Arginine- but not alanine-rich carboxy-termini trigger nuclear translocation of mutant keratin 10 in ichthyosis with confetti

Ichthyosis with confetti (IWC) is a genodermatosis associated with dominant-negative variants in keratin 10 (KRT10) or keratin 1 (KRT1). These frameshift variants result in extended aberrant proteins, localized to the nucleus rather than the cytoplasm. This mislocalization is thought to occur as a result of the altered carboxy (C)-terminus, from poly-glycine to either a poly-arginine or -alanine tail. Previous studies on the type of C-terminus and subcellular localization of the respective mutant protein are divergent. In order to fully elucidate the pathomechanism of IWC, a greater understanding is critical. This study aimed to establish the consequences for localization and intermediate filament formation of altered keratin 10 (K10) C-termini. To achieve this, plasmids expressing distinct KRT10 variants were generated. Sequences encoded all possible reading frames of the K10 C-terminus as well as a nonsense variant. A keratinocyte line was transfected with these plasmids. Additionally, gene editing was utilized to introduce frameshift variants in exon 6 and exon 7 at the endogenous KRT10 locus. Cellular localization of aberrant K10 was observed via immunofluorescence using various antibodies. In each setting, immunofluorescence analysis demonstrated aberrant nuclear localization of K10 featuring an arginine-rich C-terminus. However, this was not observed with K10 featuring an alanine-rich C-terminus. Instead, the protein displayed cytoplasmic localization, consistent with wild-type and truncated forms of K10. This study demonstrates that, of the various 3' frameshift variants of KRT10, exclusively arginine-rich C-termini lead to nuclear localization of K10

A Cell-Based Optimised Approach for Rapid and Efficient Gene Editing of Human Pluripotent Stem Cells

Introducing or correcting disease-causing mutations through genome editing in human pluripotent stem cells (hPSCs) followed by tissue-specific differentiation provide sustainable models of multiorgan diseases, such as cystic fibrosis (CF). However, low editing efficiency resulting in extended cell culture periods and the use of specialised equipment for fluorescence activated cell sorting (FACS) make hPSC genome editing still challenging. We aimed to investigate whether a combination of cell cycle synchronisation, single-stranded oligodeoxyribonucleotides, transient selection, manual clonal isolation, and rapid screening can improve the generation of correctly modified hPSCs. Here, we introduced the most common CF mutation, ΔF508, into the CFTR gene, using TALENs into hPSCs, and corrected the W1282X mutation using CRISPR-Cas9, in human-induced PSCs. This relatively simple method achieved up to 10% efficiency without the need for FACS, generating heterozygous and homozygous gene edited hPSCs within 3–6 weeks in order to understand genetic determinants of disease and precision medicine

How can gene-editing of human pluripotent stem cells help cystic fibrosis?

Cystic fibrosis (CF) is a monogenic recessive disorder, affecting 70,000 people worldwide. CF is due to mutations in the CFTR gene, resulting in a defective protein that leads to symptoms in numerous organs, especially lungs. Despite recent advances, the lack of CF material contributes to the unmet need to find effective treatments for 55% of CF patients, and to restore the function of all affected tissues.A potential strategy would be to use gene-editing technologies (TALENs or CRISPR/Cas9) to introduce into or correct specific mutations in pluripotent stem cells (hPSCs) that can be turned into any other cell type. But current protocols for gene-editing hPSCs are often complicated, lengthy (6-8 months) and costly, thus, being restricted to a few specialised labs.This study describes an optimised protocol to correct the W1282X mutation in 3 CF hPSC lines derived from an adult and children with CF (iPSCs), by transfecting a CRISPR/Cas9 plasmid, a selection plasmid and a donor template. Corrected iPSCs were produced in 3-6 weeks. This protocol was previously used to generate the most common CF genotype, ∆F508/∆F508, from healthy hPSCs using TALENs.This work demonstrated that optimising each step of the gene-editing process, including an efficient transfection of hPSCs, and rapid isolation and screening for corrected cells, can produce in vitro models for CF in less than one month with minimum costs. These cells generated from paediatric or adult CF patients can be used to generate mutation-customised tissue-specific cultures holding great promise to advance drug testing and personalised medicine for CF

Gene expression is stable in a complete CIB1 knockout keratinocyte model

Epidermodysplasia verruciformis (EV) is a genodermatosis characterized by the inability of keratinocytes to control cutaneous β-HPV infection and a high risk for non-melanoma skin cancer (NMSC). Bi-allelic loss of function variants in TMC6, TMC8, and CIB1 predispose to EV. The correlation between these proteins and β-HPV infection is unclear. Its elucidation will advance the understanding of HPV control in human keratinocytes and development of NMSC. We generated a cell culture model by CRISPR/Cas9-mediated deletion of CIB1 to study the function of CIB1 in keratinocytes. Nine CIB1 knockout and nine mock control clones were generated originating from a human keratinocyte line. We observed small changes in gene expression as a result of CIB1 knockout, which is consistent with the clearly defined phenotype of EV patients. This suggests that the function of human CIB1 in keratinocytes is limited and involves the restriction of β-HPV. The presented model is useful to investigate CIB1 interaction with β-HPV in future studies