Comprehensive survey of developmental genes in the pea aphid, Acyrthosiphon pisum: frequent lineage-specific duplications and losses of developmental genes.

Aphids exhibit unique attributes, such as polyphenisms and specialized cells to house endosymbionts, that make them an interesting system for studies at the interface of ecology, evolution and development. Here we present a comprehensive characterization of the developmental genes in the pea aphid, Acyrthosiphon pisum, and compare our results to other sequenced insects. We investigated genes involved in fundamental developmental processes such as establishment of the body plan and organogenesis, focusing on transcription factors and components of signalling pathways. We found that most developmental genes were well conserved in the pea aphid, although many lineage-specific gene duplications and gene losses have occurred in several gene families. In particular, genetic components of transforming growth factor beta (TGFbeta) Wnt, JAK/STAT (Janus kinase/signal transducer and activator of transcription) and EGF (Epidermal Growth Factor) pathways appear to have been significantly modified in the pea aphid.

The Functionality and Evolution of Eukaryotic Transcriptional Enhancers.

Enhancers regulate precise spatial and temporal patterns of gene expression in eukaryotes and, moreover, evolutionary changes in these modular cis-regulatory elements may represent the predominant genetic basis for phenotypic evolution. Here, we review approaches to identify and functionally analyze enhancers and their transcription factor binding sites, including assay for transposable-accessible chromatin-sequencing (ATAC-Seq) and clustered regularly interspaced short palindromic repeats (CRISPR)/Cas9, respectively. We also explore enhancer functionality, including how transcription factor binding sites combine to regulate transcription, as well as research on shadow and super enhancers, and how enhancers can act over great distances and even in trans. Finally, we discuss recent theoretical and empirical data on how transcription factor binding sites and enhancers evolve. This includes how the function of enhancers is maintained despite the turnover of transcription factor binding sites as well as reviewing studies where mutations in enhancers have been shown to underlie morphological change.

Sequence and expression of the hunchback gene in Lucilia sericata: a comparison with other Dipterans.

We have found that the hunchback (hb)gene from Lucilia sericata is conserved in its functional domains in comparison with related flies, although there is divergence in the protein outside these regions. The expression patterns of Lucilia hb in early embryos are broadly similar to other higher Dipterans. However, in the posterior region we report blastoderm and post-gastrulation expression patterns, which are diverged from Musca and Drosophila. These patterns are reminiscent of hb expression in more primitive insects and could be indicative of changes in the regulation of hb in Lucilia by the terminal system.

The respiratory injury in burns. An account of the management.

The management of three patients suffering from respiratory complications of burns is described. The pathogenesis and treatment of pulmonary inhalational injury is reviewed and methods of monitoring respiratory function are discussed.

Divergent structure and function of the bicoid gene in Muscoidea fly species.

We have investigated the evolution of the bicoid (bcd) gene in fly species of the Muscoidea Superfamily. We obtained the complete bcd sequence from the housefly Musca domestica and found polymorphism in the coding region among Musca strains. In addition to Musca, we cloned most of the bcd coding sequences from two blowfly species Calliphora vicina and Lucilia sericata. The 5' and 3' regulatory regions flanking the Musca bcd gene are widely diverged in sequence from Drosophila; however, some important sequence motifs identified in Drosophila bcd are present. The predicted RNA secondary structures of the 3' UTRs are similar, despite sequence divergence. Comparison of Bicoid (Bcd) proteins shows a serine-rich domain of unknown function is present in the Muscoidea species, but is absent in other species. The in vivo function of bcd in Musca was tested by RNAi to mimic loss of function phenotype. We obtained a head defect phenotype similar to weak bcd alleles of Drosophila. Although our comparisons initially suggest functional conservation between species, closer inspection reveals significant differences. Divergence of structural motifs, such as regulatory elements in flanking regions and conservation of protein domains in some species but not in others, points to functional divergence between species. We suggest that the larger embryonic size in Muscoidea species restricts the morphogenetic activity of a weak Bcd activator, which has evolved a more specialized role in head determination and lost some functions in thoracic development.

Coevolution in bicoid-dependent promoters and the inception of regulatory incompatibilities among species of higher Diptera.

To what extent and in what way do gene promoters and their transacting regulatory proteins coevolve? In this and in earlier publications we show that the Bicoid-dependent promoters of the segmentation genes hunchback and tailless in species of higher Diptera (Drosophila, Musca, Calliphora, and Lucilia) are different with respect to the copy number, spacing, sequence, and orientation of Bicoid binding sites. At the same time there are significant amino acid differences in the Bicoid homeodomain. To test these interspecific differences, we used a series of functional assays, starting with the analysis of Bicoid binding affinities of individual sites, through to transgene rescue experiments, to compare within-species with between-species mixtures of Bicoid homeodomains and hunchback or tailless promoters. We observed that components taken from different species interact with less efficiency compared with those taken from within the same species. Our interpretation is that such interspecific incompatibilities are a consequence of interactive genetic elements coevolving one with another, hence maintaining functional compatibility within each species. At the same time such a process allows differences to accumulate between species regarding the precise molecular basis whereby the common function is effected.

Rapid restructuring of bicoid-dependent hunchback promoters within and between Dipteran species: implications for molecular coevolution.

Interacting genetic elements need to coevolve if their joint function is to be maintained; for example, the correct binding of transcriptional regulators to defined binding sites in gene promoters needs to be maintained during evolution to ensure proper function. As part of a wider investigation into the molecular coevolution of the Dipteran homeodomain-bearing regulator bicoid (bcd) and Bcd-dependent promoters, we present data on the functional, structural, and sequence differences between the promoters of the segmentation gene hunchback (hb), in several species of Cyclorrhaphan (higher) Diptera. The result of phenocopying hb mutations using RNA interference (RNAi) in Musca domestica shows broadly similar functions to the hb gene in Drosophila melanogaster. However, the Bcd-binding sites in the hb promoters of Drosophila, Musca, and the two blowfly species Lucilia sericata and Calliphora vicina differ in copy number, sequence, orientation, and spacing. Furthermore, all promoters are subject to rapid turnover by slippage-like processes leading to high densities of short repetitive motifs. A study of polymorphism among six strains of M. domestica reveals that turnover by slippage also occurs in the promoter, untranslated leader, and exonic coding sequences of hb, but to different extents. We discuss these results in terms of the known interspecific differences in bcdand the potential coevolution of selected compensatory mutations in trans and cis in response to continuous promoter restructuring.