植物细胞Ca2+荧光蛋白指示剂研究进展

Ca2+作为第二信使参与了植物生长和发育过程的调控,不同生物和非生物胁迫信号均可诱导胞内Ca2+变化.对Ca2+在信号转导作用中的认识主要来自于细胞内Ca2+浓度测定.水母发光蛋白和基于荧光蛋白的Ca2+荧光指示剂作为检测细胞Ca2+信号的手段是近年发展起来的新方法.本文综述了水母发光蛋白和基于荧光蛋白的Ca2+荧光指示剂的发展、测量原理、优点与不足及其在细胞Ca2+信号转导中的应用研究进展.     

钠钙交换体的生理和病理生理功能研究进展

钠钙交换体(sodium calcium exchanger,NCX)是一种广泛分布于膜性结构(细胞质膜、线粒体膜、内质网、分泌小泡膜等)上的阳离子转运蛋白,具有两种转运Ca2+和Na+的模式:介导Na+内流、Ca2+外排的前向模式(forward mode)和作用相反的反向模式(reverse mode)。通过这种双向模式,NCX可以对胞质内Ca2+浓度进行快速精确的调节,继而影响细胞内信号转导、细胞生长发育、可兴奋细胞的兴奋及兴奋耦联的相关功能等一系列生理活动,如心肌和骨骼肌细胞的收缩、神经递质的释放、神经胶质细胞的迁移分化、免疫细胞的活化以及细胞因子与激素的分泌等。此外,在病理情况下,NCX反向模式的异常激活,被认为是NCX参与心血管系统、中枢神经系统、内分泌系统等多个系统病理生理过程的关键。在此,本文对NCX分子及其参与的生理、病理生理过程的研究进展作一综述,以提供关于NCX较为全面的认识。     

质膜钙离子ATP酶

钙离子(Ca2+)是重要的第二信使,通过与效应蛋白的结合和解离,以及在不同细胞器之间的穿梭运动而精确调控细胞活动,参与多种重要生命过程。细胞内具有精确调节Ca2+时空分布的调控系统。在静息状态下,细胞内的游离Ca2+浓度约为100 nmol/L;而当细胞受到信号刺激后,胞内的Ca2+浓度可上升至1000 nmol/L甚至更高。细胞中存在多种跨膜运送Ca2+的膜蛋白,以精确调节Ca2+浓度的时空动态变化,其中,细胞质膜上的多种Ca2+通道(包括电压门控通道、受体门控通道、储存控制通道等),以及内质网/肌质网和线粒体等胞内"钙库"膜上的雷诺丁受体、三磷酸肌醇受体等膜蛋白复合物,均可提升胞内Ca2+浓度,而细胞质膜上的钠钙交换体、质膜Ca2+-ATP酶、"钙库"膜上的内质网Ca2+-ATP酶、线粒体Ca2+单向转运体等,可将Ca2+浓度降低至静息态水平。质膜钙ATP酶是向细胞外运送Ca2+的关键膜蛋白,本文将对其结构、功能及其酶活性的调控机制做一简要综述。     

Caveolin与脑功能关系的研究进展

Caveolin作为细胞质膜微囊——Caveolae的标志蛋白,参与Caveolae的形成、定位,并具有介导膜泡运输、维持细胞胆固醇稳态和调控信号转导等功能.近年来发现,Caveolin与脑功能的生理或病理变化有关,在神经发育、突触可塑性以及神经退行性疾病中起着重要的作用.结合最新的研究进展和前期实验结果,简单介绍Caveolin的结构和功能,并对其在脑功能中的调控作用作一阐述与展望.     

水稻 Ca2+/H+ 反向转运体 OsCAX3 的功能分析和亚细胞定位研究

Ca2+/H+ 反向转运体作为一类 Ca2+外向转运器,在植物的营养和信号转导中起着非常重要的作用 . 克隆了水稻 Ca2+/H+ 反向转运体基因 OsCAX3 ,序列分析表明 OsCAX3 具有 11 个跨膜区,其中在第 6 和第 7 个跨膜区之间有一个 17 个氨基酸组成的酸性基序 (acid motif) ,功能互补实验证明 OsCAX3 具有转运 Ca2+ 的功能,并且其 N 端 26 个氨基酸序列对转运 Ca2+ 具有一定的抑制作用 . RT-PCR 分析表明 OsCAX3 的表达受到外源 Ca2+ 的诱导 . 利用 PSORT prediction 进行亚细胞定位分析,和利用 OsCAX3-GFP 融合蛋白瞬时表达分析证明, OsCAX3 定位于细胞质膜 . 以上结果表明, OsCAX3 是一种定位于细胞质膜上的 Ca2+/H+ 反向转运体 .     

细胞纤毛在信号转导与器官发育中的作用与机制

纤毛(cilia)是细胞表面的突起状细胞器,几乎存在于所有细胞表面,且广泛分布于组织和器官的上皮.纤毛由外部的纤毛膜和内部的轴丝组成,结构在进化上十分保守.根据微管组成和排列方式的不同,纤毛可分为9+2型运动纤毛与9+0型基本纤毛或非运动纤毛.作为一种特殊的感受器,纤毛通过影响细胞信号通路参与胚胎形成、心脏等内脏器官发育及人体重要生理活动.本课题组在国际上首次把前列腺素信号通路与纤毛生长及心脏发育相联系.研究发现,ABCC4/LKT前列腺素转运蛋白从细胞内运输前列腺素E2(PGE2)至细胞外,并通过结合位于纤毛膜上的G蛋白偶联受体EP4影响细胞内c AMP浓度,调节纤毛内运输蛋白的正向速率,进而调控纤毛生长与心脏等器官的左右不对称性发育.纤毛生长或功能缺陷会引发先天性心脏病、多囊肾、视网膜变性等多种疾病.本文主要介绍纤毛参与调控细胞内信号转导与器官发育及相关纤毛疾病.     

植物液泡膜阳离子/H+反向转运蛋白结构和功能研究进展

阳离子转运蛋白在调节细胞质阳离子浓度过程中发挥关键作用。液泡是一个储存多种离子的重要细胞器,阳离子 (Ca2+)/H+反向转运蛋白CAXs定位在液泡膜上,主要参与Ca2+向液泡的转运,也参与其他阳离子的转运。近年来,植物中分离鉴定了多个CAX基因,植物CAXs主要有4个功能域：NRR通过自抑制机制调节Ca2+转运活性,CaD和C功能域分别赋予CAXs的Ca2+和Mn2+专一性转运活性,D功能域可调节细胞质pH。拟南芥AtCAXs参与植物的生长发育和胁迫适应过程,AtCAX3主要在盐胁迫下转运Ca2+,At     

植物中的核质转运相关蛋白

细胞内各个生命过程的有序进行需要生物大分子在细胞核与细胞质之间有选择、有控制地转运.而细胞核膜的存在为大分子的自由穿梭设置了屏障,因此生物大分子在细胞核与细胞质之间的转运要依赖于一些受体蛋白.输入蛋白β(importinβ)是首先从人类细胞中发现的生物大分子向细胞核输入的受体,其后相继鉴定出多个与输入蛋白β具有同源性的细胞核转运受体,命名为类输入蛋白β.这些转运受体介导的转运过程在生物有机体之间高度保守,在动物及酵母中调控核质穿梭以及各个信号过程的组分与分子机制研究较为清楚,但在植物中相对匮乏.本文在介绍细胞核转运受体共有结构特点和转运机制基础上,重点综述了植物细胞核转运受体的最新研究进展以及这些受体在植物信号转导中的重要调节作用.     

非生物逆境胁迫下植物钙信号转导的分子机制

Ca2+作为植物细胞中最重要的第二信使, 参与植物对许多逆境信号的转导。在非生物逆境条件下, 植物细胞质内的钙离子在时间、空间及浓度上会出现特异性变化, 即诱发产生钙信号。钙信号再通过其下游的钙结合蛋白进行感受和转导, 进而在细胞内引起一系列的生物化学反应以适应或抵制各种逆境胁迫。目前在植物细胞中发现Ca2+/CDPK、Ca2+/CaM和Ca2+/CBL 3类钙信号系统, 研究表明它们与非生物逆境胁迫信号转导密切相关。本文通过从植物在非生物逆境条件下钙信号的感受、转导到产生适应性和抗性等方面, 介绍钙信号转导分子机制的一些研究进展。     

重组水母发光蛋白及其在植物钙离子信号检测中的应用

重组水母发光蛋白作为检测植物细胞钙信号的手段是近十几年发展起来的新方法,该文介绍了重组水母发光蛋白作为Ca2+检测探针的发展过程、测钙原理、Ca2+浓度检测方法、Ca2+浓度换算方法、优点与不足、及在植物细胞钙离子信号检测中的研究进展。并利用国外实验室提供的方法在国内首次得出冷激条件下植物细胞内细胞质中([Ca2+]cyt)和液泡膜附近([Ca2+]md)钙离子浓度动力学变化曲线。     

Neurocalcin, a novel calcium binding protein with three EF-hand domains, expressed in retinal amacrine cells and ganglion cells.

Neurocalcin (molecular weight 23,000 and 24,000) is a newly identified Ca2+ binding protein with three EF-hand domains and has a strong amino acid sequence homology with visinin and recoverin (Terasawa, M., Nakano, A., Kobayashi, R., and Hidaka, H. J. Biol. Chem. In press). We produced antibody against neurocalcin. Immunoblotting showed the presence of neurocalcin in bovine retina as well as brain, suggesting that neurocalcin was a neuron specific Ca2+ binding protein. Immunohistochemistry revealed the expression of neurocalcin in retinal amacrine cells and ganglion cells but not in the photoreceptor layer. This distribution of neurocalcin was quite different from that of visinin and recoverin. Our results suggest that neurocalcin may play an important role in a Ca2+ signal pathway of the nervous system.     

Structural, biochemical, and functional characterization of the calcium sensor neurocalcin delta in the inner retinal neurons and its linkage with the rod outer segment membrane guanylate cyclase transduction system

This study documents the detailed biochemical, structural, and functional identity of a novel Ca(2+)-modulated membrane guanylate cyclase transduction system in the inner retinal neurons. The guanylate cyclase is the previously characterized ROS-GC1 from the photoreceptor outer segments (PROS), and its new modulator is neurocalcin delta. At the membrane, the myristoylated form of neurocalcin delta senses submicromolar increments in free Ca(2+), binds to its specific ROS-GC1 domain, and stimulates the cyclase. Neurocalcin delta is not present in PROS, indicating the absence of the pathway in the outer segments and the dissociation of its linkage with phototransduction. Thus, the pathway is linked specifically with the visual transduction machinery in the secondary neurons of the retina. With the inclusion of this pathway, the findings broaden the understanding of the existing mechanisms showing how ROS-GC1 is able to receive and transduce diverse Ca(2+) signals into the cell-specific generation of second-messenger cyclic GMP in the retinal neurons.     

Ca2+-myristoyl switch and membrane binding of chemically acylated neurocalcins.

Neurocalcin is a member of a novel family of neuronal calcium sensors that belongs to the superfamily of EF-hand Ca(2+)-binding proteins. Neurocalcin is myristoylated on its N-terminus in vivo and can associate with biological membranes in a calcium and myristoyl-dependent manner. This process known as "Ca(2+)-myristoyl switch" has been best described for the photoreceptor specific protein, recoverin, as well as for several other neuronal calcium sensors. Here, we used reversed micelles to chemically acylate nonmyristoylated neurocalcin at its N-terminus with fatty acids of different lengths (from C12 to C16). This approach allowed us to prepare neurocalcin derivatives in which a single fatty acid is selectively linked to the N-terminal glycine of the polypeptide chain through an amide bond. The membrane binding properties of the monoacylated neurocalcins were then examined by cosedimentation with phospholipid vesicles and direct binding to lipid monolayers by surface plasmon resonance spectroscopy (Biacore). Our results show that neurocalcins monoacylated with lauric, myristic, or palmitic acid were able to associate with membrane in a calcium-dependent manner. This indicates that the Ca(2+)-myristoyl switch can function with different lipid moieties and is not strictly restricted to myristate. The ability to modify at will the fatty acid linked to the N-terminal glycine should be useful to analyze the contribution of the fatty acid moiety to the biological function of this family of neuronal calcium sensors.     

Neurocalcin delta modulation of ROS-GC1, a new model of Ca(2+) signaling

ROS-GC1 membrane guanylate cyclase is a Ca(2+) bimodal signal transduction switch. It is turned "off" by a rise in free Ca(2+) from nanomolar to the semicromolar range in the photoreceptor outer segments and the olfactory bulb neurons; by a similar rise in the bipolar and ganglion retinal neurons it is turned "on". These opposite operational modes of the switch are specified by its Ca(2+) sensing devices, respectively termed GCAPs and CD-GCAPs. Neurocalcin delta is a CD-GCAP. In the present study, the neurocalcin delta-modulated site, V(837)-L(858), in ROS-GC1 has been mapped. The location and properties of this site are unique. It resides within the core domain of the catalytic module and does not require the alpha-helical dimerization domain structural element (amino acids 767-811) for activating the catalytic module. Contrary to the current beliefs, the catalytic module is intrinsically active; it is directly regulated by the neurocalcin delta-modulated Ca(2+) signal and is dimeric in nature. A fold recognition based model of the catalytic domain of ROS-GC1 was built, and neurocalcin delta docking simulations were carried out to define the three-dimensional features of the interacting domains of the two molecules. These findings define a new transduction model for the Ca(2+) signaling of ROS-GC1.     

A second calcium regulator of rod outer segment membrane guanylate cyclase, ROS-GC1: neurocalcin.

ROS-GC represents a membrane guanylate cyclase subfamily whose distinctive feature is that it transduces diverse intracellularly generated Ca(2+) signals into the production of the second messenger cyclic GMP. An intriguing feature of the first subfamily member, ROS-GC1, is that it is both stimulated and inhibited by these signals. The inhibitory signals are processed by the cyclase activating proteins, GCAPs. The only known stimulatory signal is by the Ca(2+)-dependent guanylate cyclase activating protein, CD-GCAP. There are two GCAPs, 1 and 2, which link the cyclase with phototransduction, and one CD-GCAP, which is predicted to link ROS-GC1 with its retinal synaptic activity. Individual switches for these GCAPs and CD-GCAP have been respectively defined as CRM1, CRM3, and CRM2. This report defines the identity of a new ROS-GC1 regulator: neurocalcin. A surprising feature of the regulator is that it structurally is a GCAP but functionally behaves as a CD-GCAP. Recombinant neurocalcin stimulates ROS-GC1 in a dose-dependent fashion; the stimulation is Ca(2+)-dependent with an EC(50) of 20 microM; and the modulated domain resides at the C-terminal segment, between amino acids 731 and 1054. Previously, the residence of CRM2 has also been defined in this segment of the cyclase. However, the present study shows that the neurocalcin-regulated domain is distinct from CRM2. This is now designated as CRM4. Thus, the signal transduction mechanisms of neurocalcin and CD-GCAP are different, occurring through different modules of ROS-GC1. Neurocalcin signaling of ROS-GC1 is highly specific. It does not influence the activity of its second subfamily member, ROS-GC2, and of the other retinal guanylate cyclase, atrial natriuretic factor-receptor guanylate cyclase. In conclusion, the findings extend the concept of ROS-GC1's sensing diverse Ca(2+) signals, reveal the identity of its unexpected new Ca(2+) regulator, and show that the regulator acts through its specific cyclase domain. This represents an additional transduction mechanism of Ca(2+) signaling via ROS-GC1.     

Neurocalcin-like immunoreactivity in the rat esophageal nervous system

Neurocalcin is a newly identified neuronal calcium-binding protein. We tried here to investigate the immunohistochemical distribution of neurocalcin in the rat esophagus. Nerve cell bodies having neurocalcin immunoreactivity were found throughout the myenteric plexus. In the myenteric ganglia, two types of nerve terminals showed neurocalcin immunoreactivity. One was varicose terminals containing numerous small clear vesicles and forming a synapse with nerve cells. The other terminals were characterized by laminar or pleomorphic structure and many mitochondria. These laminar terminals were supposed to be sensory receptors of the esophageal wall. In the motor endplates of the striated muscles, nerve terminals containing many small clear vesicles and mitochondria also had neurocalcin immunoreactivity. After left vagus nerve cutting under the nodose ganglia, the number of immunopositive thick nerve fibers, laminar endings and nerve terminals on the striated muscles decreased markedly. Retrograde tracing experiments using Fast Blue showed extrinsic innervation of esophagus from ambiguus nucleus, dorsal motor nucleus of vagus, superior cervical ganglia, celiac ganglia, nodose ganglia and dorsal root ganglia. In the celiac ganglia, nodose ganglia and dorsal root ganglia, retrogradely labeled nerve cells were neurocalcin-immunoreactive. Neurons in the celiac ganglia may project varicose terminals, while nodose and dorsal root neurons project laminar terminals. Although cell bodies of motoneurons in the ambiguus nucleus lacked neurocalcin immunoreactivity, these neurons may contain neurocalcin only in the nerve terminals in the motor endplates. Neurocalcin immunoreactivity is distributed in many extrinsic and intrinsic neurons in the esophagus and this protein may play important roles in regulating calcium signaling in the neurons.     

塔克拉玛干沙漠不同区域柽柳沙包土壤盐分分布特征及其影响因素

柽柳(Tamarix chinensis)沙包是塔克拉玛干沙漠特殊的生物地貌景观, 对维持区域生态环境的稳定具有极其重要的作用。该研究采用野外调查与室内分析相结合的方法, 选取且末、阿拉尔、策勒、塔中4个典型区域的柽柳沙包为研究对象, 对柽柳沙包0-500 cm土壤垂直剖面进行采样, 测定土壤pH值、枯落物含量、电导率及HCO₃ ^-、Cl ^-、SO₄ ^2-、Ca ²⁺、Mg ²⁺、K ⁺、Na ⁺含量, 分析柽柳沙包中土壤盐分的空间变化规律及其影响因素。结果表明: 1)从且末、阿拉尔、策勒到塔中, 土壤pH值总体呈升高趋势, 土壤电导率及Na ⁺、Ca ²⁺、Mg ²⁺、SO₄ ^2-含量总体呈降低趋势, K ⁺、Cl ^-、HCO₃ ^-含量没有明显的变化规律。2)盐分在4个样区的垂直分布主要表现为: 且末和策勒样区柽柳沙包的土壤盐分呈表层聚集现象; 阿拉尔和塔中样区柽柳沙包的土壤盐分呈深层聚集现象。随着土层深度的增加, 土壤pH值总体呈升高的趋势, 土壤枯落物含量总体呈降低趋势; 土壤电导率在且末和策勒样区总体呈降低趋势, 阿拉尔样区呈先降低后升高再降低的变化趋势, 而塔中样区呈先升高后降低再升高的变化趋势。3)根据相关性分析和主成分分析, 且末样区土壤枯落物含量、SO₄ ^2-、Na ⁺、K ⁺为影响土壤盐分含量的主要因子, 且土壤盐分以硫酸盐为主; 阿拉尔样区影响土壤盐分组成的主要因子为Cl ^-、Na ⁺; 策勒样区为Cl ^-、K ⁺、Na ⁺; 塔中样区为Cl ^-、Na ⁺、Ca ²⁺、SO₄ ^2-, 且土壤盐分均以氯化物为主。综合分析表明, 不同区域柽柳沙包中土壤盐分存在空间变异性, 柽柳沙包土壤盐分的变化与干旱沙漠地区强烈的蒸发作用、地表风蚀强度、地下水埋深、土壤中枯落物及柽柳的生物积盐效应等因素密切相关, 是影响不同区域土壤盐分分布的关键因子。     

Distribution pattern and influencing factors of soil salinity at Tamarix cones in the Taklimakan Desert

柽柳(Tamarix chinensis)沙包是塔克拉玛干沙漠特殊的生物地貌景观, 对维持区域生态环境的稳定具有极其重要的作用。该研究采用野外调查与室内分析相结合的方法, 选取且末、阿拉尔、策勒、塔中4个典型区域的柽柳沙包为研究对象, 对柽柳沙包0-500 cm土壤垂直剖面进行采样, 测定土壤pH值、枯落物含量、电导率及HCO₃ ^-、Cl ^-、SO₄ ^2-、Ca ²⁺、Mg ²⁺、K ⁺、Na ⁺含量, 分析柽柳沙包中土壤盐分的空间变化规律及其影响因素。结果表明: 1)从且末、阿拉尔、策勒到塔中, 土壤pH值总体呈升高趋势, 土壤电导率及Na ⁺、Ca ²⁺、Mg ²⁺、SO₄ ^2-含量总体呈降低趋势, K ⁺、Cl ^-、HCO₃ ^-含量没有明显的变化规律。2)盐分在4个样区的垂直分布主要表现为: 且末和策勒样区柽柳沙包的土壤盐分呈表层聚集现象; 阿拉尔和塔中样区柽柳沙包的土壤盐分呈深层聚集现象。随着土层深度的增加, 土壤pH值总体呈升高的趋势, 土壤枯落物含量总体呈降低趋势; 土壤电导率在且末和策勒样区总体呈降低趋势, 阿拉尔样区呈先降低后升高再降低的变化趋势, 而塔中样区呈先升高后降低再升高的变化趋势。3)根据相关性分析和主成分分析, 且末样区土壤枯落物含量、SO₄ ^2-、Na ⁺、K ⁺为影响土壤盐分含量的主要因子, 且土壤盐分以硫酸盐为主; 阿拉尔样区影响土壤盐分组成的主要因子为Cl ^-、Na ⁺; 策勒样区为Cl ^-、K ⁺、Na ⁺; 塔中样区为Cl ^-、Na ⁺、Ca ²⁺、SO₄ ^2-, 且土壤盐分均以氯化物为主。综合分析表明, 不同区域柽柳沙包中土壤盐分存在空间变异性, 柽柳沙包土壤盐分的变化与干旱沙漠地区强烈的蒸发作用、地表风蚀强度、地下水埋深、土壤中枯落物及柽柳的生物积盐效应等因素密切相关, 是影响不同区域土壤盐分分布的关键因子。     

Mapping functional domains of the guanylate cyclase regulator protein, GCAP-2

Guanylate cyclase regulator protein (GCAP)-2 is a Ca2+-binding protein that regulates photoreceptor outer segment membrane guanylate cyclase (RetGC) in a Ca2+-sensitive manner. GCAP-2 activates RetGC at free Ca2+ concentrations below 100 nM, characteristic of light-adapted photoreceptors, and inhibits RetGC when free Ca2+ concentrations are above the 500 nM level, characteristic of dark-adapted photoreceptors. We have mapped functional domains in GCAP-2 by using deletion mutants and chimeric proteins in which parts of GCAP-2 were substituted with corresponding fragments of other closely related recoverin-like proteins that do not regulate RetGC. We find that in addition to the EF-hand Ca2+-binding centers there are three regions that contain GCAP-2-specific sequences essential for regulation of RetGC. 1) The region between Phe78 and Asp113 determines whether GCAP-2 activates outer segment RetGC in low or high Ca2+ concentrations. Substitution of this domain with the corresponding region from neurocalcin causes a paradoxical behavior of the chimeric proteins. They activate RetGC only at high and not at low Ca2+ concentrations. 2) The amino acid sequence of GCAP-2 between Lys29 and Phe48 that includes the EF-hand-related motif EF-1 is essential both for activation of RetGC at low Ca2+ and inhibition at high Ca2+ concentrations. Most of the remaining N-terminal region can be substituted with recoverin or neurocalcin sequences without loss of GCAP-2 function. 3) Region Val171-Asn189, adjacent to the C-terminal EF-4 contributes to activation of RetGC, but it is not essential for the ability of Ca2+-loaded GCAP-2 to inhibit RetGC. Other regions of the molecule can be substituted with the corresponding fragments from neurocalcin or recoverin, or even partially deleted without preventing GCAP-2 from regulating RetGC. Substitution of these three domains in GCAP-2 with corresponding neurocalcin sequences also affects activation of individual recombinant RetGC-1 and RetGC-2 expressed in HEK293 cells.     

The Ca(2+)-binding domains in non-muscle type alpha-actinin: biochemical and genetic analysis

Dictyostelium alpha-actinin is a Ca(2+)-regulated F-actin cross-linking protein. To test the inhibitory function of the two EF hands, point mutations were introduced into either one or both Ca(2+)-binding sites. After mutations, the two EF hands were distinguishable with respect to their regulatory activities. Inactivation of EF hand I abolished completely the F-actin cross-linking activity of Dictyostelium discoideum alpha-actinin but Ca2+ binding by EF hand II was still observed in a 45Ca2+ overlay assay. In contrast, after mutation of EF hand II the molecule was still active and inhibited by Ca2+; however, approximately 500-fold more Ca2+ was necessary for inhibition and 45Ca2+ binding could not be detected in the overlay assay. These data indicate that EF hand I has a low affinity for Ca2+ and EF hand II a high affinity, implying a regulatory function of EF hand I in the inhibition of F-actin cross-linking activity. Biochemical data is presented which allows us to distinguish two functions of the EF hand domains in D. discoideum alpha-actinin: (a) at the level of the EF- hands, the Ca(2+)-binding affinity of EF hand I was increased by EF hand II in a cooperative manner, and (b) at the level of the two subunits, the EF hands acted as an on/off switch for actin-binding in the neighboring subunit. To corroborate in vitro observations in an in vivo system we tried to rescue the abnormal phenotype of a mutant (Witke, W., M. Schleicher, A. A. Noegel. 1992. Cell. 68:53-62) by introducing the mutated alpha-actinin cDNAs. In agreement with the biochemical data, only the molecule modified in EF hand II could rescue the abnormal phenotype. Considering the fact that the active construct is "always on" because it requires nonphysiological, high Ca2+ concentrations for inactivation, it is interesting to note that an unregulated alpha-actinin was able to rescue the mutant phenotype.