Efficient targeting of a SCID gene by an engineered single-chain homing endonuclease

Sequence-specific endonucleases recognizing long target sequences are emerging as powerful tools for genome engineering. These endonucleases could be used to correct deleterious mutations or to inactivate viruses, in a new approach to molecular medicine. However, such applications are highly demanding in terms of safety. Mutations in the human RAG1 gene cause severe combined immunodeficiency (SCID). Using the I-CreI dimeric LAGLIDADG meganuclease as a scaffold, we describe here the engineering of a series of endonucleases cleaving the human RAG1 gene, including obligate heterodimers and single-chain molecules. We show that a novel single-chain design, in which two different monomers are linked to form a single molecule, can induce high levels of recombination while safeguarding more effectively against potential genotoxicity. We provide here the first demonstration that an engineered meganuclease can induce targeted recombination at an endogenous locus in up to 6% of transfected human cells. These properties rank this new generation of endonucleases among the best molecular scissors available for genome surgery strategies, potentially avoiding the deleterious effects of previous gene therapy approaches.     

DNA double-strand break repair signalling: the case of RAD51 post-translational regulation

DNA double-strand breaks (DSBs) are the major lethal lesion induced by ionizing radiation or by replication block. However, cells can take advantage of DSB-induced recombination in order to generate genetic diversity in physiological processes such as meiosis and V(D)J recombination. Two main alternative pathways compete for DSB repair: homologous recombination (HR) and non-homologous end-joining (NHEJ). This review will briefly present the mechanisms and the enzymatic complex for HR and NHEJ. The signalling of the DSB through the ATM pathway will be presented. Then, we will focus on the case of the RAD51 protein, which plays a pivotal role in HR and is conserved from bacteria to humans. Post-translational regulation of RAD51 is presented. Two contrasting situations are discussed: one with up-regulation (expression of the oncogene BCR/ABL) and one with a down-regulation (expression of the oncogene BCL-2) of RAD51, associated with apoptosis inhibition and tumour predisposition.     

The transposable element impala, a fungal member of the Tc1-mariner superfamily

A new transposable element has been isolated from an unstable niaD mutant of the fungus Fusarium oxysporum. This element, called impala, is 1280 nucleotides long and has inverted repeats of 27 bp. Impala inserts into a TA site and leaves behind a footprint when it excises. The inserted element, impala-160, is cis-active, but is probably trans-defective owing to several stop codons and frameshifts. Similarities exist between the inverted repeats of impala and those of transposons belonging to the widely dispersed mariner and Tc1 families. Moreover, translation of the open reading frame revealed three regions showing high similarities with Tc1 from Caenorhabditis elegans and with the mariner element of Drosophila mauritiana. The overall comparison shows that impala occupies an intermediate position between the mariner and Tcl-like elements, suggesting that all these elements belong to the same superfamily. The degree of relatedness observed between these elements, described in different kingdoms, raises the question of their origin and evolution.     

Transposable elements in the fungal plant pathogenFusarium oxysporum

The genome of the fungal plant pathogenFusarium oxysporum contains at least six different families of transposable elements. Representatives of both DNA transposons and retrotransposons have been identified, either by cloning of dispersed repetitive sequences (Foret andpalm) or by trapping in the nitrate reductase gene (Fot1, Fot2 Impala andHop).Fot1 andImpala elements are related to theTc1 andmariner class of transposons. These transposable elements can affect gene structure and function in several ways: inactivation of the target gene through insertion, diversification of the nucleotide sequence by imprecise excisions, and probably chromosomal rearrangements as suggested by the extensive karyotype variation observed among field isolates. Comparisons of the distribution of these elements inFusarium populations have improved our understanding of population structure and epidemiology and provided support for horizontal genetic transfer. Also they could be developed as genetic tools for tagging genes, a cloning strategy that is particularly promising in imperfect fungi.     

Fungal transposable elements: Generators of diversity and genetic tools

Representatives of several classes of transposable elements (TEs) have been characterized in a broad range of fungal species. The studies indicate that these elements are ancient and ubiquitous components of fungal genomes. Some of these elements have been shown to actively affect gene structure and function in several ways: inactivation of gene expression upon insertion, modification of the nucleotide sequence through excision, and probably by inducing extensive chromosomal rearrangements. The ability of TEs to generate a high degree of genetic diversity may therefore be important in the evolution of the fungal genome. TEs also have many potential applications in genetic research, including insertional mutagenesis and population fingerprinting, as well as gene transfer within and between species. All these genetic approaches are important as tools in studies of molecular biology and evolution of fungal species, many of which lack a functional sexual cycle.     

Transposon impala, a novel tool for gene tagging in the rice blast fungus Magnaporthe grisea

impala, a Tc1-mariner transposable element from Fusarium oxysporum, was introduced into the rice blast fungus Magnaporthe grisea to develop transposon-based insertional mutagenesis. A construct (pNIL160) containing an autonomous impala copy inserted in the promoter of niaD encoding Aspergillus nidulans nitrate reductase was introduced by transformation into a M. grisea nitrate reductase-deficient mutant. impala excision was monitored by restoration of prototrophy for nitrate. Southern analysis of niaD+ revertants revealed that impala was able to excise and reinsert at new loci in M. grisea. As observed for its host Fusarium oxysporum, impala inserted at a TA site left a typical excision footprint of 5 bp. We have shown that a defective impala copy was inactive in M. grisea, yet it can be activated by a functional impala transposase. A transformant carrying a single copy of pNIL160 was used to generate a collection of 350 revertants. Mutants either altered for their mycelial growth (Rev2) or nonpathogenic (Rev77) were obtained. Complementation of Rev77 with a 3-kb genomic fragment from a wild-type locus was successful, demonstrating the tagging of a pathogenicity gene by impala. This gene, called ORP1, is essential for penetration of host leaves by M. grisea and has no sequence homology to known genes.     

Evolutionary history of the impala transposon in Fusarium oxysporum

Impala is an active DNA transposon family that was first identified in a strain of Fusarium oxysporum pathogenic to melon. The 10 copies present in this strain define three subfamilies that differ by about 20% at the nucleotide level. This high level of polymorphism suggests the existence of an ancestral polymorphism associated with vertical transmission and/or the introduction of some subfamilies by horizontal transfer from another species. To gain insights into the molecular evolution of this family, impala distribution was investigated in strains with various host specificities by Southern blot, PCR, and sequencing. Detection of impala elements in most of the F. oxysporum strains tested indicates that impala is an ancient component of the F. oxysporum genome. Subfamily-specific amplifications and sequence and phylogenetic analyses revealed five subfamilies, several of which can be found within the same genome. This supports the hypothesis of an ancestral polymorphism followed by vertical transmission and independent evolution in the host-specific forms. Highly similar elements showing unique features (internal deletions, high rates of CG-to-TA transitions) or being present at the same genomic location were identified in several strains with different host specificities, raising questions about the phylogenetic relationships of these strains. A phylogenetic analysis performed by sequencing a portion of the EF1alpha gene showed in most cases a correlation between the presence of a particular element and a close genetic relationship. All of these data provide important information on the evolutionary origin of this element and reveal its potential as a valuable tool for tracing populations.     

Merosin deficient congenital muscular dystrophy: Clinical,neuroimaging and immunohistochemical study of 8 Egyptian pediatric patients

Congenital muscular dystrophies (CMD) are a group of heterogeneous inherited autosomal recessive disorders characterized by muscular weakness, hypotonia and contractures. The Merosin Negative CMD (MNCMD) is considered to be the most severe form and is usually associated with white matter abnormalities as seen with brain imaging. Merosin is also expressed in the nervous system and its deficiency could affect its development. This article describes the clinical picture, muscle biopsy findings and neuroimaging abnormalities of eight Egyptian Pediatric patients with the clinical presentation of merosin negative congenital muscular dystrophy. The leading clinical presentation in almost all patients was severe hypotonia, muscular weakness and failure to achieve motor developmental milestones, only Case 2 walked at 2 years of age. Mentality was normal in most patients with exception of Case 2 in whom scholastic achievement was poor and was associated with behavior abnormality. Serum Creatine kinase ranged from moderate to severe elevation, 536–3563 U/L, Electromyography demonstrated a myopathic pattern in all patients. Brain MRI showed extensive demyelination of the cerebral white matter in 6/8 patients with extension to cerebellar demyelination in Case 5. 5/8 patients underwent muscle biopsy for which immunofluorescence staining for merosin demonstrated complete deficiency of laminin α2 in Case 5 & partial deficiency of laminin α2 in Case 2.This report demonstrates the utility of Immunofluorescence staining as a guide to confirm the diagnosis of MDCMD especially when molecular diagnosis is not available.