Authenticated DNA from ancient wood remains

BACKGROUND: The reconstruction of biological processes and human activities during the last glacial cycle relies mainly on data from biological remains. Highly abundant tissues, such as wood, are candidates for a genetic analysis of past populations. While well-authenticated DNA has now been recovered from various fossil remains, the final 'proof' is still missing for wood, despite some promising studies. SCOPE: The goal of this study was to determine if ancient wood can be analysed routinely in studies of archaeology and palaeogenetics. An experiment was designed which included blind testing, independent replicates, extensive contamination controls and rigorous statistical tests. Ten samples of ancient wood from major European forest tree genera were analysed with plastid DNA markers. CONCLUSIONS: Authentic DNA was retrieved from wood samples up to 1,000 years of age. A new tool for real-time vegetation history and archaeology is ready to use.     

方兴未艾的古代DNA的研究

保留在古代生物遗骸中的遗传物质DNA是一种重要的遗传资源。古代DNA的研究对于了解包括人类在内的各种生物的起源、进化和迁徙有重要意义。古代DNA的研究有其自身的特点,并且已经取得一系列重要成就。本文综述古代DNA研究的历史、方法和进展。 Abstract：DNA present in ancient samples can be recovered,amplified and analysed.It opens a new window for genetic analysis in many different disciplines,such as anthropology,archaeology,human population genetics,animal and plant evolutionary taxonomy and forensic science.In general,ancient DNA is rare in quantity,damaged in quality.To ensure the reproducibility and reliability of the results,great cares should be taken,such as various measurements against contamination and phylogenetic analysis of ancient DNA sequences.In this paper we review recovery,amplification and analysis of ancient DNA,also discuss the guidelines to ensure the authenticity of ancient DNA and the recent advances in ancient DNA study.     

Paleoethnobotany: Modern Research Connecting Ancient Plants and Ancient Peoples

Paleoethnobotany is a growing subdiscipline of archaeology that utilizes information from numerous other disciplines to show the relationships between ancient plants and ancient peoples. The two primary disciplines that underlie paleoethnobotanical research are archaeology and botany. As such, the results of ongoing botanical research on taphonomic processes, genetic identification of ancient plant types, pollen analysis, phytoliths analysis, and seed identification directly affect the strength of paleoethnobotanical models of past human behavior. Preserved seeds form a significant portion of the archaeobotanical record. They represent not only the environment that was present when they were deposited but also a connection to the activity and culture of ancient people. Using the type of archaeobotanical remains and the archeological context of the remains, paleoethnobotanists study a diverse range of topics. These topics include, but are not limited to, the use of plants in ancient cultures, the development and rise of agriculture, and the relationship between agriculture and settlement patterns.     

A cost‐effective high‐throughput metabarcoding approach powerful enough to genotype ~44 000 year‐old rodent remains from Northern Africa

We present a cost‐effective metabarcoding approach, aMPlex Torrent, which relies on an improved multiplex PCR adapted to highly degraded DNA, combining barcoding and next‐generation sequencing to simultaneously analyse many heterogeneous samples. We demonstrate the strength of these improvements by generating a phylochronology through the genotyping of ancient rodent remains from a Moroccan cave whose stratigraphy covers the last 120 000 years. Rodents are important for epidemiology, agronomy and ecological investigations and can act as bioindicators for human‐ and/or climate‐induced environmental changes. Efficient and reliable genotyping of ancient rodent remains has the potential to deliver valuable phylogenetic and paleoecological information. The analysis of multiple ancient skeletal remains of very small size with poor DNA preservation, however, requires a sensitive high‐throughput method to generate sufficient data. We show this approach to be particularly adapted at accessing this otherwise difficult taxonomic and genetic resource. As a highly scalable, lower cost and less labour‐intensive alternative to targeted sequence capture approaches, we propose the aMPlex Torrent strategy to be a useful tool for the genetic analysis of multiple degraded samples in studies involving ecology, archaeology, conservation and evolutionary biology.     

古DNA实时荧光定量PCR实验中标准品的制备

实时荧光定量PCR技术通过对PCR每一循环扩增产物的实时检测,可对模板的精确拷贝数进行绝对定量,从而用于古DNA实验中提取和扩增条件的比较和优化.本研究采用异硫氰酸胍碱裂解-SiO2吸附的方法,从采自黑龙江省的晚更新世斑鬣狗化石材料中提取得到了斑鬣狗线粒体基因组古DNA.经常规PCR扩增后,将纯化的扩增产物克隆到微生物体内使其大量复制,再用M13通用引物扩增出含少量外源DNA的古DNA目标片段,从而建立了适用于古DNA荧光定量PCR扩增的标准品的制备方法.经检测分析,运用该方法制备的标准品性质稳定,能够准确地指示反应体系中较为精确的古DNA模板拷贝数,从而反映古DNA的提取和扩增效率,用于比较并优化古DNA提取和扩增条件.     

Evolutionary anthropology and genes: Investigating the genetics of human evolution from excavated skeletal remains

The development of molecular tools for the extraction, analysis and interpretation of DNA from the remains of ancient organisms (paleogenetics) has revolutionised a range of disciplines as diverse as the fields of human evolution, bioarchaeology, epidemiology, microbiology, taxonomy and population genetics. The paper draws attention to some of the challenges associated with the extraction and interpretation of ancient DNA from archaeological material, and then reviews the influence of paleogenetics on the field of human evolution. It discusses the main contributions of molecular studies to reconstructing the evolutionary and phylogenetic relationships between extinct hominins (human ancestors) and anatomically modern humans. It also explores the evidence for evolutionary changes in the genetic structure of anatomically modern humans in recent millennia. This breadth of research has led to discoveries that would never have been possible using traditional approaches to human evolution.     

Analysis of ancient bone DNA: techniques and applications.

The analysis of DNA from ancient bone has numerous applications in archaeology and molecular evolution. Significant amounts of genetic information can be recovered from ancient bone: mitochondrial DNA sequences of 800 base pairs have been amplified from a 750-year-old human femur by using the polymerase chain reaction. DNA recovery varies considerably between bone samples and is not dependent on the age of the specimen. We present the results of a study on a small number of bones from a mediaeval and a 17th-century cemetery in Abingdon showing the relation between gross preservation, microscopic preservation and DNA recovery.     

Nuclear gene sequences from a late pleistocene sloth coprolite

The determination of nuclear DNA sequences from ancient remains would open many novel opportunities such as the resolution of phylogenies, the sexing of hominid and animal remains, and the characterization of genes involved in phenotypic traits. However, to date, single-copy nuclear DNA sequences from fossils have been determined only from bones and teeth of woolly mammoths preserved in the permafrost. Since the best preserved ancient nucleic acids tend to stem from cold environments, this has led to the assumption that nuclear DNA would be retrievable only from frozen remains. We have previously shown that Pleistocene coprolites stemming from the extinct Shasta sloth (Nothrotheriops shastensis, Megatheriidae) contain mitochondrial (mt) DNA from the animal that produced them as well as chloroplast (cp) DNA from the ingested plants. Recent attempts to resolve the phylogeny of two families of extinct sloths by using strictly mitochondrial DNA has been inconclusive. We have prepared DNA extracts from a ground sloth coprolite from Gypsum Cave, Nevada, and quantitated the number of mtDNA copies for three different fragment lengths by using real-time PCR. We amplified one multicopy and three single-copy nuclear gene fragments and used the concatenated sequence to resolve the phylogeny. These results show that ancient single-copy nuclear DNA can be recovered from warm, arid climates. Thus, nuclear DNA preservation is not restricted to cold climates.     

How ancient DNA may help in understanding the origin and spread of agriculture

The origin and spread of agriculture have been central questions in archaeology for the last 75 years and are increasingly being addressed by a multidisciplinary approach involving biologists, ecologists, geographers and anthropologists as well as archaeologists. Molecular genetics has the potential to make an important contribution, especially by enabling the number of times that a crop or animal was domesticated to be determined. Molecular genetics can also assign approximate dates to domestication events, identify the wild progenitor of a domesticate, and provide new forms of evidence relevant to agricultural spread. With wheat, molecular genetical studies of modern plants have suggested that einkorn was domesticated just once but that emmer might have been domesticated more than once. Ancient DNA studies of animal remains have benefited from progress made with equivalent analyses of human bones, and with plant material there have been clear demonstrations of DNA preservation in desiccated seeds. Charred remains have also been shown to contain ancient DNA but this finding is unexpected in view of the high temperatures to which these seeds have supposedly been exposed. Ancient DNA studies of wheat remains have been used in taxonomic identification and in assessment of the possible bread-making quality of the wheat grown at an Early Bronze Age site in Greece.     

Using ancient DNA and coalescent-based methods to infer extinction

DNA sequences extracted from preserved remains can add considerable resolution to inference of past population dynamics. For example, coalescent-based methods have been used to correlate declines in some arctic megafauna populations with habitat fragmentation during the last ice age. These methods, however, often fail to detect population declines preceding extinction, most likely owing to a combination of sparse sampling, uninformative genetic markers, and models that cannot account for the increasingly structured nature of populations as habitats decline. As ancient DNA research expands to include full-genome analyses, these data will provide greater resolution of the genomic consequences of environmental change and the genetic signatures of extinction.     

Ancient plant DNA in archaeobotany

Plant diaspores, tissues and wood are preserved in natural and anthropogenic sediments. Also, over the past centuries, plants have been collected in herbaria. These plant remains carry macroscopic and molecular information, making them a rich source for reconstructing past plant use, agriculture, diet or vegetation—they are thus proxies for past economies, ecology, migrations or trade. This article focuses on the application of ancient DNA analyses from plants excavated at Holocene archaeological sites. A short methodological section is added to illustrate possibilities and limitations of ancient DNA research in plants.     

Palaeomicrobiology: current issues and perspectives

Palaeomicrobiology is an emerging field that is devoted to the detection, identification and characterization of microorganisms in ancient remains. Data indicate that host-associated microbial DNA can survive for almost 20,000 years, and environmental bacterial DNA preserved in permafrost samples has been dated to 400,000-600,000 years. In addition to frozen and mummified soft tissues, bone and dental pulp can also be used to search for microbial pathogens. Various techniques, including microscopy and immunodetection, can be used in palaeomicrobiology, but most data have been obtained using PCR-based molecular techniques. Infections caused by bacteria, viruses and parasites have all been diagnosed using palaeomicrobiological techniques. Additionally, molecular typing of ancient pathogens could help to reconstruct the epidemiology of past epidemics and could feed into current models of emerging infections, therefore contributing to the development of appropriate preventative measures.     

夏家店等古人骨DNA的提取、扩增及序列分析

古DNA从距今 2 0 0 0～ 50 0 0年的古代人骨 (编号为 :M89,ⅢM11,ⅢM12和AM4 )中提取出来 ,利用聚合酶链式反应分别对线粒体DNA中MTND4 基因中 112 10～ 11414(2 0 5bp)以及RegionV中 8196～ 83 16(12 1bP)进行了扩增 ,并被测序 .实验结果表明古代人骨中仍存在有大量的遗传信息 ,通过提取、扩增可以得到真实可靠的序列 .对序列进行比较发现 112 4 8,112 4 9,112 83及 112 93为易发生突变的位点 .结果经同源性分析后发现 ,ⅢM11和ⅢM12有很高同源性 ,而M89和AM4与ⅢM11和ⅢM12的同源性却比较低 .这对人类学、考古学及分子进化的研究有重要的辅助作用 .     

试论动物考古中的小哺乳动物研究

小哺乳动物种类及其数量,在哺乳动物中占据大多数。它们是自然界生态链中非常重要的、不可缺少的环节。它们体质进化较快,大部分种类居住区域选择性强,种群活动范围比较小。所以研究小哺乳动物种群面貌及其生态特征,可以帮助我们判断古遗址相对时代,解析历史时期的生态演变。小哺乳动物的生态指示性,能够帮助我们准确复原和研究古遗址环境背景。它们的分布状况及很多生态规律,在帮助我们研究古遗址环境卫生及古居民住房条件等方面有独特作用。小哺乳动物种群变化与人类经济生产的互动性,以及它们与人类的伴栖关系、人类对小哺乳动物资源的开发和利用等,均是动物考古工作中应该重视和积极开展研究的内容。开展小哺乳动物研究,需要必要的工作计划、专业技术和实验设备。我国旧石器时代的小哺乳动物考古已取得丰硕成果,新石器时代及其以后的小哺乳动物考古尚有待加强。小哺乳动物研究工作的拓展,将会有力促进动物考古学进展,促使动物考古在考古学实践中发挥出更大作用。     

Tracing genetic change over time using nuclear SNPs in ancient and modern cattle

Ancient DNA has the potential of adding the dimension of time to genetic studies. With a suitable sample set it should be possible to follow genetic changes over time as they occur. To date, only a limited number of ancient DNA studies that cover a large time span have been published, and all of these studies have used mitochondrial DNA. Here, we explore SNP typing as a way to access ancient coding nuclear genes. By targeting fragments of minimal size, we typed three polymorphic sites in 111 ancient cattle remains spanning some 4000 years. We showed that there has been a decrease in heterozygosity over time, especially since the late Middle Ages. We conclude that SNPs can be used to generate a time series for nuclear markers from ancient material, and thereby to study selection on genes over time.     

The ancient DNA revolution: the latest era in unearthing New Zealand’s faunal history

In the 25 years since the first DNA sequences were obtained from the extinct moa, ancient DNA analyses have significantly advanced our understanding of New Zealand's unique fauna. Here, we review how DNA extracted from ancient faunal remains has provided new insights into the evolutionary histories and phylogenetic relationships of New Zealand animals, and the impacts of human activities upon their populations. Moreover, we review how ancient DNA has played a key role in improving our ability to taxonomically identify fragmentary animal remains, determine biological function within extinct species, reconstruct past faunas and communities based on DNA preserved in sediments, resolve aspects of the ecology of extinct animals and characterising prehistoric parasite faunas. As ancient DNA analyses continue to become increasingly applied, and sequencing technologies continue to improve, the next 25 years promises to provide many more exciting new insights and discoveries about New Zealand's unique fauna.     

Partial uracil–DNA–glycosylase treatment for screening of ancient DNA

The challenge of sequencing ancient DNA has led to the development of specialized laboratory protocols that have focused on reducing contamination and maximizing the number of molecules that are extracted from ancient remains. Despite the fact that success in ancient DNA studies is typically obtained by screening many samples to identify a promising subset, ancient DNA protocols have not, in general, focused on reducing the time required to screen samples. We present an adaptation of a popular ancient library preparation method that makes screening more efficient. First, the DNA extract is treated using a protocol that causes characteristic ancient DNA damage to be restricted to the terminal nucleotides, while nearly eliminating it in the interior of the DNA molecules, allowing a single library to be used both to test for ancient DNA authenticity and to carry out population genetic analysis. Second, the DNA molecules are ligated to a unique pair of barcodes, which eliminates undetected cross-contamination from this step onwards. Third, the barcoded library molecules include incomplete adapters of short length that can increase the specificity of hybridization-based genomic target enrichment. The adapters are completed just before sequencing, so the same DNA library can be used in multiple experiments, and the sequences distinguished. We demonstrate this protocol on 60 ancient human samples.     

Ancient Chinese literature reveals pathways of eggplant domestication

Background and Aims

Changes in key traits occurring during the processes of plant domestication have long been subjects of debate. Only in the case of genetic analysis or with extensive plant remains can specific sets of changes be documented. Historical details of the plant domestication processes are rare and other evidence of morphological change can be difficult to obtain, especially for those vegetables that lack a substantial body of archaeological data. Botanical records chronicled in the ancient literature of established ancient civilizations, such as that of China, are invaluable resources for the study and understanding of the process of plant domestication. Here, the considerable body of ancient Chinese literature is used to explore the domestication process that has occurred with the eggplant (Solanum melongena), an important vegetable in Old World.

Methods

Information about eggplant domestication in the ancient Chinese literature was retrieved using a variety of methods. The information obtained was then sorted by taxon, examined and taxonomic identifications verified.

Key Results

It was found that the earliest record of the eggplant documented in ancient Chinese literature was in a work from 59 bc. As far as is known, this is the earliest reliable and accurately dated record of eggplant in cultivation. The analysis reveals that the process of domestication of the eggplant in China involved three principal aspects of fruit quality: size, shape and taste. These traits were actively and gradually selected; fruit size changed from small to large, taste changed from not palatable to what was termed at the time sweetish, and that over time, a wider variety of fruit shapes was cultivated.

Conclusions

The results indicate that, in addition to data gleaned from archaeology and genetics, evidence as to changes in key traits occurring during the process of plant domestication and selective forces responsible for these changes can be traced through the ancient literature in some civilizations.Key words: Solanum melongena, ancient Chinese literature, domestication process, domestication traits, selective forces     

中国东北第四纪晚期哺乳动物化石样品的古DNA损伤分析

二代测序技术的进步推动了古DNA研究的发展,古DNA研究在人类起源、动物演化等领域已经做出突出贡献。如何针对特定地点的古DNA样品特征,有效提取挖掘其中蕴含的古生物遗传信息,是发挥古代生物样品在诸多研究领域重要作用的前提。本研究将DNA损伤的两个主要指标(末端碱基替换率、平均片段长度)与样品的埋藏时间、所属地质时期、样品材料类型和建库方法相联系,分析不同因素对古DNA损伤的影响。结果表明:中国东北古脊椎动物样品中的古DNA分子的末端碱基替换率与埋藏点的含水量、样品埋藏时间呈正相关;不同地质时期的样品之间古DNA末端碱基替换率有显著差异;不同样品材料类型对于古DNA的末端碱基替换率未见明显影响;样品古DNA的平均片段长度与以上所研究的因素均无明显关系。研究结果为探明中国东北古脊椎动物样品的古DNA特征提供了分子依据,为有效选取不同地区的古脊椎动物样品及样品发掘后的合理保存提供了借鉴和参考。     

The ethnolinguistic identity of the domesticators of Asian rice

Linguistic palaeontology permits the identification of two language families whose linguistic ancestors pose the likeliest candidates for the original domesticators of rice, viz. Hmong-Mien and Austroasiatic. In the 2009 model, the ancient Hmong-Mien was identified as the primary domesticators of Asian rice, and the ancient Austroasiatics as the secondary domesticators. Recent rice genetic research leads to the modification of this model for rice domestication, but falls short of identifying the original locus of rice domestication. At the same time, the precise whereabouts of the Austroasiatic homeland remains disputed. Linguistic evidence unrelated to rice agriculture has been adduced to support a southern homeland for Austroasiatic somewhere within the Bay of Bengal littoral. The implications of new rice genetic research are discussed, the linguistic palaeontological evidence is reassessed, and an enduring problem with the archaeology of rice agriculture is highlighted.