{"id":375568,"date":"2021-01-26T17:43:30","date_gmt":"2021-01-26T20:43:30","guid":{"rendered":"https:\/\/revistapesquisa.fapesp.br\/?p=375568"},"modified":"2021-02-08T13:04:34","modified_gmt":"2021-02-08T16:04:34","slug":"disease-immune-orange-trees","status":"publish","type":"post","link":"https:\/\/revistapesquisa.fapesp.br\/en\/disease-immune-orange-trees\/","title":{"rendered":"Disease-immune orange trees"},"content":{"rendered":"

Pineapple and Hamlin orange cultivars engineered with tangerine genes have successfully developed resistance to citrus variegated chlorosis (CVC), in a project led by researchers at the Campinas Institute of Agriculture\u2019s (IAC) Citrus Center in S\u00e3o Paulo, southeastern Brazil. The researchers infected tangerine trees, which are naturally resistant to CVC, with the disease-causing bacterium, Xylella fastidiosa<\/em>, and identified a gene potentially accountable for their resistance.<\/p>\n

The gene, called RAP2.2, was already known to the scientific community for its presence in other plant species, but its role in protecting citrus plants from Xylella<\/em>, \u201cand the possibility of introducing it into sweet orange trees to create resistance,\u201d was a brand-new discovery, says biologist Alessandra Alves de Souza, who led the research team at IAC, a 133-year-old research institute. The process that led to the discovery was reported in two papers in Phytopathology<\/em> and Molecular Plant-Microbe Interactions<\/em> in 2019 and 2020, respectively.<\/p>\n

Citrus variegated chlorosis is transmitted to orange trees through the bite of a leafhopper\u2014an insect about a centimeter in length. After infecting orange trees, Xylella <\/em>bacteria immediately begin to multiply and obstruct the channels that transport water and nutrients from the root to the top of the plant. This results in small, hard fruit that are not suitable for consumption or for sale. Once the most dreaded pest for citrus growers in Brazil\u2014in 2009 Xylella<\/em> affected 42% of citrus groves in the state of S\u00e3o Paulo, the Minas Triangle, and the southeast of Minas Gerais\u2014the disease now affects 1.04% of citrus farms, according to a 2020 survey by the Brazilian Fund for Citrus Protection (FUNDECITRUS), published July 24. Crop management practices to combat the disease include the use of pesticides and planting healthy seedlings in protected environments.<\/p>\n

But genes from tangerine trees may be able to help orange trees to better defend themselves from the disease. \u201cThis gene binds to the plant\u2019s DNA and activates other genes that play a role in strengthening the plant\u2019s cell walls. This traps and prevents the bacterium from moving about as easily,\u201d explains Souza. \u201cThe plant then detects the pathogen and activates its resistance mechanism, and is able to either kill it or significantly mitigate the resulting damage.\u201d With sweet oranges being the most important crop in Brazil\u2019s citrus industry, the new plant varieties could help make growers more competitive. \u201cTheir farm operations could become more productive, more sustainable, and more cost-efficient,\u201d notes the biologist.<\/p>\n

Because tangerine and citrus trees can readily interbreed in the wild, the procedure the researchers used is termed not as transgenesis but as cisgenesis\u2014when genes are introduced from closely related species. This makes the development of new varieties not only faster but also safer by eliminating steps that could result in incompatibility.<\/p>\n

Sweet orange plants with tangerine plant genes are currently being prepared for field testing at the Citrus Center, after performing well in greenhouses. Because these are genetically modified plants, the field-testing step requires a permit from the National Biosafety Technical Commission (CTNBIO). \u201cWe\u2019re working on the paperwork and expect it will be cleared by the end of the year,\u201d says Souza. The field-testing phase should take five years and, if successful, the new plants will be approved for use by citrus growers.<\/p>\n

After identifying a series of genes potentially associated with CVC resistance mechanisms, the researchers inserted them into Arabidopsis thaliana<\/em>, a species widely used as a model plant in molecular biology research. \u201cThis saved us many years of research, as transferring and studying all the different gene candidates in orange trees would have been an expensive and lengthy process,\u201d explains Souza, \u201csince orange trees take three years to develop and have a long juvenile stage in which genetic manipulation is difficult.\u201d By performing tests on a model plant they were able to reduce this period to about eight months. Following experiments with Arabidopsis<\/em>, the researchers selected the most promising gene, RAP2.2, and transferred it to sweet orange plants.<\/p>\n

One leg of the research project was developed at the Davis campus of the University of California (UC), where biotechnologist Willian Pereira spent a year doing research as part of Brazil\u2019s Science without Borders program, while pursuing his PhD under Souza at the University of Campinas (UNICAMP).<\/p>\n

From August 2015 to July 2016, he expanded his research using Arabidopsis<\/em> model organisms in the UC Davis Department of Plant Sciences. During his time there, he compared the function of the RAP2.2 protein in the model plant and in tangerine plants. After finding they bore similarity, he evaluated how each plant would react to infection with Xylella<\/em>. \u201cThe results showed that these proteins are orthologous, meaning they perform the same functions in the two plant species. We also found that Arabidopsis <\/em>and sweet orange trees share similar infection behavior, with the bacteria colonizing the same channels and creating the same symptoms,\u201d says Pereira. Their research showed, in addition, that Arabidopsis<\/em> can be used as a model plant for future research with other citrus genes, for a variety of applications.<\/p>\n

\u201cThe possibility of developing resistant plants would mean less pesticides would be required against leafhoppers, the insect vectors of CVC,\u201d says crop scientist Antonio Juliano Ayres, general manager at FUNDECITRUS. He notes, however, that \u201cthe preliminary results from greenhouse experiments still need to be proven through field testing.\u201d<\/p>\n

But early-stage results suggest that RAP2.2 can be used not only for crops susceptible to Xylella <\/em>infection, such as olive groves and vineyards, but potentially also to combat other citrus diseases, such as greening.<\/em> Also known as HLB, which refers to its original name in Chinese (Huanglongbing<\/em>), citrus greening disease is currently the biggest challenge facing the global citrus industry, affecting 20.87% of orange groves in S\u00e3o Paulo and Minas Gerais, according to data for this year from FUNDECITRUS.<\/p>\n

Like Xylella<\/em>, HLB is also transmitted by an insect, the psyllid Diaphorina citri<\/em>, and the bacterium Candidatus liberibacter<\/em> similarly colonizes the plant\u2019s vessels. \u201cWe suspect the tangerine gene strengthens the plant\u2019s vessel walls and helps it to eliminate the bacteria. With stronger vessel walls, the insect might also be deterred from biting the plant in the first place,\u201d says Souza. \u201cWe\u2019re exploring this possibility.\u201d<\/p>\n

The Sylvio Moreira Citrus Center has a long tradition of developing new approaches to fighting citrus pests. In 2017, Souza and her colleagues developed another transgenic cultivar with resistance to CVC. In this experiment the researchers introduced a gene from the bacterium itself\u2014rpfF<\/em>\u2014into the plant\u2019s genome: rpfF<\/em> produces a hormone protein that reduces the movement of Xylella<\/em>. In 2020, the experimental plants completed two years of field tests, and have so far shown resistance to the pathogen and good development under field conditions. The Xylella<\/em> genome was the world\u2019s first genome from a plant pathogen to be sequenced, as part of the FAPESP Genome Program. The project, codeveloped by Souza, was featured on the cover of Nature on July 13, 2000.<\/p>\n

Another significant project at the Citrus Center developed a product in the lab that uses an antioxidant molecule, called N-acetylcysteine (NAC), as an active ingredient against CVC, citrus canker, and HLB. NAC has been marketed since 2019 by startup CiaCamp \u2013 da Ci\u00eancia ao Campo. Souza says the technologies they have developed are mutually supplementary. \u201cWe will never have a single gene or product that is a cure-all solution. Our research helps to provide options. Years from now, the pathogen may be able to break through the plant\u2019s resistance. So we need different approaches to be future-ready,\u201d she says.<\/p>\n

Projects<\/strong>
\n1.<\/strong> INCT 2014: comparative and functional genomics and citrus-assisted breeding (no. 14\/50880-0<\/a>); Grant Mechanism<\/strong> Thematic Project; CNPq-INCTs Cooperation; Principal Investigator<\/strong> Marcos Antonio Machado (IAC); Investment<\/strong> R$3,138,880.49.
\n2.<\/strong> Xylella fastidiosa-vector-host plant interaction and approaches for citrus variegated chlorosis and citrus canker control (no. 13\/10957-0<\/a>); Grant Mechanism<\/strong> Thematic Project; Principal Investigator Alessandra Alves de Souza (IAC); Investment<\/strong> R$2,504,726.74.
\n3.<\/strong>\u00a0Molecular basis for pathogen recognition and resistance aimed to control bacterial diseases of citrus (no. 15\/50462-6<\/a>);\u00a0Grant Mechanism<\/strong>\u00a0Regular Research Grant;\u00a0Program<\/strong>\u00a0SPRINT\u00a0Agreement<\/strong>\u00a0University of California, Davis;\u00a0Principal Investigator<\/strong>\u00a0Alessandra Alves de Souza (IAC);\u00a0Investment<\/strong>\u00a0R$24,038.58.
\n4.<\/strong>\u00a0Applied functional analysis of transcriptional factor RAP2.2 and of resistance gene RPS5 in phytopathogen Xylella fastidiosa<\/em>\u00a0tolerance (no. 13\/26944-5<\/a>);\u00a0Grant Mechanism<\/strong>\u00a0PhD Grant;\u00a0Principal Investigator<\/strong>\u00a0Alessandra Alves de Souza (IAC);\u00a0Scholarship Beneficiary<\/strong>\u00a0Willian Eduardo Lino Pereira; Investment<\/strong> R$130,462.81.<\/p>\n

Scientific articles<\/strong>
\nPEREIRA, W. E. L. et al.<\/em> Citrus reticulata<\/em> CrRAP2.2 transcriptional factor shares similar functions to the Arabidopsis homolog and increases resistance to Xylella fastidiosa<\/em><\/a>.<\/em> Molecular Plant-Microbe Interactions<\/strong>. Vol. 33, no. 3, pp. 519\u201327. Jan. 23, 2020.
\nPEREIRA, W. E. L.\u00a0et al<\/em>.\u00a0Xylella fastidiosa<\/em><\/a>\u00a0subsp.\u00a0<\/a>pauca<\/em><\/a>\u00a0and\u00a0<\/a>fastidiosa<\/em><\/a>\u00a0colonize\u00a0<\/a>Arabidopsis<\/em><\/a>\u00a0systemically and induce anthocyanin accumulation in infected leaves<\/a>.\u00a0Phytopathology<\/strong>. Vol. 109, no. 2, pp. 225\u201332. Jan. 4, 2019.<\/p>\n","protected":false},"excerpt":{"rendered":"New cultivars developed at the Campinas Agronomic Institute using tangerine genes show resistance to citrus variegated chlorosis","protected":false},"author":684,"featured_media":376425,"comment_status":"closed","ping_status":"closed","sticky":false,"template":"","format":"standard","meta":{"_acf_changed":false,"_exactmetrics_skip_tracking":false,"_exactmetrics_sitenote_active":false,"_exactmetrics_sitenote_note":"","_exactmetrics_sitenote_category":0,"footnotes":""},"categories":[169],"tags":[153,213,229,237],"coauthors":[2721],"class_list":["post-375568","post","type-post","status-publish","format-standard","has-post-thumbnail","hentry","category-technology","tag-agronomy","tag-botany","tag-epidemiology","tag-genetics"],"acf":[],"_links":{"self":[{"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/posts\/375568","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/users\/684"}],"replies":[{"embeddable":true,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/comments?post=375568"}],"version-history":[{"count":5,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/posts\/375568\/revisions"}],"predecessor-version":[{"id":378939,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/posts\/375568\/revisions\/378939"}],"wp:featuredmedia":[{"embeddable":true,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/media\/376425"}],"wp:attachment":[{"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/media?parent=375568"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/categories?post=375568"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/tags?post=375568"},{"taxonomy":"author","embeddable":true,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/coauthors?post=375568"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}