Abstract
Common chromosomal fragile sites (CFSs) are genomic regions prone to form breaks and gaps on metaphase chromosomes during conditions of replication stress. Moreover, CFSs are hotspots for deletions and amplifications in cancer genomes. Fragility at CFSs is caused by transcription of extremely large genes, which contributes to replication problems. These extremely large genes do not encode large proteins, but the extreme sizes of the genes originate from vast introns. Intriguingly, the intron sizes of extremely large genes are conserved between mammals and birds. Here, we have used reverse genetics to address the function and significance of the largest intron in the extremely large gene PRKN, which is highly fragile in our model system. Specifically, we have introduced an 80-kilobase deletion in intron 7 of PRKN. We find that gene expression of PRKN is largely unaffected by this intronic deletion. Strikingly, the intronic deletion, which leads to a 12% reduction of the overall size of the PRKN gene body, results in an almost twofold reduction of the PRKN fragility. Our results stress that while the large intron clearly contributes to the fragility of PRKN, it does not play an important role for PRKN expression. Taken together, our findings further add to the mystery concerning conservation of the seemingly non-functional but troublesome large introns in PRKN.
Highlights
chromosomal fragile sites (CFSs) are specific regions of the genome that often fail to replicate before mitosis, which results in chromosome breakage and high mutation rates (Debatisse et al, 2012)
To investigate the role of large introns in genes coinciding with CFSs, we chose to study the PRKN gene, which is highly fragile in our model cell line (Pentzold et al, 2018)
We have investigated the cellular role of the largest intron in the PRKN gene, which is located in a highly fragile CFS (Wilson et al, 2015; Okamoto et al, 2018; Pentzold et al, 2018; Voutsinos et al, 2018)
Summary
CFSs are specific regions of the genome that often fail to replicate before mitosis, which results in chromosome breakage and high mutation rates (Debatisse et al, 2012). To understand how transcription of large genes perturb replication, it is important to keep in mind that eukaryotic replication is initiated bidirectionally from origin of replication complexes (ORCs) scattered across the genome. The distance between these complexes determines the minimum distance that two opposing replication forks have to travel to complete replication of the region. Transcription of extremely large genes clears vast genomic regions of ORCs and in that way suppresses the firing of backup replication origins in these regions, impeding genome replication in an indirect manner. AT-dinucleotide rich regions capable of forming secondary structures can further perturb replication of certain regions within CFSs (Kaushal and Freudenreich, 2019)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
