Conformational analysis of the full‐length M2 protein of the influenza A virus using solid‐state NMR

The influenza A M2 protein forms a proton channel for virus infection and mediates virus assembly and budding. While extensive structural information is known about the transmembrane helix and an adjacent amphipathic helix, the conformation of the N‐terminal ectodomain and the C‐terminal cytoplasmic tail remains largely unknown. Using two‐dimensional (2D) magic‐angle‐spinning solid‐state NMR, we have investigated the secondary structure and dynamics of full‐length M2 (M2FL) and found them to depend on the membrane composition. In 2D ¹³C DARR correlation spectra, 1,2‐dimyristoyl‐sn‐glycero‐3‐phosphocholine (DMPC)‐bound M2FL exhibits several peaks at β‐sheet chemical shifts, which result from water‐exposed extramembrane residues. In contrast, M2FL bound to cholesterol‐containing membranes gives predominantly α‐helical chemical shifts. Two‐dimensional J‐INADEQUATE spectra and variable‐temperature ¹³C spectra indicate that DMPC‐bound M2FL is highly dynamic while the cholesterol‐containing membranes significantly immobilize the protein at physiological temperature. Chemical‐shift prediction for various secondary‐structure models suggests that the β‐strand is located at the N‐terminus of the DMPC‐bound protein, while the cytoplasmic domain is unstructured. This prediction is confirmed by the 2D DARR spectrum of the ectodomain‐truncated M2(21–97), which no longer exhibits β‐sheet chemical shifts in the DMPC‐bound state. We propose that the M2 conformational change results from the influence of cholesterol, and the increased helicity of M2FL in cholesterol‐rich membranes may be relevant for M2 interaction with the matrix protein M1 during virus assembly and budding. The successful determination of the β‐strand location suggests that chemical‐shift prediction is a promising approach for obtaining structural information of disordered proteins before resonance assignment.     

Phylogeography of Sophora davidii (Leguminosae) across the ‘Tanaka‐Kaiyong Line’, an important phytogeographic boundary in Southwest China

The ‘Tanaka‐Kaiyong Line’ (TKL) is a major phytogeographic boundary in Southwest China, separating East Asia's Sino‐Himalayan and Sino‐Japanese Floras. However, little is known about the importance of this boundary in promoting intraspecific phylogeographic subdivision and divergence. Using chloroplast (cpDNA) and nuclear‐intron (nDNA) sequence data, we reconstructed the population history of Sophora davidii, a drought‐tolerant riparian shrub widely distributed on either side of the TKL. Specifically, we aimed at testing two long‐standing explanations for possible vicariant events across the TKL: (i) Late Pliocene (c. 3 Ma) geological uplift of the eastern Qinghai‐Tibetan Plateau (QTP) or (ii) a sharp environmental gradient associated with the establishment of different monsoon regimes on either side of the TKL during the (Late) Pleistocene. Our genealogical analyses detected a major west–east split in cpDNA, geographically largely consistent with the TKL, and dated to c. 1.28 Ma (95% HPD: 0.21–2.96 Ma), hence postdating the latest phase of eastern QTP uplift. Furthermore, integrating cpDNA phylogeographic patterns with mismatch analyses, we found multiple refugial isolation and long‐term demographic stability of populations in the west (Hengduan Mountain Range) compared with extensive range expansions in the east, possibly during the last glacial period(s) and followed by differentiation into regional sublineages (southeast: Yunnan‐Guizhou Plateau vs. northeast: Qinling Mts./Loess Plateau). Although nuclear differentiation was less marked, the geographical pattern of nDNA haplotypes provided some further indication of the species' eastward expansion, possibly from source populations located just east of the TKL (lower Jinshajiang region). Overall, the present data reject the geological (tectonic) explanation for the TKL and, instead, provide supportive evidence for its role as a climatically driven barrier to present‐day plant dispersal. In addition, our study highlights changing temperatures and vegetation types during the last glacial period(s), along with aspects of regional topography, to be important determinants of the glacial eastward expansion of S. davidii. In consequence, our study lends support to a ‘glacial out‐of‐Hengduan Mts’. hypothesis for the xerophytic‐riparian flora of Southwest China, which in turn is inconsistent with the traditional view of the TKL as a ‘classical’ vicariant‐biogeographic boundary.     

Hexokinase from grape berries: its prokaryotic expression, polyclonal antibody preparation and biochemical property analyses

Two full-length hexokinase (HXK, EC 2.7.1.1) cDNAs, VvHXK1 with 1,413 bp and VvHXK2 with 1,458 bp were cloned from grape berries (Vitis vinifera L. Cabernet Sauvignon). VvHXK1 and VvHXK2 genes sequence from grape berries were deposited in GenBank under the accession number JN118544 and JN118545, respectively. The homology of the amino acid of VvHXK1 or VvHXK2 was very similar to ‘Pinot Noir’ grape HXK sequence, their similarties were 99.36 % and 98.97 %, respectively. More intuitive phylogenetic tree showed that the homology of amino acid sequence VvHXK1 with melon CmHXK1 was 86 %, and VvHXK2 homology with rice OsHXK3 was 83 %. The HXK proteins were successfully expressed in plasmid pET-30a (+) vectors in Escherichia coli BL21 (DE3) pLysS. The expressed proteins were purified using Ni-NTA agarose column and used to produce HXK1 antibody and conducted HXK protein blotting analysis. The results,suggested that one polypeptide band of about 51 kDa HXK protein can be detected in grape berries, HXK protein level was the highest during early grape berry development, but the lowest from 50d to 60d during development. Biochemical analysis of two hexokinase isozymes indicated that glucose was the optimal substrate of HXK, The isoelectric points of the two isozymes were 5.8 and 5.6, respectively. And the optimum pH was about 8.0. These results provide a substantial basis for the further studies of functions of grape HXKs to manipulate sugar content of grape berries.     

辽宁老秃顶子自然保护区植物区系多样性

通过野外实地调查,利用植物区系谱、多样性指数、相关分析和聚类模型等方法,对辽宁老秃顶子植物区系多样性进行量化分析,揭示山地生物多样性特点、规律以及与周边植被生态的关系。结果表明:(1)辽宁老秃顶子自然保护区种子植物种类组成丰富,共有野生种子植物123科429属1 006种,且优势科现象明显,单种属和少种属占比率较高,表现出一定古老残遗性。（2）老秃顶子自然保护区植物种的区系分布型多样,区系组成复杂,来源较广泛,具有一定古老性,但植物特有现象不明显,以温带性质分布种为主,符合暖温带北部的华北植物区系特点。(3)老秃顶子山与相邻9个山地比较,植物区系Shannon-Wiener指数差异明显(1.736～2.259),其中庐山和徂徕山的Shannon-Wiener指数较高,而白石砬子和长白山的较低;10个山地的Simpson指数差异不显著(0.711 4～0.871 5)。(4)相关性分析显示,10个不同山地植物区系之间的相似程度显著,相关系数达0.617～0.995;聚类分析显示,老秃顶子山与千山、凤凰山的植物区系关系较近。本研究结果支持老秃顶子山、千山和凤凰山共同划归华北植物区系的观点,认为把老秃顶子山保护区植物区系划归于华北山地植物亚地区较为合理。     

青藏高原东缘常见种长毛风毛菊(Saussurea hieracioides)的繁殖分配

对分布在青藏高原东缘高寒草甸常见种长毛风毛菊的6个海拔梯度(3200～3850m)18个居群的繁殖分配进行了研究,结果表明:长毛风毛菊随海拔的升高个体和营养器官减小,繁殖的投入增加;随着海拔的升高,长毛风毛菊的个体管状小花数目和种子数目减少,管状小花重量和百粒重增大;个体管状小花的数目及重量和个体种子的数目及重量间存在权衡关系;长毛风毛菊的个体大小和繁殖分配存在负相关关系。在资源受限的环境下,长毛风毛菊以减少管状小花数目和种子的数目来增加管状小花重量和百粒重,是保证有性繁殖成功的策略之一。     

云南省2006～2010年非脊灰肠道病毒分子流行病学特征分析

为了解云南省非脊髓灰质炎(脊灰)肠道病毒(NPEV)的基因型分布及分子进化特征,对2006～2010年间从急性迟缓性麻痹(AFP)病例中分离到的105株NPEVs进行VP1区部分核苷酸扩增和序列测定。所获得的云南地方株基因序列与各基因型原型株进行核苷酸与氨基酸同源性比较,并与GenBank中选取的代表株构建基因进化关系树。结果分析显示:105株NPEVs分别属于HEV-A、HEV-B、HEV-C,其中HEV-A 18株(7个血清型)所占比例为17.1%;HEV-B 77株(22个血清型)所占比例为73.3%,表明云南省AFP病例中流行的NPEV还是以HEV-B为主;HEV-C 10株(4个血清型)所占比例为9.5%;没有分离到HEV-D组肠道病毒;基因进化树中各种血清型病毒与对应原型株及代表株聚集一起,除CA2、EV90和EV76外,云南地方株与原型株位于不同分支。相同型别的毒株在5年的流行过程中变异程度亦不同,亲缘关系远近不一,表明这些病毒在云南省存在不同的传播链。     

Cationic membrane peptides: atomic-level insight of structure–activity relationships from solid-state NMR

Many membrane-active peptides, such as cationic cell-penetrating peptides (CPPs) and antimicrobial peptides (AMPs), conduct their biological functions by interacting with the cell membrane. The interactions of charged residues with lipids and water facilitate membrane insertion, translocation or disruption of these highly hydrophobic species. In this review, we will summarize high-resolution structural and dynamic findings towards the understanding of the structure–activity relationship of lipid membrane-bound CPPs and AMPs, as examples of the current development of solid-state NMR (SSNMR) techniques for studying membrane peptides. We will present the most recent atomic-resolution structure of the guanidinium-phosphate complex, as constrained from experimentally measured site-specific distances. These SSNMR results will be valuable specifically for understanding the intracellular translocation pathway of CPPs and antimicrobial mechanism of AMPs, and more generally broaden our insight into how cationic macromolecules interact with and cross the lipid membrane.     

Proteomic analysis of kidney and protective effects of grape seed procyanidin B2 in db/db mice indicate MFG-E8 as a key molecule in the development of diabetic nephropathy

Diabetic nephropathy, as a severe microvascular complication of diabetic mellitus, has become the leading cause of end-stage renal diseases. However, no effective therapeutic strategy has been developed to prevent renal damage progression to end stage renal disease. Hence, the present study evaluated the protective effects of grape seed procyanidin B2 (GSPB2) and explored its molecular targets underlying diabetic nephropathy by a comprehensive quantitative proteomic analysis in db/db mice. Here, we found that oral administration of GSPB2 significantly attenuated the renal dysfunction and pathological changes in db/db mice. Proteome analysis by isobaric tags for relative and absolute quantification (iTRAQ) identified 53 down-regulated and 60 up-regulated proteins after treatment with GSPB2 in db/db mice. Western blot analysis confirmed that milk fat globule EGF-8 (MFG-E8) was significantly up-regulated in diabetic kidney. MFG-E8 silencing by transfection of MFG-E8 shRNA improved renal histological lesions by inhibiting phosphorylation of extracellular signal-regulated kinase1/2 (ERK1?2), Akt and glycogen synthase kinase-3beta (GSK-3β) in kidneys of db/db mice. In contrast, over-expression of MFG-E8 by injection of recombinant MFG-E8 resulted in the opposite effects. GSPB2 treatment significantly decreased protein levels of MFG-E8, phospho-ERK1/2, phospho-Akt, and phospho-GSK-3β in the kidneys of db/db mice. These findings yield insights into the pathogenesis of diabetic nephropathy, revealing MFG-E8 as a new therapeutic target and indicating GSPB2 as a prospective therapy by down-regulation of MFG-E8, along with ERK1/2, Akt and GSK-3β signaling pathway.     

Halogen bonding (X‐bonding): A biological perspective

The concept of the halogen bond (or X‐bond) has become recognized as contributing significantly to the specificity in recognition of a large class of halogenated compounds. The interaction is most easily understood as primarily an electrostatically driven molecular interaction, where an electropositive crown, or σ‐hole, serves as a Lewis acid to attract a variety of electron‐rich Lewis bases, in analogous fashion to a classic hydrogen bonding (H‐bond) interaction. We present here a broad overview of X‐bonds from the perspective of a biologist who may not be familiar with this recently rediscovered class of interactions and, consequently, may be interested in how they can be applied as a highly directional and specific component of the molecular toolbox. This overview includes a discussion for where X‐bonds are found in biomolecular structures, and how their structure–energy relationships are studied experimentally and modeled computationally. In total, our understanding of these basic concepts will allow X‐bonds to be incorporated into strategies for the rational design of new halogenated inhibitors against biomolecular targets or toward molecular engineering of new biological‐based materials.     

AEBP1 upregulation confers acquired resistance to BRAF (V600E) inhibition in melanoma

An activating BRAF (V600E) kinase mutation occurs in approximately half of melanomas. Recent clinical studies have demonstrated that vemurafenib (PLX4032) and dabrafenib, potent and selective inhibitors of mutant v-raf murine sarcoma viral oncogene homolog B1 (BRAF), exhibit remarkable activities in patients with V600 BRAF mutant melanomas. However, acquired drug resistance invariably develops after the initial treatment. Identification of acquired resistance mechanisms may inform the development of new therapies that elicit long-term responses of melanomas to BRAF inhibitors. Here we report that increased expression of AEBP1 (adipocyte enhancer-binding protein 1) confers acquired resistance to BRAF inhibition in melanoma. AEBP1 is shown to be highly upregulated in PLX4032-resistant melanoma cells because of the hyperactivation of the PI3K/Akt-cAMP response element-binding protein (CREB) signaling pathway. This upregulates AEBP1 expression and thus leads to the activation of NF-κB via accelerating IκBa degradation. In addition, inhibition of the PI3K/Akt-CREB-AEBP1-NF-κB pathway greatly reverses the PLX4032-resistant phenotype of melanoma cells. Furthermore, increased expression of AEBP1 is validated in post-treatment tumors in patients with acquired resistance to BRAF inhibitor. Therefore, these results reveal a novel PI3K/Akt-CREB-AEBP1-NF-κB pathway whose activation contributes to acquired resistance to BRAF inhibition, and suggest that this pathway, particularly AEBP1, may represent a novel therapeutic target for treating BRAF inhibitor-resistant melanoma.