human | Q5 |
P6178 | Dimensions author ID | 0632446221.51 |
P856 | official website | http://iris.ucl.ac.uk/iris/browse/profile?upi=RMAYO52 |
P496 | ORCID iD | 0000-0001-9053-9613 |
P1153 | Scopus author ID | 7003927871 |
P108 | employer | University College London | Q193196 |
P734 | family name | Mayor | Q6797626 |
Mayor | Q6797626 | ||
Mayor | Q6797626 | ||
P735 | given name | Roberto | Q15905580 |
Roberto | Q15905580 | ||
P106 | occupation | researcher | Q1650915 |
P21 | sex or gender | male | Q6581097 |
Q52086392 | A balance between the anti-apoptotic activity of Slug and the apoptotic activity of msx1 is required for the proper development of the neural crest. |
Q46385490 | A new role for the Endothelin-1/Endothelin-A receptor signaling during early neural crest specification |
Q52164554 | A novel function for the Xslug gene: control of dorsal mesendoderm development by repressing BMP-4. |
Q41886607 | A novel method to study contact inhibition of locomotion using micropatterned substrates |
Q37201465 | A role for Syndecan-4 in neural induction involving ERK- and PKC-dependent pathways |
Q46264411 | Animal models for studying neural crest development: is the mouse different? |
Q50675996 | Beads on the run: beads as alternative tools for chemotaxis assays. |
Q27308929 | Ca2+/H+ exchange by acidic organelles regulates cell migration in vivo. |
Q36004847 | Cadherin Switch during EMT in Neural Crest Cells Leads to Contact Inhibition of Locomotion via Repolarization of Forces |
Q27333540 | Cadherin-11 mediates contact inhibition of locomotion during Xenopus neural crest cell migration |
Q41825411 | Cadherin-11 regulates protrusive activity in Xenopus cranial neural crest cells upstream of Trio and the small GTPases. |
Q38040276 | Cadherins in collective cell migration of mesenchymal cells |
Q43777073 | Calcium mediates dorsoventral patterning of mesoderm in Xenopus |
Q37978501 | Can mesenchymal cells undergo collective cell migration? The case of the neural crest |
Q30488942 | Cell communication with the neural plate is required for induction of neural markers by BMP inhibition: evidence for homeogenetic induction and implications for Xenopus animal cap and chick explant assays. |
Q41849676 | Cell traction in collective cell migration and morphogenesis: the chase and run mechanism |
Q27313434 | Chase-and-run between adjacent cell populations promotes directional collective migration |
Q38714872 | Chemotaxis during neural crest migration. |
Q26771268 | Collective cell migration in development |
Q38073630 | Collective cell migration of epithelial and mesenchymal cells |
Q37820947 | Collective cell migration of the cephalic neural crest: the art of integrating information |
Q42158276 | Collective chemotaxis requires contact-dependent cell polarity. |
Q35738200 | Complement fragment C3a controls mutual cell attraction during collective cell migration |
Q38305679 | Connexins in migration during development and cancer |
Q34902880 | Contact inhibition of locomotion in vivo controls neural crest directional migration |
Q27302883 | Control of the collective migration of enteric neural crest cells by the Complement anaphylatoxin C3a and N-cadherin |
Q37036244 | Delamination of neural crest cells requires transient and reversible Wnt inhibition mediated by Dact1/2 |
Q47679570 | Development of cytoskeletal connections between cells of preimplantation mouse embryos |
Q52180357 | Development of neural crest in Xenopus. |
Q42067316 | Differential requirements of BMP and Wnt signalling during gastrulation and neurulation define two steps in neural crest induction |
Q43190503 | Directional cell migration in vivo: Wnt at the crest |
Q27315012 | Directional collective cell migration emerges as a property of cell interactions |
Q46651779 | Directional migration of neural crest cells in vivo is regulated by Syndecan-4/Rac1 and non-canonical Wnt signaling/RhoA. |
Q48095335 | Distinct elements of the xsna promoter are required for mesodermal and ectodermal expression |
Q40803704 | Early neural crest induction requires an initial inhibition of Wnt signals. |
Q38367023 | Embryonic cell-cell adhesion: a key player in collective neural crest migration. |
Q52051294 | Essential role of non-canonical Wnt signalling in neural crest migration. |
Q52222450 | Expression of Xenopus snail in mesoderm and prospective neural fold ectoderm. |
Q34988700 | Extracellular signals, cell interactions and transcription factors involved in the induction of the neural crest cells. |
Q28972581 | Forcing contact inhibition of locomotion |
Q51980022 | Galphaq negatively regulates the Wnt-beta-catenin pathway and dorsal embryonic Xenopus laevis development. |
Q36220839 | Genetic network during neural crest induction: from cell specification to cell survival. |
Q92000384 | Guidelines and definitions for research on epithelial-mesenchymal transition |
Q52095654 | Identification of neural crest competence territory: role of Wnt signaling. |
Q30583159 | In vivo collective cell migration requires an LPAR2-dependent increase in tissue fluidity |
Q30768498 | In vivo confinement promotes collective migration of neural crest cells. |
Q52209849 | Induction of the prospective neural crest of Xenopus. |
Q74590764 | Inhibition of mesoderm formation by follistatin |
Q28585667 | Inhibition of neural crest migration underlies craniofacial dysmorphology and Hirschsprung's disease in Bardet-Biedl syndrome |
Q41786672 | Integrating chemotaxis and contact-inhibition during collective cell migration: Small GTPases at work |
Q44697354 | Interplay between Notch signaling and the homeoprotein Xiro1 is required for neural crest induction in Xenopus embryos. |
Q34110673 | Keeping in touch with contact inhibition of locomotion |
Q40058106 | Kremen is required for neural crest induction in Xenopus and promotes LRP6-mediated Wnt signaling. |
Q30557898 | Lamellipodin and the Scar/WAVE complex cooperate to promote cell migration in vivo |
Q38809848 | Modelling collective cell migration of neural crest. |
Q38575876 | Molecular basis of contact inhibition of locomotion |
Q72430482 | Morulae at compaction and the pattern of protein synthesis in mouse embryos |
Q42050037 | Mutual repression between Gbx2 and Otx2 in sensory placodes reveals a general mechanism for ectodermal patterning. |
Q30411299 | Neural crest and placode interaction during the development of the cranial sensory system |
Q37977230 | Neural crest delamination and migration: from epithelium-to-mesenchyme transition to collective cell migration |
Q52200484 | Neural crest formation in Xenopus laevis: mechanisms of Xslug induction. |
Q38117104 | Neural crest migration: interplay between chemorepellents, chemoattractants, contact inhibition, epithelial-mesenchymal transition, and collective cell migration |
Q64099416 | Neural crest streaming as an emergent property of tissue interactions during morphogenesis |
Q51979531 | Neural crests are actively precluded from the anterior neural fold by a novel inhibitory mechanism dependent on Dickkopf1 secreted by the prechordal mesoderm. |
Q41189362 | PDGF controls contact inhibition of locomotion by regulating N-cadherin during neural crest migration. |
Q30557444 | Par3 controls neural crest migration by promoting microtubule catastrophe during contact inhibition of locomotion |
Q43849682 | Posteriorization by FGF, Wnt, and retinoic acid is required for neural crest induction |
Q46878591 | Rediscovering contact inhibition in the embryo. |
Q50670938 | Regulation of XSnail2 expression by Rho GTPases. |
Q52166292 | Relationship between gene expression domains of Xsnail, Xslug, and Xtwist and cell movement in the prospective neural crest of Xenopus. |
Q46777853 | Ric-8A, a guanine nucleotide exchange factor for heterotrimeric G proteins, is critical for cranial neural crest cell migration. |
Q47073604 | Role of BMP signaling and the homeoprotein Iroquois in the specification of the cranial placodal field |
Q52192891 | Role of FGF and noggin in neural crest induction. |
Q96640902 | SPIN90 associates with mDia1 and the Arp2/3 complex to regulate cortical actin organization |
Q52111064 | Snail precedes slug in the genetic cascade required for the specification and migration of the Xenopus neural crest. |
Q47073571 | Snail1a and Snail1b cooperate in the anterior migration of the axial mesendoderm in the zebrafish embryo |
Q38352189 | Sox10 is required for the early development of the prospective neural crest in Xenopus embryos. |
Q58591055 | Supracellular contraction at the rear of neural crest cell groups drives collective chemotaxis |
Q93110440 | Supracellular migration - beyond collective cell migration |
Q30276831 | The Molecular Basis of Radial Intercalation during Tissue Spreading in Early Development |
Q38685677 | The front and rear of collective cell migration. |
Q48646454 | The homeoprotein Xiro1 is required for midbrain-hindbrain boundary formation. |
Q30540087 | The hypoxia factor Hif-1α controls neural crest chemotaxis and epithelial to mesenchymal transition |
Q47862681 | The inductive properties of mesoderm suggest that the neural crest cells are specified by a BMP gradient |
Q56907244 | The neural crest |
Q38350690 | The posteriorizing gene Gbx2 is a direct target of Wnt signalling and the earliest factor in neural crest induction |
Q38170173 | The role of the non-canonical Wnt-planar cell polarity pathway in neural crest migration |
Q51947640 | Wnt11r is required for cranial neural crest migration. |
Q47976544 | Xenopus brain factor-2 controls mesoderm, forebrain and neural crest development |
Q42636249 | Xenopus paraxis homologue shows novel domains of expression |
Q41976395 | Xiro, a Xenopus homolog of the Drosophila Iroquois complex genes, controls development at the neural plate |
Q52126470 | Xiro-1 controls mesoderm patterning by repressing bmp-4 expression in the Spemann organizer. |
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