Concepts and analysis of mass extinction with the late Ordovician event as an example

Twelve groups of fossils, including graptolites, brachiopods, nautiloids, trilobites, corals, crinoids, bryozoans, conodonts, ostracods, gastropods, chitinozoans, and acritarchs expired in different but substantial magnitude and global extent during the late Caradoc to latest Ashgill. It indicates a multiple‐episodic mass extinction containing the possible Prologue (late Caradoc), Climax episode (Rawtheyan) and Epilogue (late Hirnantian). The main causes of this mass extinction are recognized as a global sea‐level lowering in the climax and remarkable rapid rise at the final, and global cooling. The Chinese data, especially from the South China Paleoplate, are evaluated first. They are significant for explaining this global bioevent.     

In vitro evaluation of archaeosome vehicles for transdermal vaccine delivery

Abstract

Archaeosomes composed of archaeal total polar lipids (TPL) or semi-synthetic analog vesicles have been used as vaccine adjuvants and delivery systems in animal models for many years. Typically administered by intramuscular or subcutaneous injections, archaeosomes can induce robust, long-lasting humoral and cell-mediated immune responses against entrapped antigens and provide protection in murine models of infectious disease and cancer. Herein, we evaluated various archaeosomes for transdermal delivery, since this route may help eliminate needle-stick injuries and needle re-use, and therefore increase patient compliance. Archaeosomes composed of TPL from different archaea (Halobacterium salinarum, Methanobrevibacter smithii, Haloferax volcanii) and various semi-synthetic glycolipid combinations were evaluated for their ability to diffuse across the skin barrier using an ex vivo pig skin model and the results were compared to conventional synthetic ester liposomes. Physicochemical characteristics were determined for selected formulations including vesicle size, size distribution, zeta potential, fluidity, antigen (ovalbumin) incorporation efficiency and release. Archaeosomes, in particular those composed of M. smithii TPL or the synthetic glycolipid sulfated S-lactosylarchaeol (SLA) mixed with uncharged glycolipid lactosyl archaeol (LA), appeared to be effective carriers for ovalbumin, achieving much better antigen distribution and vesicle accumulation in the skin epidermis than conventional liposomes. The enhanced skin permeation of archaeosomes may be attributed to their chemical structure and physicochemical properties such as particle size, surface charge, stability, and fluidity of their lipid bilayer.     

ATM pathway is essential for ionizing radiation-induced autophagy

BackgroundATM plays an important role in response to DNA damage, while the roles of ATM in radiation-induced autophagy are still unclear in cervical cancer cells.MethodsHuman cervical cancer cells, Hela, were used, and cell models with ATM^?/? and MAPK14^?/? were established by gene engineering. Western blot was implemented to detect protein expression. MDC staining and GFP-LC3 relocalization were used to detect autophagy. CCK-8 was used to detect cell viability. Radiosensitivity was analyzed by colony formation assays. Co-immunoprecipitation was used to detect the interaction between different proteins, and apoptosis was detected by flow cytometry.ResultsAfter radiation autophagy was induced, illustrated by the increase of MAPLC3-II/MAPLC3-I ratio and decrease of p62, and phosphorylation of ATM simultaneously increased. ATM^?/? cells displayed hypersensitivity but had no influence on IR-induced apoptosis. Then inhibitor of ATM, KU55933, ATM and MAPK14 silencing were used, and autophagy was induced by IR more than 200% in control, and only by 35.72%, 53.18% and 24.76% in KU55933-treated cells, ATM^?/? and MAPK14^?/? cells, respectively. KU55933 inhibited IR-induced autophagy by activating mTOR pathways. ATM silencing decreased the expression of MAPK14 and mTOR signals significantly. Beclin's bond to PI3KIII and their interaction increased after IR, while in ATM^?/? and MAPK14^?/? cells this interaction decreased after IR. Both ATM and MAPK14 interacted with Beclin, while ATM^?/? and MAPK14^?/? cells showed no interaction.ConclusionsATM could promote IR-induced autophagy via the MAPK14 pathway, the mTOR pathway, and Beclin/PI3KIII complexes, which contributed to the effect of ATM on radiosensitivity.     

Structural basis of calcineurin activation by calmodulin

Calcineurin is the only known calmodulin (CaM) activated protein phosphatase, which is involved in the regulation of numerous cellular and developmental processes and in calcium-dependent signal transduction. Although commonly assumed that CaM displaces the autoinhibitory domain (AID) blocking substrate access to its active site, the structural basis underlying activation remains elusive. We have created a fused ternary complex (CBA) by covalently linking three polypeptides: CaM, calcineurin regulatory B subunit (CnB) and calcineurin catalytic A subunit (CnA). CBA catalytic activity is comparable to that of fully activated native calcineurin in the presence of CaM. The crystal structure showed virtually no structural change in the active site and no evidence of CaM despite being covalently linked. The asymmetric unit contains four molecules; two parallel CBA pairs are packed in an antiparallel mode and the large cavities in crystal packing near the calcineurin active site would easily accommodate multiple positions of AID-bound CaM. Intriguingly, the conformation of the ordered segment of AID is not altered by CaM; thus, it is the disordered part of AID, which resumes a regular α-helical conformation upon binding to CaM, which is displaced by CaM for activation. We propose that the structural basis of calcineurin activation by CaM is through displacement of the disordered fragment of AID which otherwise impedes active site access.     

Analysis of B-Class Genes NAP3L3 and NAP3L4 in Narcissus tazetta var. chinensis

Very few flower organ identity genes have been characterized in Chinese narcissus (Narcissus tazetta var. chinensis), which has petaloid sepals. Here, we report the cloning of two full-length B-class genes, namely NAP3L3 and NAP3L4, that are orthologs of the DEFICIENS lineage. Both genes are highly expressed in the second whorl of the perianth and in the stamens. NAP3L4 is also expressed strongly in the ovule. The functions of these two genes were further analyzed using transgenic plants. Ectopic expression of either gene in Arabidopsis gave no obvious floral organ transformation phenotypes. In yeast two-hybrid assays, NAP3L3 and NAP3L4 failed to homodimerize and interacted weakly with each other. The data suggest that these two genes might not be involved in the formation of petaloid sepals. Isolation and functional analysis of other B-class paralogs should be conducted to fully understand petaloid tepal development in Chinese narcissus.     

164 Extracting dynamics information from multiple structures

Meaningful dynamics information can be extracted from multiple experimental structures of the same, or closely related, proteins or RNAs. The covariance matrix of atom positions is decomposable into its principal components, and in this way, it is possible to rank-order the changes in the set of structures, and to determine what the most significant changes are. Usually, only a few principal components dominate the motions of the structures, and these usually relate to the functional dynamics. This dynamics information provides strong evidence for the plasticity of protein and RNA structures, and also suggests that these structures almost always have a highly limited repertoire of motions. In some cases, such as HIV protease, the dominant motions are opening and closing over the active site. For myoglobin, the changes are much smaller, reflecting in part the small changes in sequence, but nonetheless they show characteristic details that depend on the species. Sets of structures can also be used to derive the effective microscopic forces that are forcing a given conformational transition.     

Tetraplex Formation of d(GGGGGTTTTT): 1H NMR Study in Solution

Abstract

The oligonucleotide d(G₅T₅) can in principle form a fully matched duplex with G · T pairing and/or a tetraplex. Non-denaturing gel electrophoresis, circular dichroism and NMR experiments show that the tetraplex is exclusively formed by this oligomer in solution. In the presence of its complementary strand d(A₅C₅) at low temperature, d(G₅T₅) forms the tetraplex over the normally expected Watson-Crick duplex. However, when d(G₅T₅) and d(A₅C₅) are mixed together in equimolar amounts and heated for several minutes at 85°C, and then allowed to cool, the product was essentially the Watson-Crick duplex. The lack of resolution in the 500 MHz ¹H NMR spectra and the presence of extensive spin diffusion do not allow us to derive a quantitative structure for the tetraplex from the NMR data. However, we find good qualitative agreement between the NOESY and MINSY data and a theoretically derived stereochemically sound structure in which the G's and T's are part of a parallel tetraplex.     

RNAi-Mediated Silencing of the Flavanone 3-Hydroxylase Gene and Its Effect on Flavonoid Biosynthesis in Strawberry Fruit

Anthocyanin biosynthesis requires the activities of several enzymes in vivo. Flavanone 3-hydroxylase (F3H) converts flavanone into dihydroflavanol at an early step in the anthocyanin biosynthesis pathway. In this study we constructed an RNAi gene-silencing vector that encodes a hairpin F3H RNA. Agrobacterium strain GV3101 harboring the F3H RNAi vector was injected into strawberry fruits which were still attached to the plants 14 days after pollination. The phenotype was observed 10 days postinjection, and fruits were tested by RT-PCR and northern blot assays. The results showed that the F3H gene was downregulated by approximately 70 % in the agroinfiltrated fruits compared with the control. HPLC–MS analysis showed that anthocyanin content was greatly reduced, flavonol was also decreased, and the levels of p-coumaroyl glucoside and p-coumaroyl-1-acetate were markedly increased. We conclude that the precursors were shunted to the phenylpropanoid pathway, and that F3H is one of the key enzymes required for the biosynthesis of flavonoids in strawberry fruit. According to our results, reducing gene function via RNA interference is a rapid, simple, and effective way to identify gene function in strawberry fruit.