Lukas von Tobel scite author profile

How living systems break symmetry in an organized manner is a fundamental question in biology. In wild-type Caenorhabditis elegans zygotes, symmetry breaking during anterior-posterior axis specification is guided by centrosomes, resulting in anterior-directed cortical flows and a single posterior PAR-2 domain. We uncover that C. elegans zygotes depleted of the Aurora A kinase AIR-1 or lacking centrosomes entirely usually establish two posterior PAR-2 domains, one at each pole. We demonstrate that AIR-1 prevents symmetry breaking early in the cell cycle, whereas centrosomal AIR-1 instructs polarity initiation thereafter. Using triangular microfabricated chambers, we establish that bipolarity of air-1(RNAi) embryos occurs effectively in a cell-shape and curvature-dependent manner. Furthermore, we develop an integrated physical description of symmetry breaking, wherein local PAR-2-dependent weakening of the actin cortex, together with mutual inhibition of anterior and posterior PAR proteins, provides a mechanism for spontaneous symmetry breaking without centrosomes.

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Analysis of centriole elimination duringC. elegansoogenesis

Mikeladze-Dvali

Tobel

Strnad

et al. 2012

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SUMMARYCentrosomes are the principal microtubule organizing centers (MTOCs) of animal cells and comprise a pair of centrioles surrounded by pericentriolar material (PCM). Centriole number must be carefully regulated, notably to ensure bipolar spindle formation and thus faithful chromosome segregation. In the germ line of most metazoan species, centrioles are maintained during spermatogenesis, but eliminated during oogenesis. Such differential behavior ensures that the appropriate number of centrioles is present in the newly fertilized zygote. Despite being a fundamental feature of sexual reproduction in metazoans, the mechanisms governing centriole elimination during oogenesis are poorly understood. Here, we investigate this question in C. elegans. Using antibodies directed against centriolar components and serial-section electron microscopy, we establish that centrioles are eliminated during the diplotene stage of the meiotic cell cycle. Moreover, we show that centriole elimination is delayed upon depletion of the helicase CGH-1. We also find that somatic cells make a minor contribution to this process, and demonstrate that the germ cell karyotype is important for timely centriole elimination. These findings set the stage for a mechanistic dissection of centriole elimination in a metazoan organism.

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Loss of serum response factor in keratinocytes results in hyperproliferative skin disease in mice

Koegel¹,

Tobel²,

Schäfer³

et al. 2009

J. Clin. Invest.

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The transcription factor serum response factor (SRF) plays a crucial role in the development of several organs. However, its role in the skin has not been explored. Here, we show that keratinocytes in normal human and mouse skin expressed high levels of SRF but that SRF expression was strongly downregulated in the hyperproliferative epidermis of wounded and psoriatic skin. Keratinocyte-specific deletion within the mouse SRF locus during embryonic development caused edema and skin blistering, and all animals died in utero. Postnatal loss of mouse SRF in keratinocytes resulted in the development of psoriasis-like skin lesions. These lesions were characterized by inflammation, hyperproliferation, and abnormal differentiation of keratinocytes as well as by disruption of the actin cytoskeleton. Ultrastructural analysis revealed markedly reduced cell-cell and cell-matrix contacts and loss of cell compaction in all epidermal layers. siRNA-mediated knockdown of SRF in primary human keratinocytes revealed that the cytoskeletal abnormalities and adhesion defects were a direct consequence of the loss of SRF. In contrast, the hyperproliferation observed in vivo was an indirect effect that was most likely a consequence of the inflammation. These results reveal that loss of SRF disrupts epidermal homeostasis and strongly suggest its involvement in the pathogenesis of hyperproliferative skin diseases, including psoriasis. IntroductionThe outermost layer of the skin is formed by the epidermis, a stratified squamous epithelium mainly consisting of keratinocytes. A remarkable property of the epidermis is its self-renewing capacity. Keratinocytes of the basal layer proliferate to generate new cells that differentiate and move upward. Terminally differentiated and metabolically inactive cells form a tightly linked sheet; they are continuously sloughed off from the surface and replaced by cells from the underlying layers (1). To maintain the balance between proliferation and differentiation, a tight spatial and temporal regulation of gene expression is essential. Therefore, it is of particular interest to identify and functionally characterize the transcription factors involved in the control of epidermal homeostasis.A promising new candidate in this regulation is serum response factor (SRF), a member of the highly conserved MADS box family of transcription factors (2, 3). SRF regulates the expression of immediate early genes (3-5) and of muscle-specific genes (reviewed in ref. 6) after binding to its target sequence (CArG box), which is often located within a serum response element. In fibroblasts, SRF-dependent gene transcription is controlled by 2 types of cofactors that are regulated by different signaling pathways. Cofactors of the myocardin-related transcription factor (MRTF) family can respond to Rho family GTPases and monomeric actin. The second class of SRF

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Paternally contributed centrioles exhibit exceptional persistence in C. elegans embryos

2015

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SAS-1 Is a C2 Domain Protein Critical for Centriole Integrity in C. elegans

et al. 2014

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Centrioles are microtubule-based organelles important for the formation of cilia, flagella and centrosomes. Despite progress in understanding the underlying assembly mechanisms, how centriole integrity is ensured is incompletely understood, including in sperm cells, where such integrity is particularly critical. We identified C. elegans sas-1 in a genetic screen as a locus required for bipolar spindle assembly in the early embryo. Our analysis reveals that sperm-derived sas-1 mutant centrioles lose their integrity shortly after fertilization, and that a related defect occurs when maternal sas-1 function is lacking. We establish that sas-1 encodes a C2 domain containing protein that localizes to centrioles in C. elegans, and which can bind and stabilize microtubules when expressed in human cells. Moreover, we uncover that SAS-1 is related to C2CD3, a protein required for complete centriole formation in human cells and affected in a type of oral-facial-digital (OFD) syndrome.

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Lukas von Tobel

Aurora A depletion reveals centrosome-independent polarization mechanism in Caenorhabditis elegans

Analysis of centriole elimination duringC. elegansoogenesis

Loss of serum response factor in keratinocytes results in hyperproliferative skin disease in mice

Paternally contributed centrioles exhibit exceptional persistence in C. elegans embryos

SAS-1 Is a C2 Domain Protein Critical for Centriole Integrity in C. elegans

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