Call for Research Contract Clemente Estable Biological Research Institute (IIBCE)
Department of Cellular and Molecular Neurophysiology
The Department of Cellular and Molecular Neurophysiology of the IIBCE calls for applicants for a research contract within the framework of the project WFL-UY-13/23 #290 “The role of connexins in self-repair induced by endogenous spinal progenitors” funded by Wings for Life, Spinal Cord Research Foundation. The contract will be for 30 hours per week for a period of one year, renewable for the same period (up to a maximum of 2 years) if performance reports are satisfactorily complied with. The nominal salary is $35,000, which will be updated by the salary adjustment percentage of the Central Administration. Applicants must have a bachelor’s degree – or equivalent training – in one of the following disciplines: Biology, Biochemistry, Human Biology, Medicine or Chemistry.
Interested persons must send the following information to russoblanc@gmail.com before 5:00 p.m. on July 19, 2024, referring to the project number:
- Curriculum vitae
- Undergraduate education (and postgraduate if applicable)
- Motivation letter
The people selected in the merit evaluation will be invited to an interview to be coordinated in a timely manner.
Profile
Previous experience in any of the following items will be valued (without being exclusive): use and handling of laboratory animals; molecular biology; cell culture; cell biology; histological and immunohistochemical techniques; microscopy; electrophysiology (patch clamp) or optogenetics.
Project description:
Spinal cord injury produces devastating conditions because of limited self-repair. Although the mammalian spinal cord lacks the ability for self-repair of non-mammalian species, its ependyma reacts to injury by generating new cells that integrate the scar to limit the damage. The manipulation of the ependymal stem cell niche to maximize endogenous repair requires understanding the mechanisms by which proliferation, migration and differentiation of ependymal progenitors are controlled. We recently showed that communication via connexins (Cxs) plays a key role in the early response of ependymal cells to injury. From a translational point of view, understanding the cellular and molecular mechanisms of Cx-mediated plasticity may be important to design strategies to boost the contribution of the ependyma to repair. The central hypothesis of this proposal is that the optimization of the response of the ependyma to injury will shift the balance towards a pro-regenerative scar. We have shown that similar to stem cell niches in the embryo, early in life Cx43 and Cx26 are expressed in ependymal cells which are in general functionally coupled via gap junctions. Cx26 and gap junction coupling decrease as the ependymal stem cell niche becomes dormant in adulthood, but this down-regulation is overruled by injury. In addition to gap junctions, there is a population of permeable Cx43 hemichannels in ependymal cells that may play a part in the earliest stages of injury. Communication via Cxs is involved in wound healing and repair in different tissues by the regulation of proliferation, migration and differentiation. For example, Cx26 in the skin promotes proliferation whereas Cx43 is downregulated in the margins of healing skin wounds but its persistence impairs healing. Based on our previous studies and preliminary results, we hypothesize that -as in other tissues-Cx43 might act deleteriously whereas Cx26 would promote a better response of ependymal cells to injury that will lead to a scar permissive for regenerating axons. Our specific aims are: To investigate the role of Cx26 and Cx43 in the re-activation of ependymal cells after SCI. Aim 2: To determine the influence of Cxs on the contribution of the ependyma to tissue repair and functional recovery. Aim 3: To explore the effects of Cx26 upregulation in healing and functional recovery after SCI. To pursue these aims, we will apply a multi-technical approach that will provide a better understanding of the mechanisms by which Cx43 and Cx26 regulate the reaction of the ependyma to injury and their impact in the formation of on the glial scar. In vitro and in vivo approaches combining patch clamp recordings, immunohistochemistry, confocal and electron microscopy, DIVER imaging and optogenetics to apply both loss-of-function and gain-of-function approaches using transgenic mice models. We believe the new knowledge on the role Cxs in the ependymal stem cell niche will provide valuable clues to design new therapeutic approaches aimed at increasing the self-repair capabilities of the spinal cord to help improve functional recovery.