Reaction-diffusion approach to prevertebrae formation: effect of a local source of morphogen.

Periodic structure formation is an essential feature of embryonic development. Many models of this phenomenon, most of them based on time oscillations, have been proposed. However, temporal oscillations are not always observed during development and how a spatial periodic structure is formed still remains under question. We investigate a reaction-diffusion model, in which a Turing pattern develops without temporal oscillations, to assess its ability to account for the formation of prevertebrae. We propose a correspondence between the species of the reaction scheme and biologically relevant molecules known as morphogens. It is shown that the model satisfactorily reproduces experiments involving grafting of morphogen sources into the embryos. Using a master equation approach and the direct simulation Monte Carlo method, we examine the robustness of the results to internal fluctuations.

RAD51-independent break-induced replication to repair a broken chromosome depends on a distant enhancer site.

Without the RAD51 strand exchange protein, Saccharomyces cerevisiae cannot repair a double-strand break (DSB) by gene conversion. However, cells can repair DSBs by recombination-dependent, break-induced replication (BIR). RAD51-independent BIR is initiated more than 13 kb from the DSB. Repair depends on a 200-bp sequence adjacent to ARS310, located approximately 34 kb centromere-proximal to the DSB, but does not depend on the origin activity of ARS310. We conclude that the ability of a recombination-induced replication fork to copy > 130 kb to the end of the chromosome depends on a special site that enhances assembly of a processive repair replication fork.

Genetic requirements for RAD51- and RAD54-independent break-induced replication repair of a chromosomal double-strand break.

Broken chromosomes can be repaired by several homologous recombination mechanisms, including gene conversion and break-induced replication (BIR). In Saccharomyces cerevisiae, an HO endonuclease-induced double-strand break (DSB) is normally repaired by gene conversion. Previously, we have shown that in the absence of RAD52, repair is nearly absent and diploid cells lose the broken chromosome; however, in cells lacking RAD51, gene conversion is absent but cells can repair the DSB by BIR. We now report that gene conversion is also abolished when RAD54, RAD55, and RAD57 are deleted but BIR occurs, as with rad51Delta cells. DSB-induced gene conversion is not significantly affected when RAD50, RAD59, TID1 (RDH54), SRS2, or SGS1 is deleted. Various double mutations largely eliminate both gene conversion and BIR, including rad51Delta rad50Delta, rad51Delta rad59Delta, and rad54Delta tid1Delta. These results demonstrate that there is a RAD51- and RAD54-independent BIR pathway that requires RAD59, TID1, RAD50, and presumably MRE11 and XRS2. The similar genetic requirements for BIR and telomere maintenance in the absence of telomerase also suggest that these two processes proceed by similar mechanisms.

Negative and positive regulation of Tn10/IS10-promoted recombination by IHF: two distinguishable processes inhibit transposition off of multicopy plasmid replicons and activate chromosomal events that favor evolution of new transposons.

Tn10 is a composite transposon; inverted repeats of insertion sequence IS10 flank a tetracycline-resistance determinant. Previous work has identified several regulatory processes that modulate the interaction between Tn10 and its host. Among these, host-specified DNA adenine methylation, an IS10-encoded antisense RNA and preferential cis action of transposase are particularly important. We now find that the accessory host protein IHF and the sequences that encode the IHF-binding site in IS10 are also important regulators of the Tn10 transposition reaction in vivo and that these determinants are involved in two distinguishable regulatory processes. First, IHF and the IHF-binding site of IS10, together with other host components (e.g., HU), negatively regulate the normal intermolecular transposition process. Such negative regulation is prominent only for elements present on multicopy plasmid replicons. This multicopy plasmid-specific regulation involves effects both on the transposition reaction per se and on transposase gene expression. Second, specific interaction of IHF with its binding site stimulates transposon-promoted chromosome rearrangements but not transposition of a short Tn10-length chromosomal element. However, additional considerations predict that IHF action should favor chromosomal transposition for very long composite elements. On the basis of these and other observations we propose that, for chromosomal events, the major role of IHF is to promote the evolution of new IS10-based composite transposons.

Mutational analysis of IS10's outside end.

We present the genetic analysis of a large number of mutations in the outside end of insertion sequence IS10. (i) The terminal inverted repeat sequence is probably the primary site of transposase binding. Mutations in this region fall into phenotypic classes which correspond to their map locations, suggesting that this region may consist of several distinct functional segments. Similarities between the organization of IS10's inverted repeat and those of other transposable elements are discussed. (ii) Base pairs 23-42 include a consensus binding sequence for one of the IS10 transposition host factors, IHF. The phenotypes of mutations in this region suggest that IHF is the major host factor for outside-end transposition activity in vivo and that base pairs throughout this region are important for the IHF interaction. (iii) Mutations in bp 43-61 do not affect outside-end transposition activity but do affect, in expected ways, previously identified determinants involved in expression and regulation of transposase. (iv) Some mutations in bp 23-42 also affect transposase expression; the possibility that IHF negatively regulates transcription initiation is discussed.

Mechanism of renaturation of a large protein, aspartokinase-homoserine dehydrogenase.

The renaturation of aspartokinase-homoserine dehydrogenase and of some of its smaller fragments has been investigated after complete unfolding by 6 M guanidine hydrochloride. Fluorescence measurements show that a major folding reaction occurs rapidly (in less than a few seconds) after the protein has been transferred to native conditions and results in the shielding of the tryptophan residues from the aqueous solvent; this step also takes place in the fragments and probably corresponds to the independent folding of different segments along the polypeptide chain. The reappearance of the kinase activity, which is an index of the formation of "native" structure within a single chain, is much slower (a few minutes) and has the following properties: it is involved in a kinetic competition with the formation of aggregates; it has an activation energy of 22 +/- 5 kcal/mol; it is not related to a slow reaction in unfolding and thus probably not controlled by the cis-trans isomerization of X-Pro peptide bonds; its rate is inversely proportional to the solvent viscosity. It seems as if this reaction is limited by the mutual arrangement of the regions that have folded rapidly and independently. It is proposed that the mechanism where a fast folding of domains is followed by a slow pairing of folded domains could be generalized to other long chains composed of several domains; such a slow pairing of folded domains would correspond to a rate-limiting process specific to the renaturation of large proteins. The reappearance of the dehydrogenase activity measures the formation of a dimeric species. The dimerization can occur only after each chain has reached its "native" conformation.(ABSTRACT TRUNCATED AT 250 WORDS)