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1. Isolated Grauer's gorilla populations differ in diet and gut microbiome (advance online)

Author

Michel, A., Minocher, R., https://orcid.org/0000-0002-4614-1859, Niehoff, P., Li, Y., Nota, K., Gadhvi, M., Su, J., Iyer, N., Porter, A., Ngobobo‐As‐Ibungu, U., Binyinyi, E., Nishuli Pekeyake, R., Parducci, L., Caillaud, D., and Guschanski, K.

Abstract

The animal gut microbiome has been implicated in a number of key biological pro-cesses, ranging from digestion to behaviour, and has also been suggested to facilitate local adaptation. Yet studies in wild animals rarely compare multiple populations that differ ecologically, which is the level at which local adaptation may occur. Further, few studies simultaneously characterize diet and gut microbiome from the same sample, despite their probable interdependence. Here, we investigate the interplay between diet and gut microbiome in three geographically isolated populations of the critically endangered Grauer's gorilla (Gorilla beringei graueri), which we show to be genetically differentiated. We find population- and social group-specific dietary and gut microbial profiles and covariation between diet and gut microbiome, despite the presence of core microbial taxa. There was no detectable effect of age, and only marginal effects of sex and genetic relatedness on the microbiome. Diet differed considerably across populations, with the high-altitude population consuming a lower diversity of plants compared to low-altitude populations, consistent with plant availability constraining dietary choices. The observed pattern of covariation between diet and gut microbi-ome is probably a result of long-term social and environmental factors. Our study sug-gests that the gut microbiome is sufficiently plastic to support flexible food selection and hence contribute to local adaptation.

Published
2022

2. PaleoEcoGen: Unlocking the power of ancient environmental DNA to understand past ecological trends

Author

Monchamp, Marie-Eve, Armbrecht, L., Capo, E., Coolen, M.J.L., Cordier, T., Domaizon, I., Epp, L.S., Giguet-Covex, C., Gregory-Eaves, I., Herzschuh, U., Parducci, L., Stoof-Leichsenring, K.r., and Williams, J.W., Department of Biology, McGill University, Montreal, Canada, Australian Centre for Ancient DNA, School of biological Sciences, The University of Adelaide, Australia, Department of Aquatic Sciences and Assessment, Swedish University of Agricultural Sciences, Uppsala, Sweden, Environnements, Dynamiques et Territoires de la Montagne (EDYTEM), and Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS)

Subjects
[SDE]Environmental Sciences, past changes, climate, ancient DNA, environmental DNA, ComputingMilieux_MISCELLANEOUS
Abstract

International audience

Published
2021

8. Patterns of nucleotide diversity at photoperiod related genes in Norway spruce [Picea abies (L.) Karst.]

Author

Heuertz, Myriam [0000-0002-6322-3645], Lascoux, Martin [0000-0003-1699-9042], Källman, T., De Mita, S., Larsson, H., Gyllenstrand, N., Heuertz, Myriam, Parducci, L., Suyama, Y., Lagercrantz, U., Lascoux, Martin, Heuertz, Myriam [0000-0002-6322-3645], Lascoux, Martin [0000-0003-1699-9042], Källman, T., De Mita, S., Larsson, H., Gyllenstrand, N., Heuertz, Myriam, Parducci, L., Suyama, Y., Lagercrantz, U., and Lascoux, Martin

Abstract

The ability of plants to track seasonal changes is largely dependent on genes assigned to the photoperiod pathway, and variation in those genes is thereby important for adaptation to local day length conditions. Extensive physiological data in several temperate conifer species suggest that populations are adapted to local light conditions, but data on the genes underlying this adaptation are more limited. Here we present nucleotide diversity data from 19 genes putatively involved in photoperiodic response in Norway spruce (Picea abies). Based on similarity to model plants the genes were grouped into three categories according to their presumed position in the photoperiod pathway photoreceptors, circadian clock genes, and downstream targets. An HKA (Hudson, Kreitman and Aquade) test showed a significant excess of diversity at photoreceptor genes, but no departure from neutrality at circadian genes and downstream targets. Departures from neutrality were also tested with Tajima's D and Fay and Wu's H statistics under three demographic scenarios the standard neutral model, a population expansion model, and a more complex population split model. Only one gene, the circadian clock gene PaPRR3 with a highly positive Tajima's D value, deviates significantly from all tested demographic scenarios. As the PaPRR3 gene harbours multiple non-synonymous variants it appears as an excellent candidate gene for control of photoperiod response in Norway spruce. © 2014 Källman et al.

Published
2014

9. Molecular- and pollen-based vegetation analysis in lake sediments from central Scandinavia

Author

Parducci, L., Matetovici, I., Fontana, S.L., Bennett, K.D., Suyama, Y., Haile, J., Kjaer, K.H., Larsen, N.K., Drouzas, A.D., Willerslev, E., Parducci, L., Matetovici, I., Fontana, S.L., Bennett, K.D., Suyama, Y., Haile, J., Kjaer, K.H., Larsen, N.K., Drouzas, A.D., and Willerslev, E.

Abstract

Plant and animal biodiversity can be studied by obtaining DNA directly from the environment. This new approach in combination with the use of generic barcoding primers (metabarcoding) has been suggested as complementary or alternative to traditional biodiversity monitoring in ancient soil sediments. However, the extent to which metabarcoding truly reflects plant composition remains unclear, as does its power to identify species with no pollen or macrofossil evidence. Here, we compared pollen-based and metabarcoding approaches to explore the Holocene plant composition around two lakes in central Scandinavia. At one site, we also compared barcoding results with those obtained in earlier studies with species-specific primers. The pollen analyses revealed a larger number of taxa (46), of which the majority (78%) was not identified by metabarcoding. The metabarcoding identified 14 taxa (MTUs), but allowed identification to a lower taxonomical level. The combined analyses identified 52 taxa. The barcoding primers may favour amplification of certain taxa, as they did not detect taxa previously identified with species-specific primers. Taphonomy and selectiveness of the primers are likely the major factors influencing these results. We conclude that metabarcoding from lake sediments provides a complementary, but not an alternative, tool to pollen analysis for investigating past flora. In the absence of other fossil evidence, metabarcoding gives a local and important signal from the vegetation, but the resulting assemblages show limited capacity to detect all taxa, regardless of their abundance around the lake. We suggest that metabarcoding is followed by pollen analysis and the use of species-specific primers to provide the most comprehensive signal from the environment.

Published
2013

10. Glacial survival of boreal trees in northern Scandinavia

Author

Parducci, L., Jorgensen, T., Tollefsrud, M.M., Elverland, E., Alm, T., Fontana, S.L., Bennett, K.D., Haile, J., Matetovici, I., Suyama, Y., Edwards, M.E., Andersen, K., Rasmussen, M., Boessenkool, S., Coissac, E., Brochmann, C., Taberlet, P., Houmark-Nielsen, M., Larsen, N.K., Orlando, L., Gilbert, M.T.P., Kjaer, K.H., Alsos, I.G., Willerslev, E., Parducci, L., Jorgensen, T., Tollefsrud, M.M., Elverland, E., Alm, T., Fontana, S.L., Bennett, K.D., Haile, J., Matetovici, I., Suyama, Y., Edwards, M.E., Andersen, K., Rasmussen, M., Boessenkool, S., Coissac, E., Brochmann, C., Taberlet, P., Houmark-Nielsen, M., Larsen, N.K., Orlando, L., Gilbert, M.T.P., Kjaer, K.H., Alsos, I.G., and Willerslev, E.

Abstract

It is commonly believed that trees were absent in Scandinavia during the last glaciation and first recolonized the Scandinavian Peninsula with the retreat of its ice sheet some 9000 years ago. Here, we show the presence of a rare mitochondrial DNA haplotype of spruce that appears unique to Scandinavia and with its highest frequency to the west-an area believed to sustain ice-free refugia during most of the last ice age. We further show the survival of DNA from this haplotype in lake sediments and pollen of Trondelag in central Norway dating back similar to 10,300 years and chloroplast DNA of pine and spruce in lake sediments adjacent to the ice-free Andoya refugium in northwestern Norway as early as similar to 22,000 and 17,700 years ago, respectively. Our findings imply that conifer trees survived in ice-free refugia of Scandinavia during the last glaciation, challenging current views on survival and spread of trees as a response to climate changes.

Published
2012

11. Ancient plant DNA : review and prospects

Author

Gugerli, F, Parducci, L, Petit, R J, Gugerli, F, Parducci, L, and Petit, R J

Abstract

Ancient DNA has received much attention since the mid-1980s, when the first sequence of an extinct animal species was recovered from a museum specimen. Since then, the majority of ancient DNA studies have focused predominantly on animal species, while studies in plant palaeogenetics have been rather limited, with the notable exception of cultivated species found in archaeological sites. Here, we outline the recent developments in the analysis of plant ancient DNA. We emphasize the trend from species identification to population-level investigation and highlight the potential and the difficulties in this field, related to DNA preservation and to risks of contamination. Further efforts towards the analysis of ancient DNA from the abundant store of fossil plant remains should provide new research opportunities in palaeoecology and phylogeography. In particular, intraspecific variation should be considered not only in cultivated plants but also in wild taxa if palaeogenetics is to become a fully emancipated field of plant research.

Published
2005
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12. Ancient DNA from pollen : a genetic record of population history in Scots pine

Author

Parducci, L, Suyama, Y, Lascoux, M, Bennett, K D, Parducci, L, Suyama, Y, Lascoux, M, and Bennett, K D

Abstract

Assessments of plant population dynamics in space and time have depended on dated records of fossil pollen synthesized on a subcontinental scale. Genetic analyses of extant populations have revealed spatial relationships that are indicative of past spatial dynamics, but lack an explicit timescale. Synthesis of these data requires genetic analyses from abundant dated fossil material, and this has hitherto been lacking. Fossil pollen is the most abundant material with which to fill this data gap. Here we report genetic analyses of fossil pollen retrieved from Holtjarnen postglacial lake sediment in Sweden and show that plastid DNA is recoverable from Scots Pine and Norway spruce pollen grains that are 100 and 10 000 years old. By sequencing clones from two short plastid PCR products and by using multiple controls we show that the ancient sequences were endogenous to the fossil grains. Comparison of ancient sequences and those obtained from an extant population of Scots pine establishes the first genetic link between extant and fossil samples in this species, providing genetic continuity through time. The finding of one common haplotype present in modern, 100-year old and 10 000-year old samples suggests that it may have persisted near Holtjarnen throughout the postglacial period. This retrieval of ancient DNA from pollen has major implications for plant palaeoecology in conifer species by allowing direct estimates of population dynamics in space and time.

Published
2005
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13. Ancient DNA in pollen - Genetic analysis in two Holocene pine populations from Sweden

Author

Parducci, L., Suyama, Y., Lascoux, M., Bennett, K.D., Parducci, L., Suyama, Y., Lascoux, M., and Bennett, K.D.

Abstract

Recent advances in molecular biology offer now excellent tools to obtain DNA information from well-preserved fossil material and the discovery that ancient DNA can be amplified by polymerase chain reaction (PCR) has added a direct temporal dimension to many evolutionary studies. By using a method we recently developed for the analysis of DNA in fossil pollen, we examined the chloroplast DNA sequence variation among fossil pollen grains of Scots pine (Pinus sylvestris L.) incorporated in a Holocene sediment core collected in central Sweden. DNA sequences data obtained from fossil (100 and 10,000 cal. BP) and modern samples revealed a number of different haplotypes and their relationships were visualised by a statistical parsimony network analysis. Results from this study establish a first genetic link between modern and fossil DNA samples and provide unique genetic information useful for understanding the origin and the evolution of Scots pine ancient populations.

Published
2004

14. Ancient DNA in pollen:insigths in the recent history of plant populations

Author

Parducci, L. and Parducci, L.

Abstract

The potential of ancient DNA research is far reaching in evolutionary studies and offers many opportunities, several of which have been little explored in plant palaeoecology. Recent genetic studies of fossil pollen of Scots pine retrieved from postglacial lake sediments in Sweden showed that chloroplast DNA can be recovered and used from remains as old as 10 ka. By sequencing and comparing short, yet very informative, chloroplast DNA regions from fossil and modern specimens we can now read the evolutionary message inscribed in this genome and learn how specific regions have evolved after the last glaciation. Can this approach be used also to study the evolutionary changes occurred both in time and space in plant populations during the last glaciation?

Published
2004

15. Species identification in seven small millet species using polymerase chain reaction-restriction fragment length polymorphism of trn S-psb C gene region

Author

Parani, M, Rajesh, K, Lakshmi, M, Parducci, L, Szmidt, A E, Parida, A, Parani, M, Rajesh, K, Lakshmi, M, Parducci, L, Szmidt, A E, and Parida, A

Abstract

The chloroplast trnS-psbC gene regions from total genomic DNA of 119 accessions from seven small millet species were amplified by polymerase chain reaction (PCR) and digested with eight restriction enzymes individually as well as in combinations of two enzymes to

Published
2001

16. Taxonomic position and origin of the endemic Sicilian fir Abies nebrodensis (Lojac.) Mattei based on allozyme analysis

Author

Parducci, L, Szmidt, A E, Drouzas, M M Ribeiro A D, Parducci, L, Szmidt, A E, and Drouzas, M M Ribeiro A D

Abstract

**Laboratory of Molecular Population Genetics, Department of Biology, Graduate School of Science, Kyushu University, Fukuoka 81 2-858 1, Japan ***Laboratory of Forest Genetics and Tree Breeding, PO Box. 238, Aristotle University of Thessaloniki, GR-54006 Thessaloniki

Published
2001

17. Genetic variation at chloroplast microsatellites (cpSSRs) in Abies nebrodensis (Lojac.) Mattei and three neighboring Abies species

Author

Parducci, L, Szmidt, A E, Madaghiele, A, Anzidei, M, Vendramin, G G, Parducci, L, Szmidt, A E, Madaghiele, A, Anzidei, M, and Vendramin, G G

Abstract

Abies nebrodensis (Lojac.) Mattei (Sicilian fir) is an endangered species represented by only one population of 29 adult individuals occurring in a limited area of the Madonie Range in northern Sicily (Italy). Taxonomic boundaries between this taxon and the neighboring Abies species are not clear. In this study, we used six chloroplast simple-sequence repeats (cpSSRs) to investigate the population genetic structure and the distribution of chloroplast haplotypic variation in A. nebrodensis and three of the neighboring Abies species: Abies alba (Mill.), Abies numidica (De Lann) and Abies cephalonica (Loud.). Our aims were to quantify the level of cpDNA differentiation within the Abies populations and to shed light on the history of A. nebrodensis. Diversity levels based on the haplotype frequency at six cpSSRs were high, especially in A. alba and A. cephalonica. In all, we found 122 haplotypes among the 169 individuals analyzed, and the four species were distinguished from each other by their haplotype composition. The majority of the haplotypes (76%) were detected only once, but in A. nebrodensis seven individuals (41% of the sample population) shared the same haplotype. Moreover, the seven A. nebrodensis individuals with an identical haplotype showed a tendency to be geographically grouped within the population’s limited range. The analysis of molecular variance (AMOVA) showed a significant difference in the level of apportionment of gene diversity between the species A. alba and A. cephalonica (F-ST=0.191 and 0.012, respectively). AMOVA analysis conducted over all populations from the four species showed that 19% of the total cpSSR variation was attributable to differences among species, 6% was due to differences among populations within species, and 74% to differences within populations. The high percentage of unique haplotypes identified confirms the power of cpSSR haplotype analysis for identifying individual trees in individual Abies populations. Our results in

Published
2001

21. PCR-RFLP analysis of cpDNA in the genus Abies

Author

Parducci, L, Szmidt, A E, Parducci, L, and Szmidt, A E

Abstract

We used PCR-RFLP analysis of the chloroplast DNA of the genus Abies (family Pinaceae), to determine if the method could be employed to detect inter-specific variation in this genus and to study how the variation was distributed in different regions of the genome. Ten different chloroplast DNA regions, consisting of coding and non-coding DNA sequences, were amplified with specific primers in ten different Abies taxa. The amplification products were digested with several restriction enzymes. The results showed that the chloroplast genome is highly variable in mast of the investigated taxa and contains multiple variable regions that appear to be distributed throughout the whole genome. Species-diagnostic markers were found for four of the ten investigated species. Unexpectedly, intra-specific variation was also detected in four species. It is likely that further studies, including larger sample sizes and/or more powerful methods for the detection of chloroplast DNA variation. will reveal additional variation for this genus.

Published
1999

24. Genetic variation of Abies alba in Italy

Author

Parducci, L, Szmidt, A, Villani, F, Wang, X, Cherubini, Marcello, Parducci, L, Szmidt, A, Villani, F, Wang, X, and Cherubini, Marcello

Abstract

PARDUCCI, L., SZMIDT, A. E., VILLANI, F., WANG, X.-R. and CHERUBINI, Abies alba in Italy. - Hereditas 125: 11 - 18. Lund, Sweden. ISSN 001 8-0661. Received February 28, 1996. Accepted August 26, 1996. Italy represents the southern limit of Abies alba (Mill.) (

Published
1996

27. Taxonomic position and origin of the endemic Sicilian fir Abies nebrodensis (Lojac.) Mattei based on Allozyme analysis

Author

Parducci, L., Szmidt, A. E., Maria Margarida Ribeiro, and Drouzas, A. D.

Subjects
Abies nebrodensis, allozymes, population genetics, sicilian fir, taxonomy, Population genetics, Allozymes, Sicilian fir, Taxonomy
Abstract

The final publication is availabe at/O documento está disponível em http://www.tuzvo.sk/files/fg/volumes/2001/FG08-2_119-127.pdf Submitted by Maria Eduarda Pereira Rodrigues (erodrigues@ipcb.pt) on 2011-05-24T15:12:04Z No. of bitstreams: 1 2001 Parducci FG.pdf: 78613 bytes, checksum: 97e8fd07f6858d235c47466352f92a1a (MD5) Approved for entry into archive by Maria Eduarda Pereira Rodrigues(erodrigues@ipcb.pt) on 2011-05-24T15:15:38Z (GMT) No. of bitstreams: 1 2001 Parducci FG.pdf: 78613 bytes, checksum: 97e8fd07f6858d235c47466352f92a1a (MD5) Made available in DSpace on 2011-05-24T15:16:19Z (GMT). No. of bitstreams: 1 2001 Parducci FG.pdf: 78613 bytes, checksum: 97e8fd07f6858d235c47466352f92a1a (MD5) Previous issue date: 2001

28. Isolated Grauer's gorilla populations differ in diet and gut microbiome.

Author

Michel A, Minocher R, Niehoff PP, Li Y, Nota K, Gadhvi MA, Su J, Iyer N, Porter A, Ngobobo-As-Ibungu U, Binyinyi E, Nishuli Pekeyake R, Parducci L, Caillaud D, and Guschanski K

Subjects
Animals, Animals, Wild genetics, Diet, Altitude, Plants genetics, RNA, Ribosomal, 16S genetics, Gorilla gorilla genetics, Gastrointestinal Microbiome genetics
Abstract

The animal gut microbiome has been implicated in a number of key biological processes, ranging from digestion to behaviour, and has also been suggested to facilitate local adaptation. Yet studies in wild animals rarely compare multiple populations that differ ecologically, which is the level at which local adaptation may occur. Further, few studies simultaneously characterize diet and gut microbiome from the same sample, despite their probable interdependence. Here, we investigate the interplay between diet and gut microbiome in three geographically isolated populations of the critically endangered Grauer's gorilla (Gorilla beringei graueri), which we show to be genetically differentiated. We find population- and social group-specific dietary and gut microbial profiles and covariation between diet and gut microbiome, despite the presence of core microbial taxa. There was no detectable effect of age, and only marginal effects of sex and genetic relatedness on the microbiome. Diet differed considerably across populations, with the high-altitude population consuming a lower diversity of plants compared to low-altitude populations, consistent with plant availability constraining dietary choices. The observed pattern of covariation between diet and gut microbiome is probably a result of long-term social and environmental factors. Our study suggests that the gut microbiome is sufficiently plastic to support flexible food selection and hence contribute to local adaptation., (© 2022 The Authors. Molecular Ecology published by John Wiley & Sons Ltd.)

Published
2023
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29. Plants, pollinators and their interactions under global ecological change: The role of pollen DNA metabarcoding.

Author

Bell KL, Turo KJ, Lowe A, Nota K, Keller A, Encinas-Viso F, Parducci L, Richardson RT, Leggett RM, Brosi BJ, Burgess KS, Suyama Y, and de Vere N

Subjects
Pollen genetics, Plants genetics, DNA, Pollination genetics, Ecosystem, DNA Barcoding, Taxonomic methods
Abstract

Anthropogenic activities are triggering global changes in the environment, causing entire communities of plants, pollinators and their interactions to restructure, and ultimately leading to species declines. To understand the mechanisms behind community shifts and declines, as well as monitoring and managing impacts, a global effort must be made to characterize plant-pollinator communities in detail, across different habitat types, latitudes, elevations, and levels and types of disturbances. Generating data of this scale will only be feasible with rapid, high-throughput methods. Pollen DNA metabarcoding provides advantages in throughput, efficiency and taxonomic resolution over traditional methods, such as microscopic pollen identification and visual observation of plant-pollinator interactions. This makes it ideal for understanding complex ecological networks and their responses to change. Pollen DNA metabarcoding is currently being applied to assess plant-pollinator interactions, survey ecosystem change and model the spatiotemporal distribution of allergenic pollen. Where samples are available from past collections, pollen DNA metabarcoding has been used to compare contemporary and past ecosystems. New avenues of research are possible with the expansion of pollen DNA metabarcoding to intraspecific identification, analysis of DNA in ancient pollen samples, and increased use of museum and herbarium specimens. Ongoing developments in sequencing technologies can accelerate progress towards these goals. Global ecological change is happening rapidly, and we anticipate that high-throughput methods such as pollen DNA metabarcoding are critical for understanding the evolutionary and ecological processes that support biodiversity, and predicting and responding to the impacts of change., (© 2022 The Authors. Molecular Ecology published by John Wiley & Sons Ltd.)

Published
2023
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30. Strengthening global-change science by integrating aeDNA with paleoecoinformatics.

Author

Williams JW, Spanbauer TL, Heintzman PD, Blois J, Capo E, Goring SJ, Monchamp ME, Parducci L, and Von Eggers JM

Subjects
Computational Biology, DNA Barcoding, Taxonomic, Biodiversity, DNA, Ancient
Abstract

Ancient environmental DNA (aeDNA) data are close to enabling insights into past global-scale biodiversity dynamics at unprecedented taxonomic extent and resolution. However, achieving this potential requires solutions that bridge bioinformatics and paleoecoinformatics. Essential needs include support for dynamic taxonomic inferences, dynamic age inferences, and precise stratigraphic depth. Moreover, aeDNA data are complex and heterogeneous, generated by dispersed researcher networks, with methods advancing rapidly. Hence, expert community governance and curation are essential to building high-value data resources. Immediate recommendations include uploading metabarcoding-based taxonomic inventories into paleoecoinformatic resources, building linkages among open bioinformatic and paleoecoinformatic data resources, harmonizing aeDNA processing workflows, and expanding community data governance. These advances will enable transformative insights into global-scale biodiversity dynamics during large environmental and anthropogenic changes., Competing Interests: Declaration of interests No interests are declared., (Copyright © 2023 Elsevier Ltd. All rights reserved.)

Published
2023
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31. Environmental DNA as an emerging tool in botanical research.

Author

Johnson MD, Freeland JR, Parducci L, Evans DM, Meyer RS, Molano-Flores B, and Davis MA

Subjects
DNA Barcoding, Taxonomic methods, Biodiversity, Environmental Monitoring methods, DNA, Environmental
Abstract

Over the past quarter century, environmental DNA (eDNA) has been ascendant as a tool to detect, measure, and monitor biodiversity (species and communities), as a means of elucidating biological interaction networks, and as a window into understanding past patterns of biodiversity. However, only recently has the potential of eDNA been realized in the botanical world. Here we synthesize the state of eDNA applications in botanical systems with emphases on aquatic, ancient, contemporary sediment, and airborne systems, and focusing on both single-species approaches and multispecies community metabarcoding. Further, we describe how abiotic and biotic factors, taxonomic resolution, primer choice, spatiotemporal scales, and relative abundance influence the utilization and interpretation of airborne eDNA results. Lastly, we explore several areas and opportunities for further development of eDNA tools for plants, advancing our knowledge and understanding of the efficacy, utility, and cost-effectiveness, and ultimately facilitating increased adoption of eDNA analyses in botanical systems., (© 2023 The Authors. American Journal of Botany published by Wiley Periodicals LLC on behalf of Botanical Society of America.)

Published
2023
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32. Norway spruce postglacial recolonization of Fennoscandia.

Author

Nota K, Klaminder J, Milesi P, Bindler R, Nobile A, van Steijn T, Bertilsson S, Svensson B, Hirota SK, Matsuo A, Gunnarsson U, Seppä H, Väliranta MM, Wohlfarth B, Suyama Y, and Parducci L

Subjects
DNA, Mitochondrial genetics, Forests, Norway, Trees genetics, Picea genetics, Pinus
Abstract

Contrasting theories exist regarding how Norway spruce (Picea abies) recolonized Fennoscandia after the last glaciation and both early Holocene establishments from western microrefugia and late Holocene colonization from the east have been postulated. Here, we show that Norway spruce was present in southern Fennoscandia as early as 14.7 ± 0.1 cal. kyr BP and that the millennia-old clonal spruce trees present today in central Sweden likely arrived with an early Holocene migration from the east. Our findings are based on ancient sedimentary DNA from multiple European sites (N = 15) combined with nuclear and mitochondrial DNA analysis of ancient clonal (N = 135) and contemporary spruce forest trees (N = 129) from central Sweden. Our other findings imply that Norway spruce was present shortly after deglaciation at the margins of the Scandinavian Ice Sheet, and support previously disputed finds of pollen in southern Sweden claiming spruce establishment during the Lateglacial., (© 2022. The Author(s).)

Published
2022
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33. Improved recovery of ancient DNA from subfossil wood - application to the world's oldest Late Glacial pine forest.

Author

Lendvay B, Hartmann M, Brodbeck S, Nievergelt D, Reinig F, Zoller S, Parducci L, Gugerli F, Büntgen U, and Sperisen C

Subjects
DNA, Plant genetics, Decontamination, Picea genetics, Pinus classification, Species Specificity, DNA, Plant isolation & purification, Forests, Fossils, Pinus genetics, Wood genetics
Abstract

Ancient DNA from historical and subfossil wood has a great potential to provide new insights into the history of tree populations. However, its extraction and analysis have not become routine, mainly because contamination of the wood with modern plant material can complicate the verification of genetic information. Here, we used sapwood tissue from 22 subfossil pines that were growing c. 13 000 yr bp in Zurich, Switzerland. We developed and evaluated protocols to eliminate surface contamination, and we tested ancient DNA authenticity based on plastid DNA metabarcoding and the assessment of post-mortem DNA damage. A novel approach using laser irradiation coupled with bleaching and surface removal was most efficient in eliminating contaminating DNA. DNA metabarcoding confirmed which ancient DNA samples repeatedly amplified pine DNA and were free of exogenous plant taxa. Pine DNA sequences of these samples showed a high degree of cytosine to thymine mismatches, typical of post-mortem damage. Stringent decontamination of wood surfaces combined with DNA metabarcoding and assessment of post-mortem DNA damage allowed us to authenticate ancient DNA retrieved from the oldest Late Glacial pine forest. These techniques can be applied to any subfossil wood and are likely to improve the accessibility of relict wood for genome-scale ancient DNA studies., (© 2017 The Authors. New Phytologist © 2017 New Phytologist Trust.)

Published
2018
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35. Ancient plant DNA in lake sediments.

Author

Parducci L, Bennett KD, Ficetola GF, Alsos IG, Suyama Y, Wood JR, and Pedersen MW

Subjects
Fossils, Pollen metabolism, DNA, Ancient chemistry, DNA, Plant metabolism, Geologic Sediments chemistry, Lakes chemistry
Abstract

Contents 924 I. 925 II. 925 III. 927 IV. 929 V. 930 VI. 930 VII. 931 VIII. 933 IX. 935 X. 936 XI. 938 938 References 938 SUMMARY: Recent advances in sequencing technologies now permit the analyses of plant DNA from fossil samples (ancient plant DNA, plant aDNA), and thus enable the molecular reconstruction of palaeofloras. Hitherto, ancient frozen soils have proved excellent in preserving DNA molecules, and have thus been the most commonly used source of plant aDNA. However, DNA from soil mainly represents taxa growing a few metres from the sampling point. Lakes have larger catchment areas and recent studies have suggested that plant aDNA from lake sediments is a more powerful tool for palaeofloristic reconstruction. Furthermore, lakes can be found globally in nearly all environments, and are therefore not limited to perennially frozen areas. Here, we review the latest approaches and methods for the study of plant aDNA from lake sediments and discuss the progress made up to the present. We argue that aDNA analyses add new and additional perspectives for the study of ancient plant populations and, in time, will provide higher taxonomic resolution and more precise estimation of abundance. Despite this, key questions and challenges remain for such plant aDNA studies. Finally, we provide guidelines on technical issues, including lake selection, and we suggest directions for future research on plant aDNA studies in lake sediments., (© 2017 The Authors. New Phytologist © 2017 New Phytologist Trust.)

Published
2017
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36. Genetic diversity and divergence at the Arbutus unedo L. (Ericaceae) westernmost distribution limit.

Author

Ribeiro MM, Piotti A, Ricardo A, Gaspar D, Costa R, Parducci L, and Vendramin GG

Subjects
Bayes Theorem, Phylogeography, Spain, Ericaceae genetics, Genetic Variation
Abstract

Mediterranean forests are fragile ecosystems vulnerable to recent global warming and reduction of precipitation, and a long-term negative effect is expected on vegetation with increasing drought and in areas burnt by fires. We investigated the spatial distribution of genetic variation of Arbutus unedo in the western Iberia Peninsula, using plastid markers with conservation and provenance regions design purposes. This species is currently undergoing an intense domestication process in the region, and, like other species, is increasingly under the threat from climate change, habitat fragmentation and wildfires. We sampled 451 trees from 15 natural populations from different ecological conditions spanning the whole species' distribution range in the region. We applied Bayesian analysis and identified four clusters (north, centre, south, and a single-population cluster). Hierarchical AMOVA showed higher differentiation among clusters than among populations within clusters. The relatively low within-clusters differentiation can be explained by a common postglacial history of nearby populations. The genetic structure found, supported by the few available palaeobotanical records, cannot exclude the hypothesis of two independent A. unedo refugia in western Iberia Peninsula during the Last Glacial Maximum. Based on the results we recommend a conservation strategy by selecting populations for conservation based on their allelic richness and diversity and careful seed transfer consistent with current species' genetic structure.

Published
2017
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37. The extent and meaning of hybridization and introgression between Siberian spruce (Picea obovata) and Norway spruce (Picea abies): cryptic refugia as stepping stones to the west?

Author

Tsuda Y, Chen J, Stocks M, Källman T, Sønstebø JH, Parducci L, Semerikov V, Sperisen C, Politov D, Ronkainen T, Väliranta M, Vendramin GG, Tollefsrud MM, and Lascoux M

Subjects
Bayes Theorem, DNA, Mitochondrial genetics, DNA, Plant genetics, Genotyping Techniques, Microsatellite Repeats, Models, Genetic, Picea classification, Population Dynamics, Russia, Scandinavian and Nordic Countries, Genetics, Population, Hybridization, Genetic, Picea genetics, Refugium
Abstract

Boreal species were repeatedly exposed to ice ages and went through cycles of contraction and expansion while sister species alternated periods of contact and isolation. The resulting genetic structure is consequently complex, and demographic inferences are intrinsically challenging. The range of Norway spruce (Picea abies) and Siberian spruce (Picea obovata) covers most of northern Eurasia; yet their geographical limits and histories remain poorly understood. To delineate the hybrid zone between the two species and reconstruct their joint demographic history, we analysed variation at nuclear SSR and mitochondrial DNA in 102 and 88 populations, respectively. The dynamics of the hybrid zone was analysed with approximate Bayesian computation (ABC) followed by posterior predictive structure plot reconstruction and the presence of barriers across the range tested with estimated effective migration surfaces. To estimate the divergence time between the two species, nuclear sequences from two well-separated populations of each species were analysed with ABC. Two main barriers divide the range of the two species: one corresponds to the hybrid zone between them, and the other separates the southern and northern domains of Norway spruce. The hybrid zone is centred on the Urals, but the genetic impact of Siberian spruce extends further west. The joint distribution of mitochondrial and nuclear variation indicates an introgression of mitochondrial DNA from Norway spruce into Siberian spruce. Overall, our data reveal a demographic history where the two species interacted frequently and where migrants originating from the Urals and the West Siberian Plain recolonized northern Russia and Scandinavia using scattered refugial populations of Norway spruce as stepping stones towards the west., (© 2016 John Wiley & Sons Ltd.)

Published
2016
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38. Proxy comparison in ancient peat sediments: pollen, macrofossil and plant DNA.

Author

Parducci L, Väliranta M, Salonen JS, Ronkainen T, Matetovici I, Fontana SL, Eskola T, Sarala P, and Suyama Y

Subjects
Base Sequence, DNA, Plant classification, DNA, Plant history, Finland, History, Ancient, Molecular Sequence Data, Multiplex Polymerase Chain Reaction, Russia, Sequence Analysis, DNA methods, DNA, Plant genetics, Fossils, Geologic Sediments chemistry, Pollen genetics, Soil chemistry
Abstract

We compared DNA, pollen and macrofossil data obtained from Weichselian interstadial (age more than 40 kyr) and Holocene (maximum age 8400 cal yr BP) peat sediments from northern Europe and used them to reconstruct contemporary floristic compositions at two sites. The majority of the samples provided plant DNA sequences of good quality with success amplification rates depending on age. DNA and sequencing analysis provided five plant taxa from the older site and nine taxa from the younger site, corresponding to 7% and 15% of the total number of taxa identified by the three proxies together. At both sites, pollen analysis detected the largest (54) and DNA the lowest (10) number of taxa, but five of the DNA taxa were not detected by pollen and macrofossils. The finding of a larger overlap between DNA and pollen than between DNA and macrofossils proxies seems to go against our previous suggestion based on lacustrine sediments that DNA originates principally from plant tissues and less from pollen. At both sites, we also detected Quercus spp. DNA, but few pollen grains were found in the record, and these are normally interpreted as long-distance dispersal. We confirm that in palaeoecological investigations, sedimentary DNA analysis is less comprehensive than classical morphological analysis, but is a complementary and important tool to obtain a more complete picture of past flora., (© 2014 The Author(s) Published by the Royal Society. All rights reserved.)

Published
2015
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39. Patterns of nucleotide diversity at photoperiod related genes in Norway spruce [Picea abies (L.) Karst].

Author

Källman T, De Mita S, Larsson H, Gyllenstrand N, Heuertz M, Parducci L, Suyama Y, Lagercrantz U, and Lascoux M

Subjects
Genetics, Population, Plant Proteins genetics, Circadian Clocks genetics, Circadian Rhythm genetics, Genes, Plant genetics, Nucleotides genetics, Photoperiod, Picea genetics
Abstract

The ability of plants to track seasonal changes is largely dependent on genes assigned to the photoperiod pathway, and variation in those genes is thereby important for adaptation to local day length conditions. Extensive physiological data in several temperate conifer species suggest that populations are adapted to local light conditions, but data on the genes underlying this adaptation are more limited. Here we present nucleotide diversity data from 19 genes putatively involved in photoperiodic response in Norway spruce (Picea abies). Based on similarity to model plants the genes were grouped into three categories according to their presumed position in the photoperiod pathway: photoreceptors, circadian clock genes, and downstream targets. An HKA (Hudson, Kreitman and Aquade) test showed a significant excess of diversity at photoreceptor genes, but no departure from neutrality at circadian genes and downstream targets. Departures from neutrality were also tested with Tajima's D and Fay and Wu's H statistics under three demographic scenarios: the standard neutral model, a population expansion model, and a more complex population split model. Only one gene, the circadian clock gene PaPRR3 with a highly positive Tajima's D value, deviates significantly from all tested demographic scenarios. As the PaPRR3 gene harbours multiple non-synonymous variants it appears as an excellent candidate gene for control of photoperiod response in Norway spruce.

Published
2014
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40. Molecular- and pollen-based vegetation analysis in lake sediments from central Scandinavia.

Author

Parducci L, Matetovici I, Fontana SL, Bennett KD, Suyama Y, Haile J, Kjaer KH, Larsen NK, Drouzas AD, and Willerslev E

Subjects
Biodiversity, Cloning, Molecular, DNA Barcoding, Taxonomic, DNA Primers, DNA, Plant analysis, DNA, Plant genetics, Fossils, Plants classification, Scandinavian and Nordic Countries, Sequence Alignment, Species Specificity, Geologic Sediments analysis, Lakes analysis, Plants genetics, Pollen chemistry
Abstract

Plant and animal biodiversity can be studied by obtaining DNA directly from the environment. This new approach in combination with the use of generic barcoding primers (metabarcoding) has been suggested as complementary or alternative to traditional biodiversity monitoring in ancient soil sediments. However, the extent to which metabarcoding truly reflects plant composition remains unclear, as does its power to identify species with no pollen or macrofossil evidence. Here, we compared pollen-based and metabarcoding approaches to explore the Holocene plant composition around two lakes in central Scandinavia. At one site, we also compared barcoding results with those obtained in earlier studies with species-specific primers. The pollen analyses revealed a larger number of taxa (46), of which the majority (78%) was not identified by metabarcoding. The metabarcoding identified 14 taxa (MTUs), but allowed identification to a lower taxonomical level. The combined analyses identified 52 taxa. The barcoding primers may favour amplification of certain taxa, as they did not detect taxa previously identified with species-specific primers. Taphonomy and selectiveness of the primers are likely the major factors influencing these results. We conclude that metabarcoding from lake sediments provides a complementary, but not an alternative, tool to pollen analysis for investigating past flora. In the absence of other fossil evidence, metabarcoding gives a local and important signal from the vegetation, but the resulting assemblages show limited capacity to detect all taxa, regardless of their abundance around the lake. We suggest that metabarcoding is followed by pollen analysis and the use of species-specific primers to provide the most comprehensive signal from the environment., (© 2013 John Wiley & Sons Ltd.)

Published
2013
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41. Glacial survival of boreal trees in northern Scandinavia.

Author

Parducci L, Jørgensen T, Tollefsrud MM, Elverland E, Alm T, Fontana SL, Bennett KD, Haile J, Matetovici I, Suyama Y, Edwards ME, Andersen K, Rasmussen M, Boessenkool S, Coissac E, Brochmann C, Taberlet P, Houmark-Nielsen M, Larsen NK, Orlando L, Gilbert MT, Kjær KH, Alsos IG, and Willerslev E

Subjects
Base Sequence, DNA, Chloroplast genetics, DNA, Mitochondrial genetics, Europe, Geologic Sediments, Haplotypes, Molecular Sequence Data, Mutation, Norway, Scandinavian and Nordic Countries, Time, Ecosystem, Fossils, Ice Cover, Picea genetics, Pinus genetics
Abstract

It is commonly believed that trees were absent in Scandinavia during the last glaciation and first recolonized the Scandinavian Peninsula with the retreat of its ice sheet some 9000 years ago. Here, we show the presence of a rare mitochondrial DNA haplotype of spruce that appears unique to Scandinavia and with its highest frequency to the west-an area believed to sustain ice-free refugia during most of the last ice age. We further show the survival of DNA from this haplotype in lake sediments and pollen of Trøndelag in central Norway dating back ~10,300 years and chloroplast DNA of pine and spruce in lake sediments adjacent to the ice-free Andøya refugium in northwestern Norway as early as ~22,000 and 17,700 years ago, respectively. Our findings imply that conifer trees survived in ice-free refugia of Scandinavia during the last glaciation, challenging current views on survival and spread of trees as a response to climate changes.

Published
2012
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42. Population dynamics and genetic changes of Picea abies in the South Carpathians revealed by pollen and ancient DNA analyses.

Author

Magyari EK, Major A, Bálint M, Nédli J, Braun M, Rácz I, and Parducci L

Subjects
DNA Primers, DNA, Chloroplast genetics, DNA, Plant genetics, Europe, Evolution, Molecular, Fossils, Phylogeny, Pollen genetics, Population Dynamics, Sequence Analysis, DNA, Genetic Variation, Genetics, Population, Picea genetics
Abstract

Background: Studies on allele length polymorphism designate several glacial refugia for Norway spruce (Picea abies) in the South Carpathian Mountains, but infer only limited expansion from these refugia after the last glaciation. To better understand the genetic dynamics of a South Carpathian spruce lineage, we compared ancient DNA from 10,700 and 11,000-year-old spruce pollen and macrofossils retrieved from Holocene lake sediment in the Retezat Mountains with DNA extracted from extant material from the same site. We used eight primer pairs that amplified short and variable regions of the spruce cpDNA. In addition, from the same lake sediment we obtained a 15,000-years-long pollen accumulation rate (PAR) record for spruce that helped us to infer changes in population size at this site., Results: We obtained successful amplifications for Norway spruce from 17 out of 462 pollen grains tested, while the macrofossil material provided 22 DNA sequences. Two fossil sequences were found to be unique to the ancient material. Population genetic statistics showed higher genetic diversity in the ancient individuals compared to the extant ones. Similarly, statistically significant Ks and Kst values showed a considerable level of differentiation between extant and ancient populations at the same loci.Lateglacial and Holocene PAR values suggested that population size of the ancient population was small, in the range of 1/10 or 1/5 of the extant population. PAR analysis also detected two periods of rapid population growths (from ca. 11,100 and 3900 calibrated years before present (cal yr BP)) and three bottlenecks (around 9180, 7200 and 2200 cal yr BP), likely triggered by climatic change and human impact., Conclusion: Our results suggest that the paternal lineages observed today in the Retezat Mountains persisted at this site at least since the early Holocene. Combination of the results from the genetic and the PAR analyses furthermore suggests that the higher level of genetic variation found in the ancient populations and the loss of ancient allele types detected in the extant individuals were likely due to the repeated bottlenecks during the Holocene; however our limited sample size did not allow us to exclude sampling effect.This study demonstrates how past population size changes inferred from PAR records can be efficiently used in combination with ancient DNA studies. The joint application of palaeoecological and population genetics analyses proved to be a powerful tool to understand the influence of past population demographic changes on the haplotype diversity and genetic composition of forest tree species.

Published
2011
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43. Ancient plant DNA: review and prospects.

Author

Gugerli F, Parducci L, and Petit RJ

Subjects
Biological Evolution, DNA, Plant genetics, Genetic Markers, Paleontology methods, Phylogeny, DNA, Plant analysis, Plants genetics
Abstract

Ancient DNA has received much attention since the mid-1980s, when the first sequence of an extinct animal species was recovered from a museum specimen. Since then, the majority of ancient DNA studies have focused predominantly on animal species, while studies in plant palaeogenetics have been rather limited, with the notable exception of cultivated species found in archaeological sites. Here, we outline the recent developments in the analysis of plant ancient DNA. We emphasize the trend from species identification to population-level investigation and highlight the potential and the difficulties in this field, related to DNA preservation and to risks of contamination. Further efforts towards the analysis of ancient DNA from the abundant store of fossil plant remains should provide new research opportunities in palaeoecology and phylogeography. In particular, intraspecific variation should be considered not only in cultivated plants but also in wild taxa if palaeogenetics is to become a fully emancipated field of plant research.

Published
2005
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