Unveiling the Microscopic Origin of Irreversible Capacity Loss of Hard Carbon for Sodium-Ion Batteries

The primary bottleneck hindering the application of hard carbon in sodium-ion batteries (SIBs) anodes lies in its inadequate initial Coulombic efficiency (ICE). Unclear causes of capacity loss at the microscopic level restrict the improvement of hard carbon anodes. Here, two pivotal stages that influence the structure and composition of hard carbon, namely synthesis, and storage are evaluated; subsequently identifying crucial determinants contributing to irreversible capacity loss. The results suggest that undergrown carbon layers allowing the intrusion of solvent molecules into the interior of the hard carbon is a key factor during the synthesis stage, while the gradual formation of oxygen-containing functional groups on the surface of the hard carbon is another factor leading to irreversible loss of capacity during storage stage. This research microscopically clarifies the irreversible capacity loss mechanism on hard carbon and provides guidelines for designing and applying high ICE hard carbon for SIBs.     

Proteome-Wide Profiling of the MCF10AT Breast Cancer Progression Model

Background

Mapping the expression changes during breast cancer development should facilitate basic and translational research that will eventually improve our understanding and clinical management of cancer. However, most studies in this area are challenged by genetic and environmental heterogeneities associated with cancer.

Methodology/Principal Findings

We conducted proteomics of the MCF10AT breast cancer model, which comprises of 4 isogenic xenograft-derived human cell lines that mimic different stages of breast cancer progression, using iTRAQ-based tandem mass spectrometry. Of more than 1200 proteins detected, 98 proteins representing at least 20 molecular function groups including kinases, proteases, adhesion, calcium binding and cytoskeletal proteins were found to display significant expression changes across the MCF10AT model. The number of proteins that showed different expression levels increased as disease progressed from AT1k pre-neoplastic cells to low grade CA1h cancer cells and high grade cancer cells. Bioinformatics revealed that MCF10AT model of breast cancer progression is associated with a major re-programming in metabolism, one of the first identified biochemical hallmarks of tumor cells (the “Warburg effect”). Aberrant expression of 3 novel breast cancer-associated proteins namely AK1, ATOX1 and HIST1H2BM were subsequently validated via immunoblotting of the MCF10AT model and immunohistochemistry of progressive clinical breast cancer lesions.

Conclusion/Significance

The information generated by this study should serve as a useful reference for future basic and translational cancer research. Dysregulation of ATOX1, AK1 and HIST1HB2M could be detected as early as the pre-neoplastic stage. The findings have implications on early detection and stratification of patients for adjuvant therapy.     

Evaluation of functional RAGE gene polymorphisms in childhood acute lymphoblastic leukemia—A case-control study from Iran

We examined the possible relationship between three RAGE polymorphisms, ?429C/T, ?374 T/A, and 63-bp deletion, and susceptibility to childhood acute lymphoblastic leukemia (ALL) in an Iranian population. This study included 75 ALL patients and 115 healthy subjects. Genotyping was performed using HEXA-ARMS-polymerase chain reaction. We found no significant association among RAGE gene polymorphisms and the risk for ALL at genotype, allelic and haplotype levels (P > 0.05). The hemoglobin levels were higher in patients with RAGE ?374 TT than in the TA carriers (P = 0.019). Our results demonstrated that the RAGE gene variations were not associated with risk of pediatrics ALL.     

Detecting In Situ Copepod Diet Diversity Using Molecular Technique: Development of a Copepod/Symbiotic Ciliate-Excluding Eukaryote-Inclusive PCR Protocol

Knowledge of in situ copepod diet diversity is crucial for accurately describing pelagic food web structure but is challenging to achieve due to lack of an easily applicable methodology. To enable analysis with whole copepod-derived DNAs, we developed a copepod-excluding 18S rDNA-based PCR protocol. Although it is effective in depressing amplification of copepod 18S rDNA, its applicability to detect diverse eukaryotes in both mono- and mixed-species has not been demonstrated. Besides, the protocol suffers from the problem that sequences from symbiotic ciliates are overrepresented in the retrieved 18S rDNA libraries. In this study, we designed a blocking primer to make a combined primer set (copepod/symbiotic ciliate-excluding eukaryote-common: CEEC) to depress PCR amplification of symbiotic ciliate sequences while maximizing the range of eukaryotes amplified. We firstly examined the specificity and efficacy of CEEC by PCR-amplifying DNAs from 16 copepod species, 37 representative organisms that are potential prey of copepods and a natural microplankton sample, and then evaluated the efficiency in reconstructing diet composition by detecting the food of both lab-reared and field-collected copepods. Our results showed that the CEEC primer set can successfully amplify 18S rDNA from a wide range of isolated species and mixed-species samples while depressing amplification of that from copepod and targeted symbiotic ciliate, indicating the universality of CEEC in specifically detecting prey of copepods. All the predetermined food offered to copepods in the laboratory were successfully retrieved, suggesting that the CEEC-based protocol can accurately reconstruct the diets of copepods without interference of copepods and their associated ciliates present in the DNA samples. Our initial application to analyzing the food composition of field-collected copepods uncovered diverse prey species, including those currently known, and those that are unsuspected, as copepod prey. While testing is required, this protocol provides a useful strategy for depicting in situ dietary composition of copepods.     

一株稀有海洋真菌Stachybotrys longispora FG216的De Novo测序及基因组学分析

【背景】长孢葡萄穗霉菌(Stachybotrys longispora) FG216是一株稀有海洋真菌,其次生代谢产物FGFC1具有纤溶活性。进行S. longispora FG216的基因组序列分析,将充实和促进海洋微生物功能基因和次生代谢产物合成生物学的基础研究和应用研究。【目的】解析S. longispora FG216的基因组序列,分析基因组生物功能和同源相似性关系,分析次生代谢产物纤溶活性化合物FGFC1的相关基因。【方法】基于Illumina HiSeq高通量测序平台对S. longispora FG216菌株进行De Novo测序,使用SSPACE、Augustus等软件进行组装、编码基因预测、基因功能注释、物种共线性分析以及预测FGFC1次生代谢产物合成基因簇。【结果】S. longispora FG216的基因组测序总长度为45622830bp,共得到605个Scaffold,GC含量为51.31%,注释预测得到13329个编码基因和169个非编码RNA。基因组测序数据提交至国家微生物科学数据中心(编号为NMDC60016264),其中13 053、8 422、8 460、7 714和2 847个基因分别能够在NR、KEGG、KOG、GO和CAZy数据库匹配到注释信息。比较基因组学分析发现,Stachybotrys具有保守性,核心基因占基因家族总数目的71.44%,S. longispora FG216与S. chlorohalonata IBT 40285的相似性最高;同时,预测得到101个次生代谢产物合成基因簇,其中18个基因簇与已知的化合物相匹配。通过antiSMASH预测,Cluster57是编码合成FGFC1母核结构异吲哚啉酮的基因簇,与S.chlorohalonataIBT40285中的基因簇相似度为40%。【结论】海洋稀有真菌S.longisporaFG216的基因组信息已上传至国家微生物科学数据中心公开使用,为Stachybotrys种属的研究提供了重要的参考意义,同时发现了S. longispora FG216次生代谢产物纤溶活性化合物FGFC1母核部分编码基因是Cluster 57。     

Characterization of extracellular proteins produced by Aeromonas hydrophila AH-1

Aeromonas hydrophila is a ubiquitous Gram-negative bacterium which can cause motile aeromonad septicemia in both fish and humans. A. hydrophila secretes many extracellular proteins associated with pathogenicity and environmental adaptability. In this study, an extracellular proteome map of A. hydrophila AH-1 was constructed. The major extracellular virulence factors were characterized by comparing the proteomes of various deletion mutants with that of the wild type. The results suggested that serine protease was involved in the processing of a toxin and secreted enzymes such as hemolysin, glycerophospholipid-cholesterol acyltransferase and metalloprotease. We also showed that expressions of polar and lateral flagellins were under the control of temperature, FlhA, LafK, and RpoN. In addition, three novel proteins (potential effector proteins including one ExoT-like protein) were revealed to be secreted via the type III secretion system (TTSS) of A. hydrophila AH-1. Another novel finding was the demonstration of a crosstalk between the lateral flagellar system and the TTSS in A. hydrophila. These results showed that proteomics is a powerful tool for characterizing virulence factors. The construction of proteome maps will provide a valuable means of finding potential candidates for developing suitable diagnostics and therapeutics for this emerging pathogen.     

Intake of stigmasterol and β-sitosterol alters lipid metabolism and alleviates NAFLD in mice fed a high-fat western-style diet

Objective

To investigate and compare the effects of two common dietary phytosterols, stigmasterol and β-sitosterol, in altering lipid metabolism and attenuating nonalcoholic fatty liver disease (NAFLD).

Mechanism Underlying IκB Kinase Activation Mediated by the Linear Ubiquitin Chain Assembly Complex

The linear ubiquitin chain assembly complex (LUBAC) ligase, consisting of HOIL-1L, HOIP, and SHARPIN, specifically generates linear polyubiquitin chains. LUBAC-mediated linear polyubiquitination has been implicated in NF-κB activation. NEMO, a component of the IκB kinase (IKK) complex, is a substrate of LUBAC, but the precise molecular mechanism underlying linear chain-mediated NF-κB activation has not been fully elucidated. Here, we demonstrate that linearly polyubiquitinated NEMO activates IKK more potently than unanchored linear chains. In mutational analyses based on the crystal structure of the complex between the HOIP NZF1 and NEMO CC2-LZ domains, which are involved in the HOIP-NEMO interaction, NEMO mutations that impaired linear ubiquitin recognition activity and prevented recognition by LUBAC synergistically suppressed signal-induced NF-κB activation. HOIP NZF1 bound to NEMO and ubiquitin simultaneously, and HOIP NZF1 mutants defective in interaction with either NEMO or ubiquitin could not restore signal-induced NF-κB activation. Furthermore, linear chain-mediated activation of IKK2 involved homotypic interaction of the IKK2 kinase domain. Collectively, these results demonstrate that linear polyubiquitination of NEMO plays crucial roles in IKK activation and that this modification involves the HOIP NZF1 domain and recognition of NEMO-conjugated linear ubiquitin chains by NEMO on another IKK complex.     

Prostaglandin (PG) accumulation by mouse ovaries, oviducts, and uteri

Uteri, ovaries and oviducts from mice were collected at autopsy. Tissue slices were incubated with [³H]-PGE₂ in the presence or absence of a large excess (100 fold) of nonradioactive PGE₂ using 0.01M sodium phosphate buffer (pH 7.2). Bound and free PGs were separated by a filtration technique. PGE₂ accumulation by the uteri was evaluated as a function of incubation time, wet weight of tissues, and reproductive state. The tissue to medium ratio (T/M) was greater than 1.0 for uteri as the time of incubation increased. This suggests the presence of PGE₂ binding sites in mouse uterine tissue. Also, PGE₂ accumulation was not observed in oviducts or in ovaries.