Behavioral Implications of Knockout for the Dyslexia-Risk Gene Dcdc2 in Mice

Several genetic linkage and epidemiological studies have provided strong evidence that DCDC2 is a candidate gene for developmental dyslexia, a disorder that impairs a person’s reading ability despite adequate intelligence, education, and socio-economic status. Studies investigating embryonic intra-ventricular RNA interference (RNAi) of Dcdc2, a rat homolog of the DCDC2 gene in humans, indicate disruptions in neuronal migration in the rat cortex during development. Interestingly, these anatomical anomalies are consistent with post mortem histological analysis of human dyslexic patients. Other rodent models of cortical developmental disruption have shown impairment in rapid auditory processing and learning maze tasks in affected subjects. The current study investigates the rapid auditory processing abilities of mice heterozygous for Dcdc2 (one functioning Dcdc2 allele) and mice with a homozygous knockout of Dcdc2 (no functioning Dcdc2 allele). It is important to note that this genetic model for behavioral assessment is still in the pilot stage. However, preliminary results suggest that mice with a genetic mutation of Dcdc2 have impaired rapid auditory processing, as well as non-spatial maze learning and memory ability, as compared to wildtypes. By genetically knocking out Dcdc2 in mice, behavioral features associated with Dcdc2 can be characterized, along with other neurological abnormalities that may arise due to the loss of the functioning gene.

The Role of Raf Kinase Inhibitor Protein in Cell Motility

Raf Kinase Inhibitor Protein (RKIP) has been identified as a phosphatidylethanolamine-binding protein capable of inhibiting Raf-1 kinase, an enzyme significant in cell proliferation and cancer development. When properly functioning, RKIP can mediate the expression of Raf-1 kinase and help prevent uncontrolled cell division. RKIP also has suggested, but unclear, roles in spindle fiber formation during mitosis, regulation of apoptosis, and cell motility. The Fenteany laboratory in the Chemistry Department identified a new small molecule, named Locostatin, as a cell migration inhibitor in mammalian cells, with RKIP as its primary molecular target. Dictyostelium discoideum possess two RKIP proteins, RKIP-A and RKIP-B. In order to begin to study the function of RKIP in D. discoideum and its role in cell motility, I created a mutant cell line which lacks a functional RKIP-A gene. In this paper, we show that removal of RKIP-A does not affect vegetative motility, but impairs chemotaxis and development in the presence of drug. Interestingly, RKIP-A knockout mutants appear more resistant to drug effects on vegetative motility than wild-type cells. More research is needed to reconcile these seemingly contrasting results, and to better develop a model for RKIP-A’s role in cell motility.