Complexity reduction in the AFLP (Amplified Fragment Length Polymorphism) procedure is achieved through selective amplification of a subset of genomic DNA fragments, thereby reducing the complexity of the analyzed DNA sample. Here's how complexity reduction is achieved in AFLP:

·        Selective Restriction Digestion: AFLP begins with the digestion of genomic DNA using two different restriction enzymes. These enzymes are chosen to have different recognition sequences and cutting patterns, resulting in the generation of a large number of DNA fragments of varying lengths.

·        Adapter Ligation: Following restriction digestion, specific adapters containing known sequences are ligated to the ends of the DNA fragments. These adapters serve as priming sites for PCR amplification and also include selective nucleotides that allow for the preferential amplification of a subset of DNA fragments.

·        Pre-Selective PCR: The ligated DNA fragments are then subjected to a pre-selective PCR amplification step using primers that anneal to the adapter sequences. This step amplifies a broad range of DNA fragments, regardless of their specific sequence.

·        Selective PCR: After pre-selective amplification, a subset of DNA fragments is selectively amplified using a second round of PCR with primers that include selective bases complementary to specific sequences within the adapter-ligated fragments. These selective bases dictate the amplification of only those fragments containing the target sequences, thereby reducing the complexity of the amplified DNA sample.

·        Gel Electrophoresis and Visualization: The amplified DNA fragments are separated by gel electrophoresis based on their size, and the resulting banding pattern is visualized using techniques such as ethidium bromide staining or fluorescent labeling. The banding pattern represents the subset of DNA fragments that have been selectively amplified based on the presence of specific restriction sites and the selective PCR conditions.

 

Some modifications of the AFLP procedure include:

·        EcoTILLING AFLP: Incorporating mismatch-specific endonucleases in the AFLP procedure to identify single nucleotide polymorphisms (SNPs) and mutations.

·        EcoRAPD: Combining elements of AFLP and RAPD (Random Amplified Polymorphic DNA) to improve marker coverage and resolution.

·        High-throughput AFLP: Automation and robotics are utilized to increase the throughput of AFLP analysis, allowing for the simultaneous analysis of hundreds or thousands of samples.

·        Multiplex AFLP: Multiplexing AFLP reactions by using multiple selective primers in a single PCR reaction, allowing for the simultaneous analysis of multiple DNA fragments in a single experiment.

These modifications enhance the utility, resolution, throughput, and flexibility of the AFLP technique for various applications in genetics, genomics, breeding, and molecular biology.