Loop-mediated Isothermal Amplification (LAMP) and its application in detection A. Ishwara Bhat

1. Loop-mediated Isothermal Amplification (LAMP) and its application in detection A. IshwaraBhat Senior Scientist Indian Institute of Spices Research Marikunnu, Calicut 673012

2. Loop mediated isothermal amplification (LAMP) New amplification method used for pathogen detection in humans, animals and plants Amplification takes place at a single temperature (65 C) (No need of thermal cycler). Economy in cost as it does not require special reagents or sophisticated equipments Uses polymerase with high strand displacement activity (instead of Taq Poly) Amplification efficiency is high Can be used for RNA templates by addition of reverse transcriptase

3. Primers FIP (Forward Inner Primer): consists of the F2 region (at the 3' end) that is complementary to the F2c region, and the same sequence as the F1c region at the 5' end. F3: Forward Outer Primer consists of the F3 region that is complementary to the F3c region BIP (Backward Inner Primer): consists of the B2 region (at the 3' end) that is complementary to the B2c region, and the same sequence as the B1c region at the 5' end Internal primer FIP Loop primer FL External primer F3 F1c F2 F3c F2c FL F1c B1 BLc B2 B3 External primer B3 F3 F2 FLc F1 B1c BL B2c B3c Loop primer BL Internal primer BIP B2 B1c 3’ 5’ 3’ 5’

4. B3: Backward Outer Primer consists of the B3 region that is complementary to the B3c region Loop F (Loop Forward): sequences complementary to the single stranded loop region between the F1 and F2 regions on the 5' end of the dumbbell-like structure Loop B (Loop Backward): sequences complementary to the single stranded loop region between the B1 and B2 regions on the 5' end of the dumbbell-like structure Distance between primer regions Between 5' end of F2 and B2 is considered to be 120-180bp, and the distance between F2 and F3 as well as B2 and B3 is 0-20bp The distance for loop forming regions (5' of F2 to 3' of F1, 5' of B2 to 3' of B1) is 40-60bp

5. Tm value for primer regions About 60-65°C in the case of GC rich and Normal, about 55-60°C for AT rich GC contents About 50-60% in the case of GC rich and Normal, about 40-50% for AT rich Secondary structure Primers should be designed so as not to easily form secondary structures. 3' end sequence should not be AT rich or complementary to other primers Others If the restriction enzyme sites exist on the target sequence, except the primer regions, they can be used to confirm the amplified products Animation site: http://loopamp.eiken.co.jp/e/lamp/anim.html

6. LAMP Reaction STEP1As double stranded DNA is in the condition of dynamic equilibrium at the temperature around 65°C, one of the LAMP primers can anneal to the complimentary sequence of double stranded target DNA, then initiates DNA synthesis using the DNA polymerase with strand displacement activity, displacing and releasing a single stranded DNA. With the LAMP method, unlike with PCR, there is no need for heat denaturation of the double stranded DNA into a single strand. The following amplification mechanism explains from when the FIP anneals to such released single stranded template DNA

7. STEP2Through the activity of DNA polymerase with strand displacement activity, a DNA strand complementary to the template DNA is synthesized, starting from the 3' end of the F2 region of the FIP STEP3The F3 Primer anneals to the F3c region, outside of FIP, on the target DNA and initiates strand displacement DNA synthesis, releasing the FIP-linked complementary strand. STEP4A double strand is formed from the DNA strand synthesized from the F3 Primer and the template DNA strand

8. STEP6This single strand DNA in Step (5) serves as a template for BIP-initiated DNA synthesis and subsequent B3-primed strand displacement DNA synthesis. The BIP anneals to the DNA strand produced in Step (5). Starting from the 3' end of the BIP, synthesis of complementary DNA takes place. Through this process, the DNA reverts from a loop structure into a linear structure. The B3 Primer anneals to the outside of the BIP and then, through the activity of the DNA polymerase and starting at the 3' end, the DNA synthesized from the BIP is displaced and released as a single strand before DNA synthesis from the B3 Primer

9. STEP8The BIP-linked complementary strand displaced in Step (6) forms a structure with stem-loops at each end, which looks like a dumbbell structure. This structure serves as the starting structure for the amplification cycle in the LAMP method (LAMP cycling). The above process can be understood as producing the starting structure for LAMP cycling Animation site: http://loopamp.eiken.co.jp/e/lamp/anim.html

10. Cycling amplification step A dumbbell-like DNA structure is quickly converted into a stem-loop DNA by self-primed DNA synthesis. FIP anneals to the single stranded region in the stem-loop DNA and primes strand displacement DNA synthesis, releasing the previously synthesized strand. This released single strand forms a stem-loop structure at the 3' end because of complementary B1c and B1 regions. Then, starting from the 3' end of the B1 region, DNA synthesis starts using self-structure as a template, and releases FIP-linked complementary strand (Step (9)). The released single strand then forms a dumbbell-like structure as both ends have complementary F1 - F1c and B1c - B1 regions, respectively (Step (11)). This structure is the 'turn over' structure of the structure formed in Step (8). Similar to the Steps from (8) to (11), structure in Step (11) leads to self-primed DNA synthesis starting from the 3' end of the B1 region. Furthermore, BIP anneals to the B2c region and primes strand displacement DNA synthesis, releasing the B1-primed DNA strand. Accordingly, similar structures to Steps (9) and (10) as well as the same structure as Step (8) are produced. With the structure produced in Step (10), the BIP anneals to the single strand B2c region, and DNA synthesis continues by displacing double stranded DNA sequence. As a result of this process, various sized structures consisting of alternately inverted repeats of the target sequence on the same strand are formed

14. Procedure

15. Detection methods Visual methods Real time Optigene instrument for LAMP

16. Detection of Sweet potato feathery mottle and Sweet potato chlorotic stunt viruses by LAMP Sweet potato chlorotic virus Primers designed F3: CATCTGAGCAACTGGCTCTT (Sense orientation) B3: ACCATGAACACATTCTCGAGAT (antisense orientation) FIP: CCTGTAATTTGCCTCACAAAACTCTCCATTCTAACTCACCAGACATTATGTCT (F1c + F2) BIP: GAGATTTTTGCAAGTTTCTACGCATCTGGAAAAGAACGCGTCGAATG (B1 + B2c) F-loop: GTCTCTTGAATTCATCTTCTTGAC (antisense orientation) B-loop: CAAGCTTGGGCAAACCAAAG (Sense orientation) Sweet potato feathery mottle Primers designed F3: TACAACGTAAMCTTGACTGATATGAGT B3: GTTATGTATATTTCTAGTAACA/GTCAGT FIP: GCTGCYTTTCATCTGYAWTWTGTGGATATGCATTTGATTTYTAYGAGCT BIP: AAGAATGCRCRWAATCGGTTGTTTGGGCCTCTCCGTATCYTCTTCTT F-loop: TTCTTTAGCACGTGYAGGKG B-loop: TGGAYGGAAACGTCTCCAC

17. Procedure Total DNA/RNA isolation from infected and healthy plant

18. Incubated tube at 65 C for 40 min Product run on 1.2% agarose gel Presence of multiple bands

19. Real time LAMP assay for detection of viruses By including sybergreen dye in the reaction LAMP instrument (Genie II from Optigene, UK). Rapid amplification  Result confirmation through anneal / melt  Portable, Battery powered  ( 2 kg weight) Stand alone operation without a computer USB memory stick interface for easy access to data files  Supports many fluorescence and luminescence chemistries

20. Detection of SPFMV and SPCSV using real time LAMP

21. Melt curve analysis of LAMP products

22. Thank You