Abstract is: Jeremy Patrick Brockes FRS (born 29 February 1948) is a British biochemist who worked as an MRC Research Professor at University College London until 2016.
human | Q5 |
P5463 | AE member ID | Brockes_Jeremy |
P5361 | BNB person ID | BrockesJeremy1948- |
P9985 | EMBO member ID | jeremy-brockes |
P2070 | Fellow of the Royal Society ID | 11144 |
P646 | Freebase ID | /m/0hnd5kt |
P1960 | Google Scholar author ID | hA7eZ4wAAAAJ |
P269 | IdRef ID | 168139294 |
P244 | Library of Congress authority ID | n82028508 |
P8189 | National Library of Israel J9U ID | 987007320790005171 |
P1006 | Nationale Thesaurus voor Auteursnamen ID | 132682052 |
P856 | official website | https://iris.ucl.ac.uk/iris/browse/profile?upi=JPBRO93 |
P496 | ORCID iD | 0000-0002-3395-5159 |
P3368 | Prabook ID | 2206842 |
P1153 | Scopus author ID | 7006470776 |
P214 | VIAF ID | 16108012 |
P10832 | WorldCat Entities ID | E39PBJgXdqrqTjRh8h7Xt73xXd |
P1026 | academic thesis | The DNA modification enzyme of bacteriophage P1 | Q56457524 |
P166 | award received | Fellow of the Royal Society | Q15631401 |
P27 | country of citizenship | United Kingdom | Q145 |
P69 | educated at | University of Edinburgh | Q160302 |
St John's College | Q691283 | ||
Winchester College | Q1059517 | ||
P108 | employer | University College London | Q193196 |
P734 | family name | Brocke | Q37249689 |
Brocke | Q37249689 | ||
Brocke | Q37249689 | ||
P735 | given name | Jeremy | Q1514341 |
Jeremy | Q1514341 | ||
P1412 | languages spoken, written or signed | English | Q1860 |
P463 | member of | Royal Society | Q123885 |
Academia Europaea | Q337234 | ||
P106 | occupation | biochemist | Q2919046 |
P21 | sex or gender | male | Q6581097 |
Q59595266 | A comparative study of gland cells implicated in the nerve dependence of salamander limb regeneration |
Q35855735 | A critical role for thrombin in vertebrate lens regeneration |
Q28604019 | A dynamic architecture of life |
Q46768381 | A single-cell analysis of myogenic dedifferentiation induced by small molecules |
Q41398179 | Amphibian limb regeneration: rebuilding a complex structure |
Q28597457 | An orphan gene is necessary for preaxial digit formation during salamander limb development |
Q28288420 | Appendage regeneration in adult vertebrates and implications for regenerative medicine |
Q40603452 | Cell differentiation. Muscle escapes from a jelly mould |
Q40908494 | Cell surface markers for distinguishing different types of rat dorsal root ganglion cells in culture |
Q37206211 | Comparative aspects of animal regeneration |
Q42615795 | Delta retinoic acid receptor isoform delta 1 is distinguished by its exceptional N-terminal sequence and abundance in the limb regeneration blastema |
Q52241034 | Developmental biology. Reading the retinoid signals. |
Q44962828 | Developmental biology. We may not have a morphogen |
Q45010879 | Distinctive expression of Myf5 in relation to differentiation and plasticity of newt muscle cells |
Q51867928 | Evidence for the local evolution of mechanisms underlying limb regeneration in salamanders. |
Q52210063 | Expression and activity of the newt Msx-1 gene in relation to limb regeneration. |
Q34152526 | Functional convergence of signalling by GPI-anchored and anchorless forms of a salamander protein implicated in limb regeneration |
Q59292821 | Generation of mononucleate cells from post-mitotic myotubes proceeds in the absence of cell cycle progression |
Q48353604 | Glial growth factor and nerve-dependent proliferation in the regeneration blastema of Urodele amphibians |
Q57843506 | Heterogeneous proliferative potential in regenerative adult newt cardiomyocytes |
Q44885518 | Identification of newt connective tissue growth factor as a target of retinoid regulation in limb blastemal cells |
Q28649711 | Identification of the orphan gene Prod 1 in basal and other salamander families |
Q32063104 | Immortalization of rat embryo fibroblasts by a 3'-untranslated region |
Q59595269 | Introduction |
Q37321749 | Introduction of a retinoid reporter gene into the urodele limb blastema |
Q59595274 | Mammalian postmitotic nuclei reenter the cell cycle after serum stimulation in newt/mouse hybrid myotubes |
Q59595260 | Mechanisms underlying vertebrate limb regeneration: lessons from the salamander |
Q24645387 | Molecular basis for the nerve dependence of limb regeneration in an adult vertebrate |
Q36672125 | Motif-grafted antibodies containing the replicative interface of cellular PrP are specific for PrPSc |
Q59595313 | Muscle disease at Durango |
Q38044518 | Nerve dependence in tissue, organ, and appendage regeneration |
Q40675044 | New approaches to amphibian limb regeneration |
Q42143247 | Newt myotubes reenter the cell cycle by phosphorylation of the retinoblastoma protein |
Q59595335 | Nucleotide sequences at the sites of action of the deoxyribonucleic acid modification enzyme of bacteriophage P1 |
Q34142489 | Plasticity and reprogramming of differentiated cells in amphibian regeneration |
Q44709036 | Plasticity of retrovirus-labelled myotubes in the newt limb regeneration blastema |
Q59595267 | Positional identity of adult stem cells in salamander limb regeneration |
Q53558299 | Preparation of cultured myofibers from larval salamander limbs for cellular plasticity studies. |
Q59595276 | Receptor isoform specificity in a cellular response to retinoic acid |
Q40763099 | Recurrent turnover of senescent cells during regeneration of a complex structure |
Q41738015 | Regeneration and cancer |
Q24678617 | Regeneration as an evolutionary variable |
Q36605451 | Regeneration, tissue injury and the immune response |
Q34375907 | Regulation of p53 is critical for vertebrate limb regeneration |
Q38374997 | Retinoids, homeobox genes, and limb morphogenesis |
Q40196840 | Schwann cell growth factors |
Q44441598 | Selective activation of thrombin is a critical determinant for vertebrate lens regeneration |
Q45108296 | Structure and expression of a newt cardio-skeletal myosin gene. Implications for the C value paradox |
Q41017233 | Studies on cultured rat Schwann cells. I. Establishment of purified populations from cultures of peripheral nerve |
Q40280914 | Studies on cultured rat Schwann cells. II. Comparison with a rat Schwann cell line |
Q59595294 | Studies on cultured rat Schwann cells. III. Assays for peripheral myelin proteins |
Q59595319 | Suppression of foreign synapses |
Q38971162 | Sustained ERK activation underlies reprogramming in regeneration-competent salamander cells and distinguishes them from their mammalian counterparts |
Q56457524 | The DNA modification enzyme of bacteriophage P1 |
Q34193660 | The Meis homeoprotein regulates the axolotl Prod 1 promoter during limb regeneration |
Q36587818 | The PML-retinoic acid receptor alpha translocation converts the receptor from an inhibitor to a retinoic acid-dependent activator of transcription factor AP-1 |
Q35170865 | The aneurogenic limb identifies developmental cell interactions underlying vertebrate limb regeneration |
Q59595275 | The expression pattern of tomoregulin-1 in urodele limb regeneration and mouse limb development |
Q59595280 | The monoclonal antibody 22/18 recognizes a conformational change in an intermediate filament of the newt,Notophthalmus viridescens, during limb regeneration |
Q44199567 | The newt ortholog of CD59 is implicated in proximodistal identity during amphibian limb regeneration |
Q24798730 | The regenerative plasticity of isolated urodele myofibers and its dependence on MSX1 |
Q59595272 | Thrombin Activation of S-Phase Reentry by Cultured Pigmented Epithelial Cells of Adult Newt Iris |
Q33872717 | Thrombin regulates S-phase re-entry by cultured newt myotubes |
Q34112234 | Tissue factor expression in newt iris coincides with thrombin activation and lens regeneration |
Q33745335 | Topics in prion cell biology |
Q40739845 | Transfer of scrapie prion infectivity by cell contact in culture |
Q39032881 | Variation in salamanders: an essay on genomes, development, and evolution |
Jeremy Brockes | wikipedia |
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