An Ordered Inheritance Strategy for the Golgi Apparatus: Visualization of Mitotic Disassembly Reveals a Role for the Mitotic Spindle

During mitosis, the ribbon of the Golgi apparatus is transformed into dispersed tubulo-vesicular membranes, proposed to facilitate stochastic inheritance of this low copy number organelle at cytokinesis. Here, we have analyzed the mitotic disassembly of the Golgi apparatus in living cells and provide evidence that inheritance is accomplished through an ordered partitioning mechanism. Using a Sar1p dominant inhibitor of cargo exit from the endoplasmic reticulum (ER), we found that the disassembly of the Golgi observed during mitosis or microtubule disruption did not appear to involve retrograde transport of Golgi residents to the ER and subsequent reorganization of Golgi membrane fragments at ER exit sites, as has been suggested. Instead, direct visualization of a green fluorescent protein (GFP)-tagged Golgi resident through mitosis showed that the Golgi ribbon slowly reorganized into 1–3-μm fragments during G2/early prophase. A second stage of fragmentation occurred coincident with nuclear envelope breakdown and was accompanied by the bulk of mitotic Golgi redistribution. By metaphase, mitotic Golgi dynamics appeared to cease. Surprisingly, the disassembly of mitotic Golgi fragments was not a random event, but involved the reorganization of mitotic Golgi by microtubules, suggesting that analogous to chromosomes, the Golgi apparatus uses the mitotic spindle to ensure more accurate partitioning during cytokinesis.

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Nuclear targeted Saccharomyces cerevisiae asparagine synthetases associate with the mitotic spindle regardless of their enzymatic activity

PLoS ONE ◽

10.1371/journal.pone.0243742 ◽

2020 ◽

Vol 15 (12) ◽

pp. e0243742

Author(s):

Chalongrat Noree ◽

Naraporn Sirinonthanawech

Keyword(s):

Cell Division ◽

Mitotic Spindle ◽

Fluorescent Protein ◽

Asparagine Synthetase ◽

Yeast Genome ◽

Alpha Tubulin ◽

Nuclear Envelope Breakdown ◽

Engineered Yeast ◽

Division Process ◽

Green Fluorescent

Recently, human asparagine synthetase has been found to be associated with the mitotic spindle. However, this event cannot be seen in yeast because yeast takes a different cell division process via closed mitosis (there is no nuclear envelope breakdown to allow the association between any cytosolic enzyme and mitotic spindle). To find out if yeast asparagine synthetase can also (but hiddenly) have this feature, the coding sequences of green fluorescent protein (GFP) and nuclear localization signal (NLS) were introduced downstream of ASN1 and ASN2, encoding asparagine synthetases Asn1p and Asn2p, respectively, in the yeast genome having mCherrry coding sequence downstream of TUB1 encoding alpha-tubulin, a building block of the mitotic spindle. The genomically engineered yeast strains showed co-localization of Asn1p-GFP-NLS (or Asn2p-GFP-NLS) and Tub1p-mCherry in dividing nuclei. In addition, an activity-disrupted mutation was introduced to ASN1 (or ASN2). The yeast mutants still exhibited co-localization between defective asparagine synthetase and mitotic spindle, indicating that the biochemical activity of asparagine synthetase is not required for its association with the mitotic spindle. Furthermore, nocodazole treatment was used to depolymerize the mitotic spindle, resulting in lack of association between the enzyme and the mitotic spindle. Although yeast cell division undergoes closed mitosis, preventing the association of its asparagine synthetase with the mitotic spindle, however, by using yeast constructs with re-localized Asn1/2p have suggested the moonlighting role of asparagine synthetase in cell division of higher eukaryotes.

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Important role for the V-type H+-ATPase and the Golgi apparatus in the recycling of PTH/PTHrP receptor

AJP Endocrinology and Metabolism ◽

10.1152/ajpendo.00404.2003 ◽

2004 ◽

Vol 286 (5) ◽

pp. E704-E710 ◽

Cited By ~ 22

Author(s):

Hesham A. W. Tawfeek ◽

Abdul B. Abou-Samra

Keyword(s):

Golgi Apparatus ◽

Fluorescent Protein ◽

Brefeldin A ◽

Receptor Recycling ◽

Bafilomycin A1 ◽

Coated Pits ◽

Concanamycin A ◽

Hydrogen Atpase ◽

Green Fluorescent ◽

Pthrp Receptor

Our previous studies demonstrated that a green fluorescent protein-tagged parathyroid hormone (PTH)/PTH-related peptide (PTHrP) receptor stably expressed in LLCPK-1 cells undergoes agonist-dependent internalization into clathrin-coated pits. The subcellular localization of the internalized PTH/PTHrP receptor is not known. In the present study, we explored the intracellular pathways of the internalized PTH/PTHrP receptor. Using immunofluorescence and confocal microscopy, we show that the internalized receptors localize at a juxtanuclear compartment identified as the Golgi apparatus. The receptors do not colocalize with lysosomes. Furthermore, whereas the internalized receptors exhibit rapid recycling, treatment with proton pump inhibitors (bafilomycin-A1 and concanamycin A) or brefeldin A, Golgi disrupting agents, reduces PTH/PTHrP receptor recycling. Together, these data indicate an important role for the vacuolar-type hydrogen-ATPase and the Golgi apparatus in postendocytic PTH/PTHrP receptor recovery.

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Identification of an Axonal Kinesin-3 Motor for Fast Anterograde Vesicle Transport that Facilitates Retrograde Transport of Neuropeptides

Molecular Biology of the Cell ◽

10.1091/mbc.e07-03-0261 ◽

2008 ◽

Vol 19 (1) ◽

pp. 274-283 ◽

Cited By ~ 117

Author(s):

Rosemarie V. Barkus ◽

Olga Klyachko ◽

Dai Horiuchi ◽

Barry J. Dickson ◽

William M. Saxton

Keyword(s):

Transport Mechanism ◽

Fluorescent Protein ◽

Retrograde Transport ◽

Major Contributor ◽

Anterograde Transport ◽

Microtubule Motor ◽

Fast Transport ◽

Green Fluorescent ◽

Neuronal Functions ◽

Axonal Swellings

A screen for genes required in Drosophila eye development identified an UNC-104/Kif1 related kinesin-3 microtubule motor. Analysis of mutants suggested that Drosophila Unc-104 has neuronal functions that are distinct from those of the classic anterograde axonal motor, kinesin-1. In particular, unc-104 mutations did not cause the distal paralysis and focal axonal swellings characteristic of kinesin-1 (Khc) mutations. However, like Khc mutations, unc-104 mutations caused motoneuron terminal atrophy. The distributions and transport behaviors of green fluorescent protein-tagged organelles in motor axons indicate that Unc-104 is a major contributor to the anterograde fast transport of neuropeptide-filled vesicles, that it also contributes to anterograde transport of synaptotagmin-bearing vesicles, and that it contributes little or nothing to anterograde transport of mitochondria, which are transported primarily by Khc. Remarkably, unc-104 mutations inhibited retrograde runs by neurosecretory vesicles but not by the other two organelles. This suggests that Unc-104, a member of an anterograde kinesin subfamily, contributes to an organelle-specific dynein-driven retrograde transport mechanism.

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Partitioning of the Golgi Apparatus during Mitosis in Living HeLa Cells

The Journal of Cell Biology ◽

10.1083/jcb.137.6.1211 ◽

1997 ◽

Vol 137 (6) ◽

pp. 1211-1228 ◽

Cited By ~ 169

Author(s):

David T. Shima ◽

Kasturi Haldar ◽

Rainer Pepperkok ◽

Rose Watson ◽

Graham Warren

Keyword(s):

Golgi Apparatus ◽

Hela Cells ◽

Direct Evidence ◽

Fluorescent Protein ◽

Immunofluorescence Microscopy ◽

Critical Feature ◽

Directed Movement ◽

Late Telophase ◽

Green Fluorescent ◽

Retention Signal

The Golgi apparatus of HeLa cells was fluorescently tagged with a green fluorescent protein (GFP), localized by attachment to the NH2-terminal retention signal of N-acetylglucosaminyltransferase I (NAGT I). The location was confirmed by immunogold and immunofluorescence microscopy using a variety of Golgi markers. The behavior of the fluorescent Golgi marker was observed in fixed and living mitotic cells using confocal microscopy. By metaphase, cells contained a constant number of Golgi fragments dispersed throughout the cytoplasm. Conventional and cryoimmunoelectron microscopy showed that the NAGT I–GFP chimera (NAGFP)-positive fragments were tubulo-vesicular mitotic Golgi clusters. Mitotic conversion of Golgi stacks into mitotic clusters had surprisingly little effect on the polarity of Golgi membrane markers at the level of fluorescence microscopy. In living cells, there was little self-directed movement of the clusters in the period from metaphase to early telophase. In late telophase, the Golgi ribbon began to be reformed by a dynamic process of congregation and tubulation of the newly inherited Golgi fragments. The accuracy of partitioning the NAGFP-tagged Golgi was found to exceed that expected for a stochastic partitioning process. The results provide direct evidence for mitotic clusters as the unit of partitioning and suggest that precise regulation of the number, position, and compartmentation of mitotic membranes is a critical feature for the ordered inheritance of the Golgi apparatus.

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Retrograde Transport of Transcription Factor NF-κB in Living Neurons

Journal of Biological Chemistry ◽

10.1074/jbc.m009253200 ◽

2000 ◽

Vol 276 (15) ◽

pp. 11821-11829 ◽

Cited By ~ 81

Author(s):

Henning Wellmann ◽

Barbara Kaltschmidt ◽

Christian Kaltschmidt

Keyword(s):

Transcription Factor ◽

Green Fluorescent Protein ◽

Fluorescent Protein ◽

Retrograde Transport ◽

Receptor Activation ◽

Transcriptional Changes ◽

Localization Signal ◽

Green Fluorescent ◽

Living Neurons

The mechanism by which signals such as those produced by glutamate are transferred to the nucleus may involve direct transport of an activated transcription factor to trigger long-term transcriptional changes. Ionotropic glutamate receptor activation or depolarization activates transcription factor NF-κB and leads to translocation of NF-κB from the cytoplasm to the nucleus. We investigated the dynamics of NF-κB translocation in living neurons by tracing the NF-κB subunit RelA (p65) with jellyfish green fluorescent protein. We found that green fluorescent protein-RelA was located in either the nucleus or cytoplasm and neurites, depending on the coexpression of the cognate inhibitor of NF-κB, IκB-α. Stimulation with glutamate, kainate, or potassium chloride resulted in a redistribution of NF-κB from neurites to the nucleus. This transport depended on an intact nuclear localization signal on RelA. Thus, in addition to its role as a transcription factor, NF-κB may be a signal transducer, transmitting transient glutamatergic signals from distant sites to the nucleus.

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Internalization of Monomeric Lipopolysaccharide Occurs after Transfer Out of Cell Surface Cd14

Journal of Experimental Medicine ◽

10.1084/jem.190.4.509 ◽

1999 ◽

Vol 190 (4) ◽

pp. 509-522 ◽

Cited By ~ 58

Author(s):

Thierry Vasselon ◽

Eric Hailman ◽

Rolf Thieringer ◽

Patricia A. Detmers

Keyword(s):

Plasma Membrane ◽

Green Fluorescent Protein ◽

Golgi Apparatus ◽

Cell Surface ◽

Enhanced Green Fluorescent Protein ◽

Fluorescent Protein ◽

Soluble Cd14 ◽

Stable Transfectants ◽

Intracellular Vesicles ◽

Green Fluorescent

Lipopolysaccharide (LPS) fluorescently labeled with boron dipyrromethane (BODIPY) first binds to the plasma membrane of CD14-expressing cells and is subsequently internalized. Intracellular LPS appears in small vesicles near the cell surface and later in larger, punctate structures identified as the Golgi apparatus. To determine if membrane (m)CD14 directs the movement of LPS to the Golgi apparatus, an mCD14 chimera containing enhanced green fluorescent protein (mCD14–EGFP) was used to follow trafficking of mCD14 and BODIPY–LPS in stable transfectants. The chimera was expressed strongly on the cell surface and also in a Golgi complex–like structure. mCD14–EGFP was functional in mediating binding of and responses to LPS. BODIPY–LPS presented to the transfectants as complexes with soluble CD14 first colocalized with mCD14–EGFP on the cell surface. However, within 5–10 min, the BODIPY–LPS distributed to intracellular vesicles that did not contain mCD14–EGFP, indicating that mCD14 did not accompany LPS during endocytic movement. These results suggest that monomeric LPS is transferred out of mCD14 at the plasma membrane and traffics within the cell independently of mCD14. In contrast, aggregates of LPS were internalized in association with mCD14, suggesting that LPS clearance occurs via a pathway distinct from that which leads to signaling via monomeric LPS.

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Formation of Spindle Poles by Dynein/Dynactin-Dependent Transport of Numa

The Journal of Cell Biology ◽

10.1083/jcb.149.4.851 ◽

2000 ◽

Vol 149 (4) ◽

pp. 851-862 ◽

Cited By ~ 232

Author(s):

Andreas Merdes ◽

Rebecca Heald ◽

Kumiko Samejima ◽

William C. Earnshaw ◽

Don W. Cleveland

Keyword(s):

Fluorescent Protein ◽

Gel Filtration ◽

Cytoplasmic Dynein ◽

Spindle Pole ◽

Nuclear Envelope Breakdown ◽

Spindle Poles ◽

Mitotic Spindle Assembly ◽

Green Fluorescent ◽

Dependent Transport ◽

Dynactin Complex

NuMA is a large nuclear protein whose relocation to the spindle poles is required for bipolar mitotic spindle assembly. We show here that this process depends on directed NuMA transport toward microtubule minus ends powered by cytoplasmic dynein and its activator dynactin. Upon nuclear envelope breakdown, large cytoplasmic aggregates of green fluorescent protein (GFP)-tagged NuMA stream poleward along spindle fibers in association with the actin-related protein 1 (Arp1) protein of the dynactin complex and cytoplasmic dynein. Immunoprecipitations and gel filtration demonstrate the assembly of a reversible, mitosis-spe-cific complex of NuMA with dynein and dynactin. NuMA transport is required for spindle pole assembly and maintenance, since disruption of the dynactin complex (by increasing the amount of the dynamitin subunit) or dynein function (with an antibody) strongly inhibits NuMA translocation and accumulation and disrupts spindle pole assembly.

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A New Model for Nuclear Envelope Breakdown

Molecular Biology of the Cell ◽

10.1091/mbc.12.2.503 ◽

2001 ◽

Vol 12 (2) ◽

pp. 503-510 ◽

Cited By ~ 73

Author(s):

Mark Terasaki ◽

Paul Campagnola ◽

Melissa M. Rolls ◽

Pascal A. Stein ◽

Jan Ellenberg ◽

...

Keyword(s):

Nuclear Envelope ◽

Fluorescent Protein ◽

Three Dimensional ◽

Nuclear Pore ◽

Permeability Barrier ◽

Second Phase ◽

New Model ◽

Nuclear Envelope Breakdown ◽

Two Phases ◽

Green Fluorescent

Nuclear envelope breakdown was investigated during meiotic maturation of starfish oocytes. Fluorescent 70-kDa dextran entry, as monitored by confocal microscopy, consists of two phases, a slow uniform increase and then a massive wave. From quantitative analysis of the first phase of dextran entry, and from imaging of green fluorescent protein chimeras, we conclude that nuclear pore disassembly begins several minutes before nuclear envelope breakdown. The best fit for the second phase of entry is with a spreading disruption of the membrane permeability barrier determined by three-dimensional computer simulations of diffusion. We propose a new model for the mechanism of nuclear envelope breakdown in which disassembly of the nuclear pores leads to a fenestration of the nuclear envelope double membrane.

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Implication of a novel multiprotein Dam1p complex in outer kinetochore function

The Journal of Cell Biology ◽

10.1083/jcb.200109063 ◽

2001 ◽

Vol 155 (7) ◽

pp. 1137-1146 ◽

Cited By ~ 133

Author(s):

Iain M. Cheeseman ◽

Christine Brew ◽

Michael Wolyniak ◽

Arshad Desai ◽

Scott Anderson ◽

...

Keyword(s):

Mitotic Spindle ◽

Fluorescent Protein ◽

Temperature Sensitive ◽

Temperature Sensitive Mutants ◽

Phosphorylation Event ◽

Spindle Microtubules ◽

Green Fluorescent ◽

Kinetochore Function

Dam1p, Duo1p, and Dad1p can associate with each other physically and are required for both spindle integrity and kinetochore function in budding yeast. Here, we present our purification from yeast extracts of an ∼245 kD complex containing Dam1p, Duo1p, and Dad1p and Spc19p, Spc34p, and the previously uncharacterized proteins Dad2p and Ask1p. This Dam1p complex appears to be regulated through the phosphorylation of multiple subunits with at least one phosphorylation event changing during the cell cycle. We also find that purified Dam1p complex binds directly to microtubules in vitro with an affinity of ∼0.5 μM. To demonstrate that subunits of the Dam1p complex are functionally important for mitosis in vivo, we localized Spc19–green fluorescent protein (GFP), Spc34-GFP, Dad2-GFP, and Ask1-GFP to the mitotic spindle and to kinetochores and generated temperature-sensitive mutants of DAD2 and ASK1. These and other analyses implicate the four newly identified subunits and the Dam1p complex as a whole in outer kinetochore function where they are well positioned to facilitate the association of chromosomes with spindle microtubules.

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Microtubules Orient the Mitotic Spindle in Yeast through Dynein-dependent Interactions with the Cell Cortex

The Journal of Cell Biology ◽

10.1083/jcb.138.3.629 ◽

1997 ◽

Vol 138 (3) ◽

pp. 629-641 ◽

Cited By ~ 336

Author(s):

Janet L. Carminati ◽

Tim Stearns

Keyword(s):

Mitotic Spindle ◽

Fluorescent Protein ◽

Dynamic Instability ◽

Dynamic Properties ◽

Yeast Cells ◽

Spindle Orientation ◽

Cell Cortex ◽

Animal Cells ◽

Green Fluorescent ◽

Mutant Cells

Proper orientation of the mitotic spindle is critical for successful cell division in budding yeast. To investigate the mechanism of spindle orientation, we used a green fluorescent protein (GFP)–tubulin fusion protein to observe microtubules in living yeast cells. GFP–tubulin is incorporated into microtubules, allowing visualization of both cytoplasmic and spindle microtubules, and does not interfere with normal microtubule function. Microtubules in yeast cells exhibit dynamic instability, although they grow and shrink more slowly than microtubules in animal cells. The dynamic properties of yeast microtubules are modulated during the cell cycle. The behavior of cytoplasmic microtubules revealed distinct interactions with the cell cortex that result in associated spindle movement and orientation. Dynein-mutant cells had defects in these cortical interactions, resulting in misoriented spindles. In addition, microtubule dynamics were altered in the absence of dynein. These results indicate that microtubules and dynein interact to produce dynamic cortical interactions, and that these interactions result in the force driving spindle orientation.

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