Following cell fate in the living mouse embryo.

It has been difficult to follow many of the dramatic changes in cell fate and cell migration during mouse development. This is because there has been no enduring marker that would allow cells to be recognised in the living embryo. We believe that we have overcome this problem by developing a novel form of green fluorescent protein, named MmGFP, that proves to be easily visible and non toxic to mouse cells and does not perturb embryogenesis. We show that synthetic mRNA encoding MmGFP can be injected into blastomeres to follow the fate of their progeny during preimplantation development. We have made a stable embryonic stem cell line that expresses MmGFP and introduced these fluorescent cells into mouse embryos. For the first time, we have been able to follow the fate of embryonic stem cells in living embryos and to observe directly the contribution of these cells to distinct lineages of the postimplantation embryo. This approach should lead to a more complete description of the dynamics of cell fate in the mouse.

Removal of a cryptic intron and subcellular localization of green fluorescent protein are required to mark transgenic Arabidopsis plants brightly.

The green fluorescent protein (GFP) from the jellyfish Aequorea victoria is finding wide use as a genetic marker that can be directly visualized in the living cells of many heterologous organisms. We have sought to express GFP in the model plant Arabidopsis thaliana, but have found that proper expression of GFP is curtailed due to aberrant mRNA processing. An 84-nt cryptic intron is efficiently recognized and excised from transcripts of the GFP coding sequence. The cryptic intron contains sequences similar to those required for recognition of normal plant introns. We have modified the codon usage of the gfp gene to mutate the intron and to restore proper expression in Arabidopsis. GFP is mainly localized within the nucleoplasm and cytoplasm of transformed Arabidopsis cells and can give rise to high levels of fluorescence, but it proved difficult to efficiently regenerate transgenic plants from such highly fluorescent cells. However, when GFP is targeted to the endoplasmic reticulum, transformed cells regenerate routinely to give highly fluorescent plants. These modified forms of the gfp gene are useful for directly monitoring gene expression and protein localization and dynamics at high resolution, and as a simply scored genetic marker in living plants.

Importance of structural differences between complementary RNA molecules to control of replication of an IncB plasmid.

Replication of the IncB miniplasmid pMU720 is dependent on the expression of repA, the gene encoding replication initiator protein RepA. Binding of a small antisense RNA (RNAI) to its complementary target (stem-loop I [SLI]) in the RepA mRNA prevents the participation of SLI in the formation of a pseudoknot that is an enhancer of translation of this mRNA. Thus, RNAI regulates the frequency of replication of pMU720 by controlling the efficiency of translation of the RepA mRNA. Mutational analysis of the two seven-base complementary sequences involved in formation of the pseudoknot showed that only the five central bases of each were critical for the formation of the pseudoknot. Physical analysis of SLI showed that despite the complete complementarity of its sequence to that of RNAI, the structures of the two molecules are different. The most prominent difference between the two structures is the presence of a 4-base internal loop immediately below the hairpin loop of SLI but not that of RNAI. Closure of this internal loop in SLI resulted in a 40-fold reduction in repA expression and loss of sensitivity of the residual expression to inhibition by RNAI. By contrast, repA expression was largely unaffected by the closure of a lower internal loop whose presence in SLI and RNAI is essential for effective interaction between these two molecules. These results suggest that the interaction of SLI with the distal pseudoknot bases is fundamentally different from the RNAI-SLI binding interaction and that the differences in structure between RNAI and SLI are necessary to allow SLI to be able to efficiently bind RNAI and to participate in pseudoknot formation.

Mutations that suppress the thermosensitivity of green fluorescent protein.

BACKGROUND: The green fluorescent protein (GFP) of the jellyfish Aequorea victoria has recently attracted great interest as the first example of a cloned reporter protein that is intrinsically fluorescent. Although successful in some organisms, heterologous expression of GFP has not always been straight forward. In particular, expression of GFP in cells that require incubation temperatures around 37 degrees C has been problematic. RESULTS: We have carried out a screen for mutant forms of GFP that fluoresce more intensely than the wild-type protein when expressed in E. coli at 37 degrees C. We have characterized a bright mutant (GFPA) with reduced sensitivity to temperature in both bacteria and yeast, and have shown that the amino acids substituted in GFPA act by preventing temperature-dependent misfolding of the GFP apoprotein. We have shown that the excitation and emission spectra of GFPA can be manipulated by site-directed mutagenesis without disturbing its improved folding characteristics, and have produced a thermostable folding mutant (GFP5) that can be efficiently excited using either long-wavelength ultraviolet or blue light. Expression of GFP5 results in greatly improved levels of fluorescence in both microbial and mammalian cells cultured at 37 degrees C. CONCLUSIONS: The thermotolerant mutants of GFP greatly improve the sensitivity of the protein as a visible reporter molecule in bacterial, yeast and mammalian cells. The fluorescence spectra of these mutants can be manipulated by further mutagenesis without deleteriously affecting their improved folding characteristics, so it may be possible to engineer a range of spectral variants with improved tolerance to temperature. Such a range of sensitive reporter proteins will greatly improve the prospects for GFP-based applications in cells that require relatively high incubation temperatures.

An indelible lineage marker for Xenopus using a mutated green fluorescent protein.

We describe the use of a DNA construct (named GFP.RN3) encoding green fluorescent protein as a lineage marker for Xenopus embryos. This offers the following advantages over other lineage markers so far used in Xenopus. When injected as synthetic mRNA, its protein emits intense fluorescence in living embryos. It is non-toxic, and the fluorescence does not bleach when viewed under 480 nm light. It is surprisingly stable, being strongly visible up to the feeding tadpole stage (5 days), and in some tissues for several weeks after mRNA injection. We also describe a construct that encodes a blue fluorescent protein. We exemplify the use of this GFP.RN3 construct for marking the lineage of individual blastomeres at the 32- to 64-cell stage, and as a marker for single transplanted blastula cells. Both procedures have revealed that the descendants of one embryonic cell can contribute single muscle cells to nearly all segmental myotomes rather than predominantly to any one myotome. An independent aim of our work has been to follow the fate of cells in which an early regulatory gene has been temporarily overexpressed. For this purpose, we co-injected GFP.RN3 mRNA and mRNA for the early Xenopus gene Eomes, and found that a high concentration of Eomes results in ectopic muscle gene activation in only the injected cells. This marker may therefore be of general value in providing long term identification of those cells in which an early gene with ephemeral expression has been overexpressed.

Mechanism of binding of the antisense and target RNAs involved in the regulation of IncB plasmid replication.

The replication frequency of the IncB miniplasmid pMU720 is dependent upon the expression of the repA gene. Binding of a small, highly structured, antisense RNA (RNA I) to its complementary target in the RepA mRNA (RNA II) inhibits repA expression and thus regulates replication. Analyses of binding of RNA I to RNA II indicated that the reaction consists of three major steps. The first step, initial kissing complex formation, involves base pairing between complementary sequences in the hairpin loops of RNA I and RNA II. The second step is facilitated by interior loop structures in the upper stems of RNA I and RNA II and involves intrastand melting and interstrand pairing of the upper stem regions to form an extended kissing complex. This complex was shown to be sufficient for inhibition of repA expression. The third step involves stabilization of the extended kissing complex by pairing between complementary single-stranded tail regions of RNA I and RNA II. Thus, the final product of RNA I-RNA II binding is not a full duplex between the two molecules.

Interaction between the antisense and target RNAs involved in the regulation of IncB plasmid replication.

Physical analysis of RNA I, the small antisense RNA which regulates the replication of IncB miniplasmid pMU720, showed that it is a highly structured molecule containing an imperfectly paired stem closed by a 6-base hairpin loop. Mutational studies revealed that a 3-base sequence in the hairpin loop is critical to the interaction between RNA I and its complementary target in the RepA mRNA (RNA II). Furthermore, a 2-base interior loop in the upper stem was found to play an important role in facilitating effective binding between RNA I and RNA II. From these analyses, a model describing the molecular mechanism of binding between RNA I and RNA II is proposed.