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Huan C. Wang & Feng Yang (Phyllanthaceae), of sect. Cryptogynium (Müll.Arg.) Welzen & Pruesapan in subg. Breynia, is described from Yunnan, south-west China. It is known from only a single locality in the valley of the Yuanjiang River, and usually occurs in the understory of the savanna vegetation. It is characterized by its broadly elliptic to orbicular leaf blades, shallowly plate-like calyces of the staminate flowers, ovaries with clearly erose rim and urceolate capsules. Morphological comparisons with similar species are also presented.

The genus Phyllanthus is paraphyletic as currently circumscribed, with the genera Breynia, Glochidion and Synostemon nested within it. A phylogeny based on nuclear (ITS, PHYC) and chloroplast (matK, accD-psaI, trnS-trnG) markers is presented, including 18/18 subgenera and 53/70 sections. Differences in habit, branching type, floral and fruit characters are discussed, and we find indications for shifts in pollination and dispersal strategies possibly underlying the convergent evolution of these characters in multiple clades. Several taxonomic issues were found in the subgeneric classification of Phyllanthus that will require new transfers and rank changes. Phyllanthus subg. Anesonemoides, subg. Conami, subg. Emblica, subg. Gomphidium, subg. Kirganelia and subg. Phyllanthus are polyphyletic, and several sections appear to be paraphyletic (e.g., P. sect. Anisonema, sect. Emblicastrum, sect. Pseudoactephila, sect. Swartziani, and sect. Xylophylla); P. subg. Phyllanthodendron is furthermore paraphyletic with the genus Glochidion nested within. To create a classification of tribe Phyllantheae that comprises exclusively monophyletic taxa, it is necessary to treat several clades at the same taxonomic rank as the genera Breynia, Glochidion and Synostemon. Since combining all genera would lead to one giant heterogeneous genus that is difficult to define, we recommend dividing Phyllanthus into several monophyletic genera, which have previously been recognized and often possess diagnostic (combinations of) morphological characters. This new classification is forthcoming.

The names (Kuntze) Kuntze ex Merrill and Beille were previously reduced to synonyms of Champ. ex Benth. However, literature examination and morphological comparison suggest that is conspecific with and the species can be readily distinguished from by its styles connate into a long cylindric column and up to 3 mm long, ovaries usually 3-locular, stigma usually 3-lobed, capsules pubescent and usually 6-grooved, persistent styles 3‒4 mm long. Thus, the specific status of is here reinstated and G. is treated as its synonym.

Sauropus androgynus (S. androgynus) (2n = 4x = 52) is one of the most popular functional leafy vegetables in South and Southeast Asia. With its rich nutritional and pharmaceutical values, it has traditionally had widespread use for dietary and herbal purposes. Here, the genome of S. androgynus was sequenced and assembled, revealing a genome size of 1.55 Gb with 26 pseudo-chromosomes. Phylogenetic analysis traced back the divergence of Sauropus from Phyllanthus to approximately 29.67 million years ago (Mya). Genome analysis revealed that S. androgynus polyploidized around 20.51 Mya and shared a γ event about 132.95 Mya. Gene function analysis suggested that the expansion of pathways related to phloem development, lignin biosynthesis, and photosynthesis tended to result in the morphological differences among species within the Phyllanthaceae family, characterized by varying ploidy levels. The high accumulation of ascorbic acid in S. androgynus was attributed to the high expression of genes associated with the L-galactose pathway and recycling pathway. Moreover, the expanded gene families of S. androgynus exhibited multiple biochemical pathways associated with its comprehensive pharmacological activity, geographic adaptation and distinctive pleasurable flavor. Altogether, our findings represent a crucial genomic asset for S. androgynus, casting light on the intricate ploidy within the Phyllanthaceae family.

Baccaurea ramiflora Lour., an evergreen tree of the Baccaurea genus of the Phyllanthaceae family, is primarily distributed in South Asia, Southeast Asia, and southern China, including southern Yunnan Province. It is a wild or semi-cultivated tree species with ornamental, edible, and medicinal value, exhibiting significant development potential. In this study, we present the whole-genome sequencing of B. ramiflora, employing a combination of PacBio SMRT and Illumina HiSeq 2500 sequencing techniques. The assembled genome size was 975.8 Mb, with a contig N50 of 509.33 kb and the longest contig measuring 7.74 Mb. The genome comprises approximately 73.47% highly repetitive sequences, of which 52.1% are long terminal repeat–retrotransposon sequences. A total of 29,172 protein-coding genes were predicted, of which 25,980 (89.06%) have been annotated, Additionally, 3452 non-coding RNAs were identified. Comparative genomic analysis revealed a close relationship between B. ramiflora and the Euphorbiaceae family, with both being sister groups that diverged approximately 59.9 million years ago. During the evolutionary process, B. ramiflora exhibited positive selection in 278 candidate genes. Synonymous substitution rate and collinearity analysis demonstrated that B. ramiflora underwent a single ancient genome-wide triploidization event, without recent genome-wide duplication events. This high-quality B. ramiflora genome provides a valuable resource for basic research and tree improvement programs focusing on the Phyllanthaceae family.

Mosquitoes are vectors of devastating pathogens and parasites, causing millions of deaths every year. Dengue is a mosquito-borne viral infection found in tropical and subtropical regions around the world. Recently, transmission has strongly increased in urban and semiurban areas, becoming a major international public health concern. Aedes aegypti (Diptera: Culicidae) is the primary vector of dengue. The use of synthetic insecticides to control Aedes mosquitoes lead to high operational costs and adverse nontarget effects. In this scenario, eco-friendly control tools are a priority. We proposed a novel method to synthesize silver nanoparticles using the aqueous leaf extract of Phyllanthus niruri, a cheap and nontoxic material. The UV–vis spectrum of the aqueous medium containing silver nanostructures showed a peak at 420 nm corresponding to the surface plasmon resonance band of nanoparticles. SEM analyses of the synthesized nanoparticles showed a mean size of 30–60 nm. EDX spectrum showed the chemical composition of the synthesized nanoparticles. XRD highlighted that the nanoparticles are crystalline in nature with face-centered cubic geometry. Fourier transform infrared spectroscopy (FTIR) of nanoparticles exhibited prominent peaks 3,327.63, 2,125.87, 1,637.89, 644.35, 597.41, and 554.63 cm−1. In laboratory assays, the aqueous extract of P. niruri was toxic against larval instars (I–IV) and pupae of A. aegypti. LC50 was 158.24 ppm (I), 183.20 ppm (II), 210.53 ppm (III), 210.53 ppm (IV), and 358.08 ppm (pupae). P. niruri-synthesized nanoparticles were highly effective against A. aegypti, with LC50 of 3.90 ppm (I), 5.01 ppm (II), 6.2 ppm (III), 8.9 ppm (IV), and 13.04 ppm (pupae). In the field, the application of silver nanoparticles (10 × LC50) lead to A. aegypti larval reduction of 47.6 %, 76.7 % and 100 %, after 24, 48, and 72 h, while the P. niruri extract lead to 39.9 %, 69.2 % and 100 % of reduction, respectively. In adulticidal experiments, P. niruri extract and nanoparticles showed LC50 and LC90 of 174.14 and 6.68 ppm and 422.29 and 23.58 ppm, respectively. Overall, this study highlights that the possibility to employ P. niruri leaf extract and green-synthesized silver nanoparticles in mosquito control programs is concrete, since both are effective at lower doses if compared to synthetic products currently marketed, thus they could be an advantageous alternative to build newer and safer tools against dengue vectors.

Stemona alkaloids with a unique skeleton of pyrrolo[1,2- a ]azepine, pyrido[1,2- a ]azepine, pyrido[1,2- a ]azonine or indolizidine core are obtained only from the Stemonaceae family. And some plants from this family have been used for treating respiratory diseases and as antihelmintic in China for thousands of years. In addition, some alkaloids with [1,2- a ]azepine nucleus have also been isolated from plants of the Flueggea (Euphorbiaceae), Securinega (Phyllanthaceae), Phyllanthus (Phyllanthaceae) and Cephalotaxus (Cephalotaxaceae) genera. These alkaloids are named as Securinega alkaloids or Cephalotaxus alkaloids. A total of 94 new Stemona alkaloids, 51 new Securinega alkaloids, and 24 new Cephalotaxus alkaloids were obtained from 2009 to 2021. The absolute configurations of Stemona , Securinega , and Cephalotaxus alkaloids are usually determined using NOESY, biogenic synthesis, and data comparison methods during structural analysis. Based on an in-depth analysis of these structures, we found that the above methods are not rigorous. This article raises some problems in the structure determination of these alkaloids and summarizes the rules of nuclear magnetic resonance data of Securinega and Cephalotaxus alkaloids, which can also make the structure analysis more rigorous. In this review, we describe the isolation, structures, NMR rules, biogenic synthetic pathway and biological activities of these Stemona alkaloids, as well as the structure-related alkaloids isolated from the genera Flueggea, Securinega , Phyllanthus , and Cephalotaxus . This review also provides significant reference for the structural analysis, biogenic pathways, and pharmacological activities of Stemona , Securinega , and Cephalotaxus alkaloids. Graphical Abstract

Main conclusionWe report the genome assembly of P. cochinchinensis, as the first high-quality chromosome-level genome of Phyllanthaceae which is rich in medicinal plants.Phyllanthus cochinchinensis, a member of the Phyllanthaceae, is one of the famous medicinal plants in South China. Here, we report a de novo chromosome-level genome assembly for P. cochinchinensis using a combination of Nanopore and Illumina sequencing technologies. In total, the assembled genome consists of 284.88 Mb genomic sequences with a contig N50 of 10.32 Mb, representing ~ 95.49% of the estimated genome size. By applying Hi-C data, 13 pseudochromosomes of P. cochinchinensis were constructed, covering ~ 99.87% of the assembled sequences. The genome is annotated with 59.12% repetitive sequences and 20,836 protein-coding genes. Whole-genome duplication of P. cochinchinensis is likely shared with Ricinus communis as well as Vitis vinifera. Homologous genes within the flavonoid pathway for P. cochinchinensis were identified and copy numbers and expression level of related genes revealed potential critical genes involved in flavonoid biosynthesis. This study provides the first whole-genome sequence for the Phyllanthaceae, confirms the evolutionary status of Phyllanthus from the genomic level, and provides foundations for accelerating functional genomic research of species from Phyllanthus.

The new species from Vietnam is described and illustrated. The new species is compared with three similar species in an identification key and a table of detailed morphological characters. differs from the morphologically similar species , , and by a unique combination of characters, including fleshy sepals in the staminate flowers (vs. non-fleshy in the other three species); staminate flowers 4.9-5.8 mm in diameter (vs. ca. 3.3 mm in ); outer sepals of pistillate flowers 3.7-4.6 mm long (vs. 6-7 mm long in ); and a markedly longer ovary, 3.7-4.9 mm long (vs. < 2.8 mm long in the other three species). It further differs in having fruits ca. 27.0 mm long (vs. ≤ 25.0 mm long in the other species), pistillate flower pedicels 16-53 mm long (vs. 2.5-4.0 mm long in and 0.3-3.0 mm long in ), globose fruits (vs. starfish-shaped in ), and fewer lateral veins (6-8 pairs vs. 9-15 pairs in ).

The eudicot order Malpighiales contains ~16000 species and is the most poorly resolved large rosid clade. To clarify phylogenetic relationships in the order, we used maximum likelihood, Bayesian, and parsimony analyses of DNA sequence data from 13 gene regions, totaling 15604 bp, and representing all three genomic compartments (i.e., plastid: atpB, matK, ndhF, and rbcL; mitochondrial: ccmB, cob, matR, nad1B-C, nad6, and rps3; and nuclear: 18S rDNA, PHYC, and newly developed low-copy EMB2765). Our sampling of 190 taxa includes representatives from all families of Malpighiales. These data provide greatly increased support for the recent additions of Aneulophus, Bhesa, Centroplacus, Ploiarium, and Rafflesiaceae to Malpighiales; sister relations of Phyllanthaceae + Picrodendraceae, monophyly of Hypericaceae, and polyphyly of Clusiaceae. Oxalidales + Huaceae, followed by Celastrales are successive sisters to Malpighiales. Parasitic Rafflesiaceae, which produce the world's largest flowers, are confirmed as embedded within a paraphyletic Euphorbiaceae. Novel findings show a well-supported placement of Ctenolophonaceae with Erythroxylaceae + Rhizophoraceae, sister-group relationships of Bhesa + Centroplacus, and the exclusion of Medusandra from Malpighiales. New taxonomic circumscriptions include the addition of Bhesa to Centroplacaceae, Medusandra to Peridiscaceae (Saxifragales), Calophyllaceae applied to Clusiaceae subfamily Kielmeyeroideae, Peraceae applied to Euphorbiaceae subfamily Peroideae, and Huaceae included in Oxalidales.