Evidence that direct DNA uptake through cut shoots leads to genetic transformation of Solanum aviculare Forst.

The reporter genes GUS, NPTII and BAR, either separately or in combination, have been exploited to determine if DNA which can directly enter plants, circulate within the plant and enter nuclei, can also integrate into the genome in a manner which will permit gene expression. Feeding of either seed-derived or adventitious cut shoots of Solanum aviculare with the GUS gene followed by rooting of the shoots and growing on, resulted in all tissues of the plant showing GUS activity as detected cytochemically. Southern blot analysis of plants derived from the adventitious shoots confirmed the presence of the reporter gene in roots. Reporter gene expression was observed also in the F1 generation. If GUS and NPTII or GUS, NPTII and BAR were fed together, then in each case it was possible to have both expression and Southern blot confirmation of each of the genes. There was a relatively high rate of transformation of approximately 5% of the fed stems across all experiments conducted during the present study.

Cloning and expression pattern of a zebrafish homolog of forkhead activin signal transducer (FAST), a transcription factor mediating Nodal-related signals.

Forkhead activin signal transducer (FAST) is a member of the winged-helix family of DNA-binding proteins that has been implicated in mesoderm induction and left-right axis specification during embryonic development in Xenopus and mouse. We have cloned and characterized a zebrafish FAST homolog. Zebrafish fast is expressed maternally and zygotically. Transcripts start regionalizing and decline in level during gastrulation. During somitogenesis, fast is expressed bilaterally in the lateral plate mesoderm, like its mouse homolog. In addition, zebrafish fast is also expressed bilaterally in the dorsal diencephalon, where the nodal-related cyclops gene is only expressed on the left side. It remains to be demonstrated whether FAST expression in the brain can mediate Nodal-induced asymmetric development.