The ectopic expression of <Emphasis Type="Italic">PttKN1</Emphasis> gene causes pleiotropic alternation of morphology in transgenic carnation (<Emphasis Type="Italic">Dianthus caryophyllus</Emphasis> L<Emphasis Type="Italic">.</Emphasis>)

Carnation (Dianthus caryophyllus L.) is one of the most important ornamental plants in the world. Though morphological modification of carnation is very important to its commercial value, there have been no relevant reports until now. PttKN1 (Populus tremula × Tremuoides knotted1), isolated from the vascular cambial region of hybrid aspen, is a novel member of KNOX gene family. In this paper, we transformed 35S:PttKN1 to carnation via Agrobacterium tumefaciens. All primary transformants subsequently obtained were placed into phenotypic categories and self-pollinated. A total of 32 T0 progeny with aberrant phenotypes were obtained. PCR assay proved the validity of these transgenic plants. Phenotypes of 32 35S:PttKN1 plants were distinct from those of wild-type plants, including: (1) modification of phyllotaxis (15/32): wild-type carnation was with typical opposite phyllotaxis, while transgenic plants displayed tricussate whorled and multiple-cussate whorled phyllotaxis. Irregular modification of phyllotaxis was also observed; (2) modification of stem (9/32): wild-type stems were round; however, some transgenic plants exhibited much thicker and flatter stem; (3) the whole transgenic plants of carnation (8/32) became dwarf. These morphological modifications of carnation indicate that we have successfully attained some novel lines of carnation. These lines can have potential practical applications. In conclusion, the selection of stably genetic lines is discussed.     

Linkage of the <Emphasis Type="Italic">A</Emphasis> locus for the presence of anthocyanin and <Emphasis Type="Italic">fs10.1</Emphasis>, a major fruit-shape QTL in pepper

The purple color of the foliage, flower and immature fruit of pepper ( Capsicum spp.) is a result of the accumulation of anthocyanin pigments in these tissues. The expression of anthocyanins is controlled by the incompletely dominant gene A. We have mapped A to pepper chromosome 10 in a Capsicum annuum (5226) x Capsicum chinense (PI 159234) F(2) population to a genomic region that also controls anthocyanin expression in two other Solanaceous species, tomato and potato, suggesting that variation for tissue-specific expression of anthocyanin pigments in these plants is controlled by an orthologous gene(s). We mapped an additional locus, Fc, for the purple anther filament in an F(2) population from a cross of IL 579, a C. chinense introgression line and its recurrent parent 100/63, to the same position as A, suggesting that the two loci are allelic. The two anthocyanin loci were linked to a major quantitative trait locus, fs10.1, for fruit-shape index (ratio of fruit length to fruit width), that also segregated in the F(2) populations. This finding verified the observation of Peterson in 1959 of linkage between fruit color and fruit-shape genes in a cross between round and elongated-fruited parents. The linkage relationship in pepper resembles similar linkage in potato, in which anthocyanin and tuber-shape genes were found linked to each other in a cross of round and elongated-tuber parents. It is therefore possible that the shape pattern of distinct organs such as fruit and tuber in pepper and potato is controlled by a similar gene(s).     

Identification and functional analysis of anthocyanin biosynthesis genes in <Emphasis Type="Italic">Phalaenopsis</Emphasis> hybrids

Phalaenopsis species are among the most popular potted flowers for their fascinating flowers. When their whole-genome sequencing was completed, they have become useful for studying the molecular mechanism of anthocyanin biosynthesis. Here, we identified 49 candidate anthocyanin synthetic genes in the Phalaenopsis genome. Our results showed that duplication events might contribute to the expansion of some gene families, such as the genes encoding chalcone synthase (PeCHS), flavonoid 3′-hydroxylase (PeF3′H), and myeloblastosis (PeMYB). To elucidate their functions in anthocyanin biosynthesis, we conducted a global expression analysis. We found that anthocyanin synthesis occurred during the very early flower development stage and that the flavanone 3-hydroxylase (F3H), F3′H, and dihydroflavonol 4-reductase (DFR) genes played key roles in this process. Over-expression of Phalaenopsis flavonoid 3′,5′-hydroxylase (F3′5′H) in petunia showed that it had no function in anthocyanin production. Furthermore, global analysis of sequences and expression patterns show that the regulatory genes are relatively conserved and might be important in regulating anthocyanin synthesis through different combined expression patterns. To determine the functions of MYB2, 11, and 12, we over-expressed them in petunia and performed yeast two-hybrid analysis with anthocyanin (AN)1 and AN11. The MYB2 protein had strong activity in regulating anthocyanin biosynthesis and induced significant pigment accumulation in transgenic plant petals, whereas MYB11 and MYB12 had lower activities. Our work provided important improvement in the understanding of anthocyanin biosynthesis and established a foundation for floral colour breeding in Phalaenopsis through genetic engineering.     

The expression level of anthocyanidin synthase determines the anthocyanin content of crabapple (<Emphasis Type="Italic">Malus</Emphasis> sp.) petals

In addition to contributing to the coloration of plant organs and their defense against herbivores, the consumption of anthocyanins in the human diet has a number of health benefits. Crabapple (Malus sp.) represents a valuable experimental model system to research the mechanisms and regulation of anthocyanin accumulation, in part due to the often vivid and varied petal and leaf coloration that is exhibited by various cultivars. The enzyme anthocyanidin synthase (ANS) plays a pivotal role in anthocyanin biosynthesis; however, the relationship between ANS expression and petal pigmentation has yet to be established in crabapple. To illuminate the mechanism of anthocyanin accumulation in crabapple petals, we evaluated the expression of two crabapple ANS allelic genes (McANS-1 and McANS-2) and the levels of anthocyanins in petals from cultivars with dark red (‘Royalty’) and white (‘Flame’) petals, as well as another (‘Radiant’) whose petals have an intermediate pink color. We determined that the expression of McANS in the three cultivars correlated with the variation of anthocyanin accumulation during different petal developmental stages. Furthermore, transgenic tobacco plants constitutively overexpressing one of the two McANS genes, McANS-1, had showed elevated anthocyanin accumulation and a deeper red coloration in their petals than those from untransformed control lines. In conclusion, we propose that McANS are responsible for anthocyanin accumulation during petal coloration in different crabapple cultivars.     

Map-based cloning and functional analysis of the chromogen gene <Emphasis Type="Italic">C</Emphasis> in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

The chromogen gene C is critical for anthocyanin regulation in rice, and apiculus color is an important agronomic trait in selective breeding and variety purification. Mapbased cloning and in-depth functional analysis of the C gene will be useful for understanding the molecular mechanism of anthocyanin biosynthesis and for rice breeding. Japonica landrace Lijiangxintuanheigu (LTH) has red apiculi and purple stigmas. Genetic analysis showed that red apiculus and purple stigma in LTH co-segregated indicating control by a single dominant gene, or by two completely linked genes. Using 1,851 recessive individuals from two F₂ populations, the target gene OsC was delimited to a 70.8 kb interval on chromosome 6 that contains the rice homologue of the maize anthocyanin regulatory gene C1. When the entire OsC gene and its full-length cDNA cloned from LTH were transformed into japonica cultivar Kitaake with colorless apiculi and stigmas all positive transformants had red apiculi but non-colored stigmas, validating that OsC alone was responsible for the apiculus color and represented the functional C gene. OsC was constitutively expressed in all tissues examined, with strongest expression in leaf blades. These results set a foundation to clarify the regulatory mechanisms of OsC in the anthocyanin biosynthetic pathway.     

Differential excision patterns of the <Emphasis Type="Italic">En</Emphasis>-transposable element at the <Emphasis Type="Italic">A2</Emphasis> locus in maize relate to the insertion site

Defined mutant alleles with resident transposons display characteristic patterns of germinal and somatic reversion, and heritable changes in the timing and frequency of reversions, which have been termed “change of state” by McClintock, constantly arise. Several mechanisms were proposed to account for these changes. They may be ascribed to the structure and composition of the elements themselves (composition hypothesis) or to their location (position hypothesis). In the current study, insertion positions were determined for three autonomous En-controlled mutable alleles of the A2 locus in maize that show different somatic reversion patterns. A relationship was observed between En insertion positions in the single coding region of the intronless A2 gene and anthocyanin variegation patterns in the aleurone. An insertion in the 5′ region of the coding sequence produced a very late somatic variegation pattern, whereas two early variegation patterns were caused by En insertions in the 3′ region of the coding sequence.     

Drastic anthocyanin increase in response to <Emphasis Type="Italic">PAP1</Emphasis> overexpression in <Emphasis Type="Italic">fls1</Emphasis> knockout mutant confers enhanced osmotic stress tolerance in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

Key message

pap1 - D/fls1ko double mutant plants that produce substantial amounts of anthocyanin show tolerance to abiotic stress.

Abstract

Anthocyanins are flavonoids that are abundant in various plants and have beneficial effects on both plants and humans. Many genes in flavonoid biosynthetic pathways have been identified, including those in the MYB-bHLH-WD40 (MBW) complex. The MYB gene Production of Anthocyanin Pigment 1 (PAP1) plays a particularly important role in anthocyanin accumulation. PAP1 expression in many plant systems strongly increases anthocyanin levels, resulting in a dark purple color in many plant organs. In this study, we generated double mutant plants that harbor fls1ko in the pap1-D background (i.e., pap1-D/fls1ko plants), to examine whether anthocyanins can be further enhanced by blocking flavonol biosynthesis under PAP1 overexpression. We also wanted to examine whether the increased anthocyanin levels contribute to defense against osmotic stresses. The pap1-D/fls1ko mutants accumulated higher anthocyanin levels than pap1-D plants in both control and sucrose-treated conditions. However, flavonoid biosynthesis genes were slightly down-regulated in the pap1-D/fls1ko seedlings as compared to their expression in pap1-D seedlings. We also report the performance of pap1-D/fls1ko seedlings in response to plant osmotic stresses.

     

Isolation and characterization of <Emphasis Type="Italic">Brittle2</Emphasis> promoter from <Emphasis Type="Italic">Zea Mays</Emphasis> and its comparison with <Emphasis Type="Italic">Ze19</Emphasis> promoter in transgenic tobacco plants

ADP-glucose pyrophosphorylase (AGPase) represents a key regulatory step in starch synthesis. A 0.9 kb of 5′ flanking region preceding Brittle2 gene, encoding the small subunit of maize endosperm AGPase, was cloned from maize genome and its expression pattern was studied via the expression of β-glucuronidase (GUS) gene in transgenic tobacco. Analysis of GUS activities showed that the 0.9 kb fragment flanking Brittle2 gene was sufficient for driving the seed-preferred expression of the reporter gene. The activity of the 0.9 kb 5′ flanking fragment was compared with that of the tandem promoter region from a zein gene (zE19, encoding a maize 19 kDa zein protein). The results indicated that both promoters were seed-preferred in a dicotyledonous system as tobacco and the activity of zE19 promoter was three to fourfold higher than that of the 0.9 kb fragment flanking Brittle2 gene in transgenic tobacco seeds. At the same time, zE19-driven GUS gene expressed earlier than Brittle2 promoter during seed development. Histochemical location of GUS activity indicated that both promoters showed high expression in embryos, which is different from similar promoters tested in maize.     

Silencing of <Emphasis Type="Italic">GbANS</Emphasis> reduces cotton resistance to <Emphasis Type="Italic">Verticillium dahliae</Emphasis> through decreased ROS scavenging during the pathogen invasion process

Anthocyanins are secondary metabolites that play important roles in plant adaption to adverse environments. The anthocyanin biosynthetic pathway is conserved in high plants. Previous studies revealed the significant role of anthocyanins in natural-colorized cotton. However, little is known about the involvement of anthocyanins in the interaction of cotton and pathogen. In this study, a pathogen-induced gene was isolated from Gossypium barbadense that encodes an anthocyanidin synthase protein (GbANS) with dioxygenase structures. GbANS was preferentially expressed in colored tissue. Silencing of GbANS significantly reduced the production of anthocyanins, as well as the cotton’s resistance to Verticillium dahliae. Biochemical studies revealed that GbANS-silenced cotton accumulated more hydrogen peroxide compared to control plants during the V. dahliae invasion process. This accumulation of hydrogen peroxide corresponded with increased cell death around the invasion sites, which in turn accelerated the V. dahliae infection. Taken together, we found that GbANS contributes to the biosynthesis of anthocyanins in cotton and anthocyanins positively regulate cotton’s resistance to V. dahliae.