Cauliflower fractal forms arise from perturbations of floral gene networks.

Throughout development, plant meristems regularly produce organs in defined spiral, opposite, or whorl patterns. Cauliflowers present an unusual organ arrangement with a multitude of spirals nested over a wide range of scales. How such a fractal, self-similar organization emerges from developmental mechanisms has remained elusive.

Unwinding BRAHMA Functions in Plants.

The ATP-dependent Switch/Sucrose non-fermenting (SWI/SNF) chromatin remodeling complex (CRC) regulates the transcription of many genes by destabilizing interactions between DNA and histones. In plants, BRAHMA (BRM), one of the two catalytic ATPase subunits of the complex, is the closest homolog of the yeast and animal SWI2/SNF2 ATPases. We summarize here the advances describing the roles of BRM in plant development as well as its recently reported chromatin-independent role in pri-miRNA processing in vitro and in vivo.

LEAFY activity is post-transcriptionally regulated by BLADE ON PETIOLE2 and CULLIN3 in Arabidopsis.

The Arabidopsis LEAFY (LFY) transcription factor is a key regulator of floral meristem emergence and identity. LFY interacts genetically and physically with UNUSUAL FLORAL ORGANS, a substrate adaptor of CULLIN1-RING ubiquitin ligase complexes (CRL1). The functionally redundant genes BLADE ON PETIOLE1 (BOP1) and -2 (BOP2) are potential candidates to regulate LFY activity and have recently been shown to be substrate adaptors of CULLIN3 (CUL3)-RING ubiquitin ligases (CRL3).

A variant of LEAFY reveals its capacity to stimulate meristem development by inducing RAX1.

In indeterminate inflorescences, floral meristems develop on the flanks of the shoot apical meristem, at positions determined by auxin maxima. The floral identity of these meristems is conferred by a handful of genes called floral meristem identity genes, among which the LEAFY (LFY) transcription factor plays a prominent role. However, the molecular mechanism controlling the early emergence of floral meristems remains unknown.

RecA-promoted, RecFOR-independent progressive disassembly of replisomes stalled by helicase inactivation.

In all organisms, replication impairment is a recognized source of genomic instability, raising an increasing interest in the fate of inactivated replication forks. We used Escherichia coli strains with a temperature-inactivated replicative helicase (DnaB) and in vivo single-molecule microscopy to quantify the detailed molecular processing of stalled replication forks. After helicase inactivation, RecA binds to blocked replication forks and is essential for the rapid release of hPol III.

ruvA and ruvB mutants specifically impaired for replication fork reversal.

Replication fork reversal (RFR) is a reaction that takes place in Escherichia coli at replication forks arrested by the inactivation of a replication protein. Fork reversal involves the annealing of the leading and lagging strand ends; it results in the formation of a Holliday junction adjacent to DNA double-strand end, both of which are processed by recombination enzymes. In several replication mutants, replication fork reversal is catalysed by the RuvAB complex, originally characterized for its role in the last steps of homologous recombination, branch migration and resolution of Holliday junctions.

ruvA Mutants that resolve Holliday junctions but do not reverse replication forks.

RuvAB and RuvABC complexes catalyze branch migration and resolution of Holliday junctions (HJs) respectively. In addition to their action in the last steps of homologous recombination, they process HJs made by replication fork reversal, a reaction which occurs at inactivated replication forks by the annealing of blocked leading and lagging strand ends. RuvAB was recently proposed to bind replication forks and directly catalyze their conversion into HJs.

Recombination proteins and rescue of arrested replication forks.

Recombination proteins play crucial roles in the rescue of inactivated replication forks in Escherichia coli. The enzymes that catalyze the repair of DNA double-strand breaks by a classical strand-exchange reaction (RecBCD, RecA) act in two well-characterized fork repair pathways. They repair the DNA double-strand end made when a replication fork runs into a single-strand interruption.