Your search keyword '"meis"' showing total 7 results

1. MEIS transcription factors in development and disease.

Author

Schulte, Dorothea and Geerts, Dirk

Subjects

*TRANSCRIPTION factors, *GENE expression, *CARCINOGENESIS, *STEM cells, *DISEASES

Abstract

MEIStranscription factors are key regulators ofembryonic development and cancer. Research on MEIS genes in the embryo and in stem cell systems has revealed novel and surprisingmechanisms bywhich these proteins control gene expression. This Primer summarizes recent findings aboutMEIS protein activity and regulation in development, and discusses new insights into the role ofMEIS genes in disease, focusing on the pathogenesis of solid cancers. [ABSTRACT FROM AUTHOR]

Published

2019

2. RING1 proteins contribute to early proximal-distal specification of the forelimb bud by restricting Meis2 expression.

Author

Nayuta Yakushiji-Kaminatsui, Takashi Kondo, Endo, Takaho A., Yoko Koseki, Kaori Kondo, Osamu Ohara, Vidal, Miguel, and Haruhiko Koseki

Subjects

*POLYCOMB group proteins, *PROTEIN precursors, *CELL differentiation, *LABORATORY mice, *FORELIMB

Abstract

Polycomb group (PcG) proteins play a pivotal role in silencing developmental genes and help to maintain various stem and precursor cells and regulate their differentiation. PcG factors also regulate dynamic and complex regional specification, particularly in mammals, but this activity is mechanistically not well understood. In this study, we focused on proximal-distal (PD) patterning of the mouse forelimb bud to elucidate how PcG factors contribute to a regional specification process that depends on developmental signals. Depletion of the RING1 proteins RING1A (RING1) and RING1B (RNF2), which are essential components of Polycomb repressive complex 1 (PRC1), led to severe defects in forelimb formation along the PD axis. We show that preferential defects in early distal specification in Ring1A/B-deficient forelimb buds accompany failures in the repression of proximal signal circuitry bound by RING1B, including Meis1/2, and the activation of distal signal circuitry in the prospective distal region. Additional deletion of Meis2 induced partial restoration of the distal gene expression and limb formation seen in the Ring1A/B-deficient mice, suggesting a crucial role for RING1-dependent repression of Meis2 and likely also Meis1 for distal specification. We suggest that the RING1-MEIS1/2 axis is regulated by early PD signals and contributes to the initiation or maintenance of the distal signal circuitry. [ABSTRACT FROM AUTHOR]

Published

2016

3. Diffusible signals and epigenetic timing cooperate in late proximo-distal limb patterning.

Author

Roselló-Díez, Alberto, Arques, Carlos G., Delgado, Irene, Giovinazzo, Giovanna, and Torres, Miguel

Subjects

*EPIGENETICS, *GENE expression, *GENETIC regulation, *HISTONE acetylation, *POSITION effect (Genetics), *HISTONE acetyltransferase, *CONGENITAL disorders

Abstract

Developing vertebrate limbs initiate proximo-distal patterning by interpreting opposing gradients of diffusible signaling molecules. We report two thresholds of proximo-distal signals in the limb bud: a higher threshold that establishes the upper-arm to forearm transition; and a lower one that positions a later transition from forearm to hand. For this last transition to happen, however, the signal environment seems to be insufficient, and we show that a timing mechanism dependent on histone acetylation status is also necessary. Therefore, as a consequence of the time dependence, the lower signaling threshold remains cryptic until the timing mechanism reveals it. We propose that this timing mechanism prevents the distal transition from happening too early, so that the prospective forearm has enough time to expand and form a properly sized segment. Importantly, the gene expression changes provoked by the first transition further regulate proximo-distal signal distribution, thereby coordinating the positioning of the two thresholds, which ensures robustness. This model is compatible with the most recent genetic analyses and underscores the importance of growth during the time-dependent patterning phase, providing a new mechanistic framework for understanding congenital limb defects. [ABSTRACT FROM AUTHOR]

Published

2014

4. Connective tissue cells, but not muscle cells, are involved in establishing the proximo-distal outcome of limb regeneration in the axolotl.

Author

Nacu, Eugen, Glausch, Mareen, Huy Quang Le, Rochel Damanik, Febriyani Fiain, Schuez, Maritta, Knapp, Dunja, Khattak, Shahryar, Richter, Tobias, and Tanaka, Elly M.

Subjects

*MUSCLE cells, *LIMB regeneration, *AXOLOTLS, *COLLAGEN, *CONNECTIVE tissues

Abstract

During salamander limb regeneration, only the structures distal to the amputation plane are regenerated, a property known as the rule of distal transformation. Multiple cell types are involved in limb regeneration; therefore, determining which cell types participate in distal transformation is important for understanding how the proximo-distal outcome of regeneration is achieved. We show that connective tissue-derived blastema cells obey the rule of distal transformation. They also have nuclear MEIS, which can act as an upper arm identity regulator, only upon upper arm amputation. By contrast, myogenic cells do not obey the rule of distal transformation and display nuclear MEIS upon amputation at any proximo-distal level. These results indicate that connective tissue cells, but not myogenic cells, are involved in establishing the proximo-distal outcome of regeneration and are likely to guide muscle patterning. Moreover, we show that, similarly to limb development, muscle patterning in regeneration is influenced by β-catenin signalling. [ABSTRACT FROM AUTHOR]

Published

2013

5. A hindbrain-repressive Wnt3a/Meis3/Tsh1 circuit promotes neuronal differentiation and coordinates tissue maturation.

Author

Elkouby, Yaniv M., Polevoy, Hanna, Gutkovich, Yoni E., Michaelov, Ariel, and Frank, Dale

Subjects

*RHOMBENCEPHALON, *WNT genes, *THYROTROPIN, *NEURONS, *CELL differentiation, *XENOPUS laevis, *TRANSCRIPTION factors

Abstract

During development, early inducing programs must later be counterbalanced for coordinated tissue maturation. In Xenopus laevis embryos, activation of the Meis3 transcription factor by a mesodermal Wnt3a signal lies at the core of the hindbrain developmental program. We now identify a hindbrain restricting circuit, surprisingly comprising the hindbrain inducers Wnt3a and Meis3, and Tsh1 protein. Functional and biochemical analyses show that upon Tsh1 induction by strong Wnt3a/Meis3 feedback loop activity, the Meis3-Tsh1 transcription complex represses the Meis3 promoter, allowing cell cycle exit and neuron differentiation. Meis3 protein exhibits a conserved dual-role in hindbrain development, both inducing neural progenitors and maintaining their proliferative state. In this regulatory circuit, the Tsh1 co-repressor controls transcription factor gene expression that modulates cell cycle exit, morphogenesis and differentiation, thus coordinating neural tissue maturation. This newly identified Wnt/Meis/Tsh circuit could play an important role in diverse developmental and disease processes. [ABSTRACT FROM AUTHOR]

Published

2012

6. Prep1.1 has essential genetic functions in hindbrain development and cranial neural crest cell differentiation.

Author

Deflorian, Gianluca, Tiso, Natascia, Ferretti, Elisabetta, Meyer, Dirk, Blasi, Francesco, Bortolussi, Marino, and Argenton, Francesco

Subjects

*GENES, *DNA, *PROTEINS, *FERTILIZATION (Biology), *CELLS, *PHARYNX, *CHONDROGENESIS

Abstract

In this study we analysed the function of the Meinox gene prep1.1 during zebrafish development. Meinox proteins form heterotrimeric complexes with Hox and Pbx members, increasing the DNA binding specificity of Hox proteins in vitro and in vivo. However, a role for a specific Meinox protein in the regulation of Hox activity in vivo has not been demonstrated. In situ hybridization showed that prep1.1 is expressed maternally and ubiquitously up to 24 hours post-fertilization (hpf), and restricted to the head from 48 hpf onwards. Morpholino-induced prep1.1 lossof-function caused significant apoptosis in the CNS. Hindbrain segmentation and patterning was affected severely, as revealed by either loss or defective expression of several hindbrain markers (foxb1.2/mariposa, krox20, pax2.1 and pax6.1), including anteriorly expressed Hox genes (hoxbla, hoxa2 and hoxb2), the impaired migration of facial nerve motor neurons, and the lack of reticulospinal neurons (RSNs) except Mauthner cells. Furthermore, the heads of prep1.1 morphants lacked all pharyngeal cartilages. This was not caused by the absence of neural crest cells or their impaired migration into the pharyngeal arches, as shown by expression of dlx2 and snail1, but by the inability of these cells to differentiate into chondroblasts. Our results indicate that prepl.1 has a unique genetic function in craniofacial chondrogenesis and, acting as a member of Meinox-Pbc-Hox trimers, it plays an essential role in hindbrain development. [ABSTRACT FROM AUTHOR]

Published

2004

7. Evidence for an evolutionary conserved role of homothorax/Meis1/2 during vertebrate retina development.

Author

Heine, Peer, Dohle, Eva, Bumsted-O'Brien, Keely, Engelkamp, Dieter, and Schulte, Dorothea

Subjects

*PROTEINS, *RETINA, *CELLS, *VERTEBRATES, *CHICKS, *MICE

Abstract

During eye development, retinal progenitors are drawn from a multipotent, proliferative cell population. In Drosophila the maintenance of this cell population requires the function of the TALE-homeodomain transcription factor Hth, although its mechanisms of action are still unknown. Here we investigate whether members of the Meis gene family, the vertebrate homologs of hth, are also involved in early stages of eye development in the zebrafish. We show that meis1 is initially expressed throughout the eye primordium. Later, meis1 becomes repressed as neurogenesis is initiated, and its expression is confined to the ciliary margin, where the retinal stem population resides. Knocking down meis1 function through morpholino injection causes a delay in the G1-to-S phase transition of the eye cells, and results in severely reduced eyes. This role in cell cycle control is mediated by meis1 regulating cyclin D1 and c-myc transcription. The forced maintenance of meis1 expression in cell clones is incompatible with the normal differentiation of the meis1-expressing cells, which in turn tend to reside in undifferentiated regions of the retinal neuroepithelium, such as the ciliary margin. Together, these results implicate meis1 as a positive cell cycle regulator in early retinal cells, and provide evidence of an evolutionary conserved function for Hth/Meis genes in the maintenance of the proliferative, multipotent cell state during early eye development. [ABSTRACT FROM AUTHOR]

Published

2008