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Recent publications

Mohamed, A., Jin, Z., Osman, T., Shi, N., Tör, M., Jackson, S. and Hong, Y., 2022. Hotspot siRNA Confers Plant Resistance against Viral Infection. Biology, 11(5), p.714. DOI: 10.3390/biology11050714Link opens in a new window

Yu, Z., Wang, Y., Mei, F., Yan, H., Jin, Z., Zhang, P., Zhang, X., Tör, M., Jackson, S., Shi, N. and Hong, Y., 2022. Spinach-based RNA mimicking GFP in plant cells. Functional & Integrative Genomics, pp.1-6. 

Venail J, da Silva Santos P.H, Manechini J.R, Alves L.C., Scarpari M, Falcão T, Romanel E, Brito M, Vicentini R., Pinto L., S Jackson, (2002). Analysis of the PEBP gene family and identification of a novel FT orthologue in sugarcane, Journal of Experimental Botany, erab539,

Venail J, da Silva Santos P.H, Manechini J.R, Alves L.C., Scarpari M, Falcão T, Romanel E, Brito M, Vicentini R., Pinto L., S Jackson. (2022), Data from: Analysis of the PEBP gene family and identification of a novel FLOWERING LOCUS T orthologue in sugarcane, Dryad, Dataset,

Manechini, J.R.V., Henrique, P., Romanel, E., Brito, M., Scarpari, M., S., Jackson, S., Pinto, L.R. and Vicentini, R., (2021). Transcriptomic Analysis of Changes in Gene Expression during Flowering Induction in Sugarcane Under Controlled Photoperiodic Conditions. Frontiers in Plant Science, 12, p.808.

da Silva Santos, P.H., Manechini, J.R.V., Brito, M.S., Romanel, E., Vicentini, R., Scarpari, M., Jackson, S. and Pinto, L.R. (2021). Selection and validation of reference genes by RT-qPCR under photoperiodic induction of flowering in sugarcane (Saccharum spp.). Scientific Reports, 11(1), pp.1-10.

Yao, M., Chen, W., Kong, J., Zhang, X., Shi, N., Zhong, S., Ma, P., Gallusci, P., Jackson, S., Liu, Y. and Hong, Y., (2020). METHYLTRANSFERASE1 and ripening modulate vivipary during tomato fruit development. Plant Physiology, 183(4), pp.1883-1897.

Yuan C, Li H, Qin C, Zhang X, Chen Q, Zhang P, Xu X, He M, Zhang X, Tör M, Xue D, Wang H, Jackson S, He Y, Liu Y, Shi N & Hong Y (2020). A Foxtail mosaic virus-induced flowering (FoMViF) assay in monocotyledonous crops. J.Exp.Bot. (on-line) DOI:10.1093/jxb/eraa080

Zhang X, Kang L, Zhang Q, Meng Q, Pan Y, Yu Z, Shi N, Jackson S, Zhang X-l, Wang H, Tor M & Hong Y (2019). An RNAi suppressor activates in planta virus–mediated gene editing. Functional & Integrative Genomics,  DOI:10.1007/s10142-019-00730-y

Chen, W.W., Zhang, X., Fan, Y., Li, B., Ryabov, E., Shi, N., Zhao, M., Yu, Z., Qin, C., Zheng, Q. Zhang, P., Wang, H., Jackson, S., Cheng, Q., Liu, Y., Gallusci, P. and Y. Hong (2018). A Genetic Network for Systemic RNA Silencing in Plants. Plant physiol. 176(4): 2700-19. DOI:10.1104/pp.17.01828

Yu Z, Chen Q, Chen W, Zhang X, Mei F, Zhang P, Zhao M, Wang X, Shi N, Jackson S and Y Hong (2018). Multigene editing via CRISPR/Cas9 guided by a single-sgRNA seed in Arabidopsis. JIPB 60(5): 376-381. DOI: 10.1111/jipb.12622

Qin C, Li B, Fan Y, Zhang X, Yu Z, Ryabov E, Zhao M, Wang H, Shi N, Zhang P, Jackson S, Tor M, Cheng Q, Liu Y, Gallusci P and Y Hong (2017). Roles of Dicer-Like proteins 2 and 4 in Intra-and Intercellular Antiviral Silencing. Plant Physiol. 174: 1067-1081. DOI: 10.1104/pp.17.00475

Taylor JL, Massiah A, Kennedy S, Hong Y, and S Jackson (2017). FLC expression is down-regulated by cold treatment in Diplotaxis tenuifolia (wild rocket), but flowering time is unaffected. J. Plant Physiol. 214: 7-15. DOI: 10.1016/j.jplph.2017.03.015

Qin C, Chen W, Shen J, Cheng L, Akande F, Zhang K, Yuan C., Li C, Zhang P, Shi N, Cheng Q, Liu Y, Jackson S and Y Hong (2017). A Virus-induced Assay for Functional Dissection and Analysis of Monocot and Dicot Flowering Time Genes. Plant Physiol. 174: 875-885.
DOI: 10.1104/pp.17.00392

Sari CR, Taylor J, Hong Y and S Jackson (2016). Development of a transient viral CRISPR expression system to manipulate flowering time in plants. International Journal of Applied and Physical Sciences 2(3): 65-70. DOI: 10.20469/ijaps.2.50002-3

Sgamma T., Pape, J., Massiah, A. and S Jackson (2016). Selection of reference genes for diurnal and developmental time-course real-time PCR expression analyses in lettuce. Plant Methods 12(1): 1-9. DOI 10.1186/s13007-016-0121-y.

Chen W, Kong J, Yang J, Qin C, Yu S, Tan J, Chen Y, Wu C, Wang H, Shi Y, Li C, Li B, Zhang P, Wang Y, Lai T, Yu Z, Zhang X, Shi N, Wang H, Osman T, Liu Y, Manning K, Jackson S, Rolin D, Zhong S, Seymour G, Gallusci P & Hong Y (2015). Requirement of CHROMOMETHYLASE 3 for somatic inheritance of the spontaneous tomato epimutation Colourless non-ripening. Scientific Reports 5: 9192. DOI: 10.10381/srep09192.

Hong, Y. & Jackson S.D. (2015). Floral induction and flower formation -the role and potential
applications of miRNAs. Plant Biotechnology Journal 13: 282-292. DOI: 10.1111/pbi.12340

Chen W, Kong J, Lai T, Manning K, Wu C, Wang Y, Qin C, Li B, Zhang X, Yu Z, Wang H, Zhang P, Gu M, Yang X, Mahammed A, Li C, Osman T, Shi N, Wang H, Jackson S, Liu Y, Gallusci P and Hong Y (2015). Tuning LeSPL-CNR expression by SlymiR157 affects tomato fruit ripening. Scientific Reports 5: 7852. DOI: 10.1038/srep07852

Spanudakis, E. & S.Jackson (2014)
. The role of microRNAs in the control of flowering time. Journal of Experimental Botany 65: 365-380

Zhou, T., Zhang, H., Lai, T., Qin, C., Shi, N., Jin, M., Zhong, S., Fan, Z., Liu, Y., Wu, Z., Jackson, S., Giovannoni, J., Rolin, D., Gallusci, P. and Y. Hong (2012). Virus-induced gene complementation reveals a transcription factor network in modulation of tomato fruit ripening. Scientific Reports 2: 836. DOI:10,1038/srep00836

Jackson S.D. and Y.Hong (2012). Systemic movement of FT mRNA and a possible role in floral induction. Frontiers in Plant Science 3: article 127 pp4

Li, C., Gu, M., Shi, N., Zhang,H., Yang, X., Osman, T., Liu,Y., Wang, H., Vatish, M., Jackson, S. & Y.Hong (2011). Mobile FT mRNA contributes to the systemic florigen signaling in floral induction. Scientific Reports 1: 73. (Research highlight by Nature Middle East, doi:10.1038/nmiddleeast.2011.123).

Breeze, E., Harrison, E., McHattie, S., Hughes, L., Hickman, R., Hill, C., Kiddle, S., Kim, Y., Penfold, C., Jenkins, D., Zhang, C., Morris, K., Jenner, C., Jackson, S., Thomas, B., Tabrett, A., Legaie, R., Moore, J.D., Wild, D.L., Ott, S., Rand, D., Beynon, J., Denby, K., Mead, A. and V. Buchanan-Wollaston (2011). High resolution temporal profiling of transcripts during Arabidopsis leaf senescence reveals a distinct chronology of processes and regulation. Plant Cell 23: 873-894

Morris, K. and S.Jackson (2010). DAY NEUTRAL FLOWERING does not act through GIGANTEA and FKF1 to regulate CONSTANS expression and flowering time. Plant Signalling and Behaviour 5:1105-1107

Morris, K., Thornber, S., Codrai, L., Richardson, C., Craig, A., Sadanandom, A., Thomas, B. and S. Jackson (2010). DAY NEUTRAL FLOWERING represses CONSTANS to prevent Arabidopsis flowering early in short days. Plant Cell 22:1-11

Li, C., Zhang, K., Zeng ,X., Jackson, S., Zhou, Y., and Y. Hong (2009). A cis-element within FLOWERING LOCUS T mRNA determines its mobility and facilitates trafficking of heterologous viral RNA. J.Virology 83:3540-3548. (Faculty of 1000 Biology).

 Jackson, S.D. (2009). Tansley Review: Plant Responses to Photoperiod. New Phytologist 181: 517-531. See pdf