Subpixel colocalization reveals amyloid precursor protein-dependent kinesin-1 and dynein association with axonal vesicles

Szpankowski, Lukasz; Encalada, Sandra E.; Goldstein, Lawrence S.B.

doi:10.1073/pnas.1120510109

Cited by 37 publications

(37 citation statements)

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“…In addition to adaptor and signaling proteins, APP CTFs are also implicated in interactions with motor proteins such as kinesin, myosin, and dynein (Cottrell et al, 2005;Goldstein, 2012), thereby possibly controlling their own transport (Rodrigues et al, 2012). For example, kinesin-1 localizes to APP-positive axonal vesicles (Szpankowski et al, 2012), and kinesin-1 may interact with APP either directly or indirectly via JIP1 (Chiba et al, 2014;Goldstein, 2012;Kamal et al, 2001;Lazarov et al, 2005). Intriguingly, striking evidence has been reported that JIP1 can directly control anterograde or retrograde directions of APP transport by controlling the activities of kinesin-1 and dynein (Fu and Holzbaur, 2013).…”

Section: App Proteolytic Products: Unique Proteins With Specialized Fmentioning

confidence: 99%

Cellular Functions of the Amyloid Precursor Protein from Development to Dementia

2015

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Amyloid precursor protein (APP) is a key player in Alzheimer's disease (AD). The Aβ fragments of APP are the major constituent of AD-associated amyloid plaques, and mutations or duplications of the gene coding for APP can cause familial AD. Here we review the roles of APP in neuronal development, signaling, intracellular transport, and other aspects of neuronal homeostasis. We suggest that APP acts as a signaling nexus that transduces information about a range of extracellular conditions, including neuronal damage, to induction of intracellular signaling events. Subtle disruptions of APP signaling functions may be major contributors to AD-causing neuronal dysfunction.

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Section: App Proteolytic Products: Unique Proteins With Specialized Fmentioning

confidence: 99%

Cellular Functions of the Amyloid Precursor Protein from Development to Dementia

2015

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“…3. For each image in the Z-stack (cargo, motor 1 and motor 2; generated in step 4.2.14) determine the X-Y coordinates and intensity amplitudes for each fluorescent puncta using an established algorithm to fit 2D Gaussians to the point spread function that represents each point source in each of the three channels 16,20,21 ( Figure 2D).…”

Section: "Cargo Mapping" Analysesmentioning

confidence: 99%

“…To obtain the X-Y coordinates, a custom built MATLAB software package called "Motor Colocalization" was developed 16,20 , which incorporates a Gaussian fitting algorithm developed by Jaqaman, Danuser and colleagues [21][22][23] . The software package and detailed instructions for its use can be obtained upon request.…”

Section: Notementioning

confidence: 99%

“…Fixed cargo and motor images are superimposed onto live movement kymographs to "map" (colocalize) them to the live cargo movement trajectories 16 . To correlate the live movement of cargoes with the association of motor proteins, colocalization is analyzed using a custom made MATLAB software package called "Motor Colocalization" 16,20 . Fluorescently labeled cargoes and motors generate diffraction-limited punctate features that can partially overlap.…”

Section: Introductionmentioning

confidence: 99%

“…To resolve the position of overlapping puncta, the software first automatically fits Gaussian functions to each point spread function, representing individual fluorescent puncta, to determine their precise X-Y sub-pixel position coordinates and intensity amplitudes [21][22][23] . The positions of motors and cargoes are subsequently compared to each other to determine colocalization 16,20 . Therefore, this method more precisely assigns colocalization between fluorescent puncta as compared to other methods 24 …”

Section: Introductionmentioning

confidence: 99%

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Characterizing the Composition of Molecular Motors on Moving Axonal Cargo Using "Cargo Mapping" Analysis

Neumann

Campbell

Szpankowski

et al. 2014

JoVE

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Understanding the mechanisms by which molecular motors coordinate their activities to transport vesicular cargoes within neurons requires the quantitative analysis of motor/cargo associations at the single vesicle level. The goal of this protocol is to use quantitative fluorescence microscopy to correlate ("map") the position and directionality of movement of live cargo to the composition and relative amounts of motors associated with the same cargo. "Cargo mapping" consists of live imaging of fluorescently labeled cargoes moving in axons cultured on microfluidic devices, followed by chemical fixation during recording of live movement, and subsequent immunofluorescence (IF) staining of the exact same axonal regions with antibodies against motors. Colocalization between cargoes and their associated motors is assessed by assigning sub-pixel position coordinates to motor and cargo channels, by fitting Gaussian functions to the diffraction-limited point spread functions representing individual fluorescent point sources. Fixed cargo and motor images are subsequently superimposed to plots of cargo movement, to "map" them to their tracked trajectories. The strength of this protocol is the combination of live and IF data to record both the transport of vesicular cargoes in live cells and to determine the motors associated to these exact same vesicles. This technique overcomes previous challenges that use biochemical methods to determine the average motor composition of purified heterogeneous bulk vesicle populations, as these methods do not reveal compositions on single moving cargoes. Furthermore, this protocol can be adapted for the analysis of other transport and/or trafficking pathways in other cell types to correlate the movement of individual intracellular structures with their protein composition. Limitations of this protocol are the relatively low throughput due to low transfection efficiencies of cultured primary neurons and a limited field of view available for high-resolution imaging. Future applications could include methods to increase the number of neurons expressing fluorescently labeled cargoes. Video LinkThe video component of this article can be found at

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Dynein and Kinesin

Steele

Goldstein

2015

Encyclopedia of Life Sciences

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During the life cycle of a eukaryotic cell, chromosomes and other cellular materials must be distributed to daughter cells, proteins must be synthesised and delivered to their site of utilisation and cellular organelles must be delivered to, and retrieved from, appropriate places within the cell. In some cell types, such as neurons, essential cellular materials must be delivered across long distances from the cell body to distal axon terminals or dendrites. Because diffusion is incapable of accomplishing these tasks, eukaryotes have developed an active transport mechanism that relies on superfamilies of kinesin, dynein and myosin motor proteins that walk along microtubule or microfilament tracks. This article discusses how the microtubule‐based motors of the kinesin and dynein superfamilies mediate intracellular transport and cilia/flagella motility within eukaryotic cells. Key Concepts Microtubules have an intrinsic polarity that microtubule‐based motor proteins recognise to generate adenosine triphosphate (ATP)‐dependent unidirectional movement. Both the kinesin and dynein catalytic polypeptides contain a stand‐alone motor domain, which is the actual microtubule‐dependent ATPase force‐generating unit of these motors. Axonemal dyneins, which comprise the outer and inner dynein arms, power cilia and flagella beating by producing sliding movements between adjacent outer‐doublet microtubules. Cytoplasmic dyneins are primarily transport motors driving retrograde transport through a minus‐end‐directed ATP‐dependent mechanism. In neurons, dynein complexes with different intermediate chain isoforms have distinct roles, including cargo binding and transport, and phosphorylation of the intermediate chain may also specify binding to specific cargo. Differences in the stalk and tail domains and various associated proteins (light chains) distinguish the multiple classes of kinesin superfamily members. A key functional distinction between dyneins and kinesins is that, while kinesin family members can generate movement in the plus‐ or minus‐end direction, dynein motors generate only minus‐end‐directed movement. To fill the numerous intracellular roles for plus‐end‐directed motility, eukaryotic cells have evolved a large array of kinesin superfamily members. Microtubule‐based motors must be regulated on an individual and collective scale to facilitate the correct temporal and spatial intracellular placement of eukaryotic organelles. Cytoplasmic dynein and its dynactin complex drive retrograde, minus‐end‐directed movement in neurons, whereas kinesins typically move towards the anterograde direction.

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Subpixel colocalization reveals amyloid precursor protein-dependent kinesin-1 and dynein association with axonal vesicles

Cited by 37 publications

References 47 publications

Cellular Functions of the Amyloid Precursor Protein from Development to Dementia

Cellular Functions of the Amyloid Precursor Protein from Development to Dementia

Characterizing the Composition of Molecular Motors on Moving Axonal Cargo Using "Cargo Mapping" Analysis

Dynein and Kinesin

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