The role of QKI-5 in CG4 oligodendrocyte differentiation

2013 September 1900

The Quaking (qk) gene has been implicated in the development of oligodendroglial cells which are the primary source of myelin in the mammalian central nervous system (CNS). Qk encodes three alternatively spliced variants, QKI-5, QKI-6 and QKI-7, all of which are RNA binding proteins. Loss of QKI-6 and QKI-7 results in a dysmyelination phenotype that is present shortly after birth while loss of QKI-5 results in embryonic lethality. CG4 oligodendroglial cells were transfected with either pIRES2-QKI5 to up regulate QKI-5 expression or a QKI-5 specific siRNA to down regulate QKI-5. Cells were cultured for 6d in differentiation medium (DM) following which total RNA and protein was collected from the cell cultures, and coverslips with attached cells were processed for immunofluorescence. Increased QKI-5 expression following transfection with pIRES2-QKI5 resulted in increased Sirt2 and Plp mRNA expression, but did not affect SIRT2 and PLP protein expression. Down regulation of QKI-5 expression had no significant effect on mRNA or protein levels for QKI-6, QKI-7, Plp or Sirt2. Immunocytochemistry revealed that up regulation of QKI-5 resulted in significantly higher percentage of A2B5+ cells and a lower percentage of GalC+ cells, whereas siRNA treatment resulted in an increase in the percentage of GalC+ cells. Our results suggest QKI-5 regulates oligodendrocyte differentiation and modulates the transcription and availability of target mRNAs, such as Sirt2 and Plp, for translation. In order to gain a more complete understanding of the relationship between qk and both Sirt2 and Plp, future studies would include RNA coimmunoprecipitation, miRNA studies, and expanding the list of target genes to include various cell cycle components.

quaking

QKI

oligodendrocyte

glial cells

myelin

neurobiology

Translational research of the quaking gene : Focusing on the conjunction between development and disease

Farnsworth, Bryn

January 2016

Quaking (QKI) is an RNA binding protein involved in the post-transcriptional regulation of gene expression. Originally identified as the cause of hypomyelination in a mouse mutant, it has since been consistently implicated in a wide range of neurological diseases. As a gene exclusively expressed in glial cells of the central nervous system, such associations emphasise the importance of an indirect, or non-neuronal link to aberrant neural function. A role in early neural development has also been suggested from the viable and embryonic lethal mouse mutants, yet detailed and in vivo study has been precluded thus far by the murine uterine gestation, and mutant lethality prior to oligodendrogenesis. This thesis examines the role of QKI in human neurological disease, and explores the use of the zebrafish as a model organism to allow the unimpeded study of neural development. We first examined the expression of QKI in human post-mortem brain samples, in separate studies of Alzheimer’s disease (AD) and schizophrenia. In AD we found that QKI and the splice variants QKI5, QKI6, and QKI7 were all significantly upregulated, and were additionally implicated in the regulation of genes related to AD pathogenesis. Within schizophrenic samples, we explored the expression of QKI6B, a newly identified splice variant of QKI, alongside GFAP. We found that both were significantly upregulated, and a previously implicated regulation of GFAP by QKI was supported. In order to advance investigations of the potential of QKI to disturb neural development, we established the suitability of zebrafish for studying qki. This was achieved through phylogenetic and syntenic analysis, coupled with examination of the qki genes expression patterns. We found that qkib and qki2 are orthologues of human QKI, and both have distinct, yet overlapping expression patterns in neural progenitors, and are not found in differentiated neurons. Following from this, we explored the effects of knockdown to qkib and qki2, finding that qkib exclusively led to aberrant motor neuron development, cerebellar abnormalities, and alterations to the progenitor domain. This clearly demonstrated the crucial role of qki in early neural development, and confirms a previously speculated, yet occluded, function prior to oligodendrogenesis.

QKI

glia

oligodendrocyte

Alzheimer's

schizophrenia

zebrafish

statistics

morpholino

Finding Genes for Schizophrenia

Åberg, Karolina

January 2005

Schizophrenia is one of our most common psychiatric diseases. It severely affects all aspects of psychological functions and results in loss of contact with reality. No cure exists and the treatments available today produce only partial relief for disease symptoms. The aim of this work is to better understand the etiology of schizophrenia by identification of candidate genes and gene pathways involved in the development of the disease. In a preliminarily study, the effects of medication and genetic factors were investigated in a candidate gene, serotonin 2C receptor. This study distinguished pharmacological effects, caused by neuroleptics, and/or genetic effects, caused by unique polymorphisms, from other effects responsible for mRNA expression changes on candidate genes. The core of the thesis describes a new candidate gene for schizophrenia, the quaking homolog, KH domain RNA binding (mouse) or QKI, located on chromosome 6q26-q27. The identification of QKI is supported by previous linkage studies, current association studies and mRNA expression studies using three different sample sets. The investigated samples included a 12-generation pedigree with 16 distantly related schizophrenic cases and their parents, 176 unrelated nuclear families with at least one affected child in each family and human brain autopsies from 55 schizophrenic cases and from 55 controls. Indirect evidence showing involvement of QKI in myelin regulation of central nervous system is presented. Myelin plays an important role in development of normal brains and disruption of QKI might lead to schizophrenia symptoms. In a forth sample set, including extended pedigrees originated from a geographically isolated area above the Arctic Circle, in northeast Sweden, two additional schizophrenia susceptibility loci were identified, 2q13 and 5q21. Both these regions have previously been highlighted as potential schizophrenia loci in several other investigations, including a large Finnish study. This suggests common schizophrenia susceptibility loci for Nordic populations. A pilot investigation including a genome wide haplotype analysis is presented. This statistical strategy could be further developed and applied to the artic Swedish families, including analysis of 900 microsatellites and 10,000 SNPs. These findings will facilitate the understanding of the schizophrenia etiology and may lead to development of more efficient treatments for patients that suffer from schizophrenia.

psychiatric genetics

QKI

large pedigree

haplotype investigation

mRNAexpression

genetic linkage

myelin

HTR2C

Biology

Biologi

Functional studies of the Quaking gene : Focus on astroglia and neurodevelopment

Radomska, Katarzyna

January 2014

The RNA-binding protein Quaking (QKI) plays a fundamental role in post-transcriptional gene regulation during mammalian nervous system development. QKI is well known for advancing oligodendroglia differentiation and myelination, however, its functions in astrocytes and embryonic central nervous system (CNS) development remain poorly understood. Uncovering the complete spectrum of QKI molecular and functional repertoire is of additional importance in light of growing evidence linking QKI dysfunction with human disease, including schizophrenia and glioma. This thesis summarizes my contribution to fill this gap of knowledge.         In a first attempt to identify the QKI-mediated molecular pathways in astroglia, we studied the effects of QKI depletion on global gene expression in the human astrocytoma cell line. This work revealed a previously unknown role of QKI in regulating immune-related pathways. In particular, we identified several putative mRNA targets of QKI involved in interferon signaling, with possible implications in innate cellular antiviral defense, as well as tumor suppression. We next extended these investigations to human primary astrocytes, in order to more accurately model normal brain astrocytes. One of the most interesting outcomes of this analysis was that QKI regulates expression of transcripts encoding the Glial Fibrillary Acidic Protein, an intermediate filament protein that mediates diverse biological functions of astrocytes and is implicated in numerous CNS pathologies. We also characterized QKI splice variant composition and subcellular expression of encoded protein isoforms in human astrocytes. Finally, we explored the potential use of zebrafish as a model system to study neurodevelopmental functions of QKI in vivo. Two zebrafish orthologs, qkib and qki2, were identified and found to be widely expressed in the CNS neural progenitor cell domains. Furthermore, we showed that a knockdown of qkib perturbs the development of both neuronal and glial populations, and propose neural progenitor dysfunction as the primary cause of the observed phenotypes.        To conclude, the work presented in this thesis provides the first insight into understanding the functional significance of the human QKI in astroglia, and introduces zebrafish as a novel tool with which to further investigate the importance of this gene in neural development.

QKI

RNA-binding protein

astrocyte

interferon

GFAP

neurodevelopment

zebrafish

neural progenitor cell