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- New fluorescent probes based on gallium(III) corrole complexes for the recognition of hydrogen sulfide: a journey from solution to intracellular sitePublication . Santos, Carla I.M.; Santiago, Ana M.; Araújo, Ana R.L.; Pinto, Sandra; Agostinho, Rafaela; Simão, Sónia; Azevedo, Tomás Pais de; Antunes, Catarina; Faustino, M. Amparo F.; Araujo, Ines; Neves, M. Graça P.M.S.; Martinho, José M.G.; Maçôas, Ermelinda M.S.In this work, three fluorescent probes for detection of hydrogen sulfide (H2S) where prepared based on gallium (III) corrole complexes bearing nitro groups at beta-pyrrolic positions. Two of the compounds selected, the 3-nitro5,10,15- tris(pentafluorophenyl)corrolatogallium(III)(pyridine) (CGa-NO2) and the 3,17-dinitro-5,10,15-tris (pentafluorophenyl)corrolatogallium(III)(pyridine) (CGa-2NO2) present one and two nitro groups directly linked to the beta-pyrrolic position. The third compound, the (E)-3-(2-nitroprop-1-en-1-yl)-5,10,15-tris(pentafluorophenyl)corrolatogallium(III)(pyridine) (CGa-EtNO2), has a carbon-carbon double bond spacer between the corrole unit and the nitro group. All these derivatives were obtained from 5,10,15-tris(pentafluorophenyl)corrolatogallium(III)(pyridine) (CGa). The precursor CGa and the derivative CGa-EtNO2 behaved as turn-OFF probes, while compound CGa-NO2 responded as a turn-ON probe in the presence of H2S in the pH range of 5-9. Mechanistic studies show that the interaction of H2S with the probes involves its coordination with gallium(III) and in some cases the reduction of the nitro group to a new aminated corrole. While the formation of the coordination complex with H2S is almost immediate, the kinetics of the reduction is slow. Interestingly, for CGaNO2 the two processes can be explored in a ratiometric sensing of H2S in a non-aqueous solution showing a good linearity over an extended concentration range (5-200 mu M). The response of the corroles to H2S in intracellular medium was studied in 2D cultured cells (HeLa).
- Spatio-temporal dynamics of early somite segmentation in the chicken embryoPublication . Maia-Fernandes, Ana C; Martins, Ana; Borralho Martins, Nísia; Pais de Azevedo, Tomás; Magno, Ramiro; dos Santos Duarte, Guilhermina Isabel; Andrade, Raquel; MDuring vertebrate embryo development, the body is progressively segmented along the anterior-posterior (A-P) axis early in development. The rate of somite formation is controlled by the somitogenesis embryo clock (EC), which was first described as gene expression oscillations of hairy1 (hes4) in the presomitic mesoderm of chick embryos with 15-20 somites. Here, the EC displays the same periodicity as somite formation, 90 min, whereas the posterior-most somites (44-52) only arise every 150 minutes, matched by a corresponding slower pace of the EC. Evidence suggests that the rostral-most somites are formed faster, however, their periodicity and the EC expression dynamics in these early stages are unknown. In this study, we used time-lapse imaging of chicken embryos from primitive streak to somitogenesis stages with high temporal resolution (3-minute intervals). We measured the length between the anterior-most and the last formed somitic clefts in each captured frame and developed a simple algorithm to automatically infer both the length and time of formation of each somite. We found that the occipital somites (up to somite 5) form at an average rate of 75 minutes, while somites 6 onwards are formed approximately every 90 minutes. We also assessed the expression dynamics of hairy1 using half-embryo explants cultured for different periods of time. This showed that EC hairy1 expression is highly dynamic prior to somitogenesis and assumes a clear oscillatory behaviour as the first somites are formed. Importantly, using ex ovo culture and live-imaging techniques, we showed that the hairy1 expression pattern recapitulates with the formation of each new pair of somites, indicating that somite segmentation is coupled with EC oscillations since the onset of somitogenesis.
- Spatio-temporal dynamics of early somite segmentation in the chicken embryoPublication . Ana Martins-Jesus; Borralho-Martins, Nísia; Tomás Pais-de-Azevedo; Magno, Ramiro; Maia-Fernandes, Ana C; Borralho Martins, Nísia; Pais de Azevedo, Tomás; dos Santos Duarte, Guilhermina Isabel; Varzielas Pego de Andrade, Raquel GláuciaDuring vertebrate embryo development, the body is progressively segmented along the anterior-posterior (A-P) axis early in development. The rate of somite formation is controlled by the somitogenesis embryo clock (EC), which was first described as gene expression oscillations of hairy1 (hes4) in the presomitic mesoderm of chick embryos with 15–20 somites. Here, the EC displays the same periodicity as somite formation, 90 min, whereas the posterior-most somites (44–52) only arise every 150 minutes, matched by a corresponding slower pace of the EC. Evidence suggests that the rostral-most somites are formed faster, however, their periodicity and the EC expression dynamics in these early stages are unknown. In this study, we used time-lapse imaging of chicken embryos from primitive streak to somitogenesis stages with high temporal resolution (3-minute intervals). We measured the length between the anterior-most and the last formed somitic clefts in each captured frame and developed a simple algorithm to automatically infer both the length and time of formation of each somite. We found that the occipital somites (up to somite 5) form at an average rate of 75 minutes, while somites 6 onwards are formed approximately every 90 minutes. We also assessed the expression dynamics of hairy1 using half-embryo explants cultured for different periods of time. This showed that EC hairy1 expression is highly dynamic prior to somitogenesis and assumes a clear oscillatory behaviour as the first somites are formed. Importantly, using ex ovo culture and live-imaging techniques, we showed that the hairy1 expression pattern recapitulates with the formation of each new pair of somites, indicating that somite segmentation is coupled with EC oscillations since the onset of somitogenesis.