Your search keyword '"Faik, Ahmed"' showing total 3 results

1. Review: Plant cell wall biochemical omics: The high-throughput biochemistry for polysaccharide biosynthesis.

Author

Faik, Ahmed and Held, Michael

Subjects

*PLANT cell walls, *BIOCHEMISTRY, *BIOSYNTHESIS, *BOTANICAL chemistry, *PROTEIN microarrays, *ANALYTICAL chemistry

Abstract

• Biochemistry of plant cell wall biosynthesis lacks high-throughput methods. • Overview of new high-throughput technologies to benefit plant cell wall biosynthesis. • Use of protein array technology in enzyme assays and protein–protein interaction. • Adapting recent advances in analytical chemistry for rapid product identification. Progress in the functional biochemical analysis of plant glycosyltransferases (GTs) has been slow because plant GTs are generally membrane proteins, operate as part of larger, multimeric complexes, and utilize a vast complexity of substrate acceptors. Therefore, the field would benefit from development of adequate high throughput expression as well as product detection and characterization techniques. Here we review current approaches to tackle such obstacles and suggest a new path forward: nucleic acid programmable protein arrays (NAPPA) with liquid sample desorption ionization (LS-DESI-MS) mass spectrometry. NAPPA utilizes in vitro transcription and translation to produce epitope-tagged fusion proteins from cloned GT cDNAs. LS-DESI is a soft ionization technique that allows rapid and sensitive MS-based product characterization in situ. Coupling both approaches provides the opportunity to examine individual GT functions as well as protein–protein interactions. Furthermore, advances in automated oligosaccharide synthesis and lipid nanodisc technology should allow testing of plant GT activity in presence of numerous substrate acceptors and lipid environments in a high throughput fashion. Thus, NAPPA-DESI-MS has great potential to make headway in biochemical characterization of the large number of plant GTs. [ABSTRACT FROM AUTHOR]

Published

2019

2. New insights on β-glycan synthases using in vitro GT-array (i-GT-ray) platform.

Author

Bhattarai, Matrika, Wang, Qi, Hussain, Zawar, Tanim-Al-Hassan, Md, Chen, Hao, and Faik, Ahmed

Subjects

*TRANSMEMBRANE domains, *PLANT cell walls, *MEMBRANE proteins, *SYNTHASES, *FUNCTIONAL genomics, *HEMICELLULOSE, *CELLULOSE synthase

Abstract

Cellulose and hemicellulose are the major structural β-glycan polysaccharides in cell walls of land plants. They are characterized by a backbone of β-(1,3)- and/or β-(1,4)-linked sugars such as glucose, mannose, or xylose. The backbones of these polymers are produced by processive glycosyltransferases (GTs) called synthases having multiple transmembrane domains anchoring them to the membrane. Thus, they are among the most difficult membrane proteins to test in vitro and to purify. Recently, we developed an in vitro GT-array (i -GTray) platform and showed that non-processive type II membrane GTs could be produced via cell-free system in a soluble and active form and tested in this platform. To determine whether i -GT-ray platform is adequate for the production and testing of β-glycan synthases, we tested five synthases involved in cellulose, xyloglucan, (gluco)mannan, and β-(1,3)(1,4)-mixed-linkage glucan synthesis. Our results revealed unsuspected features of these enzymes. For example, all these synthases could be produced in a soluble and active form and are active in the absence of detergent or membrane lipids, and none of them required a primer for initiation of synthesis. All synthases produced ethanol-insoluble products that were susceptible to the appropriate hydrolases (i.e., cellulase, lichenase, mannanase). Using this platform, we showed that At CslC4 and At XXT1 interact directly to form an active xyloglucan synthase that produced xylosylated cello-oligosaccharides (up to three xylosyl residues) when supplied with UDP-Glc and UDP-Xyl. i -GTray platform represents a simple and powerful functional genomics tool for discovery of new insights of synthase activities and can be adapted to other enzymes. • Processive glycosyltransferases (synthases) are active on i -GT-ray platform. • Synthases did not require detergent or membrane lipids for activity on i -GT-ray. • No synthases required a primer to initiate polymer synthesis in vitro. • At CslC4 and At XXT1 interact directly in vitro. • At CslC4/ At XXT1 complex is active and produces xylosylated cello-oligosaccharides. [ABSTRACT FROM AUTHOR]

Published

2024

3. Composition, Assembly, and Trafficking of a Wheat Xylan Synthase Complex.

Author

Nan Jiang, Wiemels, Richard E., Soya, Aaron, Whitley, Rebekah, Held, Michael, and Faik, Ahmed

Subjects

*CHEMICAL composition of plants, *WHEAT, *XYLANS, *PLANT cell walls, *BIOSYNTHESIS, *COMPLEX compounds, *SYNTHASES

Abstract

Xylans play an important role in plant cell wall integrity and have many industrial applications. Characterization of xylan synthase (XS) complexes responsible for the synthesis of these polymers is currently lacking. We recently purified XS activity from etiolated wheat (Triticum aestivum) seedlings. To further characterize this purified activity, we analyzed its protein composition and assembly. Proteomic analysis identified six main proteins: two glycosyltransferases (GTs) TaGT43-4 and TaGT47-13; two putative mutases (TaGT75-3 and TaGT75-4) and two non-GTs; a germin-like protein (TaGLP); and a vernalization related protein (TaVER2). Coexpression of TaGT43-4, TaGT47-13, TaGT75-3, and TaGT75-4 in Pichia pastoris confirmed that these proteins form a complex. Confocal microscopy showed that all these proteins interact in the endoplasmic reticulum (ER) but the complexes accumulate in Golgi, and TaGT43-4 acts as a scaffold protein that holds the other proteins. Furthermore, ER export of the complexes is dependent of the interaction between TaGT43-4 and TaGT47-13. Immunogold electron microscopy data support the conclusion that complex assembly occurs at specific areas of the ER before export to the Golgi. A di-Arg motif and a long sequence motif within the transmembrane domains were found conserved at the NH2-terminal ends of TaGT43-4 and homologous proteins from diverse taxa. These conserved motifs may control the forward trafficking of the complexes and their accumulation in the Golgi. Our findings indicate that xylan synthesis in grasses may involve a new regulatory mechanism linking complex assembly with forward trafficking and provide new insights that advance our understanding of xylan biosynthesis and regulation in plants. [ABSTRACT FROM AUTHOR]

Published

2016