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Genetic Variation Analysis of EMS-Induced Chili Pepper (Capsicum frutescens L.) Mutants Using SSR Markers Dwinianti, Edia Fitri; Mastuti, Retno; Arumingtyas, Estri Laras
Journal of Tropical Life Science Vol 9, No 3 (2019)
Publisher : Journal of Tropical Life Science

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Mutation induction with chemical mutagen ethyl methane sulfonate (EMS) capable of producing genetic variation in plants. The purpose of this research was to evaluate genetic variation of EMS-induced chili pepper mutants using SSR molecular marker. Various concentration of EMS (0.01%; 0.02%; 0.04%) were applied to chili pepper seeds of Genotypes 2, 7, and 11. The genomic DNA was isolated from mutants and control plants then used for PCR analysis using three SSR primers namely CA26, CA52 and CA96. The three SSR primers were able to detect genetic variation in the three genotypes of EMS-induced chili pepper mutants and control plants. A total of 18 alleles have been identified in all three SSR loci with PIC values ranging from 0.792 to 0.893. The three genotypes of chili pepper plants had different sensitivity to EMS mutation induction. Genotype 11 plants showed higher sensitivity to EMS treatment than genotypes 2 and 7 based on the amount of genomic changes. Dendrogram constructed based on genetic similarity values distributed the mutants and control plants into three main groups with similarity coefficients ranging from 0.34 to 0.90. Similar genotype either control plant or mutants, especially Genotypes 2 and 7 were group into similar group. However, for the Genotype 11 plants, large genome changes cause mutant plants G11K1, G11K2, G11K3 had a low genetic similarity to their control plants, so the mutants were separated in a different group from the control plant. Those indicate that EMS mutation induction capable of increasing genetic variation in chili pepper plants based on SSR molecular marker.

MICROSATELLITE MARKER FOR GENETIC VARIATION ANALYSIS IN LOCAL CHILI PEPPER (CAPSICUM FRUTESCENS L.) INDUCED BY ETHYL METHANE SULFONATE (EMS) Juliandari, Ria Reinnata; Mastuti, Retno; Arumningtyas, Estri Laras; Arumningtyas, Estri Laras
Journal of Tropical Life Science Vol 9, No 2 (2019)
Publisher : Journal of Tropical Life Science

Mutation using Ethyl Methane Sulfonate (EMS) is a simple and quick method to produce genetic variation in chili pepper. In this study, a total of 3 genotypes of local chili pepper (Capsicum frutescens L.), i.e. Genotype 2 (G2), Genotype 7 (G7), and Genotype 11 (G11) were induced by EMS with concentrations of 0% (K0), 0.01% (K1), 0.02% (K2), and 0.04% (K3). Genetic variation analysis in mutant was performed based on 3 microsatellite markers CA 19, CA 27, CA 62. Those molecular markers successfully detected the genetic variation in chili pepper mutant based on the number and size of microsatellite alleles variation. The 3 genotypes of chili pepper mutant produced a total of 15 alleles with the average Polymorphism Information Content (PIC) value of 0.82. Compared to the control plant, genetic variations in genome level were observed in local chili pepper. Furthermore, the treatment of EMS with concentration of 0.04% produced the most notable genetic variation in 3 genotypes of local chili pepper.

MICROSATELLITE MARKER FOR GENETIC VARIATION ANALYSIS IN LOCAL CHILI PEPPER (CAPSICUM FRUTESCENS L.) INDUCED BY ETHYL METHANE SULFONATE (EMS) Juliandari, Ria Reinnata; Mastuti, Retno; Arumningtyas, Estri Laras; Arumningtyas, Estri Laras
Journal of Tropical Life Science Vol 9, No 2 (2019)
Publisher : Journal of Tropical Life Science

Mutation using Ethyl Methane Sulfonate (EMS) is a simple and quick method to produce genetic variation in chili pepper. In this study, a total of 3 genotypes of local chili pepper (Capsicum frutescens L.), i.e. Genotype 2 (G2), Genotype 7 (G7), and Genotype 11 (G11) were induced by EMS with concentrations of 0% (K0), 0.01% (K1), 0.02% (K2), and 0.04% (K3). Genetic variation analysis in mutant was performed based on 3 microsatellite markers CA 19, CA 27, CA 62. Those molecular markers successfully detected the genetic variation in chili pepper mutant based on the number and size of microsatellite alleles variation. The 3 genotypes of chili pepper mutant produced a total of 15 alleles with the average Polymorphism Information Content (PIC) value of 0.82. Compared to the control plant, genetic variations in genome level were observed in local chili pepper. Furthermore, the treatment of EMS with concentration of 0.04% produced the most notable genetic variation in 3 genotypes of local chili pepper.

Genetic Diversity Study Among Six Genera of Amaranth Family Found in Malang Based on RAPD Marker Fatinah, Arik Arubil; Arumingtyas, Estri Laras; Mastuti, Retno
Journal of Tropical Life Science Vol 2, No 3 (2012)
Publisher : Journal of Tropical Life Science

Show Abstract | Download Original | Original Source | Check in Google Scholar

Genera of amaranth family tend to have phenotypic variation partly caused by environmental factor. Phenotypic variation was the result of interaction between genetic and environmental factors. One of molecular markers that is widely used for detecting genetic variation is RAPD. RAPD is used for polymorphism detections and is now possible for identifiying a large number of loci and ascribes unambiguous taxonomic and genetic relationships among different taxa. Members of amaranth family found in Indonesia are Amaranthus, Celosia, Aerva, Alternanthera, Achyranthes, Gomphrena, Salsola, and Iresine. Six genera of which (Amaranthus, Celosia, Aerva, Alternanthera, Achyranthes, and Gomphrena) were observed in this study. DNA was extracted from fresh young leaves using Doyle and Doyles method with modification in the extraction buffer used. RAPD analyses were carried out with 20 decamer primers from Kit A of Operon Technology. DNA was amplified using master cycler gradient Eppendorf with 35 cycles. RAPD products were separated on 1,5 % agarose gels and detected by staining with ethidium bromide. There were 374 bands generated in 18 random primers. The number of monomorphic bands, polymorphic bands, and the percentage of polymorphism were 21 bands, 353 bands, and 94,38 % respectively. The high number and percentage of polymorphic bands revealed genomic DNA variation. This variation is in accordance with phenotypic variation detected in this experiment. Therefore, it can be concluded that, based on DNA polymorphism detected by RAPD, Amaranth family can be classified into two sub families namely Amaranthoideae and Gomphrenoideae.

Conservation strategy of Anaphalis spp. in Bromo Tengger Semeru National Park, East Java Ade, Filza Yulina; Hakim, Luchman; Arumingtyas, Estri Laras; Azrianingsih, Rodiyati
Journal of Tropical Life Science Vol 11, No 1 (2021)
Publisher : Journal of Tropical Life Science

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.11594/tls.11.01.10

The objective of the paper were to identify factors related to conservation strategy of Anaphalis in BTSNP. This study found internal factor related to strength includes the existence of species and value of Anaphalis spp., while the weaknesses include increase of habitat degradation and disturbance caused by tourism activities. The opportunities for conservation includes support of policy in biodiversity conservation and increase of ecotourism movement, while the threats aspect include less control of land uses changes and increase of mass tourism. The SWOT analyses recommends some significant strategy which are derived from combination of enhancing strength to optimizing opportunities, reducing weaknesses and optimizing opportunities, Enhancing strength to reduce threats and managing weaknesses to manage risk. Â

Constructing Phenetic and Phylogenetic Relationship Using Clad'97 Rahardi, Brian; Arumningtyas, Estri Laras; Mahmudi, Wayan Firdaus
Journal of Tropical Life Science Vol 2, No 1 (2012)
Publisher : Journal of Tropical Life Science

Show Abstract | Download Original | Original Source | Check in Google Scholar

Relationship construction has a very important position in classification process for arranging taxonomy of organism. In the world of taxonomy, there are two the most familiar relationship diagram, cladogram and phenogram. In every construction activity, a researcher is always facing character state data from taxa that becomes components of the diagram. Calculation that is used for construction is often incorporate iterative or repetitive process that needs time and precision. The existence of calculating tools that produces both text and graphical output are hopefully decrease time and error during construction. Basic algorithm that is used in calculation is for phylogenetic construction by Kluge and Farris in 1969,for phenetic construction using cluster analysis with slight modification. Basic common algorithm used in the software is by calculating two dimensional arrays of taxa x characters matrix and creating distance or similarity matrix. In more detail the program creates one dimensional array of taxonomical object and each object has some other one dimensional array containing data commonly exist in a taxonomic unit. The relationship between one object and theother are regulated by an object that created by class representing taxonomic tree. Cladogram is constructed by calculating nearest distance between each taxon (OTU) and creating one HTU in every bifurcation. Phenogram is constructed agglomeratively by searching highest similarity between taxon then grouped into new taxon. Program calculates numerical data after we do character scoring. Final result for each user may be different; this may be due to decision by user during construction process. This paper hopefully attracts people from systematic computation to develop further into open source software and multi-platform feature.

Genetic variation of Dacrycarpus imbricatus in Bromo Tengger Semeru National Park, East Java Based on trnL (UAA) Intron Region Rahadiantoro, Apriyono; Hakim, Luchman; Arumingtyas, Estri Laras
Journal of Tropical Life Science Vol 3, No 2 (2013)
Publisher : Journal of Tropical Life Science

Show Abstract | Download Original | Original Source | Check in Google Scholar

The conservation of Jamuju Dacrycarpus imbricatus (Blume) de Laub. in Java Island has been considered important. One of the the limitation of such program is related to the viability data on the genetic diversity of species target. The aim of study was to determine genetic variation of D. imbricatus in Bromo Tengger Semeru Park, East Java based on trnL (UAA) intron region. DNA sample was collected from several D. imbricatus seedling population in Bromo Tengger Semeru National Park (BTSNP) in East Java. DNA was isolated and amplified using PCR. Genetic variation was estimated using trnL (UAA) intron sequences. This study confirm that D. imbricatus in Bromo Tengger Semeru has low genetic diversity. Based on the phylogenetic tree, D. imbricatus population from Bromo Tengger Semeru Park is closely related to D. imbricatus from Sabah-Malaysia and Hainan-China with 100 % similarity value. These data implies that population and habitat management of D. imbricatus in Bromo Tengger Semeru should be designed to enhance the population survival in the future.

Constructing Phenetic and Phylogenetic Relationship Using Clad'97 Brian Rahardi; Estri Laras Arumningtyas; Wayan Firdaus Mahmudi
Journal of Tropical Life Science Vol. 2 No. 1 (2012)
Publisher : Journal of Tropical Life Science

Show Abstract | Download Original | Original Source | Check in Google Scholar

Relationship construction has a very important position in classification process for arranging taxonomy of organism. In the world of taxonomy, there are two the most familiar relationship diagram, cladogram and phenogram. In every construction activity, a researcher is always facing character state data from taxa that becomes components of the diagram. Calculation that is used for construction is often incorporate iterative or repetitive process that needs time and precision. The existence of calculating tools that produces both text and graphical output are hopefully decrease time and error during construction. Basic algorithm that is used in calculation is for phylogenetic construction by Kluge and Farris in 1969,for phenetic construction using cluster analysis with slight modification. Basic common algorithm used in the software is by calculating two dimensional arrays of taxa x characters matrix and creating distance or similarity matrix. In more detail the program creates one dimensional array of taxonomical object and each object has some other one dimensional array containing data commonly exist in a taxonomic unit. The relationship between one object and theother are regulated by an object that created by class representing taxonomic tree. Cladogram is constructed by calculating nearest distance between each taxon (OTU) and creating one HTU in every bifurcation. Phenogram is constructed agglomeratively by searching highest similarity between taxon then grouped into new taxon. Program calculates numerical data after we do character scoring. Final result for each user may be different; this may be due to decision by user during construction process. This paper hopefully attracts people from systematic computation to develop further into open source software and multi-platform feature.

Genetic Diversity Study Among Six Genera of Amaranth Family Found in Malang Based on RAPD Marker Arik Arubil Fatinah; Estri Laras Arumingtyas; Retno Mastuti
Journal of Tropical Life Science Vol. 2 No. 3 (2012)
Publisher : Journal of Tropical Life Science

Show Abstract | Download Original | Original Source | Check in Google Scholar

Genera of amaranth family tend to have phenotypic variation partly caused by environmental factor. Phenotypic variation was the result of interaction between genetic and environmental factors. One of molecular markers that is widely used for detecting genetic variation is RAPD. RAPD is used for polymorphism detections and is now possible for identifiying a large number of loci and ascribes unambiguous taxonomic and genetic relationships among different taxa. Members of amaranth family found in Indonesia are Amaranthus, Celosia, Aerva, Alternanthera, Achyranthes, Gomphrena, Salsola, and Iresine. Six genera of which (Amaranthus, Celosia, Aerva, Alternanthera, Achyranthes, and Gomphrena) were observed in this study. DNA was extracted from fresh young leaves using Doyle and Doyles method with modification in the extraction buffer used. RAPD analyses were carried out with 20 decamer primers from Kit A of Operon Technology. DNA was amplified using master cycler gradient Eppendorf with 35 cycles. RAPD products were separated on 1,5 % agarose gels and detected by staining with ethidium bromide. There were 374 bands generated in 18 random primers. The number of monomorphic bands, polymorphic bands, and the percentage of polymorphism were 21 bands, 353 bands, and 94,38 % respectively. The high number and percentage of polymorphic bands revealed genomic DNA variation. This variation is in accordance with phenotypic variation detected in this experiment. Therefore, it can be concluded that, based on DNA polymorphism detected by RAPD, Amaranth family can be classified into two sub families namely Amaranthoideae and Gomphrenoideae.

Genetic variation of Dacrycarpus imbricatus in Bromo Tengger Semeru National Park, East Java Based on trnL (UAA) Intron Region Apriyono Rahadiantoro; Luchman Hakim; Estri Laras Arumingtyas
Journal of Tropical Life Science Vol. 3 No. 2 (2013)
Publisher : Journal of Tropical Life Science

Show Abstract | Download Original | Original Source | Check in Google Scholar

The conservation of Jamuju Dacrycarpus imbricatus (Blume) de Laub. in Java Island has been considered important. One of the the limitation of such program is related to the viability data on the genetic diversity of species target. The aim of study was to determine genetic variation of D. imbricatus in Bromo Tengger Semeru Park, East Java based on trnL (UAA) intron region. DNA sample was collected from several D. imbricatus seedling population in Bromo Tengger Semeru National Park (BTSNP) in East Java. DNA was isolated and amplified using PCR. Genetic variation was estimated using trnL (UAA) intron sequences. This study confirm that D. imbricatus in Bromo Tengger Semeru has low genetic diversity. Based on the phylogenetic tree, D. imbricatus population from Bromo Tengger Semeru Park is closely related to D. imbricatus from Sabah-Malaysia and Hainan-China with 100 % similarity value. These data implies that population and habitat management of D. imbricatus in Bromo Tengger Semeru should be designed to enhance the population survival in the future.

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