Classification, biosynthesis, and biological functions of triterpene esters in plants

Mechanisms of bone regeneration repair and potential and efficacy of small molecule drugs

Bone regeneration and repair is a complex physiological process of bone formation. To date, existing research has greatly enhanced our understanding of bone regeneration and repair, achieving significant success in treating bone injuries. However, extensive bone defects, bone nonunion, and metabolic bone diseases remain incompletely solved challenges in modern medicine. With the emergence of High-Throughput Screening (HTS) technology, previous studies have identified numerous small molecule compounds with potential for inducing bone formation and enhancing bone metabolism. However, the effects of these small molecules on bone regeneration and repair through related signaling pathways have not been systematically elaborated. Therefore, in this literature review, we focus on summarizing the classical signaling pathways affecting bone regeneration and repair, as well as the research progress and applications of related small molecule drugs.

Multi-Omics and Functional Insights into Triterpenoid Biosynthesis Pathways in Neopicrorhiza scrophulariiflora (Pennell) D.Y.Hong

Neopicrorhiza scrophulariiflora (Pennell) D.Y.Hong, an endangered perennial herb, is rich in triterpenes, iridoids, and phenolic compounds, which exhibit significant pharmacological effects. However, the molecular mechanisms of triterpenoid biosynthesis in N. scrophulariiflora remain unclear. Here, transcriptomic and metabolomic analyses were performed to investigate the triterpene content in different tissues and the expression patterns of key enzyme-encoding genes related to triterpenoid biosynthesis. We functionally characterized eight upstream oxidosqualene cyclases (OSCs) involved in triterpenoid biosynthesis, among which NsOSC2 is a bifunctional enzyme capable of catalyzing the conversion of 2,3-oxidosqualene to β-amyrin and α-amyrin. Additionally, an efficient regeneration system and a stable genetic transformation system were established for N. scrophulariiflora. These findings reveal key genes in triterpenoid biosynthesis, providing a theoretical foundation for the future production of key triterpenoids in N. scrophulariiflora through synthetic biology approaches.

Harnessing Apple Cell Suspension Cultures in Bioreactors for Triterpene Production: Transcriptomic Insights into Biomass and Triterpene Biosynthesis

Plant cell suspension cultures offer a sustainable method for producing valuable secondary metabolites, such as bioactive pentacyclic triterpenes. This study established a high-triterpene-yielding cell suspension culture from the apple cultivar "Cox Orange Pippin". Through transcriptomic analysis and triterpene profiling across growth phases, we uncovered complex regulatory networks that govern biomass production and triterpene biosynthesis. Key biological processes, including cell cycle regulation, cell wall biosynthesis, lipid metabolism, and stress response mechanisms, play pivotal roles in culture dynamics. Differential gene expression linked to these processes revealed how the culture adapts to growth conditions and nutrient availability at each growth phase. Methyl jasmonate elicitation enhanced phenylpropanoid and flavonoid biosynthesis, along with specific triterpene production pathways, highlighting its potential for optimizing secondary metabolite production. Key enzymes, such as oxidosqualene cyclase 4 and a putative C-2α hydroxylase, were identified as promising targets for future metabolic engineering efforts. This study represents the first in-depth report on the molecular mechanisms underlying plant cell growth in bioreactors, specially focusing on a cell suspension culture derived from a semi-russeted apple cultivar. The findings reveal key regulatory pathways in biomass accumulation and triterpene production, offering valuable insights for optimizing bioreactor cultures for industrial applications.

Astracondensatol D: A 6/6/5/6 Cycloartane Triterpenoid from Astragalus condensatus

Astracondensatol D (1), a pentacyclic triterpenoid featuring an uncommon 6/6/5/6-fused ring system, along with its precursor astracondensatol E (2), and two simplified 20(27)-octanorcycloastragenol derivatives (3 and 4) were isolated from Astragalus condensatus for the first time. Classical NMR spectroscopic data, integrated with NMR and DP4+ calculations, unambiguously determined their absolute stereostructures. X-ray crystallography provided independent confirmation of the structure of compound 3. The plausible biosynthetic pathway, encompassing the Wagner-Meerwein rearrangement and retro-aldol reaction, was proposed for their formation and supported by computational analysis.

Biosynthesis of triterpenoids in plants: Pathways, regulation, and biological functions

Plant triterpenoids, a vast and diverse group of natural compounds derived from six isoprene units, exhibit an extensive array of structural diversity and remarkable biological activities. In this review, we update the recent research progress in the catalytic mechanisms underlying triterpene synthesis and summarize the current insights into the biosynthetic pathways and regulatory mechanisms of triterpenoids. We emphasize the biosynthesis of pharmacologically active triterpenoids and the role of triterpenoid synthesis in plant growth, development, defense mechanisms, and plant-microbe interactions. This insight review offers a comprehensive perspective on the applications and future avenues of triterpenoid research.

Recent trends in the elucidation of complex triterpene biosynthetic pathways in horticultural trees

Triterpene (C30 isoprene compounds) represents the most structurally diverse class of natural products and has been extensively exploited in the food, medicine, and industrial sectors. Decades of research on medicinal triterpene biosynthetic pathways have revealed their roles in stress tolerance and shaping microbiota. However, the biological function and mechanism of triterpenes are not fully identified. Even this scientific window narrows down for horticultural trees. The lack of knowledge and a scalable production system limits the discovery of triterpene pathways. Recent synthetic biology research revealed several important biosynthetic pathways that define their roles and address many societal sustainability challenges. Here, I review the chemical diversity and biosynthetic enzymes involved in triterpene biosynthesis of horticultural trees. This review also outlines the integrated Design-Build-Test-Learn (DBTL) pipelines for the discovery, characterization, and optimization of triterpene biosynthetic pathways. Further, these DBTL components share many fundamental and technical difficulties, highlighting opportunities for interdisciplinary collaboration between researchers worldwide. This advancement opens up unprecedented opportunities for the bioengineering of triterpene compounds toward development and scaleup processes.

Integrated metabolomic and transcriptomic analysis revealed the transition of functional components in edible flower buds of Hemerocallis citrina Baroni

The edible flower buds of Hemerocallis citrina Baroni are used both as a vegetable and functional food. It has various health benefits due to the diversity of natural products. However, the establishment of functional components in the edible flower bud remains to be studied. We conducted a high-resolution metabolomic analysis of flower buds at three developmental stages, 1-2 cm, 4-6 cm, and edible (10-15 cm). Our analysis revealed 157 differential accumulated metabolites, including flavonoids (49), fatty acids (17) and terpenoids (13) while most of them decreased during flower bud development. Among them, 2 flavonoids, 2 long-chain fatty acids and 1 triterpene saponin are highly accumulated in edible flower buds. Furthermore, the expression levels of catalytic genes mirrored the changes in metabolite levels detected. These results track the dynamics of functional component accumulation during edible flower bud development, laying the theoretical basis for nutrition formation in H. citrina.

The Role of Pentacyclic Triterpenoids in Non-Small Cell Lung Cancer: The Mechanisms of Action and Therapeutic Potential

Lung cancer remains a major global health problem because of its high cancer-related mortality rate despite advances in therapeutic approaches. Non-small cell lung cancer (NSCLC), a major subtype of lung cancer, is more amenable to surgical intervention in its early stages. However, the prognosis for advanced NSCLC remains poor, owing to limited treatment options. This underscores the growing need for novel therapeutic strategies to complement existing treatments and improve patient outcomes. In recent years, pentacyclic triterpenoids, a group of natural compounds, have emerged as promising candidates for cancer therapy due to their anticancer properties. Pentacyclic triterpenoids, such as lupeol, betulinic acid, betulin, oleanolic acid, ursolic acid, glycyrrhetinic acid, glycyrrhizin, and asiatic acid, have demonstrated the ability to inhibit cell proliferation and angiogenesis, induce apoptosis, suppress metastasis, and modulate inflammatory and immune pathways in NSCLC cell line models. These compounds exert their effects by modulating important signaling pathways such as NF-κB, PI3K/Akt, and MAPK. Furthermore, advances in drug delivery technologies such as nanocarriers and targeted delivery systems have improved the bioavailability and therapeutic efficacy of triterpenoids. However, despite promising preclinical data, rigorous clinical trials are needed to verify their safety and efficacy. This review explores the role of triterpenoids in NSCLC and therapeutic potential in preclinical models, focusing on their molecular mechanisms of action.

Detoxification of Aflatoxin B1 by Phytochemicals in Agriculture and Food Science

Aflatoxin B1 (AFB1), the most toxic and harmful mycotoxin, has a high likelihood of occurring in animal feed and human food, which seriously affects agriculture and food safety and endangers animal and human health. Recently, natural plant products have attracted widespread attention due to their low toxicity, high biocompatibility, and simple composition, indicating significant potential for resisting AFB1. The mechanisms by which these phytochemicals resist toxins mainly involve antioxidative, anti-inflammatory, and antiapoptotic pathways. Moreover, these substances also inhibit the genotoxicity of AFB1 by directly influencing its metabolism in vivo, which contributes to its elimination. Here, we review various phytochemicals that resist AFB1 and their anti-AFB1 mechanisms in different animals, as well as the common characteristics of phytochemicals with anti-AFB1 function. Additionally, the shortcomings of current research and future research directions will be discussed. Overall, this comprehensive summary contributes to the better application of phytochemicals in agriculture and food safety.