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in higher plants, inflorescence architecture is an important agronomic trait directly determining seed yield. however, little information is available on the regulatory mechanism of inflorescence development in perennial woody plants. based on two inflorescence branching mutants, we investigated the transcriptome differences in inflorescence buds between two mutants and wild-type (wt) plants by rna-seq to identify the genes and regulatory networks controlling inflorescence architecture in jatropha curcas l., a perennial woody plant belonging to euphorbiaceae. two inflorescence branching mutants were identified in germplasm collection of jatropha. the duo xiao hua (dxh) mutant has a seven-order branch inflorescence, and the gynoecy (g) mutant has a three-order branch inflorescence, while wt jatropha has predominantly four-order branch inflorescence, occasionally the three- or five-order branch inflorescences in fields. using weighted gene correlation network analysis (wgcna), we identified several hub genes involved in the cytokinin metabolic pathway from modules highly associated with inflorescence phenotypes. among them, jatropha adenosine kinase 2 (jcadk2), adenine phosphoribosyl transferase 1 (jcapt1), cytokinin oxidase 3 (jcckx3), isopentenyltransferase 5 (jcipt5), lonely guy 3 (jclog3) and jclog5 may participate in cytokinin metabolic pathway in jatropha. consistently, exogenous application of cytokinin (6-benzyladenine, 6-ba) on inflorescence buds induced high-branch inflorescence phenotype in both low-branch inflorescence mutant (g) and wt plants. these results suggested that cytokinin is an important regulator in controlling inflorescence branching in jatropha. in addition, comparative transcriptome analysis showed that arabidopsis homologous genes jatropha agamous-like 6 (jcagl6), jcagl24, fruitful (jcful), leafy (jclfy), sepallatas (jcseps), terminal flower 1 (jctfl1), and wuschel-related homeobox 3 (jcwox3), were differentially expressed in inflorescence

strigolactone (sl), auxin and cytokinin (ck) interact to regulate shoot branching. ck has long been considered to be the only key phytohormone to promote lateral bud outgrowth. here we report that gibberellin also acts as a positive regulator in the control of shoot branching in the woody plant jatropha curcas. we show that gibberellin and ck synergistically promote lateral bud outgrowth, and that both hormones influence the expression of putative branching regulators, j. curcas branched1 and branched2, which are key transcription factors maintaining bud dormancy. moreover, treatment with paclobutrazol, an inhibitor of de novo gibberellin biosynthesis, significantly reduced the promotion of bud outgrowth by ck, suggesting that gibberellin is required for ck-mediated axillary bud outgrowth. in addition, sl, a plant hormone involved in the repression of shoot branching, acted antagonistically to both gibberellin and ck in the control of lateral bud outgrowth. consistent with this, the expression of jcmax2, a j. curcas homolog of arabidopsis more axillary growth 2 encoding an f-box protein in the sl signaling pathway, was repressed by gibberellin and ck treatment. we also provide physiological evidence that gibberellin also induces shoot branching in many other trees, such as papaya, indicating that a more complicated regulatory network occurs in the control of shoot branching in some perennial woody plants.

background: physic nut (jatropha curcas l.) is a potential feedstock for biofuel production because jatropha oil is highly suitable for the production of the biodiesel and bio-jet fuels. however, jatropha exhibits low seed yield as a result of unreliable and poor flowering. flowering locus t (ft) –like genes are important flowering regulators in higher plants. to date, the flowering genes in jatropha have not yet been identified or characterized. results: to better understand the genetic control of flowering in jatropha, an ft homolog was isolated from jatropha and designated as jcft. sequence analysis and phylogenetic relationship of jcft revealed a high sequence similarity with the ft genes of litchi chinensis, populus nigra and other perennial plants. jcft was expressed in all tissues of adult plants except young leaves, with the highest expression level in female flowers. overexpression of jcft in arabidopsis and jatropha using the constitutive promoter cauliflower mosaic virus 35s or the phloem-specific promoter arabidopsis sucrose transporter 2 promoter resulted in an extremely early flowering phenotype. furthermore, several flowering genes downstream of jcft were up-regulated in the jcft-overexpression transgenic plant lines. conclusions: jcft may encode a florigen that acts as a key regulator in flowering pathway. this study is the first to functionally characterize a flowering gene, namely, jcft, in the biofuel plant jatropha.

background: jatropha curcas l. is a potential biofuel plant. application of exogenous cytokinin (6-benzyladenine, ba) on its inflorescence buds can significantly increase the number of female flowers, thereby improving seed yield. to investigate which genes and signal pathways are involved in the response to cytokinin in j. curcas inflorescence buds, we monitored transcriptional activity in inflorescences at 0, 3, 12, 24, and 48 h after ba treatment using a microarray. results: we detected 5,555 differentially expressed transcripts over the course of the experiment, which could be grouped into 12 distinct temporal expression patterns. we also identified 31 and 131 transcripts in j. curcas whose homologs in model plants function in flowering and phytohormonal signaling pathways, respectively. according to the transcriptional analysis of genes involved in flower development, we hypothesized that ba treatment delays floral organ formation by inhibiting the transcription of the a, b and e classes of floral organ-identity genes, which would allow more time to generate more floral primordia in inflorescence meristems, thereby enhancing inflorescence branching and significantly increasing flower number per inflorescence. ba treatment might also play an important role in maintaining the flowering signals by activating the transcription of gigantea (gi) and inactivating the transcription of constitutive photomorphogenic 1 (cop1) and terminal flower 1b (tfl1b). in addition, exogenous cytokinin treatment could regulate the expression of genes involved in the metabolism and signaling of other phytohormones, indicating that cytokinin and other phytohormones jointly regulate flower development in j. curcas inflorescence buds. conclusions: our study provides a framework to better understand the molecular mechanisms underlying changes in flowering traits in response to cytokinin treatment in j. curcas inflorescence buds. the results provide valuable information related to the mechanisms of cross-talk among multiple phytohormone signaling pathways in woody plants.

background: jatropha curcas, whose seed content is approximately 30–40% oil, is an ideal feedstock for producing biodiesel and bio-jet fuels. however, jatropha plants have a low number of female flowers, which results in low seed yield that cannot meet the needs of the biofuel industry. thus, increasing the number of female flowers is critical for the improvement of jatropha seed yield. our previous findings showed that cytokinin treatment can increase the flower number and female to male ratio and also induce bisexual flowers in jatropha. the mechanisms underlying the influence of cytokinin on jatropha flower development and sex determination, however, have not been clarified. results: this study examined the transcriptional levels of genes involved in the response to cytokinin in jatropha inflorescence meristems at different time points after cytokinin treatment by 454 sequencing, which gave rise to a total of 294.6 mb of transcript sequences. up-regulated and down-regulated annotated and novel genes were identified, and the expression levels of the genes of interest were confirmed by qrt-pcr. the identified transcripts include those encoding genes involved in the biosynthesis, metabolism, and signaling of cytokinin and other plant hormones, flower development and cell division, which may be related to phenotypic changes of jatropha in response to cytokinin treatment. our analysis indicated that jatropha orthologs of the floral organ identity genes known as abce model genes, jcap1,2, jcpi, jcag, and jcsep1,2,3, were all significantly repressed, with an exception of one b-function gene jcap3 that was shown to be up-regulated by ba treatment, indicating different mechanisms to be involved in the floral organ development of unisexual flowers of jatropha and bisexual flowers of arabidopsis. several cell division-related genes, including jccyca3;2, jccycd3;1, jccycd3;2 and jctso1, were up-regulated, which may contribute to the increased flower number after cytokinin treatment. conclusions: this study presents the first report of global expression patterns of cytokinin-regulated transcripts in jatropha inflorescence meristems. this report laid the foundation for further mechanistic studies on jatropha and other non-model plants responding to cytokinin. moreover, the identification of functional candidate genes will be useful for generating superior varieties of high-yielding transgenic jatropha.

mother of ft and tfl1 (mft)-like genes belong to the phosphatidylethanoamine-binding protein (pebp) gene family in plants. in contrast to their homologs flowering locus t (ft)-like and terminal flower 1 (tfl1)-like genes, which are involved in the regulation of the flowering time pathway, mft-like genes function mainly during seed development and germination. in this study, a full-length cdna of the mft-like gene jcmft1 from the biodiesel plant jatropha curcas (l.) was isolated and found to be highly expressed in seeds. the promoter of jcmft1 was cloned and characterized in transgenic arabidopsis. a histochemical b-glucuronidase (gus) assay indicated that the jcmft1 promoter was predominantly expressed in both embryos and endosperms of transgenic arabidopsis seeds. fluorometric gus analysis revealed that the jcmft1 promoter was highly active at the mid to late stages of seed development. after seed germination, the jcmft1 promoter activity decreased gradually. in addition, both the jcmft1 expression in germinating jatropha embryos and its promoter activity in germinating arabidopsis embryos were induced by abscisic acid (aba), possibly due to two aba-responsive elements, a g-box and an ry repeat, in the jcmft1 promoter region. these results show that the jcmft1 promoter is seed-preferential and can be used to control transgene expression in the seeds of jatropha and other transgenic plants.

plukenetia volubilis, whose seeds contain a high content of polyunsaturated fatty acids, produces approximately 60 male flowers but only 1–2 female flowers per inflorescence. increasing the number of female flowers is critical for yield improvement of p. volubilis. in this study, we determined the effect of the plant growth regulator 6-benzyladenine (ba) on floral sex determination in p. volubilis. exogenous application of ba converted male flowers on most of the inflorescences to female flowers, and approximately 8–20% of the induced female flowers further developed into fruits. treatment with various concentrations of ba resulted in 3–41 female flowers per inflorescence, reaching the highest average of 23.9 at 160 mg/l ba treatment. there were 3–22 inflorescences with induced female flowers per branch on the trees treated with various concentrations of ba, and the highest average of 13.8 was observed at 20 mg/l of ba treatment. the average number of fruits per infructescence was 3.3 in the trees treated with the optimal concentration of ba (20 mg/l), compared with 1.3 for infructescences of the control trees. the results of this study show that ba is a plant growth regulator with the potential to induce floral feminization and promote fruiting of p. volubilis.

jatropha curcas is a promising renewable feedstock for biodiesel and bio-jet fuel production. to study gene expression in jatropha in different tissues throughout development and under stress conditions, we examined a total of 11 typical candidate reference genes using real-time quantitative polymerase chain reaction (rt-qpcr) analysis, which is widely used for validating transcript levels in gene expression studies. the expression stability of these candidate reference genes was assessed across a total of 20 samples, including various tissues at vegetative and reproductive stages and under desiccation and cold stress treatments. the results obtained using software qbaseplus showed that the top-ranked reference genes differed across the sample subsets. the combination of actin, gapdh, and ef1α would be appropriate as a reference panel for normalizing gene expression data across samples at different developmental stages; the combination of actin, gapdh, and tub5 should be used as a reference panel for normalizing gene expression data across samples under various abiotic stress treatments. with regard to different developmental stages, we recommend the use of actin and tub8 for normalization at the vegetative stage and gapdh and ef1α for normalization at the reproductive stage. for abiotic stress treatments, we recommend the use of tub5 and tub8 for normalization under desiccation stress and gapdh and actin for normalization under cold stress. these results are valuable for future research on gene expression during development or under abiotic stress in jatropha. to our knowledge, this is the first report on the stability of reference genes in jatropha.

sacha inchi (plukenetia volubilis) seeds are rich in oil that contains a high content of polyunsaturated fatty acids. for genetic improvement and breeding of sacha inchi, a rapid and nondestructive method for determination of oil content in seeds is critical. in this study, time-domain nuclear magnetic resonance (td-nmr) was employed to determine oil content in sacha inchi seeds at different developmental stages, in comparison with the standard soxhlet extraction method. a highly significant correlation (r = 0.988) between oil content determined by td-nmr analysis and that measured by soxhlet extraction was found. compared with soxhlet extraction, the td-nmr analysis provides a more accurate determination of oil content in sacha inchi seeds at the late period of oil accumulation. the results demonstrated that the td-nmr analysis is a non-destructive and efficient method for reliable determination of oil content in sacha inchi seeds at different developmental stages.

plant dehydrin proteins (dhns) are known to be important for environmental stress tolerance and are involved in various developmental processes. two full
length cdnas jcdhn
1 and jcdhn
2 encoding two dehydrins from jatropha cur
cas seeds were identified and characterized. jcdhn
1 is 764 bp long and contains an open reading frame of 528 bp. the deduced jcdhn
1 protein has 175 a.a. residues that form a 19.3
kda polypeptide with a predicted isoelectric point (pi) of 6.41. jcdhn
2 is 855 bp long and contains an open reading frame of 441 bp. the deduced jcdhn
2 protein has 156 a.a. residues that form a 17.1
kda polypeptide with a predicted pi of 7.09. jcdhn
1 is classified as type y3sk2 and jcdhn
2 is classified as type y2sk2 according to the ysk shorthand for structural classification of dehydrins. homology analysis indi
cates that both jcdhn
1 and jcdhn
2 share identity with dhns of other plants. analysis of the conserved domain revealed that jcdhn
2 has glycoside hydrolase gh20 super
family activity. quantitative real time pcr analysis for jcdhn
1 and jcdhn
2 expression during seed development showed increasing gene expression of both their transcript levels along with the natural dehydration process during seed development. a sharp increase in jcdhn
2 transcript level occurred in response to water content dropping from 42% in mature seeds to 12% in dry seeds. these results indicate that both jcdhns have the potential to play a role in cell protection during dehydration occurring naturally during jatropha orthodox seed development.