A comprehensive gene network for fine tuning floral development in poplar

Herbaceous model species, especially Arabidopsis has provided a wealth of information about the genes involved in floral induction and development of inflorescences and flowers. While the genus Populus is an important model system for the molecular biology of woody plant. These two genuses differ in many ways. This study was designed to improve understanding of flower development in poplar at a system level, as its regulatory pathway to a large extent remains poorly known, owing to the presently limited mutant pool. To address this issue, a poplar GeneChip was employed to detect genes expressed during the whole floral developmental process. Using the expressed floral genes, a systematic gene network was constructed with the aid of functional association with Arabidopsis. The results suggested that autonomous, gibberellin, vernalization, photoperiod, ethylene, brassinosteroid, stress-induced and floral suppression pathways are involved in poplar flowering. Modularity analysis revealed several pathways in common with Arabidopsis, such as autonomous, gibberellin, vernalization and photoperiod pathways. In addition, brassinosteroid, stress-induced and floral suppression pathways were implicated as additional novel pathways. Notably, a difference in vernalization between Arabidopsis and poplar was revealed. Autonomous, gibberellin, vernalization, photoperiod, ethylene, brassinosteroid, stress-induced and floral suppression pathways integrated into a systematic gene network in floral development of poplar. Compared to Arabidopsis, brassinosteroid, stress-induced and floral suppression pathways are additional in poplar, and FLC is absent in vernalization pathway in poplar. Preliminary conclusions drawn here provide a basis for both identification of key genes and elucidation of molecular mechanisms involved in poplar floral development.     

The Vaccinium corymbosum FLOWERING LOCUS T-like gene (VcFT): a flowering activator reverses photoperiodic and chilling requirements in blueberry

Key message

The blueberry FLOWERING LOCUS T ( FT )-like gene ( VcFT ) cloned from the cDNA of a tetraploid, northern highbush blueberry ( Vaccinium corymbosum L.) is able to reverse the photoperiodic and chilling requirements and drive early and continuous flowering.

Abstract

Blueberry is a woody perennial bush with a longer juvenile period than annual crops, requiring vernalization to flower normally. Few studies have been reported on the molecular mechanism of flowering in blueberry or other woody plants. Because FLOWERING LOCUS T (FT) from Arabidopsis thaliana plays a multifaceted role in generating mobile molecular signals to regulate plant flowering time, isolation and functional analysis of the blueberry (Vaccinium corymbosum L.) FT-like gene (VcFT) will facilitate the elucidation of molecular mechanisms of flowering in woody plants. Based on EST sequences, a 525-bpVcFT was identified and cloned from the cDNA of a tetraploid, northern highbush blueberry cultivar, Bluecrop. Ectopic expression of 35S:VcFT in tobacco induced flowering an average of 28 days earlier than wild-type plants. Expression of the 35S:VcFT in the blueberry cultivar Aurora resulted in an extremely early flowering phenotype, which flowered not only during in vitro culture, a growth stage when nontransgenic shoots had not yet flowered, but also in 6–10-week old, soil-grown transgenic plants, in contrast to the fact that at least 1 year and 800 chilling hours are required for the appearance of the first flower of both nontransgenic ‘Aurora’ and transgenic controls with the gusA. These results demonstrate that the VcFT is a functional floral activator and overexpression of the VcFT is able to reverse the photoperiodic and chilling requirements and drive early and continuous flowering.     

Oxidation and reduction of sulfite contribute to susceptibility and detoxification of SO2 in Populus × canescens leaves

Key Message

The critical level for SO ₂ susceptibility of Populus × canescens is approximately 1.2 μL L ^?1 SO ₂ . Both sulfite oxidation and sulfite reduction and assimilation contribute to SO ₂ detoxification.

Abstract

In the present study, uptake, susceptibility and metabolism of SO₂ were analyzed in the deciduous tree species poplar (Populus × canescens). A particular focus was on the significance of sulfite oxidase (SO) for sulfite detoxification, as SO has been characterized as a safety valve for SO₂ detoxification in herbaceous plants. For this purpose, poplar plants were exposed to different levels of SO₂ (0.65, 0.8, 1.0, 1.2 μL L^?1) and were characterized by visible injuries and at the physiological level. Gas exchange parameters (stomatal conductance for water vapor, CO₂ assimilation, SO₂ uptake) of the shoots were compared with metabolite levels (sulfate, thiols) and enzyme activities [SO, adenosine 5′-phosphosulfate reductase (APR)] in expanding leaves (80–90 % expanded). The critical dosage of SO₂ that confers injury to the leaves was 1.2 μL L^?1 SO₂. The observed increase in sulfur containing compounds (sulfate and thiols) in the expanding leaves strongly correlated with total SO₂ uptake of the plant shoot, whereas SO₂ uptake rate was strongly correlated with stomatal conductance for water vapor. Furthermore, exposure to high concentration of SO₂ revealed channeling of sulfite through assimilatory sulfate reduction that contributes in addition to SO-mediated sulfite oxidation to sulfite detoxification in expanding leaves of this woody plant species.     

A putative poplar PP2C-encoding gene negatively regulates drought and abscisic acid responses in transgenic Arabidopsis thaliana

Key message

Here we link for the first time a poplar gene with putative function in ABA signaling to the regulation of drought responses, providing a target for drought tolerance improvement in poplars.

Abstract

Populus species are valued for their fast growth and are cultivated widely. Many of the commonly used species and hybrids are, however, regarded as drought sensitive, which poses a problem for large-scale cultivation particularly in light of climate change-induced drought spells in areas of poplar growth. While many hundreds of drought-induced genes have been identified in Populus species, very little is known about the genes and the signaling process that leads to a drought response in these species. Based on sequence similarity, the poplar G059200 gene is a potential ortholog of AtPP2CA, an inhibitor of drought and abscisic acid (ABA) responses in Arabidopsis thaliana. To test if G059200 has a similar function, we generated transgenic A. thaliana plants overexpressing this gene. These transgenic lines exhibited reduced responses to exogenous ABA and reduced tolerance to osmotic stress. Finally, drought tolerance of plants was also significantly reduced. Taken together, these data provide evidences that G059200 acts as a negative regulator of ABA responses. The ability to negatively regulate drought stress responses suggests that G059200 may be targeted for drought tolerance breeding, for example, by identification of individuals harboring natural or induced loss-of-function alleles, or by RNA interference technology, to generate poplar plants with reduced activity of G059200.     

DR5 as a reporter system to study auxin response in Populus

Key message

Auxin responsive promoter DR5 reporter system is functional in Populus to monitor auxin response in tissues including leaves, roots, and stems.

Abstract

We described the behavior of the DR5::GUS reporter system in stably transformed Populus plants. We found several similarities with Arabidopsis, including sensitivity to native and synthetic auxins, rapid induction after treatment in a variety of tissues, and maximal responses in root tissues. There were also several important differences from Arabidopsis, including slower time to maximum response and lower induction amplitude. Young leaves and stem sections below the apex showed much higher DR5 activity than did older leaves and stems undergoing secondary growth. DR5 activity was highest in cortex, suggesting high levels of auxin concentration and/or sensitivity in this tissue. Our study shows that the DR5 reporter system is a sensitive and facile system for monitoring auxin responses and distribution at cellular resolution in poplar.     

Physiological adaptations of five poplar genotypes grown under SRC in the semi-arid Mediterranean environment

Key message

The genotype ‘Neva’ under high plant density showed the highest biomass yield and optimal physiological strategies and could be the most suitable choice under semi-arid environment

Abstract

The poplars (Populus spp.) are the most sensitive plants to water deficit conditions among the woody species utilized for biomass production for energetic purposes; their productivity is associated with water availability in the soil. In the Mediterranean environment, crops are mainly limited by evapotranspirative demand that is not balanced by rainfall supply. As new hybrids with high growth rates and resistance to water stress are selected, the use of poplar as an energy crop may increase in Southern regions of Mediterranean Europe. The growth dynamics and physiological characteristics of poplar hybrid genotypes have been monitored for 2 years at a site with a Mediterranean climate, Apulia region, that could be used for energy crops. Unrooted cuttings of three recently selected genotypes of poplar (‘Neva’, ‘Dvina’ and ‘Lena’) and two “traditional” genotypes (‘Luisa Avanzo’ and ‘Bellini’) were planted in the spring of 2010 at two different densities: (a) low plant density = 1,667 cuttings ha^?1 (LPD); (b) high plant density = 6,667 cuttings ha^?1 (HPD). The genotypes ‘Lena’ and ‘Dvina’ showed the lowest survival rates and the poorest growth among the hybrid poplar tested. The genotype ‘Bellini’ had low stomatal sensitivity to soil water content and a moderate productive performance. The genotypes ‘Luisa Avanzo’ and ‘Neva’ had a good degree of rooting and sprouting, high values of leaf relative water content (RWC_l) and low values of stomatal conductance (g _s) during the summer months. In “Neva”, these characteristics were associated with the best yields (4 t ha^?1) in HPD.     

Development of SCAR marker for sex identification in dioecious Garcinia gummi-gutta

Key message

We have developed sex-specific SCAR marker for the identification of dioecious Garcinia gummi - gutta (L.), which is useful for the selection of G. gummi - gutta at seedling stage and for plantation programmes.

Abstract

Garcinia gummi-gutta (L.) Robs. is a dioecious fruit yielding tree, which is naturally distributed as well as cultivated in the orchards in Western Ghat regions of India. A sex-linked DNA fragment was identified in Garcinia gummi-gutta (L.) Robs. by screening 150 randomly amplified polymorphic DNA primers and only one of them (OPBD20) showed different amplification band pattern associated with sex type. This sex-linked fragment was converted into male-specific sequence-characterized amplified region (SCAR) marker, CAM-566. The primers deigned in this study (OPBD20F and OPBD20R) correctly differentiated 12 male and 12 female plants at high annealing temperatures. Thus, a 556-bp band was amplified in male samples but not in female ones. Nevertheless, it should be noted that the fragments from both sexes were amplified at relatively low annealing temperatures. Additionally, the developed SCAR marker successfully identified the sexes of ten sex-unknown samples. Therefore, it can be used as an effective, convenient and reliable tool for sex determination in such dioecious species.     

The low fertility of Chinese white poplar: dynamic changes in anatomical structure, endogenous hormone concentrations, and key gene expression in the reproduction of a naturally occurring hybrid

Key message

We report that low fertility during intraspecific hybridization in Chinese white poplar was caused by prefertilization barriers, reduced ovules, and embryonic abortion. Hormone concentrations and gene expression patterns were also evaluated during the fertilization process.

Abstract

Hybrid vigor holds tremendous potential for yield increases and trait improvement; however, some hybridization combinations within Populus show very low fertility. To explore the causes of this low fertility in intraspecific hybridization of Chinese white poplar, we examined anatomical structure, hormone levels and expression of key genes in two unique crossing combinations of Populus × tomentosa “Pt02” × P. × tomentosa “LM50”, and (P. × tomentosa × P. alba cv. bolleana “Ptb”) × P. × tomentosa “LM50”. The seed set potential in the intraspecific hybridization P. × tomentosa “Pt02” × P. × tomentosa “LM50” was quite low, which was likely caused by prefertilization barriers, reduced ovule numbers, and embryonic abortion in ovaries. During intraspecific hybridization, we found reduced indoleacetic acid (IAA) in pistils, which may cause pollen tube deformations and increased IAA in heart-stage embryos, which may affect embryo development. Gibberellin A3 (GA3) decreased from the zygote dormancy stage to globular-stage embryos, which may be caused by failure of fertilization in specific embryos. The maximum zeatin (Z) concentration was found in heart-stage embryos, but Z concentrations quickly decreased, which may affect endosperm development. Increasing concentrations of abscisic acid (ABA) during zygote dormancy and eight-cell proembryo stages likely induced abscission of the infructescence. High ABA concentrations also regulated embryo maturity. Measurement of genes expression showed that high expression of SRK and/or SLG may result in rejection of pollen by stigmatic papillae through a mechanism, reminiscent of self-incompatibility. Also, low expression of LEC1 and FUS3 may cause embryonic abortion. Identification and eventual bypassing of these barriers may allow future genetic improvement of this key woody crop species.     

Purple-leaved Ficus lyrata plants produced by overexpressing a grapevine VvMybA1 gene

Key message

This study established an efficient method of regenerating plants of Ficus lyrata and producing purple-leaved F. lyrata plants through genetic transformation using a VvMybA1 gene of grapevine.

Abstract

Ficus lyrata, a species with unique violin- or guitar-shaped leaves, was regenerated from leaf-derived calli cultured on Murashige and Skoog (MS) basal medium supplemented with 4.5 μM N-phenyl-N’-1, 2, 3-thiadiazol-5-yl urea (TDZ) and 0.5 μM α-naphthalene acetic acid (NAA). Leaf discs were inoculated with Agrobacterium tumefaciens strain EHA 105 harboring a binary vector DEAT that contains the VvMybA1 gene and neomycin phosphotransferase (npt II) gene and subsequently cultured on the established regeneration medium supplemented with 100 mg l^?1 kanamycin. Results showed that 87.5 % of the leaf discs produced kanamycin-resistant callus, and 68.8 % of them produced adventitious shoots. Transgenic plants with three leaf colors including green, green-purple, and purple were produced. Regular and quantitative real-time PCR analyses confirmed the integration of transgenes into the host genome. Semi-quantitative RT-PCR analysis indicated that the VvMybA1 gene was responsible for the purple-colored phenotype. Purple-leaved plants with strong color stability grew vigorously in a greenhouse. This study illustrated the feasibility of using a genetically engineered VvMybA1 gene for drastic modification of leaf color of an important woody ornamental plant.     

Temperature regulation of floral buds and floral thermogenicity in Magnolia denudata (Magnoliaceae)

Key message

The gynoecium in M. denudata was thermogenic, and the first peak in the female phase lasted longer than the second peak in the male phase during flowering.

Abstract

The floral biology of Magnolia denudata, including the thermogenesis of floral buds and blooming, were investigated using a portable infrared thermal imaging radiometer and digital infrared thermometer. We found that M. denudata buds have extremely dense trichomes that maintain internal temperatures above external temperatures. The pattern of thermogenesis in M. denudata anthesis consisted of two distinct episodes corresponding to apparent receptivity of the stigmas in the female phase and incipient shedding of pollen in the male phase: one begins in the female phase and lasts about 6 h and another occurs synchronously 24 h later and lasts about 4 h in the male phase. In addition, we found that the temperature was significantly elevated in the inner petals upon flowering, indicating that they may play an important role in producing a warm floral chamber. These results increase our understanding of the strategies used by Magnoliaceae blossoms to maintain an optimal microclimate at low temperatures in the early spring.     

The Arabidopsis kinesin gene AtKin-1 plays a role in the nuclear division process during megagametogenesis

Key message

Atkin - 1 , the only Kinesin-1 member of Arabidopsis thaliana , plays a role during female gametogenesis through regulation of nuclear division cycles.

Abstract

Kinesins are microtubule-dependent motor proteins found in eukaryotic organisms. They constitute a superfamily that can be further classified into at least 14 families. In the Kinesin-1 family, members from animal and fungi play roles in long-distance transport of organelles and vesicles. Although Kinesin-1-like sequences have been identified in higher plants, little is known about their function in plant cells, other than in a recently identified Kinesin-1-like protein in a rice pollen semi-sterile mutant. In this study, the gene encoding the only Kinesin-1 member in Arabidopsis, AtKin-1 was found to be specifically expressed in ovules and anthers. AtKin-1 loss-of-function mutants showed substantially aborted ovules in siliques, and this finding was supported by complementation testing. Reciprocal crossing between mutant and wild-type plants indicated that a defect in AtKin-1 results in partially aborted megagametophytes, with no observable effects on pollen fertility. Further observation of ovule development in the mutant pistils indicated that the enlargement of the megaspore was blocked and nuclear division arrested at the one-nucleate stage during embryo sac formation. Our data suggest that AtKin-1 plays a role in the nuclear division cycles during megagametogenesis.