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Author: Sarah Copeland
Publisher:
ISBN: 9781339543420
Category :
Languages : en
Pages :
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Book Description
Mitochondrial DNA (mtDNA) analysis is a useful method for analyzing samples with limited or degraded DNA due to the high copy number per cell. The most common approach uses Sanger sequencing and capillary electrophoresis to analyze the two hypervariable regions (HVI and HVII) within the non-coding portion of the mitochondrial genome. However, this approach does not allow for mixture analysis, misses potentially discriminating information in the coding region, and fails if the mtDNA is too badly degraded. Next-generation sequencing (NGS) is a high throughput, massively parallel technique that allows for clonal amplification of single DNA molecules making it ideal for analyzing mixtures and heteroplasmy in mtDNA. Also, the analysis of single molecules is a more sensitive approach which can be used for analysis of limited DNA or potentially degraded samples.This study had two aims. The first was to use the Roche 454 GS Jr to sequence the hypervariable regions of mtDNA from five comingled bone samples originating from the 20th century AD, five bone samples from the 15th century AD, and one bone sample from the 3rd century AD. The second aim was to use probe capture and the Illumina MiSeq NGS platform to sequence the whole mitochondrial genome of artificially degraded K562 DNA, naturally degraded DNA from a modern bone sample (~50 years old), and extremely degraded DNA from a 15th century AD bone and a 3rd century AD bone. A sub-aim was to compare a selection of small fragment removal methods following adaptor ligation to minimize sample loss at this step of library preparation. Prior linear array and degradation qPCR results indicated that comingled remains from the 20th century AD were highly degraded. HVI & HVII sequencing using the Roche 454 was attempted because, in spite of also using long amplicons, it is a more sensitive assay. 29 comingled remains samples from the 20th century AD were amplified for 454 analysis, but only three showed successful results when viewed by gel. Those samples were sequenced by 454 along with two samples that appeared to fail amplification from this same group. All five of the comingled remains were successfully sequenced except for the HVII region of one sample, however, all were mixtures. The five 15th century AD bone samples and 3rd century AD bone sample were highly degraded. Two of the 15th century AD samples failed sequencing entirely and another failed HVII. The 3rd century AD sample also failed HVII sequencing. There were mixtures among these samples as well, which points to the need for optimized methods of sample cleaning to remove more of the exogenous DNA present on bone samples. A probe capture technique followed by whole genome sequencing on the Illumina Miseq was used to analyze one highly degraded bone sample from each of the 15th and 3rd centuries AD along with a naturally degraded modern bone purchased from The Bone Room in Berkeley, CA, and artificially degraded commercial K562 DNA (human chronic myelogenous leukemia cell line). Probe capture doesn't utilize PCR amplification, therefore no specific sites are required to be intact for the assay to be successful, potentially making it a viable alternative for samples that are too degraded for PCR-based HVI and HVII analysis. The protocol calls for a small fragment removal step after adaptor ligation that could potentially remove precious sample along with the unligated adaptor, so a variety of small fragment removal methods were tested to limit the sample loss at this step of library preparation. All of the artificially degraded samples had 100% coverage regardless of the small fragment removal method and had an average percent aligned reads of 95.59% indicating high specificity for the probe capture. Three of the four naturally degraded modern bone samples from The Bone Room had 100% coverage whereas the last sample only had a 23 bp unsequenced portion in an area with low coverage for the other samples as well. The average percent aligned reads was 49.28% indicating a capture of a substantial amount of exogenous DNA by the probe capture technique. The highly degraded ancient bone samples failed sequencing after appearing to have successfully completed library preparation, once again potentially indicating a substantial amount of exogenous DNA. These two NGS assays were able to successfully sequence degraded bone samples. However, before they can be successful at sequencing highly degraded samples, a method of cleaning bones to remove exogenous DNA and a method of purifying extracted DNA to remove inhibitors must be optimized.
Author: Sarah Copeland
Publisher:
ISBN: 9781339543420
Category :
Languages : en
Pages :
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Book Description
Mitochondrial DNA (mtDNA) analysis is a useful method for analyzing samples with limited or degraded DNA due to the high copy number per cell. The most common approach uses Sanger sequencing and capillary electrophoresis to analyze the two hypervariable regions (HVI and HVII) within the non-coding portion of the mitochondrial genome. However, this approach does not allow for mixture analysis, misses potentially discriminating information in the coding region, and fails if the mtDNA is too badly degraded. Next-generation sequencing (NGS) is a high throughput, massively parallel technique that allows for clonal amplification of single DNA molecules making it ideal for analyzing mixtures and heteroplasmy in mtDNA. Also, the analysis of single molecules is a more sensitive approach which can be used for analysis of limited DNA or potentially degraded samples.This study had two aims. The first was to use the Roche 454 GS Jr to sequence the hypervariable regions of mtDNA from five comingled bone samples originating from the 20th century AD, five bone samples from the 15th century AD, and one bone sample from the 3rd century AD. The second aim was to use probe capture and the Illumina MiSeq NGS platform to sequence the whole mitochondrial genome of artificially degraded K562 DNA, naturally degraded DNA from a modern bone sample (~50 years old), and extremely degraded DNA from a 15th century AD bone and a 3rd century AD bone. A sub-aim was to compare a selection of small fragment removal methods following adaptor ligation to minimize sample loss at this step of library preparation. Prior linear array and degradation qPCR results indicated that comingled remains from the 20th century AD were highly degraded. HVI & HVII sequencing using the Roche 454 was attempted because, in spite of also using long amplicons, it is a more sensitive assay. 29 comingled remains samples from the 20th century AD were amplified for 454 analysis, but only three showed successful results when viewed by gel. Those samples were sequenced by 454 along with two samples that appeared to fail amplification from this same group. All five of the comingled remains were successfully sequenced except for the HVII region of one sample, however, all were mixtures. The five 15th century AD bone samples and 3rd century AD bone sample were highly degraded. Two of the 15th century AD samples failed sequencing entirely and another failed HVII. The 3rd century AD sample also failed HVII sequencing. There were mixtures among these samples as well, which points to the need for optimized methods of sample cleaning to remove more of the exogenous DNA present on bone samples. A probe capture technique followed by whole genome sequencing on the Illumina Miseq was used to analyze one highly degraded bone sample from each of the 15th and 3rd centuries AD along with a naturally degraded modern bone purchased from The Bone Room in Berkeley, CA, and artificially degraded commercial K562 DNA (human chronic myelogenous leukemia cell line). Probe capture doesn't utilize PCR amplification, therefore no specific sites are required to be intact for the assay to be successful, potentially making it a viable alternative for samples that are too degraded for PCR-based HVI and HVII analysis. The protocol calls for a small fragment removal step after adaptor ligation that could potentially remove precious sample along with the unligated adaptor, so a variety of small fragment removal methods were tested to limit the sample loss at this step of library preparation. All of the artificially degraded samples had 100% coverage regardless of the small fragment removal method and had an average percent aligned reads of 95.59% indicating high specificity for the probe capture. Three of the four naturally degraded modern bone samples from The Bone Room had 100% coverage whereas the last sample only had a 23 bp unsequenced portion in an area with low coverage for the other samples as well. The average percent aligned reads was 49.28% indicating a capture of a substantial amount of exogenous DNA by the probe capture technique. The highly degraded ancient bone samples failed sequencing after appearing to have successfully completed library preparation, once again potentially indicating a substantial amount of exogenous DNA. These two NGS assays were able to successfully sequence degraded bone samples. However, before they can be successful at sequencing highly degraded samples, a method of cleaning bones to remove exogenous DNA and a method of purifying extracted DNA to remove inhibitors must be optimized.
Author: Cassandra Taylor
Publisher:
ISBN: 9781369616446
Category :
Languages : en
Pages :
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Book Description
Forensic DNA samples are often highly degraded, making them unsuitable for traditional methods of DNA analysis, such as STR analysis, because target sequences and primer binding sites are not intact. Mitochondrial DNA (mtDNA) is useful for analyzing degraded DNA because of its high copy number; the high copy number makes successful typing more likely. Traditional methods of mtDNA analysis, including Sanger sequencing, are commonly used to only target only the HVI/HVII regions of the mitochondrial genome. These analysis methods miss discriminating information outside of the HV1/HVII, limiting the discriminatory power of mitochondrial DNA analysis. Probe capture is a novel technique that uses mtDNA sequence-specific probes to enrich and capture the entire mitochondrial genome. Analyzing the entire mitochondrial genome allows detection of discriminating information outside of the HVI/HVII regions and increases the discriminatory power of mitochondrial DNA analysis. Next Generation Sequencing, a massively parallel, clonal, and high-throughput technique, is an excellent tool for analyzing the entire mitochondrial genome. The purpose of this project was to test the efficiency of Dr. Calloway’s optimized probe capture assay on degraded DNA by analyzing the entire mitochondrial genome of highly degraded bone samples. Throughout the course of this project, three sets of bones samples, dating to 100, 2000, and 4000 years old respectively, were tested. Seven highly degraded bone samples recovered from a comingled tomb in Rijeka, Croatia and dating to approximately 100 years old were successfully sequenced with coverage of the mitochondrial genome ranging from approximately 52 to 98%. Haplogroups were determined for six of these samples based on the sequenced variants present in the entire mitochondrial genome. Additionally, six prehistoric bone samples dating to approximately 2000 years ago were sequenced with coverage of the mitochondrial genome ranging from 26 to 100%. The last set of samples, dating to 4000 years old, was recovered from a necropolis on the island of Kor?ula, Croatia. These six samples were successfully sequenced with coverage of the mitochondrial genome ranging from 26 to 100%.
Author: Daniela Cuenca
Publisher:
ISBN: 9781303538070
Category :
Languages : en
Pages :
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Book Description
DNA samples limited in quantity or degraded are often encountered in forensic casework. The success of analyzing these samples has increased with the application of mini STR and bi-allelic SNPs. Although there is a clear advantage in targeting nuclear DNA (that is, its high discrimination power), degraded and quantity limited samples often cannot be effectively analyzed through such methods. Instead, quality limited and degraded samples can be more effectively analyzed through the use of mitochondrial DNA (mtDNA) because of its high copy number. Yet, mtDNA's small size and highly conserved genome lower its discrimination potential. Next generation sequencing technology allows for the analysis of the entire mitochondrial genome, compensating for limitations of current mtDNA analysis methods. In 2012, a colleague developed a probe capture 454 next generation sequencing assay for target enrichment and deep sequencing of the whole mitochondrial genome. She included the liquid phase probe capture step into the assay design to enrich for mtDNA and to eliminate the need for amplification primers that target the sample DNA. As a result, the designed assay has the potential to analyze highly degraded samples while bypassing amplification complications. To further improve the assay's capability of processing degraded samples, I incorporated a mechanical shearing fragmentation method independent of sample quality into the assay. The goal of my project was to optimize and validate this assay for use on limited, mixed, and degraded samples.
Author: Angie Ambers
Publisher: Academic Press
ISBN: 0128163690
Category : Law
Languages : en
Pages : 628
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Book Description
Forensic Genetic Approaches for Identification of Human Skeletal Remains: Challenges, Best Practices, and Emerging Technologies provides best practices on processing bone samples for DNA testing. The book outlines forensic genetics tools that are available for the identification of skeletal remains in contemporary casework and historical/archaeological investigations. Although the book focuses primarily on the use of DNA for direct identification or kinship analyses, it also highlights complementary disciplines often used in concert with genetic data to make positive identifications, such as forensic anthropology, forensic odontology, and forensic art/sculpting. Unidentified human remains are often associated with tragic events, such as fires, terrorist attacks, natural disasters, war conflicts, genocide, airline crashes, homicide, and human rights violations under oppressive totalitarian regimes. In these situations, extensive damage to soft tissues often precludes the use of such biological samples in the identification process. In contrast, bone material is the most resilient, viable sample type for DNA testing. DNA recovered from bone often is degraded and in low quantities due to the effects of human decomposition, environmental exposure, and the passage of time. The complexities of bone microstructure and its rigid nature make skeletal remains one of the most challenging sample types for DNA testing. Provides best practices on processing bone samples for DNA testing Presents detailed coverage of proper facilities design for skeletal remains processing, selection of optimal skeletal elements for DNA recovery, specialized equipment needed, preparation and cleaning of bone samples for DNA extraction, and more Highlights complementary disciplines often used in concert with genetic data to make positive identifications, such as forensic anthropology, forensic odontology, and forensic art/sculpting
Author: Hirak Ranjan Dash
Publisher: Springer
ISBN: 9789811643170
Category : Science
Languages : en
Pages : 1206
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Book Description
This reference book comprehensively reviews the significance of DNA technology in forensic science. After presenting the theory, basic principles, tools and techniques that are used in forensic DNA typing, it summarizes various techniques, including autosomal STR, Y-STR, X-STR, mitochondrial DNA and NGS, used in solving both criminal as and civil cases, such as paternity disputes, identification of mutilated remains, and culprit identification in sexual assault and murder cases. It also provides an overview of DNA-based genetic diagnostics for various diseases, and discusses the role of DNA typing in drug reactions, as well as the application of non-human DNA profiling of animals and plants in forensic science investigations. Lastly, the book examines the role of internal quality control in maintaining the high quality of DNA profiling.
Author: Mary Wisner
Publisher:
ISBN: 9780438931091
Category :
Languages : en
Pages : 0
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Book Description
One of the persisting challenges in the forensic DNA analysis field is interpreting mixtures with nuclear genetic markers when the DNA is degraded or present in trace amounts. In these scenarios, utilizing mitochondrial DNA (mtDNA) analysis can be beneficial due to the higher copy number per cell compared to nuclear DNA. However, until the emergence of Next-Generation Sequencing (NGS) with its capability of clonal sequencing, analysis of mtDNA mixtures was very challenging. We used our custom mtgenome probe capture Next-Generation Sequencing (NGS) system to sequence complex mtDNA mixtures. We report here analysis of contrived mixtures of two contributors in 50:50 and 95:5 ratios as well as three-person mixtures ranging from equal proportions (33:33:33 ratio) to low amounts of the minor contributors, as in a 90:5:5 ratio. Additionally, we have applied this system to the analysis of mtDNA mixtures from forensically relevant samples. Furthermore, by utilizing the massively parallel, clonal aspects of NGS, we can bioinformatically separate and count the individual sequence reads and calculate the proportions of the contributors. For data analysis, we use both variant frequency-based software program GeneMarker®HTS and phylogenetic-based software program Mixemt to de-convolute the mixtures. Mixemt allows us to assign each sequence read to its originating contributors using phylogenetically informative polymorphisms. GeneMarker®HTS allows us to detect all mutations, including “private” mutations (non-phylogenetically informative polymorphisms) and assign them to individual contributors based on frequency. Using our custom probe capture NGS system and both GeneMarker®HTS and Mixemt software programs, we show that we can interpret complex mixtures of equal proportion contributors, trace amount contributors, and more than two contributors in contrived mixtures as well as challenging forensic specimens.
Author: Jaiprakash G. Shewale
Publisher: CRC Press
ISBN: 1466571268
Category : Law
Languages : en
Pages : 449
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Book Description
The field of forensic DNA analysis has grown immensely in the past two decades and genotyping of biological samples is now routinely performed in human identification (HID) laboratories. Application areas include paternity testing, forensic casework, family lineage studies, identification of human remains, and DNA databasing. Forensic DNA Analysis: Current Practices and Emerging Technologies explores the fundamental principles and the application of technologies for each aspect of forensic DNA analysis. The book begins by discussing the value of DNA evidence and how to properly recognize, document, collect, and store it. The remaining chapters examine: The most widely adopted methods and the best practices for DNA isolation from forensic biological samples and human remains Studies carried out on the use of both messenger RNA and small (micro) RNA profiling Real-time polymerase chain reaction (PCR) methods for quantification and assessment of human DNA prior to genotyping Capillary electrophoresis (CE) as a tool for forensic DNA analysis Next-generation short tandem repeat (STR) genotyping kits for forensic applications, the biological nature of STR loci, and Y-chromosome STRs (Y-STRs) Mitochondrial DNA (mtDNA) sequence analysis Single nucleotide polymorphisms (SNPs) and insertion/deletion polymorphisms (indels) in typing highly degraded DNA Deep-sequencing technologies The current state of integrated systems in forensic DNA analysis The book concludes by discussing various aspects of sample-processing training and the entities that provide such training programs. This volume is an essential resource for students, researchers, teaching faculties, and other professionals interested in human identification/forensic DNA analysis.
Author: Elena Pilli
Publisher: CRC Press
ISBN: 1000064581
Category : Law
Languages : en
Pages : 479
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Book Description
Forensic DNA Analysis: Technological Development and Innovative Applications provides a fascinating overview of new and innovative technologies and current applications in forensic genetics. Edited by two forensic experts with many years of forensic crime experience with the Italian police and with prestigious academic universities, the volume takes an interdisciplinary perspective, the volume presents an introduction to genome polymorphisms, discusses, forensic genetic markers, presents a variety of new methods and techniques in forensic genetics, and looks at a selection of new technological innovations and inventions now available from commercial vendors. The book is an important resource for scientists, researchers, and other experts in the field who will find it of interest for its exhaustive discussion of the most important technological innovations in forensic genetics. For those newer to the field, the volume will be an invaluable reference guide to the forensic world.
Author: Pankaj Shrivastava
Publisher: Springer Nature
ISBN: 9811566550
Category : Science
Languages : en
Pages : 673
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Book Description
The book explores the fundamental principles, advances in forensic techniques, and its application on forensic DNA analysis. The book is divided into three modules; the first module provides the historical prospect of forensic DNA typing and introduces fundamentals of forensic DNA typing, methodology, and technical advancements, application of STRs, and DNA databases for forensic DNA profile analysis. Module 2 examines the problems and challenges encountered in extracting DNA and generating DNA profiles. It provides information on the methods and the best practices for DNA isolation from forensic biological samples and human remains like ancient DNA, DNA typing of skeletal remains and disaster victim identification, the importance of DNA typing in human trafficking, and various problems associated with capillary electrophoresis. Module 3 emphasizes various technologies that are based on SNPs, STRs namely Y-STR, X-STR, mitochondrial DNA profiling in forensic science. Module 4 explores the application of non-human forensic DNA typing of domestic animals, wildlife forensics, plant DNA fingerprinting, and microbial forensics. The last module discusses new areas and alternative methods in forensic DNA typing, including Next-Generation Sequencing, and its utility in forensic science, oral microbes, and forensic DNA phenotyping. Given its scope, the book is a useful resource in the field of DNA fingerprinting for scientists, forensic experts, and students at the postgraduate level.
Author: Eline M. J. Schotsmans
Publisher: John Wiley & Sons
ISBN: 1118953320
Category : Medical
Languages : en
Pages : 546
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Book Description
A truly interdisciplinary approach to this core subject within Forensic Science Combines essential theory with practical crime scene work Includes case studies Applicable to all time periods so has relevance for conventional archaeology, prehistory and anthropology Combines points of view from both established practitioners and young researchers to ensure relevance
