about
A family of transmembrane proteins with homology to the MET-hepatocyte growth factor receptorCloning and characterization of two members of the vertebrate Dlx gene familyEMX1 homeoprotein is expressed in cell nuclei of the developing cerebral cortex and in the axons of the olfactory sensory neuronsPaclitaxel loading in PLGA nanospheres affected the in vitro drug cell accumulation and antiproliferative activity.CD200 expression in patients with Multiple Myeloma: another piece of the puzzle.Otx genes and the genetic control of brain morphogenesis.Genetic and molecular roles of Otx homeodomain proteins in head development.Gene expression analysis of PTEN positive glioblastoma stem cells identifies DUB3 and Wee1 modulation in a cell differentiation modelResistance of papillary thyroid cancer stem cells to chemotherapy.Bone augmentation after ectopic implantation of a cell-free collagen-hydroxyapatite scaffold in the mouse.MicroRNA and pediatric tumors: Future perspectives.Combination of Collagen-Based Scaffold and Bioactive Factors Induces Adipose-Derived Mesenchymal Stem Cells Chondrogenic Differentiation In vitro.Disulfiram, an old drug with new potential therapeutic uses for human hematological malignancies.NF-κB localization in multiple myeloma plasma cells and mesenchymal cells.Proteasome inhibitors synergize with tumor necrosis factor-related apoptosis-induced ligand to induce anaplastic thyroid carcinoma cell death.Lyoprotected nanosphere formulations for paclitaxel controlled delivery.Homeobox genes in the developing central nervous system.Novel Mechanisms of Spinal Cord Plasticity in a Mouse Model of Motoneuron Disease.Human adipose-derived mesenchymal stem cells seeded into a collagen-hydroxyapatite scaffold promote bone augmentation after implantation in the mouse.Tangential migration of cells from the basal to the dorsal telencephalic regions in the chick.Antitumor activity of bortezomib alone and in combination with TRAIL in human acute myeloid leukemia.In Vivo Evaluation of Biocompatibility and Chondrogenic Potential of a Cell-Free Collagen-Based Scaffold.Noggin and Sonic hedgehog are involved in compensatory changes within the motoneuron-depleted mouse spinal cord.cDNA sequence, map, and expression of the murine homolog of GTBP, a DNA mismatch repair gene.Involvement of brain-derived neurotrophic factor and sonic hedgehog in the spinal cord plasticity after neurotoxic partial removal of lumbar motoneurons.Neocortical neurons: where do they come from?Branchial HOX gene expression and human craniofacial development.Cx36 is dynamically expressed during early development of mouse brain and nervous system.Connexins in the Central Nervous System: Physiological Traits and Neuroprotective Targets.TDP-43 as a Modulator of Synaptic Plasticity in a Mouse Model of Spinal Motoneuron Degeneration.c-otx2 is expressed in two different phases of gastrulation and is sensitive to retinoic acid treatment in chick embryo.The PU.1 transcription factor induces cyclin D2 expression in U937 cellsBlocking the APRIL circuit enhances acute myeloid leukemia cell chemosensitivityNeuromuscular Plasticity in a Mouse Neurotoxic Model of Spinal Motoneuronal LossClobetasol Modulates Adult Neural Stem Cell Growth via Canonical Hedgehog Pathway ActivationThe branchial Hox code and its implications for gene regulation, patterning of the nervous system and head evolutionConserved homeobox genes in the developing brainExpression of connexin36 mRNA in adult rodent brainExpression of HOX homeobox genes in the adult human colonic mucosa (and colorectal cancer?)Expression of cell fate determinants and plastic changes after neurotoxic lesion of adult mice spinal cord by cholera toxin-B saporin
P50
Q24318269-476B8EE8-D578-4798-AE0E-E743F5A678C9Q24318837-60F70583-51C9-46E5-8CEA-3C09A81F7A97Q28292374-EB09C1B4-13E8-4CC9-8484-4AF74BE68006Q33355378-333BF66F-2F4A-4E2A-BF59-1D290EFF405CQ33356849-67EB64B4-F6A7-4B6A-9C22-8E287302104EQ33537177-B03CB47F-C6B0-478D-855D-E89A467FC3B2Q33892762-2D285B0C-9E6E-4FB4-8DF9-0D1F40CCB261Q35069587-65ACE6BD-1525-4067-8D02-11C5FD7E7F5EQ37002770-58AE1669-F6E9-436E-BDC6-F4B9DF05CEC3Q37399638-7EE354CB-5F1D-419A-9179-94E98022719CQ38375692-1CB1CFD3-8F7B-4E1B-9A00-F4641333183CQ38956250-D4821425-98F1-47F8-BC56-CD1F8E897812Q39398672-9A462302-E4E4-4959-A739-31B2EE16175BQ39673309-6565A59C-CF1E-490F-AE95-1E7C0F75E315Q40165719-6B9EFFD2-2F14-4D08-90DE-7F7555A28373Q40218727-EE768036-CD94-47E5-90A4-ACC9ADE0D054Q40710298-7D482BAD-2268-4209-839D-E9171FBC7641Q40727948-6CE1E5F6-AD71-4BDD-A7F1-77A1145BA394Q41223047-262EC784-E1E9-497F-BB64-895656DA8805Q42454558-08E9DAD4-94B0-4605-BB1A-2395BA30AAF8Q46419725-5E529EFE-7C0A-45F2-9D4A-3E9BDF2E6A4BQ47156336-8B29CA7E-1876-4DC2-9435-11F337374C17Q47999044-D5235974-DADB-4692-B960-DECBB71F5885Q48060657-130297C8-91DC-42D9-AD69-7E0B9A1336ADQ48517186-BD291B50-02A8-4C56-8889-B0F0E7DC27C9Q48542979-573BF655-8DB5-43BF-A886-26A022DD9FEDQ48777443-DF5163F7-095D-4080-9902-36991DAB8816Q49153537-F8F932CA-470C-45FB-9787-78F26C6BD7E4Q50016422-CA91917F-56AF-4C4E-9503-B0D7044FD22EQ50971960-E064B5DC-7673-447E-8B60-B8BD706D9A92Q52211551-396FFBCC-8D3B-4DE2-98AD-4505797C9625Q59341238-AAE71389-D6CF-4B65-BDAB-563BF10770E9Q61388166-437A755C-11A6-47DB-9E71-8393B2335CB2Q64119448-AD4D1854-134C-4605-A5A5-4A7E7F99AFB3Q64250921-4223E695-E6B7-4B38-9764-2C1D2719F918Q67652649-3CA82601-E957-46C0-8BB0-37CD21DC4DD1Q72690394-E88890A4-B545-4CA3-9BE2-EFEB416BBEBCQ73859566-02831128-0229-44CE-BDB0-71F0FA838472Q81161835-BCC22FCF-04C6-42AA-BDC9-8EAE65F6456AQ84043510-72E6368E-C021-4C17-BBBA-229E25A508C3
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Massimo Gulisano
@ast
Massimo Gulisano
@en
Massimo Gulisano
@es
Massimo Gulisano
@nl
type
label
Massimo Gulisano
@ast
Massimo Gulisano
@en
Massimo Gulisano
@es
Massimo Gulisano
@nl
prefLabel
Massimo Gulisano
@ast
Massimo Gulisano
@en
Massimo Gulisano
@es
Massimo Gulisano
@nl
P106
P1153
55523103241
P31
P496
0000-0001-8654-1745