Celia Antonio scite author profile

Metaphase chromosome alignment is a key step of animal cell mitosis. The molecular mechanism leading to this equatorial positioning is still not fully understood. Forces exerted at kinetochores and on chromosome arms drive chromosome movements that culminate in their alignment on the metaphase plate. In this paper, we show that Xkid, a kinesin-like protein localized on chromosome arms, plays an essential role in metaphase chromosome alignment and in its maintenance. We propose that Xkid is responsible for the polar ejection forces acting on chromosome arms. Our results show that these forces are essential to ensure that kinetochores and chromosome arms align on a narrow equatorial plate during metaphase, a prerequisite for proper chromosome segregation.

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Genetic Screens forCaenorhabditis elegansMutants Defective in Left/Right Asymmetric Neuronal Fate Specification

Sarin¹,

O'Meara²,

Flowers³

et al. 2007

110

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We describe here the results of genetic screens for Caenorhabditis elegans mutants in which a single neuronal fate decision is inappropriately executed. In wild-type animals, the two morphologically bilaterally symmetric gustatory neurons ASE left (ASEL) and ASE right (ASER) undergo a left/right asymmetric diversification in cell fate, manifested by the differential expression of a class of putative chemoreceptors and neuropeptides. Using single cell-specific gfp reporters and screening through a total of almost 120,000 haploid genomes, we isolated 161 mutants that define at least six different classes of mutant phenotypes in which ASEL/R fate is disrupted. Each mutant phenotypic class encompasses one to nine different complementation groups. Besides many alleles of 10 previously described genes, we have identified at least 16 novel ''lsy'' genes (''laterally symmetric''). Among mutations in known genes, we retrieved four alleles of the miRNA lsy-6 and a gain-of-function mutation in the 39-UTR of a target of lsy-6, the cog-1 homeobox gene. Using newly found temperature-sensitive alleles of cog-1, we determined that a bistable feedback loop controlling ASEL vs. ASER fate, of which cog-1 is a component, is only transiently required to initiate but not to maintain ASEL and ASER fate. Taken together, our mutant screens identified a broad catalog of genes whose molecular characterization is expected to provide more insight into the complex genetic architecture of a left/right asymmetric neuronal cell fate decision.A PART from expressing a core set of features that distinguish neuronal from nonneuronal cell types, individual cell types in the nervous system express distinct batteries of genes that generate the structural and functional diversity of neuronal cell types. The diversification of cell fate in the developing nervous system presumably relies on the interplay of a host of regulatory factors. Screens for mutant animals defective in neuronal fate specification provide a powerful and unbiased approach to identify these regulatory factors. Such screens have been successfully conducted in various model systems, most prominently flies and worms, yielding valuable insights into the molecular mechanisms that control neuronal fate specification. We describe here genetic screens for neuronal fate mutants in the nematode Caenorhabditis elegans that focus on a cell fate decision executed by a single neuron class, the ASE gustatory neurons. This neuron class is composed of two morphologically bilaterally symmetric neurons, ASE We have previously reported the identification of mutants that affect the development of the left/right asymmetry of the ASE neurons (Chang et al. 2003; Hobert 2003, 2005;Johnston et al. 2006). These mutants, which we termed lsy mutants (for laterally symmetric) to indicate their role in controlling the fate of two left/right asymmetric neurons, fell into four distinct classes ( Figure 1A). In class I mutants, both ASE neurons adopt the fate of the ASEL neuron, with a concomitant loss of ASE...

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TheC. elegansTailless/TLX transcription factornhr-67controls neuronal identity and left/right asymmetric fate diversification

Sarin

Antonio

Tursun

et al. 2009

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An understanding of the molecular mechanisms of cell fate determination in the nervous system requires the elucidation of transcriptional regulatory programs that ultimately control neuron-type-specific gene expression profiles. We show here that the C. elegans Tailless/TLX-type, orphan nuclear receptor NHR-67 acts at several distinct steps to determine the identity and subsequent left/right (L/R) asymmetric subtype diversification of a class of gustatory neurons, the ASE neurons. nhr-67 controls several broad aspects of sensory neuron development and, in addition, triggers the expression of a sensory neuron-type-specific selector gene, che-1, which encodes a zinc-finger transcription factor. Subsequent to its induction of overall ASE fate, nhr-67 diversifies the fate of the two ASE neurons ASEL and ASER across the L/R axis by promoting ASER and inhibiting ASEL fate. This function is achieved through direct expression activation by nhr-67 of the Nkx6-type homeobox gene cog-1, an inducer of ASER fate, that is inhibited in ASEL through the miRNA lsy-6. Besides controlling bilateral and asymmetric aspects of ASE development, nhr-67 is also required for many other neurons of diverse lineage history and function to appropriately differentiate, illustrating the broad and diverse use of this type of transcription factor in neuronal development.

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Xkid chromokinesin is required for the meiosis I to meiosis II transition in Xenopus laevis oocytes

Perez

Antonio

Flament³

et al. 2002

Nat Cell Biol

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Xkid chromokinesin is required for chromosome alignment on the metaphase plate of spindles formed in Xenopus laevis egg extracts. We have investigated the role of Xkid in Xenopus oocyte meiotic maturation, a progesterone-triggered process that reinitiates the meiotic cell cycle in oocytes arrested at the G2/M border of meiosis I. Here we show that Xkid starts to accumulate at the time of germinal vesicle breakdown and reaches its largest quantities at metaphase II in oocytes treated with progesterone. Both germinal vesicle breakdown and spindle assembly at meiosis I can occur normally in the absence of Xkid. But Xkid-depleted oocytes cannot reactivate Cdc2/cyclin B after meiosis I and, instead of proceeding to meiosis II, they enter an interphase-like state and undergo DNA replication. Expression of a Xkid mutant that lacks the DNA-binding domain allows Xkid-depleted oocytes to complete meiotic maturation. Our results show that Xkid has a role in the meiotic cell cycle that is independent from its role in metaphase chromosome alignment.

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Celia Antonio

Xkid, a Chromokinesin Required for Chromosome Alignment on the Metaphase Plate

Genetic Screens forCaenorhabditis elegansMutants Defective in Left/Right Asymmetric Neuronal Fate Specification

TheC. elegansTailless/TLX transcription factornhr-67controls neuronal identity and left/right asymmetric fate diversification

Xkid chromokinesin is required for the meiosis I to meiosis II transition in Xenopus laevis oocytes

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