Résumé
ObjectiveTo establish a polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) method for rapid distinguishing Periplocae Cortex from Acanthopanacis Cortex and Lycii Cortex, so as to avoid the influence of genetic confusion on drug safety. MethodThe DSS-tagged sequences of Periplocae Cortex were obtained from the Chloroplast Genome Information Resource (CGIR) and analyzed to find the enzymatic cleavage sites that were different from those of Acanthopanacis Cortex and Lycii Cortex. The specific enzymatic cleavage site, Cla I, of Periplocae Cortex was selected, on the basis of which the primers for PCR-RFLP were designed. Furthermore, the factors such as annealing temperature, number of cycles, Taq enzyme, PCR instruments, and enzymatic treatment time that may influence PCR-RFLP were studied. The established PCR-RFLP method was applied to the identification of Periplocae Cortex, Acanthopanacis Cortex, and Lycii Cortex samples produced in different regions. ResultThe PCR-RFLP at the annealing temperature of 59 ℃ and with 40 cycles showed clear bands of the samples. When the enzyme digestion time was 30 min. The reaction produced the target bands at about 140 bp and 290 bp for both Periplocae Cortex and its original plant and only a band at about 430 bp for Acanthopanacis Cortex, Lycii Cortex, and their original plants. The method can accurately distinguish Periplocae Cortex from its confounders Acanthopanacis Cortex and Lycii Cortex. ConclusionThe PCR-RFLP method for distinguishing Periplocae Cortex from Acanthopanacis Cortex and Lycii Cortex was established. It has high stability, sensitivity, and applicability, providing a reference for the quality control of Periplocae Cortex, Acanthopanacis Cortex, and Lycii Cortex.
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ObjectiveTo establish a rapid method for evaluating the heterozygosity of Murraya paniculata germplasm materials and provide as a foundation for developing germplasm breeding and innovation measures for M. paniculata. MethodSingle nucleotide polymorphisms (SNPs) were screened from the genome resequencing data of 65 plants of M. paniculata. A self-written script was used to transform 20 SNPs into restriction fragment length polymorphism (RFLP) markers. Polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) was employed to detect the 20 RFLP markers in 12 M. paniculata germplasm accessions, and the heterozygosity of M. paniculata germplasm accessions was calculated based on the number of enzyme-cutting bands at the 20 RFLP marker sites. Plink was used to calculate the whole genome heterozygosity of 12 M. paniculata germplasm accessions, and the results obtained with different methods were compared. ResultThere was no significant difference in the heterozygosity calculated by the PCR-RFLP method and the genome resequencing method. The PCR-RFLP and genome resequencing methods identified 8 and 9 germplasm accessions, respectively, with a heterozygosity level less than 30%. Seven germplasm accessions with heterozygosity less than 30.00% were calculated by both methods. ConclusionThe PCR-RFLP method established in this study for evaluating the heterozygosity of M. paniculata germplasm demonstrates the precision of 87.5% and the accuracy of 77.8%. This method serves as a reference for developing heterozygosity evaluation methods in other medicinal plant germplasm resources.
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ObjectiveIn recent years, with the sharp decline of wild resources in Arisaematis Rhizoma and Pinelliae Rhizoma and the immaturity of medicinal cultivation technology, their adulterants have appeared frequently in the market, and the main identifying characteristics have mostly disappeared in the circulation of medicinal materials. Therefore, there is an urgent need to establish a molecular identification method that can quickly and effectively identify the specificity of Arisaematis Rhizoma and Pinelliae Rhizoma. MethodAfter comparison of the rbcL sequences of Arisaematis Rhizoma,Pinelliae Rhizoma, and their adulterants, the specific enzyme cleavage sites Hae Ⅲ and Dra Ⅰ of Arisaematis Rhizoma and Pinelliae Rhizoma, respectively, were selected and identified by polymerase chain reaction-restriction fragment length polymorphism(PCR-RFLP). The main system conditions of PCR-RFLP reaction were established and optimized, and their durability and the ability to detect genuine, adulterants, and mixed counterfeits were investigated. ResultThe PCR-RFLP identification method of Arisaematis Rhizoma and Pinelliae Rhizoma was established. After specific primer amplification, Arisaematis Rhizoma and Pinelliae Rhizoma could be digested by Hae Ⅲ and Dra Ⅰ-restricted endonucleases respectively, at annealing temperature of 54 ℃, the number of cycles of 35, and the amount of DNA template of 3-30 ng, producing two fragments or small cut fragments with a single band between 100-250 bp, whereas the mixed counterfeits were not cleaved and both showed a band at 250 bp. The method is highly accurate in identifying adulterants and mixed counterfeits of Arisaematis Rhizoma or Pinelliae Rhizoma. ConclusionThe PCR-RFLP method developed in this study allows for the rapid identification of Arisaematis Rhizoma and Pinelliae Rhizoma.
Résumé
@#Objective To identify the genotype of Toxoplasma gondii isolated strains from a congenital teras(KS strain)and an HIV⁃Toxoplasma co⁃infected patient in Jiangsu Province. Methods T. gondii DNA of tachyzoites of a isolate from a congenital teras(KS strain)and blood DNA of an HIV⁃Toxoplasma co⁃infected patient in Jiangsu Province were extracted,and 11 loci were identified for the genotype by polymerase chain reaction restriction fragment length polymorphism(PCR⁃RFLP). Results The complete bands were obtained from the congenital teras(KS strain)and HIV⁃Toxoplasma co⁃infected patient in Jiangsu Province,and identified as T. gondii gene type I. Conclusion T. gondii gene type I may be the dominant genotype strain of T. gondii among the women who have the abnormal pregnant outcomes and HIV⁃Toxoplasma co⁃infected patients in Jiangsu Province.