The United Nations declared 2016 as the International Year of Pulses (grain legumes) under the banner 'nutritious seeds for a sustainable future'. A second green revolution is required to ensure food and nutritional security in the face of global climate change. Grain legumes provide an unparalleled solution to this problem because of their inherent capacity for symbiotic atmospheric nitrogen fixation, which provides economically sustainable advantages for farming. In addition, a legume-rich diet has health benefits for humans and livestock alike. However, grain legumes form only a minor part of most current human diets, and legume crops are greatly under-used. Food security and soil fertility could be significantly improved by greater grain legume usage and increased improvement of a range of grain legumes. The current lack of coordinated focus on grain legumes has compromised human health, nutritional security and sustainable food production.
Indirect development with an intermediate larva exists in all major animal lineages1, which makes larvae central to most scenarios of animal evolution2–11. Yet how larvae evolved remains disputed. Here we show that temporal shifts (that is, heterochronies) in trunk formation underpin the diversification of larvae and bilaterian life cycles. We performed chromosome-scale genome sequencing in the annelid Owenia fusiformis with transcriptomic and epigenomic profiling during the life cycles of this and two other annelids. We found that trunk development is deferred to pre-metamorphic stages in the feeding larva of O. fusiformis but starts after gastrulation in the non-feeding larva with gradual metamorphosis of Capitella teleta and the direct developing embryo of Dimorphilus gyrociliatus. Accordingly, the embryos of O. fusiformis develop first into an enlarged anterior domain that forms larval tissues and the adult head12. Notably, this also occurs in the so-called ‘head larvae’ of other bilaterians13–17, with which the O. fusiformis larva shows extensive transcriptomic similarities. Together, our findings suggest that the temporal decoupling of head and trunk formation, as maximally observed in head larvae, facilitated larval evolution in Bilateria. This diverges from prevailing scenarios that propose either co-option9,10 or innovation11 of gene regulatory programmes to explain larva and adult origins.
Animal development is classified as conditional or autonomous based on whether cell fates are specified through inductive signals or maternal determinants, respectively. Yet how these two major developmental modes evolved remains unclear. During spiral cleavage—a stereotypic embryogenesis ancestral to 15 invertebrate groups, including molluscs and annelids—most lineages specify cell fates conditionally, while some define the primary axial fates autonomously. To identify the mechanisms driving this change, we study Owenia fusiformis, an early-branching, conditional annelid. In Owenia, ERK1/2-mediated FGF receptor signalling specifies the endomesodermal progenitor. This cell likely acts as an organiser, inducing mesodermal and posterodorsal fates in neighbouring cells and repressing anteriorising signals. The organising role of ERK1/2 in Owenia is shared with molluscs, but not with autonomous annelids. Together, these findings suggest that conditional specification of an ERK1/2+ embryonic organiser is ancestral in spiral cleavage and was repeatedly lost in annelid lineages with autonomous development.
Embryonic organisers are signalling centres that instruct the establishment of body plans during animal embryogenesis, thus underpinning animal morphological diversity. In spiral cleavage - a stereotypic developmental programme ancestral to 14, nearly half, of the animal phyla (e.g., molluscs, annelids and flatworms), a cell known as the D-quadrant organiser defines cell fates and the body axes. ERK1/2 specifies the embryonic organiser in molluscs, yet how this signalling cascade exerts organising activity and whether this role is conserved in other spiral cleaving groups is unclear. Here, we demonstrate that ERK1/2 promotes the specification and inductive activity of the D-quadrant organiser in Owenia fusiformis, an early-branching annelid exhibiting ancestral developmental traits. In this species, active di-phosphorylated ERK1/2 mediated by FGF receptor activity localises to the 4d micromere, establishing the bilateral symmetry and specifying the hindgut and trunk mesodermal progenitor. Accordingly, impairing FGFR and ERK1/2 activity, as well as cell communication results in embryos developing anteroventrally radialised. Differential transcriptomic profiling shows the ParaHox cdx and the Notch ligand delta as FGFR/ERK1/2 downstream targets in 4d, further revealing that 4d specification instructs the expression of mesodermal and posterodorsal genes in neighbouring cells, putatively via the Notch pathway. The instructing role of ERK1/2 in the D-quadrant organiser is thus shared between O. fusiformis and molluscs, representing an ancestral trait of spiral cleavage. Altogether, our study begins to dissect the gene network promoting axial patterning and posterior growth in spiral cleavage, revealing extensive mechanistic diversification in body plan specification despite overall conservation of cleavage patterns in Spiralia.
Indirect development with an intermediate larva exists in all major animal lineages, and thus larvae are central to most scenarios for animal evolution. Yet how larvae evolved remains disputed. Here we show that changes in the timing of trunk formation underpin the diversification of larvae and bilaterian life cycles. Combining chromosome-scale genome sequencing with transcriptomic and epigenomic profiling in the slow-evolving oweniid Owenia fusiformis, we found that different genes and genomic regulatory elements control the development of its feeding larva and adult stage. First, O. fusiformis embryos develop into an enlarged anterior domain that forms larval tissues and the adult head, as posterior growth and trunk patterning is deferred to pre-metamorphic stages. These traits also occur in the so-called "head larvae" of other bilaterians, with whom O. fusiformis larva shows extensive transcriptomic similarities. Conversely, animals with non-feeding larvae and gradual metamorphoses, such as the annelid Capitella teleta, start trunk differentiation during embryogenesis, like direct developers. Together, our findings suggest that the ancestral temporal decoupling of head and trunk formation, as retained in extant "head larvae", allowed larval evolution in Bilateria, questioning prevailing scenarios that propose either co-option or innovation of gene regulatory programmes to explain larva and adult origins.
The Chinese vaccine industry is developing rapidly due to an emerging and large market for current and new vaccines, a large potential for local vaccine manufacturing both in the public and private domain, and a governmental orientation towards national vaccine self-sufficiency. There are currently over 40 companies and institutions manufacturing a large variety of traditional (EPI) and some new vaccines. The innovative development capacity of state vaccine institutions is stimulated by significant government investments. Various Chinese influenza manufacturers were in 2009 among the first worldwide to obtain national license for their pandemic H1N1 flu vaccines. It is of interest to note that private but also governmental entities are committed to raise manufacturing quality standards to reach WHO prequalification. It is expected that WHO prequalification for at least one product from a Chinese manufacturer will have been obtained by 2011. This will open the door to the global market for Chinese vaccines.
The phylogenetic interrelationships among four hexapod lineages (Protura, Collembola, Diplura and Insecta) are pivotal to understanding the origin of insects and the early diversification of Hexapoda, but they have been difficult to clarify based on the available data. In this study, we identified 91 conserved microRNA (miRNA) families from 36 panarthropod taxa, including seven newly sequenced non‐insect hexapods. We found major clade differentiation accompanied by the origin of novel miRNA families, and most miRNA clusters are conserved with a high degree of microsynteny. Importantly, we were able to identify two miRNA families unique to Hexapoda, and four miRNA families and a miRNA cluster that exist exclusively in Diplura and Insecta, suggesting a close relationship between Diplura and Insecta as well as the monophyly of Hexapoda. Combined with a phylogenetic analysis based on the presence/absence matrix of miRNA families, our study demonstrates the effectiveness of miRNA in resolving deep phylogenetic problems.
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