The lncRNA regulates seasonal color patterns in buckeye butterflies.

Long noncoding RNAs (lncRNAs) are transcribed elements increasingly recognized for their roles in regulating gene expression. Thus far, however, we have little understanding of how lncRNAs contribute to evolution and adaptation. Here, we show that a conserved lncRNA, , is an important color patterning gene in the buckeye butterfly .

-regulatory modes of inactivation in butterfly forewings.

gene clusters encode transcription factors that drive regional specialization during animal development: for example the Hox factor Ubx is expressed in the insect metathoracic (T3) wing appendages and differentiates them from T2 mesothoracic identities. transcriptional regulation requires silencing activities that prevent spurious activation and regulatory crosstalks in the wrong tissues, but this has seldom been studied in insects other than , which shows a derived dislocation into two genomic clusters that disjoined () and (). Here, we investigated how is restricted to the hindwing in butterflies, amidst a contiguous cluster.

Frizzled2 receives WntA signaling during butterfly wing pattern formation.

Butterfly color patterns provide visible and biodiverse phenotypic readouts of the patterning processes. Although the secreted ligand WntA has been shown to instruct the color pattern formation in butterflies, its mode of reception remains elusive. Butterfly genomes encode four homologs of the Frizzled-family of Wnt receptors.

Efficient transgenesis in pantry moths.

While transposon-based transgenesis is widely used in various emerging model organisms, its relatively low transposition rate in butterflies and moths has hindered its use for routine genetic transformation in Lepidoptera. Here, we tested the suitability of a codon-optimized transposase () in mRNA form to deliver and integrate transgenic cassettes into the genome of the pantry moth . Co-injection of mRNA with donor plasmids successfully integrated 1.

Deep cis-regulatory homology of the butterfly wing pattern ground plan.

Butterfly wing patterns derive from a deeply conserved developmental ground plan yet are diverse and evolve rapidly. It is poorly understood how gene regulatory architectures can accommodate both deep homology and adaptive change. To address this, we characterized the cis-regulatory evolution of the color pattern gene in nymphalid butterflies.

Erratum: Mapping and CRISPR homology-directed repair of a recessive white eye mutation in moths.

[This corrects the article DOI: 10.1016/j.isci.

Mapping and CRISPR homology-directed repair of a recessive white eye mutation in moths.

The pantry moth is a worldwide pest of stored food products and a promising laboratory model system for lepidopteran functional genomics. Here we describe efficient methods for precise genome editing in this insect. A spontaneous recessive white-eyed phenotype maps to a frameshift deletion (.

Molecular Phylogeny and Evolution of Amazon Parrots in the Greater Antilles.

Amazon parrots ( spp.) colonized the islands of the Greater Antilles from the Central American mainland, but there has not been a consensus as to how and when this happened. Today, most of the five remaining island species are listed as endangered, threatened, or vulnerable as a consequence of human activity.

Genomic architecture of a genetically assimilated seasonal color pattern.

Developmental plasticity allows genomes to encode multiple distinct phenotypes that can be differentially manifested in response to environmental cues. Alternative plastic phenotypes can be selected through a process called genetic assimilation, although the mechanisms are still poorly understood. We assimilated a seasonal wing color phenotype in a naturally plastic population of butterflies () and characterized three responsible genes.

Multiple roles forlaccase2 in butterfly wing pigmentation, scale development, and cuticle tanning.

Lepidopteran wing scales play important roles in a number of functions including color patterning and thermoregulation. Despite the importance of wing scales, however, we still have a limited understanding of the genetic mechanisms that underlie scale patterning, development, and coloration. Here, we explore the function of the phenoloxidase-encoding gene laccase2 in wing and scale development in the nymphalid butterfly Vanessa cardui.

Parallel evolution of ancient, pleiotropic enhancers underlies butterfly wing pattern mimicry.

Color pattern mimicry in butterflies is a classic case study of complex trait adaptation via selection on a few large effect genes. Association studies have linked color pattern variation to a handful of noncoding regions, yet the presumptive cis-regulatory elements (CREs) that control color patterning remain unknown. Here we combine chromatin assays, DNA sequence associations, and genome editing to functionally characterize 5 cis-regulatory elements of the color pattern gene We were surprised to find that the cis-regulatory architecture of is characterized by pleiotropy and regulatory fragility, where deletion of individual cis-regulatory elements has broad effects on both color pattern and wing vein development.

Macroevolutionary shifts of function potentiate butterfly wing-pattern diversity.

Butterfly wing patterns provide a rich comparative framework to study how morphological complexity develops and evolves. Here we used CRISPR/Cas9 somatic mutagenesis to test a patterning role for , a signaling ligand gene previously identified as a hotspot of shape-tuning alleles involved in wing mimicry. We show that loss-of-function causes multiple modifications of pattern elements in seven nymphalid butterfly species.

Single master regulatory gene coordinates the evolution and development of butterfly color and iridescence.

The gene has been implicated in butterfly wing pattern adaptation by genetic association, mapping, and expression studies. The actual developmental function of this gene has remained unclear, however. Here we used CRISPR/Cas9 genome editing to show that plays a fundamental role in nymphalid butterfly wing pattern development, where it is required for determination of all chromatic coloration.

ChIP-Seq-Annotated Heliconius erato Genome Highlights Patterns of cis-Regulatory Evolution in Lepidoptera.

Uncovering phylogenetic patterns of cis-regulatory evolution remains a fundamental goal for evolutionary and developmental biology. Here, we characterize the evolution of regulatory loci in butterflies and moths using chromatin immunoprecipitation sequencing (ChIP-seq) annotation of regulatory elements across three stages of head development. In the process we provide a high-quality, functionally annotated genome assembly for the butterfly, Heliconius erato.