Flow sorting and culture of plant protoplasts

Conditions have been established for the rapid flow analysis of leaf protoplasts of Nicotiana tabacum L. cv. Xanthi using a flow cytometer-cell sorter. A procedure based upon chlorophyll autofluorescence was devised to permit the systematic evaluation of flow conditions in order to identify those under which protoplast damage was minimized. These conditions were employed for the flow sorting of protoplasts, following which it was possible to regenerate the sorted protoplasts into complete plants. The application of flow sorting is discussed for the rapid identification and selection of somatic hybrids produced by protoplast fusion.     

Analysis of viability and cell types of macroalgal protoplasts using flow cytometry

The ability to rapidly distinguish viable sub-populations of cells within populations of macroalgal protoplast isolations was demonstrated using flow cytometry. Viable protoplasts from Ulva sp. and Porphyra perforata J. Ag. were distinguished from non-viable protoplasts based on differential fluorescein accumulation. The identities of cortical and epidermal protoplasts from Macrocystis pyrifera (L.) C. Ag. were inferred based on light-scattering and chlorophyll a autofluorescence. Three cell types could be distinguished among protoplasts released from thalli of P. perforata based on chlorophyll a and phycoerythrin autofluorescence. Mixed protoplast populations of Ulva sp. and P. perforata were also discernable based on relative chlorophyll a and phycoerythrin autofluorescence. The ability to screen heterogenous protoplast populations rapidly, combined with the cell sorting capabilities of many flow cytometers, should prove valuable for seaweed biotechnology.     

The characterization and isolation of plant heterokaryons by flow cytometry

Summary Plant heterokaryons were identified and isolated from a population of protoplasts following fusion. Endogenous chlorophyll autofluorescence and exogenously supplied fluorochromes were utilized to differentiate between parental and heterokaryon populations. Flow cytometric analysis detected heterokaryons based upon the simultaneous presence of both chlorophyll and an exogenously supplied fluorochrome within one cell. These parameters were utilized to sort large numbers of heterokaryons from the fusion mixture using modified flow instrumentation. Modifications to the instrumentation which allowed this sorting are discussed.     

Flow cytometry as a method for assaying the biological activity of phytotoxins

A flow cytometric method has been developed for the qualitative and quantitative evaluation of the biological activities of phytotoxins from plant pathogenic fungi. The method utilized fresh wheat (Triticum aestivum L.) leaf protoplast preparations treated with purified phytotoxins, triticone A-B and triticone D. Subsequently, protoplasts were exposed to fluorescein diacetate, and analyzed by flow cytometry. Information acquired included fluorescence owing to esterase activity on fluorescein diacetate, and chlorophyll autofluorescence. Results indicate that triticone A-B has a rapid dose-dependent toxic effect on wheat protoplasts but triticone D has no toxic effect. This method can also yield information on the mechanism of action of phytotoxins that are relatively unstable or available only in small quantities.     

Viable sorting of intact multicellular spheroids by flow cytometry

A flow cytometric method has been developed for sorting viable, intact multicellular spheroids in order to obtain uniformly-sized populations with diameters in the range of 50-100 microns. A FACS II instrument was modified for this purpose by installing a 200-microns-diameter exit orifice and by making adjustments in the sheath flow, oscillator frequency, and number of droplets sorted. Polystyrene microspheres (44 and 88 microns diameter) and 41-96-microns-diameter spheroids could be sorted and recovered with 70-100% efficiency, an improvement over previous reports. Unstained, viable spheroids were simultaneously analyzed for small-angle forward light scatter, 90 degree light scatter, and autofluorescence using a 488-nm laser operating at 100 mW. Analysis of the data demonstrated a considerable variation in both the 90 degrees light scatter and the autofluorescence signals for a given forward angle light scattering signal. By setting narrow sort windows on the forward angle light scattering signal and either the 90 degree light scatter or autofluorescence signals, uniformly spherical spheroid populations could be recovered. These sorted populations had coefficients of variation of the mean diameter in the range of 5-9%. This represents a variation of less than one cell diameter, and is a major improvement over any other technique. There was no significant difference in the subsequent growth rates of sorted spheroids compared to the unsorted spheroids. This technique will apply when uniform populations of small spheroids are required, such as investigations of the contact effect or in the initiation of growth curve studies.     

Flow cytometry and sorting of protoplasts from carrot cell cultures reveal two cell subpopulations with different morphogenetic potential

Microscopic and flow cytometric analysis of protoplasts derived from carrot (Daucus carota L.) cells in culture revealed two different cellular subpopulations that differ in their light-scattering properties and in the emission of red autofluorescence. The two subpopulations were sorted on the basis of scattering properties and cultured independently. Subpopulation 1, characterized by higher side scattering (SS) values, had a higher cytoplasm/vacuole ratio and developed numerous proembryogenic masses (PEMs). Sorted on the basis of its lower SS values, subpopulation 2 was characterized by more vacuolated cells with higher red autofluorescence and was unable to develop PEMs.     

Optimization of flow cytometric detection and cell sorting of transgenic Plasmodium parasites using interchangeable optical filters

ABSTRACT: BACKGROUND: Malaria remains a major cause of morbidity and mortality worldwide. Flow cytometry-based assays that take advantage of fluorescent protein (FP)-expressing malaria parasites have proven to be valuable tools for quantification and sorting of specific subpopulations of parasite-infected red blood cells. However, identification of rare subpopulations of parasites using green fluorescent protein (GFP) labelling is complicated by autofluorescence (AF) of red blood cells and low signal from transgenic parasites. It has been suggested that cell sorting yield could be improved by using filters that precisely match the emission spectrum of GFP. METHODS: Detection of transgenic Plasmodium falciparum parasites expressing either tdTomato or GFP was performed using a flow cytometer with interchangeable optical filters. Parasitaemia was evaluated using different optical filters and, after optimization of optics, the GFP-expressing parasites were sorted and analysed by microscopy after cytospin preparation and by imaging cytometry. RESULTS: A new approach to evaluate filter performance in flow cytometry using two-dimensional dot blot was developed. By selecting optical filters with narrow bandpass (BP) and maximum position of filter emission close to GFP maximum emission in the FL1 channel (510/20, 512/20 and 517/20; dichroics 502LP and 466LP), AF was markedly decreased and signalbackground improve dramatically. Sorting of GFP-expressing parasite populations in infected red blood cells at 90 or 95% purity with these filters resulted in 50-150% increased yield when compared to the standard filter set-up. The purity of the sorted population was confirmed using imaging cytometry and microscopy of cytospin preparations of sorted red blood cells infected with transgenic malaria parasites. DISCUSSION: Filter optimization is particularly important for applications where the FP signal and percentage of positive events are relatively low, such as analysis of parasite-infected samples with in the intention of gene-expression profiling and analysis. The approach outlined here results in substantially improved yield of GFP-expressing parasites, and requires decreased sorting time in comparison to standard methods. It is anticipated that this protocol will be useful for a wide range of applications involving rare events.     

Relation between protoplast division,cell-cycle stage and nuclear chromatin structure

Summary Using different sources of protoplasts and two complementary techniques, flow cytometry and image analysis, to study the cell-cycle phases, we sought to define the particular protoplast state associated with the disposition to divide. Both inPetunia and inNicotiana plumbaginifolia, tissues with a higher G2 frequency (from different aged plants) yielded protoplasts capable of increased cell division. InSorghum, the age of the plant does not modify the proportion of G2 nuclei in leaf protoplasts, and we used root protoplasts to increase G2 frequencies. InHelianthus annuus, leaf protoplasts did not divide; however, hypocotyl protoplast preparations with relatively high 4C DNA frequencies do divide. Moreover, image analysis of chromatin structure indicated that leaf nuclei were in the G0 phase, unlike those from hypocotyls which were in G1. A high frequency of protoplasts with G2 nuclei appears to be correlated with the ability of a given preparation to undergo division; conversely, the differentiated G0 state is not conducive to division.     

Isolation,sorting, and characterization of uni- and binucleate tapetal protoplasts from anthers of normal and Texas cytoplasmic male-sterileZea mays L.

Summary A cytological study of Texas cytoplasmic male sterile (Tcms) and normal (N) anther tapetal protoplasts ofZea mays was undertaken to determine whether there were any differences prior to Tcms male cell abortion not noted in previous published studies. Squash preparations, tapetal protoplast separation via flow cytometry, image analysis, and electron microscopy were utilized. Chemically preserved tapetal protoplasts from both lines were prominently angular in shape and typically smaller than any other cell type in the anthers. The tapetum from both lines consisted of a mixture of uninucleate and binucleate protoplasts. The Tcms tapetum consistently had a higher proportion of binucleate protoplasts during all stages of microsporogenesis prior to abortion. The size of Tcms uniand binucleate tapetal protoplasts was more variable than the N tapetal protoplasts and was largest during the microspore stage when male cells abort. Tapetal nuclear size in both lines was less variable. Uni- and binucleate tapetal protoplasts from each line could be separated from the other anther cells and from each other by filtration and then by flow cytometry, based on intensity of nuclear fluorescence. These results suggest that Tcms uninucleate tapetal protoplasts have a higher level of DNA than N uninucleate tapetal protoplasts. Both fluorescence microscopy and electron microscopy confirmed pure populations of intact uni- and binucleate tapetal protoplasts using flow cytometry. The results from this study indicate that the methodology presented here could be used for a variety of further studies to better understand the cellular and molecular basis of male sterility in maize, and in other taxa, where the tapetum is the primary target that leads to male sterility.Abbreviations AO acridine orange - Bi binucleate protoplast - D dyad - DAPI 4,6-diamidino-2-phenylindole - FC flow cytometry - M meiocyte - MI microspore - MMC mithramycin - N normal anther tapetal protoplast - PI propidium iodide - PS protoplast sorting - RT room temperature - SM sporogenous mass - Tems Texas cytoplasmic male sterile anther tapetal protoplast - Uni uninucleate protoplast     

Selection and enrichment of plant protoplast heterokaryons of Brassicaceae by flow sorting

The experimental conditions for an efficient and reproducible enrichment of fusion products by flow cytometry, using protoplasts of different Brassica species as hybridization material, have been investigated. The heterokaryons were identified by the endogenous chlorophyll autofluorescencence of mesophyll protoplasts of one parent and the fluorescense of exogenously supplied carboxyfluorescin to the hypocotyl protoplasts of the other parent. By using a low head drive frequency (11 kHz), a large nozzle (110 μm) and a low nozzle pressure (30–35 kPa) good survival of the protoplasts was obtained after sorting. Heterokaryons were sorted using these parameters and on average 80% of the protoplasts were fusion products as judged by microscopy. They were cultured in small volumes, 150 μl, and started to divide after 3–5 days and regenerated calli easily. Isozyme analysis of the calli confirmed that 81% had the pattern typical for a hybrrid. Differentiation into shoots have been obtained from some of the hybrid calli; these shoots were also confirmed to be true hybrids.     

Allantoinase activity and ureide content of mesophyll and paraveinal mesophyll of soybean leaves

Paraveinal mesophyll (PVM) is a specialized soybean (Glycine max Merr.) leaf tissue which represents a significant biochemical compartment. Stereological measurements showed that PVM makes up 23% of the mesophyll volume in nodulated soybean. To get an indication of the extent of involvement of PVM in ureide metabolism, physical characteristics, distribution of allantoinase activity and ureide content were determined in isolated PVM protoplasts (PVMP) and mesophyll protoplasts (MP). PVMP were larger and contained less chlorophyll and protein than MP. PVMP had twice as much allantoinase activity per protoplast but only half as much allantoinase activity when expressed on a volume basis as compared to MP. Total leaf ureide concentration was high and nearly equally distributed between MP and PVMP. PVMP had a higher ureide content per protoplast, a higher concentration of allantoic acid and a lower ratio of allantoin to allantoic acid. These results suggest that both tissues have the capacity to assimilate allantoin in vivo. The data are discussed with reference to the relative access of the two mesophyll tissues to incoming ureides.     

The production of clonal and axenic cultures of microalgae using fluorescence-activated cell sorting

Unialgal cultures of the flagellate algae Cyanophora paradoxa, Haematococcus lacustris, Monomastix sp., Scherffelia dubia and Spermatozopsis similis which contained bacteria were sorted by flow cytometry to obtain axenic clonal cultures. The variables used for fluorescence-activated cell sorting (FACS) were chlorophyll autofluorescence, forward scatter and side scatter of the laser beam. To produce clonal cultures, a single cell was sorted into each culture flask. Depending on the species, about 20–30% of the sorted cultures grew successfully and at least 20% of these were axenic even if the numerical ratio betweeen bacteria and algae in the original cultures was as high as 300:1. FACS represents an effective and rapid method for the preparation of clonal and axenic cultures of microalgae.     

Flow cytometric measurement of pollutant stresses on algal cells

The lichen Usnea fulvoreagens (R?s). R?s. was treated with four pH levels (5.5, 4.5, 3.5, and 2.5) of simulated acid rain (sulfuric acid, nitric acid, and a 1:1 combination of both) and automobile exhaust. The samples were dissociated and analyzed by a Becton-Dickinson FACS 440 flow cytometer. Analyses included measurement of chlorophyll autofluorescence and fluorescence due to uptake of fluorescein diacetate (FDA) and calcofluor white M2R (CFW). Cell parameters measured were esterase activity (FDA), membrane permeability (FDA, CFW), and intracellular pH (FDA). Mean fluorescence intensity from FDA staining and numbers of events were incorporated with autofluorescence information to produce a "stress index" of relative cell stress. Results indicated that highly stressed samples (lower pH treatments and greater exposure to exhaust) exhibited a low "stress index" of FDA fluorescence.     

Phosphate accumulation in leaves of wheat seedlings measured in leaf cell protoplasts isolated after root or foliar treatment with orthophosphate

Leaf cell protoplasts were isolated from wheat seedlings ( Triticum aestivum L. cv. Urquie) after orthophosphate (Pi) treatment of the plant to determine the capacity for intracellular phosphate accumulation. Seedlings were treated with Pi concentrations near the phytotoxic level to maximize the Pi concentration in the leaf prior to protoplast isolation 1 day later. Both foliar and root treatment of seedlings with Pi increased the phosphate content of leaf protoplasts by approximately 20 μmol (mg chlorophyll)⁻¹ over Pi levels in untreated controls. Phosphate-loaded protoplasts from treated seedlings had similar photosynthetic rates and starch content but 50% more soluble reducing sugar than protoplasts from untreated seedlings. Protoplast dark respiration decreased after treatments which increased protoplast potassium content. The results suggest that similar amounts of Pi can be accumulated by leaf cells of wheat after foliar or root application of Pi to the seedling without hindering Pi-sensitive processes such as photosynthesis and starch synthesis.     

Correlation between the inhibition of photosynthesis and the decrease in area of detached leaf discs or volume/absorbance of protoplasts under osmotic stress in pea (Pisum sativum)

Exposure to osmotic stress reduces leaf area and protoplast volume while decreasing photosynthesis. But the measurement of protoplast volume is tedious, while rapid determinations of leaf area in the field are difficult. We evaluated the quantitative relationship between the extent of decrease in area of detached leaf discs or the volume of protoplast of pea ( Pisum sativum ) and reduction in their photosynthetic capacity under osmotic stress. Osmotic stress was induced by increasing sorbitol concentration in the surrounding medium of the leaf discs from zero to 1.0 M (-3.1 MPa), and in case of protoplasts from 0.4 M (-1.3 MPa, isotonicity) to 1.0 M (-3.1 MPa, hypertonicity). There was a high degree of positive correlation between the extent of reduction in the area of detached leaf discs or the volume of protoplasts (indicated by diameter or absorption at 440 nm) and the decrease in photosynthesis. The correlation coefficients between inhibition of photosynthesis and the decrease in leaf disc area or protoplast volume were 0.96 and 0.99, respectively. We therefore suggest that the decrease in absorbance at 440 nm (corrected for turbidity at 750 nm) can be used as a simple measure to predict the inhibition due to osmotic stress of photosynthesis in mesophyll protoplasts. Similarly, the reduction in area of detached leaf discs could also be a very simple and useful criterion to assess osmotic tolerance of photosynthesis.     

Antibodies to cell-surface antigens of plant protoplasts

Both mouse and rabbit polyclonal antibodies to plant cell-surface antigens were developed by immunization with cell membrane material from oat (Avena sativa L. cv. Garry) roots. We were able to quickly assess the activity of antisera by monitoring the degree of protoplast agglutination and by using an indirect immunofluorescence assay. Using polyclonal antibodies to cell-surface antigens, we have found that oat root protoplasts share common surface antigens with protoplasts from other plant tissues and species. From experiments with antisera treated with excess oat leaf or oat root protoplasts before our immunoassays, we have obtained evidence for the existence of organ-specific cell-surface antigens in higher plants.     

Phytochrome-mediated swelling of etiolated leaf protoplasts and its possible biological significance

Summary Red light, mediated by the photoreceptor phytochrome, induces maize leaf unrolling as well as leaf expansion. Protoplasts prepared from maize leaves still in the rolled condition swell in a red-far red photoreversible manner indicating that phytochrome mediates this phenomenon. To determine if protoplast swelling is related to leaf unrolling, leaf expansion, or both, we compared red-light induced swelling of protoplasts from rolled maize leaves to protoplasts prepared from tissues that are known to grow in response to light but do not unroll. We also compared the swelling response of protoplasts from rolled vs. unrolled leaves. In all cases, we found that swelling correlated with the unrolling response and not leaf expansion.     

Flow sorting and culture of protoplasts: Conditions for high-frequency recovery,growth and morphogenesis from sorted protoplasts of suspension cultures of nicotiana

Protoplasts were prepared from suspension cultures of Nicotiana tabacum cv Wisconsin 38 that had been prelabeled with FITC. The protoplasts were subjected to flow sorting based on fluorescence content using a Coulter EPICS V Flow Cytometer — Cell Sorter. Conditions were established that allowed the recovery after sorting of approximately 30% of the initial protoplasts in a viable state. These were subsequently regenerated into calli that underwent shoot morphogenesis.Abbreviations FITC Fluorescein isothiocyanate - FDA fluorescein diacetate