Cytoplasmic dynein participates in the centrosomal localization of the Golgi complex.

Corthésy–Theulaz, Irène; Pauloin, Alain; Pfeffer, Suzanne R.

doi:10.1083/jcb.118.6.1333

Cited by 275 publications

(185 citation statements)

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“…Astral MTs seem indispensable for the reclustering of the organelle in a central location (Shima et al, 1998), but intermediate steps in this process might involve the capture of Golgiattached MTs in the centrosomal area to facilitate the reclustering process. Such a model would require Golgi MTs to exhibit reverse polarity or would be quite complicated in terms of molecular motor regulation, because Golgi reclustering is dynein dependent (Corthésy-Theulaz et al, 1992;Fath et al, 1994, Burkhardt et al, 1997Harada et al, 1998). This would be in a way similar to the behavior of chromosomes during mitosis because they have the possibility to directly nucleate MTs in addition to their capture by centrosomal MTs (Carazo-Salas et al, 1999).…”

Section: Discussionmentioning

confidence: 99%

“…Consistent with earlier findings by Feiguin et al (1994), who found that the expression of kinesin antisense oligonucleotide rendered the Golgi apparatus more compact, microinjection of antikinesin antibodies inhibited Golgi dispersion along stable, nocodazole-resistant MTs (Minin, 1997). Conversely, the central localization of the Golgi apparatus involves cytoplasmic dynein (Corthésy-Theulaz et al, 1992;Fath et al, 1994;Burkhardt et al, 1997;Harada et al, 1998). It is also worth noting that, in addition to the kinesin-mediated disruption of the central Golgi complex during MT depolymerization, the dispersion of Golgi elements also relies on the reconstitution of mini Golgi stacks at endoplasmic reticulum (ER) exit sites (Cole et al, 1996;Storrie et al, 1998).…”

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confidence: 99%

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The Golgi Complex Is a Microtubule-organizing Organelle

Chabin-Brion

Marceiller

Perez

et al. 2001

MBoC

272

244

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We show that the Golgi complex can directly stimulate microtubule nucleation in vivo and in vitro and thus behaves as a potent microtubule-organizing organelle in interphase cells. With the use of nocodazole wash-out experiments in hepatic cells, we found that the occurrence of noncentrosomal, early stabilized microtubules is highly correlated with the subcellular localization of Golgi membranes. With the use of in vitro reconstituted microtubule assembly systems with or without cytosol, we also found that, in contrast to centrosomally attached microtubules, the distal ends of Golgi-attached microtubules are remotely stabilized in a way that requires additional cytosolic component (s). Finally, we demonstrate that Golgi-based microtubule nucleation is direct and involves a subset of ␥-tubulin bound to the cytoplasmic face of the organelle. INTRODUCTIONIn interphase cells, the microtubule (MT) network plays a major role in membrane dynamics and organelle localization. In this context, the interaction between the Golgi complex and the MT network has been extensively studied. The Golgi apparatus colocalizes with the minus ends of MTs, which are usually associated with the centrosome (for review see Kreis et al., 1997;Thyberg and Moskalewski, 1999). This localization actually results from an equilibrium between two contradictory movements that have been unraveled with the use of MT-depolymerizing drugs and probably occur on MT subpopulations with different dynamics. The dispersal of Golgi elements occurs along stable MTs after depolymerization of the most labile MT population (Minin, 1997), whereas their reclustering involves newly assembled MTs (Ho et al., 1989). These contradictory movements of Golgi elements are mediated by distinct molecular motors. Consistent with earlier findings by Feiguin et al. (1994), who found that the expression of kinesin antisense oligonucleotide rendered the Golgi apparatus more compact, microinjection of antikinesin antibodies inhibited Golgi dispersion along stable, nocodazole-resistant MTs (Minin, 1997). Conversely, the central localization of the Golgi apparatus involves cytoplasmic dynein (Corthésy-Theulaz et al., 1992;Fath et al., 1994;Burkhardt et al., 1997;Harada et al., 1998). It is also worth noting that, in addition to the kinesin-mediated disruption of the central Golgi complex during MT depolymerization, the dispersion of Golgi elements also relies on the reconstitution of mini Golgi stacks at endoplasmic reticulum (ER) exit sites (Cole et al., 1996;Storrie et al., 1998). Such data on the scattering and the reclustering of the Golgi complex have led to the view that Golgi membranes undergo an intimate relationship with MTs and especially with a population of nocodazole-resistant, stable MTs. Stable MTs are characterized by the occurrence of posttranslationally modified tubulin-especially detyrosinated and acetylated tubulin (for review, see MacRae, 1997), which is thought to accumulate in stable MTs because of their longer half-lives, but does not influence MT stability i...

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

The Golgi Complex Is a Microtubule-organizing Organelle

Chabin-Brion

Marceiller

Perez

et al. 2001

MBoC

272

244

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“…Each heavy chain has two structural domains that perform distinct functions: the catalytic head domain, which contains the MgATPase and ATP-sensitive microtubule-binding activities; and the flexible dynein specialization occurs in the motor domain: all axonemal dyneins carry an outer doublet microtubule as their cargo, but each arm is specialized to generate precise mechanical force so that the dynein arms working together initiate and propagate ciliary bends (Asai and Brokaw, 1993;Brokaw, 1994). In contrast to axonemal dynein, cytoplasmic dynein carries a diverse array of molecular cargoes (Schnapp and Reese, 1989;Verde et al, 1991;Corthesy-Theulaz et al, 1992;Lin and Collins, 1992;Aniento et al, 1993;Vaisberg et al, 1993;Saunders et al, 1995;Wang et al, 1995) and is probably less specialized in force production. The current view is that cytoplasmic dynein is a homodimer of the heavy chain MAPlC (Vallee et al, 1988;Neely et al, 1990).…”

Section: Introductionmentioning

confidence: 99%

The dynein genes of Paramecium tetraurelia: the structure and expression of the ciliary beta and cytoplasmic heavy chains.

Kandl

Forney

Asai

1995

MBoC

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The genes encoding two Paramecium dynein heavy chains, DHC-6 and DHC-8, have been cloned and sequenced. Sequence-specific antibodies demonstrate that DHC-6 encodes ciliary outer arm beta-chain and DHC-8 encodes a cytoplasmic dynein heavy chain. Therefore, this study is the first opportunity to compare the primary structures and expression of two heavy chains representing the two functional classes of dynein expressed in the same cell. Deciliation of paramecia results in the accumulation of mRNA from DHC-6, but not DHC-8. Nuclear run-on transcription experiments demonstrate that this increase in the steady state concentration of DHC-6 mRNA is a consequence of a rapid induction of transcription in response to deciliation. This is the first demonstration that dynein, like other axonemal components, is transcriptionally regulated during reciliation. Analyses of the sequences of the two Paramecium dyneins and the dynein heavy chains from other organisms indicate that the heavy chain can be divided into three regions: 1) the sequence of the central catalytic domain is conserved among all dyneins; 2) the tail domain sequence, consisting of the N-terminal 1200 residues, differentiates between axonemal and cytoplasmic dyneins; and 3) the N-terminal 200 residues are the most divergent and appear to classify the isoforms. The organization of the heavy chain predicts that the variable tail domain may be sufficient to target the dynein to the appropriate place in the cell.

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“…The ability of the Golgi to undergo continuous, homotypic fusion can nevertheless be monitored by live-cell video microscopy after microinjection or fusion of two cell types harboring different colored Golgi stacks. Indeed, exogenously added, wild-type Golgi complexes could receive cargo from the Golgi complexes of mutant, semiintact CHO cells (35).…”

Section: Combining Premises 1 Andmentioning

confidence: 99%

How the Golgi works: A cisternal progenitor model

Pfeffer

2010

Proc. Natl. Acad. Sci. U.S.A.

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The Golgi complex is a central processing compartment in the secretory pathway of eukaryotic cells. This essential compartment processes more than 30% of the proteins encoded by the human genome, yet we still do not fully understand how the Golgi is assembled and how proteins pass through it. Recent advances in our understanding of the molecular basis for protein transport through the Golgi and within the endocytic pathway provide clues to how this complex organelle may function and how proteins may be transported through it. Described here is a possible model for transport of cargo through a tightly stacked Golgi that involves continual fusion and fission of stable, "like" subcompartments and provides a mechanism to grow the Golgi complex from a stable progenitor, in an ordered manner.

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Cytoplasmic dynein participates in the centrosomal localization of the Golgi complex.

Cited by 275 publications

References 61 publications

The Golgi Complex Is a Microtubule-organizing Organelle

The Golgi Complex Is a Microtubule-organizing Organelle

The dynein genes of Paramecium tetraurelia: the structure and expression of the ciliary beta and cytoplasmic heavy chains.

How the Golgi works: A cisternal progenitor model

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