Pooggin et al. (1998) concluded that mutations occurred within the 35S RNA leader sequence at “a surprisingly low frequency.” The requirement for a functional ribosome shunt could provide one constraint that could limit change within the 35S RNA leader sequence (Shababi et al. 2006).
Similitudes entre RT de CaMV et HIV http://www.btinternet.com/~nlpWESSEX/Documents/JIChiv-camv.htm
du point de vue des lignées non-symptomatiques, il est probable qu'on observe des mutations sur le gène VI, dans la mesure où : « the chlorosis and stunting in P6-transgenic and CaMV-infected plants are dependent on interactions between P6 and components involved in ethylene signalling, and that the suppressor gene product may function to augment these interactions. » Geri et al. 2004. Plant Mol Biol
Broglio, E. P. (1995). “Mutational analysis of cauliflower mosaic virus gene VI: changes in host range, symptoms, and discovery of transactivation-positive, noninfectious mutants.” Mol Plant Microbe Interact 8(5): 755-60. Gene VI of cauliflower mosaic virus (CaMV) has been shown to be a determinant of host specificity of the virus as well as a factor influencing symptom development in infected plants. In addition, it plays a crucial role in viral gene expression through a process of posttranscriptional transactivation. In the present study, linker- insertion mutations within gene VI of a cloned, recombinant cauliflower mosaic virus genome were constructed and tested for infectivity, symptom development on solanaceous plants, and the ability of transactivate viral gene expression. Certain mutations in the first third of the gene resulted in changes in symptoms shown by test plants. Another mutation, also in the first third of the gene, blocked infectivity in the Nicotiana species tested and systemic movement in Datura stramonium. The mutants were also tested in protoplasts for the ability to transactivate virus gene expression. Infectious mutants were invariably positive for transactivation and mutants negative for transactivation were noninfectious. Interestingly, two mutants positive for transactivation were noninfectious, suggesting a second function for gene VI in the infection process. These results further suggest a role for gene VI, as yet not fully understood, in systemic movement of the virus in infected plants.
Cui et al 2007 Plant Cell
Induced Expression of CDKC and CYCT1 Genes by CaMV Infection
Because of their roles in CaMV infection, we analyzed the expression of these CDKC and CYCT1 genes in CaMV-infected plants. Fully expanded lower leaves of 4-week-old Arabidopsis plants were mechanically inoculated with CaMV. As described above, it takes ;10 to 13 d after inoculation to first detect significant levels of CaMV viral DNA and observe symptom development in upper systemically infected leaves (Figure 1). As shown in Figure 6, the levels of transcripts for CDKC;1, CDKC;2, CYCT1;4, and CYCT1;5 were quite constant during the first 10 DAI but increased substantially at 14, 18, and 24 DAI. Neither mock inoculation nor TMV-cg or CaLCuV inoculation induced expression of the genes (Figure 6). Thus, the four genes were induced specifically by CaMV infection.