Microsatellite DNA Analysis of the Communal Breeding System of the Smooth-billed Ani (Crotophaga ani) in Southwest Puerto Rico

Startek, Jennifer Melissa

05 1900

The communal breeding system of the smooth-billed ani (Crotophaga ani) was studied at two wildlife refuges in southwest Puerto Rico. Groups ranged in size from 2 to 9 adults, and communal clutches ranged in size from 11 to more than 25 eggs. Microsatellite DNA loci were isolated and used to examine the mating system and the extent of reproductive skew in individual groups. Loci were also screened in guira cuckoos (Guira guira) to examine the relationships suggested by Quinn et al. (1994). In the four focal smooth-billed ani groups, I found suggestions of monogamy, polygamy, and incidents of intraspecific brood parasitism. In all groups, incubated clutch size and microsatellite data indicate that subordinate females are gaining some reproductive success. At one nest, evidence suggested a decrease in the intensity of reproductive skew between successive nests. Although the data are limited, they suggest that alternative strategies to monogamy may be more prevalent than previously believed, and that reproductive skew may be affected by the availability of limiting resources within the breeding season. / Thesis / Master of Science (MS)

biology

microsatellite DNA analysis

communal breeding system

amooth-billed ani; Crotophaga ani

southwest Puerto Rice

Assessing Migration and Demographic Change in pre-Roman and Roman Period Southern Italy Using Whole-Mitochondrial DNA and Stable Isotope Analysis / The Biogeographic Origins of Iron Age Peucetians and Working-Class Romans From Southern Italy

Emery, Matthew

06 1900

Assessing population diversity in southern Italy has traditionally relied on archaeological and historic evidence. Although informative, these lines of evidence do not establish specific instances of within lifetime mobility, nor track population diversity over time. In order to investigate the population structure of ancient South Italy I sequenced the mitochondrial DNA (mtDNA) from 15 Iron Age (7th – 4th c. BCE) and 30 Roman period (1st – 4th c. BCE) individuals buried at Iron Age Botromagno and Roman period Vagnari, in southern Italy, and analyzed δ18O and 87Sr/86Sr values from a subset of the Vagnari skeletal assemblage. Phylogenetic analysis of 15 Iron Age mtDNAs together with 231 mtDNAs spanning European prehistory suggest that southern Italian Iapygians share close genetic affinities to Neolithic populations from eastern Europe and the Near East. Population pairwise analysis of Iron Age, Roman, and mtDNA datasets spanning the pan-Mediterranean region (n=357), indicate that Roman maternal genetic diversity is more similar to Neolithic and Bronze Age populations from central Europe and the eastern Mediterranean, respectively, than to Iron Age Italians. Genetic distance between population age categories imply moderate mtDNA turnover and constant population size during the Roman conquest of South Italy in the 3rd century BCE. In order to determine the local versus non-local demographic at Vagnari, I measured the 87Sr/86Sr and 18O/16O of composition of 43 molars, and the 87Sr/86Sr composition of an additional 13 molars, and constructed a preliminary 87Sr/86Sr variation map of the Italian peninsula using disparate 87Sr/86Sr datasets. The relationship between 87Sr/86Sr and previously published δ18O data suggest a relatively low proportion of migrants lived at Vagnari (7%). This research is the first to generate whole-mitochondrial DNA sequences from Iron Age and Roman period necropoleis, and demonstrates the ability to gain valuable information from the integration of aDNA, stable isotope, archaeological and historic evidence. / Thesis / Doctor of Philosophy (PhD) / With biochemical information obtained from teeth, this study examines the population structure and geographic origins in two archaeological communities located in southern Italy. Analysis of classical remains has traditionally been the subject of historical and archaeological inquiry. However, new applications evaluate these population changes with integrated stable isotope and ancient DNA techniques. Overall, the biochemical results suggest that the pre-Roman communities harbor deep maternal ancestry originating from eastern Europe and the eastern Mediterannean. These results, when compared to the genetic diversity of Roman and broader Mediterranean populations, indicate that the Romans share closer genetic similarity with ancient Stone and Bronze Age communites from Europe and the eastern Mediterranean, than with the pre-Roman community studied here. Furthermore, tooth chemistry results indicate a predominantly local population buried in the Roman period cemetery.

Strategies for low copy number DNA analysis

Raker, Virginia L.

01 October 2003

No description available.

Chemistry

Physical Sciences and Mathematics

Assessment of sequence variation within commonly encountered human alpha fibrinogen (HumFGA) alleles

Ban, Jeffrey David

01 October 2002

No description available.

DNA -- Analysis

Human genetics -- Variation

Nucleotide sequence

Chemistry

Physical Sciences and Mathematics

Validation of thirteen short tandem repeat loci for use in forensic casework

Badger, Charles Allen

01 January 2000

No description available.

DNA -- Analysis

Forensic genetics

Polymerase chain reaction

Life Sciences

Microbiology

Molecular Biology

Extraction and quantification of human deoxyribonucleic acid, and the amplification of human short tandem repeats and a sex identification marker from fly larvae found on decomposing tissue

Schiro, George J.

01 July 2001

No description available.

DNA -- Analysis

Forensic sciences

Polymerase chain reaction

Chemistry

Physical Sciences and Mathematics

Feasibility of crime scene pcr-based dna analysis using the mobile molecular laboratory

Glidewell, Debra E.

01 October 2001

No description available.

DNA -- Analysis

Forensic sciences

Polymerase chain reaction

Chemistry

Physical Sciences and Mathematics

Sensitive Forensic DNA Analysis : Application of Pyrosequencing and Real-time PCR Quantification

Andréasson, Hanna

January 2005

<p>The field of forensic genetics is growing fast and the development and optimisation of more sensitive, faster and more discriminating forensic DNA analysis methods is highly important. In this thesis, an evaluation of the use of novel DNA technologies and the development of specific applications for use in forensic casework investigations are presented.</p><p>In order to maximise the use of valuable limited DNA samples, a fast and user-friendly Real-time PCR quantification assay, of nuclear and mitochondrial DNA copies, was developed. The system is based on the 5’ exonuclease detection assay and was evaluated and successfully used for quantification of a number of different evidence material types commonly found on crime scenes. Furthermore, a system is described that allows both nuclear DNA quantification and sex determination in limited samples, based on intercalation of the SYBR Green dye to double stranded DNA. </p><p>To enable highly sensitive DNA analysis, Pyrosequencing of short stretches of mitochondrial DNA was developed. The system covers both control region and coding region variation, thus providing increased discrimination power for mitochondrial DNA analysis. Finally, due to the lack of optimal assays for quantification of mitochondrial DNA mixture, an alternative use of the Pyrosequencing system was developed. This assay allows precise ratio quantification of mitochondrial DNA in samples showing contribution from more than one individual.</p><p>In conclusion, the development of optimised forensic DNA analysis methods in this thesis provides several novel quantification assays and increased knowledge of typical DNA amounts in various forensic samples. The new, fast and sensitive mitochondrial DNA Pyrosequencing assay was developed and has the potential for increased discrimination power.</p>

Genetics

forensic

sensitive DNA analysis

DNA quantification

mtDNA

Real-time PCR

Pyrosequencing

Genetik

Clinical genetics

Klinisk genetik

Sensitive Forensic DNA Analysis : Application of Pyrosequencing and Real-time PCR Quantification

Andréasson, Hanna

January 2005

The field of forensic genetics is growing fast and the development and optimisation of more sensitive, faster and more discriminating forensic DNA analysis methods is highly important. In this thesis, an evaluation of the use of novel DNA technologies and the development of specific applications for use in forensic casework investigations are presented. In order to maximise the use of valuable limited DNA samples, a fast and user-friendly Real-time PCR quantification assay, of nuclear and mitochondrial DNA copies, was developed. The system is based on the 5’ exonuclease detection assay and was evaluated and successfully used for quantification of a number of different evidence material types commonly found on crime scenes. Furthermore, a system is described that allows both nuclear DNA quantification and sex determination in limited samples, based on intercalation of the SYBR Green dye to double stranded DNA. To enable highly sensitive DNA analysis, Pyrosequencing of short stretches of mitochondrial DNA was developed. The system covers both control region and coding region variation, thus providing increased discrimination power for mitochondrial DNA analysis. Finally, due to the lack of optimal assays for quantification of mitochondrial DNA mixture, an alternative use of the Pyrosequencing system was developed. This assay allows precise ratio quantification of mitochondrial DNA in samples showing contribution from more than one individual. In conclusion, the development of optimised forensic DNA analysis methods in this thesis provides several novel quantification assays and increased knowledge of typical DNA amounts in various forensic samples. The new, fast and sensitive mitochondrial DNA Pyrosequencing assay was developed and has the potential for increased discrimination power.

Genetics

forensic

sensitive DNA analysis

DNA quantification

mtDNA

Real-time PCR

Pyrosequencing

Genetik

Clinical genetics

Klinisk genetik

Effect of Netropsin on One-electron Oxidation of DNA

Roberts, Lezah Wilette

19 July 2005

One electron oxidation of DNA has been studied extensively over the years. When a charge is injected into a DNA duplex, it migrates through the DNA until it reaches a trap. Upon further reactions, damage occurs in this area and strand cleavage can occur. Many works have been performed to see what can affect this damage to DNA. Netropsin is a minor groove binder that can bind to tracts of four to five A:T base pairs. It has been used in the studies within to determine if it can protect DNA against oxidative damage, caused by one-electron oxidation, when it is bound within the minor groove of the DNA. By using a naphthacenedione derivative as a photosensitizer, several DNA duplexes containing netropsin binding sites as well as those without binding sites, were irradiated at 420 nm, analyzed, and visualized to determine its effect on oxidative damage. It has been determined netropsin creates a quenching sphere of an average of 5.8 * 108 Šwhether bound to the DNA or not. Herein we will show netropsin protects DNA against oxidative damage whether it is free in solutions or bound within the minor groove of a DNA duplex.

Photosensitizer

Charge transfer

Netropsin

TQ

DNA

Electron transfer

One-electron oxidation

DNA Analysis

Photosensitization, Biological

Oxidation, Physiological

Charge transfer in biology