Testing Pollen Sorted by Flow Cytometry as the Basis for High-Resolution Lacustrine Chronologies

Zimmerman, Susan; Brown, Thomas A.; Hassel, Christiane; Heck, Jessica M.

doi:10.1017/rdc.2018.89

Cited by 18 publications

(28 citation statements)

References 49 publications

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“…Third, reworked pollen is suggested as a major source of old-carbon contamination in lacustrine settings where extensive old lacustrine deposits occur at the surface (Mensing and Southon 1999;Zimmerman et al 2019) or redeposition occurs from glacial melt (Neulieb et al 2013;Zhang et al 2017). There is no evidence of a Holocene glacial meltwater source in the Yellowstone Lake watershed.…”

Section: Carbon Source Of Yellowstone Terrestrial Pollenmentioning

confidence: 99%

“…carbonates, algal remains, humic acids) from the sample. Although some studies suggest dating errors as a result of incomplete separation of non-pollen material (Regnéll 1992;Richardson and Hall 1994) or incorporation of reworked pollen grains (Mensing and Southon 1999;Zimmerman et al 2019), pollenconcentrate ages typically produce more reliable chronologies than bulk-sediment ages where reservoir effects are a concern (e.g. Brown et al 1989;Vandergoes and Prior 2003;Newnham et al 2007;Fletcher et al 2017).…”

Section: Introductionmentioning

confidence: 99%

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Erroneously Old Radiocarbon Ages From Terrestrial Pollen Concentrates in Yellowstone Lake, Wyoming, Usa

et al. 2020

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Accelerator mass spectrometry (AMS) dating of pollen concentrates is often used in lake sediment records where large, terrestrial plant remains are unavailable. Ages produced from chemically concentrated pollen as well as manually picked Pinaceae grains in Yellowstone Lake (Wyoming) sediments were consistently 1700–4300 cal years older than ages established by terrestrial plant remains, tephrochronology, and the age of the sediment-water interface. Previous studies have successfully utilized the same laboratory space and methods, suggesting the source of old-carbon contamination is specific to these samples. Manually picking pollen grains precludes admixture of non-pollen materials. Furthermore, no clear source of old pollen grains occurs on the deglaciated landscape, making reworking of old pollen grains unlikely. High volumes of CO2 are degassed in the Yellowstone Caldera, potentially introducing old carbon to pollen. While uptake of old CO2 through photosynthesis is minor (F14C approximately 0.99), old-carbon contamination may still take place in the water column or in surficial lake sediments. It remains unclear, however, what mechanism allows for the erroneous ages of highly refractory pollen grains while terrestrial plant remains were unaffected. In the absence of a satisfactory explanation for erroneously old radiocarbon ages from pollen concentrates, we propose steps for further study.

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Section: Carbon Source Of Yellowstone Terrestrial Pollenmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Erroneously Old Radiocarbon Ages From Terrestrial Pollen Concentrates in Yellowstone Lake, Wyoming, Usa

et al. 2020

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“…Gates created using biparametric scatterplots of these parameters can therefore be used to circumscribe mature pollen, spores, or microspore events before measurement, counting, and/or sorting [9,23]. Natural autofluorescence of sporopollenin in the pollen wall can also be used for taxonomic identification and sorting of environmental pollen samples (e.g., airborne pollen [24]) and fossil pollen from sediments [23,25]. While such autofluorescence is relatively uniform within species, users should be aware that exceptions have been observed [26].…”

Section: Whole Mature Pollen and Sporesmentioning

confidence: 99%

“…Since the pollen cells are long dead, these applications rely mostly on natural autofluorescence of sporopollenin in the pollen wall or whole pollen light scatter properties (SSC and FSC),which may allow their assignment to a particular (group of) plant species[23,32]. Promising applications include using flow sorting to obtain fossil pollen samples in sufficient concentration and purity to allow either radiocarbon dating of layers in a sedimentary sequence[23,25] or extraction and sequencing of ancient DNA[33].Because the objective of flow sorting is to obtain the correct particle type in as pure a form as possible, methods should be validated using samples of known composition. Recovery of some particle types may be more difficult than others; for example, vegetative nuclei may be more prone to disruption than sperm nuclei[22].…”

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confidence: 99%

Flow cytometric analysis of pollen and spores: An overview of applications and methodology

et al. 2021

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Pollen grains are the male gametophytes in a seed-plant life cycle. Their small, particulate nature and crucial role in plant reproduction have made them an attractive object of study using flow cytometry (FCM), with a wide range of applications existing in the literature. While methodological considerations for many of these overlap with those for other tissue types (e.g., general considerations for the measurement of nuclear DNA content), the relative complexity of pollen compared to single cells presents some unique challenges. We consider these here in the context of both the identification and isolation of pollen and its subunits, and the types of research applications. While the discussion here mostly concerns pollen, the general principles described here can be extended to apply to spores in ferns, lycophytes, and bryophytes. In addition to recommendations provided in more general studies, some recurring and notable issues related specifically to pollen and spores are highlighted.

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“…The most powerful feature of the presented sorting method is its capability to sort most pollen taxa, i.e., from the smallest types to large types of up to 170 m at high throughput, which allows efficient concentration of fossil pollen from virtually all sedimentary deposits for 14 C dating or other analytical applications. This is a breakthrough achievement compared to conventional particle sorters that can sort particles up to a size of only 100 m (sortable particle volume of 0.52 nl) at a throughput of 10,000 Hz (30) or conventional large-particle sorters, such as those by Union Biometrica, which sort particles in the size range of 20 to 400 m (sortable particle volume of 4.0 pl to 34 nl) at low-throughput rates of maximum 20 particles/s (17,31). Compared to these two kinds of conventional sorters previously used for pollen purification, the sorting performance [defined as "sortable particle volume" × "throughput" (14)] of the new device (sortable particle volume of up to 7.0 nl; throughput of 5000 Hz) is on April 22, 2021 http://advances.sciencemag.org/ Downloaded from about 7.5 and 59 times higher, respectively.…”

Section: Purification Of Fossil Pollen For 14 C Datingmentioning

confidence: 99%

Breakthrough in purification of fossil pollen for dating of sediments by a new large-particle on-chip sorter

et al. 2021

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Particle sorting is a fundamental method in various fields of medical and biological research. However, existing sorting applications are not capable for high-throughput sorting of large-size (>100 micrometers) particles. Here, we present a novel on-chip sorting method using traveling vortices generated by on-demand microjet flows, which locally exceed laminar flow condition, allowing for high-throughput sorting (5 kilohertz) with a record-wide sorting area of 520 micrometers. Using an activation system based on fluorescence detection, the method successfully sorted 160-micrometer microbeads and purified fossil pollen (maximum dimension around 170 micrometers) from lake sediments. Radiocarbon dates of sorting-derived fossil pollen concentrates proved accurate, demonstrating the method’s ability to enhance building chronologies for paleoenvironmental records from sedimentary archives. The method is capable to cover urgent needs for high-throughput large-particle sorting in genomics, metabolomics, and regenerative medicine and opens up new opportunities for the use of pollen and other microfossils in geochronology, paleoecology, and paleoclimatology.

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Testing Pollen Sorted by Flow Cytometry as the Basis for High-Resolution Lacustrine Chronologies

Cited by 18 publications

References 49 publications

Erroneously Old Radiocarbon Ages From Terrestrial Pollen Concentrates in Yellowstone Lake, Wyoming, Usa

Erroneously Old Radiocarbon Ages From Terrestrial Pollen Concentrates in Yellowstone Lake, Wyoming, Usa

Flow cytometric analysis of pollen and spores: An overview of applications and methodology

Breakthrough in purification of fossil pollen for dating of sediments by a new large-particle on-chip sorter

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