Abstract
BackgroundMultiplex PCR has been successfully applied in many areas since it was first reported in 1988; however, it suffers from poor universality.ResultsA novel method called Universal Multiplex PCR (UM-PCR) was created, which simultaneously amplifies multiple target fragments from genomic DNA. The method has two steps. First, the universal adapter-F and universal adapter-R are connected to the forward primers and the reverse primers, respectively. Hairpin structures and cross dimers of five pairs of adapter-primers are detected. Second, UM-PCR amplification is implemented using a novel PCR procedure termed “Two Rounds Mode” (three and 28–32 cycles). The first round (the first three cycles) is named the “One by One Annealing Round”. The second round (28–32 cycles) combines annealing with extension. In the first two cycles of the first round, primers only amplify the specific templates; there are no templates for the universal adapters. The templates of universal adapters begin to be synthesized from the second cycle of the first round, and universal adapters and primers commence full amplification from the third cycle of the first round.ConclusionsUM-PCR greatly improves the universality of multiplex PCR. UM-PCR could rapidly detect the genetic purity of maize seeds. In addition, it could be applied in other areas, such as analysis of polymorphisms, quantitative assays and identifications of species.
Highlights
Multiplex polymerase chain reaction (PCR) has been successfully applied in many areas since it was first reported in 1988; it suffers from poor universality
The results suggested that Zhengdan 958 and Xianyu 335 could be identified based on the length of PCR products, with no cross-reaction
The bands amplified by “Two Rounds Mode” with U-primers were slightly larger (36 bp) than the bands amplified by routine PCR with simple sequence repeat (SSR) primers
Summary
Multiplex PCR has been successfully applied in many areas since it was first reported in 1988; it suffers from poor universality. As one of the three major grain crops worldwide, is important for feed and industrial raw materials. It occupies an important position in world agricultural production. The genetic purity of maize seeds has received much attention. Low seed purity reduces the biomass, thereby affecting the final yield. There are many methods for testing the genetic purity of seeds, such as morphological identification, identification by physical and chemical methods, identification by physiological and biochemical methods, and identification by molecular biology and cell biology [1-15]. Protein and isozyme electrophoresis are widely used in seed genetic purity testing.
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