). The study has a particular focus on the plant as grown in Africa. The onion is a monocotyledonous, allogamous, and entomophilous plant, with a one-year production cycle for bulb production, and a two-year production cycle for seeds. The onion is one of the most significant vegetables in the ARN-509 concentration world because of its use as both a food and a medicine. Literature. Twenty-eight morphological markers, linked to seed, leaf, flower and bulb traits, were identified as the most discriminant phenotypical criteria. Biochemical and molecular markers were also developed to characterize
genetic variations between and within onion varieties. Previous studies examining West Africa onion varieties showed that only six enzyme systems are polymorphic. However, only twenty-four
isozymes have been used to compare the onion to other Allium species. This low number of polymorphic biochemical markers makes it more difficult to determine the genetic diversity of onions. On the other hand, molecular markers at DNA level, EGFR inhibitor such as RAPD, RFLP, AFLP, SSR, are very useful to analyze diversity at varietal and species level, using cultivated and spontaneous forms, and to analyze the level of introgression between the onion and the other species of the genus. Conclusions. Selumetinib cell line Genetic diversity analysis showed an important variability between and within Africa
onion landraces. It would be useful to combine in situ and ex situ conservation, using these genetic resources to improve the production and the appropriate use of African onion cultivars.”
“The possibility to visualize and image the arrangement of proteins within the cell at the molecular level has always been an attraction for scientists in biological research. In particular, for signalling molecules such as GPCRs (G-protein-coupled receptors), the existence of protein aggregates such as oligomers or clusters has been the topic of extensive debate. One of the reasons for this lively argument is that the molecular size is below the diffraction-limited resolution of the conventional microscopy, precluding the direct visualization of protein super-structures. On the other hand, new super-resolution microscopy techniques, such as the PALM (photoactivated localization microscopy), allow the limit of the resolution power of conventional optics to be broken and the localization of single molecules to be determined with a precision of 10-20 nm, close to their molecular size. The application of super-resolution microscopy to study the spatial and temporal organization of GPCRs has brought new insights into receptor arrangement on the plasma membrane.