Sibyle Moulin

Characterization of the atypical karyotype of the black-winged kite Elanus caeruleus (Falconiformes: Accipitridae) by means of classical and molecular cytogenetic techniques.

The karyotype of the black-winged kite (Elanus caeruleus), a small diurnal raptor living in Africa, Asia and southern Europe, was studied with classical (G-, C-, R-banding, and Ag-NOR staining) and molecular cytogenetic methods, including primed in-situ labelling (PRINS) and fluorescence in-situ hybridization (FISH) with telomeric (TTAGGG) and centromeric DNA repeats. The study revealed that the genome size, measured by flow cytometry (3.1 pg), is in the normal avian range. However, the black-winged kite karyotype is particularly unusual among birds in having a moderate diploid number of 68 chromosomes, and containing only one pair of dot-shaped microchromosomes. Moreover, the macrochromosomes are medium-sized, with the Z and W gonosomes being clearly the largest in the set. C-banding shows that constitutive heterochromatin is located at the centromeric regions of all chromosomes, and that two pairs of small acrocentrics and the pair of microchromosomes are almost entirely heterochromatic and G-band negative. The distribution pattern of a centromeric repeated DNA sequence, as demonstrated by PRINS, follows that of C-heterochromatin. The localization of telomeric sequences by FISH and PRINS reveals many strong telomeric signals but no extratelomeric signal was observed. The atypical organization of the karyotype of the black-winged kite is considered in the context of the modes of karyotypic evolution in birds.

Phylogenomics of African guenons

The karyotypes of 28 specimens belonging to 26 species of Cercopithecinae have been compared with each other and with human karyotype by chromosome banding and, for some of them, by Zoo-FISH (human painting probes) techniques. The study includes the first description of the karyotypes of four species and a synonym of Cercopithecus nictitans. The chromosomal homologies obtained provide us with new data on a large number of rearrangements. This allows us to code chromosomal characters to draw Cercopithecini phylogenetic trees, which are compared to phylogenetic data based on DNA sequences. Our findings show that some of the superspecies proposed by Kingdon (1997The Kingdon Field Guide to African Mammals, Academic Press.) and Groves (2001Primates Taxonomy, Smithsonian Institution Press) do not form homogeneous groups and that the genus Cercopithecus is paraphyletic, in agreement with previous molecular analyses. The evolution of Cercopithecini karyotypes is mainly due to non-centromeric chromosome fissions and centromeric shifts or inversions. Non-Robertsonian translocations occurred in C. hamlyni and C. neglectus. The position of chromosomal rearrangements in the phylogenetic tree leads us to propose that the Cercopithecini evolution proceeded by either repeated fission events facilitated by peculiar genomic structures or successive reticulate phases, in which heterozygous populations for few rearranged chromosomes were present, allowing the spreading of chromosomal forms in various combinations, before the speciation process.

Use of meiotic pachytene stage of spermatocytes for karyotypic studies in insects

Coleopterans represent by far the largest animal group, with more than 300,000 identified species. Only little progress in their chromosome analysis has been accomplished during recent decades, compared with that made in vertebrate cytogenetics. Both the small size of their genome and the difficulty of obtaining mitotic cells with nice chromosomes have limited the application of conventional techniques, such as chromosome banding. A method for obtaining chromosome banding on well-spread bivalents from the pachytene stage of the meiotic prophase, the most frequent stage in young imagines, is described. It makes possible the identification of all bivalents and the establishment of the karyotype with greater ease and accuracy than with mitotic cells. In addition, it gives some insight into chromosome organization at a stage when autosomes are assumed to undergo an intense transcriptional activity. The results of the technique, which was successfully applied to many species, are described here in two of them, Cetonia aurata and Adesmia montana as examples.

A fifth major genetic group among honeybees revealed in Syria

BackgroundApiculture has been practiced in North Africa and the Middle-East from antiquity. Several thousand years of selective breeding have left a mosaic of Apis mellifera subspecies in the Middle-East, many uniquely adapted and survived to local environmental conditions. In this study we explore the genetic diversity of A. mellifera from Syria (n = 1258), Lebanon (n = 169) and Iraq (n = 35) based on 14 short tandem repeat (STR) loci in the context of reference populations from throughout the Old World (n = 732).ResultsOur data suggest that the Syrian honeybee Apis mellifera syriaca occurs in both Syrian and Lebanese territories, with no significant genetic variability between respective populations from Syria and Lebanon. All studied populations clustered within a new fifth independent nuclear cluster, congruent with an mtDNA Z haplotype identified in a previous study. Syrian honeybee populations are not associated with Oriental lineage O, except for sporadic introgression into some populations close to the Turkish and Iraqi borders. Southern Syrian and Lebanese populations demonstrated high levels of genetic diversity compared to the northern populations.ConclusionThis study revealed the effects of foreign queen importations on Syrian bee populations, especially for the region of Tartus, where extensive introgression of A. m. anatolica and/or A. m. caucasica alleles were identified. The policy of creating genetic conservation centers for the Syrian subspecies should take into consideration the influence of the oriental lineage O from the northern Syrian border and the large population of genetically divergent indigenous honeybees located in southern Syria.

Genotypic Influence on Aversive Conditioning in Honeybees, Using a Novel Thermal Reinforcement Procedure

In Pavlovian conditioning, animals learn to associate initially neutral stimuli with positive or negative outcomes, leading to appetitive and aversive learning respectively. The honeybee (Apis mellifera) is a prominent invertebrate model for studying both versions of olfactory learning and for unraveling the influence of genotype. As a queen bee mates with about 15 males, her worker offspring belong to as many, genetically-different patrilines. While the genetic dependency of appetitive learning is well established in bees, it is not the case for aversive learning, as a robust protocol was only developed recently. In the original conditioning of the sting extension response (SER), bees learn to associate an odor (conditioned stimulus - CS) with an electric shock (unconditioned stimulus - US). This US is however not a natural stimulus for bees, which may represent a potential caveat for dissecting the genetics underlying aversive learning. We thus first tested heat as a potential new US for SER conditioning. We show that thermal stimulation of several sensory structures on the bee’s body triggers the SER, in a temperature-dependent manner. Moreover, heat applied to the antennae, mouthparts or legs is an efficient US for SER conditioning. Then, using microsatellite analysis, we analyzed heat sensitivity and aversive learning performances in ten worker patrilines issued from a naturally inseminated queen. We demonstrate a strong influence of genotype on aversive learning, possibly indicating the existence of a genetic determinism of this capacity. Such determinism could be instrumental for efficient task partitioning within the hive.

Présence d’un caryotype très original à 53–54 chromosomes chez Vesperus xatarti Mulsant 1839 (Coleoptera : Cerambycidae : Vesperinae)

Résumé Après description de techniques permettant ďétablir avec précision le caryotype des coléoptères, I’analyse cytogénétique du Vesperus xatarti est rapportée. Son caryotype est tout à fait particulier, puisqu’il possède 53–54 chromosomes à I’état diploïde, un nombre bien supérieur à ce qui a été rapporté jusqu’ici chez les Coléoptères. Ceci indique qu’une évolution importante, probablement par fissions chromosomiques multiples, en est à I’origine. Utilisation de marquage chromosomique en bandės permet de montrer que la variation de nombre est liée au sexe : 54 chez la femelle et 53 chez le mâle. Cette différence est due au fait que la femelle possède deux pairęs de petits autosomes, et le mâle deux autosomes uniques et un autre chromosome résultant de leur fusion ou de leur maintien non fissionné. Cette particularité, décrite chez ďautres coléoptères comme un système à chromosomes sexuels multiples, n’avait jamais été encore observée chez les Cerambycidae. Ces particularités chromosomiques mériteraient ďêtre prises en compte pour une éventuelle révision de la position systématique des Vespėrus.