Your search keyword '"Luise Ørsted Brandt"' showing total 4 results

1. Archaeological Wool Textiles: A Window into Ancient Sheep Genetics?

Author

Morten E. Allentoft and Luise Ørsted Brandt

Subjects

Wool, Textile production, Window (computing), Biology, Archaeology

Published

2019

2. DNA from keratinous tissue. Part I: Hair and nail

Author

Andrew Wilson, Eske Willerslev, M. Thomas P. Gilbert, Luise Ørsted Brandt, Maia E. Olsen, Desmond J. Tobin, Camilla Friis Bengtsson, and Mads F. Bertelsen

Subjects

Mitochondrial DNA, Context (language use), Biology, DNA, Mitochondrial, Polymerase Chain Reaction, Specimen Handling, law.invention, chemistry.chemical_compound, law, Keratin, medicine, Animals, Humans, Alleles, Polymerase chain reaction, Cell Nucleus, chemistry.chemical_classification, integumentary system, DNA, General Medicine, Anatomy, Nuclear DNA, medicine.anatomical_structure, Ancient DNA, Nails, Biochemistry, chemistry, Nail (anatomy), Hair, Developmental Biology

Abstract

Keratinous tissues such as nail, hair, horn, scales and feather have been used as a source of DNA for over 20 years. Particular benefits of such tissues include the ease with which they can be sampled, the relative stability of DNA in such tissues once sampled, and, in the context of ancient genetic analyses, the fact that sampling generally causes minimal visual damage to valuable specimens. Even when freshly sampled, however, the DNA quantity and quality in the fully keratinized parts of such tissues is extremely poor in comparison to other tissues such as blood and muscle - although little systematic research has been undertaken to characterize how such degradation may relate to sample source. In this review paper we present the current understanding of the quality and limitations of DNA in two key keratinous tissues, nail and hair. The findings indicate that although some fragments of nuclear and mitochondrial DNA appear to be present in almost all hair and nail samples, the quality of DNA, both in quantity and length of amplifiable DNA fragments, vary considerably not just by species, but by individual, and even within individual between hair types.

Published

2012

3. Species Identification of Archaeological Skin Objects from Danish Bogs: Comparison between Mass Spectrometry-Based Peptide Sequencing and Microscopy-Based Methods

Author

Ulla Mannering, Luise Ørsted Brandt, Mathilde Sarret, Enrico Cappellini, Christian D. Kelstrup, Anne Lisbeth Schmidt, and Jesper V. Olsen

Subjects

Proteomics, Science, Denmark, Social Sciences, Biology, Mass spectrometry, Research and Analysis Methods, Biochemistry, Mass Spectrometry, Analytical Chemistry, Microscopy, Animals, Electron Microscopy, Skin, Multidisciplinary, Geography, Shotgun sequencing, Organisms, Electrospray Ionization Mass Spectrometry, Biology and Life Sciences, Paleontology, Light Microscopy, Prehistoric Animals, Archaeology, Chemistry, Ancient DNA, Proteome, Physical Sciences, Peptide sequencing, Earth Sciences, Medicine, Identification (biology), Scanning Electron Microscopy, Peptides, Research Article

Abstract

Denmark has an extraordinarily large and well-preserved collection of archaeological skin garments found in peat bogs, dated to approximately 920 BC - AD 775. These objects provide not only the possibility to study prehistoric skin costume and technologies, but also to investigate the animal species used for the production of skin garments. Until recently, species identification of archaeological skin was primarily performed by light and scanning electron microscopy or the analysis of ancient DNA. However, the efficacy of these methods can be limited due to the harsh, mostly acidic environment of peat bogs leading to morphological and molecular degradation within the samples. We compared species assignment results of twelve archaeological skin samples from Danish bogs using Mass Spectrometry (MS)-based peptide sequencing, against results obtained using light and scanning electron microscopy. While it was difficult to obtain reliable results using microscopy, MS enabled the identification of several species-diagnostic peptides, mostly from collagen and keratins, allowing confident species discrimination even among taxonomically close organisms, such as sheep and goat. Unlike previous MS-based methods, mostly relying on peptide fingerprinting, the shotgun sequencing approach we describe aims to identify the complete extracted ancient proteome, without preselected specific targets. As an example, we report the identification, in one of the samples, of two peptides uniquely assigned to bovine foetal haemoglobin, indicating the production of skin from a calf slaughtered within the first months of its life. We conclude that MS-based peptide sequencing is a reliable method for species identification of samples from bogs. The mass spectrometry proteomics data were deposited in the ProteomeXchange Consortium with the dataset identifier PXD001029.

Published

2014

4. Characterising the potential of sheep wool for ancient DNA analyses

Author

Luise Ørsted Brandt, Lena Diana Tranekjer, Karin Margarita Frei, Maj Ringgaard, Margarita Gleba, Ulla Mannering, Eske Willerslev, and M. Thomas P. Gilbert

Subjects

Archeology, Mitochondrial DNA, Sheep, Ancient DNA, Mitochondria, Nuclear, Sheep, Textile, Wool, Ancient DNA, business.industry, Textile, Wool, Zoology, Mordant, Biology, biology.organism_classification, law.invention, Nuclear DNA, Biotechnology, Mitochondria, law, Anthropology, Nuclear, Dyeing, business, Ovis, Polymerase chain reaction

Abstract

The use of wool derived from sheep (Ovis aries) hair shafts is widespread in ancient and historic textiles. Given that hair can represent a valuable source of ancient DNA, wool may represent a valuable genetic archive for studies on the domestication of the sheep. However, both the quality and content of DNA in hair shafts are known to vary, and it is possible that common treatments of wool such as dyeing may negatively impact the DNA. Using quantitative real-time polymerase chain reaction (PCR), we demonstrate that in general, short fragments of both mitochondrial and single-copy nuclear DNA can be PCR-amplified from wool derived from a variety of breeds, regardless of the body location or natural pigmentation. Furthermore, although DNA can be PCR-amplified from wool dyed with one of four common plant dyes (tansy, woad, madder, weld), the use of mordants such as alum or iron leads to considerable DNA degradation. Lastly, we demonstrate that mtDNA at least can be PCR-amplified, cloned and sequenced from a range of archaeological and historic Danish, Flemmish and Greenlandic wool textile samples. In summary, our data suggest that wool offers a promising source for future ancient mitochondrial DNA studies.

Published

2011