Yves Bigot

The Human SETMAR Protein Preserves Most of the Activities of the Ancestral Hsmar1 Transposase

ABSTRACT Transposons have contributed protein coding sequences to a unexpectedly large number of human genes. Except for the V(D)J recombinase and telomerase, all remain of unknown function. Here we investigate the activity of the human SETMAR protein, a highly expressed fusion between a histone H3 methylase and a mariner family transposase. Although SETMAR has demonstrated methylase activity and a DNA repair phenotype, its mode of action and the role of the transposase domain remain obscure. As a starting point to address this problem, we have dissected the activity of the transposase domain in the context of the full-length protein and the isolated transposase domain. Complete transposition of an engineered Hsmar1 transposon by the transposase domain was detected, although the extent of the reaction was limited by a severe defect for cleavage at the 3′ ends of the element. Despite this problem, SETMAR retains robust activity for the other stages of the Hsmar1 transposition reaction, namely, site-specific DNA binding to the transposon ends, assembly of a paired-ends complex, cleavage of the 5′ end of the element in Mn2+, and integration at a TA dinucleotide target site. SETMAR is unlikely to catalyze transposition in the human genome, although the nicking activity may have a role in the DNA repair phenotype. The key activity for the mariner domain is therefore the robust DNA-binding and looping activity which has a high potential for targeting the histone methylase domain to the many thousands of specific binding sites in the human genome provided by copies of the Hsmar1 transposon.

Human and other mammalian genomes contain transposons of the mariner family

Internal fragments of the putative transposase gene of mariner‐like elements (MLEs) were amplified from human, mouse, rat, chinese hamster, sheep and bovine genomic DNAs by polymerase chain reaction (PCR). The sequences identified in human, ovine and bovine genomes correspond to ancient degenerate transposons. Screening mammalian sequence libraries identified a truncated element in the human ABL gene and the sequence of its 5′‐ITR was determined. This ITR sequences were used in PCR experiments with DNA from six mammalian species and detected full‐sized and deleted MLEs. The presence of MLE in mammalian genomes demonstrates that they are ubiquitous mobile elements found from fungi to man. This observation strongly raises the possibility that MLE could constitute tools for the modification of eucaryotic genomes.

Biological and molecular features of the relationships between Diadromus pulchellus ascovirus, a parasitoid hymenopteran wasp (Diadromus pulchellus) and its lepidopteran host, Acrolepiopsis assectella.

The Diadromus pulchellus ascovirus (DpAV) has been isolated from laboratory strains of Diadromus pulchellus and in natural wild populations collected from the Antibes locality (southern France). The DpAV genome was found in the cells of the head, thorax and abdomen of this hymenopteran wasp. DpAV virions are present in the female genitalia and are transmitted to the nymphal lepidopteran host, Acrolepiopsis assectella, at each oviposition of the female wasp. The presence of the DpAV genome in all Diadromus somatic cells suggests that it is inherited by vertical transmission. DpAV is amplified in the host tissues during the larval development of D. pulchellus in A. assectella. Cell lysis due to amplification of the virus does not prevent the development of the hymenopteran larva. Virus amplification appears to be slower in nymphs parasitized by D. pulchellus than in nymphs artificially infected with DpAV alone. Lysis of the nymphal cells due to viral replication seems to be synchronous with egg hatching and the development of the hymenopteran larva. The features of DpAV and its relationship with the parasitoid wasp D. pulchellus during its development are compared to those of the ichnoviruses.

Features of DNA fragments obtained by random amplified polymorphic DNA (RAPD) assays

Random amplified polymorphic DNA (RAPD) fragments were prepared from samples of Calonectris diomedea (Corys shearwater, Aves) and Haemonchus contortus (Nematoda) DNA by polymerase chain reaction (PCR) using decamers containing two restriction enzyme sites as primers. Six of 19 studied RAPD fragments probably originated from traces of commensal microorganisms. Many rearranged fragments, absent in the original genomic DNA, were synthesized and amplified during the processing of all the DNA samples, indicating that interactions occur within and between strands during the annealing step of PCR. The model of interactions between molecular species during DNA amplification with a single arbitrary oligonucleotide primer was modified to include nested primer annealing and interactions within and between strands. The presence of these artefacts in the final RAPD have a major effect on the interpretation of polymorphism studies.

The ITR binding domain of the Mariner Mos-1 transposase

Abstract Mariner-like elements are widespread eukaryotic transposons, but Mos-1 is the only natural element that is known to be active. Little is known about the biochemistry of mariner transposition. The first step in the process is the binding of the transposase to the 5′ and 3′ inverted terminal repeats (ITRs) of the element. Using the 3′ ITR of the element, we have determined the binding properties of a recombinant Mos-1 transposase produced in bacteria, and we have used deletion derivatives to localize the minimal ITR binding domain between amino acids 1 and 141. Its features and structure indicate that it differs from the ITR binding domain of the transposase encoded by Tc1-related elements.

Assembly of the Tc1 and mariner transposition initiation complexes depends on the origins of their transposase DNA binding domains

In this review, we focus on the assembly of DNA/protein complexes that trigger transposition in eukaryotic members of the IS630–Tc1–mariner (ITm) super-family, the Tc1- and mariner-like elements (TLEs and MLEs). Elements belonging to this super-family encode transposases with DNA binding domains of different origins, and recent data indicate that the chimerization of functional domains has been an important evolutionary aspect in the generation of new transposons within the ITm super-family. These data also reveal that the inverted terminal repeats (ITRs) at the ends of transposons contain three kinds of motif within their sequences. The first two are well known and correspond to the cleavage site on the outer ITR extremities, and the transposase DNA binding site. The organization of ITRs and of the transposase DNA binding domains implies that differing pathways are used by MLEs and TLEs to regulate transposition initiation. These differences imply that the ways ITRs are recognized also differ leading to the formation of differently organized synaptic complexes. The third kind of motif is the transposition enhancers, which have been found in almost all the functional MLEs and TLEs analyzed to date. Finally, in vitro and in vivo assays of various elements all suggest that the transposition initiation complex is not formed randomly, but involves a mechanism of oriented transposon scanning.

Physiological and Biochemical Analysis of Factors in the Female Venom Gland and Larval Salivary Secretions of the Ectoparasitoid Wasp Eupelmus orientalis.

The stinging adult female and the biting newly-hatched larva of the solitary ectoparasitoid wasp Eupelmus orientalis can both cause permanent paralysis and stop the development of Callosobruchus maculatus host larvae. These two processes of host envenomation appeared to be independent and complementary in primary parasitism or in hyperparasitism of a distantly related hymenopteran host species. In contrast, the development of larvae as hyperparasites on members of their own species or genus depended completely on the prior injection of female venom. The venoms of the female and the first instar larva had similar effects on the cellular metabolism of the primary hosts. Protein synthesis was blocked in C. maculatus hosts envenomated by a female or a first instar larva of E. orientalis, but the absence of DNA breakdown indicated that these paralysed hosts were alive and quiescent. The venomous secretions injected by adult females and first instar larvae of E. orientalis had distinct electrophoretic profiles. The immunoreactive features of proteins from female venom and larval secretions were also examined. There is evidence for antigenic conservation between some venom proteins of E. orientalis and Apis mellifera. Lastly, the hyaluronidase, phospholipase and lipase activities in the female venom gland and in larval-derived secretions of E. orientalis were assayed. No lipase activity was detected. Phospholipase activity was found in both the female venom and the larval secretions of E. orientalis, whereas hyaluronidase was specific to the female venom.

The wild-type conformation of the Mos-1 inverted terminal repeats is suboptimal for transposition in bacteria.

The two inverted terminal repeats (ITRs) flanking the Mos-1 mariner element differ in sequence at four positions. Gel retardation experiments indicated that each of these differences has a significant impact on the quality of the interaction between the ITR and the Mos-1 transposase. We showed that the transposase binds to the 3′ ITR better than to the 5′ ITR. The results of transposition assays performed in Escherichia coli indicated that these differences have an influence on the rate of transposition and the stability of the transposition products. Finally, we find that the wild-type configuration of the Mos-1 element, with one 5′ ITR and one 3′ ITR, is less efficient for transposition in bacteria than that of an element having two 3′ ITRs.

Assembly of the mariner Mos1 Synaptic Complex

ABSTRACT The mobility of transposable elements via a cut-and-paste mechanism depends on the elaboration of a nucleoprotein complex known as the synaptic complex. We show here that the Mos1 synaptic complex consists of the two inverted terminal repeats of the element brought together by a transposase tetramer and is designated paired-end complex 2 (PEC2). The assembly of PEC2 requires the formation of a simpler complex, containing one terminal repeat and two transposase molecules and designated single-end complex 2 (SEC2). In light of the formation of SEC2 and PEC2, we demonstrate the presence of two binding sites for the transposase within a single terminal repeat. We have found that the sequence of the Mos1 inverted terminal repeats contains overlapping palindromic and mirror motifs, which could account for the binding of two transposase molecules “side by side” on the same inverted terminal repeat. We provide data indicating that the Mos1 transposase dimer is formed within a single terminal repeat through a cooperative pathway. Finally, the concept of a tetrameric synaptic complex may simply account for the inability of a single mariner transposase molecule to interact at the same time with two kinds of DNA: the inverted repeat and the target DNA.

Genomic Sequence of Spodoptera frugiperda Ascovirus 1a, an Enveloped, Double-Stranded DNA Insect Virus That Manipulates Apoptosis for Viral Reproduction

ABSTRACT Ascoviruses (family Ascoviridae) are double-stranded DNA viruses with circular genomes that attack lepidopterans, where they produce large, enveloped virions, 150 by 400 nm, and cause a chronic, fatal disease with a cytopathology resembling that of apoptosis. After infection, host cell DNA is degraded, the nucleus fragments, and the cell then cleaves into large virion-containing vesicles. These vesicles and virions circulate in the hemolymph, where they are acquired by parasitic wasps during oviposition and subsequently transmitted to new hosts. To develop a better understanding of ascovirus biology, we sequenced the genome of the type species Spodoptera frugiperda ascovirus 1a (SfAV-1a). The genome consisted of 156,922 bp, with a G+C ratio of 49.2%, and contained 123 putative open reading frames coding for a variety of enzymes and virion structural proteins, of which tentative functions were assigned to 44. Among the most interesting enzymes, due to their potential role in apoptosis and viral vesicle formation, were a caspase, a cathepsin B, several kinases, E3 ubiquitin ligases, and especially several enzymes involved in lipid metabolism, including a fatty acid elongase, a sphingomyelinase, a phosphate acyltransferase, and a patatin-like phospholipase. Comparison of SfAV-1a proteins with those of other viruses showed that 10% were orthologs of Chilo iridescent virus proteins, the highest correspondence with any virus, providing further evidence that ascoviruses evolved from a lepidopteran iridovirus. The SfAV-1a genome sequence will facilitate the determination of how ascoviruses manipulate apoptosis to generate the novel virion-containing vesicles characteristic of these viruses and enable study of their origin and evolution.