Project description:The evolution of the amniotic egg was one of the great evolutionary innovations in the history of life, freeing vertebrates from an obligatory connection to water and thus permitting the conquest of terrestrial environments. Among amniotes, genome sequences are available for mammals and birds, but not for non-avian reptiles. Here we report the genome sequence of the North American green anole lizard, Anolis carolinensis. We find that A. carolinensis microchromosomes are highly syntenic with chicken microchromosomes, yet do not exhibit the high GC and low repeat content that are characteristic of avian microchromosomes. Also, A. carolinensis mobile elements are very young and diverse-more so than in any other sequenced amniote genome. The GC content of this lizard genome is also unusual in its homogeneity, unlike the regionally variable GC content found in mammals and birds. We describe and assign sequence to the previously unknown A. carolinensis X chromosome. Comparative gene analysis shows that amniote egg proteins have evolved significantly more rapidly than other proteins. An anole phylogeny resolves basal branches to illuminate the history of their repeated adaptive radiations.

Project description:Protemics of anolis carolinensis tails undergoing regeneration. As amniote vertebrates, lizards are the most closely related organisms to humans capable of appendage regeneration. Lizards can autotomize, or release their tails as a means of predator evasion, and subsequently regenerate a functional replacement. Green anoles (Anolis carolinensis) can regenerate their tails through a process that involves differential expression of hundreds of genes, which has previously been analyzed by transcriptomic and microRNA analysis. To investigate protein expression in regenerating tissue, we performed whole proteomic analysis of regenerating tail tip and base. This is the first proteomic data set available for the green anole lizard. We identified 976 proteins only in the regenerating tail base, 796 only in the tail tip, and 874 in both tip and base. For 90% of these proteins in these tissues, we were able to assign a clear orthology to gene models in either the Ensembl or NCBI databases. For 20 proteins in the tail base (2.5%), 7 proteins in the tail tip (0.9%), and 7 proteins in both regions (0.8%), the gene model in Ensembl and NCBI matched an uncharacterized protein, confirming that these predictions are present in the proteome. Ontology and pathways analysis of proteins expressed in the regenerating tail base identified categories including actin filament-based process, ncRNA metabolism, regulation of phosphatase activity, small GTPase mediated signal transduction, and cellular component organization or biogenesis. Analysis of proteins expressed in the tail tip identified categories including regulation of organelle organization, regulation of protein localization, ubiquitin-dependent protein catabolism, small GTPase mediated signal transduction, morphogenesis of epithelium, and regulation of biological quality. These proteomic findings confirm pathways and gene families activated in tail regeneration in the green anole as well as identify uncharacterized proteins whose role in regrowth remains to be revealed.

Project description:Hox genes control many aspects of embryonic development in metazoans. Previous analyses of this gene family revealed a surprising diversity in terms of gene number and organization between various animal species. In vertebrates, Hox genes are grouped into tightly organized clusters, claimed to be devoid of repetitive sequences. Here, we report the genomic organization of the four Hox loci present in the green anole lizard and show that they have massively accumulated retrotransposons, leading to gene clusters larger in size when compared to other vertebrates. In addition, similar repeats are present in many other development-related gene-containing regions, also thought to be refractory to such repetitive elements. Transposable elements are major sources of genetic variations, including alterations of gene expression, and hence this situation, so far unique among vertebrates, may have been associated with the evolution of the spectacular realm of morphological variations in the body plans of Squamata. Finally, sequence alignments highlight some divergent evolution in highly conserved DNA regions between vertebrate Hox clusters, which may coincide with the emergence of mammalian-specific features.

Project description:The lizards are evolutionarily the closest vertebrates to humans that demonstrate the ability to regenerate entire appendages containing cartilage, muscle, skin, and nervous tissue. We previously isolated PAX7-positive cells from muscle of the green anole lizard, Anolis carolinensis, that can differentiate into multinucleated myotubes and express the muscle structural protein, myosin heavy chain. Studying gene expression in these satellite/progenitor cell populations from A. carolinensis can provide insight into the mechanisms regulating tissue regeneration. We generated a transcriptome from proliferating lizard myoprogenitor cells and compared them to transcriptomes from the mouse and human tissues from the ENCODE project using XGSA, a statistical method for cross-species gene set analysis. These analyses determined that the lizard progenitor cell transcriptome was most similar to mammalian satellite cells. Further examination of specific GO categories of genes demonstrated that among genes with the highest level of expression in lizard satellite cells were an increased number of genetic regulators of chondrogenesis, as compared to mouse satellite cells. In micromass culture, lizard PAX7-positive cells formed Alcian blue and collagen 2a1 positive nodules, without the addition of exogenous morphogens, unlike their mouse counterparts. Subsequent quantitative RT-PCR confirmed up-regulation of expression of chondrogenic regulatory genes in lizard cells, including bmp2, sox9, runx2, and cartilage specific structural genes, aggrecan and collagen 2a1. Taken together, these data suggest that tail regeneration in lizards involves significant alterations in gene regulation with expanded musculoskeletal potency.

Project description:The clustered protocadherins (Pcdhs), Pcdh-?, -?, and -?, are transmembrane proteins constituting a subgroup of the cadherin superfamily. Each Pcdh cluster is arranged in tandem on the same chromosome. Each of the three Pcdh clusters shows stochastic and combinatorial expression in individual neurons, thus generating a hugely diverse set of possible cell surface molecules. Therefore, the clustered Pcdhs are candidates for determining neuronal molecular diversity. Here, we showed that the targeted deletion of DNase I hypersensitive (HS) site HS5-1, previously identified as a Pcdh-? regulatory element in vitro, affects especially the expression of specific Pcdh-? isoforms in vivo. We also identified a Pcdh-? cluster control region (CCR) containing six HS sites (HS16, 17, 17', 18, 19, and 20) downstream of the Pcdh-? cluster. This CCR comprehensively activates the expression of the Pcdh-? gene cluster in cis, and its deletion dramatically decreases their expression levels. Deleting the CCR nonuniformly down-regulates some Pcdh-? isoforms and does not affect Pcdh-? expression. Thus, the CCR effect extends beyond the 320-kb region containing the Pcdh-? cluster to activate the upstream Pcdh-? genes. Thus, we concluded that the CCR is a highly specific regulatory unit for Pcdh-? expression on the clustered Pcdh genomic locus. These findings suggest that each Pcdh cluster is controlled by distinct regulatory elements that activate their expression and that the stochastic gene regulation of the clustered Pcdhs is controlled by the complex chromatin architecture of the clustered Pcdh locus.

Project description:The green anole lizard (Anolis carolinensis) is a model organism for behavior and genomics that is native to the southeastern United States. It is currently thought that the ancestors of modern green anoles dispersed to peninsular Florida from Cuba. However, the climatic changes and geological features responsible for the early diversification of A. carolinensis in North America have remained largely unexplored. This is because previous studies (1) differ in their estimates of the divergence times of populations, (2) are based on a single genetic locus or (3) did not test specific hypotheses regarding the geologic and topographic history of Florida. Here we provide a multi-locus study of green anole genetic diversity and find that the Florida peninsula contains a larger number of genetically distinct populations that are more diverse than those on the continental mainland. As a test of the island refugia hypothesis in Pleistocene Florida, we use a coalescent approach to estimate the divergence times of modern green anole lineages. We find that all demographic events occurred during or after the Upper Pliocene and suggest that green anole diversification was driven by population divergence on interglacial island refugia in Florida during the Lower Pleistocene, while the region was often separated from continental North America. When Florida reconnected to the mainland, two separate dispersal events led to the expansion of green anole populations across the Atlantic Seaboard and Gulf Coastal Plain.

Project description:Anolis carolinensis is an emerging model species and the sole member of its genus native to the United States. Considerable morphological and physiological variation has been described in the species, and the recent sequencing of its genome makes it an attractive system for studies of genome variation. To inform future studies of molecular and phenotypic variation within A. carolinensis, a rigorous account of intraspecific population structure and relatedness is needed. Here, we present the most extensive phylogeographic study of this species to date. Phylogenetic analyses of mitochondrial DNA sequence data support the previous hypothesis of a western Cuban origin of the species. We found five well-supported, geographically distinct mitochondrial haplotype clades throughout the southeastern United States. Most Florida populations fall into one of three divergent clades, whereas the vast majority of populations outside Florida belong to a single, shallowly diverged clade. Genetic boundaries do not correspond to major rivers, but may reflect effects of Pleistocene glaciation events and the Appalachian Mountains on migration and expansion of the species. Phylogeographic signal should be examined using nuclear loci to complement these findings.

Project description:The clustered protocadherins (Pcdh) are encoded by three closely linked gene clusters (Pcdh-alpha, -beta, and -gamma) that span nearly 1 million base pairs of DNA. The Pcdh-alpha gene cluster encodes a family of 14 distinct cadherin-like cell surface proteins that are expressed in neurons and are present at synaptic junctions. Individual Pcdh-alpha mRNAs are assembled from one of 14 "variable" (V) exons and three "constant" exons in a process that involves both differential promoter activation and alternative pre-mRNA splicing. In individual neurons, only one (and rarely two) of the Pcdh alpha1-12 promoters is independently and randomly activated on each chromosome. Thus, in most cells, this unusual form of monoallelic expression leads to the expression of two different Pcdh-alpha 1-12 V exons, one from each chromosome. The two remaining V exons in the cluster (Pcdh-alphaC1 and alphaC2) are expressed biallelically in every neuron. The mechanisms that underlie promoter choice and monoallelic expression in the Pcdh-alpha gene cluster are not understood. Here we report the identification of two long-range cis-regulatory elements in the Pcdh-alpha gene cluster, HS5-1 and HS7. We show that HS5-1 is required for maximal levels of expression from the Pcdh alpha1-12 and alphaC1 promoters, but not the Pcdh-alphaC2 promoter. The nearly cluster-wide requirement of the HS5-1 element is consistent with the possibility that the monoallelic expression of Pcdh-alpha V exons is a consequence of competition between individual V exon promoters for the two regulatory elements.

Project description:BACKGROUND: The synaptic cell adhesion molecules, protocadherins, are a vertebrate innovation that accompanied the emergence of the neural tube and the elaborate central nervous system. In mammals, the protocadherins are encoded by three closely-linked clusters (alpha, beta and gamma) of tandem genes and are hypothesized to provide a molecular code for specifying the remarkably-diverse neural connections in the central nervous system. Like mammals, the coelacanth, a lobe-finned fish, contains a single protocadherin locus, also arranged into alpha, beta and gamma clusters. Zebrafish, however, possesses two protocadherin loci that contain more than twice the number of genes as the coelacanth, but arranged only into alpha and gamma clusters. To gain further insight into the evolutionary history of protocadherin clusters, we have sequenced and analyzed protocadherin clusters from the compact genome of the pufferfish, Fugu rubripes. RESULTS: Fugu contains two unlinked protocadherin loci, Pcdh1 and Pcdh2, that collectively consist of at least 77 genes. The fugu Pcdh1 locus has been subject to extensive degeneration, resulting in the complete loss of Pcdh1gamma cluster. The fugu Pcdh genes have undergone lineage-specific regional gene conversion processes that have resulted in a remarkable regional sequence homogenization among paralogs in the same subcluster. Phylogenetic analyses show that most protocadherin genes are orthologous between fugu and zebrafish either individually or as paralog groups. Based on the inferred phylogenetic relationships of fugu and zebrafish genes, we have reconstructed the evolutionary history of protocadherin clusters in the teleost fish lineage. CONCLUSION: Our results demonstrate the exceptional evolutionary dynamism of protocadherin genes in vertebrates in general, and in teleost fishes in particular. Besides the 'fish-specific' whole genome duplication, the evolution of protocadherin genes in teleost fishes is influenced by lineage-specific gene losses, tandem gene duplications and regional sequence homogenization. The dynamic protocadherin clusters might have led to the diversification of neural circuitry among teleosts, and contributed to the behavioral and physiological diversity of teleosts.

Project description:Cartilaginous fishes are the oldest living phylogenetic group of jawed vertebrates. Here, we demonstrate the value of cartilaginous fish sequences in reconstructing the evolutionary history of vertebrate genomes by sequencing the protocadherin cluster in the relatively small genome (910 Mb) of the elephant shark (Callorhinchus milii). Human and coelacanth contain a single protocadherin cluster with 53 and 49 genes, respectively, that are organized in three subclusters, Pcdhalpha, Pcdhbeta, and Pcdhgamma, whereas the duplicated protocadherin clusters in fugu and zebrafish contain >77 and 107 genes, respectively, that are organized in Pcdhalpha and Pcdhgamma subclusters. By contrast, the elephant shark contains a single protocadherin cluster with 47 genes organized in four subclusters (Pcdhdelta, Pcdhepsilon, Pcdhmu, and Pcdhnu). By comparison with elephant shark sequences, we discovered a Pcdhdelta subcluster in teleost fishes, coelacanth, Xenopus, and chicken. Our results suggest that the protocadherin cluster in the ancestral jawed vertebrate contained more subclusters than modern vertebrates, and the evolution of the protocadherin cluster is characterized by lineage-specific differential loss of entire subclusters of genes. In contrast to teleost fish and mammalian protocadherin genes that have undergone gene conversion events, elephant shark protocadherin genes have experienced very little gene conversion. The syntenic block of genes in the elephant shark protocadherin locus is well conserved in human but disrupted in fugu. Thus, the elephant shark genome appears to be less prone to rearrangements compared with teleost fish genomes. The small and "stable" genome of the elephant shark is a valuable reference for understanding the evolution of vertebrate genomes.