Rotation angle of stem cell division plane controls spiral phyllotaxis in mosses

Journal of Plant Research - The spiral arrangement (phyllotaxis) of leaves is a shared morphology in land plants, and exhibits diversity constrained to the Fibonacci sequence. Phyllotaxis in...     

A MAP kinase is activated late in plant mitosis and becomes localized to the plane of cell division.

In eukaryotes, mitogen-activated protein kinases (MAPKs) are part of signaling modules that transmit diverse stimuli, such as mitogens, developmental cues, or various stresses. Here, we report a novel alfalfa MAPK, Medicago MAP kinase 3 (MMK3). Using an MMK3-specific antibody, we detected the MMK3 protein and its associated activity only in dividing cells. The MMK3 protein could be found during all stages of the cell cycle, but its protein kinase activity was transient in mitosis and correlated with the timing of phragmoplast formation. Depolymerization of microtubules by short treatments with the drug amiprophosmethyl during anaphase and telophase abolished MMK3 activity, indicating that intact microtubules are required for MMK3 activation. During anaphase, MMK3 was found to be concentrated in between the segregating chromosomes; later, it localized at the midplane of cell division in the phragmoplast. As the phragmoplast microtubules were redistributed from the center to the periphery during telophase, MMK3 still localized to the whole plane of division; thus, phragmoplast microtubules are not required to keep MMK3 at this location. Together, these data strongly support a role for MMK3 in the regulation of plant cytokinesis.     

The Arabidopsis CLASP gene encodes a microtubule-associated protein involved in cell expansion and division

Controlling microtubule dynamics and spatial organization is a fundamental requirement of eukaryotic cell function. Members of the ORBIT/MAST/CLASP family of microtubule-associated proteins associate with the plus ends of microtubules, where they promote the addition of tubulin subunits into attached kinetochore fibers during mitosis and stabilize microtubules in the vicinity of the plasma membrane during interphase. To date, nothing is known about their function in plants. Here, we show that the Arabidopsis thaliana CLASP protein is a microtubule-associated protein that is involved in both cell division and cell expansion. Green fluorescent protein-CLASP localizes along the full length of microtubules and shows enrichment at growing plus ends. Our analysis suggests that CLASP promotes microtubule stability. clasp-1 T-DNA insertion mutants are hypersensitive to microtubule-destabilizing drugs and exhibit more sparsely populated, yet well ordered, root cortical microtubule arrays. Overexpression of CLASP promotes microtubule bundles that are resistant to depolymerization with oryzalin. Furthermore, clasp-1 mutants have aberrant microtubule preprophase bands, mitotic spindles, and phragmoplasts, indicating a role for At CLASP in stabilizing mitotic arrays. clasp-1 plants are dwarf, have significantly reduced cell numbers in the root division zone, and have defects in directional cell expansion. We discuss possible mechanisms of CLASP function in higher plants.     

A conformational switch controls cell wall-remodelling enzymes required for bacterial cell division

Remodelling of the peptidoglycan (PG) exoskeleton is intimately tied to the growth and division of bacteria. Enzymes that hydrolyse PG are critical for these processes, but their activities must be tightly regulated to prevent the generation of lethal breaches in the PG matrix. Despite their importance, the mechanisms regulating PG hydrolase activity have remained elusive. Here we investigate the control of cell division hydrolases called amidases (AmiA, AmiB and AmiC) required for Escherichia coli cell division. Poorly regulated amiB mutants were isolated encoding lytic AmiB variants with elevated basal PG hydrolase activities in vitro. The structure of an AmiB orthologue was also solved, revealing that the active site of AmiB is occluded by a conserved alpha helix. Strikingly, most of the amino acid substitutions in the lytic AmiB variants mapped to this domain and are predicted to disrupt its interaction with the active site. Our results therefore support a model in which cell separation is stimulated by the reversible relief of amidase autoinhibition governed by conserved subcomplexes within the cytokinetic ring. Analogous conformational control mechanisms are likely to be part of a general strategy used to control PG hydrolases present within multienzyme PG-remodelling machines.     

Microtubule-associated proteins MAP65-1 and MAP65-2 positively regulate axial cell growth in etiolated Arabidopsis hypocotyls

The Arabidopsis thaliana MAP65-1 and MAP65-2 genes are members of the larger eukaryotic MAP65/ASE1/PRC gene family of microtubule-associated proteins. We created fluorescent protein fusions driven by native promoters that colocalized MAP65-1 and MAP65-2 to a subset of interphase microtubule bundles in all epidermal hypocotyl cells. MAP65-1 and MAP65-2 labeling was highly dynamic within microtubule bundles, showing episodes of linear extension and retraction coincident with microtubule growth and shortening. Dynamic colocalization of MAP65-1/2 with polymerizing microtubules provides in vivo evidence that plant cortical microtubules bundle through a microtubule-microtubule templating mechanism. Analysis of etiolated hypocotyl length in map65-1 and map65-2 mutants revealed a critical role for MAP65-2 in modulating axial cell growth. Double map65-1 map65-2 mutants showed significant growth retardation with no obvious cell swelling, twisting, or morphological defects. Surprisingly, interphase microtubules formed coaligned arrays transverse to the plant growth axis in dark-grown and GA(4)-treated light-grown map65-1 map65-2 mutant plants. We conclude that MAP65-1 and MAP65-2 play a critical role in the microtubule-dependent mechanism for specifying axial cell growth in the expanding hypocotyl, independent of any mechanical role in microtubule array organization.     

Clock controls timing of mouse pancreatic differentiation through regulation of Wnt- and Notch-based and cell division components

The oscillations of circadian genes control the daily circadian clock, regulating a diverse array of physiologies with the 24-hour light/dark cue across a wide variety of organisms. Here we first show that before embryonic circadian rhythms occur, the oscillation (nucleocytoplasmic shuttling) of core circadian gene Clock is tissue-specific and correlated with the state of differentiation during both early development and later pancreas organogenesis. Disruption of Clock as well as Timeless in the embryonic pancreas does not block pancreatic differentiation but alters the balance and maturity of endocrine and exocrine cells. Molecular analysis indicates that inhibition of Clock or Timeless expression disturbs not only cell cycle regulators, but also Wnt- and Notch-signaling components, whose oscillations establish the timing mechanism in somitogenesis. Thus, our results provide new insights about circadian genes' function in control of the timing of differentiation during embryonic development.     

htpR-like gene controls cell division and proteolysis in Pseudomonas aeruginosa

As shown in hybridization experiments, the genome of Pseudomonas aeruginosa cells contains a htpR-like gene which controls the expression of heat shock genes in cells of Escherichia coli. By means of specially constructed plasmids, the synthesis of htpR antisense RNA has been found to disturb cell division and proteolytic processes in P. aeruginosa, suggesting the functional relationship of htpR genes in E. coli and Pseudomonas bacteria.     

The RepA protein of plasmid pSC101 controls Escherichia coli cell division through the SOS response

Although plasmid copy number varies widely among different plasmid species, normally copy number is maintained within a narrow range for any given plasmid. Such copy number control has been shown to occur by regulation of the rate of plasmid DNA replication. Here we report a novel mechanism by which the pSC101 plasmid also can detect an imbalance between the cellular level of its replication protein, RepA, and plasmid-borne RepA binding sites to inhibit bacterial DNA replication and delay host cell division when RepA is in relative excess. We show that delayed cell division occurs by RepA-mediated induction of the SOS response and can be reversed by over-expression of the host DNA primase, DnaG. The effects of RepA excess are prevented by introducing a surfeit of RepA binding sites. The mechanism reported here may help to limit variation in plasmid copy number and allow repopulation of cells with plasmids when copy number falls--potentially pre-empting plasmid loss in cultures of dividing cells.     

Dual localized kinesin‐12 POK2 plays multiple roles during cell division and interacts with MAP65‐3

Kinesins are versatile nano‐machines that utilize variable non‐motor domains to tune specific motor microtubule encounters. During plant cytokinesis, the kinesin‐12 orthologs, PHRAGMOPLAST ORIENTING KINESIN (POK)1 and POK2, are essential for rapid centrifugal expansion of the cytokinetic apparatus, the phragmoplast, toward a pre‐selected cell plate fusion site at the cell cortex. Here, we report on the spatio‐temporal localization pattern of POK2, mediated by distinct protein domains. Functional dissection of POK2 domains revealed the association of POK2 with the site of the future cell division plane and with the phragmoplast during cytokinesis. Accumulation of POK2 at the phragmoplast midzone depends on its functional POK2 motor domain and is fine‐tuned by its carboxy‐terminal region that also directs POK2 to the division site. Furthermore, POK2 likely stabilizes the phragmoplast midzone via interaction with the conserved microtubule‐associated protein MAP65‐3/PLEIADE, a well‐established microtubule cross‐linker. Collectively, our results suggest that dual localized POK2 plays multiple roles during plant cell division.     

A MAP kinase cascade that controls plant cytokinesis

Several components of mitogen-activated protein kinase (MAPK) cascades have been identified in higher plants and have been implicated in cellular responses to a wide variety of abiotic and biotic stimuli. Our recent work has demonstrated that a MAP kinase cascade is involved in the regulation of cytokinesis in plant cells. The MAP kinase cascade in tobacco includes NPK1 MAPK kinase kinase, NQK1 MAPK kinase, and NRK1 MAPK, and its activation is triggered by the binding of NACK1/2 kinesin-like protein to the NPK1 MAPK kinase kinase at the late M-phase of the cell cycle. We refer to this cascade as the NACK-PQR pathway. In this review, we introduce a mechanism for the regulation of plant cytokinesis, focusing on the role of the NACK-PQR pathway.     

PTEN regulates PLK1 and controls chromosomal stability during cell division

PTEN functions as a guardian of the genome through multiple mechanisms. We have previously established that PTEN maintains the structural integrity of chromosomes. In this report, we demonstrate a fundamental role of PTEN in controlling chromosome inheritance to prevent gross genomic alterations. Disruption of PTEN or depletion of PTEN protein phosphatase activity causes abnormal chromosome content, manifested by enlarged or polyploid nuclei. We further identify polo-like kinase 1 (PLK1) as a substrate of PTEN phosphatase. PTEN can physically associate with PLK1 and reduce PLK1 phosphorylation in a phosphatase-dependent manner. We show that PTEN deficiency leads to PLK1 phosphorylation and that a phospho-mimicking PLK1 mutant causes polyploidy, imitating functional deficiency of PTEN phosphatase. Inhibition of PLK1 activity or overexpression of a non-phosphorylatable PLK1 mutant reduces the polyploid cell population. These data reveal a new mechanism by which PTEN controls genomic stability during cell division.     

PAR3 and aPKC regulate Golgi organization through CLASP2 phosphorylation to generate cell polarity

The organization of the Golgi apparatus is essential for cell polarization and its maintenance. The polarity regulator PAR complex (PAR3, PAR6, and aPKC) plays critical roles in several processes of cell polarization. However, how the PAR complex participates in regulating the organization of the Golgi remains largely unknown. Here we demonstrate the functional cross-talk of the PAR complex with CLASP2, which is a microtubule plus-end–tracking protein and is involved in organizing the Golgi ribbon. CLASP2 directly interacted with PAR3 and was phosphorylated by aPKC. In epithelial cells, knockdown of either PAR3 or aPKC induced the aberrant accumulation of CLASP2 at the trans-Golgi network (TGN) concomitantly with disruption of the Golgi ribbon organization. The expression of a CLASP2 mutant that inhibited the PAR3-CLASP2 interaction disrupted the organization of the Golgi ribbon. CLASP2 is known to localize to the TGN through its interaction with the TGN protein GCC185. This interaction was inhibited by the aPKC-mediated phosphorylation of CLASP2. Furthermore, the nonphosphorylatable mutant enhanced the colocalization of CLASP2 with GCC185, thereby perturbing the Golgi organization. On the basis of these observations, we propose that PAR3 and aPKC control the organization of the Golgi through CLASP2 phosphorylation.     

Regulation of the plane of cell division in vacuolated cells

Summary In small leaf explants fromNautilocalyx lynchii (Hook. f.) Sprague (Gesneriaceae) the vacuolated epidermal cells divide after 3–4 days. Most cells divide periclinally, but longitudinal and transverse divisions are also found. Before mitosis the cells form a phragmosome (PS), a cytoplasmic structure which contacts the cell cortex at the future division site. An experimental approach was used to find out at which time the plane of cell division becomes fixed: prior to or during the formation of a PS.When 3 day-old explants were divided into two parts by a longitudinal cut, a high percentage of the cells near the wound divided longitudinally. Cells which already had a PS at the time of wounding most often divided in the plane of the PS. Some of the cells with a non-longitudinal PS, however, formed a longitudinal cell wall after the replacement of the original PS by a longitudinal PS.The observations show that most cells which had not yet formed a PS could be induced to form a cell wall in a new direction. As soon as the formation of the PS had started, however, it became more difficult to induce a change in the plane of cell division. These results suggest that the division site is chosen during the formation of the PS.Abbreviations BMT band of microtubules - DIC differential interference contrast microscopy - l longitudinal - l-o longitudinal-oblique - MT microtubule - p periclinal - PM prometaphase - PPB preprophase band - PS phragmosome - t transverse - t-o transverse-oblique     

Arabidopsis thaliana MAP65-1 and MAP65-2 function redundantly with MAP65-3/PLEIADE in cytokinesis downstream of MPK4

Plant cytokinesis occurs by the growth of cell plates from the interior to the periphery of the cell. These dynamic events in cytokinesis are mediated by a plant-specific microtubule (MT) array called the phragmoplast, which consists of bundled antiparallel MTs between the two daughter nuclei. The NACK-PQR pathway, a NACK1 kinesin-like protein and mitogen activated protein kinase (MAPK) cascade, is a key regulator of plant cytokinesis through the regulation of phragmoplast MTs. The MT-associated protein MAP65 has been identified as one of the structural components of MT assays involved in cell division, and we recently showed that Arabidopsis AtMAP65-3/PLEIADE (PLE) is a substrate of MPK4 that is a component of the NACK-PQR pathway in Arabidopsis. Here we show that AtMAP65-1 and AtMAP65-2 are also phosphorylated by MPK4. AtMAP65-1 and AtMAP65-2 that localize to the phragmoplast were phosphorylated by MPK4 in vitro. Although mutants of the Arabidopsis AtMAP65-1 and AtMAP65-2 genes exhibited a wild-type phenotype, double mutations of AtMAP65-3 and AtMAP65-1 or AtMAP65-2 caused more severe growth and cytokinetic defects than the single atmap65-3/ple mutation. These results suggest that AtMAP65-1 and AtMAP65-2 also function in cytokinesis downstream of MPK4.Key words: MAP65, microtubule-associated protein, MAPK, cytokinesis, phragmoplast, microtubule, arabidopsisMitogen-activated protein kinase (MAPK) cascades are highly conserved signaling modules in eukaryotes, and are involved in various signaling processes in plant development, cell division and responses to endogenous or exogenous stimuli.¹ The NACK-PQR pathway, one of the best-characterized MAPK cascades in plants, has been identified as a key regulator of plant cytokinesis in tobacco. This pathway is composed of NPK1 MAPK kinase kinase (MAPKKK), NQK1/NtMEK1 MAPK kinase (MAPKK), NRK1/NTF6 MAPK and NACK1 kinesin-like protein, an activator of NPK1 MAPKKK.^2–5 During cytokinesis, all these components are localized on the equator of the phragmoplast, which is the plant-specific cytokinetic apparatus organized by microtubules (MTs). Downstream of this pathway, tobacco MAP65-1, an MT-associated protein, is phosphorylated by NRK1/NTF6 MAPK and phosphorylated MAP65-1 is localized to the equator of the phragmoplast.⁶ Phosphorylation of MAP65-1 by NRK1/NTF6 decreases the ability of MAP65-1 to bundle MTs, suggesting that the NACK-PQR pathway regulates expansion of the phragmoplast through the phosphorylation of MAP65.⁶The NACK-PQR pathway also seems to be conserved in Arabidopsis and rice. Several orthologs of components of the NACK-PQR pathway except for MAPK have been identified independently as regulators of cytokinesis in these plants.^3,5,7–14 Recently we reported that ANP MAPKKKs, MPK6/ANQ MAPKK and MPK4 MAPK biochemically constitute the MAPK pathway and HINKEL/AtNACK1 functions as an activator of ANP MAPKKKs.¹⁵ In addition, we revealed that MPK4 MAPK is localized to cell plates during cytokinesis, is required for cytokinesis in Arabidopsis and phosphorylates AtMAP65-3.¹⁶ Although AtMAP65-3 is proposed to be involved in cytokinesis,^17,18 and AtMAP65-1 is supposed to be a substrate of MPK4 based on a series of experiments,^6,19,20 the involvement in cytokinesis of other closely related members of the Arabidopsis MAP65 family, AtMAP65-1 and AtNAP65-2, has yet to be tested. In this report, we suggest redundant functions of these MAP65 molecules in cytokinesis of Arabidopsis.