René Rezsohazy

The IS4 family of insertion sequences: evidence for a conserved transposase motif.

The eight IS 231 variants characterized so far (IS 231 A‐F, V and W) display similar transposases with an overall 40% identity. Comparison with all the proka‐ryotic transposable elements sequenced so far revealed that the IS231 transposases share two conserved regions with those of 35 other insertion sequences of wide origins. These insertion sequences, defining the IS4 family, have a common bipartite organization of their ends and are divided into two similarity groups. Interestingly, the transposase domains conserved within this family display similarities with the well known integrase domain shared by transposases of the IS3 and IS15 families, and integrases of retroelements. This domain is also found in IS30‐ related elements and Tn7 TnsB protein. Amino acid residues conserved throughout all these prokaryotic and eukaryotic mobile genetic elements define a major transposase/integrase motif, likely to play an important role in the transposition process.

IS231 and other Bacillus thuringiensis transposable elements: a review.

Bacillus thuringiensis is an entomopathogenic bacterium whose toxicity is due to the presence in the sporangia of δ-endotoxin crystals active against agricultural pests and vectors of human and animal diseases. Most of the genes coding for these toxin proteins are plasmid-borne and are generally structurally associated with insertion sequences (IS231, IS232, IS240, ISBT1 and ISBT2) and transposons (Tn4430 and Tn5401). Several of these mobile elements have been shown to be active and are believed to participate in the crystal gene mobility, thereby contributing to the variation of bacterial toxicity. Structural analysis of the iso-IS231 elements indicates that they are related to IS1151 fromClostridium perfringens and distantly related to IS4 and IS186 fromEscherichia coli. Like the other IS4 family members, they contain a conserved transposase-integrase motif found in other IS families and retroviruses. Moreover, functional data gathered from IS231 A inEscherichia coli indicate a non-replicative mode of transposition, with a marked preference for specific targets. Similar results were also obtained inBacillus subtilis andB. thuringiensis, and a working model for DNA-protein interactions at the target site is proposed.

IS231A insertion specificity: consensus sequence and DNA bending at the target site.

In its natural host, Bacillus thuringiensis, the insertion sequence IS231A is preferentially inserted into the terminal inverted repeats of the transposon Tn4430. Using a novel transposition assay, we demonstrate that the Tn4430 ends behave as insertion hot spots for IS231A in Escherichia coli. Sequence analysis reveals that IS231A insertion sites match the 5′‐GGG(N)5CCC‐3′consensus. However, this consensus is not the only determinant of IS231A insertion specificity. Although both Tn4430 ends have identical sequences, one is strongly preferred to the other and the orientation of insertion into this end is not random. We demonstrate that this preference is determined by the flanking regions of the site. These regions display a conserved periodic organization of their sequence which, by conferring anisotropic flexibility, would induce the DNA to bend in a roughly ‘S’ ‐shaped structure centred on the target consensus. DNA conformation analysis by polyacrylamide gel electrophoresis indeed shows that the preferred target site of IS231A is flanked by DNA segments curved in opposite directions. We present a model in which DNA bendability and curvature would contribute to the positioning of IS231A transposase on the target DNA.

An ultraconserved Hox–Pbx responsive element resides in the coding sequence of Hoxa2 and is active in rhombomere 4

The Hoxa2 gene has a fundamental role in vertebrate craniofacial and hindbrain patterning. Segmental control of Hoxa2 expression is crucial to its function and several studies have highlighted transcriptional regulatory elements governing its activity in distinct rhombomeres. Here, we identify a putative Hox–Pbx responsive cis-regulatory sequence, which resides in the coding sequence of Hoxa2 and is an important component of Hoxa2 regulation in rhombomere (r) 4. By using cell transfection and chromatin immunoprecipitation (ChIP) assays, we show that this regulatory sequence is responsive to paralogue group 1 and 2 Hox proteins and to their Pbx co-factors. Importantly, we also show that the Hox–Pbx element cooperates with a previously reported Hoxa2 r4 intronic enhancer and that its integrity is required to drive specific reporter gene expression in r4 upon electroporation in the chick embryo hindbrain. Thus, both intronic as well as exonic regulatory sequences are involved in Hoxa2 segmental regulation in the developing r4. Finally, we found that the Hox–Pbx exonic element is embedded in a larger 205-bp long ultraconserved genomic element (UCE) shared by all vertebrate genomes. In this respect, our data further support the idea that extreme conservation of UCE sequences may be the result of multiple superposed functional and evolutionary constraints.

The Nuclear Factor κB–Activator Gene PLEKHG5 Is Mutated in a Form of Autosomal Recessive Lower Motor Neuron Disease with Childhood Onset

Lower motor neuron diseases (LMNDs) include a large spectrum of clinically and genetically heterogeneous disorders. Studying a large inbred African family, we recently described a novel autosomal recessive LMND variant characterized by childhood onset, generalized muscle involvement, and severe outcome, and we mapped the disease gene to a 3.9-cM interval on chromosome 1p36. We identified a homozygous missense mutation (c.1940 T-->C [p.647 Phe-->Ser]) of the Pleckstrin homology domain-containing, family G member 5 gene, PLEKHG5. In transiently transfected HEK293 and MCF10A cell lines, we found that wild-type PLEKHG5 activated the nuclear factor kappa B (NF kappa B) signaling pathway and that both the stability and the intracellular location of mutant PLEKHG5 protein were altered, severely impairing the NF kappa B transduction pathway. Moreover, aggregates were observed in transiently transfected NSC34 murine motor neurons overexpressing the mutant PLEKHG5 protein. Both loss of PLEKHG5 function and aggregate formation may contribute to neurotoxicity in this novel form of LMND.

Cellular and molecular insights into Hox protein action.

Hox genes encode homeodomain transcription factors that control morphogenesis and have established functions in development and evolution. Hox proteins have remained enigmatic with regard to the molecular mechanisms that endow them with specific and diverse functions, and to the cellular functions that they control. Here, we review recent examples of Hox-controlled cellular functions that highlight their versatile and highly context-dependent activity. This provides the setting to discuss how Hox proteins control morphogenesis and organogenesis. We then summarise the molecular modalities underlying Hox protein function, in particular in light of current models of transcription factor function. Finally, we discuss how functional divergence between Hox proteins might be achieved to give rise to the many facets of their action. Summary: This Review discusses the molecular and cellular scale mechanisms underlying the diverse roles of the Hox transcription factors during morphogenesis and organogenesis.

Loss of Function but No Gain of Function Caused by Amino Acid Substitutions in the Hexapeptide of Hoxa1 In Vivo

ABSTRACT Homeodomain containing transcription factors of the Hox family play critical roles in patterning the anteroposterior embryonic body axis, as well as in controlling several steps of organogenesis. Several Hox proteins have been shown to cooperate with members of the Pbx family for the recognition and activation of identified target enhancers. Hox proteins contact Pbx via a conserved hexapeptide motif. Previous biochemical studies provided evidence that critical amino acid substitutions in the hexapeptide sequence of Hoxa1 abolish its interaction with Pbx. As a result, these substitutions also abolish Hoxa1 activity on known target enhancers in cellular models, suggesting that Hoxa1 activity relies on its capacity to interact with Pbx. Here, we show that mice with mutations in the Hoxa1 hexapeptide display hindbrain, cranial nerve, and skeletal defects highly reminiscent of those reported for the Hoxa1 loss of function. Since similar hexapeptide mutations in the mouse Hoxb8 and the Drosophila AbdA proteins result in activity modulation and gain of function, our data demonstrate that the functional importance of the hexapeptide in vivo differs according to the Hox proteins.

Hox Proteins Display a Common and Ancestral Ability to Diversify Their Interaction Mode with the PBC Class Cofactors

Hox protein function during development and evolution relies on conserved multiple interaction modes with cofactors of the PBC and Meis families.

IS231D, E and F, three new insertion sequences in Bacillus thuringiensis: extension of the IS231 family.

IS231 constitutes a family of insertion sequences widespread among Bacillus thuringiensis subspecies. Three new IS231 variants have been isolated from B. thuringiensis subspecies finitimus (IS231 D and E) and israelensis (IS231 F). Like the previously described IS231 A, B and C, these 1.7 kb elements display single open reading frames encoding 477/478‐amino‐acid proteins which share between 72% and 88% identity with those of the other members of the family. Sequence comparisons also reveal that all the iso‐IS231 terminal inverted repeats are strongly conserved 20bp sequences. A region susceptible to forming a stable hairpin structure is found just upstream of the open reading frame. Nucleotide substitutions occurring on one strand of the hairpin stems are compensated for by complementary changes at facing positions, giving credence to the hypothesis that this secondary structure plays a role in the regulation of transposition. Examination of IS231 D, E and F flanking sequences reveals that IS231 F is bordered by a 12bp direct repeat. No direct repeats were found flanking IS231 D or IS231 E.

Differential and opposed transcriptional effects of protein fusions containing the VP16 activation domain.

Overexpression of strong transcriptional activators like herpes simplex virion protein 16 (VP16) may lead to non‐specific inhibition of gene expression as a result of the titration of transcription factors. Here we report that a fusion between the homeoprotein Hoxa2 and the VP16 activation domain inhibits transcription from the strong promoter/enhancers of cytomegalovirus (CMV) and Rous sarcoma virus (RSV). A similar fusion involving a Hoxa2 mutant protein that is defective in DNA binding has no effect on the CMV promoter but increases, rather than inhibits, the RSV promoter activity. This suggests that depending on its ability to bind DNA, the VP16 activator can interact with different sets of cofactors, giving rise to distinct transcriptional effects.