Mechanical unfolding of TNfn3: the unfolding pathway of a fnIII domain probed by protein engineering, AFM and MD simulation

Protein engineering Phi-value analysis combined with single molecule atomic force microscopy (AFM) was used to probe the molecular basis for the mechanical stability of TNfn3, the third fibronectin type III domain from human tenascin. This approach has been adopted previously to solve the forced unfolding pathway of a titin immunoglobulin domain, TI I27. TNfn3 and TI I27 are members of different protein superfamilies and have no sequence identity but they have the same beta-sandwich structure consisting of two antiparallel beta-sheets. TNfn3, however, unfolds at significantly lower forces than TI I27. We compare the response of these proteins to mechanical force. Mutational analysis shows that, as is the case with TI I27, TNfn3 unfolds via a force-stabilised intermediate. The key event in forced unfolding in TI I27 is largely the breaking of hydrogen bonds and hydrophobic interactions between the A' and G-strands. The mechanical Phi-value analysis and molecular dynamics simulations reported here reveal that significantly more of the TNfn3 molecule contributes to its resistance to force. Both AFM experimental data and molecular dynamics simulations suggest that the rate-limiting step of TNfn3 forced unfolding reflects a transition from the extended early intermediate to an aligned intermediate state. As well as losses of interactions of the A and G-strands and associated loops there are rearrangements throughout the core. As was the case for TI I27, the forced unfolding pathway of TNfn3 is different from that observed in denaturant studies in the absence of force.     

Protein interactions and misfolding analyzed by AFM force spectroscopy

Protein misfolding is conformational transition dramatically facilitating the assembly of protein molecules into aggregates of various morphologies. Spontaneous formation of specific aggregates, mostly amyloid fibrils, was initially believed to be limited to proteins involved in the development of amyloidoses. However, recent studies show that, depending on conditions, the majority of proteins undergo structural transitions leading to the appearance of amyloidogenic intermediates followed by aggregate formation. Various techniques have been used to characterize the protein misfolding facilitating the aggregation process, but no direct evidence as to how such a conformational transition increases the intermolecular interactions has been obtained as of yet. We have applied atomic force microscopy (AFM) to follow the interaction between protein molecules as a function of pH. These studies were performed for three unrelated and structurally distinctive proteins, alpha-synuclein, amyloid beta-peptide (Abeta) and lysozyme. It was shown that the attractive force between homologous protein molecules is minimal at physiological pH and increases dramatically at acidic pH. Moreover, the dependence of the pulling forces is sharp, suggesting a pH-dependent conformational transition within the protein. Parallel circular dichroism (CD) measurements performed for alpha-synuclein and Abeta revealed that the decrease in pH is accompanied by a sharp conformational transition from a random coil at neutral pH to the more ordered, predominantly beta-sheet, structure at low pH. Importantly, the pH ranges for these conformational transitions coincide with those of pulling forces changes detected by AFM. In addition, protein self-assembly into filamentous aggregates studied by AFM imaging was shown to be facilitated at pH values corresponding to the maximum of pulling forces. Overall, these results indicate that proteins at acidic pH undergo structural transition into conformations responsible for the dramatic increase in interprotein interaction and promoting the formation of protein aggregates.     

Spring-mass running: simple approximate solution and application to gait stability

The planar spring-mass model is frequently used to describe bouncing gaits (running, hopping, trotting, galloping) in animal and human locomotion and robotics. Although this model represents a rather simple mechanical system, an analytical solution predicting the center of mass trajectory during stance remains open. We derive an approximate solution in elementary functions assuming a small angular sweep and a small spring compression during stance. The predictive power and quality of this solution is investigated for model parameters relevant to human locomotion. The analysis shows that (i), for spring compressions of up to 20% (angle of attack > or = 60 degree, angular sweep < or = 60 degree) the approximate solution describes the stance dynamics of the center of mass within a 1% tolerance of spring compression and 0.6 degree tolerance of angular motion compared to numerical calculations, and (ii), despite its relative simplicity, the approximate solution accurately predicts stable locomotion well extending into the physiologically reasonable parameter domain. (iii) Furthermore, in a particular case, an explicit parametric dependency required for gait stability can be revealed extending an earlier, empirically found relationship. It is suggested that this approximation of the planar spring-mass dynamics may serve as an analytical tool for application in robotics and further research on legged locomotion.     

Atomic force microscopy and laser confocal scanning microscopy analysis of callose fibers developed from protoplasts of embryogenic cells of a conifer

Efficiency of novel fiber formation was much improved in protoplast culture of embryogenic cells (ECs) of a conifer, Larix leptolepis (Sieb. et Zucc.) Gord., by pre-culturing ECs in a medium containing a high concentration of glutamine (13.7 mM). The fibrillar substructures of large and elongated fibers of protoplasts isolated from Larix ECs were investigated by laser confocal scanning microscopy (LCSM) after Aniline Blue staining and atomic force microscopy (AFM) using a micromanipulator without any pre-treatment. Fibers were composed of bundles of fibrils and subfibrils, whose diameters were defined as 0.7 and 0.17 μm, respectively, by image analysis after LCSM and AFM. These fibers were proven to be composed of callose by using specific degrading enzymes for β-1,4-glucan and β-1,3-glucan.     

Pretransition and progressive softening of bovine carbonic anhydrase II as probed by single molecule atomic force microscopy

To develop a simple method for probing the physical state of surface adsorbed proteins, we adopted the force curve mode of an atomic force microscope (AFM) to extract information on the mechanical properties of surface immobilized bovine carbonic anhydrase II under native conditions and in the course of guanidinium chloride-induced denaturation. A progressive increase in the population of individually softened molecules was probed under mildly to fully denaturing conditions. The use of the approach regime of force curves gave information regarding the height and rigidity of the molecule under compressive stress, whereas use of the retracting regime of the curves gave information about the tensile characteristics of the protein. The results showed that protein molecules at the beginning of the transition region possessed slightly more flattened and significantly more softened conformations compared with that of native molecules, but were still not fully denatured, in agreement with results based on solution studies. Thus the force curve mode of an AFM was shown to be sensitive enough to provide information concerning the different physical states of single molecules of globular proteins.     

Effects of Phe-to-Trp mutation and fluorotryptophan incorporation on the solution structure of cardiac troponin C, and analysis of its suitability as a potential probe for in situ NMR studies

19F NMR spectroscopy is potentially a powerful tool for probing protein properties in situ. However, results obtained using this technique are relevant only if the 19F probe offers minimal perturbation to the surrounding environment. In this paper, we examine the effect of 5-fluorotryptophan (5fW) incorporation on the three-dimensional structure of cardiac troponin-C (cTnC), with the intention of developing a 19F-labeled TnC for use in in situ 19FNMR. We find that, in general, 5fW does not perturb the structure of the protein significantly. Replacement of residue Phe 153 with 5fW produces no noticeable change in protein conformation. However, replacement of residue Phe 104 with 5fW produces a folding behavior that is dependent on the Escherichia coli strain used to express the mutant. The orientations of the indole rings in these mutants are such that the Trp residue adopts a chi2 of approximately 90 degrees in the F104W mutant and approximately -100 degrees in the F153W mutant. Using results from 19F-1H heteronuclear NOE experiment, we show the replacement of L-Trp with 5fW at these positions does not change the orientation of the indole ring and the spread of the 5fW side-chain dihedral angles increases moderately for the F104(5fW) mutant and not at all for the F153(5fW) mutant. Based on these structures, we conclude that the substitution of Phe by 5fW at these two positions has minimal effects on the structure of cTnC and that the 5fW indole rings in both mutants have well defined orientation, making the two mutants viable candidates for use in in situ 19F NMR spectroscopy.     

A comparative study on intrinsic fluorescence of BSA and lysozyme proteins in presence of different divalent ions from their solution and thin film conformations

Optical emission behaviours of lysozyme and bovine serum albumin, from bulk and thin film geometry, were studied in the presence of three different divalent ions (Mg²⁺, Ca²⁺ or Ba²⁺) using different spectroscopic [steady‐state fluorescence, UV–Vis and Fourier transform infra‐red (FTIR)] techniques. Additionally, protein thin films on silicon surfaces were prepared and morphological studies were carried out using atomic force microscopy. Dynamic quenching was mainly identified for both proteins in the presence of Mg²⁺, Ca²⁺ and Ba²⁺ ions. The molecular conformation of the proteins was modified in thin films compared with that in solution, consequently quenching efficiencies also varied. ATR‐FTIR studies confirmed the conformational changes of proteins in the presence of all divalent ions. All metal ions used were divalent in nature and belonged to the same group of the periodic table but, depending on their individual characteristics such as electron affinity, ionic radius, etc., the magnitude of the protein and hydrated ion interaction varied and accordingly the quenching efficiency was modified. Quenching was maximum for Ca²⁺ ions, followed by the other two ions. Our study clearly illustrates the geometry‐dependent physical and biological functions of proteins.     

Lipid droplets induced by secreted phospholipase A2 and unsaturated fatty acids protect breast cancer cells from nutrient and lipotoxic stress

Cancer cells driven by the Ras oncogene scavenge unsaturated fatty acids (FAs) from their environment to counter nutrient stress. The human group X secreted phospholipase A₂ (hGX sPLA₂) releases FAs from membrane phospholipids, stimulates lipid droplet (LD) biogenesis in Ras-driven triple-negative breast cancer (TNBC) cells and enables their survival during starvation. Here we examined the role of LDs, induced by hGX sPLA₂ and unsaturated FAs, in protection of TNBC cells against nutrient stress. We found that hGX sPLA₂ releases a mixture of unsaturated FAs, including ω-3 and ω-6 polyunsaturated FAs (PUFAs), from TNBC cells. Starvation-induced breakdown of LDs induced by low micromolar concentrations of unsaturated FAs, including PUFAs, was associated with protection from cell death. Interestingly, adipose triglyceride lipase (ATGL) contributed to LD breakdown during starvation, but it was not required for the pro-survival effects of hGX sPLA₂ and unsaturated FAs. High micromolar concentrations of PUFAs, but not OA, induced oxidative stress-dependent cell death in TNBC cells. Inhibition of triacylglycerol (TAG) synthesis suppressed LD biogenesis and potentiated PUFA-induced cell damage. On the contrary, stimulation of LD biogenesis by hGX sPLA₂ and suppression of LD breakdown by ATGL depletion reduced PUFA-induced oxidative stress and cell death. Finally, lipidomic analyses revealed that sequestration of PUFAs in LDs by sPLA₂-induced TAG remodelling and retention of PUFAs in LDs by inhibition of ATGL-mediated TAG lipolysis protect from PUFA lipotoxicity. LDs are thus antioxidant and pro-survival organelles that guard TNBC cells against nutrient and lipotoxic stress and emerge as attractive targets for novel therapeutic interventions.     

参附注射液联合TEC新辅助化疗治疗乳腺癌的临床疗效及安全性分析

目的:研究参附注射液联合TEC方案新辅助化疗治疗乳腺癌的临床疗效及安全性。方法:选取我院肿瘤科及乳腺外科2016年7月-2018年1月收治的120例乳腺癌患者,将其随机分为对照组和观察组。对照组50例给予TEC方案新辅助化疗;观察组70例给予TEC方案新辅助化疗联合参附注射液静脉滴注治疗。观察并比较两组患者治疗后的临床治疗效果,治疗前后白细胞、中性粒细胞、红细胞以及血小板计数、CD_4~+、CD_8~+和CD_4~+/CD_8~+的变化。结果:治疗后,对照组的总有效率为70%,观察组的总有效率为84.3%,观察组显著高于对照组(P0.05)。两组治疗后白细胞、中性粒细胞、红细胞、血小板板计数、CD_4~+、CD_8~+和CD_4~+/CD_8~+均较治疗前有不同程度减少,对照组以上指标均明显低于观察组(P0.05)。两组患者均发生口腔黏膜炎、呕吐、腹泻、便秘等不良反应,观察组不良反应发生率显著低于对照组(P0.05),且两组均未发生毒性反应致死事件。结论:TEC方案新辅助化疗联合参附注射液静脉滴注治疗乳腺癌患者能有效改善患者的细胞免疫功能,提高临床疗效,并且能有效抑制骨髓抑制和消化道反应,提高患者依从性。