Artificial microRNA-mediated resistance against Oman strain of tomato yellow leaf curl virus

Maha R Al-Roshdi¹, Ume Ammara¹, Jamal Khan¹, Abdullah M Al-Sadi¹, Muhammad Shafiq Shahid¹

Affiliations

PMID: 37063229
PMCID: PMC10098008
DOI: 10.3389/fpls.2023.1164921

Artificial microRNA-mediated resistance against Oman strain of tomato yellow leaf curl virus

Maha R Al-Roshdi et al. Front Plant Sci. 2023.

. 2023 Mar 30:14:1164921.

doi: 10.3389/fpls.2023.1164921. eCollection 2023.

Authors

Maha R Al-Roshdi¹, Ume Ammara¹, Jamal Khan¹, Abdullah M Al-Sadi¹, Muhammad Shafiq Shahid¹

Affiliation

¹ Department of Plant Sciences, College of Agricultural and Marine Sciences, Sultan Qaboos University, Al-Khod, Oman.

PMID: 37063229
PMCID: PMC10098008
DOI: 10.3389/fpls.2023.1164921

Abstract

Tomato yellow leaf curl virus (TYLCV) is a global spreading begomovirus that is exerting a major restraint on global tomato production. In this transgenic approach, an RNA interference (RNAi)-based construct consisting of sequences of an artificial microRNA (amiRNA), a group of small RNA molecules necessary for plant cell development, signal transduction, and stimulus to biotic and abiotic disease was engineered targeting the AC1/Rep gene of the Oman strain of TYLCV-OM. The Rep-amiRNA constructs presented an effective approach in regulating the expression of the Rep gene against TYLCV as a silencing target to create transgenic Solanum lycopersicum L. plant tolerance against TYLCV infection. Molecular diagnosis by PCR followed by a Southern hybridization analysis were performed to confirm the effectiveness of agrobacterium-mediated transformation in T0/T1-transformed plants. A substantial decrease in virus replication was observed when T1 transgenic tomato plants were challenged with the TYLCV-OM infectious construct. Although natural resistance options against TYLCV infection are not accessible, the current study proposes that genetically transformed tomato plants expressing amiRNA could be a potential approach for engineering tolerance in plants against TYLCV infection and conceivably for the inhibition of viral diseases against different strains of whitefly-transmitted begomoviruses in Oman.

Keywords: RNA interference; agrobacterium-infiltration; artificial microRNA; gene silencing; southern blotting.

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Conflict of interest statement

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Figures

**Figure 1**
Schematic diagram of Rep-amiRNA1 **(A)** and Rep-amiRNA2 **(B)** cloned at the *EcoR*I/*Hind*III site of the pCAMBIA2300 plant expression vector, comprising the 35S2 promoter, *Nos* terminator, and *Npt*II as selectable markers **(C)**.

**Figure 2**
A fragment of 8.7 kb of expression vector pCAMBIA2300 Rep-amiRNA1 (Lane 1) and Rep-amiRNA2 (Lane 2) with a size of 300 bp. M= DNA marker **(A)**. *Agrobacterium* transformed with pCAMBIA2300 harboring Rep-amiRNA1 (Lane 1-4) and Rep-amiRNA2 (Lane 5-8). A fragment of 8.7 kb and 300 bp was yielded. M=DNA marker **(B)**.

**Figure 3**
Transient assay with Rep-amiRNA1 and Rep-amiRNA2 constructs in *N. benthamiana* plants agroinfiltrated with Rep-amiRNA1 **(B)** and Rep-amiRNA2(C). **(A)** is a healthy plant, shown here in comparison with a symptomatic plant **(D)**.

**Figure 4**
Southern hybridization blotting investigation of *N. benthamiana* plants inoculated with Rep-amiRNA1 (Lane 3-7) and Rep-amiRNA2 (Lane 8-11) and challenged with TYLCV. DNA from symptomatic plant inoculated with TYLCV only (Lane 2). Lane 1 is plasmid DNA. The position of single-stranded (ss), supercoiled (sc), and linear (lin) viral DNA forms is indicated with arrow. N= Negative control **(A)**. Southern blot analysis of F1-transformed tomato plants inoculated with Rep-amiRNA1 (Lane 4-8) and Rep-amiRNA2(Lane 3) and challenged with TYLCV-OM. DNA from symptomatic plant inoculated with TYLCV-OM as control (Lane 2). Lane 1 is plasmid DNA. N= Negative control. The position of single-stranded (ss), supercoiled (sc), and linear (lin) viral DNA forms is indicated with arrow **(B)**.

**Figure 5**
Tomato transformation. **(A)** Seedlings of tomato germinated on MS medium. **(B)** Cotyledon explants on pre-culture medium. **(C)** Cotyledon explants on selection medium after co-cultivation with *Agrobacterium*. **(D, E)** Callus with regeneration shoots on selection medium. **(F)** Shoots regenerating from a single callus growing on selection medium. **(G)** Cotyledon explant was discarded. **(H)** Young plantlet on shoot elongation medium. **(I)** Plantlet with well-developed roots on rooting medium. **(J)** Fully regenerated plant hardened in soil. **(K)** Two months after hardening. **(L)** Plant at flowering stage. **(M, N)** Mature transgenic tomato plants with fruits.

**Figure 6**
PCR results for Rep-amiRNA1 construct amplified from transformed tomato plants. Amplicon of 300bp was observed in 11 plants transformed with Rep-amiRNA1 construct. P1, P2= Positive control, N= Negative control, M= 1kb marker DNA **(A)**. PCR products were analyzed for Rep-amiRNA1 and Rep-amiRNA2 constructs amplified from transformed tomato plants. Amplicon of 300bp was observed in 10 plants transformed with Rep-amiRNA1 (Lane 1-9, 11) and three plants transformed with Rep-amiRNA2 (Lane 12, 13, 15). P1, P2= Positive control, N= Negative control, M= 1kb marker DNA **(B)**. PCR products were analyzed for Rep-amiRNA1 and Rep-amiRNA2 constructs amplified from transformed tomato plants. Amplicon of 300 bp was observed in three plants transformed with Rep-amiRNA1 (Lane 1, 3, 9) and two plants transformed with Rep-amiRNA2 (Lane 5, 6). P1, P2= Positive control, N= Negative control, M= 1kb marker DNA **(C)**.

**Figure 7**
Electron micrograph of a phloem **(A)** and parenchymal **(B)** cells from agroinoculated, symptomless transgenic plant. Nucleolus is obvious in the nucleus “N”, and a small clump “C” is also visible.

See this image and copyright information in PMC

References

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Artificial microRNA-mediated resistance against Oman strain of tomato yellow leaf curl virus

Affiliation

Artificial microRNA-mediated resistance against Oman strain of tomato yellow leaf curl virus

Authors

Affiliation

Abstract

Conflict of interest statement

Figures

References

LinkOut - more resources

Full Text Sources