Resumen de Multidisciplinary study of the role of calcium in plant in vitro embryogenesis
Calcium (Ca2+) is an essential cation that plays fundamental roles in all living organisms. From a functional point of view, Ca2+ acts as a second messenger that regulates different cellular processes. Previous works point to the fact that Ca2+ signaling may be involved in the early stages of induction of in vitro plant embryogenesis, but the actual role of Ca2+ in this process remained unveiled. Thus, the main goal of the present Thesis is to study the role of Ca2+ in in vitro embryogenesis using two in vitro systems: somatic embryogenesis and microspore embryogenesis. Chemical treatments and detection of Ca2+ with fluorescent probes and genetically-encoded cameleon sensors imaged by fluorescence and confocal microscopy were performed to determine the importance of Ca2+ homeostasis for induction of embryogenesis and the dynamics of Ca2+ levels during the induction and establishment of somatic and microspore-derived embryos. We observed that Ca2+ increase is an early marker of induction of in vitro embryogenesis and Ca2+ levels during in vitro embryogenesis are dynamic in all the systems we studied. Moreover, Ca2+ oscillations might be related to the differentiation processes that take place in the induced cells upon binding to calmodulin. We showed that Ca2+ increase within a defined range has system-specific positive effects in embryo yield, being more sensitive those systems using isolated cell suspensions rather than those using tissues as explants. Finally, we studied the role of callose during somatic embryogenesis, and we observed that inhibiting callose deposition prevents embryo development, which suggests a relationship between the formation of a callose barrier and the establishment of embryo identity in somatic cells.
