Viruses attack on plants

Most plant viruses are transmitted by insect vectors that cause damage to the plant and create an entry point for pathogens, or that tap into the phloem to feed. Once inside, viruses use the handful of genes in their tiny genomes to orchestrate the plant cells’ machinery, while evading the plant’s defenses. Below is a generalized depiction of this infection process for RNA viruses, the most common type of plant virus. Some viruses can infect plants when aphids and other insects tap into the phloem to feed. Such insect vectors can also pick up virus particles and carry them to new plant hosts. Other viruses infect plant cells through a wound site created by a leaf-munching insect such as a beetle.
In a major breakthrough that helps us better understand how viruses cause diseases in plants and potentially in animals and humans -- Dr Ming-Bo Wang and Neil Smith of CSIRO Plant Industry have revealed a genetic mechanism that enables viral organisms to infect hosts and cause diseases.
"Cucumber Mosaic Virus (CMV) is a common, destructive virus that affects a wide range of food crops and ornamental plants," Dr Wang said. "What we found was that CMV, accompanied by a special type of viral particle called a 'satellite', causes its distinctive yellowing symptoms in plants by slicing a gene that makes chlorophyll, the green pigment in leaves. By preventing the production of chlorophyll, the virus causes the leaves to become partially or entirely yellowed which dramatically affects growth and productivity." Importantly, Dr Wang and Mr Smith determined the exact gene affected by this virus -- a gene called CHL1. "Pinpointing this gene represents a major step forward in understanding exactly how some viruses cause disease symptoms in susceptible organisms," Dr Wang said. Until recently, scientists did not fully understand why viruses only affected a small range of host organisms. This discovery shows that the accompanying satellite gene of CMV must directly match the host plant's genes to cause the yellowing disease. When the viral satellite's genes match the host plant's genes, the satellite genes 'lock' onto and slice the host's genes, preventing the host from forming green chlorophyll pigment.
"Think of it as like doing up a zipper on your jacket -- two opposing but different sections have to come together for it to work," Dr Wang said. "So one half of the 'zipper' genes come from the virus and the other half of the genes from the host, and when they match up the virus causes disease." This finding means researchers can focus on finding genes in viruses that match known genetic sequences in plants, and this can help to reveal the cause of diseases by other viruses. Knowing how CMV causes symptoms, Dr Wang and Mr Smith also experimented to see if they could block the viral disease in plants. They created specially altered plants with an extra copy of the chlorophyll-producing gene. This gene had been changed so that it no longer matched the viral gene, allowing the plants to produce the green chlorophyll pigment. Remarkably, this small change in genetic makeup prevented the plants from becoming yellow and diseased but did not change any other aspects of the plants' growth, habit or form.
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