Species Delimitation of Asteropyrum (Ranunculaceae) Based on Morphological, Molecular, and Ecological Variation

Insights into the phylogenetic relationships and species boundaries of the Myricaria squamosa complex (Tamaricaceae) based on the complete chloroplast genome

Myricaria plants are widely distributed in Eurasia and are helpful for windbreak and embankment protection. Current molecular evidence has led to controversy regarding species boundaries within the Myricaria genus and interspecific phylogenetic relationships between three specific species-M. bracteata, M. paniculata and M. squamosa-which have remained unresolved. This study treated these three unresolved taxa as a species complex, named the M. squamosa complex. The genome skimming approach was used to determine 35 complete plastome sequences and nuclear ribosomal DNA sequences for the said complex and other closely related species, followed by de novo assembly. Comparative analyses were conducted across Myricaria to identify the genome size, gene content, repeat type and number, SSR (simple sequence repeat) abundance, and codon usage bias of chloroplast genomes. Tree-based species delimitation results indicated that M. bracteata, M. paniculata and M. squamosa could not be distinguished and formed two monophyletic lineages (P1 and P2) that were clustered together. Compared to plastome-based species delimitation, the standard nuclear DNA barcode had the lowest species resolution, and the standard chloroplast DNA barcode and group-specific barcodes delimitated a maximum of four out of the five species. Plastid phylogenomics analyses indicated that the monophyletic M. squamosa complex is comprised of two evolutionarily significant units: one in the western Tarim Basin and the other in the eastern Qinghai-Tibet Plateau. This finding contradicts previous species discrimination and promotes the urgent need for taxonomic revision of the threatened genus Myricaria. Dense sampling and plastid genomes will be essential in this effort. The super-barcodes and specific barcode candidates outlined in this study will aid in further studies of evolutionary history.

Recent Advances in the Integrative Taxonomy of Plants

Biodiversity conservation and management call for rapid and accurate global assessments at the species level [...].

Ancient allopatry and ecological divergence act together to promote plant diversity in mountainous regions: evidence from comparative phylogeography of two genera in the Sino-Himalayan region

BACKGROUND

How geographical isolation and ecological divergence act together to promote plant diversity in mountainous regions remains largely unknown. In this study, we chose two genera comprising a small number of species distributed in the Sino-Himalayan region, Megacodon (Gentianaceae) and Beesia (Ranunculaceae), which both exhibit a fragmented distribution pattern and are found across a wide range of elevations. By summarizing their common patterns of speciation and/or divergence processes, we aim to understand how environmental changes accelerated lineage diversification in the Sino-Himalayan region through ancient allopatry and ecological divergence.

RESULTS

Using ddRAD-seq, chloroplast genome sequences, and specific molecular markers, we studied the phylogenetic relationships, population structure, and historical biogeography of Beesia and Megacodon. Both genera began to diverge from the late Miocene onwards, with ancient allopatry at lower elevations formed narrow-range species or relict populations. Mantel tests between genetic distance and climatic, elevational, or geographic distance revealed an isolation-by-distance pattern in Beesia and Megacodon stylophorus. Megacodon showed two clades occupying entirely different altitudinal ranges, whereas Beesia calthifolia exhibited a genetic divergence pattern along an elevation gradient. Furthermore, we conducted morphological measurements on Beesia calthifolia and found that different elevational groups had distinct leaf shapes.

CONCLUSIONS

The regional disjunctions of plant groups in the Sino-Himalayan region are drastic and closely related to several biogeographic boundaries. As a consequence of major geological and climate change, ecological divergence when different elevations are colonized often happens simultaneously within plant groups. Although habitat fragmentation and parapatric ecological divergence each spur speciation to different extents, a combined effect of these two factors is a common phenomenon in the Sino-Himalayan region.

Phylogenetic discordance and integrative species delimitation in the Mammillaria haageana species complex (Cactaceae)

Species complexes consist of very close phylogenetic relatives, where morphological similarities make it difficult to distinguish between them using traditional taxonomic methods. Here, we focused on the long-standing challenge of species delimitation in the Mammillaria haageana complex, a group that presents great morphological diversity that makes its taxonomy a puzzle. Our work integrates genomic, morphological, and ecological data to establish the taxonomic limits in the M. haageana complex, and we also studied the evolutionary relationships with the remainder of the M. ser. Supertextae species. Our genetic analyses, as well as morphological and ecological evidence, led us to propose that the M. haageana complex is made up of six distinct entities (M. acultzingensis, M. conspicua, M. haageana, M. lanigera, M. meissneri, and M. san-angelensis), mainly as a result of ecological speciation. A recent taxonomic proposal considered these taxa as a single species; therefore, we propose their recognition at the species level. Our results also show a high level of incomplete lineage sorting rather than reticulation, which is especially likely in recently diverged species such as those comprising M. ser. Supertextae. The species hypotheses proposed here may be useful in future extinction risk assessments and conservation strategies.

Aspidistradaibuensis var. longkiauensis, a new variety of Aspidistra (Asparagaceae) from Taiwan, identified through morphological and genetic analyses

Aspidistra Ker Gawl. is one of the the most diverse and fastest-growing genera of angiosperm. Most Aspidistra species have been discovered in a limited area or a single site through morphological comparison. Because of the lack of population studies, morphological variation within species and the boundaries of some species remain unclear. In recent years, combining genetic and morphological markers has become a powerful approach for species delimitation. In this study, we performed population sampling and integrated morphometrics and microsatellite genetic diversity analyses to determine the species diversity of Aspidistra in Taiwan. We identified three species, namely Aspidistraattenuata Hayata; A.daibuensisHayatavar.daibuensis; A.mushaensisHayatavar.mushaensis; and reduced A.longiconnectiva C.T.Lu, K.C.Chuang & J.C.Wang to the variety level, and described a new variety, A.daibuensisHayatavar.longkiauensis. The description, diagnosis, distribution, and photographs of this new variety as well as a key to the known Taiwanese Aspidistra are provided.

A new synonym of Enkianthusperulatus (Ericaceae) in East Asia, based on morphological and molecular evidence

Enkianthuscalophyllus was once treated as a synonym of E.serrulatus. However, field observations indicate that E.calophyllus is distinct from E.serrulatus but resembles E.perulatus in flowers, leaves, fruits and seeds. Hence, a taxonomic revision of these species was conducted based on morphological comparisons of flowers, leaves, fruits and seeds, as well as molecular analyses of nuclear ribosomal internal transcribed spacer (nrITS) and six plastid DNA markers (psbA-trnH, rpl32-trnL, trnL-trnF, rps16-trnQ, psbJ-petA and matK). The morphological and molecular results reject the synonymization of E.calophyllus with E.serrulatus, and instead show it to be placed in a clade with E.perulatus. Based on molecular evidence and a reassessment of the morphology we synonymize E.calophyllus with the older name E.perulatus.

Understanding the Taxonomic Complexes and Species Delimitation within Sambucus L. (Viburnaceae)

The genus Sambucus belongs to the family Viburnaceae, and has long been a debatable taxon regarding its systematics and taxonomic assignment. It is known for its morphological and genetic variations and thus the taxonomic delimitation remains uncertain. Phenotypic and genotypic variations within plant species causes difficulties in the detection of species boundaries. In the present review, we compiled a set of studies that assessed species discrimination within Sambucus genus by morphological and molecular markers as well as the taxonomic uncertainties in the re-circumscription of the segregated genera i.e., Viburnum L., Sambucus L., and Adoxa L., (syn. Sinadoxa C.Y. Wu, Z.L. Wu & R.F. Huang/Tetradoxa C.Y. Wu) from Caprifoliaceae and their family assignment. The data was obtained from published journal articles and various online databases. Morphological and molecular diagnostic characters were employed to distinguish Sambucus species. Our findings indicated that high intraspecific variations within narrow-ranged populations and their widespread counterparts contribute to its taxonomic complications. Additionally, intraspecific variations within Sambucus species leads to misidentifications and the misapplication of names, occasioning the publication of many putative synonyms and ambiguous names. Possible interspecific hybridizations experienced between Sambucus species increases complexity in character evolution. A morphological analysis showed that the endocarp seed morphological characters can reliably support the segregation of Sambucus taxa into discrete taxonomic entities. In molecular analysis, the NeighborNet (NN) phylogenetic split network revealed three distinct genera including Viburnum, Sambucus, and Adoxa, which clustered separately. The Maximum Likelihood (ML) analysis indicated that the Sambucus species formed a monophyletic group and clustered into two major clades, a small clade containing S. maderensis, S. peruviana, S. nigra, and S. canadensis, and a large clade encompassing the rest of the species with significantly supported clades (<52%). The preferred family assignment for Sambucus is Viburnaceae.