The amphiphilic nature of saponins and their effects on artificial and biological membranes and potential consequences for red blood and cancer cells

Lorent, Joseph H.; Quetin-Leclercq, Joëlle; Mingeot‐Leclercq, Marie‐Paule

doi:10.1039/c4ob01652a

Cited by 204 publications

(162 citation statements)

References 168 publications

(276 reference statements)

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“…Structurally, saponins are amphiphilic molecules that are composed of one or more hydrophilic sugar residues and hydrophobic steroidal or triterpenoidal part on the basis of which they are called as steroidal saponin or triterpenoidal saponins. The non-sugar water-insoluble part is called as sapogenin, and on the basis of sugar present in saponin molecules they can be either monodesmosidic (contains only one sugar residue), bidesmosidic (contains two sugar residues) or polydesmosidic (more than two sugar residues) saponins (Lorent et al 2014). Structural variants of saponin are found in plants due to the presence of different sugar at different position and orientation.…”

Section: Introductionmentioning

confidence: 99%

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Recent advances in steroidal saponins biosynthesis and in vitro production

Upadhyay

Jeena

Shikha

et al. 2018

Planta

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Main conclusion Steroidal saponins exhibited numerous pharmacological activities due to the modification of their backbone by different cytochrome P450s (P450) and UDP glycosyltransferases (UGTs). Plant-derived steroidal saponins are not sufficient for utilizing them for commercial purpose so in vitro production of saponin by tissue culture, root culture, embryo culture, etc, is necessary for its large-scale production.Saponin glycosides are the important class of plant secondary metabolites, which consists of either steroidal or terpenoidal backbone. Due to the existence of a wide range of medicinal properties, saponin glycosides are pharmacologically very important. This review is focused on important medicinal properties of steroidal saponin, its occurrence, and biosynthesis. In addition to this, some recently identified plants containing steroidal saponins in different parts were summarized. The high throughput transcriptome sequencing approach elaborates our understanding related to the secondary metabolic pathway and its regulation even in the absence of adequate genomic information of non-model plants. The aim of this review is to encapsulate the information related to applications of steroidal saponin and its biosynthetic enzymes specially P450s and UGTs that are involved at later stage modifications of saponin backbone. Lastly, we discussed the in vitro production of steroidal saponin as the plant-based production of saponin is time-consuming and yield a limited amount of saponins. A large amount of plant material has been used to increase the production of steroidal saponin by employing in vitro culture technique, which has received a lot of attention in past two decades and provides a way to conserve medicinal plants as well as to escape them for being endangered.

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Section: Introductionmentioning

confidence: 99%

“…Structural variants of saponin are found in plants due to the presence of different sugar at different position and orientation. The most common sugars residues that are found in saponins are d-glucose, d-galactose, l-rhamnose, l-arabinose, d-glucuronic acid, d-fucose and d-xylose (Lorent et al 2014).…”

Section: Introductionmentioning

confidence: 99%

Recent advances in steroidal saponins biosynthesis and in vitro production

Upadhyay

Jeena

Shikha

et al. 2018

Planta

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“…By purification of the raw plant material, fractions with distinct immunostimulatory properties and safety profiles have been identified1. Although most saponins have strong binding affinity for cholesterol, only some stimulate the immune system2. Forty nanometer cage-like particles called immune stimulatory complexes (ISCOMs) form when immunoactive saponin, cholesterol and phospholipid are brought together and dialysed3.…”

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confidence: 99%

Saponin-based adjuvants induce cross-presentation in dendritic cells by intracellular lipid body formation

et al. 2016

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Saponin-based adjuvants (SBAs) are being used in animal and human (cancer) vaccines, as they induce protective cellular immunity. Their adjuvant potency is a factor of inflammasome activation and enhanced antigen cross-presentation by dendritic cells (DCs), but how antigen cross-presentation is induced is not clear. Here we show that SBAs uniquely induce intracellular lipid bodies (LBs) in the CD11b+ DC subset in vitro and in vivo. Using genetic and pharmacological interference in models for vaccination and in situ tumour ablation, we demonstrate that LB induction is causally related to the saponin-dependent increase in cross-presentation and T-cell activation. These findings link adjuvant activity to LB formation, aid the application of SBAs as a cancer vaccine component, and will stimulate development of new adjuvants enhancing T-cell-mediated immunity.

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“…Interactions between saponin and cholesterol in the cell membrane, and the resulting membrane damage, may underlie saponin-induced hemolysis and other toxicities. 19 The incorporation of PD into OVA-PD-Lipos may reduce interactions with cholesterol and account for the reduction in toxicity to mouse BMDCs as well as the reduction in hemolytic activity.…”

Section: Toxicity Of Ova-pd-lipos To Bmdcsmentioning

confidence: 99%

Enhanced immunization via dissolving microneedle array-based delivery system incorporating subunit vaccine and saponin adjuvant

Zhao

Zhang

Liu

et al. 2017

IJN

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Purpose To enhance the immunogenicity of the model subunit vaccine, ovalbumin (OVA) was combined with platycodin (PD), a saponin adjuvant. To reduce the toxicity of PD, OVA, and adjuvant were loaded together into liposomes before being incorporated into a dissolving microneedle array. Methods OVA- and PD-loaded liposomes (OVA-PD-Lipos) were prepared using the film dispersion method. Their uptake behavior, toxicity to mouse bone marrow dendritic cells (BMDCs), and hemolytic activity to rabbit red blood cells (RBCs) were evaluated. The OVA-PD-Lipos were incorporated into a dissolving microneedle array. The chemical stability of OVA and the physical stability of OVA-PD-Lipos in microneedle arrays were investigated. The immune response of Institute of Cancer Research mice and potential skin irritation reaction of rabbits to OVA-PD-Lipos-MNs were evaluated. Results The uptake of OVA by mouse BMDCs was greatly enhanced when OVA was prepared as OVA-PD-Lipos, and in this form, the toxicity of PD was dramatically reduced. OVA was chemically stable as OVA-PD-Lipos, when OVA-PD-Lipos was incorporated into a dissolving microneedle array. Institute of Cancer Research mice treated with OVA-PD-Lipos-MNs showed a significantly enhanced immune response. PD combined with OVA elicited a balanced Th1 and Th2 humoral immune response in mice, with minimal irritation in rabbit skin. Conclusion The dissolving microneedle array-based system is a promising delivery vehicle for subunit vaccine and its adjuvant.

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The amphiphilic nature of saponins and their effects on artificial and biological membranes and potential consequences for red blood and cancer cells

Cited by 204 publications

References 168 publications

Recent advances in steroidal saponins biosynthesis and in vitro production

Recent advances in steroidal saponins biosynthesis and in vitro production

Saponin-based adjuvants induce cross-presentation in dendritic cells by intracellular lipid body formation

Enhanced immunization via dissolving microneedle array-based delivery system incorporating subunit vaccine and saponin adjuvant

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