花粉中的收缩蛋白与细胞质流动

从植物的花粉中提取得到了肌球蛋白和肌动蛋白,用4－30％SDS梯度聚丙烯酰胺凝胶电泳测定丝瓜花粉肌球蛋白重链的分子量为165kD.花粉肌球蛋白的ATP酶活性与兔肌肌球蛋白ATP酶活性具有一致的特征,即在0．5mol/l KCl的条件下,其K＋－EDTA ATP酶活性最高,Ca^2+-ATP酶活性次之,Mg^2+-ATP酶活性最低,用SDS制备型聚丙烯酰胺凝胶电泳的方法,制备得到了电泳纯的玉米花粉肌动蛋白,用SDS聚丙烯酰胺凝胶电泳测定了肌动蛋白的分子量,结果表明,花粉肌动蛋白与兔肌肌动蛋白具有相同的分子量（43kD)。药物处理表明,细胞松弛素B,氯丙嗪和氯四环素对花粉管细胞质流动均有抑制作用。而秋水仙碱对细胞质流动没有抑制作用,对肌球蛋白和肌动蛋白在花粉管细胞质流动中所起的作用进行了讨论。     

花粉中的收缩蛋白与细胞质流动

从植物的花粉中提取得到了肌球蛋白和肌动蛋白,用4－30％SDS梯度聚丙烯酰胺凝胶电泳测定丝瓜花粉肌球蛋白重链的分子量为165kD.花粉肌球蛋白的ATP酶活性与兔肌肌球蛋白ATP酶活性具有一致的特征,即在0．5mol/l KCl的条件下,其K＋－EDTA ATP酶活性最高,Ca^2 -ATP酶活性次之,Mg^2 -ATP酶活性最低,用SDS制备型聚丙烯酰胺凝胶电泳的方法,制备得到了电泳纯的玉米花粉肌动蛋白,用SDS聚丙烯酰胺凝胶电泳测定了肌动蛋白的分子量,结果表明,花粉肌动蛋白与兔肌肌动蛋白具有相同的分子量（43kD)。药物处理表明,细胞松弛素B,氯丙嗪和氯四环素对花粉管细胞质流动均有抑制作用。而秋水仙碱对细胞质流动没有抑制作用,对肌球蛋白和肌动蛋白在花粉管细胞质流动中所起的作用进行了讨论。     

丝瓜肌球蛋白的电子显微学研究

从丝瓜 (Luffacylindrica (L .)Roem .)卷须中纯化得到分子量为 174kD的肌球蛋白 ,并对其进行了酶学与电子显微学的研究。这种肌球蛋白具有肌动蛋白激活的MgATPase活性 ,能够被抗动物肌肉的肌球蛋白的单克隆抗体识别。电子显微学研究表明 :它有两个头部 (大小和形状与动物肌肉的肌球蛋白相似 )和一条相对较短的尾部。还对丝瓜卷须的肌动蛋白进行了观测 ,偶尔发现一些尾部有球状结构的肌球蛋白。该肌球蛋白的免疫特性和超微结构证明了它由 2条重链组成 ,并与传统的肌球蛋白相似。然而 ,这种 174kD的肌球蛋白是否参与了丝瓜的接触卷曲有待于进一步研究。     

芹菜韧皮部中的肌动蛋白

芹菜韧皮部初步纯化的肌动蛋白,用SDS聚丙烯酸胺凝胶电泳进行分离,得到与兔骨胳肌的肌动蛋白相似的迁移率,其分子量为43 000道尔顿,与免肌肌动蛋白的分子量相一致。韧皮部的G-肌动蛋白聚合成F-肌动蛋白,在电子显微镜下观察到直径5～7nm肌动蛋白的微丝。用兔肌的重酶解肌球蛋白处理并负染后,在电镜下观察到箭头状装饰。韧皮部的F-肌动蛋白能激活兔肌重酶解肌球蛋白ATP酶的活性,酶活性可被激活8倍以上。证明芹菜韧皮部中确实存在肌动蛋白。     

小麦线粒体表面存在肌球蛋白

证明了小麦 (TriticumaestivumL .)线粒体上存在肌球蛋白。通过免疫印迹鉴定发现小麦线粒体蛋白重链与抗体进行交叉反应 ,其分子量略高于动物骨骼肌肌球蛋白的重链 ,经计算 ,该蛋白的分子量为 2 10kD。通过电镜观察到溶液中的F_肌动蛋白可以和NEM (N_ethylmaleimide)处理的线粒体结合 ,并发现F_肌动蛋白可以激活线粒体悬浮液的ATP酶活性 ,证明线粒体外膜的外表面存在肌球蛋白     

丝瓜肌球蛋白的电子显微学研究

从丝瓜(Luffa cylindrica (L.) Roem.)卷须中纯化得到分子量为174kD的肌球蛋白,并对其进行了酶学与电子显微学的研究.这种肌球蛋白具有肌动蛋白激活的MgATPase活性,能够被抗动物肌肉的肌球蛋白的单克隆抗体识别.电子显微学研究表明:它有两个头部(大小和形状与动物肌肉的肌球蛋白相似)和一条相对较短的尾部.还对丝瓜卷须的肌动蛋白进行了观测,偶尔发现一些尾部有球状结构的肌球蛋白.该肌球蛋白的免疫特性和超微结构证明了它由2条重链组成,并与传统的肌球蛋白相似.然而,这种174 kD的肌球蛋白是否参与了丝瓜的接触卷曲有待于进一步研究.     

人心肌肌球蛋白轻链1与重链和肌动蛋白的结合

在测得中国人心肌肌球蛋白轻链 1cDNA的核苷酸序列 ,并获得一株单克隆抗体 (HCMLC1 8)的基础上 ,用PCR方法 ,以中国人心肌肌球蛋白轻链 1的cDNA为模板 ,分别获得中国人心肌肌球蛋白轻链 1的各为 98个氨基酸的N端和C端片段cDNA的克隆并进行了表达。同时进行了其表达产物和大鼠心肌肌球蛋白重链和人心肌肌动蛋白以及单克隆抗体结合的研究 ,发现三者均和轻链 1的N端相结合 ,结合位点各不相同。这些结合位点可能均位于轻链 1的分子表面 ,而且如果轻链 1在实验状态下先与肌动蛋白结合 ,则有可能影响轻链与重链间的彼此结合。肌动蛋白在体外能以不同位点结合肌球蛋白重链和轻链 ,可能在肌肉收缩过程中具有重要的生理意义     

人心肌肌球蛋白链1与重链和肌动蛋白的结合

在测得中国人心肌肌球蛋白轻链1cDNA的核苷酸序列,并获得一株单克隆抗体（HCMLC1－8）的基础上,用PCR方法,以中国人心肌肌球蛋白轻链1的cDNA模板,分别获得中国人心肌肌球蛋白轻链1的各为98个氨基酸的N端和C端片段cDNA的克隆并进行了表达。同时进行了其表达产物和大鼠心肌肌球蛋白重链和人心肌肌动蛋白以及单克隆抗体结合的研究,发现三者均和轻链1的N端相结合,结合们点各不相同。这些结合位点可能均位于轻链1的分子表面,而且如果轻链1在实验状态下先与肌动蛋白结合,则有可能影响轻链与重链间的彼此结合,肌动蛋白在体外能以不同位点结合肌球蛋白重链和轻链,可能在肌肉收缩过程中具有重要的生理意义。     

心肌肌钙蛋白Ⅰ基因突变与心肌病的研究进展

心肌肌钙蛋白I(cTnI)是心肌肌钙蛋白复合物的亚单位之一,与心肌肌钙蛋白T和C相互作用,与肌动蛋白-原肌球蛋白结合从而抑制肌动蛋白-肌球蛋白的收缩作用。在肥厚型、扩张型和限制型心肌病中发现30多种cTnI基因的突变,cTnI基因突变转基因小鼠也反映了心肌病的特征。本文总结了cTnI基因突变在心肌病发病机制中的研究情况。     

果蝇非常规肌球蛋白的结构与功能

肌球蛋白是一类重要的分子马达,可以将ATP水解产生的能量转化成动能,沿由肌动蛋白组成的细丝运动。肌球蛋白构成一个大的基因家族,在许多细胞活动中起着重要作用,包括肌肉收缩、胞内转运、听觉、视觉等。果蝇基因组有13种肌球蛋白基因,包括2种常规肌球蛋白和11种非常规肌球蛋白。本文综述了近年来果蝇非常规肌球蛋白的研究进展。     

STUDIES ON MUSCLE DIFFERENTIATION. V. ANTIGENICITIES OF MYOSIN AND OF ACTIN FROM FROG SKELETAL MUSCLES1

Both intact and denatured preparations of myosin and actin from frog skeletal muscles produced in rabbits antisera containing antibodies against authentic myosin and actin, respectively, though being contaminated with antibodies against other proteins. Antigenicity of our frog myosin as revealed in agar diffusion tests was indistinguishable from that of cardiac muscle myosin from the same species. Similarly, skeletal muscle myosins from other amphibians shared to a certain extent immunological characteristics with our frog myosin, but those from avian and mammalian materials did not. Similarity in antigenicity was also demonstrated among our skeletal muscle actin, cardiac muscle actin from the same species and skeletal muscle actin from the other anurans studied. However, skeletal muscle actin from an urodele could not clearly be correlated in its immunological properties with our frog actin, and those from avian and mammalian materials were antigenically different from our frog actin. Thus, the degree of antigenic similarity of these muscle proteins seemed to be correlated with the phylogenic relationship of the animals so far studied. The results also indicated that our antisera could only be applied to immuno-cytological and immuno-embryological studies of myosin and actin when the antisera absorbed with the corresponding antigen preparations were used as negative controls.     

Immunocytochemical evidence for colocalization in neurite growth cones of actin and myosin and their relationship to cell-substratum adhesions

Sensory neurons from 8- to 11-day chick embryos were cultured on polyornithine-treated coverslips, fixed with glutaraldehyde, and stained for immunofluorescent localization of actin. Actin was distributed in a fibrous form in the growth cones, extending into filopodia and lamellipodial expansions of the growth cone margin. Often, these actin fibers were located at sites of linear adhesions to the glass substratum, as viewed by interference reflection optics. Our antisera to myosin did not recognize myosin in glutaraldehyde-fixed cells, and paraformaldehyde, which preserves the antigenicity of myosin, did not fix embryonic neurons well. Thus, myosin was localized in NGF-stimulated PC12 cells, whose morphology is better preserved by paraformaldehyde. Within the growth cones of PC12 neurites, actin and myosin are distributed into fibrous arrays which resemble the actin fibers seen in the growth cones of sensory neurons. Thus, actomyosin-like contractile forces may be exerted in neurite growth cones. These forces may act in concert with cell-substratum adhesive bonds to move the growth cone across the substratum or move organelles within the growth cone.     

Myosin and actin in melanophore-like variants of goldfish erythrophoroma cells: their intracellular distribution and possible association with pigment translocation

Summary The occurrence and intracellular distribution of myosin and actin in melanophore-like cells derived from a goldfish erythrophoroma cell line have been studied by means of sodium dodecylsulfate-polyacrylamide gel electrophoresis (SDS-PAGE), immunoblot and immunofluorescence using antisera against chick gizzard myosin heavy chain and carp skeletal muscle actin. SDS-PAGE of the cell extracts separates out one band at 200 kDalton; this is conjugated with the anti-myosin antiserum. Immunofluorescence using the anti-myosin antiserum discloses that myosin in these cells occurs in two forms: discrete, minute clusters and thin filaments bearing a resemblance to stress fibers. The former is distributed evenly over the entire cytoplasm in the cells with dispersed pigments and, upon pigment aggregation, accumulates densely around collapsed melanosomes. The latter runs as thin bundles either radially along the cell center-to-periphery axis or connecting the corners of cell margins; it gives a similar profile in all states of the motile response. Immunofluorescence using the antiactin antiserum or rhodamine-conjugated phalloidin discloses that actin is similarly distributed to myosin, suggesting its possible existence as actomyosin. Simultaneous translocation of the amorphous forms of myosin and actin with melanosomes indicates that they may be involved in pigment migration.     

Participation of myosin in gliding motility and host cell invasion by Toxoplasma gondii

Toxoplasma gondii is an obligate intracellular parasite that actively invades mammalian cells using a unique form of gliding motility that critically depends on actin filaments in the parasite. To determine if parasite motility is driven by a myosin motor, we examined the distribution of myosin and tested the effects of specific inhibitors on gliding and host cell invasion. A single 90 kDa isoform of myosin was detected in parasite lysates using an antisera that recognizes a highly conserved myosin peptide. Myosin was localized in T. gondii beneath the plasma membrane in a circumferential pattern that overlapped with the distribution of actin. The myosin ATPase inhibitor, butanedione monoxime (BDM), reversibly inhibited gliding motility across serum-coated slides. The myosin light-chain kinase inhibitor, KT5926, also blocked parasite motility and greatly reduced host cell attachment; however, these effects were primarily caused by its ability to block the secretion of microneme proteins, which are involved in cell attachment. In contrast, while BDM partially reduced cell attachment, it prevented invasion even under conditions in which microneme secretion was not affected, indicating a potential role for myosin in cell entry. Collectively, these results indicate that myosin(s) probably participate(s) in powering gliding motility, a process that is essential for cell invasion by T. gondii .     

Antibodies directed against N-terminal residues on actin do not block acto-myosin binding

Several studies using a variety of approaches have suggested a possible role for the amino-terminal residues of skeletal muscle actin in acto-myosin interaction. In order to assess the significance of acto-S-1 contacts involving the N-terminal segment of actin, we have prepared polyclonal antisera against a synthetic peptide corresponding to the seven amino-terminal residues of rabbit skeletal muscle actin (alpha-N-terminal peptide). Affinity-purified immunoglobulin (Ig) G (and Fab) prepared from these antisera reacts strongly and specifically with the amino-terminal segment of both G- and F-actin but not with myosin subfragment 1 (S-1). This specificity was determined by Western blot analysis of actin and its proteolytic fragments and the inhibition of the above reactivity by the alpha-N-terminal peptide. The alpha-N-terminal peptide did not interact with S-1 in solution, affect S-1 and actin-activated S-1 MgATPase, or cause dissociation of the acto-S-1 complex. In separate experiments F-actin could be cosedimented with S-1 and affinity-purified IgG or Fab by using an air-driven ultracentrifuge. Densitometric analysis of sodium dodecyl sulfate/polyacrylamide gels of pellet and supernatant fractions from such experiments demonstrated the binding of both S-1 and IgG or Fab to the same F-actin protomer. Our results suggest that, while the acidic N-terminal amino acids of actin may contact the myosin head, these residues cannot be the main determinants of acto-S-1 interaction.     

Purification and characterization of an Acanthamoeba nuclear actin-binding protein

Immunolocalization of monoclonal antibodies to Acanthamoeba myosin I showed a cross-reactive protein in nuclei (Hagen, S. J., D. P. Kiehart, D. A. Kaiser, and T. D. Pollard. 1986. J. Cell Biol. 103:2121-2128). This protein is antigenically related to myosin I in that nine monoclonal antibodies and three polyclonal antibodies are cross-reactive. However, studies with affinity-purified antibodies and two-dimensional peptide maps show that the protein is not a proteolytic product of myosin I. We have used cell fractionation and column chromatography to purify this protein. It is a dimer of 34-kD polypeptides with a Stokes' radius of 4 nm. A polyclonal antisera generated against the purified protein confirms the nuclear localization seen with the cross-reactive monoclonal antibodies. The 34-kD protein binds actin filaments in an ATP-insensitive manner with a Kd of approximately 0.25 microM without cross-linking, severing, or capping. No ATPase activity was detected in the presence or absence of actin. It also binds to DNA. These unique properties suggest we have discovered a new class of actin-binding protein. We have given this protein the name NAB for "nuclear actin-binding" protein.     

Correlation between the distribution of smooth muscle or non muscle myosins and alpha-smooth muscle actin in normal and pathological soft tissues

The distribution of smooth muscle (SM) and non muscle myosins was compared with that of alpha-SM actin in various normal and pathological tissues and in cultured cells by means of indirect immunofluorescence using a monoclonal antibody specific for alpha-SM actin [anti-alpha sm-1, Skalli et al., 1986b] and two polyclonal antibodies raised against bovine aortic myosin (ABAM) and human platelet myosin (AHPM), respectively. In normal tissues ABAM stained vascular and parenchymal smooth muscle cells (SMC), myoepithelial cells and myoid cells of the testis in a pattern similar to that reported by other authors with antisera raised against non vascular SM myosin. Cells stained with ABAM were always positive for anti-alpha sm-1. In human and experimental atheromatous plaques, most cells were positive for AHPM; a variable proportion was also stained for ABAM plus anti-alpha sm-1. Myofibroblasts from rat granulation tissue, Dupuytren's nodule and stroma from breast carcinoma were constantly positive for AHPM and negative for ABAM; however, myofibroblasts from Dupuytren's nodule and breast carcinoma were anti-alpha sm-1 positive. Early primary cultures of rat aortic SMC were positive for ABAM and anti-alpha sm-1 and became negative for ABAM and positive for AHPM after a few days in culture. They remained positive for AHPM and anti-alpha sm-1 after passages; the staining of AHPM and anti-alpha sm-1 appeared to be colocalized along the same stress fibers. These results may be relevant for the understanding of SMC function and adaptation, and show that in non malignant SMC proliferation, alpha-SM actin represents a more general marker of SM origin than SM myosin.     

Presence of a unit for actin-myosin interaction during the superprecipitation of actomyosin.

The interaction of actin with myosin was studied in the presence of ATP at low ionic strength by means of measurements of the actin-activated ATPase activity of myosin and superprecipitation of actomyosin. At high ATP concentrations the ATPase activities of myosin, heavy meromyosin (HMM) and myosin subfragment 1 (S-1) were activated by actin in the same extent. At low ATP concentrations the myosin ATPase activity was activated about 30-fold by actin, whereas those of HMM and S-1 were stimulated only several-fold. This high actin activation of myosin ATPase was coupled with the occurrence of superprecipitation. The activation of HMM or S-1 ATPase by actin shows a simple hyperbolic dependence on actin concentration, but the myosin ATPase was maximally activated by actin at a 2:1 molar ratio of actin to myosin, and a further increase in the actin concentration had no effect on the activation. These results suggest the presence of a unit for actin-myosin interaction, composed of two actin monomers and one myosin molecule in the filaments.     

Functional characterization of the secondary actin binding site of myosin II

The role of the interaction between actin and the secondary actin binding site of myosin (segment 565-579 of rabbit skeletal muscle myosin, referred to as loop 3 in this work) has been studied with proteolytically generated smooth and skeletal muscle myosin subfragment 1 and recombinant Dictyostelium discoideum myosin II motor domain constructs. Carbodiimide-induced cross-linking between filamentous actin and myosin loop 3 took place only with the motor domain of skeletal muscle myosin and not with those of smooth muscle or D. discoideum myosin II. Chimeric constructs of the D. discoideum myosin motor domain containing loop 3 of either human skeletal muscle or nonmuscle myosin were generated. Significant actin cross-linking to the loop 3 region was obtained only with the skeletal muscle chimera both in the rigor and in the weak binding states, i.e., in the absence and in the presence of ATP analogues. Thrombin degradation of the cross-linked products was used to confirm the cross-linking site of myosin loop 3 within the actin segment 1-28. The skeletal muscle and nonmuscle myosin chimera showed a 4-6-fold increase in their actin dissociation constant, due to a significant increase in the rate for actin dissociation (k(-)(A)) with no significant change in the rate for actin binding (k(+A)). The actin-activated ATPase activity was not affected by the substitutions in the chimeric constructs. These results suggest that actin interaction with the secondary actin binding site of myosin is specific for the loop 3 sequence of striated muscle myosin isoforms but is apparently not essential either for the formation of a high affinity actin-myosin interface or for the modulation of actomyosin ATPase activity.     

The contractile apparatus of striated muscle in the course of atrophy and regeneration

Summary Changes in the contractile apparatus of denervated rat soleus muscles were investigated during the course of reinnervation.As observed earlier, in the course of denervation atrophy the ratio of myosin to actin filaments decreases because myosin filaments disappear faster than actin filaments (Jakubiec-Puka et al. 1981 a). After reinnervation the amount of myosin filaments and myosin heavy chains (myosin HC) in the muscle increased during the first few days; the increment of actin content was negligible. The proportion of myosin HC to actin remained lower than normal for about 30 days. The excess of actin filaments frequently observed in the newly-formed myofibrils reflects this disproportion.The results show a lability of myosin and suggest some cytoskeletal role for actin filaments.