Feb 25, 2023
Flow cytometry trait measurements (size, granularity and chlorophyll-a) of diatoms
- Phoebe Argyle1,
- Jana Hinners2,
- Nathan Walworth3,
- Sinead Collins4,
- Naomi M. Levine3,
- Martina Doblin5
- 1Climate Change Cluster, University of Technology Sydney, Sydney, Australia;
- 2Institute of Coastal Ocean Dynamics, Helmholtz-Zentrum Geesthacht, Geesthacht, Germany;
- 3Department of Biological Sciences, University of Southern California, Los Angeles, CA, USA;
- 4Institute of Evolutionary Biology, University of Edinburgh, Edinburgh, UK;
- 5Climate Change Cluster, University of Technology Sydney, Sydney, Australia. Sydney Institute of Marine Science, Mosman, Sydney, Australia
External link: https://doi.org/10.3389/fmicb.2021.706235
Protocol Citation: Phoebe Argyle, Jana Hinners, Nathan Walworth, Sinead Collins, Naomi M. Levine, Martina Doblin 2023. Flow cytometry trait measurements (size, granularity and chlorophyll-a) of diatoms. protocols.io https://dx.doi.org/10.17504/protocols.io.dm6gpr2x5vzp/v1
Manuscript citation:
Argyle, P.A., Hinners, J., Walworth, N.G., Collins, S., Levine, N.M., Doblin, M.A., 2021. A High-Throughput Assay for Quantifying Phenotypic Traits of Microalgae. Frontiers in Microbiology 12(2910).
License: This is an open access protocol distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited
Protocol status: Working
We use this protocol and it's working
Created: April 22, 2020
Last Modified: February 25, 2023
Protocol Integer ID: 36013
Keywords: diatom, flow cytometry, trait-based methods, Thalassiosira, high-throughput, microalgae, chlorophyll-a
Funders Acknowledgement:
Gordon and Betty Moore Foundation Marine Microbes Initiative
Grant ID: MMI 7397
Abstract
A method and guide for measuring size, relative granularity, and chlorophyll-a content in centric diatom cells. This method was developed on a CytoFlex LX instrument with Thalassiosira spp. as the model organism.
This protocol was used in the following publications:
Argyle, P. A., Walworth, N. G., Hinners, J., Collins, S., Levine, N. M., & Doblin, M. A. (2021). Multivariate trait analysis reveals diatom plasticity constrained to a reduced set of biological axes. ISME Communications, 1(1), 59.
Argyle, P. A., Hinners, J., Walworth, N. G., Collins, S., Levine, N. M., & Doblin, M. A. (2021). A high-throughput assay for quantifying phenotypic traits of microalgae. Frontiers in microbiology, 12, 706235.
Guidelines
Flow cytometry analyses are most efficient if run in the afternoon of the day of sampling, however these samples can also be snap frozen in liquid nitrogen, stored at −80°C and analysed in delayed mode.
Fluorescence of chlorophyll-a diminishes over time so ensure the time between sampling and measurement is similar for all samples being compared.
Materials
Equipment
CytoFLEX LX
NAME
Flow cytometer
TYPE
Beckman Coulter
BRAND
C40312
SKU
LINK
CytoFLEX LX N3-V5-B3-Y5-R3-I2 Flow Cytometer (21 Detectors, 6 Lasers)
SPECIFICATIONS
Equipment
96 Well TC-Treated Microplates
NAME
Microplate
TYPE
Corning®
BRAND
CLS3799-1EA
SKU
LINK
Equipment
Parafilm
NAME
lab consumable
TYPE
Parafilm M
BRAND
PM996
SKU
LINK
Can be purchased from many vendors
SPECIFICATIONS
Paraformaldehyde 8% EM Grade aqueous solutionsEmgridCatalog #157-8
CytoFlex Daily QC BeadsBeckman CoulterCatalog #B53230
Flow Cytometry Size Calibration Kit (nonfluorescent microspheres)Thermo FisherCatalog #F13838
Protocol materials
Paraformaldehyde 8% EM Grade aqueous solutionsEmgridCatalog #157-8
Materials, Step 2
CytoFlex Daily QC BeadsBeckman CoulterCatalog #B53230
In Materials and 2 steps
Flow Cytometry Size Calibration Kit (nonfluorescent microspheres)Thermo FisherCatalog #F13838
Materials, Step 8
Safety warnings
Paraformaldehyde is toxic so ensure this is added under a fume hood or chemical safety cabinet.
Sample preparation
Sample preparation
1h
1h
Aliquot 200 µL of live, uniform culture and transfer to a round-bottom tissue culture plate. Agitate culture gently to suspend cells to create a uniform culture.
Equipment
96 Well TC-Treated Microplates
NAME
Microplate
TYPE
Corning®
BRAND
CLS3799-1EA
SKU
LINK
Fix the cells with 20 µL (10 % volume ) paraformaldehyde 8% solution, resulting in a final concentration of 0.8% paraformaldehyde. Use a fume hood as this reagent is toxic.
Paraformaldehyde 8% EM Grade aqueous solutionsEmgridCatalog #157-8
Secure the lid and wrap plate edges with parafilm to prevent evaporation and store at 4 °C prior to analysis (analyse within 48 hours, ideally later the same day).
Equipment
Parafilm
NAME
lab consumable
TYPE
Parafilm M
BRAND
PM996
SKU
LINK
Can be purchased from many vendors
SPECIFICATIONS
Flow cytometry setup
Flow cytometry setup
Load plate into the flow cytometer, this protocol was developed using a CytoFLEX LX instrument.
Equipment
CytoFLEX LX
NAME
Flow cytometer
TYPE
Beckman Coulter
BRAND
C40312
SKU
LINK
CytoFLEX LX N3-V5-B3-Y5-R3-I2 Flow Cytometer (21 Detectors, 6 Lasers)
SPECIFICATIONS
Set up the flow cytometer and run the daily Quality control (QC) protocol as per the instrument instructions.
In this case for the Cytoflex LX, multi-spectra beads CytoFlex Daily QC BeadsBeckman CoulterCatalog #B53230 are used to ensure the correct functioning of the instrument.
These beads may also be used to ensure consistency across experimental runs, as discussed in step 8.
Optimise gain and threshold settings for the detectors of interest in the flow cytometer. A spare aliquot of diatom culture can be used to optimise gain/thresold settings. Culture media obtained from filtering diatom culture (through a 0.22 μm filter) can also be used to identify background scatter and set thresholds.
The lazer and detectors are as follows, however this will depend on the particular instrument so exact numbers may not match if a different instrument is used.
Forward scatter area: Si-photodiode with built-in 488/8 band-pass filter (CytoFLEX Channel name: FSC-A)
Side scatter area: 488nm (50mw), Optical Filter: 488/8 nm, (CytoFLEX Channel name: SSC-A)
Chlorophyll a: Laser: 488nm (50mw), Optical Filter: 690/50 nm, (CytoFLEX Channel name: B690-50)
Thresholds were set at 4000 for FSC-A (forward scatter area) and 2000 for B690-50 (chlorophyll-a) to distinguish cells from background debris and particulates.
Flow cytometry analysis
Flow cytometry analysis
Samples are mixed for 6 seconds by the CytoFlex instrument before analysis.
During development samples were generally run at medium speed/flow rate of 30 µL per minute for 00:01:00 . Analysis is done on at least 200 cells, however in most cases it would be at least 2000 cells. The abort rate (%) was <1%. In the case of a highly dense culture, a slower speed maybe prudent to ensure a low abort rate and ensure accuracy of analysis. In the case of a low density culture, a higher flow rate or longer duration of analysis may be used to ensure an adequate number of cells are analyzed.
Diatoms were gated visuallt using event density plots of chlorophyll fluorescence and forward scatter (see below).
1m
Calibration using beads
Calibration using beads
The multi-spectra beads CytoFlex Daily QC BeadsBeckman CoulterCatalog #B53230 that are used to calibrate the instrument on startup may also be used to ensure comparability between experimental runs.
It is recommended to analyse samples from one experiment on the same day, however if this is not possible it is necessary to ensure that the instrument is performing similarly on the different days of analysis.
Using the parameters and thresholds established for diatoms, the QC beads may be run as if they were a sample and gated according to their chlorophyll fluorescence, forward scatter and side scatter (see image below). This way, if the beads fall within the same gates on each day of analysis, it may be assumed that samples run on different days may be fairly compared.
Daily QC beads gated according to forward scatter (FSC-A) and side scatter (SSC-A)
In addition to the QC beads, beads of known diameter were used to create a linear calibration of forward scatter vs. spherical size. For this protocol, beads of 2,4,6,10 and 15µm Flow Cytometry Size Calibration Kit (nonfluorescent microspheres)Thermo FisherCatalog #F13838 were used. These beads can also be used to ensure the performance of the instrument is consistent across experimental runs for FSC and SSC measures (see image).
Calculating cell size and metrics
Calculating cell size and metrics
Using the FSC measure of the size beads and the known diameters, create a linear equation to approximate spherical size of the diatom cells. Use the median FSC value based on a minimum of 200 cells but ideally 2000 or more.
e.g. Spherical size = (FSC +275,549)/83,539
Spherical size may also be considered as "equivalent spherical diameter" or ESD, as the diatom cells are not actually spherical in shape.
For other metrics (granularity and chlorophyll-a), units are given as relative fluoresence units (RFU) from the flow cytometer, which can be used for comparative purposes between samples. Again, the median value is used from a minimum of 200 cells.
It is recommended that these values be corrected against cell size (ESD), as these traits are directly correlated with cell size, so it may be useful to assess these traits independent of size.