High EphA3 expressing ophthalmic trigeminal sensory axons are sensitive to ephrin-A5-Fc: implications for lobe specific axon guidance.

The ophthalmic, maxillary and mandibular axon branches of the trigeminal ganglion provide cutaneous sensory innervation to the vertebrate face. In the chick embryo, the trigeminal ganglion is bilobed, with ophthalmic axons projecting from the ophthalmic lobe, while maxillary and mandibular projections emerge from the maxillomandibular lobe. To date, target tissue specific guidance cues that discriminately guide the axon projections from the two trigeminal ganglion lobes are unknown. EphA receptor tyrosine kinases and ephrin-A ligands are excellent candidates for this process as they are known to mediate axon guidance in the developing nervous system. Accordingly, the expression of EphAs and ephrin-As was investigated at stages 13, 15, 20 of chick embryogenesis when peripheral axons from the trigeminal ganglion are pathfinding. EphA3 is expressed highly in the ophthalmic trigeminal ganglion lobe neurons in comparison to maxillomandibular trigeminal ganglion lobe neurons. Furthermore, from stages 13-20 ephrin-A2 and ephrin-A5 ligands are only localized to the mesenchyme of the first branchial arch (maxillary and mandibular processes), the target fields for maxillomandibular trigeminal ganglion axons. We found that ophthalmic and not maxillomandibular lobe axons were responsive to ephrin-A5-Fc utilizing a substratum choice assay. The implication of these results is that EphA3 forward signaling in ophthalmic sensory axons may be an important mechanism in vivo for lobe specific guidance of trigeminal ganglion ophthalmic projections.

Alternative splicing and expressivity of the Axin(Fu) allele in mice.

Variable expressivity and incomplete penetrance are common for numerous mutations. In most cases the reasons behind these phenomena remain obscure. Caused by the insertion of a murine retrotransposon into intron 6 of the Axin locus, the Axin(Fu) mutation induces alternative splicing and ultimately leads to abnormal tail development in mice. In this investigation RNase protection assay was used to investigate the potential connection between alternative splicing with the expressivity and penetrance of the mutant allele. The results reported here confirm previous observations that alternative splicing occurs in mRNA transcribed from the mutant Axin(Fu) allele. However this investigation also shows that lower levels of alternative splicing commonly take place in the wild type transcript. Correlation analysis reveals a significant connection between tail abnormalities and the ratio of correct to alternatively spliced mRNAs. Overall this paper demonstrates that higher levels of alternatively spliced mRNAs correlate with stronger expression of the mutant trait.

Unusual inheritance of the AxinFu mutation in mice is associated with widespread rearrangements in the proximal region of chromosome 17.

AxinFu is a mutation in mice that causes fused tails and other developmental abnormalities as a result of insertion of an intracisternal-A particle (IAP), a murine retrotransposon, into intron 6. In a small percentage of offspring we found that the mutant allele reverts to wild-type through loss of the insertion with concomitant disappearance of the mutant phenotype. Investigation of a series of microsatellite loci in the proximal region of chromosome 17 revealed novel alleles which arise simultaneously with disappearance of IAP from AxinFu. These novel microsatellite variants are distinct from the parental alleles and those so far discovered are organized into two haplotypes. Both haplotypes demonstrate stable Mendelian inheritance. Results show that these rearrangements, which are involved in the production of the new haplotypes, exceed millions of base pairs.

A novel subfamily of LINE-derived elements in mice.

Hybrid sequences have been described previously that consist of a 5' region homologous to ORF2 of LINEs and a 3' end that shares homology with a sequence located in the first intron of Cepsilon immunoglobulin. The present investigation has revealed 14 new sequences from seven murine species, that show high homology to those observed earlier. Database search has found several new homologous hybrid sequences including one located in the mouse T-cell receptor (Tcra) locus. Several interesting features of this sequence include identical 15-bp flanking short direct repeats as well as poly-A signal and A-rich sequence at the 3' end. We have classified this set of sequences as LINE-derived elements (LDEs), which constitute a newly observed subfamily. Comparative analysis of these sequences suggests that a single recombination event was responsible for the production of an LDE progenitor. The phylogenetic tree shows a number of elements that pre-existed in the common ancestor of murine species and displays different evolutionary rates. The time of LDE origin is estimated at approximately 10-15 MYA.