One Cell at a Time: Advances in Single-Cell Methods and Instrumentation for Discovery in Aquatic Microbiology

Grujčić, Vesna; Taylor, Gordon; Foster, Rachel A.

doi:10.3389/fmicb.2022.881018

Cited by 7 publications

(4 citation statements)

References 91 publications

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“…Microbial ecologists have recently been able to adapt and combine a variety of tools previously developed in far-ranging fields [Grujcic et al 2022] for fungal identification, such as matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) [Cornut et al 2019]; single-spore isolation, followed by marker gene (rDNA) barcoding sequencing [Bärlocher et al 2010; Karpov et al 2020; Kagami et al 2021; Strassert et al 2021; van den Wyngaert et al 2022; Nakanishi et al 2023] and even single-spore isolation, genome amplification and whole-genome sequencing [Ciobanu et al 2022]. While the single cell analysis using flow cytometry is an established method, it is limited by the size of the cells and only works in an automated manner, which usually excludes manual inspections by cells.…”

Section: Discussionmentioning

confidence: 99%

Exploring environmental microfungal diversity through serial single cell screening

Mariz,

Nawaz,

Bösch

et al. 2024

Preprint

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Known for its remarkable diversity and ecological importance, the fungal kingdom remains largely unexplored. In fact, the number of unknown and undescribed fungi is predicted to exceed the number of known fungal species by far. Despite efforts to uncover these dark fungal taxa, we still face inherent sampling biases and methodological limitations. Here, we present a framework that combines taxonomic knowledge, molecular biology, and data processing to explore the fungal biodiversity of enigmatic aquatic fungal lineages. Our work is based on serial screening of environmental fungal cells to approach unknown fungal taxa. Microscopic documentation is followed by DNA analysis of laser micro-dissected cells, coupled with a ribosomal operon barcoding step realized by long-read sequencing, followed by an optional whole genome sequencing step. We tested this approach on a range of aquatic fungal cells mostly belonging to the group of aquatic hyphomycetes derived from environmental samples. From this initial screening, we were able to identify thirty-two potentially new fungal taxa in the target dataset. By extending this methodology to other fungal lineages associated with different habitats, we expect to increasingly characterize the molecular barcodes of dark fungal taxa in diverse environmental samples. This work offers a promising solution to the challenges posed by unknown and unculturable fungi and holds the potential to be applied to the diverse lineages of undescribed microeukaryotes.

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Section: Discussionmentioning

confidence: 99%

Exploring environmental microfungal diversity through serial single cell screening

Mariz,

Nawaz,

Bösch

et al. 2024

Preprint

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“…As a result, mass spectrometric imaging 3D mapping of complex microbiological forms (e.g., aggregates or biofilms) can be difficult. Additional measures are required for successful sample preparation, demanding further stabilization or freezing, which generally results in loss of live cells [Watrous and Dorrestein, 2011;Grujcic et al, 2022]. Moreover, SIMS imaging employs a harsh and destructive ionization technique leaving cells in a nonviable state after analysis [Watrous and Dorrestein, 2011].…”

Section: Secondary Ion Mass Spectrometrymentioning

confidence: 99%

“…Most NanoSIMS analysis efforts utilize isotope and/or rare element labeling to enable the detection of processes or species of interest inside biological samples [Nuñez et al, 2018]. NanoSIMS is now frequently used in combination with other measures such as fluorescent in situ hybridization (FISH) or bioorthogonal noncanonical amino acid tagging (BONCAT) [Grujcic et al, 2022] (discussed below). Although the method is destructive and downstream applications such as cultivation and omics approaches are not possible, its application in a variety of studies shows a valuable information gain in the detection of MDM and description of prokaryotic communities on single-cell level (reviewed in, e.g., [Orphan and House, 2009;Gao et al, 2016;Musat et al, 2016;Nuñez et al, 2018]).…”

Section: Secondary Ion Mass Spectrometrymentioning

confidence: 99%

Targeted Cell Labeling and Sorting of Prokaryotes for Cultivation and Omics Approaches

Sturm,

Mojarrad,

Kaster

2023

Microb Physiol

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To date, the vast majority of prokaryotic organisms escapes detailed characterization because they cannot be isolated in axenic cultures. These organisms are referred to as microbial dark matter. Targeted labelling and sorting of these microorganisms pave the way for single-cell, enrichment, or cultivation approaches. In this review, we describe an array of different methods ranging from labeling-free to specific labelling techniques. In addition, different cell sorting methods and their combinations with targeting strategies are summarized and downstream applications like sequencing and cultivation are reviewed. Recent advances, challenges, and limitations of the particular methods are discussed with respect to cell viability, genome integrity as well as throughput, in order to help researchers select the most suitable methods for their specific research questions.

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“…Therefore, by adapting the laser geometry or optimizing the laser focusing, MALDI-MSI seems to be in a position to get closer to microscopic techniques. Additionally, the potential combination of single-cell imaging and single-cell sequencing was underlined as being able to give important insights regarding aquatic microbes and their environment [ 131 ]. Secondly, the limit of detection of microorganisms per pixel needs to be established.…”

Section: Outlooks and Future Challenges For Maldi-imaging In Microbio...mentioning

confidence: 99%

MALDI Mass Spectrometry Imaging: A Potential Game-Changer in a Modern Microbiology

Feucherolles

Frache

2022

Cells

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Nowadays, matrix-assisted laser desorption/ionization time of flight mass spectrometry (MALDI-TOF MS) is routinely implemented as the reference method for the swift and straightforward identification of microorganisms. However, this method is not flawless and there is a need to upgrade the current methodology in order to free the routine lab from incubation time and shift from a culture-dependent to an even faster independent culture system. Over the last two decades, mass spectrometry imaging (MSI) gained tremendous popularity in life sciences, including microbiology, due to its ability to simultaneously detect biomolecules, as well as their spatial distribution, in complex samples. Through this literature review, we summarize the latest applications of MALDI-MSI in microbiology. In addition, we discuss the challenges and avenues of exploration for applying MSI to solve current MALDI-TOF MS limits in routine and research laboratories.

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One Cell at a Time: Advances in Single-Cell Methods and Instrumentation for Discovery in Aquatic Microbiology

Cited by 7 publications

References 91 publications

Exploring environmental microfungal diversity through serial single cell screening

Exploring environmental microfungal diversity through serial single cell screening

Targeted Cell Labeling and Sorting of Prokaryotes for Cultivation and Omics Approaches

MALDI Mass Spectrometry Imaging: A Potential Game-Changer in a Modern Microbiology

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