Convergent evolution of disordered lipidic structural colour in the fruits of Lantana strigocamara (syn. L. camara hybrid cultivar)

The majority of plant colours are produced by anthocyanin and carotenoid pigments, but colouration obtained by nanostructured materials (i.e. structural colours) is increasingly reported in plants. Here, we identify a multilayer photonic structure in the fruits of Lantana strigocamara and compare it with a similar structure in Viburnum tinus fruits. We used a combination of transmission electron microscopy (EM), serial EM tomography, scanning force microscopy and optical simulations to characterise the photonic structure in L.&thinsp;strigocamara. We also examine the development of the structure during maturation. We found that the structural colour derives from a disordered, multilayered reflector consisting of lipid droplets of c.105&thinsp;nm that form a plate-like structure in 3D. This structure begins to form early in development and reflects blue wavelengths of light with increasing intensity over time as the structure develops. The materials used are likely to be lipid polymers. Lantana strigocamara is the second origin of a lipid-based photonic structure, convergently evolved with the structure in Viburnum tinus. Chemical differences between the lipids in L. strigocamara and those of V. tinus suggest a distinct evolutionary trajectory with implications for the signalling function of structural colours in fruits. &nbsp;</p

Fraction of exhaled nitric oxide values in childhood are associated with 17q11.2-q12 and 17q12-q21 variants

BACKGROUND: The fraction of exhaled nitric oxide (Feno) value is a biomarker of eosinophilic airway inflammation and is associated with childhood asthma. Identification of common genetic variants associated with childhood Feno values might help to define biological mechanisms related to specific asthma phenotypes. OBJECTIVE: We sought to identify the genetic variants associated with childhood Feno values and their relation with asthma. METHODS: Feno values were measured in children age 5 to 15 years. In 14 genome-wide association studies (N = 8,858), we examined the associations of approximately 2.5 million single nucleotide polymorphisms (SNPs) with Feno values. Subsequently, we assessed whether significant SNPs were expression quantitative trait loci in genome-wide expression data sets of lymphoblastoid cell lines (n = 1,830) and were related to asthma in a previously published genome-wide association data set (cases, n = 10,365; control subjects: n = 16,110). RESULTS: We identified 3 SNPs associated with Feno values: rs3751972 in LYR motif containing 9 (LYRM9; P = 1.97 × 10(-10)) and rs944722 in inducible nitric oxide synthase 2 (NOS2; P = 1.28 × 10(-9)), both of which are located at 17q11.2-q12, and rs8069176 near gasdermin B (GSDMB; P = 1.88 × 10(-8)) at 17q12-q21. We found a cis expression quantitative trait locus for the transcript soluble galactoside-binding lectin 9 (LGALS9) that is in linkage disequilibrium with rs944722. rs8069176 was associated with GSDMB and ORM1-like 3 (ORMDL3) expression. rs8069176 at 17q12-q21, but not rs3751972 and rs944722 at 17q11.2-q12, were associated with physician-diagnosed asthma. CONCLUSION: This study identified 3 variants associated with Feno values, explaining 0.95% of the variance. Identification of functional SNPs and haplotypes in these regions might provide novel insight into the regulation of Feno values. This study highlights that both shared and distinct genetic factors affect Feno values and childhood asthma.C.O. is supported by a NIH grant that supported the Hutterite studies (R01 HL085197). D.E. is supported by UK Medical Research Council Centre (G0600705). G.S. is supported by UK Medical Research Council Centre (G0600705). J.K. is funded by a Wellcome Trust 4-year PhD studentship in molecular, genetic, and life course epidemiology (WT083431MA). L.D. is supported by a European Respiratory Society/Marie Curie Joint Research Fellowship of the European Respiratory Society and the European Community’s Seventh Framework Programme FP7/2007-2013–Marie Curie Actions under grant agreement RESPIRE, PCOFUND-GA-2008-229571 (no. MC 1226- 2009). N.T. is supported by UK Medical Research Council Centre (G0600705). R.V. was partly supported by an unrestricted personal grant from GlaxoSmithKline, NL. V.J. is supported by the Netherlands Organization for Health Research and Development (ZonMw 90700303, 916.10159). L. Duijts is supported by a European Respiratory Society/Marie Curie Joint Research Fellowship of the European Respiratory Society and the European Community’s Seventh Framework Programme (FP7/2007-2013-Marie Curie Actions under grant agreement RESPIRE, PCOFUND-GA-2008-229571 [no. MC 1226-2009]). M. T. Salam has received research support from the National Heart, Lung, and Blood Institute (NHLBI; 5R01HL61768 and 5R01HL76647); the Southern California Environmental Health Sciences Center funded by the National Institute of Environmental Health Sciences (5P30ES007048); and the Environmental Protection Agency (EPA; 5P01ES009581, R826708-01, and RD831861-01), the National Institute of Environmental Health Sciences (5P01ES011627), and the Hastings Foundation. J. Genuneit has received grant EuFP6 (018996 under IP LSH-2004-1.25- 1). Evans has received a grant in the form of the MRC New Investigator Award G0600705. B. St Pourcain has received research support with Autism Speaks (7132). O. Fuchs has received research support from the European Commission within Seventh Framework Programme (theme FP7-KBBE-2007- 1) as part of EFRAIM (Impact of exogenous factors in the development of Allergy, contract no. 211911), the European Respiratory Society for a long-term research fellowship (no. 675). F. D. Gilliand has received research support from the NHLBI (5R01HL61768 and 5R01HL76647), Southern California Environmental Health Sciences Center funded by the National Institute of Environmental Health Sciences (5P30ES007048), the Children’s Environmental Health Center funded by the National Institute of Environmental Health Sciences and the Environmental Protection Agency (5P01Es009581, R826708-01, and RD831861-01), the National Institute of Environmental Health Sciences (5P01ES011627