Development of Real-Time Fluorescence CRISPR/Cas12a-Based Detection as a Portable Diagnostic System Using Integrated Circuits
Main Article Content
Abstract
A solution for achieving high-performance measurements in a space-constrained experimental setup was developed as a portable incubating instrument for real-time fluorescence detection of AvrPi9 gene in rice blast fungus by using a calibrated spectrometer in CRISPR-Cas12a detection. The system demonstrates accurate temperature control with low energy consumption and low deviation of ±0.16 °C from the setpoint temperatures, with high sensitivity and accurate detection within 10 min. The CRISPR-Cas12a detection reaction was demonstrated using AvrPi9 PCR product, crRNAs, LbCas12a and fluorescence-quencher reporter incubating at 37 °C for 10 min. Calibrated C12666MA spectrometer with 480 nm and 520 nm LEDs vs HR4000 reference exhibits low RMS of 0.54 and 1.30 and drift of 6.4 nm and 4.84 nm, respectively indicating high accuracy and reliability in fluorescence detection. Fluorescence signals were observed under an LED transilluminator, while real-time analysis was conducted through spectrometric measurements upon excitation by a 480 nm high-intensity blue LED source. Accuracy of detection between positive, non-template and non-target control was reported with no incidence of false positives observed. The instrument exhibits reliable quantitative detection capabilities with a limit of detection of 3.8 ng of DNA targets that are comparable to when running the same reaction on a commercial real-time PCR, with a detection limit of 1 ng. This study demonstrates that the CRISPR-Cas12a detection method represents a significant breakthrough in molecular diagnostics due to its advantages of rapidity, high sensitivity, and convenience allowing for the development of a compact, and energy-efficient platform that can facilitate real-time on-site diagnostics with accurate temperature control.
Article Details
References
R. Augustine, A. Hasan, S. Das, R. Ahmed, Y. Mori, T. Notomi, B. D. Kevadiya, and A. S. Thakor, “Loop-Mediated Isothermal Amplification (LAMP): A rapid, sensitive, specific, and cost-effective point-of-care test for coronaviruses in the context of COVID-19 pandemic,” Biology (Basel), vol. 9, no. 8, p. 182, 2020.
Y. Zhang, Y. Zhang, and K. Xie, “Evaluation of CRISPR/Cas12a-based DNA detection for fast pathogen diagnosis and GMO test in rice,” Molecular Breeding, vol. 40, 2020, Art. no. 11.
K. Buddhachat, N. Sripairoj, O. Ritbamrung, P. Inthima, K. Ratanasut, T. Boonsrangsom, T. Rungrat, P. Pongcharoen, and K. Sujipuli, “RPA-Assisted Cas12a system for detecting pathogenic xanthomonas oryzae, a causative agent for bacterial leaf blight disease in rice,” Rice Science, vol. 29, no. 4, pp. 340–352, 2022.
C. Sukphattanaudomchoke, S. Siripattanapipong, T. Thita, S. Leelayoova, P. Piyaraj, M. Mungthin, and T. Ruang-Areerate, “Simplified closed tube loop mediated isothermal amplification (LAMP) assay for visual diagnosis of Leishmania infection,” Acta Tropica, vol. 212, 2020, Art. no. 105651.
A. Kumaran, N. Jude Serpes, T. Gupta, A. James, A. Sharma, D. Kumar, R. Nagraik, V. Kumar, and S. Pandey, “Advancements in CRISPR-based biosensing for next-gen point of care diagnostic application,” Biosensors (Basel), vol. 13, no. 2, 2023.
X. Liu, X. Qiu, S. Xu, Y. Che, L. Han, Y. Kang, Y. Yue, S. Chen, F. Li, and Z. Li, “A CRISPR-Cas12a-assisted fluorescence platform for rapid and accurate detection of nocardia cyriacigeorgica,” Frontiers in Cellular and Infection Microbiology, vol. 12, 2022, Art. no. 835213.
L. Fang, L. Yang, M. Han, H. Xu, W. Ding, and X. Dong, “CRISPR-cas technology: A key approach for SARS-CoV-2 detection,” Front Bioeng Biotechnol, vol. 11, 2023, Art. no. 1158672.
J. H. Soh, E. Balleza, M. N. A. Rahim, H. M. Chan, S. M. Ali, J. K. C. Chuah, S. Edris, A. Atef, A. Bahieldin, J. Y. Ying, and J. S. M. Sabir, “CRISPR-based systems for sensitive and rapid on-site COVID-19 diagnostics,” Trends Biotechnol, vol. 40, no. 11, pp. 1346–1360, 2022.
J. P. Broughton, X. Deng, G. Yu, C. L. Fasching, V. Servellita, J. Singh, X. Miao, J. A. Streithorst, A. Granados, A. Sotomayor-Gonzalez, K. Zorn, A. Gopez, E. Hsu, W. Gu, S. Miller, C. Y. Pan, H. Guevara, D. A. Wadford, J. S. Chen, and C. Y. Chiu, “CRISPR-Cas12-based detection of SARS-CoV-2,” Nat Biotechnol, vol. 38, no. 7, pp. 870–874, 2020.
Y. Dai, Y. Jia, J. Correll, X. Wang, and Y. Wang, “Diversification and evolution of the avirulence gene AVR-Pita1 in field isolates of Magnaporthe oryzae,” Fungal Genetics and Biology, vol. 47, no. 12, pp. 973–980, 2010.
Y. Zhou, F. Lei, Q. Wang, W. He, B. Yuan, and W. Yuan, “Identification of novel alleles of the rice blast-resistance gene Pi9 through sequence-based allele mining,” Rice, vol. 13, no. 1, 2020, Art. no. 80.
J. Huang, W. Si, Q. Deng, P. Li, and S. Yang, “Rapid evolution of avirulence genes in rice blast fungus Magnaporthe oryzae,” BMC Genet, vol. 15, 2014, Art. no. 45.
Y. Petit-Houdenot and I. Fudal, “Complex Interactions between fungal avirulence genes and their corresponding plant resistance genes and consequences for disease resistance management,” vol. 8, 2017, doi: 10.3389/ fpls.2017.01072.
J. Wu, Y. Kou, J. Bao, Y. Li, M. Tang, X. Zhu, A. Ponaya, G. Xiao, J. Li, C. Li, M. Y. Song, C. J. Cumagun, Q. Deng, G. Lu, J. S. Jeon, N. I. Naqvi, and B. Zhou, “Comparative genomics identifies the Magnaporthe oryzae avirulence effector AvrPi9 that triggers Pi9-mediated blast resistance in rice,” New Phytol, vol. 206, no. 4, pp. 1463–1475, 2015.
P. Puanprapai, T. Toojunda, and C. Jantasuriyarat, “Rice blast fungus avirulence gene AvrPi9 detection using a combination of RPA and CRISPR-Cas12a techniques,” HAYATI Journal of Biosciences, vol. 12, no. 8, 2023, Art. no.1569.
Y. Wu, L. Bai, C. Ye, Y. Guan, K. Yan, H. Chen, and Z. Jiang, “Novel miniaturized fluorescence loop-mediated isothermal amplification detection system for rapid on-site virus detection,” Front Bioeng Biotechnol, vol. 10, 2022, Art. no. 964244.
S. Jirawannaporn, U. Limothai, S. Tachaboon, J. Dinhuzen, P. Kiatamornrak, W. Chaisuriyong, J. Bhumitrakul, O. Mayuramart, S. Payungporn, and N. Srisawat, “Rapid and sensitive point-of-care detection of Leptospira by RPA-CRISPR/ Cas12a targeting lipL32,” PLOS Neglected Tropical Diseases, vol. 16, no. 1, 2022, Art no. e0010112.
J. P. Holmann, Experimental Methods for Engineers, 8th ed. New York: McGraw-Hill, pp. 6–7, 2011.
D. M. Jenkins, R. Kubota, J. Dong, Y. Li, and D. Higashiguchi, “Handheld device for real-time, quantitative, LAMP-based detection of Salmonella enterica using assimilating probes,” Biosens Bioelectron, vol. 30, no. 1, pp. 255–260, 2011.
Bio-Rad laboratories, “CFX Connect Real-time PCR System,” 2023. [Online]. Available: http:// www.bio-rad.com
J. R. Taylor, An Introduction to Error Analysis, 2nd ed. New York: University Science Books, pp. 97–103, 1997.
Hamamatsu, “C12666MA Mini-spectrometer,” 2022. [Online]. Available: http://www.hama matsu.com
M. L. Pieck, A. Ruck, M. L. Farman, G. L. Peterson, J. P. Stack, B. Valent, and K. F. Pedley, “Genomics-Based marker discovery and diagnostic assay development for wheat blast,” Plant Disease, vol. 101, no. 1, pp. 103–109, 2017.
G. Sun, J. Liu, G. Li, X. Zhang, T. Chen, J. Chen, H. Zhang, D. Wang, F. Sun, and H. Pan, “Quick and accurate detection and quantification of Magnaporthe oryzae in rice using real-time quantitative polymerase chain reaction,” Plant Disease, vol. 99, no. 2, pp. 219–224, 2015.
M. Su'udi, J. Kim, J. M. Park, S.C. Bae, D. Kim, Y. H. Kim, and I. P. Ahn, “Quantification of rice blast disease progressions through Taqman real-time PCR,” Mol Biotechnol, vol. 55, no. 1, pp. 43–48, 2013.
L. Rajendran, G. Nagaraj, A. Kamalakannan, M. Ganesan, R. Subramanian, and K. Marimuthu, “Development of Loop mediated isothermal amplification (LAMP) assay for the detection of Magnaporthe oryzae causing blast in rice,” Research Square, 2022, doi: 10.21203/rs.3.rs- 1322856/v1.
L. Li, S. Y. Zhang, and C. Q. Zhang, “Establishment of a rapid detection method for rice blast fungus based on one-step loop-mediated isothermal amplification (LAMP),” Plant Disease, vol. 103, no. 8, pp. 1967–1973, 2019.
M. Prasannakumar, P. B. Parivallal, P. Devanna, H. Mahesh, and E. Edwinraj, “LAMP-based foldable microdevice platform for the rapid detection of Magnaporthe oryzae and Sarocladium oryzae in rice seed,” Scientific Reports, vol. 11, p. 178, 2021.
S. F. Ortega, J. Tomlinson, J. Hodgetts, D. Spadaro, M. L. Gullino, and N. Boonham, “Development of loop-mediated isothermal amplification assays for the detection of seedborne fungal pathogens Fusarium fujikuroi and Magnaporthe oryzae in rice seed,” Plant Disease, vol. 102, no. 8, pp. 1549–1558, 2018.
M. U. Younas, G. Wang, H. Du, Y. Zhang, I. Ahmad, N. Rajput, M. Li, Z. Feng, K. Hu, N.U. Khan, W. Xie, M. Qasim, Z. Chen, and S. Zuo, “Approaches to reduce rice blast disease using knowledge from host resistance and pathogen pathogenicity,” International Journal of Molecular Sciences, vol. 24, no. 5, p. 4985, 2023.
J. Tan, H. Zhao, J. Li, Y. Gong, and X. Li, “The devastating rice blast airborne pathogen Magnaporthe oryzae-a review on genes studied with mutant analysis,” Pathogens, vol. 12, no. 3, 2023, Art. no. 379.
A. Sharma, J. B. Jones, and F. F. White, “Recent advances in developing disease resistance in plants,” F1000Res, vol. 8, 2019, doi: 10.12688/ f1000research.20179.1.
I. M. Lobato and C. K. O'Sullivan, “Recombinase polymerase amplification: Basics, applications and recent advances,” Trends Analytical Chemistry, vol. 98, pp. 19–35, Jan. 2018.
L. Dong, S. Liu, J. Li, D. Tharreau, P. Liu, D. Tao, and Q. Yang, “A rapid and simple method for DNA preparation of Magnaporthe oryzae from single rice blast lesions for PCR-based molecular analysis,” The Plant Pathology Journal, vol. 38, no. 6, pp. 679–684, 2022.