Kristen Correia scite author profile

In a screen for novel sequences expressed during embryonic heart development we have isolated a gene which encodes a putative RNA-binding protein. This protein is a member of one of the largest families of RNA-binding proteins, the RRM (RNA Recognition Motif) family. The gene has been named hermes (for HEart, RRM Expressed Sequence). The hermes protein is 197-amino acids long and contains a single RRM domain. In situ hybridization analysis indicates that hermes is expressed at highest levels in the myocardium of the heart and to a lesser extent in the ganglion layer of the retina, the pronephros and epiphysis. Expression of hermes in each of these tissues begins at approximately the time of differentiation and is maintained throughout development. Analysis of the RNA expression of the hermes orthologues from chicken and mouse reveals that, like Xenopus, the most prominent tissue of expression is the developing heart. The sequence and expression pattern of hermes suggests a role in post-transcriptional regulation of heart development.

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Comparison of Cbln1 and Cbln2 functions using transgenic and knockout mice

Rong

Peng

Parris

et al. 2012

Journal of Neurochemistry

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Cbln1 is the prototype of a family of secreted neuronal glycoproteins (Cbln1-4) and its genetic elimination results in synaptic alterations in cerebellum and striatum. In cerebellum, Cbln1 acts as a bi-functional ligand bridging pre-synaptic β-neurexins on granule cells to post-synaptic Grid2 on Purkinje neurons. Although much is known concerning the action of Cbln1, little is known of the function of its other family members. Here we show that Cbln1 and Cbln2 have similar binding activities to β-neurexins and Grid2 and the targeted ectopic expression of Cbln2 to Purkinje cells in transgenic mice rescues the cerebellar deficits in Cbln1-null animals: suggesting the two proteins have redundant function mediated by their common receptor binding properties. Cbln1 and Cbln2 are also co-expressed in the endolysosomal compartment of the thalamic neurons responsible for the synaptic alterations in striatum of Cbln1-null mice. Therefore, to determine whether the two family members have similar functions we generated Cbln2-null mice. Cbln2-null mice do not show the synaptic alterations evident in striatum of Cbln1-null mice. Thus Cbln2 can exhibit functional redundancy with Cbln1 in cerebellum but it does not have the same properties as Cbln1 in thalamic neurons, implying one or both utilize different receptors/mechanisms in this brain region.

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Surface ectoderm is necessary for the morphogenesis of somites

Correia

Conlon

2000

Mechanisms of Development

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The paraxial mesoderm of the neck and trunk of mouse embryos undergoes extensive morphogenesis in forming somites. Paraxial mesoderm is divided into segments, it elongates along its anterior posterior axis, and its cells organize into epithelia. Experiments were performed to determine if these processes are autonomous to the mesoderm that gives rise to the somites. Presomitic mesoderm at the tailbud stage was cultured in the presence and absence of its adjacent tissues. Somite segmentation occurred in the absence of neural tube, notochord, gut and surface ectoderm, and occurred in posterior fragments in the absence of anterior presomitic mesoderm. Mesodermal expression of Dll1 and Notch1, genes with roles in segmentation, was largely independent of other tissues, consistent with autonomous segmentation. However, surface ectoderm was found to be necessary for elongation of the mesoderm along the anterior-posterior axis and for somite epithelialization. To determine if there is specificity in the interaction between ectoderm and mesoderm, ectoderm from different sources was recombined with presomitic mesoderm. Surface ectoderm from only certain parts of the embryo supported somite epithelialization and elongation. Somite epithelialization induced by ectoderm was correlated with expression of the basic-helix-loop-helix gene Paraxis in the mesoderm. This is consistent with the genetically defined requirement for Paraxis in somite epithelialization. However, trunk ectoderm was able to induce somite epithelialization in the absence of strong Paraxis expression. We conclude that somitogenesis consists of autonomous segmentation patterned by Notch signaling and nonautonomous induction of elongation and epithelialization by surface ectoderm.

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Kristen Correia

The RNA-binding protein gene, hermes, is expressed at high levels in the developing heart

Comparison of Cbln1 and Cbln2 functions using transgenic and knockout mice

Surface ectoderm is necessary for the morphogenesis of somites

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