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Ethnopharmacological relevance: The genus Polygonatum Tourn, ex Mill. contains numerous chemical components, such as steroidal saponins, polysaccharides, flavonoids, alkaloids, and others, it possesses diverse pharmacological activities, such as anti-aging, anti-tumor, immunological regulation, as well as blood glucose management and fat reducing properties. Aim of the review: This study reviews the current state of research on the systematic categorization, chemical composition, pharmacological effects, and processing changes of the plants belonging to the genus Polygonatum, to provide a theoretical foundation for their scientific development and rational application. Materials and methods: The information was obtained by searching the scientific literature published between 1977 and 2022 on online databases (including PubMed, CNKI, SciFinder, and Web of Science) and other sources (such as the Chinese Pharmacopoeia 2020 edition, and Chinese herbal books). Results: The genus Polygonatum contains 79 species, and 233 bioactive chemical compounds were identified in them. The abundance of pharmacological activities, such as antioxidant activities, anti-fatigue activities, anti-inflammatory activities, etc., were revealed for the representatives of this genus. In addition, there are numerous processing methods, and many chemical constituents and pharmacological activities change after the unappropriated processing. Conclusions: This review summarizes the taxonomy classification, chemical composition, pharmacological effects, and processing of the plants belonging to the genus Polygonatum, providing references and research tendencies for plant-based drug development and further clinical applications.

Liver cancer remains a smajor cause of mortality worldwide, underscoring the urgent need for novel natural therapeutics. Polygonatum kingianum var. grandifolium (PK) and Polygonatum sibiricum Redouté (PS) are rice in terpenoids, yet their anti-liver cancer mechanisms remain poorly understood. This study used metabolism, network analysis, molecular docking, and molecular dynamics simulations to investigate their therapeutic potential. Metabolomic analysis identified nine differential terpenoid metabolites, with Maslinic acid and Alphitolic acid being species-specific. Network analysis revealed 23 liver cancer-related targets, including five key proteins: HMGCR, PTGS2, ESR1, PPARG, and PGR. Functional enrichment analysis identified 126 GO terms and 11 KEGG pathways ( P  < 0.05). Molecular docking suggested strong binding affinities between core compounds and targets, while molecular dynamics simulations confirmed the stability of maslinic acid and alphitolic acid with their respective targets. This study enhances the pharmacological understanding of Polygonatum species and offers promising insights for the development of novel liver cancer treatments.

The Polygonati Rhizoma have generated significant market attention for their medicinal and culinary applications. However, morphological similarities and ambiguous species boundaries complicate the identification of genera and species, thereby impeding product development and utilization within Polygonatum sensu lato . Despite the widespread application of the chloroplast genome for taxonomic boundary revisions for Polygonatum s.l. , a critical gap persist regarding their genomic applicability and the lack of standardized pipelines for developing species-specific molecular markers capable of rapid discrimination among species. This study aims to assess the effectiveness of chloroplast genomes in clarifying the current taxonomic status of the genera and species of Polygonatum s.l. , and develop a reliable process for rapid identification of designated species from other species. A total of 21 chloroplast genomes were sequenced and assembled, and subsequent analyses included phylogenetic inference, multiple molecular species delimitation methods, and an automated screening framework were employed for subsequent analysis. Comparative analyses revealed relatively conserved chloroplast genomes, with notable variation limited primarily to the length of IR and LSC regions. By integrating multiple delimitation methods, the chloroplast genome validated 82.46% of the current classifications of Polygonatum s.l. , demonstrating strong support (90.63%) for species represented by multiple sequences, yet only moderate support (70%) for those with single-sequence representation. Additionally, this study established and validated a scalable molecular marker development framework, spanning from identification of species-specific SNPs/InDels to the design of high-resolution molecular markers, illustrated through case studies involving Heteropolygonatum and three medicinally significant Polygonatum species.

The complete genome sequence of a putative novel potyvirus, tentatively named “polygonatum kingianum mottle virus” (PKgMV; GenBank accession no. ON428226), infecting Polygonatum kingianum in China, was obtained by next-generation sequencing (NGS), reverse transcription polymerase chain reaction (RT-PCR), and rapid amplification of cDNA ends (RACE). PKgMV exhibits the typical genome organization and characteristics of members of the genus Potyvirus, with a length of 10,002 nucleotides (nt) and a large open reading frame (nt 108 to 9,746) encoding a polyprotein of 3,212 amino acids (aa) (363.68 kDa). Pairwise comparisons revealed that the PKgMV polyprotein shares 50.5–68.6% nt and 43.1–72.2% aa sequence identity with reported members of the genus Potyvirus. Moreover, phylogenetic analysis indicated that PKgMV is closely related to polygonatum kingianum virus 1 (PKgV1; accession no. MK427056). These results suggest that the PKgMV is a novel member of the genus Potyvirus of the family Potyviridae.

To characterize the chromosomes of the four species of Polygonatum Miller, 1754, used in traditional Chinese medicine, P. cyrtonema Hua, 1892, P. kingianum Collett et Hemsley, 1890, P. odoratum (Miller, 1768) Druce, 1906, and P. sibiricum Redouté, 1811, and have an insight into the karyotype variation of the genus Polygonatum , fluorescence in situ hybridization (FISH) with 5S and 45S rDNA oligonucleotide probes was applied to analyze the karyotypes of 9 populations of the four species. Detailed molecular cytogenetic karyotypes of the 9 populations were established for the first time using the dataset of chromosome measurements and FISH signals of 5S and 45S rDNA. Four karyotype asymmetry indices, CV CI , CV CL , M CA and Stebbins’ category, were measured to elucidate the asymmetry of the karyotypes and karyological relationships among species. Comparison of their karyotypes revealed distinct variations in the karyotypic parameters and rDNA patterns among and within species. The basic chromosome numbers detected were x = 9, 11 and 13 for P. cyrtonema , x = 15 for P. kingianum , x = 10 and 11 for P. odoratum , and x = 12 for P. sibiricum . The original basic chromosome numbers of the four species were inferred on the basis of the data of this study and previous reports. All the 9 karyotypes were of moderate asymmetry and composed of metacentric, submetacentric and subtelocentric chromosomes or consisted of two of these types of chromosomes. Seven populations have one locus of 5S rDNA and two loci of 45S rDNA, and two populations added one 5S or 45S locus. The karyological relationships among the four species revealed by comparison of rDNA patterns and PCoA based on x , 2 n , TCL, CV CI , M CA and CV CL were basically accordant with the phylogenetic relationships revealed by molecular phylogenetic studies. The mechanisms of both intra- and inter-specific dysploidy in Polygonatum were discussed based on the data of this study and literature.

The pollen morphology of 54 species and one variety of seven genera in Polygonatae including Clintonia, Disporopsis, Disporum, Maianthemum, Polygonatum, Smilacina and Streptopus was observed and studied in detail; of these, nine species were reported for the first time. Our results showed that the surface ornamentation of pollen grains of the studied materials could be divided into seven types, namely gemmate, granulate-foveolate, perforate, reticulate, rugulate, rugulate-perforate and verrucate. In line with previous studies, we believe that (i) Smilacina ginfushanicum should be classified into the genus Heteropolygonatum rather than the genus Smilacina; (ii) Polygonatum should be divided into section Polygonatum and section Verticillata; (iii) Smilacina and Maianthemum should be combined as one genus, i.e. Maianthemum sensu lato; and (iv) Clintonia, Disporum and Streptopus should be separated from the tribe Polygonatae.