植物细胞的生物力学研究现状与进展

植物细胞的生物力学, 是探索生物生长奥妙的基础。本文阐述了国内外关于植物细胞生物力学的研究现状与进展; 讨论了植物细胞力学分析的几个基本理论; 重点讨论了植物细胞的力学模型及组织模型, 其中包括植物细胞的流变特性、黏附特性、应激效应(植物对外界应力刺激的响应)以及植物器官之茎杆的研究; 提出了植物细胞生物力学应在以下几个方面做进一步深入研究: 细胞间接触和细胞间相互渗透, 应力刺激对植物根、茎和叶等方面的影响以及外力在细胞中传递与分布规律。     

局部力学刺激对黄瓜系统抗病性的诱导

病原真菌在侵入植物细胞过程中,除了分泌化学物质外还通过物理挤压细胞产生力学作用.用压应力作为力学信号,研究了局部力学刺激对黄瓜系统抗病性的诱导.结果表明,力学刺激可以诱导黄瓜系统抗病性的产生.当细胞壁与质膜间的黏附被Arg-Gly-Asp(RGD)阻断后,力学刺激对黄瓜系统抗病性的诱导几乎完全被减除.通过薄层色谱和液相色谱分析,发现力学刺激可以使植保素含量明显增加.这表明黄瓜植保素的积累可能是力学刺激诱导其产生抗性的原因之一.而细胞壁与质膜间的黏附被RGD阻断后,力学刺激只能诱导植保素的部分积累.即力学刺激对植保素积累的诱导依赖于细胞膜与细胞壁间的黏附.     

机械力及力学信号转导影响干细胞命运的研究进展

干细胞作为一种未分化的祖细胞,目前已被广泛应用于开展组织损伤修复、再生以及干细胞特异谱系分化的研究.大量研究表明,干细胞所处的微环境对调控干细胞的生长和分化具有重要作用,多种溶液介质、细胞外基质和信号通路等参与了干细胞命运的调控.尽管已有大量研究证明,溶液介质(如激素和生长因子)在干细胞的生长和分化中发挥重要作用,但近年来越来越多的研究表明,机械力及力学信号转导同样在干细胞自我更新、分化、衰老和凋亡等细胞生理过程中起到重要的作用.本文将对机械应力响应的细胞基础、生物力学及力学信号调控干细胞自我更新和分化,以及生物力学调控干细胞命运可能的作用机制几个方面加以综述.     

静态单轴拉伸应变刺激对细胞有丝分裂方向的影响

力学刺激对细胞发育具有重要意义,它如何对细胞分化及组织形态的发生产生影响是一个尚未完全阐明的问题.细胞的有丝分裂过程与细胞增殖、分化以及胚胎发育、组织器官形态形成和损伤组织的修复再生等特性密切相关,例如,细胞的有丝分裂方向就是影响细胞极性分化,乃至组织形态发生的因素之一.那么,力学刺激是否通过改变细胞有丝分裂方向从而影响细胞的分裂分化呢?以小鼠成骨细胞系MC3T3为模型,探讨了静态单轴拉伸应变刺激对细胞形态、应力纤维排布方向和有丝分裂方向的影响.结果显示,在4%及8%静态单轴拉伸应变条件下,48 h之内细胞形态发生明显变化,细胞呈梭状,长轴沿应变方向排列,细胞骨架微丝呈束状平行排列,方向与应变方向相关.统计学分析表明,4%应变刺激48 h后、8%应变6 h后、8%应变12 b后、8%应变24 h后,及8%应变48 h后,分别有49%,43%,54%,54%,和62%的细胞应力纤维排列方向与单轴拉伸应变方向的夹角在300以内,以及50%,48%,56%,53%和62%的细胞有丝分裂方向与单轴应变方向夹角在300以内.统计学分析表明,细胞形态、应力纤维排布及有丝分裂方向与拉伸方向相关,且应力纤维排列方向和有丝分裂方向之间呈现高的相关性,这种相关性在拉伸刺激48 h后表现很明显,由此推测,存在力学刺激影响细胞形态及细胞应力纤维排布方向,控制有丝分裂方向的机制.     

针刀干预对膝骨关节炎兔髌韧带拉伸、蠕变及应力松弛等生物力学特性的影响

针刀干预对髌韧带生物力学特性可以产生一定的影响,故针刀对膝骨关节炎具有一定的治疗作用.本研究采用左后肢伸直位固定制动法造成膝骨关节炎模型兔(Leporidae),并应用针刀进行治疗,治疗结束后,通过对膝关节髌韧带进行应力松弛、蠕变及拉伸等力学测试,研究针刀干预对髌韧带生物力学的影响.结果显示,针刀干预可以明显改善髌韧带的生物力学特性,激发髌韧带的拉伸、蠕变、应力松弛特性的恢复,维护膝关节的平衡与稳定.     

关于农业生物力学问题

生物力学作为一门独立学科以来发展十分迅速，在自然界（动物、植物、微生物、细胞）也开展了这方面研究。未来力学的发展，主要跨学科上，但跨学科不太容易，可它又是现实的发展趋势[1]。随着当今世界人口增长，带来了粮食短缺，能源资源不足和环境污染等，研究生物工程和生物力学显得非常重要，而且正在逐步转移到农业方面[2]。农业生物力学是现代生物科学的一个分支，它属于农业生物工程国外用力学的方法对农业生物材料的研究，已有30多年的历史，特别几个发达国家近几年的研究成果。对农业现代化多方面有较大的作用与价值。     

植物对环境应力刺激的生物学效应

植物生长在自然环境中由于其“不动性”而不可避免地要受到各种环境应力的刺激,应力－生长关系一直是生物学家和物理学家所关心的课题,是生物力学的灵魂。很多研究已经表明外界应力作用对植物的生长发育有着重要的影响。本综述了国内外关于应力对植物组织所引起的生物学效应,首先论述了环境应力所引起的宏观生物学效应,随后重点论述了环境应力所引起的生物学效应在细胞和分子水平上的研究,其中包括单个细胞的加载、电磁场、微     

微流控芯片在心肌细胞功能研究中的应用

心肌细胞是心脏结构和功能的基本单位,约占心脏细胞总数的三分之一,是心脏发育、生理病理研究的重点对象,然而传统的在体和体外研究技术存在诸多困难,无法实现细胞微环境的有效控制和生理功能的实时动态监测,制约着心肌细胞功能研究的快速发展。近年来迅速发展的微加工技术,尤其是微流控芯片技术为心肌细胞功能研究提供了便利。微流控芯片技术具有微米尺度的细胞及其微环境的时空控制功能,有效提高了体外细胞研究的组织相关性,是心肌细胞生理功能和力学特性研究的重要工具,如实时监测单个心肌细胞的代谢活性、表征细胞的电生理特性和力学特性、研究细胞微环境和力学微环境对心肌细胞形态和功能的影响。本文从前述几个方面对微流控芯片在心肌细胞生理功能研究中的应用进行综述和对其应用前景进行了展望。     

骨再生的力学生物学问题

生物力学主要探讨力学刺激与细胞的形态、结构和功能之间的关系。骨组织改变其形态和结构以适应力学刺激,表现为骨的适应性重建。骨的生长是骨塑形和骨重建两个过程协同作用的结果,以调整骨的形状、大小和组成,适应其所处的力学环境。骨组织工程的目的就是修复骨组织的正常生物力学功能。近年来,骨组织工程的研究主要集中于模拟骨生长的在体生理条件,从而刺激细胞形成有功能的骨组织。生物反应器能够模拟体内生理状态,为种子细胞在生物支架材料上生长提供一个适宜的力学环境。     

炎症反应中巨噬细胞的力学生物学

炎症反应存在于机体诸多生理和病理过程中,是最基本的保护性反应之一。在动脉粥样硬化等慢性炎症性血管疾病发病过程中,巨噬细胞作为重要的免疫细胞参与并调控炎症的进程。在炎症刺激下,巨噬细胞的生物力学特性(如质膜流动性、细胞刚度、细胞与基质的粘附、细胞骨架的组成与结构等)会发生相应的变化,细胞行为和功能随之改变。本文旨在回顾炎症模型下巨噬细胞力学特性与其功能之间关系及其机理的研究进展,尤其关注了细胞刚度如何介导炎症刺激对巨噬细胞行为和功能的影响。     

Universal foliage-stem scaling across environments and species in dicot trees: plasticity, biomechanics and Corner's Rules

Trees range from small-leaved, intricately branched species with slender stems to large-leaved, coarsely branched ones with thick stems. We suggest a mechanism for this pattern, known as Corner's Rules, based on universal scaling. We show similar crown area–stem diameter scaling between trunks and branches, environments, and species spanning a wide range of leaf size and stem biomechanics. If crown and stem maintain metabolically driven proportionality, but similar amounts of photosynthates are produced per unit crown area, then the greater leaf spacing in large-leaved species requires lower density stem tissue and, meeting mechanical needs, thicker stems. Congruent with this scenario, we show a negative relationship between leaf size and stem Young's modulus. Corner's Rules emerge from these mutual adjustments, which suggest that adaptive studies cannot consider any of these features independently. The constancy of scaling despite environmental challenges identifies this trait constellation as a crucial axis of plant diversification.     

Cell wall proteome analysis of Arabidopsis thaliana mature stems

Plant stems carry flowers necessary for species propagation and need to be adapted to mechanical disturbance and environmental factors. The stem cell walls are different from other organs and can modify their rigidity or viscoelastic properties for the integrity and the robustness required to withstand mechanical impacts and environmental stresses. Plant cell wall is composed of complex polysaccharide networks also containing cell wall proteins (CWPs) crucial to perceive and limit the environmental effects. The CWPs are fundamental players in cell wall remodeling processes, and today, only 86 have been identified from the mature stems of the model plant Arabidopsis thaliana. With a destructive method, this study has enlarged its coverage to 302 CWPs. This new proteome is mainly composed of 27.5% proteins acting on polysaccharides, 16% proteases, 11.6% oxido‐reductases, 11% possibly related to lipid metabolism and 11% of proteins with interacting domains with proteins or polysaccharides. Compared to stem cell wall proteomes already available (Brachypodium distachyon, Sacharum officinarum, Linum usitatissimum, Medicago sativa), that of A. thaliana stems has a higher proportion of proteins acting on polysaccharides and of proteases, but a lower proportion of oxido‐reductases.     

Plant material features responsible for bamboo's excellent mechanical performance: a comparison of tensile properties of bamboo and spruce at the tissue,fibre and cell wall levels

MethodsThe mechanical properties of single fibres and tissue slices of stems of mature moso bamboo (Phyllostachys pubescens) and spruce (Picea abies) latewood were investigated in microtensile tests. Cell parameters, cellulose microfibril angles and chemical composition were determined using light and electron microscopy, wide-angle X-ray scattering and confocal Raman microscopy.ConclusionsThe superior tensile properties of bamboo fibres and fibre bundles are mainly a result of amplified cell wall formation, leading to a densely packed tissue, rather than being based on specific cell wall properties. The material optimization towards extremely compact fibres with a multi-lamellar cell wall in bamboo might be a result of a plant growth strategy that compensates for the lack of secondary thickening growth at the tissue level, which is not only favourable for the biomechanics of the plant but is also increasingly utilized in terms of engineering products made from bamboo culms.     

细胞对机械刺激感知的生物力学机制

细胞作为机体的基本单位,始终处于一个受力环境中。微环境中的细胞不仅受化学信号的影响,还受基质刚度、外界力载荷及胞外基质(ECM)结构的调控,这些都能影响细胞分化、迁移、形态发生、增殖等方面的生物学反应。目前,部分学者致力于细胞生物力学的应用和机制方面的探索,但对于细胞力学感知机理的认知仍无法形成一个完整的定论。本文将就整合素、G蛋白耦联受体、张力活化通道(SAC)、细胞核等介导的细胞生物力学感知通路作一综述。     

Effects of Vibration on Mechanical Properties and Biomass Allocation Pattern ofCapsella bursa-pastoris(Cruciferae)

The herbaceous dicot speciesCapsella bursa-pastoris(Cruciferae)was used to determine the influence of chronic mechanical perturbationon the biomass allocation pattern (i.e. dry weight distributionamong roots, stems and reproductive structures) and the mechanicalproperties of roots and stems (i.e. tensile breaking stressand Young's modulus). It was hypothesized that mechanicallystimulated plants would allocate more of their total biomassto root systems and less to shoots compared to control plantsand that the breaking stress (a measure of strength) and Young'smodulus (a measure of material stiffness) would increase forroots and decrease for stems because these responses would adaptivelyreduce the bending moment at the base of shoots and increasethe anchorage strength of root systems. It was also hypothesizedthat mechanical perturbation would maladaptively reduce therelative fitness of individuals by reducing biomass allocationto their reproductive organs and the ability to broadcast seedsby means of elastic stem flexure. These hypotheses were testedby vibrating cultivated plants for 60 s every day during thecourse of growth to maturity and comparing their dry weightdistributions and the mechanical properties of their body parts(measured in tension) to those of undisturbed control plants.Based on a total of 51 experimentally manipulated and 44 controlplants for which mechanical properties were successfully tested,chronic organ flexure resulted in more massive root systemsand less massive vegetative shoots, increased the magnitudesof root breaking stress and Young's modulus and had the reverseeffect on stems, reduced the dry weight of reproductive structuresat maturity, delayed the formation of the first mature flowerand fruit, and accelerated the on-set of plant senescence comparedto control plants. These responses to chronic organ flexureare interpreted to be vegetatively adaptive, since they reducethe probability of stem and root failure as a consequence ofwind-pressure or foraging, and to be reproductively maladaptive,since they reduce reproductive effort and the ability to mechanicallydischarge seeds.Copyright 1998 Annals of Botany Company Adaptation, biomass allocation, biomechanics, elastic properties, roots, stems, thigmomorphogenesis.     

臭椿茎中分泌道的发育及其组织化学研究

利用植物解剖学方法研究臭椿茎和叶柄中分泌道的结构、分布和发育过程.结果表明:臭椿茎和叶柄中的分泌道分布于髓的周缘,次生木质部中无分泌道.分泌道是由一层分泌细胞围绕分泌腔而构成,分泌细胞外有1～2层鞘细胞.分泌道以裂生方式形成,其发育过程可分为3个阶段:原始细胞阶段、形成阶段和成熟阶段.在原始细胞阶段,一群原始细胞具浓厚细胞质,细胞核清晰可见;形成阶段,原始细胞的中央细胞间细胞壁中层降解,细胞壁分离,形成腔隙,随着分泌细胞数量的增加,分泌腔体积扩大;成熟阶段的分泌道具有12～16个分泌细胞,1～2层鞘细胞,分泌腔直径为30～50μm.组织化学研究表明,分泌细胞及分泌道内含物中含大量的萜类、多糖和脂类物质.机械创伤能够诱导次生木质部中产生创伤分泌道.臭椿茎中的分泌道和创伤性分泌道在抵御生物和非生物胁迫中起重要作用.     

Mechanical modeling and structural analysis of the primary plant cell wall

Plant cell growth is a fundamental process during plant development whose spatial and temporal dynamics are controlled by the cell wall. Modeling mechanical aspects of cell growth therefore requires the integration of structural cell wall details with quantitative biophysical parameters. Recent advances in microscopic techniques and mechanical modeling have made significant contributions to the field of cell wall biomechanics. Live observation of cellulose microfibrils at high z-resolution now enables determining the dynamic orientation of these polymers in the different wall layers of growing cells. Mechanical modeling approaches have been developed to operate at the scale of individual molecules and will thus be able to exploit the availability of the high-resolution structural data. The combination of these techniques has the potential to make a significant and quantitative contribution to our understanding of plant growth and development.     

Abiotic stresses increase plant regeneration ability

In disturbed habitats, vegetative regeneration is partly ruled by plant reserves and intrinsic growth rates. Under nutrient-limiting conditions, perennial plants tend to exhibit an increased allocation to storage organs. Under mechanically stressful conditions, plants also tend to increase allocation to below-ground biomass and storage organs. We tested whether those stresses acting differently on plants (nutrient level versus mechanical forces) led to similar effect on storage organs and regeneration ability. We measured, for an aquatic plant species, (1) the size and allocation to storage organs (stems) and (2) the regeneration ability of the storage organs. Plant stems were collected in 4 habitats ranked along a nutrient stress gradient, and having encountered null versus significant mechanical stress (flowing water). All stems were placed in similar neutral conditions and left for a period of 6 weeks before measuring their survival and growth. Dry mass allocation to the storage organ (stem) was higher in stressful habitats. Moreover, stress encountered by plants before the experiment significantly affected regeneration: stems of previously stressed plants (i.e. plants that had grown in nutrient-poor or mechanically stressful habitats) survived better than unstressed ones. Stems of plants having encountered mechanical stress before the experiment had increased growth in nutrient-rich habitats but reduced growth in the poorest habitats. These results demonstrate that regeneration could rely on the level of stress previously encountered by plants. Stress could lead to greater regeneration ability following mechanical failure. The possible mechanisms involved in these results are discussed.