Filopodia formation induced by active mDia2/Drf3

Filopodia are rod-shaped cell surface protrusions composed of a parallel bundle of actin filaments. Since filopodia frequently emanate from lamellipodia, it has been proposed that they form exclusively by the convergence and elongation of actin filaments generated in lamellipodia networks. However, filopodia form without Arp2/3-complex, which is essential for lamellipodia formation, indicating that actin filaments in filopodia may be generated by other nucleators. Here we analyzed the effects of ectopic expression of GFP-tagged full length or a constitutively active variant of the human formin mDia2/Drf3. By contrast to the full-length molecule, which did not affect cell behaviour and was entirely cytosolic, active Drf3 lacking the C-terminal regulatory region (Drf3DeltaDAD) induced the formation of filopodia and accumulated at their tips. Low expression of Drf3DeltaDAD induced rod-shaped or tapered filopodia, whereas over-expression resulted in multiple, club-shaped filopodia. The clubs were filled with densely bundled actin filaments, whose number but not packing density decreased further away from the tip. Interestingly, clubs frequently increased in width after protrusion beyond the cell periphery, which correlated with increased amounts of Drf3DeltaDAD at their tips. These data suggest Drf3-induced filopodia form and extend by de novo nucleation of actin filaments instead of convergent elongation. Finally, Drf3DeltaDAD also induced the formation of unusual, lamellipodia-like structures, which contained both lamellipodial markers and the prominent filopodial protein fascin. Microarray analyses revealed highly variable Drf3 expression levels in different commonly used cell lines, reflecting the need for more detailed analyses of the functions of distinct formins in actin cytoskeleton turnover and different cell types.     

A study of protein A-gold resolution for immunoelectron microscopy

For the purpose of investigating a topographical correlation between antigen molecules and protein A-gold(PAG) particles which localized as an immunocytochemical probe, the simplest model on a localization pattern of antigen molecules, which were arranged two-dimensionally on a plane surface of the resin, was used. Ultrathin sections of a G-actin layer, which was adsorbed on epoxy resin and was re-embedded subsequently in JB-4 resin, was stained indirectly with rabbit anti-actin antibody and subsequently by PAG. From this immunoelectron microscopy, a histogram (relative frequency, denoted by y vs. relative length, denoted by x) was obtained using a computer-assisted method. For this histogram, a fitting curve was calculated by a least squares optimization and three parameters (H, U, and W) of the curve which could be useful for a study on the topographical organization of antigen molecules were estimated. Parameter H (maximum y of the curve) would reflect the maximum amount of epitopes at x = U. Half width W, which is the width of the curve at y = H/2, would reflect a breath of epitope masses. This fitting curve was separated into two overlapping curves whose Ws were different from each other. The one constituent curve of which value W was smaller than the other was regarded as a unit curve and the other constituent curve could be resolved into many unit curves whose W values are the same. From these unit curves, the resolution power of the immunoelectron microscopy, using a post-embedding procedure of ultrathin sections, was estimated as 58–66 A°.     

Simultaneous process to isolate actomyosin and actin from post-rigor porcine skeletal muscle

A simultaneous actomyosin and actin isolation procedure from post-rigor porcine muscle was developed, based on differential solubility, gel filtration chromatography and extraction steps. The isolation process was evaluated by SDS-PAGE analysis and silver staining. Actomyosin and actin were isolated in a simultaneous process yielding 0.14 mg and 2.5 mg/g of meat, respectively, using a shorter purification process than others reported in the literature but with similar recoveries. Furthermore, actin preserves its polymerisation ability and both proteins, actomyosin and actin, could be used in further studies.     

Surpassing the lateral resolution limit by a factor of two using structured illumination microscopy

Lateral resolution that exceeds the classical diffraction limit by a factor of two is achieved by using spatially structured illumination in a wide-field fluorescence microscope. The sample is illuminated with a series of excitation light patterns, which cause normally inaccessible high-resolution information to be encoded into the observed image. The recorded images are linearly processed to extract the new information and produce a reconstruction with twice the normal resolution. Unlike confocal microscopy, the resolution improvement is achieved with no need to discard any of the emission light. The method produces images of strikingly increased clarity compared to both conventional and confocal microscopes.     

磷酸伯喹的辐射稳定性及其对聚乙烯醇(PVA)辐射裂解的影响

磷酸伯喹经吸收0.75～10Mrad剂量后,在结构上未发现变化。由于喹啉基的共轭,它对能量的转移作用是相当大的,当聚乙烯醇(PVA)中加入磷酸伯喹时,可使PVA的裂解延缓(但对裂解的机理不产生影响)。磷酸伯喹含量以线性关系影响着PVA的各种裂解参数值。     

Development of a standing-wave fluorescence microscope with high nodal plane flatness

This article reports about the development and application of a standing-wave fluorescence microscope (SWFM) with high nodal plane flatness. As opposed to the uniform excitation field in conventional fluorescence microscopes an SWFM uses a standing-wave pattern of laser light. This pattern consists of alternating planar nodes and antinodes. By shifting it along the axis of the microscope a set of different fluorescent structures can be distinguished. Their axial separation may just be a fraction of a wavelength so that an SWFM allows distinction of structures which would appear axially unresolved in a conventional or confocal fluorescence microscope. An SWFM is most powerful when the axial extension of the specimen is comparable to the wavelength of light. Otherwise several planes are illuminated simultaneously and their separation is hardly feasible. The objective of this work was to develop a new SWFM instrument which allows standing-wave fluorescence microscopy with controlled high nodal plane flatness. Earlier SWFMs did not allow such a controlled flatness, which impeded image interpretation and processing. Another design goal was to build a compact, easy-to-use instrument to foster a more widespread use of this new technique. The instrument developed uses a green-emitting helium–neon laser as the light source, a piezoelectric movable beamsplitter to generate two mutually coherent laser beams of variable relative phase and two single-mode fibres to transmit these beams to the microscope. Each beam is passed on to the specimen by a planoconvex lens and an objective lens. The only reflective surface whose residual curvature could cause wavefront deformations is a dichroic beamsplitter. Nodal plane flatness is controlled via interference fringes by a procedure which is similar to the interferometric test of optical surfaces. The performance of the instrument was tested using dried and fluorescently labelled cardiac muscle cells of rats. The SWFM enabled the distinction of layers of stress fibres whose axial separation was just a fraction of a wavelength. Layers at such a small distance would lie completely within the depth-of-field of a conventional or confocal fluorescence microscope and could therefore not be distinguished by these two methods. To obtain futher information from the SWFM images it would be advantageous to use the images as input-data to image processing algorithms such as conceived by Krishnamurthi et al. (Proc. SPIE, 2655, 1996, 18–25). To minimize specimen-caused nodal plane distortion, the specimen should be embedded in a medium of closely matched refractive index. The proper match of the refractive indices could be checked via the method presented here for the measurement of nodal plane flatness. For this purpose the fluorescent layer of latex beads would simply be replaced by the specimen. A combination of the developed SWFM with a specimen embedded in a medium of matched refractive index and further image processing would exploit the full potential of standing-wave fluorescence microscopy.     

激光共聚焦显微成像技术在植物细胞微丝骨架三维动态观察中的应用

激光扫描共聚焦显微镜(laser scanning confocal microscope,LSCM)是目前生物学领域应用最广泛、分辨率高的仪器。可用于细胞内形态结构观察及三维重建、组分空间定位、实时动态变化监测等研究,图像分析软件还能提供荧光强度、空间距离定量测定的丰富信息。本文以携带GFP融合拟南芥丝束蛋白1(AtFIM1)的肌动蛋白结合结构域2(fABD2)基因的B Y-2转基因细胞系为材料,运用LSCM技术观察到间期细胞的网络状微丝结构并重构出胞内微丝的三维网络结构;实时动态监测细胞有丝分裂过程中微丝骨架的动态变化;通过细胞内荧光强度的分布直观地看出BY-2细胞胞质分裂过程中微丝骨架的动态变化。这些结果显示出LSCM在研究植物细胞微丝骨架的三维网络动态结构及图像荧光强度分析与统计方面的优越性。     

Mechanisms of actin stress fibre assembly

Stress fibres are contractile acto-myosin structures found from many types of non-muscle cells, where they are involved in adhesion, motility and morphogenesis. Stress fibres typically display a periodic alpha-actinin-myosin II pattern and are thus suggested to resemble the sarcomeric actin filament structures of muscle cells. Mammalian cells contain three categories of stress fibres: ventral stress fibres that are attached to focal adhesions at both ends, dorsal stress fibres that are attached to focal adhesions typically at one end and transverse arcs that are curved acto-myosin bundles, which do not directly attach to focal adhesions. In this review, we discuss the definition of stress fibres, organization of actin filaments and other components within these contractile structures, and the mechanisms of stress fibre assembly.