diabetic complications. The goal of this review is to summarize O-GlcNAcylation, to present the current evidence for the role of O-GlcNAc in diabetic complications, and discuss conclusions and future directions for research on O-GlcNAc in the progression of diabetic complications.

Multi-faceted substrate specificity of heparanase.

Heparan sulfate is a highly sulfated polysaccharide abundantly present in the extracellular matrix. Heparan sulfate consists of a disaccharide repeating unit of glucosamine and glucuronic and iduronic acid residues. The functions of heparan sulfate are largely dictated by its size as well as the sulfation patterns. Heparanase is an enzyme that cleaves heparan sulfate polysaccharide into smaller fragments, regulating the functions of heparan sulfate. Understanding the substrate specificity plays a critical role in dissecting the biological functions of heparanase and heparan sulfate. The prevailing view is that heparanase recognizes specific sulfation patterns in heparan sulfate. However, emerging evidence suggests that heparanase is capable of varying its substrate specificities depending on the saccharide structures around the cleavage site. The plastic substrate specificity suggests a complex role of heparanase in regulating the structures of heparan sulfate in matrix biology.

Unraveling the specificity of heparanase utilizing synthetic substrates.

Heparanase is a promising anticancer target because of its involvement in cancer invasion and metastasis. Heparanase cleaves heparan sulfate (HS), a sulfated polysaccharide, and activates a series of HS-mediated cell proliferation and angiogenesis processes. Understanding the substrate specificity of heparanase will aid the discovery of heparanase inhibitors. Here, we sought to determine the specificity of heparanase using synthetic polysaccharide substrates. The substrates were prepared using purified HS biosynthetic enzymes. Using these substrates, we were able to dissect the structural moieties required for heparanase. Our data suggest that heparanase cleaves the linkage between a GlcA unit and an N-sulfo glucosamine unit carrying either a 3-O-sulfo or a 6-O-sulfo group. In addition, heparanase cleaves the linkage of a GlcA unit and N-sulfo glucosamine unit with a 2-O-sulfated GlcA residue, not a 2-O-sulfated IdoA residue, in proximity. We also discovered that the polysaccharide with repeating disaccharide units of IdoA2S-GlcNS inhibits the activity of heparanase. Our findings advance the understanding of the substrate specificity of heparanase and identify a lead compound for developing polysaccharide-based heparanase inhibitors.

Mitral valvular interstitial cells demonstrate regional, adhesional, and synthetic heterogeneity.

BACKGROUND/AIMS: Because various regions of the mitral valve contain distinctive extracellular matrix enabling the tissues to withstand diverse mechanical environments, we investigated phenotype and matrix production of porcine valvular interstitial cells (VICs) from different regions. METHODS: VICswere isolated from the chordae (MCh), the center of the anterior leaflet (AlCtr), and the posterior leaflet free edge (PlFree), then assayed for metabolic, growth, and adhesion rates; collagen and glycosaminoglycan (GAG) production, and phenotype using biochemical assays, flow cytometry, and immunocytochemistry. RESULTS: The AlCtr VICs exhibited the fastest metabolism but slowest growth. PlFree cells grew the fastest, but demonstrated the least smooth muscle alpha-actin, vimentin, and internal complexity. AlCtr VICs secreted less collagen into the culture medium but more 4-sulfated GAGs than other cells. Adhesion-based separation resulted in altered secretion of sulfated GAGs by MCh and AlCtr cells but not by the PlFree cells. CONCLUSIONS: VICs isolated from various regions of the mitral valve demonstrate phenotypic differences in culture, corresponding to the ability of the mitral valve to accommodate the physical stresses or altered hemodynamics that occur with injury or disease. Further understanding of VIC and valve mechanobiology could lead to novel medical or tissue engineering approaches to treat valve diseases.