Global analysis of canola genes targeted by SHORT HYPOCOTYL UNDER BLUE 1 during endosperm and embryo development

Seed development in dicots includes early endosperm proliferation followed by growth of the embryo to replace the endosperm. Endosperm proliferation in dicots not only provides nutrient supplies for subsequent embryo development but also enforces a space limitation, influencing final seed size. Overexpression of Arabidopsis SHORT HYPOCOTYL UNDER BLUE1::uidA (SHB1:uidA) in canola produces large seeds. We performed global analysis of the canola genes that were expressed and influenced by SHB1 during early endosperm proliferation at 8 days after pollination (DAP) and late embryo development at 13 DAP. Overexpression of SHB1 altered the expression of 973 genes at 8 DAP and 1035 genes at 13 DAP. We also surveyed the global SHB1 association sites, and merging of these sites with the RNA sequencing data identified a set of canola genes targeted by SHB1. The 8‐DAP list includes positive and negative genes that influence endosperm proliferation and are homologous to Arabidopsis MINI3, IKU2, SHB1, AGL62, FIE and AP2. We revealed a major role for SHB1 in canola endosperm development based on the dynamics of SHB1‐altered gene expression, the magnitude of SHB1 chromatin immunoprecipitation enrichment and the over‐representation of eight regulatory genes for endosperm development. Our studies focus on an important agronomic trait in a major crop for global agriculture. The datasets on stage‐specific and SHB1‐induced gene expression and genes targeted by SHB1 also provide a useful resource in the field of endosperm development and seed size engineering. Our practices in an allotetraploid species will impact similar studies in other crop species.     

Seed-specific expression of seven Arabidopsis promoters

Seeds contain storage compounds, from various carbohydrates to proteins and lipids, which are synthesized during seed development. For the purposes of many plant researches or commercial applications, developing promoter systems expressing specifically in seeds or in particular constituents or tissues/compartments of seeds are indispensable. To screen genes dominantly or specifically expressed in seed tissues, we analyzed Arabidopsis ATH1 microarray data open to the public. Thirty-two candidate genes were selected and their expressions in seed tissues were confirmed by RT-PCR. Finally, seven genes were selected for promoter analysis. The promoters of seven genes were cloned into pBI101 vector and transformed into Arabidopsis to assay histochemical β-glucuronidase (GUS) activity. We found that Pro-at3g03230 promoter drove GUS expression in a chalazal endosperm, Pro-at4g27530:GUS expressed in both chalazal endosperm and embryo, Pro-at4g31830 accelerated GUS expression both in radicle and procambium, Pro-at5g10120 and Pro-at5g16460 drove GUS expression uniquely in embryo, Pro-at5g53100:GUS expressed only in endosperm, and Pro-at5g54000 promoted GUS expression in both embryo and inner integument. These promoters can be used for expressing any genes in specific seed tissues for practical application.     

Maternal control of integument cell elongation and zygotic control of endosperm growth are coordinated to determine seed size in Arabidopsis

We use Arabidopsis thaliana as a model to investigate coordination of cell proliferation and cell elongation in the three components that develop side by side in the seed. Two of these, the embryo and its nurturing annex, the endosperm, are placed under zygotic control and develop within the seed integument placed under maternal control. We show that integument cell proliferation and endosperm growth are largely independent from each other. By contrast, prevention of cell elongation in the integument by the mutation transparent testa glabra2 (ttg2) restricts endosperm and seed growth. Conversely, endosperm growth controlled by the HAIKU (IKU) genetic pathway modulates integument cell elongation. Combinations of TTG2 defective seed integument with reduction of endosperm size by iku mutations identify integument cell elongation and endosperm growth as the primary regulators of seed size. Our results strongly suggest that a cross talk between maternal and zygotic controls represents the primary regulator of the coordinated control of seed size in Arabidopsis.     

Isolation and Characterization of Fruit-specific Promoters ACS4 and EXP1 from Tomato (Solanum lycopersicum L)

Promoter engineering in plants holds a great promise for understanding complexity of genetic regulatory system in response to specific internal and external cues and for crop improvement. In the present investigation, we report characterization of two fruit-specific promoters SIACS4 and SIEXP1 that were isolated from tomato (Solanum lycopersicum L cv Pusa Ruby). In silico analysis of the cloned promoter sequences revealed the presence of a seed-specific cis-element in SIACS4 and several putative seed, embryo and endosperm-specific cis-elements in SIEXP1 in addition to fruit-specific ethylene responsive regulatory elements. The fruit- and seed-specific expression of both the promoters was analyzed in transgenic tomato lines expressing the promoter:: GUS fusion constructs. The SIACS4 promoter (?1 to ?373) showed GUS activity restricted specifically to flower buds and seeds in fruits. On the contrary, the SIEXP1 promoter (?1 to ?769) showed high level of expression in seeds as compared to fruit tissues at different stages of fruit ripening. No GUS expression was observed in leaves satisfying the fruit-specific nature of both the promoters. Based on deletion analysis, minimal promoters SIACS4DL2 (?1 to ?126) and SIEXP1DL1 (?1 to ?254) were identified which can be used to drive tissue-specific expression of transgenes for introducing traits of agronomic importance such as resistance to fruit borer and for enhancing both nutritional and keeping quality of tomato fruits.     

The Ubiquitin Receptor DA1 Interacts with the E3 Ubiquitin Ligase DA2 to Regulate Seed and Organ Size in Arabidopsis

Seed size in higher plants is determined by the coordinated growth of the embryo, endosperm, and maternal tissue. Several factors that act maternally to regulate seed size have been identified, such as AUXIN RESPONSE FACTOR2, APETALA2, KLUH, and DA1, but the genetic and molecular mechanisms of these factors in seed size control are almost totally unknown. We previously demonstrated that the ubiquitin receptor DA1 acts synergistically with the E3 ubiquitin ligase ENHANCER1 OF DA1 (EOD1)/BIG BROTHER to regulate the final size of seeds in Arabidopsis thaliana. Here, we describe another RING-type protein with E3 ubiquitin ligase activity, encoded by DA2, which regulates seed size by restricting cell proliferation in the maternal integuments of developing seeds. The da2-1 mutant forms large seeds, while overexpression of DA2 decreases seed size of wild-type plants. Overexpression of rice (Oryza sativa) GRAIN WIDTH AND WEIGHT2, a homolog of DA2, restricts seed growth in Arabidopsis. Genetic analyses show that DA2 functions synergistically with DA1 to regulate seed size, but does so independently of EOD1. Further results reveal that DA2 interacts physically with DA1 in vitro and in vivo. Therefore, our findings define the genetic and molecular mechanisms of three ubiquitin-related proteins DA1, DA2, and EOD1 in seed size control and indicate that they are promising targets for crop improvement.     

Isolation of four rice seed-specific promoters and evaluation of endosperm activity

Cereal grains are major targets for genetically improving the nutritional value of food and for producing recombinant proteins. Strong and tissue-specific promoters are highly desired for effectively controlling expression in the seed or endosperm. In this study, we isolated four rice promoters from the 5′ upstream region of putative seed-specifically expressed genes: PROLAM26, RAL2, RAL4 and CAPIP. By generating transgenic rice plants carrying promoter-reporter constructs, we found these four promoters to be specifically expressed in seeds, with three having endosperm-specific or -preferential activity. The strength of each promoter in the endosperm was determined and compared to a constitutively expressed OsACTIN promoter and an endosperm-specifically expressed Glu4-B promoter in single-copy transgenic plants. The promoter of RAL2 exhibited relatively high activity, and the promoters of RAL4 and CAPIP exhibited activities comparable with those of OsACTIN and Glu4-B. In addition, monitoring activities in high-generation (T₃–T₄) homozygous progeny of single-copy plants revealed maintenance of expression for all four promoters, with no evidence of silencing. Taken together, our findings offer four stable rice seed-specific promoters of different strengths for endosperm expression.     

Promoters of AaGL2 and AaMIXTA-Like1 genes of Artemisia annua direct reporter gene expression in glandular and non-glandular trichomes

Herein, we report cloning and analysis of promoters of GLABRA2 (AaGL2) homolog and a MIXTA-Like (AaMIXTA-Like1) gene from Artemisia annua. The upstream regulatory regions of AaGL2 and AaMIXTA-Like1 showed the presence of several crucial cis-acting elements. Arabidopsis and A. annua seedlings were transiently transfected with the promoter-GUS constructs using a robust agro-infiltration method. Both AaGL2 and AaMIXTA-Like1 promoters showed GUS expression preferentially in Arabidopsis single-celled trichomes and glandular as well as T-shaped trichomes of A. annua. Transgenic Arabidopsis harboring constructs in which AaGL2 or AaMIXTA-Like1 promoters would control GFP expression, showed fluorescence emanating specifically from trichome cells. Our study provides a fast and efficient method to study trichome-specific expression, and 2 promoters that have potential for targeted metabolic engineering in plants.