Sunlight-induced anthocyanin pigmentation in maize vegetative tissues

Although, in maize, sunlight-regulated anthocyanin formation in vegetative tissues is observed only in the cultivars harbouring homozygous recessive pl loci, the identity of the photoreceptor mediating this process is not yet fully established. In this study the nature of photoreceptor(s) mediating this response was examined using an Indian hybrid maize cultivar (Kanchan-521). The etiolated maize seedlings of this cultivar on exposure to sunlight formed anthocyanin in all vegetative organs. Sunlight elicited photoinduction of anthocyanin with a slow increase between 4-16 h after the sunlight exposure, followed by a rapid increase between 16-24 h. The photoinduction of anthocyanin was primarily mediated by the UV-B component of sunlight and could be elicited by exposure to an artificial UV-B light source. The sunlight-mediated induction of anthocyanin was reduced if the sunlight exposure was terminated with a far-red pulse before transfer to darkness, indicating a coaction of phytochrome in this photoresponse. Exposure to sunlight also stimulated phenylalanine ammonia lyase (PAL) activity in all organs with two temporally separated peaks. The first peak of PAL between 4-12 h was induced by phytochrome, and the second peak of PAL between 12-24 h was induced by UV-B light. These results indicate that the photoinduction of anthocyanin in maize is mediated by a coaction of UV-B light and phytochrome.     

Developmental and environmental regulation of anthocyanin pigmentation in wheat tissues transformed with anthocyanin regulatory genes

Summary Cell autonomous anthocyanin pigmentation, produced by the anthocyanin regulatory genes B and C1 controlled by the constitutive CaMV35s promoter (pBC1-7), was used to optimize biolistic gene delivery into embryogenic wheat (Triticum aestivum L. cv ‘Chris’) scutellum cultures. Intensely pigmented callus cells were observed 24 h postbombardment but these cells did not continue to divide and were developmentally terminal. A population of nonexpressing cells generated transgenic sectors which showed light-dependent anthocyanin pigmentation. Anthocyanin pigmentation was suppressed in regenerating shoot cultures but reverted to light-dependent production in the pericarp of developing seeds. Similarly, following microtargeted gene delivery into apical meristems, anthocyanin production was developmentally suppressed in leaf base meristems but prominent anthocyanin sectors developed in mature tissues beyond this region and persisted throughout leaf growth. In three developmental situations, callus proliferation, plant regeneration, and leaf growth, perpetuation of cells with anthocyanin regulator genes under the control of constitutive promoters was dependent on a higher level of regulation to suppress pigmentation at developmentally sensitive stages of meristematic activity. These findings provide additional evidence that the anthocyanin regulatory genes may be responsive to a variety of developmental and environmental stimuli. Present address: Genetics & Plant Breeding Department, G. B. Pant University of Agriculture Technology, Pantnagar, U.P., India, 263145.     

Germinal reversion of an unstable mutation for anthocyanin pigmentation in soybean

Summary Plants of the w4-mutable line of soybean [Glycine max (L.) Merr.] are chimeral for anthocyanin pigmentation. Mutable plants produce both near-white and purple flowers, as well as flowers of mutable phenotype with purple sectors on near-white petals. It is established here that the mutable trait is conditioned by an unstable recessive allele of the w4 locus that conditions anthocyanin biosynthesis. The gene symbol w4-m is assigned to the mutable allele. Allele w4-m was derived from a stable, wild-type W4 progenitor allele and reverts at high frequency to a stable, wild-type W4 allele. Reversion occurs both early and late during the development of the germ line. Several experiments give estimates of germinal reversion frequency, indicating that approximately 6% of mutable alleles revert to wild-type from one generation to the next. Allele w4-m exhibits many features typical of an allele controlled by a transposable element.     

A maize anthocyanin transactivator induces pigmentation in hairy roots of dicotyledonous species

Several dicotyledonous species were infected with an Agrobacterium rhizogenes binary vector harbouring the plasmid 121.Sn which contains the maize gene Sn under the constitutive promoter CaMV35S. In maize, Sn transactivates the anthocyanin pathway in different tissues. The aim of this work was to test the efficiency of this gene to regulate the anthocyanin pathway in heterologous systems and verify its suitability as a reporter gene. The pigmentation of the hairy roots was compared with hairy roots stained for β-glucuronidase activity, which were used as a control. In two polymorphic genotypes of Lotus angustissimus, DNA integration and expression were assayed. The maize gene is competent to induce anthocyanin pigmentation in different species, but the complexity of the regulatory mechanisms of anthocyanin synthesis restricts the use of Sn as a reporter gene. Received: 27 June 1996 / Revision received: 30 September 1996 / Accepted: 11 September 1997     

Benzyl adenine restores anthocyanin pigmentation in suspension cultures of wild Vaccinium pahalae

The overriding influence of cytokinin source on flavonoid production in vitro was explored using a suspension culture system for Vaccinium pahalae. The substitution of kinetin by 20 μM benzyl adenine (BA) in the suspension culture media resulted in a three-fold increase in total anthocyanin yield, and a more rapid production during the cell culture cycle. Anthocyanin production reached a maximum after a 16–20 day interval in cultures containing an optimal kinetin concentration, but pigment accumulation peaked at only 12–16 days when BA was used as the sole cytokinin source. Unlike some other production systems which increase secondary metabolite production at the expense of cell growth, BA-supplementation promoted both increased growth and increased anthocyanin productivity. In BA-supplemented medium, cultures were not susceptible to typical osmotically-induced cell growth suppression. When, after multiple subcultures in kinetin-containing media, anthocyanin production capability was lost or diminished, productivity could be restored within 3 days after transfer of cells to a BA-supplemented medium. This revised version was published online in June 2006 with corrections to the Cover Date.     

Genetic analysis of anthocyanin of the anthers and culm pigmentation in common wheat

Anthocyanin pigmentation of various organs develops during plant ontogeny in response to adverse and damaging abiotic and biotic stressors (environmental factors). Using the monosome method, the genes responsible for anther and culm anthocyanin pigmentation (Pan1 and Pc2, respectively) were localized to 7D chromosome in introgressive lines from crosses between common wheat Triticum aestivum L. and the species Triticum timopheevii Zhuk. Genetic analysis of ten common wheat genotypes using testers carrying genes Pan1, Pn1, and Pn2 showed that these genotypes contained Pan1 and Pn2 genes. Visual examination of plants from 70 and 76 varieties of respectively winter and spring common wheat revealed anthocyanin pigmentation of anthers and culms in 36 varieties. Pan1 and Pn2 genes were presumably introduced into common wheat from Aegilops tauschii (Fig.) Tzvel., a donor of the D genome.     

Linkage disequilibrium and genome-wide association analysis for anthocyanin pigmentation and fruit color in eggplant

Background

The genome-wide association (GWA) approach represents an alternative to biparental linkage mapping for determining the genetic basis of trait variation. Both approaches rely on recombination to re-arrange the genome, and seek to establish correlations between phenotype and genotype. The major advantages of GWA lie in being able to sample a much wider range of the phenotypic and genotypic variation present, in being able to exploit multiple rounds of historical recombination in many different lineages and to include multiple accessions of direct relevance to crop improvement.

Results

A 191 accessions eggplant (Solanum melongena L.) association panel, comprising a mixture of breeding lines, old varieties and landrace selections originating from Asia and the Mediterranean Basin, was SNP genotyped and scored for anthocyanin pigmentation and fruit color at two locations over two years. The panel formed two major clusters, reflecting geographical provenance and fruit type. The global level of linkage disequilibrium was 3.4 cM. A mixed linear model appeared to be the most appropriate for GWA. A set of 56 SNP locus/phenotype associations was identified and the genomic regions harboring these loci were distributed over nine of the 12 eggplant chromosomes. The associations were compared with the location of known QTL for the same traits.

Conclusion

The GWA mapping approach was effective in validating a number of established QTL and, thanks to the wide diversity captured by the panel, was able to detect a series of novel marker/trait associations.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-896) contains supplementary material, which is available to authorized users.     

A glutathione S-transferase GhTT19 determines flower petal pigmentation via regulating anthocyanin accumulation in cotton

Anthocyanin accumulations in the flowers can improve seed production of hybrid lines, and produce higher commodity value in cotton fibre. However, the genetic mechanism underlying the anthocyanin pigmentation in cotton petals is poorly understood. Here, we showed that the red petal phenotype was introgressed from Gossypium bickii through recombination with the segment containing the R₃ ^bic region in the A07 chromosome of Gossypium hirsutum variety LR compared with the near-isogenic line of LW with white flower petals. The cyanidin-3-O-glucoside (Cy3G) was the major anthocyanin in red petals of cotton. A GhTT19 encoding a TT19-like GST was mapped to the R₃^bic site associated with red petals via map-based cloning, but GhTT19 homologue gene from the D genome was not expressed in G. hirsutum. Intriguingly, allelic variations in the promoters between GhTT19^LW and GhTT19^LR, rather than genic regions, were found as genetic causal of petal colour variations. GhTT19-GFP was found localized in both the endoplasmic reticulum and tonoplast for facilitating anthocyanin transport. An additional MYB binding element found only in the promoter of GhTT19^LR, but not in that of GhTT19^LW, enhanced its transactivation by the MYB activator GhPAP1. The transgenic analysis confirmed the function of GhTT19 in regulating the red flower phenotype in cotton. The essential light signalling component GhHY5 bonded to and activated the promoter of GhPAP1, and the GhHY5-GhPAP1 module together regulated GhTT19 expression to mediate the light-activation of petal anthocyanin pigmentation in cotton. This study provides new insights into the molecular mechanisms for anthocyanin accumulation and may lay a foundation for faster genetic improvement of cotton.     

Genetic analysis of floral anthocyanin pigmentation traits in Asiatic hybrid lily using molecular linkage maps

To understand the genetic background of two floral anthocyanin pigmentation traits, anthocyanin pigmentation in the flower tepals and spot formation, in the Asiatic hybrid lily (2n = 24), segregation of the two traits among 96 F₁ plants derived from a cross between commercial cultivars 'Montreux' and 'Connecticut King' were investigated. 'Montreux' has anthocyanin pigmentation in the tepals with many spots, and 'Connecticut King' has flowers with carotenoid pigmentation without spots. The F₁ plants with or without anthocyanin pigment in the tepals segregated with a 1:1 segregation ratio, indicating that a single gene controls anthocyanin pigmentation in the tepals. The number of spots per square centimeter of all tepals showed continuous distribution in the F₁ plants. To map the loci for the two anthocyanin pigmentation traits, molecular linkage maps in the Asiatic hybrid lily were constructed using a double pseudo-testcross strategy, with the same F₁ plants used for phenotypic evaluation, and 212 PCR-based DNA markers. The trait for anthocyanin pigmentation in tepals was used as a trait marker. The map of 'Montreux' comprised 95 markers in 26 linkage groups, and the map of 'Connecticut King' used 119 markers in 24 linkage groups. The total map lengths were 867.5 and 1,114.8 cM, respectively. The trait locus for anthocyanin pigmentation in the tepals was between markers ASR35-180 and P506-40 in linkage group 1 of the 'Montreux' map with a map distance of 1.2 cM and 2.6 cM, respectively. A single-point analysis of quantitative trait loci (QTLs) for tepal spot number identified two putative QTLs in linkage groups 1 and 19 of the 'Connecticut King' map. One putative QTL in linkage group 19 explained 64% of the total phenotypic variation. Because both putative QTLs were mapped on the linkage map of 'Connecticut King' that has no spots, dominant alleles of them might suppress spot formation.