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1. Data from: Predictive links between petal color and pigment quantities in natural Penstemon hybrids

   https://doi.org/10.5061/dryad.vhhmgqp09  

   Stevens, Joshua; Wheeler, Lucas; Williams, Noah; Norton, Alice; Wessinger, Carolyn (January 2023, Dryad)

   Flowers have evolved remarkable diversity in petal color, in large part due to pollinator-mediated selection. This diversity arises from specialized metabolic pathways that generate conspicuous pigments. Despite the clear link between flower color and floral pigment production, studies determining predictive relationships between pigmentation and petal color are currently lacking. In this study, we analyze a dataset consisting of hundreds of natural Penstemon hybrids that exhibit variation in flower color, including blue, purple, pink, and red. For each individual hybrid, we measured anthocyanin pigment content and petal spectral reflectance. We found that floral pigment quantities are correlated with hue, chroma, and brightness as calculated from petal spectral reflectance data: hue is related to the relative amounts of delphinidin vs. pelargonidin pigmentation, whereas brightness and chroma are correlated with the total anthocyanin pigmentation. We used a partial least squares regression approach to identify predictive relationships between pigment production and petal reflectance. We find that pigment quantity data provide robust predictions of petal reflectance, confirming a pervasive assumption that differences in pigmentation should predictably influence flower color. Moreover, we find that reflectance data enables accurate inferences of pigment quantities, where the full reflectance spectra provide much more accurate inference of pigment quantities than spectral attributes (brightness, chroma, and hue). Our predictive framework provides readily interpretable model coefficients relating spectral attributes of petal reflectance to underlying pigment quantities. These relationships represent key links between genetic changes affecting anthocyanin production and ecological functions of petal coloration. 

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2. Evolutionary walks through flower colour space driven by gene expression in Petunia and allies (Petunieae)

   https://doi.org/10.1098/rspb.2023.0275  

   Wheeler, Lucas C.; Dunbar-Wallis, Amy; Schutz, Kyle; Smith, Stacey D. (July 2023, Proceedings of the Royal Society B: Biological Sciences)

   The structure and function of biochemical and developmental pathways determine the range of accessible phenotypes, which are the substrate for evolutionary change. Accordingly, we expect that observed phenotypic variation across species is strongly influenced by pathway structure, with different phenotypes arising due to changes in activity along pathway branches. Here, we use flower colour as a model to investigate how the structure of pigment pathways shapes the evolution of phenotypic diversity. We focus on the phenotypically diverse Petunieae clade in the nightshade family, which containsca180 species ofPetuniaand related genera, as a model to understand how flavonoid pathway gene expression maps onto pigment production. We use multivariate comparative methods to estimate co-expression relationships between pathway enzymes and transcriptional regulators, and then assess how expression of these genes relates to the major axes of variation in floral pigmentation. Our results indicate that coordinated shifts in gene expression predict transitions in both total anthocyanin levels and pigment type, which, in turn, incur trade-offs with the production of UV-absorbing flavonol compounds. These findings demonstrate that the intrinsic structure of the flavonoid pathway and its regulatory architecture underlies the accessibility of pigment phenotypes and shapes evolutionary outcomes for floral pigment production. 

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3. The carotenoid redshift: Physical basis and implications for visual signaling

   https://doi.org/10.1002/ece3.10408  

   McCoy, Dakota E.; Shultz, Allison J.; Dall, Jacqueline E.; Dionne, Jennifer A.; Johnsen, Sönke (September 2023, Ecology and Evolution)

   Abstract Carotenoid pigments are the basis for much red, orange, and yellow coloration in nature and central to visual signaling. However, as pigment concentration increases, carotenoid signals not only darken and become more saturated but they also redshift; for example, orange pigments can look red at higher concentration. This occurs because light experiences exponential attenuation, and carotenoid‐based signals have spectrally asymmetric reflectance in the visible range. Adding pigment disproportionately affects the high‐absorbance regions of the reflectance spectra, which redshifts the perceived hue. This carotenoid redshift is substantial and perceivable by animal observers. In addition, beyond pigment concentration, anything that increases the path length of light through pigment causes this redshift (including optical nano‐ and microstructures). For example, maleRamphocelustanagers appear redder than females, despite the same population and concentration of carotenoids, due to microstructures that enhance light–pigment interaction. This mechanism of carotenoid redshift has sensory and evolutionary consequences for honest signaling in that structures that redshift carotenoid ornaments may decrease signal honesty. More generally, nearly all colorful signals vary in hue, saturation, and brightness as light–pigment interactions change, due to spectrally asymmetrical reflectance within the visible range of the relevant species. Therefore, the three attributes of color need to be considered together in studies of honest visual signaling. 

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4. Coding‐Sequence Evolution Does Not Explain Divergence in Petal Anthocyanin Pigmentation Between Mimulus luteus Var luteus and M. l. variegatus

   https://doi.org/10.1111/ede.12493  

   Orr, Walker E; Kim, Ji Yang; Márquez, Iker_J Sánchez; Ryan, Caine J; Raj, Tejas; Hom, Ellen K; Person, Ashley E; Vonada, Anne; Stratton, John A; Cooley, Arielle M (March 2025, Evolution & Development)

   ABSTRACT Biologists have long been interested in understanding genetic constraints on the evolution of development. For example, noncoding changes in a gene might be favored over coding changes if they are less constrained by pleiotropic effects. Here, we evaluate the importance of coding‐sequence changes to the recent evolution of a novel anthocyanin pigmentation trait in the monkeyflower genusMimulus. The magenta‐floweredMimulus luteusvar.variegatusrecently gained petal lobe anthocyanin pigmentation via a single‐locus Mendelian difference from its sister taxon, the yellow‐floweredM. l. luteus. Previous work showed that the differentially expressed transcription factor geneMYB5a/NEGANis the single causal gene. However, it was not clear whetherMYB5acoding‐sequence evolution (in addition to the observed patterns of differential expression) might also have contributed to increased anthocyanin production inM. l. variegatus. Quantitative image analysis of tobacco leaves, transfected withMYB5acoding sequence from each taxon, revealed robust anthocyanin production driven by both alleles. Counter to expectations, significantly higher anthocyanin production was driven by the allele from the low‐anthocyaninM. l. luteus, a result that was confirmed through both a replication of the initial study and analysis by an alternative method of spectrophotometry on extracted leaf anthocyanins. Together with previously published expression studies, our findings support the hypothesis that petal pigment inM. l. variegatuswas not gained by protein‐coding changes, but instead solely via noncoding cis‐regulatory evolution. Finally, while constructing the transgenes needed for this experiment, we unexpectedly discovered two sites inMYB5athat appear to be post‐transcriptionally edited—a phenomenon that has been rarely reported, and even less often explored, for nuclear‐encoded plant mRNAs. 

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5. The regulatory network for petal anthocyanin pigmentation is shaped by the MYB5a/NEGAN transcription factor in Mimulus

   https://doi.org/10.1093/genetics/iyaa036  

   Zheng, Xingyu; Om, Kuenzang; Stanton, Kimmy A; Thomas, Daniel; Cheng, Philip A; Eggert, Allison; Simmons, Emily; Yuan, Yao-Wu; Conradi Smith, Gregory D; Puzey, Joshua R; et al (February 2021, Genetics)

   Bomblies, K (Ed.)

   Abstract Much of the visual diversity of angiosperms is due to the frequent evolution of novel pigmentation patterns in flowers. The gene network responsible for anthocyanin pigmentation, in particular, has become a model for investigating how genetic changes give rise to phenotypic innovation. In the monkeyflower genus Mimulus, an evolutionarily recent gain of petal lobe anthocyanin pigmentation in M. luteus var. variegatus was previously mapped to genomic region pla2. Here, we use sequence and expression analysis, followed by transgenic manipulation of gene expression, to identify MYB5a—orthologous to the NEGAN transcriptional activator from M. lewisii—as the gene responsible for the transition to anthocyanin-pigmented petals in M. l. variegatus. In other monkeyflower taxa, MYB5a/NEGAN is part of a reaction-diffusion network that produces semi-repeating spotting patterns, such as the array of spots in the nectar guides of both M. lewisii and M. guttatus. Its co-option for the evolution of an apparently non-patterned trait—the solid petal lobe pigmentation of M. l. variegatus—illustrates how reaction-diffusion can contribute to evolutionary novelty in non-obvious ways. Transcriptome sequencing of a MYB5a RNAi line of M. l. variegatus reveals that this genetically simple change, which we hypothesize to be a regulatory mutation in cis to MYB5a, has cascading effects on gene expression, not only on the enzyme-encoding genes traditionally thought of as the targets of MYB5a but also on all of its known partners in the anthocyanin regulatory network. 

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