Cristina Pérez-Sánchez scite author profile

Rho GTPases control cytoskeletal dynamics through cytoplasmic effectors, and regulate transcriptional activation by the Myocardin Related Transcription Factors (MRTFs), coactivators for Serum Response Factor (SRF). We used RNAi to investigate the contribution of the MRTF-SRF pathway to cytoskeletal dynamics in MDA-MB-231 breast carcinoma and B16F2 melanoma cells, where basal MRTF-SRF activity is Rho-dependent. Depletion of MRTFs or SRF reduces cell adhesion, spreading, invasion and motility in culture, without affecting proliferation or inducing apoptosis; MRTF-depleted tumor cell xenografts exhibit reduced cell motility but proliferate normally. MRTF- and SRF-depleted tumor cells fail to colonise the lung from the bloodstream, being unable to persist following their initial arrival at the lung. Only a few genes exhibit MRTF-dependent expression in both cell lines. Two of these, MYH9 (MLC2) and MYL9 (NMHCIIa), are also required for invasion and lung colonisation. Conversely, expression of an activated MRTF increases lung colonisation by poorly metastatic B16F0 cells. Actin-based cell behaviour and experimental metastasis thus requires Rho-dependent nuclear signalling through the MRTF-SRF network.

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Evaluation of Trichoderma harzianum for controlling root rot caused by Phytophthora capsici in pepper plants

Ahmed

Pérez-Sánchez

Egea

et al. 1999

Plant Pathology

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The ability of Trichoderma harzianum to control the rotting of pepper (Capsicum annuum) plant roots caused by Phytophthora capsici was studied. Interactions between the fungi were assessed in vitro on three culture media (V8c, Czapek and 2% water agar) and in vivo in plants grown in a substrate inoculated with P. capsici and T. harzianum. Studies on mutual antagonism in vitro showed that P. capsici was inhibited by T. harzianum; however, the intensity of inhibition differed according to the medium used, being greatest on Czapek. Analysis of the fungal populations in the plant growth substrate showed that T. harzianum consistently reduced that of P. capsici over time. This reduction in the pathogen population was associated with a reduction in root rot of between 24 and 76%, although plant growth (dry weight) was still reduced by 21·2-24·7%, compared with the uninoculated control. In the absence of T. harzianum with the same pathogen inoculum levels, the reduction in dry weight was 59·8-68·6%, suggesting that T. harzianum reduced the damage.

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FHX, a Novel Fork Head Factor with a Dual DNA Binding Specificity

Pérez-Sánchez¹,

Gómez-Ferrerı́a²,

Fuente³

et al. 2000

Journal of Biological Chemistry

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The HNF3/fork head family includes a large number of transcription factors that share a structurally related DNA binding domain. Fork head factors have been shown to play important roles both during development and in the adult. We now describe the cloning of a novel mammalian fork head factor that we have named FHX (fork head homologous X (FHX), which is expressed in many adult tissues. In the embryo, FHX expression showed a very early onset during the cleavage stages of preimplantation development. Polymerase chain reaction-assisted site selection experiments showed that FHX bound DNA with a dual sequence specificity. Sites recognized by FHX could be classified into two different types according to their sequences. Binding of FHX to sequences of each type appeared to occur independently. Our data suggest that either different regions of the fork head domain or different molecular forms of this domain could be involved in binding of FHX to each type of site. In transfection assays, FHX was capable of activating transcription from promoters containing FHX sites of either type.The regulated expression of the genome is essential for the homeostatic maintenance and correct cell differentiation and morphogenesis of an organism. Transcription factors play a preponderant role in this regard. From an evolutionary standpoint, all transcription factors derive from a small set of primitive factors. These, upon successive gene duplication-divergence events and fusion with other genes or parts of genes, have given rise to the whole panoply of extant transcription factors. Consequently, current transcription factors may be sorted into different families according to their homology relationships. One of these families, which appears to have been highly successful in evolution, is the fork head/HNF3 family, with known members in species from yeast to humans, with the striking exception of green plants, where no fork head factor has been described so far (for a review, see Ref.

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