Abstract
The choroid plexus, an epithelial-based structure localized in the brain ventricle, is the major component of the blood-cerebrospinal fluid barrier. The choroid plexus produces the cerebrospinal fluid and regulates the components of the cerebrospinal fluid. Abnormal choroid plexus function is associated with neurodegenerative diseases, tumor formation in the choroid plexus epithelium, and hydrocephaly. In this study, we used zebrafish (Danio rerio) as a model system to understand the genetic components of choroid plexus development. We generated an enhancer trap line, Et(cp:EGFP)sj2, that expresses enhanced green fluorescent protein (EGFP) in the choroid plexus epithelium. Using immunohistochemistry and fluorescent tracers, we demonstrated that the zebrafish choroid plexus possesses brain barrier properties such as tight junctions and transporter activity. Thus, we have established zebrafish as a functionally relevant model to study choroid plexus development. Using an unbiased approach, we performed a forward genetic dissection of the choroid plexus to identify genes essential for its formation and function. Using Et(cp:EGFP)sj2, we isolated 10 recessive mutant lines with choroid plexus abnormalities, which were grouped into five classes based on GFP intensity, epithelial localization, and overall choroid plexus morphology. We also mapped the mutation for two mutant lines to chromosomes 4 and 21, respectively. The mutants generated in this study can be used to elucidate specific genes and signaling pathways essential for choroid plexus development, function, and/or maintenance and will provide important insights into how these genetic mutations contribute to disease.
Highlights
The choroid plexus consists of polarized epithelial cells projecting into the brain ventricle to create a blood-cerebrospinal fluid barrier between fenestrated capillaries and the cerebrospinal fluid (Wolburg and Paulus, 2010)
We found that the myelencephalic choroid plexus epithelial cells migrated from the outer rhombomeres into the midbrain-hindbrain boundary as described previously (GarciaLecea et al, 2008) and anteriorly from the developing spinal cord
The goal of our study was to establish zebrafish as a functionally relevant model to study choroid plexus development and as a screening tool to genetically dissect genes involved in choroid plexus formation, function, and maintenance
Summary
The choroid plexus consists of polarized epithelial cells projecting into the brain ventricle to create a blood-cerebrospinal fluid barrier between fenestrated capillaries and the cerebrospinal fluid (Wolburg and Paulus, 2010). Previous studies have classified choroid plexus development by observing modifications in cell morphology, measuring glycogen content as it matures, and examining gene expression (Dohrmann, 1970; Strazielle and Ghersi-Egea, 2000; Dziegielewska et al, 2001; Kratzer et al, 2012, 2013; Liddelow et al, 2014) Signaling pathways such as Sonic hedgehog (Huang et al, 2009; Nielsen and Dymecki, 2010), BMP (Currle et al, 2005), and Notch (Irvin et al, 2004) have been found to contribute to choroid plexus formation. Identifying altered genes and signaling pathways in the choroid plexus that cause disease initiation or progression can help determine potential therapeutic targets for treatment
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