about
A nontoxic polypeptide oligomer with a fungicide potency under agricultural conditions which is equal or greater than that of their chemical counterpartsThe unique biosynthetic route from lupinus beta-conglutin gene to bladBridging the Gap to Non-toxic Fungal Control: Lupinus-Derived Blad-Containing Oligomer as a Novel Candidate to Combat Human Pathogenic Fungi.Reference gene validation for quantitative RT-PCR during biotic and abiotic stresses in Vitis viniferaGenome-wide analysis of transcript abundance and translation in Arabidopsis seedlings subjected to oxygen deprivationEngineering grapevine for increased resistance to fungal pathogens without compromising wine stability.Valuing the Endangered Species Antirrhinum lopesianum: Neuroprotective Activities and Strategies for in vitro Plant PropagationBlad-Containing Oligomer Fungicidal Activity on Human Pathogenic Yeasts. From the Outside to the Inside of the Target Cell.Proteins in Soy Might Have a Higher Role in Cancer Prevention than Previously Expected: Soybean Protein Fractions Are More Effective MMP-9 Inhibitors Than Non-Protein Fractions, Even in Cooked Seeds.Is the exoproteome important for bacterial pathogenesis? Lessons learned from interstrain exoprotein diversity in Listeria monocytogenes grown at different temperatures.Multiple lectin detection by cell membrane affinity binding.(Poly)phenols protect from α-synuclein toxicity by reducing oxidative stress and promoting autophagy.The neuroprotective potential of phenolic-enriched fractions from four Juniperus species found in Portugal.Neuroprotective effects of digested polyphenols from wild blackberry species.Antioxidant properties and neuroprotective capacity of strawberry tree fruit (Arbutus unedo).Are vicilins another major class of legume lectins?Antioxidant capacity of Macaronesian traditional medicinal plants.Transcriptomic changes following the compatible interaction Vitis vinifera-Erysiphe necator. Paving the way towards an enantioselective role in plant defence modulation.β-N-Acetylhexosaminidase involvement in α-conglutin mobilization in Lupinus albus.Characterization of the proteins from Vigna unguiculata seeds.Contribution of Yap1 towards Saccharomyces cerevisiae adaptation to arsenic-mediated oxidative stress.Regulatory role for a conserved motif adjacent to the homeodomain of Hox10 proteins.Analysis of phenolic compounds in Portuguese wild and commercial berries after multienzyme hydrolysis.Legume seeds and colorectal cancer revisited: Protease inhibitors reduce MMP-9 activity and colon cancer cell migration.Vitis vinifera secondary metabolism as affected by sulfate depletion: diagnosis through phenylpropanoid pathway genes and metabolites.Is protein degradation correlated with either the charge or size of Lemna proteins?Effect of osmotic stress on protein turnover in Lemna minor fronds.Environmental conditions during vegetative growth determine the major proteins that accumulate in mature grapes.Exposure of Lemna minor to arsenite: expression levels of the components and intermediates of the ubiquitin/proteasome pathway.Dyospiros kaki phenolics inhibit colitis and colon cancer cell proliferation, but not gelatinase activities.Bioaccessible (poly)phenol metabolites from raspberry protect neural cells from oxidative stress and attenuate microglia activation.Daily polyphenol intake from fresh fruits in Portugal: contribution from berry fruits.Bioactive compounds from endemic plants of Southwest Portugal: inhibition of acetylcholinesterase and radical scavenging activities.Phenolic sulfates as new and highly abundant metabolites in human plasma after ingestion of a mixed berry fruit purée.Differences in the Expression of Cold Stress-Related Genes and in the Swarming Motility Among Persistent and Sporadic Strains of Listeria monocytogenes.Urinary metabolite profiling identifies novel colonic metabolites and conjugates of phenolics in healthy volunteersGenome-wide Analysis of Transcript Abundance and Translation in Arabidopsis Seedlings Subjected to Oxygen Deprivation.Comparative Analysis of the Exoproteomes of Listeria monocytogenes Strains Grown at Low TemperaturesYap1 mediates tolerance to cobalt toxicity in the yeast Saccharomyces cerevisiaeNeuroprotective effect of blackberry (Rubus sp.) polyphenols is potentiated after simulated gastrointestinal digestion
P50
Q28545796-6771B960-ADF7-482B-BC82-61AC25724200Q33523279-BC16899F-984F-4052-8CB9-2815F611C9D8Q33843321-3711D40B-A0A2-45EF-A214-B64955CCF149Q34395853-5400C3D3-71F1-4FF5-BF7F-77F1EDF7849BQ34583930-127119F4-923A-4EE0-85F0-C09C0E85B517Q35707737-7BB667C8-1E0D-487E-8C16-33326D80EA27Q36335111-9329F4BF-17C0-4F4A-B560-35F44C781856Q37438608-B9F431AA-A73E-4B87-92E1-F7AE9A8874E2Q37729631-42531D1E-93F5-47AC-9734-002FB19F1D9CQ38240184-5D0BD949-934C-4469-93F2-DAECEEC65B5DQ38327278-A82F3BFB-0E4E-4B16-8799-4EC798A72C39Q38937100-688290BA-5A28-442E-AB6D-D6F3641155E4Q39301660-9E5D485B-B146-42E4-A9CA-8AC59B1E537AQ39400029-71258F4E-700F-4AF3-98E3-C787B87079FDQ39746343-5604931A-35D9-469D-B2E9-BC52515D33D9Q41711504-E740D14B-78CB-4672-B3F9-97E0F2240575Q43081333-C8C014DF-E7AE-468E-A136-B5D9170D411AQ43832843-1EC19984-947E-436E-8275-6FBE22148CDBQ44566891-920D045E-FE7E-4BC7-9689-7CD1D569FF5DQ44804820-CBF0A103-56B7-4E6A-AF6B-A72A1BBC8681Q44939519-6B13A5E7-BCF1-4DEE-B2E6-C44657A723A4Q45516316-BD2222D1-32E3-473A-85D5-639A295303C6Q46602303-ABBBFCE2-67D0-462D-9E1D-8BC5C7F6A477Q46632132-6720D0A3-ED3B-4D86-B544-E41F6FF37B6BQ46941869-F9803E72-536B-4537-9DC3-6BD5511AC5DBQ47204232-85E5A7E3-5C43-46DC-99FB-77D34270A86EQ47726539-824B7FA9-AB4F-4E27-A869-BE61BF9666F8Q47809297-AD803C96-5ABA-4966-BC40-9B12EFE0C198Q48085193-90756C2B-C899-4A5D-8EB0-E88586500DFCQ50655430-E9086F33-82B4-4EF6-B78C-45C12E4AE081Q51561647-2400DB6B-CB87-496F-98BA-8842112EDC9BQ52801857-B6034E81-23A3-4EC1-A4D1-9E7A7EA2F93CQ52802923-A333BD49-EF1B-4AEB-A125-311B2E491E5CQ52838045-9355F890-2F20-4255-9422-B5C5546FE434Q53505907-56E467A9-9F19-49C4-9B95-DF926B054B2AQ54510038-3BA57B09-844A-41A9-AC77-D8C4B70DCDD8Q55497331-4310FB58-4C37-4DD8-848A-B668379024DFQ57661622-C382712A-1A97-4320-A36D-FA3DC4B4BC56Q58201773-4511CF29-4A89-49E1-A1DE-FD7664B982B4Q58201790-FCD76464-9309-46E2-BFC4-347F46100F2B
P50
description
hulumtues
@sq
researcher
@en
ricercatore
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wetenschapper
@nl
հետազոտող
@hy
name
Ricardo Boavida Ferreira
@ast
Ricardo Boavida Ferreira
@en
Ricardo Boavida Ferreira
@es
Ricardo Boavida Ferreira
@nl
Ricardo Boavida Ferreira
@sl
type
label
Ricardo Boavida Ferreira
@ast
Ricardo Boavida Ferreira
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Ricardo Boavida Ferreira
@es
Ricardo Boavida Ferreira
@nl
Ricardo Boavida Ferreira
@sl
prefLabel
Ricardo Boavida Ferreira
@ast
Ricardo Boavida Ferreira
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Ricardo Boavida Ferreira
@es
Ricardo Boavida Ferreira
@nl
Ricardo Boavida Ferreira
@sl
P214
P106
P1153
7202612275
P21
P214
P31
P496
0000-0002-5027-7564