ABSTRACT
Introduction: For the rapid and accurate genetic identification and authentication of living organisms, improved random amplified polymorphic DNA (RAPD) fragment based development of sequence-characterized amplified region (SCAR) markers is an important genetic technique. Objective: This study aimed to develop SCAR markers for perennial herb Eclipta prostrate (E. prostrate). Methods: Here the RAPD fragments by improved RAPD amplification with primers A11 and N-7 for E. prostrate were cloned into pGEX-T vector, and PCR amplification identified the positive clones. After the enzymatic digestion, they were sequenced with Sanger sequencing. Results: Two SCAR markers were developed, which were very specific to E. prostrate, not found in Penthorum chinense Pursh(P. chinense). The nucleotide sequence search by BLAST GenBank database showed that they are novel in E. prostrate, therefore they were deposited in Genbank with accession number KX671034, KX671035. The markers did not show any identity to other species. Conclusions: Thus, in this study two specific SCAR markers were developed for genetically distinguishing and identifying the plant species E. prostrate from herb P. chinense and others.
Introducción: Verificación genética del arbusto Eclipta prostrate (Asteraceae) (Para la identificación y verificación genética rápida y precisa de organismos vivos, el uso de fragmentos de ADN polimórfico amplificado aleatoriamente (RAPD) mejorado de marcadores de región amplificada caracterizada por secuencia (SCAR) es una técnica genética importante. Objetivo: Este estudio tuvo como objetivo desarrollar marcadores SCAR para la hierba perenne Eclipta postrate (E. postrate). Métodos: En este estudio os fragmentos RAPD mediante amplificación RAPD mejorada con los cebadores A11 y N-7 para E. postrate se clonaron en el vector pGEX-T, y la amplificación por PCR identificó los clones positivos. Después de la digestión enzimática, se realizó una secuenciación Sanger. Resultados: Se desarrollaron dos marcadores SCAR, muy específicos para E. postrate, que no se encuentran en Penthorum chinense Pursh (P. chinense). La búsqueda de las secuencias de nucleótidos con BLAST en GenBank mostró que son nuevos en E. postrate, por lo que fueron depositados en Genbank con los números de acceso: KX671034 y KX671035. Los marcadores no mostraron ninguna identidad a otras especies. Conclusiones: En este estudio se desarrollaron dos marcadores SCAR específicos para distinguir e identificar genéticamente la especie de planta E. postrate de la hierba P. chinense y otras.
ABSTRACT
The fruiting body pattern is an important agronomic trait of the edible fungus Auricularia auricula-judae, and an important breeding target. There are two types of fruiting body pattern: the cluster type and the chrysanthemum type. We identified the fruiting body pattern of 26 test strains, and then constructed two different near-isogenic pools. Then, we developed sequence characterized amplified region (SCAR) molecular markers associated with the fruiting body pattern based on sequence-related amplified polymorphism (SRAP) markers. Ten different bands (189–522 bp) were amplified using 153 pairs of SRAP primers. The SCAR marker “SCL-18” consisted of a single 522-bp band amplified from the cluster-type strains, but not the chrysanthemum strains. This SCAR marker was closely associated with the cluster-type fruiting body trait of A. auricula-judae. These results lay the foundation for further research to locate and clone genes controlling the fruiting body pattern of A. auricula-judae.
Subject(s)
Breeding , Chrysanthemum , Cicatrix , Clone Cells , Fruit , FungiABSTRACT
Background Analysis of genetic diversity is important for the authentication of a species. Litchi (Litchi chinensis Sonn.) is a subtropical evergreen tree. Recently, L. chinensis has been characterized by an improved random amplified polymorphic DNA (RAPD) and inter-simple sequence repeat (ISSR) analysis. The goal of this study was to develop sequence-characterized amplified region (SCAR) markers from the improved RAPD fragments for the genetic analysis of L. chinensis. Results The improved RAPD fragments from L. chinensis were cloned, sequenced and converted into stable SCAR markers. Sequencing of three cloned RAPD fragments revealed that the clone L7-16 consisted of 222 nucleotides (GenBank accession number KM235222), clone L9-6 consisted of 648 nucleotides (GenBank accession number KM235223), and clone L11-26 consisted of 369 nucleotides (GenBank accession number KM235224). Then, specific primers for SCAR markers L7-16, L9-6, and L11-26 were designed and synthesized. PCR amplification was performed using DNA templates from 24 different samples, including 6 samples of L. chinensis and other plants. The SCAR marker L9-6 was specific for all of the L. chinensis samples, the SCAR marker L11-26 specific for five L. chinensis samples, and the SCAR marker L7-16 only specific for the samples from Luzhou. Conclusions This study developed stable SCAR markers for the identification of L. chinensis by the cloning of the improved RAPD fragments. Combining RAPD and SCAR markers provides a simple and reliable tool for the genetic characterization of plant species.
Subject(s)
Cloning, Molecular , Random Amplified Polymorphic DNA Technique , Litchi/genetics , DNA/isolation & purification , Genetic Markers , Polymerase Chain Reaction , Sequence Analysis, DNA , Nucleic Acid Amplification TechniquesABSTRACT
Genetic diversity within a species is a common feature, which plays a vital role in its survival and adaptability, and is important for the identification and authentication of a species. Lonicera japonica is a traditionally used medicinal plant, which have been recently genetically characterized by an improved ran- dom amplified polymorphic DNA (RAPD) analysis. In this study, the molecular markers on the basis of these RAPD fragments have been developed to identify specific L. japonica variety. The DNAs were extracted from fresh young leaves of different samples of L. japonica collected from Shenzhen, Yichang, Leshan, Emei and Loudi, China. The DNA materials were amplified using improved RAPD PCR. Different RAPD bands were excised, cloned and developed for stable sequence-characterized amplified region (SCAR) markers with differ- ent species. Two SCAR markers, JYH3-3 and JYH4-3, have been successfully cloned from improved RAPD fragments. The SCAR marker JYH3-3 was found specific for all of the L. japonica samples collected from the different regions, and another marker JYH 4-3 was strictly specific to the Shenzhen sample from Guangdong province, which is geographically distant from Hubei, Sichuan and Hunan Provinces (source of other L. japonica samples). The marker JYH3-3 was found as specific molecular marker for the identification of L. japonica, while JYH4-3 was found as molecular marker strictly specific for the Shenzhen sample. The developed SCAR mark- ers might serve as more specific molecular markers for L. japonica variety authentication. The combination of improved RAPD analysis and SCAR marker development have resulted useful tools to study the genetic variety of any organism, which we have successfully applied here in L. japonica.
La diversidad genética dentro de una especie es una característica común, que juega un papel vital en su supervivencia y adaptabilidad, y es importante para la identificación y la autenticación de una especie. Lonicera japonica es una planta medicinal utilizada tradicionalmente, que han sido recientemente caracterizada genéticamente por amplificación aleatoria mejorada de ADN polimórfico (RAPD). En este estudio, los marcadores moleculares basados en estos fragmentos de RAPD se han desarrollado para identificar una variedad específica de L. japonica. Los ADN se extrajeron de las hojas jóvenes frescas de diferentes muestras de L. japonica recogidas de Shenzhen, Yichang, Leshan, Emei y Loudi, China. Los materiales de ADN fueron amplificados utilizando el RAPD PCR mejorado. Diferentes bandas RAPD fueron extraídas, clonadas y desarrolladas para las regiones amplificadas de secuencia conocida (SCAR) con marcado- res de diferentes especies. Dos marcadores SCAR, JYH3-3 y JYH4-3, se clonaron con éxito de los RAPD mejorados. El marcador SCAR JYH3-3 se encontró específico para todas las muestras de L. japonica recolectadas en las diferentes regiones, mientras que el otro marcador JYH4-3 era estrictamente específico para la muestra de Shenzhen de la provincia de Guangdong, que está geográficamente distante de Hubei, Sichuan y Provincias Hunan (fuente de otras muestras de L. japonica). Se encontró que JYH3-3 es un marcador molecular específico para la identificación de L. japonica, mientras que JYH4-3 se encontró como marcador molecular estrictamente específico para la muestra de Shenzhen. Los marcadores SCAR desarrollados podrían servir como marcadores moleculares más específicos para la autenticación de la variedad L. japonica. La combi- nación de RAPD mejorado y el desarrollo del marcador SCAR han dado como resultado herramientas útiles para el estudio de la variedad genética de cualquier organismo, que hemos aplicado con éxito en L. japonica.
Subject(s)
Cloning, Molecular/methods , Lonicera/genetics , China , Genetic Markers , Lonicera/classification , Polymerase Chain Reaction , Random Amplified Polymorphic DNA TechniqueABSTRACT
Sequence characterized amplified region (SCAR) markers are one of the most effective and accurate tools for microbial identification. In this study, we applied SCAR markers for the rapid and accurate detection of Phytophthora katsurae, the casual agent of chestnut ink disease in Korea. In this study, we developed seven SCAR markers specific to P. katsurae using random amplified polymorphic DNA (RAPD), and assessed the potential of the SCAR markers to serve as tools for identifying P. katsurae. Seven primer pairs (SOPC 1F/SOPC 1R, SOPC 1-1F/SOPC 1-1R, SOPC 3F/SOPC 3R, SOPC 4F/SOPC 4R, SOPC 4F/SOPC 4-1R, SOPD 9F/SOPD 9R, and SOPD 10F/SOPD 10R) from a sequence derived from RAPD fragments were designed for the analysis of the SCAR markers. To evaluate the specificity and sensitivity of the SCAR markers, the genomic DNA of P. katsurae was serially diluted 10-fold to final concentrations from 1 mg/mL to 1 pg/mL. The limit of detection using the SCAR markers ranged from 100 microg/mL to 100 ng/mL. To identify the limit for detecting P. katsurae zoospores, each suspension of zoospores was serially diluted 10-fold to final concentrations from 10 x 10(5) to 10 x 10(1) zoospores/mL, and then extracted. The limit of detection by SCAR markers was approximately 10 x 10(1) zoospores/mL. PCR detection with SCAR markers was specific for P. katsurae, and did not produce any P. katsurae-specific PCR amplicons from 16 other Phytophthora species used as controls. This study shows that SCAR markers are a useful tool for the rapid and effective detection of P. katsurae.
Subject(s)
Cicatrix , DNA , Ink , Korea , Limit of Detection , Phosphatidylcholines , Phytophthora , Polymerase Chain Reaction , Sensitivity and SpecificityABSTRACT
Objective To evaluate the indeterminate growth mutant of tomato derived by space mutagenesis to provide the basis for selecting and cultivating the molecular markers of tomato growth habit. Methods Fifty 10-mer randomly amplified polymorphic DNA(RAPD) primers were used to examine the polymorphism of M1 and 10-3-2. Their polymorphic fragments were cloned, and then were transferred to SCAR markers. Results Of all the 50 10-mer RAPD primers, 44 primers amplified polymerase chain reaction(PCR) products and 2 primers (S165 and S168) amplified stable reproducible polymorphic products. The molecular weight of the specific amplified products were 300 bp and 1 500 bp respectively, therefore they were named as TRS165300 and TRS1681500 temporarily. And TRS1681500 was transferred into stable sequence characterized amplified region(SCAR) marker and this marker could be a specific genetic marker of this indeterminate growth habit mutant. Conclusion Space mutation can produce mutants at DNA level from the loaded materials. The indeterminate growth mutant of tomato is derived by space mutagenesis which can provide a valuable material for studying the regulation and control of tomato growth habit.