急性捕食风险不能完全限制饥饿 雌性长爪沙鼠的觅食活动

觅食活动是动物生存和繁殖所必需的基本的活动,受个体生理状态（如饥饿）和环境状况（如捕食、食物可利用性）时空变化的影响,能量状态-风险分配假说指出,动物在应对不同风险时会优化觅食和反捕食努力的时间和能量分配。然而,有关啮齿动物觅食决策的能量状态-捕食风险分配假说的研究结论尚不统一。本研究在野外实验室以艾鼬（Mustela eversmannii）气味作为捕食风险刺激源,以非捕食者（马）气味源作为对照,首先通过Y型观测箱检验雌性饥饿长爪沙鼠（Meriones unguiculatus）对捕食者气味的辨别能力（Wilcoxon 秩检验）;在此基础上通过中立场行为观测箱分别测定饥饿雌鼠在“有食物和天敌气味源”与“有食物和非天敌气味源”环境下的觅食活动,采用Mann-Whitney Z检验比较两者间的行为差异,以验证急性捕食风险限制饥饿沙鼠觅食活动的假设,并探讨动物在饥饿风险与捕食风险共存情况下的觅食行为对策。结果显示,（1）长爪沙鼠对天敌气味反应明显,厌恶和回避有较高潜在捕食风险的空间;（2）虽然觅食潜伏期在捕食风险存在时有所增加,但急性捕食风险并未影响饥饿沙鼠的觅食频次,沙鼠通过缩短每次觅食的持续时间来应对捕食风险;与此同时,（3）饥饿沙鼠在急性捕食风险条件下对环境探究的次数明显增加,一定程度上提高反捕食努力,且自我修饰表现显著,以缓释捕食压力的恐惧效应。这些结果表明,急性捕食风险不能完全抑制饥饿沙鼠的觅食努力,在有捕食风险情况下,饥饿的长爪沙鼠会权衡觅食获取能量和避免捕食的收益和代价,优化觅食策略。本研究结果支持能量状态-风险分配假说关于在短期高风险情况下反捕食努力分配更多,但当动物在饥饿风险持续时间比例显著增加时,动物最终也必须在高风险情况下觅食的预测,也反映了长爪沙鼠对食物资源不可预测及捕食风险高的干旱半干旱荒漠环境的行为适应对策。     

Cave-adapted evolution in the North American amblyopsid fishes inferred using phylogenomics and geometric morphometrics

Cave adaptation has evolved repeatedly across the Tree of Life, famously leading to pigmentation and eye degeneration and loss, yet its macroevolutionary implications remain poorly understood. We use the North American amblyopsid fishes, a family spanning a wide degree of cave adaptation, to examine the impact of cave specialization on the modes and tempo of evolution. We reconstruct evolutionary relationships using ultraconserved element loci, estimate the ancestral histories of eye-state, and examine the impact of cave adaptation on body shape evolution. Our phylogenomic analyses provide a well-supported hypothesis for amblyopsid evolutionary relationships. The obligate blind cavefishes form a clade and the cave-facultative eyed spring cavefishes are nested within the obligate cavefishes. Using ancestral state reconstruction, we find support for at least two independent subterranean colonization events within the Amblyopsidae. Eyed and blind fishes have different body shapes, but not different rates of body shape evolution. North American amblyopsids highlight the complex nature of cave-adaptive evolution and the necessity to include multiple lines of evidence to uncover the underlying processes involved in the loss of complex traits.     

NADPH缺陷型Corynebacterium glutamicum重组菌株的构建及其性能分析

[目的]改造谷氨酸棒杆菌(Corynebacterium glutamicum)中NADPH合成途径,阻断胞内NADPH的合成,获得1株NADPH营养缺陷型菌株。[方法]通过失活L-赖氨酸高产菌C. glutamicum Lys-χ中葡萄糖-6-磷酸脱氢酶(Zwf)和苹果酸酶(MalE)并将NADP~+依赖型异柠檬酸脱氢酶(NADP~+-Icdcg)替换成变形链球菌(Streptococcus mutans)中的NAD~+-Icdsm,阻断胞内NADPH的合成。随后结合辅因子工程,引入大肠杆菌(Escherichia coli)中膜结合吡啶核苷酸转氢酶(PntAB)并通过不同强度启动子控制PntAB的表达水平。最后,分析不同重组菌中胞内氧化还原水平和L-赖氨酸生产强度的变化。[结果]重组菌C.glutamicum Lys-χΔZMI_(Cg)::I_(Sm)(即Lys-x1)胞内检测不到NADPH,为1株NADPH营养缺陷型菌株。该重组菌只在以葡萄糖酸为碳源的基础培养基中生长和积累L-赖氨酸,而以葡萄糖、丙酮酸、α-酮戊二酸和草酰乙酸为碳源时无法生长。此外,表达E.coli中的PntAB可回补重组菌Lys-χ1胞内NADPH的水平,但由于不同强度启动子控制PntAB表达水平不同,重组菌胞内NADPH水平也不同,并影响L-赖氨酸的生产强度。[结论]重组菌Lys-χ1可作为有效的底盘细胞,用于考察不同的NADPH再生策略,获得不同胞内NADPH水平的重组菌株,为进一步阐明NADPH调控微生物细胞生理代谢功能的机制提供研究基础。     

Disorder and order in unfolded and disordered peptides and proteins: A view derived from tripeptide conformational analysis. II. Tripeptides with short side chains populating asx and β‐type like turn conformations

In the preceding paper, we found that ensembles of tripeptides with long or bulky chains can include up to 20% of various turns. Here, we determine the structural and thermodynamic characteristics of GxG peptides with short polar and/or ionizable central residues (D, N, C), whose conformational distributions exhibit higher than average percentage (>20%) of turn conformations. To probe the side‐chain conformations of these peptides, we determined the ³J(H^α,H^β) coupling constants and derived the population of three rotamers with χ₁‐angles of ?60°, 180° and 60°, which were correlated with residue propensities by DFT‐calculations. For protonated GDG, the rotamer distribution provides additional evidence for asx‐turns. A comparison of vibrational spectra and NMR coupling constants of protonated GDG, ionized GDG, and the protonated aspartic acid dipeptide revealed that side chain protonation increases the pPII content at the expense of turn populations. The charged terminal groups, however, have negligible influence on the conformational properties of the central residue. Like protonated GDG, cationic GCG samples asx‐turns to a significant extent. The temperature dependence of the UVCD spectra and ³J(H^NH^α) constants suggest that the turn populations of GDG and GNG are practically temperature‐independent, indicating enthalpic and entropic stabilization. The temperature‐independent J‐coupling and UVCD spectra of GNG require a three‐state model. Our results indicate that short side chains with hydrogen bonding capability in GxG segments of proteins may serve as hinge regions for establishing compact structures of unfolded proteins and peptides. Proteins 2013. © 2012 Wiley Periodicals, Inc.     

Theoretical Study On The Reaction Mechanism Of Gecl3ch2ch2cooh+h2o→gecl2ohch2ch2cooh+hcl

The mechanism and dynamical properties for the title reaction have been investigated theoretically. Three reaction pathways have been found. Geometries, vibrational frequencies, infra-red (IR) intensities and relative energies for various stationary points in the three reaction channels have been determined respectively. The corresponding rate constants at the B3LYP/6-31++G(2d,2p) level have been deduced over a wide temperature range of 200–2000 K by using canonical variational transition state theory with small curvature tunnelling effect. Solvent effects are taken into account via the Onsager model of self-constant reaction field at the same level of theory. This preliminary study shows that the complex formation is favoured by the use of water solvent.     

Controllers for imposing continuum-to-molecular boundary conditions in arbitrary fluid flow geometries

We present a new parallelised controller for steering an arbitrary geometric region of a molecular dynamics (MD) simulation towards a desired thermodynamic and hydrodynamic state. We show that the controllers may be applied anywhere in the domain to set accurately an initial MD state, or solely at boundary regions to prescribe non-periodic boundary conditions (PBCs) in MD simulations. The mean molecular structure and velocity autocorrelation function remain unchanged (when sampled a few molecular diameters away from the constrained region) when compared with those distributions measured using PBCs. To demonstrate the capability of our new controllers, we apply them as non-PBCs in parallel to a complex MD mixing nano-channel and in a hybrid MD continuum simulation with a complex coupling region. The controller methodology is easily extendable to polyatomic MD fluids.     

Monte Carlo Study of the Buckingham Exponential-six Fluid

Abstract

In this paper we report the results of extensive Monte Carlo simulations of a pure fluid of Buckingham modified exponential-six molecules. Data are presented for the configurational energy and pressure covering a wide range of temperatures and densities. These data are interpreted using the generalized van der Waals partition function with a novel separation into free volume and mean potential terms. We find, surprisingly, that the Buckingham fluid is described by a simple van der Waals-like equation of state provided that the b parameter is temperature dependent and chosen in a theoretically correct manner.     

Excited state intramolecular proton transfer in 3-hydroxychromone: a DFT-based computational study

Potential energy (PE) curves for intramolecular proton transfer in the ground (GSIPT) and intramolecular proton transfer in the excited (ESIPT) states of 3-hydroxychromone (3HC) have been studied using DFT-B3LYP/6-31G(d,p) and TD-DFT/6-31G(d,p) level of theory, respectively. Our calculations suggest the non-viability of GSIPT in 3HC. Excited states PE calculations show the existence of ESIPT process in 3HC. ESIPT in 3HC has also been explained in terms of HOMO and LUMO electron densities of the enol and keto tautomers of 3HC.     

Population density analysis for determining the protonation state of the catalytic dyad in BACE1-tertiary carbinamine-based inhibitor complex

BACE1 is an aspartyl protease with a very relevant role in medicinal chemistry related to Alzheimer Disease since it has demonstrated to be a promising therapeutic target for inhibition and possible control for the progress of the peptide accumulation characteristic of this pathology. The enzymatic activity of this protein is given by the aspartic dyad, Asp93 and Asp289, which can adopt several protonation states depending on the chemical nature of its inhibitors, this is, monoprotonated, diprotonated and di-deprotonated states. In the present study, the analysis of the population density, for a series of protein-inhibitor molecular dynamics simulations, was carried out to identify the most feasible protonation state adopted by the catalytic dyad in the presence of tertiary carbinamine (TC) transition state analog inhibitors. The results revealed that the monoprotonated Asp289i state, in which the Asp93 and Asp289 residue side chains are deprotonated and protonated on the inner oxygen, respectively, is the most preferred in the presence of TC family inhibitors. This result was obtained after evaluating, for all 9 possible protonation state configurations, the individual and combined population densities of a set of parameters sensitive to protonation state of the Aspartic dyad, using an X-ray experimental BACE1/TC crystallographic structure as reference. This case study demonstrates again the usefulness of the concept of population density as a quantitative tool to establish the most stable system settings, among all possible, by measuring the level of occurrence of simultaneous events obtained from a sampling over time. These results will help to clear the phenomena related to the TCs inhibitory pathway, as well as assist in the design of better TC inhibitors against Alzheimer’s protease.     

Remarkable disparity in mechanical response among the extracellular domains of type I and II cadherins

Cadherins, a large family of calcium-dependent adhesion molecules, are critical for intercellular adhesion. While crystallographic structures for several cadherins show clear structural similarities, their relevant adhesive strengths vary and their mechanisms of adhesion between types I and II cadherin subfamilies are still unclear. Here, stretching of cadherins was explored experimentally by atomic force microscopy and computationally by steered molecular dynamics (SMD) simulations, where partial unfolding of the E-cadherin ectodomains was observed. The SMD simulations on strand-swapping cadherin dimers displayed similarity in binding strength, suggesting contributions of other mechanisms to explain the strength differences of cell adhesion in vivo. Systematic simulations on the unfolding of the extracellular domains of type I and II cadherins revealed diverse pathways. However, at the earliest stage, a remarkable similarity in unfolding was observed for the various type I cadherins that was distinct from that for type II cadherins. This likely correlates positively with their distinct adhesive properties, suggesting that the initial forced deformation in type I cadherins may be involved in cadherin-mediated adhesion.

An animated Interactive 3D Complement (I3DC) is available in Proteopedia at http://proteopedia.org/w/Journal:JBSD:25