Vincenzo Caputo

Strong conservation of the bird Z chromosome in reptilian genomes is revealed by comparative painting despite 275 million years divergence

The divergence of lineages leading to extant squamate reptiles (lizards, snakes, and amphisbaenians) and birds occurred about 275 million years ago. Birds, unlike squamates, have karyotypes that are typified by the presence of a number of very small chromosomes. Hence, a number of chromosome rearrangements might be expected between bird and squamate genomes. We used chromosome-specific DNA from flow-sorted chicken (Gallus gallus) Z sex chromosomes as a probe in cross-species hybridization to metaphase spreads of 28 species from 17 families representing most main squamate lineages and single species of crocodiles and turtles. In all but one case, the Z chromosome was conserved intact despite very ancient divergence of sauropsid lineages. Furthermore, the probe painted an autosomal region in seven species from our sample with characterized sex chromosomes, and this provides evidence against an ancestral avian-like system of sex determination in Squamata. The avian Z chromosome synteny is, therefore, conserved albeit it is not a sex chromosome in these squamate species.

A centromeric satellite DNA may be involved in heterochromatin compactness in gobiid fishes.

Centromere and telomere composition and organization were studied in various gobiid species exhibiting and not exhibiting chromosome polymorphisms involving Robertsonian rearrangements. In Gobius cobitis, we isolated an AT-rich centromeric DNA satellite, designated pCOB, and found that several sequences contain adenine stretches, various CA/TG dinucleotide steps, and a sequence 76% homologous to the yeast CDE III centromeric sequence. All of these traits are generally considered important for centromeric function, and the hypothesis has been advanced that some are involved in the control of DNA curvature and thus in the degree of centromeric chromatin compactness. Based on these features, and on the fact that they are found only in the species not exhibiting Robertsonian biarmed chromosomes, a role for pCOB in preventing centric fusions has been hypothesized. Our data also suggest that, as in other species, the formation of Robertsonian biarmed chromosomes is accompanied by the loss of telomeric sequences.

Karyotype differentiation between two species of carangid fishes, genus Trachurus (Perciformes : Carangidae)

A karyological study ofTrachurus trachurus andT. mediterraneus (Perciformes: Carangidae) was conducted by standard, fluorochrome staining (CMA3, mithramycin, quinacrine mustard, DAPI), C-, Ag-NOR, and Alu-I banding methods. The karyotypes of both species consisted of 2n = 48 chromosomes, but of different FN:T. trachurus possessed a chromosome complement of 2 metacentric and 46 acrocentric elements, fundamental number (FN) = 50 andT. mediterraneus, a chromosome complement of 4 metacentric, 4 submetacentric, 14 subtelocentric and 26 acrocentric chromosomes, FN = 70. In neither of the two taxa investigated were heteromorphic sex chromosomes observed. The nucleolar organizer region was interstitially located on the long arm of the Ist pair of chromosomes in both species, intermediate inT. mediterraneus and subterminal inT. trachurus. Constitutive heterochromatin was found in nearly all centromeric and telomeric regions inT. trachurus; inT. mediterraneus it formed less intense telomeric and centromeric bands and thin interstitial bands on eight chromosome pairs. In addition, the C-positive material reacted differently to the digestion with endonuclease Alu-l in the two species. The results are discussed and compared with karyological data known for other species of Carangidae.

Heterochromatin heterogeneity and chromosome variability in four species of gobiid fishes (Perciformes: Gobiidae)

A karyological study of four species of gobiid fishes, Gobius niger, G. paganellus, G. cobitis, and Zosterisessor ophiocephalus (Perciformes, Gobiidae), was conducted by standard, fluorochrome staining (using chromomycin A3, mithramycin, and DAPI), Alu-I digestion, and CBG- and RBG-banding methods. Our cytogenetic data indicate that heterochromatin in these taxa is highly differentiated, exhibiting heterogeneity in staining characteristics, and presumably in underlying DNA sequences, and a different capability for promoting Robertsonian fusions.

Conservation of chromosomes syntenic with avian autosomes in squamate reptiles revealed by comparative chromosome painting

In contrast to mammals, birds exhibit a slow rate of chromosomal evolution. It is not clear whether high chromosome conservation is an evolutionary novelty of birds or was inherited from an earlier avian ancestor. The evolutionary conservatism of macrochromosomes between birds and turtles supports the latter possibility; however, the rate of chromosomal evolution is largely unknown in other sauropsids. In squamates, we previously reported strong conservatism of the chromosomes syntenic with the avian Z, which could reflect a peculiarity of this part of the genome. The chromosome 1 of iguanians and snakes is largely syntenic with chromosomes 3, 5 and 7 of the avian ancestral karyotype. In this project, we used comparative chromosome painting to determine how widely this synteny is conserved across nine families covering most of the main lineages of Squamata. The results suggest that the association of the avian ancestral chromosomes 3, 5 and 7 can be dated back to at least the early Jurassic and could be an ancestral characteristic for Unidentata (Serpentes, Iguania, Anguimorpha, Laterata and Scinciformata). In Squamata chromosome conservatism therefore also holds for the parts of the genome which are homologous to bird autosomes, and following on from this, a slow rate of chromosomal evolution could be a common characteristic of all sauropsids. The large evolutionary stasis in chromosome organization in birds therefore seems to be inherited from their ancestors, and it is particularly striking in comparison with mammals, probably the only major tetrapod lineage with an increased rate of chromosomal rearrangements as a whole.

Mitochondrial DNA sequence analysis reveals multiple Pleistocene glacial refugia for Podarcis muralis (Laurenti, 1768) in the Italian Peninsula

Abstract The genetic variability of the wall lizard, Podarcis muralis, was analysed in that part of its range regarded as its area of origin and also its expansion centre. The analysis was performed on partial cytochrome b sequences (405 bp) of 117 specimens representing 31 sampling locations from southern, central and northern Italy. The results of this study revealed 30 haplotypes in the Italian sample belonging to three main genetic lineages. The genetic divergence among haplotypes ranged from 0.2 to 6.6%, whereas the estimation of divergence times among mtDNA lineages highlighted a complex pattern of genetic differentiation with both Pleistocene and Pliocene divergences (3.2–0.7 Ma). These results put in evidence the role played by the pre-Pleistocene and Pleistocene palaeogeographic and palaeoclimatic events in shaping the genetic diversity of the wall lizard in Italy and confirm the role of this peninsula as glacial refuge. In addition, AMOVA analysis revealed the presence of geographically structured clades indicating the occurrence of multiple glacial refugia in Italy, thus supporting a refugia-within-refugia scenario for the wall lizard in Italy. Finally, the results of this study seem to indicate a lack of congruence between the four morphological subspecies currently recognised in the Italian Peninsula and the main genetic lineages detected.

Evolution of digit identity in the three-toed Italian skink Chalcides chalcides: a new case of digit identity frame shift

SUMMARY Digit identity in the avian wing is a classical example of conflicting anatomical and embryological evidence regarding digit homology. Anatomical in conjunction with phylogenetic evidence supports the hypothesis that the three remaining digits in the bird wing are digits 1, 2, and 3. At the same time, various lines of embryological evidence support the notion that these digits develop in positions that normally produce digits 2, 3, and 4. In recent years, gene expression as well as experimental evidence was published that supports the hypothesis that this discrepancy arose from a digit identity shift in the evolution of the bird wing. A similar but less well‐known controversy has been ongoing since the late 19th century regarding the identity of the digits of the three‐toed Italian skink, Chalcides chalcides. Comparative anatomy identifies these digits as 1, 2, and 3, while embryological evidence suggests their derivation from embryological positions 2, 3, and 4. Here we re‐examine this evidence and add gene expression data to determine the identity of the three digits of C. chalcides. The data confirm that the adult and the embryological evidence for digit identity are in conflict, and the expression of Hoxd11 suggests that digits 1, 2, and 3 develop in positions 2, 3, and 4. We conclude that in C. chalcides, and likely in its close relatives, a digit identity frame shift has occurred, similar to the one in avian evolution. This result suggests that changes in of digit identity might be a more frequent consequence of digit reduction than previously assumed.

Phylogeographic inferences on the native brown trout mtDNA variation in central Italy

Genetic diversity was analysed in Salmo trutta populations living in an area of central Italy by sequencing 310 bp of the 5′ end of the mtDNA control region (D‐loop) and by Restriction Fragment Length Polymorphism (RFLP) analysis of three mtDNA segments. Data show a genetic structure profoundly altered by stockings with allochthonous material of Atlantic origin. In fact, 15 of the RFLP haplotypes detected are linked to an Atlantic sequence. The remaining 9 were instead coupled with sequences representing the three major phylogenetic lineages previously identified in the Mediterranean basin (Adriatic, marmoratus, and Mediterranean), representing the native genetic diversity of brown trout in that area. The close genetic affinity observed between these latter haplotypes and those found in the Balkan peninsula by other authors seems to be in accordance with a recent, natural, history of dispersion between the two borders of the Adriatic Sea. These results appear significant from a conservation point of view as, in spite of the massive stocking with hatchery‐reared specimens, they highlight the persistence of Salmo trutta native genetic diversity in central Italy.

Chromosomal evolution in Gekkonidae. I. Chromosome painting between Gekko and Hemidactylus species reveals phylogenetic relationships within the group.

Geckos are a large group of lizards characterized by a rich variety of species, different modes of sex determination and diverse karyotypes. In spite of many unresolved questions on lizards’ phylogeny and taxonomy, the karyotypes of most geckos have been studied by conventional cytogenetic methods only. We used flow-sorted chromosome-specific painting probes of Japanese gecko (Gekko japonicus), Mediterranean house gecko (Hemidactylus turcicus) and flat-tailed house gecko (Hemidactylus platyurus) to reveal homologous regions and to study karyotype evolution in seven gecko species (Gekko gecko, G. japonicus, G. ulikovskii, G. vittatus, Hemidactylus frenatus, H. platyurus and H. turcicus). Generally, the karyotypes of geckos were found to be conserved, but we revealed some characteristic rearrangements including both fissions and fusions in Hemidactylus. The karyotype of H. platyurus contained a heteromorphic pair in all female individuals, where one of the homologues had a terminal DAPI-negative and C-positive heterochromatic block that might indicate a putative sex chromosome. Among two male individuals studied, only one carried such a polymorphism, and the second one had none, suggesting a possible ZZ/ZW sex determination in some populations of this species. We found that all Gekko species have retained the putative ancestral karyotype, whilst the fission of the largest ancestral chromosome occurred in the ancestor of modern Hemidactylus species. Three common fissions occurred in the ancestor of Mediterranean house and flat-tailed house geckos, suggesting their sister group relationships. PCR-assisted mapping on flow-sorted chromosome libraries with conserved DMRT1 gene primers in G. japonicus indicates the localization of DMRT1 gene on chromosome 6.

Skinks (Reptilia: Scincidae) Have Highly Conserved Karyotypes as Revealed by Chromosome Painting

Skinks represent the most diversified squamate reptiles with a great variation in body size and form, and are found worldwide in a variety of habitats. Their remarkable diversification has been accompanied by only a few chromosome rearrangements, resulting in highly-conservative chromosomal complements of these lizards. In this study cross-species chromosome painting using Scincus scincus (2n = 32) as the source genome, was used to detect the chromosomal rearrangements and homologies between the following skinks: Chalcides chalcides (2n = 28), C. ocellatus (2n = 28), Eumeces schneideri (2n = 32), Lepidothyris fernandi (2n = 30), Mabuya quinquetaeniata (2n = 32). The results of this study confirmed a high degree of chromosome conservation between these species. The main rearrangements in the studied skinks involve chromosomes 3, 5, 6 and 7 of S. scincus. These subtelocentric chromosomes are homologous to the p and q arms of metacentric pair 3 and 4 in C. chalcides, C. ocellatus, L. fernandi, and M. quinquetaeniata, while they are entirely conserved in E. schneideri. Other rearrangements involve S. scincus 11 in L. fernandi and M. quinquetaeniata, supporting the monophyly of Lygosominae, and one of the chromosomes S. scincus 12–16, in M. quinquetaeniata. In conclusion, our data support the monophyly of Scincidae and confirm that Scincus-Eumeces plus Chalcides do not form a monophyletic clade, suggesting that the Scincus-Eumeces clade is basal to other members of this family. This study represents the first time the whole genome of any reptile species has been used for cross-species chromosome painting to assess chromosomal evolution in this group of vertebrates.