Probing and tracking organelles in living plant cells

Intracellular organelle movements and positioning play pivotal roles in enabling plants to proliferate life efficiently and to survive diverse environmental stresses. The elaborate dissection of organelle dynamics and their underlying mechanisms (e.g., the role of the cytoskeleton in organelle movements) largely depends on the advancement and efficiency of organelle tracking systems. Here, we provide an overview of some recently developed tools for labeling and tracking organelle dynamics in living plant cells.     

光激活荧光蛋白及其在植物分子细胞生物学研究中的应用

光激活荧光蛋白是指用特定光照射时,其荧光特性发生显著改变的一类荧光蛋白。借助光激活荧光蛋白的这种特性,可以实现对活细胞、细胞器或胞内分子的时空标记和追踪。该文介绍了目前光激活荧光蛋白的性质,并从多个方面对其应用进行了概括,包括分子标记与动态分析、蛋白质相互作用、细胞器及细胞组分动态研究、细胞追踪以及在光激活定位显微镜中的应用等,且对目前光激活荧光蛋白在植物分子细胞生物学中的应用进行了详细介绍。     

Myosin VI regulates actin dynamics and melanosome biogenesis

Myosin VI has been implicated in various steps of organelle dynamics. However, the molecular mechanism by which this myosin contributes to membrane traffic is poorly understood. Here, we report that myosin VI is associated with a lysosome-related organelle, the melanosome. Using an actin-based motility assay and video microscopy, we observed that myosin VI does not contribute to melanosome movements. Myosin VI expression regulates instead the organization of actin networks in the cytoplasm. Using a cell-free assay, we showed that myosin VI recruited actin at the surface of isolated melanosomes. Myosin VI is involved in the endocytic-recycling pathway, and this pathway contributes to the transport of a melanogenic enzyme to maturing melanosomes. We showed that depletion of myosin VI accumulated a melanogenic enzyme in enlarged melanosomes and increased their melanin content. We confirmed the requirement of myosin VI to regulate melanosome biogenesis by analysing the morphology of melanosomes in choroid cells from of the Snell's waltzer mice that do not express myosin VI. Together, our results provide new evidence that myosin VI regulates the organization of actin dynamics at the surface of a specialized organelle and unravel a novel function of this myosin in regulating the biogenesis of this organelle.     

蓝光调控的植物器官与细胞器运动

蓝光可诱导植物的器官和细胞器运动,从而更好地适应环境。这些运动反应包括向光反应(phototropism)、叶绿体运动(chloroplast movements)、气孔开放(stomatal opening)、细胞核定位(nuclei positioning)以及叶片伸展和定位(leaf expansion and positioning)。调控这些运动反应的主要蓝光受体是向光素(phototropins)。本文综述向光素的分子特性与感光机制,以及由向光素介导的各种器官及细胞器运动和相关信号转导途径的最新研究进展。     

Making sense of melanosome dynamics in mouse melanocytes

Molecular motors drive most if not all organelle movements in Eukaryotic cells. These proteins are thought to bind to the organelle surface and, through the action of their mechanochemical domains, to translocate the organelle along a cytoskeletal track. In the case of the myosin family of molecular motors, the cytoskeletal track is filamentous actin. Microtubules serve as the cytoskeletal track for the kinesins and dyneins. While a considerable amount is known about the motors and tracks responsible for the bi-directional movement of pigment granules in fish and frog melanophores, relatively little is known about how melanosomes in mammalian melanocytes are transported out the cells dendritic arbor, accumulated at the ends of these dendrites, and transferred to keratinocytes. In this short review, we focus on the use of video microscopy to address these questions in mouse melanocytes, and we describe how an analysis of melanosome dynamics within wild type and dilute melanocytes shaped our thinking regarding the role of an unconventional myosin in melanosome transport and distribution.     

Molecular motors: from one motor many tails to one motor many tales

Kinesin and dynein molecular motor proteins generate the movement of a wide variety of materials in cells. Such movements are crucial for many different cellular and developmental functions, including organelle movement, localization of developmental determinants, mitosis, meiosis and possibly long-range signaling in neurons. Kinesins that control the dynamics of microtubules have also been discovered. Recent work has begun to identify processes in which defective molecular motor function can cause human disease.     

Finite-particle tracking reveals submicroscopic-size changes of mitochondria during transport in mitral cell dendrites

The mechanisms of molecular motor regulation during bidirectional organelle transport are still uncertain. There is, for instance, the unsettled question of whether opposing motor proteins can be engaged in a tug-of-war. Clearly, any non-synchronous activation of the molecular motors of one cargo can principally lead to changes in the cargo's shape and size; the cargo's size and shape parameters would certainly be observables of such changes. We therefore set out to measure position, shape and size parameters of fluorescent mitochondria (during their transport) in dendrites of cultured neurons using a finite-particle tracking algorithm. Our data clearly show transport-related submicroscopic-size changes of mitochondria. The observed displacements of the mitochondrial front and rear ends are consistent with a model in which microtubule plus- and minus-end-directed motor proteins or motors of the same type but moving along anti-parallel microtubules are often out-of-phase and occasionally engaged in a tug-of-war. Mostly the leading and trailing ends of mitochondria undergo similar characteristic movements but with a substantial time delay between the displacements of both ends, a feature reminiscent of an inchworm-like motility mechanism. More generally, we demonstrate that observing the position, shape and size of actively transported finite objects such as mitochondria can yield information on organelle transport that is generally not accessible by tracking the organelles' centroid alone.     

Does the brain use sliding variables for the control of movements?

Delays in the transmission of sensory and motor information prevent errors from being instantaneously available to the central nervous system (CNS) and can reduce the stability of a closed-loop control strategy. On the other hand, the use of a pure feedforward control (inverse dynamics) requires a perfect knowledge of the dynamic behavior of the body and of manipulated objects. Sensory feedback is essential both to accommodate unexpected errors and events and to compensate for uncertainties about the dynamics of the body. Experimental observations concerning the control of posture, gaze and limbs have shown that the CNS certainly uses a combination of closed-loop and open-loop control. Feedforward components of movement, such as eye saccades, occur intermittently and present a stereotyped kinematic profile. In visuo-manual tracking tasks, hand movements exhibit velocity peaks that occur intermittently. When a delay or a slow dynamics are inserted in the visuo-manual control loop, intermittent step-and-hold movements appear clearly in the hand trajectory. In this study, we investigated strategies used by human subjects involved in the control of a particular dynamic system. We found strong evidence for substantial nonlinearities in the commands produced. The presence of step-and-hold movements seemed to be the major source of nonlinearities in the control loop. Furthermore, the stereotyped ballistic-like kinematics of these rapid and corrective movements suggests that they were produced in an open-loop way by the CNS. We analyzed the generation of ballistic movements in the light of sliding control theory assuming that they occurred when a sliding variable exceeded a constant threshold. In this framework, a sliding variable is defined as a composite variable (a combination of the instantaneous tracking error and its temporal derivatives) that fulfills a specific stability criterion. Based on this hypothesis and on the assumption of a constant reaction time, the tracking error and its derivatives should be correlated at a particular time lag before movement onset. A peak of correlation was found for a physiologically plausible reaction time, corresponding to a stable composite variable. The direction and amplitude of the ongoing stereotyped movements seemed also be adjusted in order to minimize this variable. These findings suggest that, during visually guided movements, human subjects attempt to minimize such a composite variable and not the instantaneous error. This minimization seems to be obtained by the execution of stereotyped corrective movements. Received: 18 February 1997 / Accepted in revised form: 29 July 1997     

Subcellular motility: A correlated light and electron microscopic study using cultured cells

To assess the possible role of filaments in subcellular motility, particular cultured cells were studied by light and electron microscopy. Motile cell margins always contained meshworks of ~50 Å diam. filaments. Organelles moved within cytoplasm occupied by a meshwork of 50–100 Å filaments and microtubules. When cells were treated with cytochalasin B, movements of cell margins stopped, but organelle movements continued; electron microscopically, while subplasmalemmal filaments had disappeared, subcortical filaments and microtubules remained. When cells were treated with hypertonic medium, organelle movements ceased but marginal movements continued; electron microscopically, although cell margins contained normal filament arrays, few subcortical filaments remained. It is concluded that while cell margins are moved by a meshwork of filaments, organelle movement is mediated by a subcortical meshwork of filaments and microtubules.     

光激活荧光蛋白及其在植物分子细胞生物学研究中的应用

光激活荧光蛋白是指用特定光照射时, 其荧光特性发生显著改变的一类荧光蛋白。借助光激活荧光蛋白的这种特性,可以实现对活细胞、细胞器或胞内分子的时空标记和追踪。该文介绍了目前光激活荧光蛋白的性质, 并从多个方面对其应用进行了概括, 包括分子标记与动态分析、蛋白质相互作用、细胞器及细胞组分动态研究、细胞追踪以及在光激活定位显微镜中的应用等, 且对目前光激活荧光蛋白在植物分子细胞生物学中的应用进行了详细介绍。     

The structure of cytoplasm in directly frozen cultured cells. II. Cytoplasmic domains associated with organelle movements

The relationship between organelle movement and cytoplasmic structure in cultured fibroblasts or epithelial cells was studied using video-enhanced differential interference contrast microscopy and electron microscopy of directly frozen whole mounts. Two functional cytoplasmic domains are characterized by these techniques. A central domain rich in microtubules is associated with directed as well as Brownian movements of organelles, while a surrounding domain rich in f-actin supports directed but often intermittent organelle movements more distally along small but distinct individual microtubule tracks. Differences in the organization of the cytoplasm near microtubules may explain why organelle movements are typically continuous in central regions but usually intermittent along the small tracks through the periphery. The central type of cytoplasm has a looser cytoskeletal meshwork than the peripheral cytoplasm which might, therefore, interfere less frequently with organelles moving along microtubules there.     

From observing to controlling: Inducible control of organelle dynamics and interactions

The dynamics and interactions of cellular organelles underlie many aspects of cellular functioning. Until recently, assessment of organelle dynamics has been primarily observational or required whole-cell perturbations to assess the implications of altered organelle motility and positioning. However, thanks to recently developed and optimized intervention strategies, we now have the ability to control organelles in their unperturbed state, altering organelle positioning, membrane trafficking pathways, as well as organelle interactions. This can be performed both globally and locally, giving fine control over the range, reversibility, and extent of organelle dynamics. Here, we describe how these tools are currently used for controlling organelles and give insight into the exciting future of this emerging field.     

Cultured cell extracts support organelle movement on microtubules in vitro

Directed movements of organelles have been observed in a variety of cultured cells. To study the regulation and molecular basis of intracellular organelle motility, we have prepared extracts from cultured chick embryo fibroblasts (CEF cells) which support the movement of membraneous organelles along microtubules. The velocity, frequency and characteristics of organelle movements in vitro were similar to those within intact cells. Organelles and extract-coated anionic beads moved predominantly (80%) toward the minus ends of microtubules that had been regrown from centrosomes, corresponding to retrograde translocation. Similar microtubule-dependent organelle movements were observed in extracts prepared from other cultured cells (African green monkey kidney and 3T3 cells). Organelle motility was ATP and microtubule dependent. The frequency of organelle movement was inhibited by acidic (pH less than 7) or alkaline (pH greater than 8) solutions, high ionic strength ([ KCl] = 0.1 M), and the chelation of free magnesium ions. Treatment of the extracts with adenylyl imidodiphosphate (AMP-PNP, 7 mM), sodium orthovanadate (vanadate; Na3VO4, 20 microM), or N-ethylmaleimide (NEM, 2 mM) blocked all organelle motility. The decoration of microtubules with organelles was observed in the presence of AMP-PNP or vanadate. Motility was not affected by cytochalasin D (2 microM) or cAMP (1 mM). Kinesin (Mr = 116,000), an anterograde microtubule-based motor, was partially purified from the CEF extract by microtubule affinity purification in the presence of AMP-PNP, and was able to drive the movement of microtubule on glass coverslips. A similar preparation made in the presence of vanadate contained a different subset of proteins and did not support motility. These results demonstrate that intracellular organelle motility can be reproduced in vitro and provide the basis for investigating the roles of individual molecular components involved in the organelle motor complex.     

Seeing the Song: Left Auditory Structures May Track Auditory-Visual Dynamic Alignment

Auditory and visual signals generated by a single source tend to be temporally correlated, such as the synchronous sounds of footsteps and the limb movements of a walker. Continuous tracking and comparison of the dynamics of auditory-visual streams is thus useful for the perceptual binding of information arising from a common source. Although language-related mechanisms have been implicated in the tracking of speech-related auditory-visual signals (e.g., speech sounds and lip movements), it is not well known what sensory mechanisms generally track ongoing auditory-visual synchrony for non-speech signals in a complex auditory-visual environment. To begin to address this question, we used music and visual displays that varied in the dynamics of multiple features (e.g., auditory loudness and pitch; visual luminance, color, size, motion, and organization) across multiple time scales. Auditory activity (monitored using auditory steady-state responses, ASSR) was selectively reduced in the left hemisphere when the music and dynamic visual displays were temporally misaligned. Importantly, ASSR was not affected when attentional engagement with the music was reduced, or when visual displays presented dynamics clearly dissimilar to the music. These results appear to suggest that left-lateralized auditory mechanisms are sensitive to auditory-visual temporal alignment, but perhaps only when the dynamics of auditory and visual streams are similar. These mechanisms may contribute to correct auditory-visual binding in a busy sensory environment.     

Organelle, bead, and microtubule translocations promoted by soluble factors from the squid giant axon

A reconstituted system for examining directed organelle movements along purified microtubules has been developed. Axoplasm from the squid giant axon was separated into soluble supernatant and organelle-enriched fractions. Movement of axoplasmic organelles along MAP-free microtubules occurred consistently only after addition of axoplasmic supernatant and ATP. The velocity of such organelle movement (1.6 micron/sec) was the same as in dissociated axoplasm. The axoplasmic supernatant also supported movement of microtubules along a glass surface and movement of carboxylated latex beads along microtubules at 0.5 micron/sec. The direction of microtubule movement on glass was opposite to that of organelle and bead movement on microtubules. The factors supporting movements of microtubules, beads, and organelles were sensitive to heat, trypsin, AMP-PNP and 100 microM vanadate. All of these movements may be driven by a single, soluble ATPase that binds reversibly to organelles, beads, or glass and generates a translocating force on a microtubule.     

Regulation of kinesin-directed movements

Bidirectional organelle transport along microtubules is most likely mediated by the opposing forces generated by two microtubule-based motors: kinesin and cytoplasmic dynein. Because the direction and timing of organelle movements are controlled by the cell, the activity of one or both of these motor molecules must be regulated. Recent studies demonstrate that kinesin, kinesin-like proteins and kinesin-associated proteins can be phosphorylated, and suggest that changes in their phosphorylation state may modulate kinesin's ability to interact with either microtubules or organelles. Thus, it is possible that phosphorylation regulates kinesin-driven movements.     

Semi-automated analysis of organelle movement and membrane content: understanding rab-motor complex transport function

Organelle motility is an essential cellular function that is regulated by molecular motors, and their adaptors and activators. Here we established a new method that allows more direct investigation of the function of these peripheral membrane proteins in organelle motility than is possible by analysis of the organelle movement alone. This method uses multi-channel time-lapse microscopy to record the movement of organelles and associated fluorescent proteins, and automatic organelle tracking, to compare organelle movement parameters with the association of membrane proteins. This approach allowed large-scale, unbiased analysis of the contribution of organelle-associated proteins and cytoskeleton tracks in motility. Using this strategy, we addressed the role of membrane recruitment of Rab GTPases and effectors in organelle dynamics, using the melanosome as a model. We found that Rab27a and Rab32/38 were mainly recruited to sub-populations of slow-moving/static and fast-moving melanosomes, respectively. The correlation of Rab27a recruitment with slow movement/docking was dependent on the effector melanophilin. Meanwhile, using cytoskeleton-disrupting drugs, we observed that this speed:Rab content relationship corresponded to a decreased frequency of microtubule (MT)-based transport and an increased frequency of actin-dependent slow movement/docking. Overall, our data indicate the ability of Rab27a and effector recruitment to switch melanosomes from MT- to actin-based tethering and suggest that a network of Rab signalling may integrate melanosome biogenesis and transport.     

Mitochondria as regulators of stimulus-evoked calcium signals in neurons

An important challenge in the study of Ca2+ signalling is to understand the dynamics of intracellular Ca2+ levels during and after physiological stimulation. While extensive information is available regarding the structural and biophysical properties of Ca2+ channels, pumps and exchangers that control cellular Ca2+ movements, little is known about the quantitative properties of the transporters that are expressed together in intact cells or about the way they operate as a system to orchestrate stimulus-induced Ca2+ signals. This lack of information is particularly striking given that many qualitative properties of Ca2+ signals (e.g. whether the Ca2+ concentration within a particular organelle rises or falls during stimulation) depend critically on quantitative properties of the underlying Ca2+ transporters (e.g. the rates of Ca2+ uptake and release by the organelle). This monograph describes the in situ characterization of Ca2+ transport pathways in sympathetic neurons, showing how mitochondrial Ca2+ uptake and release systems define the direction and rate of net Ca2+ transport by this organelle, and how the interplay between mitochondrial Ca2+ transport and Ca+2 transport across the plasma membrane contribute to depolarization-evoked Ca2+ signals in intact cells.     

A complex choreography of cell movements shapes the vertebrate eye

Optic cup morphogenesis (OCM) generates the basic structure of the vertebrate eye. Although it is commonly depicted as a series of epithelial sheet folding events, this does not represent an empirically supported model. Here, we combine four-dimensional imaging with custom cell tracking software and photoactivatable fluorophore labeling to determine the cellular dynamics underlying OCM in zebrafish. Although cell division contributes to growth, we find it dispensable for eye formation. OCM depends instead on a complex set of cell movements coordinated between the prospective neural retina, retinal pigmented epithelium (RPE) and lens. Optic vesicle evagination persists for longer than expected; cells move in a pinwheel pattern during optic vesicle elongation and retinal precursors involute around the rim of the invaginating optic cup. We identify unanticipated movements, particularly of central and peripheral retina, RPE and lens. From cell tracking data, we generate retina, RPE and lens subdomain fate maps, which reveal novel adjacencies that might determine corresponding developmental signaling events. Finally, we find that similar movements also occur during chick eye morphogenesis, suggesting that the underlying choreography is conserved among vertebrates.     

Membrane trafficking, organelle transport, and the cytoskeleton

Cytoskeleton-associated motor proteins typically drive organelle movements in eukaryotic cells in a manner that is tightly regulated, both spatially and temporally. In the past year, a novel organelle transport mechanism utilizing actin polymerization was described. Important advances were also made in the assignment of functions to several new motors and in our understanding of how motor proteins are regulated during organelle transport. In addition, insights were gained into how and why organelles are transported cooperatively along the microtubule and actin cytoskeletons, and into the importance of motor-mediated transport in the organization of the cytoskeleton itself.