Tesis doctoral de Eduardo Moreno González
One of the main issues in animal evolution deal with the transition from radial organisms (the radiata), with only one axis of symmetry, the oral-aboral axis, to bilateral organims (the bilateria), bearing two orthogonal body axes, the anteroposterior and the dorsoventral axis. finding the extant bilateral organism closest to the bilaterian ancestor is the first and necessary step to open new ways of analysis. Recent molecular phylogenies have convincingly shown that the acoel flatworms, traditionally classified within the platyhelminthes, are the sister group of the remaining bilateria, branching out before the common ancestor of protostomes, and deuterostomes (the so-called pda). hox and parahox genes encode for transcripcional regulators involved in the control the anteroposterior (ap) body axis in all bilateral animals. Hox genes are usually organized in clusters (duboule 2007) and show a collinear correspondence between gene order and the body levels at which these genes are expressed. however, it is still unclear when in the evolutionary history of bilaterians the hox system first conferred positional identity along the ap-axis. Hence, the comparative study of the patterning genes hox and parahox in acoel flatworms, could be crucial to understand the origin of the hox-parahox axial patterning system and how the morphological transition from radial to bilateral animals has happened. in this thesis, we report on the cloning, genomic arrangement, and expression domains of hox genes in the acoel species symsagittifera roscoffensis. Three hox genes were detected: one from each of the major groups of hox genes, which are anterior, central, and posterior, nemed srhox1, srhox5 and srhoxpost respectively. All acoel species studied to date contain the same minimal complement of three hox genes and one cdx parahox gene. in bacterial artificial chromosome cloning, sequencing, and chromosomal fluorescente in situ hybridization, hox genes were not observed as being clustered in a unique genomic region in s. Roscoffensis. Nevertheless, despite its dispersion within the genome, hox genes are expressed in nested domains along the ap axis in the juvenile worm. The basic set of hox genes in acoels and their coarse nested spatial deployment might be the first indicators of the role of hox genes in the evolution of bilateral symmetry and ap positional identity from a hypothetical radial ancestor. in order to understand how the ap axis have been established over evolutionary time, the execution of functional analyses is essential. With this purpose, we have performed the knockdown of the posterior hox, iphoxpost, in the postembryonic development the acoel species isodiametra pulchra, using rna interference technologies. the analysis has been done, for the first time in acoels, and we demonstrate that the functions of this gene are restricted to the posterior region of the animal, within the muscular and neural tissues. We conclude, therefore, that the posterior hox genes were used to specify and maintain defined anatomical regions within the ap axis of animals since the beginning of bilaterian evolution.
Datos académicos de la tesis doctoral «Caracterització de los genes hox en el acelo symsagittifera roscoffensis«
- Título de la tesis: Caracterització de los genes hox en el acelo symsagittifera roscoffensis
- Autor: Eduardo Moreno González
- Universidad: Barcelona
- Fecha de lectura de la tesis: 30/06/2010
Dirección y tribunal
- Director de la tesis
- Pedro Martínez Serra
- Tribunal
- Presidente del tribunal: jordi García fernández
- andreas Hejnol (vocal)
- (vocal)
- (vocal)