Cryptosporidium spp. in Domestic Dogs: the “Dog” Genotype

Genetic and phylogenetic characterization of Cryptosporidium isolates at two loci (18S rRNA gene and heat shock gene) from both Australian and United States dogs demonstrated that dog-derived Cryptosporidium isolates had a distinct genotype which is conserved across geographic areas. Phylogenetic analysis provided support for the idea that the “dog” genotype is, in fact, a valid species

Dystrophin Isoform Induction In Vivo by Antisense-mediated Alternative Splicing

Antisense oligomer-induced manipulation of dystrophin pre-mRNA processing can remove exons carrying mutations, or exclude exons flanking frameshifting mutations, and restore dystrophin expression in dystrophinopathy models and in Duchenne muscular dystrophy (DMD) patients. Splice intervention can also be used to manipulate the normal dystrophin pre-mRNA processing and ablate dystrophin expression in wild-type mice, with signs of pathology being induced in selected muscles within 4 weeks of commencing treatment. The disruption of normal dystrophin pre-mRNA processing to alter the reading frame can be very efficient and offers an alternative mechanism to RNA silencing for gene suppression. In addition, it is possible to remove in-frame exon blocks from the DMD gene transcript and induce specific dystrophin isoforms that retain partial functionality, without having to generate transgenic animal models. Specific exon removal to yield in-frame dystrophin transcripts will facilitate mapping of functional protein domains, based upon exon boundaries, and will be particularly relevant where there is either limited, or conflicting information as to the consequences of in-frame dystrophin exon deletions on the clinical severity and progression of the dystrophinopathy

Rational Design of Antisense Oligomers to Induce Dystrophin Exon Skipping

Duchenne muscular dystrophy (DMD), one of the most severe neuromuscular disorders of childhood, is caused by the absence of a functional dystrophin. Antisense oligomer (AO) induced exon skipping is being investigated to restore functional dystrophin expression in models of muscular dystrophy and DMD patients. One of the major challenges will be in the development of clinically relevant oligomers and exon skipping strategies to address many different mutations. Various models, including cell-free extracts, cells transfected with artificial constructs, or mice with a human transgene, have been proposed as tools to facilitate oligomer design. Despite strong sequence homology between the human and mouse dystrophin genes, directing an oligomer to the same motifs in both species does not always induce comparable exon skipping. We report substantially different levels of exon skipping induced in normal and dystrophic human myogenic cell lines and propose that animal models or artificial assay systems useful in initial studies may be of limited relevance in designing the most efficient compounds to induce targeted skipping of human dystrophin exons for therapeutic outcomes