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1. Enzymatic Synthesis of Glycosphingolipids: A Review

   https://doi.org/10.1055/a-1426-4451  

   Li, Qingjiang; Guo, Zhongwu (June 2021, Synthesis)

   null (Ed.)

   Abstract Glycosphingolipids (GSLs) are the major vertebrate glycolipids, which contain two distinctive moieties, a glycan and a ceramide, stitched together by a β-glycosidic linkage. The hydrophobic lipid chains of ceramide can insert into the cell membrane to form ‘lipid rafts’ and anchor the hydrophilic glycan onto the cell surface to generate microdomains and function as signaling molecules. GSLs mediate signal transduction, cell interactions, and many other biological activities, and are also related to many diseases. To meet the need of biological studies, chemists have developed various synthetic methodologies to access GSLs. Among them, the application of enzymes to GSL synthesis has witnessed significant advancements in the past decades. This short review briefly summarizes the history and progress of enzymatic GSL synthesis. 1 Introduction 1.1 The Glycosphingolipid Structure 1.2 GSL Biosynthesis 1.3 Functions and Biological Significance 1.4 Overview of GSL Synthesis 1.5 Scope of the Review 2 Glycotransferases for GSL Synthesis 3 Glycosynthases for GSL Synthesis 4 Enzymatic Synthesis of Ceramide 5 Conclusion 

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2. Diverse allyl glucosinolate catabolites independently influence root growth and development

   https://doi.org/10.1104/pp.20.00170  

   Katz, Ella; Bagchi, Rammyani; Jeschke, Verena; Rasmussen, Alycia R.; Hopper, Aleshia; Burow, Meike; Estelle, Mark; Kliebenstein, Daniel J. (April 2020, Plant Physiology)

   Glucosinolates (GSLs) are sulfur-containing defense metabolites produced in the Brassicales, 29 including the model plant Arabidopsis (Arabidopsis thaliana). Previous work suggests that 30 specific GSLs may function as signals to provide direct feedback regulation within the plant to 31 calibrate defense and growth, including allyl-GSL, a defense metabolite and one of the most 32 widespread GSLs in Brassicaceae that has also been associated with growth inhibition. Here we 33 show that at least three separate potential catabolic products of allyl-GSL or closely related 34 compounds affect growth and development by altering different mechanisms influencing plant 35 development. Two of the catabolites, raphanusamic acid and 3-butenoic acid, differentially affect 36 processes downstream of the auxin signaling cascade. Another catabolite, acrylic acid, affects 37 meristem development by influencing the progression of the cell cycle. These independent 38 signaling events propagated by the different catabolites enable the plant to execute a specific 39 response that is optimal to any given environment. 

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3. ELONGATED HYPOCOTYL 5 interacts with HISTONE DEACETYLASE 9 to suppress glucosinolate biosynthesis in Arabidopsis

   https://doi.org/10.1093/plphys/kiae284  

   Choi, Dasom; Kim, Seong-Hyeon; Choi, Da-Min; Moon, Heewon; Kim, Jeong-Il; Huq, Enamul; Kim, Dong-Hwan (May 2024, Plant Physiology)

   Abstract Glucosinolates (GSLs) are defensive secondary metabolites produced by Brassicaceae species in response to abiotic and biotic stresses. The biosynthesis of GSL compounds and the expression of GSL-related genes are highly modulated by endogenous signals (i.e. circadian clocks) and environmental cues, such as temperature, light, and pathogens. However, the detailed mechanism by which light signaling influences GSL metabolism remains poorly understood. In this study, we found that a light-signaling factor, ELONGATED HYPOCOTYL 5 (HY5), was involved in the regulation of GSL content under light conditions in Arabidopsis (Arabidopsis thaliana). In hy5-215 mutants, the transcript levels of GSL pathway genes were substantially upregulated compared with those in wild-type (WT) plants. The content of GSL compounds was also substantially increased in hy5-215 mutants, whereas 35S::HY5-GFP/hy5-215 transgenic lines exhibited comparable levels of GSL-related transcripts and GSL content to those in WT plants. HY5 physically interacts with HISTONE DEACETYLASE9 and binds to the proximal promoter region of MYB29 and IMD1 to suppress aliphatic GSL biosynthetic processes. These results demonstrate that HY5 suppresses GSL accumulation during the daytime, thus properly modulating GSL content daily in Arabidopsis plants. 

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4. Transamidation of N-acyl-glutarimides with amines

   Liu, Yongmei; Achtenhagen, Marcel; Liu, Ruzhang; Szostak, Michal (February 2018, Organic & biomolecular chemistry)

   The development of new transamidation reactions for the synthesis of amides is an important and active area of research due to the central role of amide linkage in various fields of chemistry. Herein, we report a new method for transamidation of N-acyl-glutarimides with amines under mild, metal-free conditions that relies on amide bond twist to weaken amidic resonance. A wide range of amines and functional groups, including electrophilic substituents that would be problematic in metal-catalyzed protocols, are tolerated under the reaction conditions. Mechanistic experiments implicate the amide bond twist, thermodynamic stability of the tetrahedral intermediate and leaving group ability of glutarimide as factors controlling the reactivity of this process. The method further establishes the synthetic utility of N-acyl-glutarimides as bench-stable, twist-perpendicular, amide-based reagents in acyl-transfer reactions by a metal-free pathway. The origin of reactivity of N-acyl-glutarimides in metal-free and metal-catalyzed processes is discussed and compared. 

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5. Caulobacter crescentus Adapts to Phosphate Starvation by Synthesizing Anionic Glycoglycerolipids and a Novel Glycosphingolipid

   https://doi.org/10.1128/mBio.00107-19  

   Stankeviciute, Gabriele; Guan, Ziqiang; Goldfine, Howard; Klein, Eric A. (April 2019, mBio)

   Shuman, Howard A. (Ed.)

   ABSTRACT Caulobacter crescentus adapts to phosphate starvation by elongating its cell body and a polar stalk structure. The stalk is an extension of the Gram-negative envelope containing inner and outer membranes as well as a peptidoglycan cell wall. Cellular elongation requires a 6- to 7-fold increase in membrane synthesis, yet phosphate limitation would preclude the incorporation of additional phospholipids. In the place of phospholipids, C. crescentus can synthesize several glycolipid species, including a novel glycosphingolipid (GSL-2). While glycosphingolipids are ubiquitous in eukaryotes, the presence of GSL-2 in C. crescentus is surprising since GSLs had previously been found only in Sphingomonas species, in which they play a role in outer membrane integrity. In this paper, we identify three proteins required for GSL-2 synthesis: CcbF catalyzes the first step in ceramide synthesis, while Sgt1 and Sgt2 sequentially glycosylate ceramides to produce GSL-2. Unlike in Sphingomonas , GSLs are nonessential in C. crescentus ; however, the presence of ceramides does contribute to phage resistance and susceptibility to the cationic antimicrobial peptide polymyxin B. The identification of a novel lipid species specifically produced upon phosphate starvation suggests that bacteria may be able to synthesize a wider variety of lipids in response to stresses than previously observed. Uncovering these lipids and their functional relevance will provide greater insight into microbial physiology and environmental adaptation. IMPORTANCE Bacteria adapt to environmental changes in a variety of ways, including altering their cell shape. Caulobacter crescentus adapts to phosphate starvation by elongating its cell body and a polar stalk structure containing both inner and outer membranes. While we generally think of cellular membranes being composed largely of phospholipids, cellular elongation occurs when environmental phosphate, and therefore phospholipid synthesis, is limited. In order to adapt to these environmental constraints, C. crescentus synthesizes several glycolipid species, including a novel glycosphingolipid. This finding is significant because glycosphingolipids, while ubiquitous in eukaryotes, are extremely rare in bacteria. In this paper, we identify three proteins required for GSL-2 synthesis and demonstrate that they contribute to phage resistance. These findings suggest that bacteria may synthesize a wider variety of lipids in response to stresses than previously observed. 

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