Characterization of the <i>Arabidopsis</i> Augmin Complex Uncovers Its Critical Function in the Assembly of the Acentrosomal Spindle and Phragmoplast Microtubule Arrays

Hotta, Takashi; Kong, Zhaosheng; Ho, Chin‐Min Kimmy; Zeng, Cui Jing Tracy; Horio, Tetsuya; Fong, S.K.H.; Vuong, T. Minh; Lee, Yuh‐Ru Julie; Liu, Bo

doi:10.1105/tpc.112.096610

Cited by 93 publications

(120 citation statements)

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“…g-Tubulin localization to phragmoplast MTs is largely dependent on augmin as it becomes dissociated from the phragmoplast in augmin mutant cells in A. thaliana [42 ]. In the mutant, the phragmoplast MT array often fails to expand toward the cell periphery and MTs ultimately became disorganized [42 ]. Similarly when genes encoding augmin subunits are silenced in the moss P. patens, phragmoplast expansion is inhibited because of compromised MT formation in the array [43 ].…”

Section: Amplification Of Mts At the Phragmoplast Peripherymentioning

confidence: 99%

“…The 8-subunit complex augmin contains a MAP and serves as a docking factor for the g-tubulin complex to localize to spindle MTs in animal and plant cells [40,41 ,42 ]. g-Tubulin localization to phragmoplast MTs is largely dependent on augmin as it becomes dissociated from the phragmoplast in augmin mutant cells in A. thaliana [42 ]. In the mutant, the phragmoplast MT array often fails to expand toward the cell periphery and MTs ultimately became disorganized [42 ].…”

Section: Amplification Of Mts At the Phragmoplast Peripherymentioning

confidence: 99%

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The rise and fall of the phragmoplast microtubule array

Lee

Liu

2013

Current Opinion in Plant Biology

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The cytokinetic apparatus, the phragmoplast, contains a bipolar microtubule (MT) framework that has the MT plus ends concentrated at or near the division site. This anti-parallel MT array provides tracks for the transport of Golgi-derived vesicles toward the plus ends so that materials enclosed are subsequently deposited at the division site. Here we will discuss a proposed model of the centrifugal expansion of the phragmoplast that takes place concomitantly with the assembly of the cell plate, the ultimate product of vesicle fusion. The expansion is a result of continuous MT assembly at the phragmoplast periphery while the MTs toward the center of the phragmoplast are disassembled. These events are the result of MT-dependent MT polymerization, bundling of antiparallel MTs coming from opposite sides of the division plane that occurs selectively at the phragmoplast periphery, positioning of the plus ends of cross-linked MTs at or near the division site by establishing a minimal MT-overlapping zone, and debundling of anti-parallel MTs that is triggered by phosphorylation of MT-associated proteins. The debundled MTs are disassembled at last by factors including the MT severing enzyme katanin. IntroductionThe innovation of the phragmoplast marks a significant advancement in the evolution from green algae to land plants [1]. The phragmoplast contains a core of two mirrored sets of anti-parallel microtubules (MTs) whose plus ends are concentrated at or near the midzone of this cytokinetic apparatus (Figure 1) [2]. The ultimate mission of this bipolar MT array is to allow Golgi-derived vesicles to be transported unidirectionally toward MT plus ends so that the materials enclosed in these vesicles are deposited for the assembly of the cell plate. Phragmoplast MTs, like those MTs in spindles during mitosis, undergo continuous remodeling throughout cytokinesis [3,4]. Upon the completion of anaphase, MTs are polymerized and coalesced in the spindle midzone, and a bipolar array is established as the Kinesin-5 motor acts on anti-parallel MTs to slide them against each other ( Figure 1a) [5,6 ,7]. Concomitant with the addition of more MTs to the array, the MTs are shortened at their minus ends, which are facing the reforming daughter nuclei (Figure 1b). One of the most spectacular phenomena in cytokinesis is the centrifugal expansion of the phragmoplast MT array from the cell center to the edge. During the expansion, new MT filaments are added to the periphery of the phragmoplast while older ones in the inner part of the phragmoplast array are disassembled ( Figure 1c). This is particularly challenging because those opposing activities occur simultaneously within a few microns of each other. The assembly of new MTs uses tubulin subunits released from the depolymerization of older MTs [3].Before MT-associated proteins (MAPs) and MT-based motors were identified, microscopic observations had revealed many structural details of the phragmoplast in elegant systems like the endosperm of the African blood lily Haemanthus and tobacc...

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Section: Amplification Of Mts At the Phragmoplast Peripherymentioning

confidence: 99%

Section: Amplification Of Mts At the Phragmoplast Peripherymentioning

confidence: 99%

The rise and fall of the phragmoplast microtubule array

Lee

Liu

2013

Current Opinion in Plant Biology

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“…For example, GRMZM2G311883 is a gene homologous to Arabidopsis MODIFIER OF SNC1-1 14 (MOS14), which is known to form a link between splicing and RNAdependent DNA methylation . Also, genes involved in cell cycle regulation, such as CYCD4, APC10, TIP120-encoding (Wang et al, 2011b), FORMIN8-like (Xue et al, 2011), and AUGMIN6-like (Hotta et al, 2012), are represented in the data set, as are developmental processes affecting the vasculature (Petricka et al, 2008), meristem maintenance , and cell shape and plant architecture (O'Hara et al, 2013). Several genes that are differentially methylated in the older zones play a known role in development.…”

Section: Differential Methylation Along the Developing Maize Leaf Potmentioning

confidence: 99%

Differential Methylation during Maize Leaf Growth Targets Developmentally Regulated Genes

et al. 2014

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DNA methylation is an important and widespread epigenetic modification in plant genomes, mediated by DNA methyltransferases (DMTs). DNA methylation is known to play a role in genome protection, regulation of gene expression, and splicing and was previously associated with major developmental reprogramming in plants, such as vernalization and transition to flowering. Here, we show that DNA methylation also controls the growth processes of cell division and cell expansion within a growing organ. The maize (Zea mays) leaf offers a great tool to study growth processes, as the cells progressively move through the spatial gradient encompassing the division zone, transition zone, elongation zone, and mature zone. Opposite to de novo DMTs, the maintenance DMTs were transcriptionally regulated throughout the growth zone of the maize leaf, concomitant with differential CCGG methylation levels in the four zones. Surprisingly, the majority of differentially methylated sequences mapped on or close to gene bodies and not to repeat-rich loci. Moreover, especially the 59 and 39 regions of genes, which show overall low methylation levels, underwent differential methylation in a developmental context. Genes involved in processes such as chromatin remodeling, cell cycle progression, and growth regulation, were differentially methylated. The presence of differential methylation located upstream of the gene anticorrelated with transcript expression, while gene body differential methylation was unrelated to the expression level. These data indicate that DNA methylation is correlated with the decision to exit mitotic cell division and to enter cell expansion, which adds a new epigenetic level to the regulation of growth processes.DNA methylation is the covalent modification of nucleotides in DNA by the addition of a methyl group. In the nuclear genome of higher eukaryotes, 5-methylcytosine is the most important DNA modification (Goll and Bestor, 2005). It is a phenomenon of ancient origin predating plant-animal diversification. However, some differences exist between plant and animal methylome patterning and function, and DNA methylation has been found to be evolutionarily lost in a few species (Feng et al., 2010;Zemach et al., 2010). Eukaryotic DNA methylation is established by DNA methyltransferase (DMT) enzymes that transfer a methyl group from S-adenosyl Met to the fifth carbon of cytosine. These enzymes can largely be subdivided in maintenance and de novo DMTs, depending on whether the recognition site is already methylated or not. Maintenance DMTs conserve the methylation status of symmetrical (palindromic) sites after DNA replication, by recognizing the hemimethylated locus and methylating the newly synthesized strand. In plants, there are two types of maintenance DMTs: DNA METHYLTRANSFERASE (MET) and CHROMOMETHYLASE (CMT). The former methylates CG sites during DNA replication, whereas the latter methylates CHG (H = A, C, or T) sites located in chromatin in which histone 3 is dimethylated on Lys-9 (Goll and Bestor, 2005). De no...

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“…Results from mutant studies suggest that GIP1a may increase the nucleation capacity of g-TuRCs in vivo (Nakamura et al, 2012). Many of the proteins that direct the localization or activity of g-TuRCs turn out to be essential genes (Ho et al, 2011;Hotta et al, 2012;Nakamura et al, 2012;Walia et al, 2014), indicating a critical role for the spatiotemporal regulation of g-TuRC-dependent microtubule nucleation in plant cells.…”

Section: Microtubule Nucleationmentioning

confidence: 99%

“…The AUGMIN complex, composed of six subunits common to all eukaryotes and two plant-specific subunits (Hotta et al, 2012), was initially found to recruit g-TuRC to microtubules within the mitotic spindle and the phragmoplast (Ho et al, 2011). Further work revealed that this complex recruits g-TuRC to interphase microtubules to promote nucleation activity (Liu et al, 2014).…”

Section: Microtubule Nucleationmentioning

confidence: 99%