Metal Complex Pigment Involved in the Blue Sepal Color Development of Hydrangea

Oyama, Kin‐ichi; Yamada, Tomomi; Ito, Daisuke; Kondo, Tadao; Yoshida, Kumi

doi:10.1021/acs.jafc.5b02368

Cited by 36 publications

(41 citation statements)

References 43 publications

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“…As previously reported [13,14,17], we performed reproduction experiments by mixing Dp3G ( 1 ), co-pigment and Al 3+ in various buffer solutions at a concentration of 100 mM. For NMR measurements, we used an unusually concentrated buffer such as 6 M [17].…”

Section: Resultsmentioning

confidence: 99%

“…Recently, we measured the 1 H-NMR spectrum of the hydrangea blue-complex by mixing 1 , 2 and Al 3+ in a ratio of 1:2:1 in 6 M acetate buffer at pD 4.0 [17]. Analysis of the spectrum gave a partial structural information, indicating that in the hydrangea-blue complex, Dp3G ( 1 ) might exist in an equilibrium between chelating and non-chelating structures that have an interaction with 5CQ ( 2 ).…”

Section: Introductionmentioning

confidence: 99%

“…Analysis of the spectrum gave a partial structural information, indicating that in the hydrangea-blue complex, Dp3G ( 1 ) might exist in an equilibrium between chelating and non-chelating structures that have an interaction with 5CQ ( 2 ). Therefore, we proposed a schematic structure of the hydrangea blue-complex as a 1:1:1 complex of 1 , 2 and Al 3+ [17]. However, the composition was not determined unambiguously.…”

Section: Introductionmentioning

confidence: 99%

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Direct Observation of Hydrangea Blue-Complex Composed of 3-O-Glucosyldelphinidin, Al3+ and 5-O-Acylquinic Acid by ESI-Mass Spectrometry

2018

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The blue sepal color of hydrangea is due to a metal complex anthocyanin composed of 3-O-glucosyldelphinidin (1) and an aluminum ion with the co-pigments 5-O-caffeoylquinic acid (2) and/or 5-O-p-coumaroylquinic acid (3). The three components, namely anthocyanin, Al3+ and 5-O-acylquinic acids, are essential for blue color development, but the complex is unstable and only exists in an aqueous solution. Furthermore, the complex did not give analyzable NMR spectra or crystals. Therefore, many trials to determine the detailed chemical structure of the hydrangea-blue complex have not been successful to date. Instead, via experiments mixing 1, Al3+ and 2 or 3 in a buffered solution at pH 4.0, we obtained the same blue solution derived from the sepals. However, the ratio was not stoichiometric but fluctuated. To determine the composition of the complex, we tried direct observation of the molecular ion of the complex using electrospray-ionization mass spectrometry. In a very low-concentration buffer solution (2.0 mM) at pH 4.0, we reproduced the hydrangea-blue color by mixing 1, 2 and Al3+ in ratios of 1:1:1, 1:2:1 and 1:3:1. All solution gave the same molecular ion peak at m/z = 843, indicating that the blue solution has a ratio of 1:1:1 for the complex. By using 3, the observed mass number was m/z = 827 and the ratio of 1, 3 and Al3+ was also 1:1:1. A mixture of 1, 3-O-caffeoylquinic acid (4) and Al3+ did not give any blue color but instead was purple, and the intensity of the molecular ion peak at m/z = 843 was very low. These results strongly indicate that the hydrangea blue-complex is composed of a ratio of 1:1:1 for 1, Al3+ and 2 or 3.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Direct Observation of Hydrangea Blue-Complex Composed of 3-O-Glucosyldelphinidin, Al3+ and 5-O-Acylquinic Acid by ESI-Mass Spectrometry

2018

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“…inter-and intramolecular complex formation between the anthocyanin and colorless electron-rich molecules (copigments) also present in the vacuoles or covalently attached to the sugar residues [4,5]. Anthocyanins with vicinal OH groups in the B-ring can chelate metal ions like Al(III), resulting in a change in the color from red-purple for the free anthocyanin to blue in the metal complex [6] (the chemical basis of the red/blue color change in Hydrangea flowers [7]). The blue pigments of some flowers are even more complex, the colored species being a self-organizing metal-ion-stabilized supramolecular complex of defined stoichiometry formed between anthocyanins and copigment molecules (e.g.…”

Section: Introductionmentioning

confidence: 99%

From vine to wine: photophysics of a pyranoflavylium analog of red wine pyranoanthocyanins

Freitas

Silva

et al. 2017

Pure and Applied Chemistry

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Abstract:In the ground state, the p-methoxyphenyl-substituted pyranoflavylium cation I, prepared by the reaction of the 5,7-dihydroxy-4-methylflavylium cation with p-methoxybenzaldehyde, is a weak acid (pK a = 3.7 ± 0.1). In its lowest excited singlet state, I is a moderate photoacid (pK a * = 0.67) in 30% methanol-water acidified with trifluoroacetic acid (TFA). In comparison to anthocyanins and 7-hydroxyflavylium cations, the photoacidity of I is much less pronounced and the rate of proton loss from the excited acid form of I much slower (by a factor of up to 100). In 50% ethanol:0.10 mol dm −3 HClO 4 , the excited state of the acid form of I undergoes fast (12 ps) initial relaxation (potentially in the direction of an intramolecular charge transfer state), followed by much slower (340 ps) adiabatic deprotonation to form the excited base. The excited base in turn exhibits a moderately fast relaxation (70 ps), consistent with solvent hydrogen-bond reorganization times, followed by slower but efficient decay (1240 ps) back to the ground state. As in uncomplexed anthocyanins and 7-hydroxyflavylium cations, the photophysical behavior of I points to excited state proton transfer as the dominant excited state deactivation pathway of pyranoanthocyanins, consistent with relatively good photostability of natural pyranoanthocyanins.

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“…Ser., Hydrangeaceae, Cornales) are the best-known example of flavonoid-metal complexation influencing the corolla color. Under high aluminum content and acidity of the soil, the flowers are blue due to a nonstoichiometric complex with Al 3+ , delphinidin 3-glucosides, quinic acid derivatives, while upon low aluminum concentrations, the same metal-pigment-copigment complex became light pink, as the result of soil pH change (Yoshida et al 2003, Kondo et al 2005, Oyama et al 2015.…”

Section: Introductionmentioning

confidence: 99%

Chemical analysis of color change and transcriptional profile in flavonoids biosynthesis during flower development of Tibouchina pulchra (Cham.) Cong.

Rezende¹

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AgradecimentosAo fim de quatro anos tenho muito o que agradecer. Foram anos de aprendizado, dedicação e mudanças. Muitas pessoas participaram deste processo.Primeiramente gostaria de agradecer à Claudia, minha orientadora, por toda paciência, incentivo e suporte em minha formação. Desde a iniciação científica até aqui passaram-se dez anos, meu amadurecimento científico deve-se em grande parte ao seu apoio. Obrigada.À Magda, minha co-orientadora, agradeço por me inserir no mundo da biologia molecular e por todo aprendizado acadêmico compartilhado. Também sou muito grata pelo grande apoio à ida ao exterior. Não poderia deixar de mencionar que as pausas para um cigarro foram sempre produtivas, seja para falar da vida ou para ter insights sobre o trabalho.Aos professores da Fitoquímica por todos os anos em que aprendi muito com vocês, tanto numa conversa informal, quanto em nossos seminários. Ao Marcelo, agradeço por toda a ajuda nas identificações químicas e paciência diante dos meus questionamentos.Ao Eduardo Leal da Sistemática Vegetal que me auxiliou com os nomes de espécies da grande tabela do capítulo 1. Ao Erismaldo, jardineiro do IB, que muito me ajudou para que as mudas de Tibouchina ficassem bem.Ao Mads que me recebeu em seu laboratório na Dinamarca e ao Thomas, além de todos os técnicos dos laboratórios e amigos que fiz por lá. Em especial Irene, Christou e Jorge.Aos meus colegas da Fitoquímica, agradeço pelos anos em que discutíamos resultados entre pausas de almoço e café. Aqui vai um agradecimento especial à Priscila, Alice, Fernanda, Dalila e Kátia que me ajudaram nas coletas ou regando plantas quando eu estava ausente. Falando em almoço, não posso deixar de agradecer às amigas que almoçam comigo, quase que diariamente, nos últimos anos:Aline, Kátia e Mourisa. Apesar de hoje em dia estar ausente, agradeço à Carol, pois muito trocamos nos anos de convivência.Às técnicas do laboratório, agradeço por tantas vezes que passamos almoços falando sobre cromatografias e afins. Obrigada por serem sempre prestativas e por todas as risadas compartilhadas. AbstractFloral color change is a widespread phenomenon in angiosperms, but poorly understood from the genetic and chemical point of view. This thesis aimed to investigate this phenomenon in Tibouchina pulcha, a native species whose flowers change from white to dark pink. To reach this goal, flavonoid biosynthetic gene expression and compounds were profiled. By using hyphenated techiniques (UPLC-HRMS and NMR), thirty phenolic compounds were quantified and identified, being sixteen described for the first time in T. pulchra. Moreover, an inedite compound was also identified. Five key genes of the flavonoid biosynthetic pathway were partially cloned, sequenced, and the mRNA levels were analyzed (RT-qPCR) along flower development. Collectively, the obtained results demonstrated that the flower color change in T. pulchra is regulated at transcriptional level. Additionally, a metal quantification suggests that Fe 3+ ion might influence the saturation of the color a...

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Metal Complex Pigment Involved in the Blue Sepal Color Development of Hydrangea

Cited by 36 publications

References 43 publications

Direct Observation of Hydrangea Blue-Complex Composed of 3-O-Glucosyldelphinidin, Al3+ and 5-O-Acylquinic Acid by ESI-Mass Spectrometry

Direct Observation of Hydrangea Blue-Complex Composed of 3-O-Glucosyldelphinidin, Al3+ and 5-O-Acylquinic Acid by ESI-Mass Spectrometry

From vine to wine: photophysics of a pyranoflavylium analog of red wine pyranoanthocyanins

Chemical analysis of color change and transcriptional profile in flavonoids biosynthesis during flower development of Tibouchina pulchra (Cham.) Cong.

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