Statistical correlations of primer thermodynamic stability DeltaG degrees for enhanced flax ISSR-PCR cultivar authentication.

We revealed four statistically significant correlations related to inter-simple-sequence repeat (ISSR) patterns: (1) between thermodynamic free energy DeltaG degrees of ISSR primer sequence and PCR reamplification intensity (dA(i)), (2) between free energy DeltaG degrees of ISSR primer sequence and PIC coefficient quantifying the polymorphism of ISSR patterns, (3) and (4) between free energy DeltaG degrees of anchor sequence of primer and the number of total, and polymorphic bands in ISSR patterns, respectively. Methodological recommendations for effective ISSR primer design were inferred based on revealed correlations. In particular, free energy of ISSR primer sequence is recommended to be DeltaG degrees > 160 kJ/mol of interaction and free energy of flanking anchor sequence in primer to be around DeltaG degrees = 28 kJ/mol of interaction to produce ISSR patterns displaying maximum polymorphism of flax germplasm.

Insertion of a reamplification round into the ISSR-PCR protocol gives new flax fingerprinting patterns.

We expanded the basic ISSR-PCR protocol by an additional PCR reamplification round in order to detect whether increased PCR productivity would give new bands in ISSR patterns. We found that the reamplification step had a prominent impact on the quality of the inter-simple-sequence repeat (ISSR) PCR patterns of flax, depending on the particular primer used for PCR amplification. We could clearly distinguish between two types of reamplification effect. Most ISSR primers (16 out of 21) gave no reamplification effect as usual, but five primers (23.8%) provided a new ISSR fingerprinting pattern after the 2nd reamplification round, leaving the previous 1st round pattern completely blank. Therefore, we recommend the expansion of a basic ISSR-PCR protocol for another reamplification round in order to mine out full the fingerprinting potential from ISSR-PCR method.