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1. Dissecting the regulatory roles of ORM proteins in the sphingolipid pathway of plants

   https://doi.org/10.1371/journal.pcbi.1008284  

   Alsiyabi, Adil; Solis, Ariadna Gonzalez; Cahoon, Edgar B.; Saha, Rajib (January 2021, PLOS Computational Biology)

   Salehi-Ashtiani, Kourosh (Ed.)

   Sphingolipids are a vital component of plant cellular endomembranes and carry out multiple functional and regulatory roles. Different sphingolipid species confer rigidity to the membrane structure, facilitate trafficking of secretory proteins, and initiate programmed cell death. Although the regulation of the sphingolipid pathway is yet to be uncovered, increasing evidence has pointed to orosomucoid proteins (ORMs) playing a major regulatory role and potentially interacting with a number of components in the pathway, including both enzymes and sphingolipids. However, experimental exploration of new regulatory interactions is time consuming and often infeasible. In this work, a computational approach was taken to address this challenge. A metabolic network of the sphingolipid pathway in plants was reconstructed. The steady-state rates of reactions in the network were then determined through measurements of growth and cellular composition of the different sphingolipids in Arabidopsis seedlings. The Ensemble modeling framework was modified to accurately account for activation mechanisms and subsequently used to generate sets of kinetic parameters that converge to the measured steady-state fluxes in a thermodynamically consistent manner. In addition, the framework was appended with an additional module to automate screening the parameters and to output models consistent with previously reported network responses to different perturbations. By analyzing the network’s response in the presence of different combinations of regulatory mechanisms, the model captured the experimentally observed repressive effect of ORMs on serine palmitoyltransferase (SPT). Furthermore, predictions point to a second regulatory role of ORM proteins, namely as an activator of class II (or LOH1 and LOH3) ceramide synthases. This activating role was found to be modulated by the concentration of free ceramides, where an accumulation of these sphingolipid species dampened the activating effect of ORMs on ceramide synthase. The predictions pave the way for future guided experiments and have implications in engineering crops with higher biotic stress tolerance. 

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2. Mechanism of sphingolipid homeostasis revealed by structural analysis of Arabidopsis SPT-ORM1 complex

   https://doi.org/10.1126/sciadv.adg0728  

   Liu, Peng; Xie, Tian; Wu, Xinyue; Han, Gongshe; Gupta, Sita D.; Zhang, Zike; Yue, Jian; Dong, Feitong; Gable, Kenneth; Niranjanakumari, Somashekarappa; et al (March 2023, Science Advances)

   The serine palmitoyltransferase (SPT) complex catalyzes the first and rate-limiting step in sphingolipid biosynthesis in all eukaryotes. ORM/ORMDL proteins are negative regulators of SPT that respond to cellular sphingolipid levels. However, the molecular basis underlying ORM/ORMDL-dependent homeostatic regulation of SPT is not well understood. We determined the cryo–electron microscopy structure ofArabidopsisSPT-ORM1 complex, composed of LCB1, LCB2a, SPTssa, and ORM1, in an inhibited state. A ceramide molecule is sandwiched between ORM1 and LCB2a in the cytosolic membrane leaflet. Ceramide binding is critical for the ORM1-dependent SPT repression, and dihydroceramides and phytoceramides differentially affect this repression. A hybrid β sheet, formed by the amino termini of ORM1 and LCB2a and induced by ceramide binding, stabilizes the amino terminus of ORM1 in an inhibitory conformation. Our findings provide mechanistic insights into sphingolipid homeostatic regulation via the binding of ceramide to the SPT-ORM/ORMDL complex that may have implications for plant-specific processes such as the hypersensitive response for microbial pathogen resistance. 

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3. Plasma and vacuolar membrane sphingolipidomes: composition and insights on the role of main molecular species

   https://doi.org/10.1093/plphys/kiab064  

   Carmona-Salazar, Laura; Cahoon, Rebecca E; Gasca-Pineda, Jaime; González-Solís, Ariadna; Vera-Estrella, Rosario; Treviño, Victor; Cahoon, Edgar B; Gavilanes-Ruiz, Marina (February 2021, Plant Physiology)

   null (Ed.)

   Abstract Lipid structures affect membrane biophysical properties such as thickness, stability, permeability, curvature, fluidity, asymmetry, and interdigitation, contributing to membrane function. Sphingolipids are abundant in plant endomembranes and plasma membranes (PMs) and comprise four classes: ceramides, hydroxyceramides, glucosylceramides, and glycosylinositolphosphoceramides (GIPCs). They constitute an array of chemical structures whose distribution in plant membranes is unknown. With the aim of describing the hydrophobic portion of sphingolipids, 18 preparations from microsomal (MIC), vacuolar (VM), PM, and detergent-resistant membranes (DRM) were isolated from Arabidopsis (Arabidopsis thaliana) leaves. Sphingolipid species, encompassing pairing of long-chain bases and fatty acids, were identified and quantified in these membranes. Sphingolipid concentrations were compared using univariate and multivariate analysis to assess sphingolipid diversity, abundance, and predominance across membranes. The four sphingolipid classes were present at different levels in each membrane: VM was enriched in glucosylceramides, hydroxyceramides, and GIPCs; PM in GIPCs, in agreement with their key role in signal recognition and sensing; and DRM in GIPCs, as reported by their function in nanodomain formation. While a total of 84 sphingolipid species was identified in MIC, VM, PM, and DRM, only 34 were selectively distributed in the four membrane types. Conversely, every membrane contained a different number of predominant species (11 in VM, 6 in PM, and 17 in DRM). This study reveals that MIC, VM, PM, and DRM contain the same set of sphingolipid species but every membrane source contains its own specific assortment based on the proportion of sphingolipid classes and on the predominance of individual species. 

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4. Disruption of long‐chain base hydroxylation alters growth and impacts sphingolipid synthesis in Physcomitrella patens

   https://doi.org/10.1002/pld3.336  

   Steinberger, Abraham R.; Merino, William Oscar; Cahoon, Rebecca E.; Cahoon, Edgar B.; Lynch, Daniel V. (July 2021, Plant Direct)

   Abstract Sphingolipids have roles as membrane structural components and as bioactive molecules in plants. InPhyscomitrella patens, 4‐hydroxysphinganine (phytosphingosine, t18:0) is the predominant sphingolipid long‐chain base (LCB). To assess the functional significance of t18:0, CRISPR‐Cas9 mutagenesis was used to generate mutant lines lacking the soleSPHINGOID BASE HYDROXYLASE(SBH) gene encoding the hydroxylase responsible for converting sphinganine (d18:0) to t18:0. Total sphingolipid content insbhprotonemata was 2.4‐fold higher than in wild‐type. Modest changes in glycosyl inositolphosphorylceramide (GIPC) glycosylation patterns occurred. Sphingolipidomic analyses of mutants lacking t18:0 indicated modest alterations in acyl‐chain pairing with d18:0 in GIPCs and ceramides, but dramatic alterations in acyl‐chain pairing in glucosylceramides, in which 4,8‐sphingadienine (d18:2) was the principal LCB. A striking accumulation of free and phosphorylated LCBs accompanied loss of the hydroxylase. Thesbhlines exhibited altered morphology, including smaller chloronemal cell size, irregular cell shape, reduced gametophore size, and increased pigmentation. In the presence of the synthetic trihydroxy LCB t17:0, the endogenous sphingolipid content ofsbhlines decreased to wild‐type levels, and the mutants exhibited phenotypes more similar to wild‐type plants. These results demonstrate the importance of sphingolipid content and composition to Physcomitrella growth. They also illuminate similarities in regulating sphingolipid content but differences in regulating sphingolipid species composition between the bryophyteP. patensand angiospermA. thaliana. 

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5. De novo cholesterol biosynthesis in bacteria

   https://doi.org/10.1038/s41467-023-38638-8  

   Lee, Alysha K.; Wei, Jeremy H.; Welander, Paula V. (May 2023, Nature Communications)

   Abstract Eukaryotes produce highly modified sterols, including cholesterol, essential to eukaryotic physiology. Although few bacterial species are known to produce sterols, de novo production of cholesterol or other complex sterols in bacteria has not been reported. Here, we show that the marine myxobacteriumEnhygromyxa salinaproduces cholesterol and provide evidence for further downstream modifications. Through bioinformatic analysis we identify a putative cholesterol biosynthesis pathway inE. salinalargely homologous to the eukaryotic pathway. However, experimental evidence indicates that complete demethylation at C-4 occurs through unique bacterial proteins, distinguishing bacterial and eukaryotic cholesterol biosynthesis. Additionally, proteins from the cyanobacteriumCalothrixsp. NIES-4105 are also capable of fully demethylating sterols at the C-4 position, suggesting complex sterol biosynthesis may be found in other bacterial phyla. Our results reveal an unappreciated complexity in bacterial sterol production that rivals eukaryotes and highlight the complicated evolutionary relationship between sterol biosynthesis in the bacterial and eukaryotic domains. 

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