A genome-wide functional screen shows MAGI-1 is an L1CAM-dependent stabilizer of apical junctions in C. elegans.

BACKGROUND: In multicellular organisms, cell-cell junctions are involved in many aspects of tissue morphogenesis. α-catenin links the cadherin-catenin complex (CCC) to the actin cytoskeleton, stabilizing cadherin-dependent adhesions. RESULTS: To identify modulators of cadherin-based cell adhesion, we conducted a genome-wide RNAi screen in C. elegans and uncovered MAGI-1, a highly conserved protein scaffold. Loss of magi-1 function in wild-type embryos results in disorganized epithelial migration and occasional morphogenetic failure. MAGI-1 physically interacts with the putative actin regulator AFD-1/afadin; knocking down magi-1 or afd-1 function in a hypomorphic α-catenin background leads to complete morphogenetic failure and actin disorganization in the embryonic epidermis. MAGI-1 and AFD-1 localize to a unique domain in the apical junction and normal accumulation of MAGI-1 at junctions requires SAX-7/L1CAM, which can bind MAGI-1 via its C terminus. Depletion of MAGI-1 leads to loss of spatial segregation and expansion of apical junctional domains and greater mobility of junctional proteins. CONCLUSIONS: Our screen is the first genome-wide approach to identify proteins that function synergistically with the CCC during epidermal morphogenesis in a living embryo. We demonstrate novel physical interactions between MAGI-1, AFD-1/afadin, and SAX-7/L1CAM, which are part of a functional interactome that includes components of the core CCC. Our results further suggest that MAGI-1 helps to partition and maintain a stable, spatially ordered apical junction during morphogenesis.

Testing the efficacy of RNA interference in Haemonchus contortus.

RNA interference (RNAi) is widely used in Caenorhabditis elegans to identify gene function and has been adapted as a high throughput screening method to identify genes involved in essential processes. We have been examining whether RNAi could also be used on the strongylid parasitic nematode Haemonchus contortus to study gene function. Eleven genes were targeted in L1 and exsheathed L3 H. contortus larvae with RNAi methodologies which have been shown to be effective in C. elegans and parasitic nematodes-feeding, soaking and electroporation. Reverse transcriptase-PCR and, where possible, protein assays were carried out to examine decreases in mRNA and protein levels. RNAi soaking in dsRNA to beta-tubulin and sec-23, a gene involved in vesicle transport, resulted in specific decreases in mRNA levels in exsheathed L3 larvae. No signs of specific decreases in expression levels were observed for the other nine genes tested. Following electroporation of dsRNA in L1 stage larvae, significant decreases were observed for two out of four genes tested. These findings suggest that the RNAi pathway is functional in H. contortus and that, under certain conditions, it is possible to suppress gene expression by RNAi. However, it only works on a limited number of genes and in some cases the effect is small and difficult to reproduce. This indicates that the RNAi approaches established for C. elegans and other nematodes have limited efficacy in H. contortus. This may reflect differences between nematode species in dsRNA uptake and transport into cells and between cells.

Ectopic expression of a Haemonchus contortus GATA transcription factor in Caenorhabditis elegans reveals conserved function in spite of extensive sequence divergence.

Comparative analysis between Caenorhabditis elegans and other nematode species offers a powerful approach to study gene function. C. elegans also has great potential as a surrogate expression system to study the function of genes from parasitic nematode species where transgenic methodologies are unavailable. However there is little information on the extent to which the biology of C. elegans is conserved with other nematode species and very few parasitic nematode genes have yet been functionally expressed in C. elegans. We have identified and characterised a homologue of the C. elegans GATA transcription factor elt-2, a central regulator of endoderm development, from the parasitic nematode Haemonchus contortus. The H. contortus ELT-2 polypeptide is present in endoderm nuclei throughout embryonic and post-embryonic development, except for in the infective L3 stage, and our experiments reveal that the development of the H. contortus endodermal lineage is strikingly similar to that of C. elegans. Sequence conservation between the H. contortus and C. elegans ELT-2 polypeptides broadly reflects function since the major region of sequence identity corresponds to the DNA binding domain. However, the overall level of sequence identity is remarkably low with the only other major region of identity corresponding to an unusual zinc finger domain. In spite of this, ectopic expression of the H. contortus elt-2 gene in transgenic C. elegans is sufficient to activate a programme of endodermal differentiation demonstrating that function is highly conserved. This approach of ectopic expression using an inducible promoter provides an effective way in which to use C. elegans for the in vivo functional analysis of parasitic nematode genes.