How to analyze continuous and discrete repeated measures in small-sample cross-over trials?

To optimize the use of data from a small number of subjects in rare disease trials, an at first sight advantageous design is the repeated measures cross-over design. However, it is unclear how these within-treatment period and within-subject clustered data are best analyzed in small-sample trials. In a real-data simulation study based upon a recent epidermolysis bullosa simplex trial using this design, we compare non-parametric marginal models, generalized pairwise comparison models, GEE-type models and parametric model averaging for both repeated binary and count data. The recommendation of which methodology to use in rare disease trials with a repeated measures cross-over design depends on the type of outcome and the number of time points the treatment has an effect on. The non-parametric marginal model testing the treatment-time-interaction effect is suitable for detecting between group differences in the shapes of the longitudinal profiles. For binary outcomes with the treatment effect on a single time point, the parametric model averaging method is recommended, while in the other cases the unmatched generalized pairwise comparison methodology is recommended. Both provide an easily interpretable effect size measure, and do not require exclusion of periods or subjects due to incompleteness.

Paired nicking-mediated COL17A1 reframing for junctional epidermolysis bullosa.

Junctional epidermolysis bullosa (JEB) is a debilitating hereditary skin disorder caused by mutations in genes encoding laminin-332, type XVII collagen (C17), and integrin-α6ß4, which maintain stability between the dermis and epidermis. We designed patient-specific Cas9-nuclease- and -nickase-based targeting strategies for reframing a common homozygous deletion in exon 52 of COL17A1 associated with a lack of full-length C17 expression. Subsequent characterization of protein restoration, indel composition, and divergence of DNA and mRNA outcomes after treatment revealed auspicious efficiency, safety, and precision profiles for paired nicking-based COL17A1 editing. Almost 46% of treated primary JEB keratinocytes expressed reframed C17. Reframed COL17A1 transcripts predominantly featured 25- and 37-nt deletions, accounting for >42% of all edits and encoding C17 protein variants that localized accurately to the cell membrane. Furthermore, corrected cells showed accurate shedding of the extracellular 120-kDa C17 domain and improved adhesion capabilities to laminin-332 compared with untreated JEB cells. Three-dimensional (3D) skin equivalents demonstrated accurate and continuous deposition of C17 within the basal membrane zone between epidermis and dermis. Our findings constitute, for the first time, gene-editing-based correction of a COL17A1 mutation and demonstrate the superiority of proximal paired nicking strategies based on Cas9 D10A nickase over wild-type Cas9-based strategies for gene reframing in a clinical context.

Cut and Paste: Efficient Homology-Directed Repair of a Dominant Negative KRT14 Mutation via CRISPR/Cas9 Nickases.

With the ability to induce rapid and efficient repair of disease-causing mutations, CRISPR/Cas9 technology is ideally suited for gene therapy approaches for recessively and dominantly inherited monogenic disorders. In this study, we have corrected a causal hotspot mutation in exon 6 of the keratin 14 gene (KRT14) that results in generalized severe epidermolysis bullosa simplex (EBS-gen sev), using a double-nicking strategy targeting intron 7, followed by homology-directed repair (HDR). Co-delivery into EBS keratinocytes of a Cas9 D10A nickase (Cas9n), a predicted single guide RNA pair specific for intron 7, and a minicircle donor vector harboring the homology donor template resulted in a recombination efficiency of >30% and correction of the mutant KRT14 allele. Phenotypic correction of EBS-gen sev keratinocytes was demonstrated by immunofluorescence analysis, revealing the absence of disease-associated K14 aggregates within the cytoplasm. We achieved a promising safety profile for the CRISPR/Cas9 double-nicking approach, with no detectable off-target activity for a set of predicted off-target genes as confirmed by next generation sequencing. In conclusion, we demonstrate a highly efficient and specific gene-editing approach for KRT14, offering a causal treatment option for EBS.

'Loss of efficacy of topical 5% permethrin for treating scabies: an Austrian single-center study'.

BACKGROUND: Scabies is a contagious, itchy, parasitic infection of the skin. It is transmitted by skin-to-skin contact or by contact with contaminated material. Recent observations, especially in the outpatient setting, suggest there is decreasing efficacy of the standard treatment of choice, topical 5% permethrin cream. OBJECTIVES: To assess the efficacy and safety of topical permethrin for scabies treatment in patients. METHODS: Patients visiting the Dermatology outpatient clinic with dermatoscopy-assured scabies were assessed for enrollment in the study. In total, 55 patients were enrolled and sequentially randomized into three groups. Group (A) received permethrin 5% cream on two occasions within a one-week interval, while (intensive) group (B) received the same administration of permethrin 5% cream plus the daily application of the cream on dermatoscopically verified affected sites (hands and/or genitals and/or feet). The treatment was evaluated at 3 weeks by dermatoscopy. Group A patients who failed to respond were allowed to repeat the treatment according to the group B scheme and were again evaluated after 3 weeks (group C). RESULTS: Two applications of permethrin 5% cream (group A) produced a cure rate of 29% at follow-up. The intense application of permethrin 5% cream (group B) was not superior at follow-up (cure rate 31%). Patients who were retreated according to the intense scheme (group C) did not benefit at all. CONCLUSION: Mite populations with reduced susceptibility to permethrin exist in Austria and necessitate the evaluation of alternative treatment regimens.Key MessagesHuman scabies is a rising major public health issue worldwide and has been designated as a neglected tropical disease by the World Health Organization.Resistance to permethrin, the most widely prescribed first-line therapy for scabies is to date underreported.At present, treatment recommendations remain controversially discussed as official guidelines do not address current development of resistances, and therefore their clinical applicability is limited.

COL17A1 editing via homology-directed repair in junctional epidermolysis bullosa.

Background: Epidermolysis bullosa (EB), a severe genetic disorder characterized by blister formation in skin, is caused by mutations in genes encoding dermal-epidermal junction proteins that function to hold the skin layers together. CRISPR/Cas9-induced homology-directed repair (HDR) represents a promising tool for editing causal mutations in COL17A1 in the treatment of junctional epidermolysis bullosa (JEB). Methods: In this study, we treated primary type XVII collagen (C17)-deficient JEB keratinocytes with either Cas9 nuclease or nickase (Cas9n) ribonucleoproteins (RNP) and a single-stranded oligonucleotide (ssODN) HDR template in order to correct a causal pathogenic frameshift mutation within the COL17A1 gene. Results: As analyzed by next-generation sequencing of RNP-nucleofected keratinocytes, we observed an HDR efficiency of ∼38% when cells were treated with the high-fidelity Cas9 nuclease, a mutation-specific sgRNA, and an ssODN template. The combined induction of end-joining repair and HDR-mediated pathways resulted in a C17 restoration efficiency of up to 60% as assessed by flow cytometry. Furthermore, corrected JEB keratinocytes showed a significantly increased adhesive strength to laminin-332 and an accurate deposition of C17 along the basement membrane zone (BMZ) upon differentiation into skin equivalents. Conclusion: Here we present a gene editing approach capable of reducing end joining-generated repair products while increasing the level of seamless HDR-mediated gene repair outcomes, thereby providing a promising CRISPR/Cas9-based gene editing approach for JEB.

Recessive Dystrophic Epidermolysis bullosa due to Hemizygous 40 kb Deletion of COL7A1 and the Proximate PFKFB4 Gene Focusing on the Mutation c.425A>G Mimicking Homozygous Status

Background: Dystrophic Epidermolysis bullosa (DEB) is a rare inherited mechanobullous disease characterised by the hyperfragility of the skin and mucous membranes. It is (typically) caused by (loss-of-function) mutations in the COL7A1 gene that impair the formation of collagen type VII, which represents the major constituent of anchoring fibrils within the basement membrane zone of epithelialised tissues. In a 4-year-old patient diagnosed with the clinical features of recessive DEB, genotyping via Next-Generation EB Panel Sequencing initially revealed the homozygosity of the maternal c.425A>G mutation, while the paternal heterozygosity in exon 3 was lacking. This genetic profile suggested incongruent gene transmission due to uniparental isodisomy (UPD) or the occurrence of a hemizygous deletion of unknown size. Methods: Thus, the EB panel sequencing of genomic DNA, followed by a paternity test and analysis of microsatellite markers, as well as multiplex ligation-dependent probe amplification (MLPA) copy number analysis using patient and parental DNA, were performed. Results: This approach revealed a paternally derived hemizygous deletion spanning from exon 3 to exon 118. Linear amplification-mediated PCR (LAM-PCR) determined the breaking points within intron 2 of the COL7A1 gene, comprising a 40kb segment within intron 1 of the adjacent PFKFB4 gene. Conclusion: This report highlights the relevance of advanced molecular profiling to determine new/exceptional/unusual genotypes and the accurate mode of genetic transmission in DEB.

A non-viral and selection-free COL7A1 HDR approach with improved safety profile for dystrophic epidermolysis bullosa.

Gene editing via homology-directed repair (HDR) currently comprises the best strategy to obtain perfect corrections for pathogenic mutations of monogenic diseases, such as the severe recessive dystrophic form of the blistering skin disease epidermolysis bullosa (RDEB). Limitations of this strategy, in particular low efficiencies and off-target effects, hinder progress toward clinical applications. However, the severity of RDEB necessitates the development of efficient and safe gene-editing therapies based on perfect repair. To this end, we sought to assess the corrective efficiencies following optimal Cas9 nuclease and nickase-based COL7A1-targeting strategies in combination with single- or double-stranded donor templates for HDR at the COL7A1 mutation site. We achieved HDR-mediated correction efficiencies of up to 21% and 10% in primary RDEB keratinocytes and fibroblasts, respectively, as analyzed by next-generation sequencing, leading to full-length type VII collagen restoration and accurate deposition within engineered three-dimensional (3D) skin equivalents (SEs). Extensive on- and off-target analyses confirmed that the combined treatment of paired nicking and single-stranded oligonucleotides constituted a highly efficient COL7A1-editing strategy, associated with a significantly improved safety profile. Our findings, therefore, represent a further advancement in the field of traceless genome editing for genodermatoses.

Predictable CRISPR/Cas9-Mediated COL7A1 Reframing for Dystrophic Epidermolysis Bullosa.

End-joining‒based gene editing is frequently used for efficient reframing and knockout of target genes. However, the associated random, unpredictable, and often heterogeneous repair outcomes limit its applicability for therapeutic approaches. This study revealed more precise and predictable outcomes simply on the basis of the sequence context at the CRISPR/Cas9 target site. The severe dystrophic form of the blistering skin disease epidermolysis bullosa (DEB) represents a suitable model platform to test these recent developments for the disruption and reframing of dominant and recessive alleles, respectively, both frequently seen in DEB. We delivered a CRISPR/Cas9 nuclease as ribonucleoprotein into primary wild-type and recessive DEB keratinocytes to introduce a precise predictable single adenine sense-strand insertion at the target site. We achieved type VII collagen knockout in more than 40% of ribonucleoprotein-treated primary wild-type keratinocytes and type VII collagen restoration in more than 70% of ribonucleoprotein-treated recessive DEB keratinocytes. Next-generation sequencing of the on-target site revealed the presence of the precise adenine insertion upstream of the pathogenic mutation in at least 17% of all analyzed COL7A1 alleles. This demonstrates that COL7A1 editing based on precise end-joining‒mediated DNA repair is an efficient strategy to revert the disease-associated nature of DEB regardless of the mutational inheritance.