AI Article Synopsis
- Root-knot nematodes cause abnormal growth in cucumber roots by forming feeding sites called galls and disrupting natural root architecture.
- The study found that as the number of nematodes in these galls increases, the number of root tips decreases, highlighting the impact of nematode parasitism on root development.
- Additionally, the research revealed that auxin distribution is altered in response to nematode infection, with specific genes regulating auxin transport being significantly expressed during gall formation.
Article Abstract
Root-knot nematodes induce the formation of feeding sites within the host roots and the relocation of auxin into galls results in abnormal lateral root growth. Here, we analyzed the changes in cucumber root architecture under stress and the distribution of auxin in these morphological and molecular root changes. The number of root tips significantly decreased, and regression analysis showed a positive relationship between the size of root galls and the numbers of nematodes in galls compared with the lateral roots on galls, emphasizing the effect of nematode parasitism on root development. Data generated via a promoter-reporter system using the transgenic hairy root system first characterized the auxin distribution during nematode parasitism in cucumber. Using staining of root galls, we further detected the expression of and , which regulate polar auxin transport. The results showed that both and were induced in galls, and the relative expression of the two genes significantly increased at 21 DAI. The TIBA treatment, which can disrupt polar auxin transport inhibited the numbers of cucumber root tips and total length following increasing concentration gradients. Moreover, the numbers of galls were significantly affected by TIBA treatment, which showed the vital role of auxin during nematode parasitism. Our findings suggest that the transportation of auxin plays an important role during gall formation and induces cucumber lateral root development within nematode feeding sites.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11478513 | PMC |
| http://dx.doi.org/10.3390/plants13192679 | DOI Listing |
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