Nanoscale flow cytometry (NFC), also called flow virometry, is an adaptation of flow cytometry technology for the analysis of individual submicron-sized particles.
Size and fluorescence standards are essential for the set-up, optimization, and quality control of flow cytometers. These calibration standards are critical for standardized data acquisition between laboratories, instruments, and technological platforms.
There are currently no size standards that accurately portray the refractive indices of extracellular vesicles (EVs) and viruses, or the level of fluorescence that is achievable on biological particles. As shown in
Using synthetic bead standards as a tool to measure relative particle size by side scattered light (SSC) or by forward scattered light (FSC) results in a significant underestimation of the actual size of the biological particles when analyzed by flow cytometry.
The analysis of particles in the nanometer size range (e.g., 90-200 nm) is challenging because the size of the particles is at the limit of detection of current flow cytometers. In fact, published specifications for cytometers indicate that 200 nm is the limit of detection. In practice, however, this detection limit is lower, but extensive optimization of assays, and careful set-up and calibration of the cytometers are required to achieve this range.
It would therefore be desirable to develop standards for NFC.
It is an object of the present disclosure to obviate or mitigate at least one disadvantage of previous approaches.
In a first aspect, the present disclosure provides a recombinant nucleic acid encoding a modified gammaretrovirus the recombinant nucleic acid comprising: a mutation that reduces or abolishes expression of the viral glyco-Gag protein, and a nucleic acid encoding a fluorescent protein inserted in-frame into the proline-rich region (PRR) of the viral env protein.
In a second aspect, there is provided a use of enveloped virus particles, wherein the virus particles are fluorescent, as a size or calibration standard in nanoscale flow cytometry.
In a third aspect, there is provide a method of calibrating a flow cytometer comprising: measuring a calibration standard comprising enveloped virus particles, wherein the virus particles are fluorescent, in nanoscale flow cytometry.
In a fourth aspect, there is provided a flow cytometry method comprising: measuring a size standard comprising enveloped virus particles, wherein the virus particles are fluorescent, in nanoscale flow cytometry.
In another aspect, there is provided a method of detecting particles by nanoscale flow cytometry, the method comprising calibrating a flow cytometer with a control sample comprising enveloped virus particles as described herein, and, following calibration, detecting particles in a sample by nanoscale flow cytometry.
In another aspect, there is provided a method of detecting viral particles or extracellular vesicles comprising at least one marker, the method comprising calibrating a flow cytometer with a control sample comprising enveloped virus particles as described herein, and detecting viral particles or extracellular vesicles comprising the at least one marker in a sample by nanoscale flow cytometry.
In another aspect, there is provided a method of enumerating markers on microparticles by nanoscale flow cytometry, the method comprising calibrating a flow cytometer with a control sample comprising enveloped virus particles as described herein, and, following calibration, enumerating markers on microparticles of a sample by nanoscale flow cytometry.
In another aspect, there if provided a method of enumerating markers on viral particles or extracellular vesicles, the method comprising calibrating a flow cytometer with a control sample comprising enveloped virus particles as described herein, and enumerating markers on viral particles or extracellular vesicles in a sample by nanoscale flow cytometry.
In another aspect, there is provided a size standard or calibration ladder for nanoscale flow cytometry, comprising a plurality of types of enveloped virus particles, each of the enveloped particles being fluorescent, wherein each of the types of virus particles is of a different size.
In another aspect, there is provided a method of producing fluorescent enveloped virus particles comprising at least one selected marker, the method comprising: infecting a host cell expressing the at least one selected marker with enveloped virus particles, and recovering enveloped virus particles produced by the infected host cell, wherein the recovered enveloped virus particles comprise the at least one selected marker, and wherein the recovered enveloped virus particles are fluorescent.
Other aspects and features of the present disclosure will become apparent to those ordinarily skilled in the art upon review of the following description of specific embodiments in conjunction with the accompanying figures.
Embodiments of the present disclosure will now be described, by way of example only, with reference to the attached Figures.
Generally, the present disclosure provides fluorescent enveloped virus particles for use as a size or calibration standard in nanoscale flow cytometry. The standards may be used as controls in some applications.
Also described is a recombinant nucleic acid encoding a modified gammaretrovirus, the recombinant nucleic acid comprising a mutation that abolishes expression of the viral glyco-Gag protein, and a nucleic acid encoding a fluorescent protein inserted in-frame into the proline-rich region (PRR) of the viral env protein.
In one aspect, there is provided a recombinant nucleic acid encoding a modified gammaretrovirus the recombinant nucleic acid comprising: a mutation that reduces or abolishes expression of the viral glyco-Gag protein, and a nucleic acid encoding a fluorescent protein inserted in-frame into the proline-rich region (PRR) of the viral env protein.
By “gammaretrovirus” will be understood as members of the eponymous genus of the retroviridae family. Examples includes those viruses known as CAS-BR-E, MLV 1313 (Amphotropic MLV), Pmv11 (Polytropic MLV), Xmx15 (Xenotropic MLV), FrMLV (Friend MLV), M-MLV (Moloney MLV), DG-75, AKV MLV (AKV MLV), SL3-3 MLV, E-MLV (Ecotropic MLV), Rauscher MLV, Mus Dunni endogenous virus, Abelson MLV, or XMRV. The term will be understood to encompass relative viruses having, e.g. 80%, 90%, 95%, 98%, or 99% sequence identify to any member of the gammaretrovirus family.
By “recombinant” is meant a nucleic acid that has been genetically altered, e.g., by the addition or insertion of a heterologous nucleic acid that is not present in the natural sequence.
By “mutation that reduces abolishes expression of the viral glyco-Gag protein” is meant any suitable sequence change that results in a relative reduction or reduction to undetectable levels (respectively), of the extended form of Gag, termed glyco-Gal (gPr80), that is characteristic of gammaretroviruses. The viral glyco-gag can be readily identified, e.g. by sequence conversation (e.g., homology) with glyco-Gal (gPr80) of M-MLV.
By “fluorescent protein” is meant a protein that absorbs light of a specific wavelength (e.g., absorption wavelength) and emits light with a longer wavelength (e.g., emission wavelength). The term fluorescent protein encompasses natural fluorescent proteins (i.e., the natural form of the fluorescent protein without any genetic manipulations) and genetically mutated fluorescent proteins (e.g., fluorescent proteins engineered to change the identity of one or more amino acid residues). Fluorescent proteins include, but are not limited to, green fluorescent proteins (e.g., GFP, enhanced GFP (eGFP), Emerald, Superfolder GFP, Azami Green, mWasabi, TagGFP, TurboGFP, AcGFP, ZsGreen, T-Sapphire, and T-Sapphire), blue fluorescent proteins (e.g., EBFP, EBFP2, Azurite, mTagBFP), cyan fluorescent proteins (e.g., ECFP, mECFP, Cerulean, CyPet, AmCyan1, Midori-Ishi Cyan, TagCFP, mTFP1 (Teal)), yellow fluorescent proteins (e.g., EYFP, Topaz, Venus, mCitrine, YPet, TanYFP, PhiYFP, ZsYellow1, and mBanana), orange fluorescent proteins (e.g., Kurabira Orange, Kurabira Orange2, mOrange, mOrange2, dTomato, dTomato-Tandem, TagRFP, TagRFP-T, DsRed, DsRed2, DsRed-Express (T1), DsRed-Monomer, and mTangerine), and red fluorescent proteins (e.g., mRuby, mApple, mStrawberry, AsRed2, mRFP1, JRed, mCherry, HcRed1, mRaspberry, dKeima-Tandem, HcRed-Tandem, mPlum, and AQ143).
In one embodiment, the fluorescent protein is green fluorescent protein (GFP). “GFP” will be understood to refer to the green fluorescent protein from the jellyfish, Aequorea victoria. The fluorescent protein may also be a GFP derivative, for example, comprising one or more mutation that enhances fluorescent relative to the parent GFP. In one embodiment, the fluorescent protein may be enhanced green fluorescent protein (eGFP). “eGFP” will be understood to comprise an F64L mutation, yielding improved characteristics, such as extinction coefficient and quantum yield.
A skilled person would readily appreciate that a nucleic acid encoding a fluorescent protein could comprise sequence changes that do not substantially reduce or abrogate fluorescence. This could be readily tested.
By “inserted” is meant cloned into the proline-rich region in an in-frame manner.
By “in frame” is meant that the coding sequence for the fluorescent protein will be cloned in the same reading frame as the env protein into which it is inserted. The manner of cloning will be understood to permit the fluorescent protein to be expressed and to properly fold and achieve its fluorescent character. The fluorescent protein may be linked by an appropriate spacer.
In one embodiment, the modified gammaretrovirus is CAS-BR-E, MLV 1313 (Amphotropic MLV), Pmv11 (Polytropic MLV), Xmx15 (Xenotropic MLV), FrMLV (Friend MLV), M-MLV (Moloney MLV), DG-75, AKV MLV (AKV MLV), SL3-3 MLV, E-MLV (Ecotropic MLV), Rauscher MLV, Mus Dunni endogenous virus, Abelson MLV, XMRV, Porcine endogenous type C, Gibbon leukemia virus, Baboon endogenous virus strain M7, Feline leukemia virus, Koala retrovirus, or Wooly monkey virus. The recombinant nucleic acid may comprise a nucleic acid encoding one of these viruses, for example, as listed in Table 1 by GenBank Accession Number.
In one embodiment, the recombinant nucleic acid may comprise a nucleic acid having a sequence that is at least 80% identical to one of the references sequences in Table 1. In one embodiment, the recombinant nucleic acid may comprise a nucleic acid having a sequence that is at least 85% identical to one of the references sequences in Table 1.In one embodiment, the recombinant nucleic acid may comprise a nucleic acid having a sequence that is at least 90% identical to one of the references sequences in Table 1. In one embodiment, the recombinant nucleic acid may comprise a nucleic acid having a sequence that is at least 95% identical to one of the references sequences in Table 1. In one embodiment, the recombinant nucleic acid may comprise a nucleic acid having a sequence that is at least 98% identical to one of the references sequences in Table 1. In one embodiment, the recombinant nucleic acid may comprise a nucleic acid having a sequence that is at least 99% identical to one of the references sequences in Table 1.
In one embodiment, the modified gammaretrovirus is a modified Moloney murine leukemia virus (M-MLV), wherein the mutation reduces or abolishes expression of gPr80 protein.
In one embodiment, the recombinant nucleic acid comprises a nucleic acid sequence derived from GenBank Accession NCBI: NC_001501, modified with said mutation and said nucleic acid encoding fluorescent protein. It will be appreciated that this GenBank entry is annotated, permitting its features to be readily identified. For example, where viral proteins are named with respect to M-MLV, a skilled person would appreciate that these proteins correspond to those annotated in NC_001501.
By “derived from”, a skilled person would appreciate that the recombinant nucleic acid could comprise sequence changes relative to this reference sequence to the extent that they do not negatively impact the assembly the viral particles for the intended application. An example would be silent mutations in coding regions that do not impact coding, transcription, or translation. Conservative amino acid changes (e.g. resulting in amino acids with similar side chain chemistry) could also be encompassed. The recombinant nucleic acid so derived could, for example comprise a sequence that has 80%, 85%, 90%, 91%, 92%, 93%, 94%, 95%, 96%, 97%, 98%, 99% sequence identity to NC_001501 across the full length thereof. The recombinant nucleic acid so derived could encode the proteins encoded by NC_001501, with or without amino acid sequence differences.
In one embodiment, the recombinant nucleic acid comprises the nucleic acid sequence of GenBank Accession NCBI: NC_001501, modified with said mutation and said nucleic acid encoding fluorescent protein.
In one embodiment, the mutation that reduces or abolishes expression of gPr80 is in the CTG codon at positions 93-95 of NC_001501. In one embodiment, the mutation that reduces abolishes expression of gPr80 is a CTG→CTA mutation. It has surprisingly been found that such a mutation increases the fluorescence of M-MLV in which the env protein is labelled with eGFP. Without being bound by theory, it is believed that reduction abrogation of gPr80 expression from the CTG alternate start codon leads to more expression of env-eGFP, and/or greater incorporation of the env-eGFP into the viral particles. It is expected that other sequences change to reduce or abrogate translation from the CTG at positions 93-95 (or otherwise reduce expression of gPr80) would produce similar effects. Likewise, it is expected that mutations in other gammaretroviruses that reduce or abolish expression of the glyco Gal-pol would have similar effects. These mutation may be in the start codon from which transcription of the glyco Gal-pol is initiated. These mutations may be in the codon corresponding to positions 93-95 of M-MLV, which would be readily identifiable, e.g., by sequence alignment.
By “proline-rich region” will be understood the flexible area of the viral env protein. The proline rich region corresponds to the region encoded by nucleotide positions 6299 to 6435 of NC_001501. For other gammaretroviruses, a corresponding region or position for insertion could be readily identified by sequence alignment with NC_001501.
In one embodiment, the PRR of the viral env protein corresponds to the region encoded by nucleotide positions 6302 to 6433 of GenBank Accession NCBI: NC_001501.
In one embodiment, the fluorescent protein is inserted into the PRR after the serine at position 6400.
In one embodiment, there is provided a vector comprising the above-described nucleic acid.
By “vector” is meant any genetic element, such as a plasmid, phage, transposon, cosmid, chromosome, virus, virion, etc., which is capable of replication when associated with the proper control elements and which can transfer gene sequences into or between cells. Thus, the term includes cloning and expression vehicles, as well as viral vectors.
In one aspect, there is provided a host cell comprising the above-defined nucleic acid or the above-defined vector.
By “host cell” is meant a cell or population of cells into which the recombinant nucleic acid has been introduced. In certain embodiments, a host cell of the present invention is a eukaryotic cell or cell line, for example, a plant, animal, vertebrate, mammalian, rodent, mouse, primate, or human cell or cell line. Any suitable host cells which will support propagation of or expression from a given recombinant nucleic acid is intended. The host cell may be, e.g., transiently or stably transfected, or infected such that it comprises the nucleic acid or vector. The recombinant nucleic acid may be integrated into the genome of the host cell.
In one embodiment, the host cell comprises at least one selected marker. The purpose of having a host cell comprising a marker, in some embodiments, is to facilitate uptake of the at least one selected marker by viruses that egress from the host cell, thus permitting recovery of viral particles comprising the at least one selected marker.
By “marker” will be understood any molecule or protein whose presence can be detected. Such a molecule may be detectable, e.g. by immunological methods (e.g. antibodies) or by staining. The markers may be part of, associated with, or otherwise derived from any membrane of a cell, such as the outer cell membrane or an intracellular membrane.
Examples of the latter include organelle and vesicle membranes, such as endocytic vesicle membranes. Accordingly, a “marker” may be, e.g. an endocytic marker. Example markers include proteins, phospholipids, glycoproteins, or receptors. Markers may be membrane components, membrane-anchored components, membrane-associated components, membrane-spanning components, or membrane derived components.
In one embodiment, the at least one selected marker may be characteristic of a particular cell type or cellular state. In one embodiment, the at least one selected marker may be operationally specific to a particular cell type or cellular state. “Operationally unique” is intended to mean distinguishable in the context of the sample with the detection means employed. In one embodiment, the at least one selected marker may be unique to a particular cell type or cellular state.
In one embodiment, the at least one selected marker comprises a plurality of markers of a selected profile. By “profile” will be understood a particular set of markers.
In one embodiment, the selected profile may be characteristic of a particular cell type or cellular state. In one embodiment, the selected profile may be operationally specific to a particular cell type or cellular state. In one embodiment, the selected profile may be unique to a particular cell type or cellular state.
By employing host cells that comprise the at least one marker, viral particles that egress from the host cell may take up the at least one marker. As discussed, the at least one marker need not be limited to markers that are part of or associated with the outer membrane. The cell-derived envelope of enveloped viruses may also, in some instances, comprise, e.g., endocytic vesicle membranes, and thereby may comprise proteins and/or lipids found therein. This is a result of their release through the endocytic secretion pathways shared by exosomes. Accordingly, viruses may display endocytic makers on their surface (e.g., see. tetraspanins CD9, CD63 and CD81—see
The host cell type may be established based on a marker of interest already being expressed by that cell type (some applications may involve pseudotyping a virus in order to permit infection of the desired host cell). That is to say, the marker may be endogenous to the host cell in some embodiments. The marker may be expressed endogenously by the host cell due to a cellular state, such as a disease state.
In other embodiments, the host cell may be modified (e.g. transfected, infected, or otherwise manipulated, e.g. by CRISPR) to express an exogenous marker of interest. The host cell may be recombinant.
In some embodiments, the at least one marker may be modified to increase incorporation into the viral envelope upon egress, in some embodiments. For example, the at least one marker may be a recombinant protein comprising a transmembrane (TM) domain of the native viral envelope glycoprotein. In other embodiments, the marker may be modified with a membrane signal peptide In order to direct the insertion of a protein into a membrane and increase incorporation into viral particles upon egress.
In some embodiments, the at least one selected marker(s) may be characteristic of disease cells. Here, “disease cell” will be understood to indicate a cell in anything other than a healthy state. For example, the host cell may be infected with a pathogen, may be in state of inflammation, may be in an altered metabolic state, may be undergoing apoptosis, may be a pre-cancerous cell, or may be a cancer cell. The marker(s) may indicate the presence, stage, or severity of disease; or may provide information about the affected cell type (e.g., the location of an infection).
Cells of a subject could be analyzed to determine a characteristic marker or profile thereof, in order to select the at least one marker or the profile. Controls could then be generated.
In one aspect, there is provided an enveloped virus particle produced by the above-described cell.
By “enveloped virus”, as used herein, is meant a virus that has an envelope covering its protective protein capsids. Envelopes are typically derived from portions of the host cell membranes (phospholipids and proteins), but comprise some viral glycoproteins.
They may help viruses avoid the host immune system. Glycoproteins on the surface of the envelope serve to identify and bind to receptor sites on the host's membrane. The viral envelope then fuses with the host's membrane, allowing the capsid and viral genome to enter and infect the host. Non-limiting examples of enveloped virus include Herpesviruses, Poxviruses, Hepadnaviruses, Flavivirus, Togavirus, Coronavirus, Hepatitis D, Orthomyxovirus, Paramyxovirus, Rhabdovirus, Bunyavirus, Filovirus, and Retroviruses.
In one embodiment, the enveloped virus comprises the at least one selected marker.
In one embodiment, the enveloped virus comprises the plurality of markers of the selected profile.
In some embodiments, the marker(s) may be recombinant. For example, the marker(s) may be modified to increase incorporation into the viral particles, e.g. as described above.
In one aspect, there is provided a use of enveloped virus particles, wherein the virus particles are fluorescent, as a size or calibration standard in flow cytometry.
In one aspect, there are provided enveloped virus particles for use as a size or calibration standard in nanoscale flow cytometry, wherein the virus particles are fluorescent.
In one embodiment, the flow cytometry is nanoscale flow cytometry.
By ““nanoscale flow cytometry” is meant flow cytometry as applied to particles of less than 1 μm in size. The technology may be used to analyze biological molecules such as proteins, DNA and lipids inside or on the surface of individual cells. Cell components labeled with fluorescent antibodies or fluorescent reporter proteins, such as eGFP, are excited by a laser to emit light, which is then detected and its intensity measured by the flow cytometer. This provides highly quantitative information on the relative abundance of these molecules in a single cell. With advances in optics, fluidics and laser technologies, the most powerful commercial flow cytometers can now be configured and optimized to analyze microparticles, EVs and viruses in an approach called nanoscale flow cytometry or NanoFlow. This technology can provide a wealth of information on the relative sizes of EVs in a sample, distribution of sub-populations, and identify the specific protein and lipid markers on their surface. Furthermore, cell sorters with upgraded lasers and optics can also sort and isolate microparticles based on size and or fluorescence. However, most commercial flow cytometers do not come pre-configured to analyze microparticles. Hardware modifications, adjustments and optimizations may be required, as well as adaptations to, e.g., sample preparation and staining procedures for the challenges of microparticle analyses.
By “standard” will be understood a sample provided to serve as a reference. The standard may possess a pre-determined property, such as size and/or fluorescence intensity. The standard may be used to calibrate equipment, or may be run with or in parallel to a test sample, e.g., to provide a reference or benchmark. Some standards may comprise a plurality of types of enveloped virus particles, e.g. having different sizes. A standard may be designed or selected based on the nature of the test samples.
By “microparticle” is meant any particle that is less than 1 μm in size. This term can include living organisms such as small bacteria or cells, or particles that are secreted or released at the surface of cells through budding, such as extracellular vesicles.
“Extracellular vesicle” (EV) is a term used to describe small biological structures with a membranous outer layer that are released from the cells of all three domains of life: Archea, Bacteria and Eukaryota. EVs that bud from bacteria are surrounded by the same components that constitute the cell wall, such as peptidoglycans and lipopolysaccharides; whereas EVs released from eukaryotic cells are enveloped by a bilayer phospholipid structure. There are three types of submicron-sized EVs that are known to be released from eukaryotic cells: 1) microvesicles (MVs) (50 nm-1000 nm); 2) exosomes (60 nm-100nm), and 3) enveloped viruses and virus-like particles (60 nm-300 nm).
“Microvesicles” (MVs) are structures released at the plasma membrane that contain elements of the cytosol such as lipids, proteins, mRNAs and micro RNAs. The release of MVs is a natural and continuous process carried out by all types of cells. EVs carry the same surface receptors, markers and antigens as the cell from which they are released. MVs can be taken up by a recipient cell by several ways, including receptor-mediated fusion with the plasma membrane at the surface of a cell, non-specific uptake through phagocytosis or macropinocytosis, and through clathrin-, calveolin-, or lipid raft-mediated endocytosis followed by fusion with the endosomal membrane. Once the cargo of MVs is released, these molecules can alter biological functions in the recipient cell. For example, cytokines can be released that will activate the transcription of certain genes involved in immune defenses against a specific pathogen, proteins can be expressed from cargo mRNA that will induce the cell to proliferate, and miRNAs can downregulate the expression of specific proteins. These subtle modifications to a recipient cell's metabolism constitute a way for cells to communicate information and harmonize responses with cells both near and far.
“Exosomes” are also extracellular vesicles surrounded by a phospholipid bilayer which, from a biochemical standpoint, are undistinguishable from MVs. Although they are on average smaller than MVs, they also contain cell surface receptors and cytosolic proteins, lipids, mRNAs and miRNAs. The defining feature that distinguishes MVs from exosomes is their cellular origin and mode of secretion. While MVs are released by budding at the cell surface, exosomes originate from intraluminal vesicles (ILVs) located inside multivesicular bodies. Multivesicular bodies, or late endosomes, are formed by the internalization of the plasma membrane, and therefore contain cell surface markers and cytosolic components. This is where proteins are sorted before being either permanently disassembled by degradative lysosomes, or trafficked to the cell surface where ILVs are released into the extracellular space as exosomes. There are several mechanisms that have been identified that recruit specific RNAs and proteins into ILVs. This is why exosomes are often enriched in certain types of RNAs.
In one embodiment, the nanoscale flow cytometry is for measurement of particles less than 1 μm, 900 nm, 800 nm, 700 nm, 600 nm, 500 nm, 400 nm, or 300 nm in size. In one embodiment, the nanoscale flow cytometry is for measurement of particles less than 250 nm in size. In one embodiment, the nanoscale flow cytometry is for measurement of particles less than 200 nm in size. In one embodiment, the nanoscale flow cytometry is for measurement of particles less than 120 nm in size. In one embodiment, the nanoscale flow cytometry is for measurement of particles less than 100 nm in size. In one embodiment, the nanoscale flow cytometry is for measurement of particles less than 50 nm in size. In one embodiment, the particles are from 10 nm to 200 nm in size. In one embodiment, the particles are from 25 nm to 200 nm in size. In one embodiment, the particles are from 50 nm to 200 nm in size. In one embodiment, the particles are from 120 nm to 200 nm in size. In one embodiment, the particles are from 90 nm to 200 nm in size. In one embodiment, the particles are from 100 nm to 200 nm in size. In one embodiment, the particles are from 10 nm to 200 nm in size. In one embodiment, the particles are from 25 nm to 250 nm in size. In one embodiment, the particles are from 50 nm to 250 nm in size. In one embodiment, the particles are from 90 nm to 250 nm in size. In one embodiment, the particles are from 100 nm to 250 nm in size. In one embodiment, the particles are from 120 nm to 250 nm in size. In one embodiment, the particles are from 10 nm to 500 nm in size. In one embodiment, the particles are from 25 nm to 500 nm in size. In one embodiment, the particles are from 50 nm to 500 nm in size. In one embodiment, the particles are from 90 nm to 500 nm in size. In one embodiment, the particles are from 100 nm to 500 nm in size. In one embodiment, the particles are from 120 nm to 500 nm in size. In one embodiment, the particles are from 90 nm to 120 nm in size.
In one embodiment, the enveloped virus particles each comprise fluorescent dye. The dye may be a lipid-targeting dye, such as a lipid membrane-targeting dye. Examples include DID, Dil, FM4-64, fluorescent sphingolipid (Ceramide-BODIPY TR), or fluorescent phospholipid (DHPE-Rhodamine). The dye may be a protein-targeting dye. The dye may be a nucleic acid targeting dye. Examples include SYBR II (for RNA) or SYBR I (for DNA). Enveloped virus particles can be either indirectly or directly labeled with a fluorescent dye. In one embodiment, the enveloped virus particles are indirectly labelled with the fluorescent dye. “Indirect labelling” is done by staining a virus-infected cell with a fluorescent dye. Proteins and/or lipids in this cell become stained, and egress virus particles then take-up the dye by acquiring labeled proteins and lipids. In one embodiment, the enveloped virus particles are directly labelled with the fluorescent dye. “Direct labelling” is done by purifying egress virus and adding a dye directly to them. These methods of labeling viruses don't appear to be clearly defined.
In on embodiment, the enveloped virus particles each comprise one or more fluorescent protein. In one embodiment, the fluorescent protein is green fluorescent protein (GFP). In one embodiment, the fluorescent protein is enhanced green fluorescent protein (eGFP). In one embodiment, the enveloped virus particles each comprise viral envelope proteins, each labelled with the fluorescent protein.
By “labelled” it will be understood that the viral envelope protein is somehow attached, coupled, or linked to the fluorescent protein. This could be achieved, e.g., by chemical addition, or by modification of the envelope protein coding nucleic acid sequence so that it is linked to (or contains) the in-frame coding sequence for the fluorescent protein. The fluorescent protein would thus be translated and would fold to recapitulate the fluorescence of the parent protein from which it is determined. The linking could be done via a suitable spacer sequence, as necessary.
In one embodiment, each of the envelope proteins is labelled with one fluorescent protein.
In one embodiment, the viral envelope proteins are M-MLV envelope proteins.
In one embodiment, the enveloped virus particles are pseudotyped with the viral envelope proteins.
By “pseudotyped” will be understood that the enveloped virus is produced such that it incorporates a non-native or modified envelope protein. This method can be used to alter host tropism or to achieve an increased/decreased stability of the virus particles. For example, cell infected with a particular enveloped virus could be further modified to comprise a sequence encoding a pseudotyping construct expressing the non-native or modified envelope protein.
In some embodiments of the present invention, the pseudotyping is accomplished with an M-MLV envelope protein, e.g. linked to eGFP (env-eGFP), as described herein. This has been found to particularly effective for fluorescent labelling of viral particles.
In one embodiment, the viral envelope protein and the fluorescent protein are as encoded by SEQ ID NO: 1. SEQ ID NO: 1 depicts the nucleic acid coding sequence (CDS) according to one embodiment. In one embodiment, the pseudotyping is accomplished with a vector comprising the sequence of SEQ ID NO: 2. SEQ ID NO: 2 depicts the nucleic acid sequence of a vector for pseudotyping, according to one embodiment.
In one embodiment there is provided a use of a nucleic acid comprising SEQ ID NO: 1 or SEQ ID NO: 2 for pseudotyping an enveloped viral particle.
In one embodiment there is provided a method of pseudotyping an enveloped viral particle, comprising introducing, into a cell infected with an enveloped virus, a nucleic acid comprising SEQ ID NO: 1 or SEQ ID NO: 2.
In one embodiment there is provided a method of pseudotyping an enveloped viral particle, comprising introducing, into a cell comprising sequences for producing an enveloped virus, a nucleic acid comprising SEQ ID NO: 1 or SEQ ID NO: 2.
In one embodiment, the enveloped virus particles are pseudotyped to be non-infectious to humans.
In one embodiment, the enveloped virus particles are encoded by a nucleic acid comprising at least one sequence modification that reduces or abrogates expression of the endogenous viral envelope protein. Reduction of expression of endogenous viral envelope protein renders pseudotyping with a non-endogenous viral envelop protein more efficient.
The enveloped virus particles could be of any suitable virus type. In one embodiment, the enveloped virus particles comprise MLV, ALV, HIV, HSV, Influenza, and/or VSV particles. In one embodiment, the virus particles are gammaretrovirus particles. In one embodiment, the gammaretrovirus particles are CAS-BR-E, MLV 1313 (Amphotropic MLV), Pmv11 (Polytropic MLV), Xmx15 (Xenotropic MLV), FrMLV(Friend MLV), M-MLV (Moloney MLV), DG-75, AKV MLV (AKV MLV), SL3-3 MLV, E-MLV (Ecotropic MLV), Rauscher MLV, Mus Dunni endogenous virus, Abelson MLV, XMRV, Porcine endogenous type C, Gibbon leukemia virus, Baboon endogenous virus strain M7, Feline leukemia virus, Koala retrovirus, or Wooly monkey virus. In one embodiment, the enveloped virus particles comprise M-MLV particles.
In one embodiment, the enveloped virus particles are modified M-MLV particles encoded the recombinant nucleic acid as defined above.
In one embodiment, the enveloped virus particles comprise a plurality of enveloped virus types, each of the types being a different size.
By “different size”, in this context, will be understood as distinguishable as different sizes, e.g., as determined by cryo-electron microscopy (cryo-EM). Cryo-EM methods are described, for example, in by Yeager et al. (1998).67
In one embodiment, the enveloped virus particles are of a single virus type.
In one embodiment, the enveloped virus comprises at least one selected marker (e.g., as defined above). In one embodiment, the at least one selected marker may be characteristic of a biological parameter. In one embodiment, the at least one selected marker may be characteristic of a particular cell type or cellular state. In one embodiment, the at least one selected marker may be operationally specific to a particular cell type or cellular stateln one embodiment, the at least one selected marker may be unique to a particular cell type or cellular state.
In one embodiment, the enveloped virus comprises a plurality of markers of the selected profile (e.g. as defined above). In one embodiment, the selected profile may be characteristic of a biological parameter. In one embodiment, the selected profile may be characteristic of a particular cell type or cellular state. In one embodiment, the selected profile may be operationally specific to a particular cell type or cellular state. In one embodiment, the selected profile may be unique to a particular cell type or cellular state.
In some embodiments, the at least one marker may be modified to increase incorporation into the viral envelope upon egress, in some embodiments. For example, the at least one marker may be a recombinant protein comprising the transmembrane (TM) domain of the native viral envelope glycoprotein. In other embodiments, the marker may be modified with a membrane signal peptide In order to direct the insertion of a protein into a membrane and increase incorporation into viral particles upon egress.
In some embodiments, the at least one selected marker(s) may be characteristic of disease cells. For example, marker may be indicative of infection with a pathogen, a state of inflammation, an altered metabolic state, apoptosis, pre-cancer, or cancer. The marker(s) may indicate the presence, stage, or severity of disease; or may provide information about the affected cell type (e.g., the location of an infection).
In some embodiments, the size or calibration standard is a control for detection of viral particles or extracellular vesicles. In some embodiments, the control may be a negative control. In some embodiments, the control may be positive control. In some embodiments, the positive control may be for the detection of viral particles or extracellular vesicles comprising the same at least one selected marker. In some embodiments, the size or calibration standard is a positive control for detection of viral particles or extracellular vesicles comprising the same plurality of markers of the selected profile.
Where “same” is referred to it in this context will be appreciated that is to be viewed from the perspective of detection. That is to say, viral particles comprising recombinant marker(s) could be used as controls for the detection of viral particles or extracellular vesicles comprising the “same” markers, even if the detected markers are not themselves recombinant.
In one embodiment, the control is for enumeration of markers on microparticles of interest (e.g. EVs or viruses). By comparing to calibrated international control Molecules of Equivalent Soluble Fluorophores (MESF) bead standard having a defined number of florescent particles, e.g., as established by the National Institute of Standards and Technology (NIST), the number of fluorescent markers on viral particles of the control may be established, e.g. by linear regression. Thereafter, the control may be used as an “MESF surrogate” to enumerate markers on microparticles from a sample. For example, in some applications markers on microparticles and the markers on the MESF surrogate control could be labelled with the same fluorophore, e.g. by binding of a fluorescent antibody.
In one aspect, there is provided a method of calibrating a flow cytometer comprising: measuring a calibration standard comprising enveloped virus particles, wherein the virus particles are fluorescent, in nanoscale flow cytometry.
In one aspect, there is provided a flow cytometry method comprising: measuring a size standard comprising enveloped virus particles, wherein the virus particles are fluorescent, in nanoscale flow cytometry.
In some embodiment, the enveloped virus particles comprise a fluorescent dye.
In some embodiment, the enveloped virus particles comprise a fluorescent protein.
In some embodiments, the step of measuring comprises measuring enveloped virus particles as described above. In some embodiments, the step of measuring comprises measuring enveloped virus particles comprising particles encoded by the recombinant nucleic acid as described above.
In one aspect, there is provided a method of detecting particles by nanoscale flow cytometry, the method comprising calibrating a flow cytometer with a control sample comprising enveloped virus particles as described herein, and, following calibration, detecting particles in a sample by nanoscale flow cytometry.
In one aspect, there is provided a method of detecting viral particles or extracellular vesicles comprising at least one marker, the method comprising calibrating a flow cytometer with a control sample comprising enveloped virus particles as described herein, and detecting viral particles or extracellular vesicles comprising the at least one marker in a sample by nanoscale flow cytometry.
In one aspect, there is provided a method of enumerating markers on microparticles by nanoscale flow cytometry, the method comprising calibrating a flow cytometer with a control sample comprising enveloped virus particles as described herein, and, following calibration, enumerating markers on microparticles in a sample by nanoscale flow cytometry. In one embodiment, the enumeration may be accomplished by linear regression.
In one aspect, there if provided a method of enumerating markers on viral particles or extracellular vesicles, the method comprising calibrating a flow cytometer with a control sample comprising enveloped virus particles as described herein, and enumerating markers on viral particles or extracellular vesicles in a sample by nanoscale flow cytometry. In one embodiment, the enumeration may be accomplished by linear regression. In some embodiments, the markers on the control sample and viral particles or extracellular vesicles are fluorescently labelled. They may be labelled with the same fluorophore. In some embodiments, number of markers on the control sample may be determined by prior comparison to an MEF bead having a defined number of florescent particles, e.g., as established by the NIST.
In the above, in some embodiments, the sample may be from a subject. The subject may be mammalian in some embodiments. The subject may be human in some embodiments.
In some embodiments, detection of viral particles or extracellular vesicles comprising the at least one marker may be indicative of a biological parameter, such as a disease parameter. In some embodiments, a number of markers above or below a threshold value may be indicative of a biological parameters, such as a disease parameter. The biological parameter may be presence or absence of a disease. For example, the biological parameter may be cancer, pre-cancer, disease staging, disease severity, infection, inflammation, apoptosis, a metabolic state, treatment response, or affected tissue or cell type identity.
In some embodiments, the nanoscale flow cytometry is for measurement of particles less than 250 nm in size. In one embodiment, the nanoscale flow cytometry is for measurement of particles less than 200 nm in size. In one embodiment, the nanoscale flow cytometry is for measurement of particles less than 120 nm in size. In one embodiment, the nanoscale flow cytometry is for measurement of particles less than 100 nm in size. In one embodiment, the nanoscale flow cytometry is for measurement of particles less than 50 nm in size.
In one aspect, there is provided a size standard or calibration ladder for nanoscale flow cytometry, comprising a plurality of types of enveloped virus particles, each of the enveloped virus particles being fluorescent, wherein each of the types is a different size.
A “ladder” will be understood of a mixture of virus particles types having different sizes. It will be understood that the “type” refers to population of virus particles characterized by a particular size. This size would be understood as different median size, and some heterogeneity is to be expected within a single population of the same type of viral particles. Size can be determined, e.g. by cryro-EM. Each type of virus particle in the ladder in the ladder may comprise the same fluorophore, be it a dye or a fluorescent protein. Alternatively, each type of virus particle in the ladder may comprise a different fluorophore. When different, the fluorophores, for example may absorb and/or emit at different wavelengths. With a given ladder, one or more types of virus particles may comprises a dye and one or more types may comprise fluorescent proteins. Alternatively, depending on requirements, the ladders may comprise virus particle types comprising only dyes or only fluorescent proteins.
The enveloped virus particles of a ladder may comprise MLV, ALV, HIV, HSV, Influenza, and/or VSV particles. In one embodiment, the ladder may comprise gammaretrovirus particles. In one embodiment, the gammaretrovirus particles are CAS-BR-E, MLV 1313 (Amphotropic MLV), Pmv11 (Polytropic MLV), Xmx15 (Xenotropic MLV), FrMLV (Friend MLV), M-MLV (Moloney MLV), DG-75, AKV MLV (AKV MLV), SL3-3 MLV, E-MLV (Esotropic MLV), Rauscher MLV, Mus Dunni endogenous virus, Abelson MLV, XMRV, Porcine endogenous type C, Gibbon leukemia virus, Baboon endogenous virus strain M7, Feline leukemia virus, Koala retrovirus, or Wooly monkey virus. In one embodiment, the enveloped virus particles comprise M-MLV particles. In one embodiment, the ladder may comprise the virus particles listed in
In one embodiment, the virus particles are as defined above. In one embodiment, the particle comprise particles encoded by the recombinant nucleic acid as described above.
In one aspect, there is provided a method of producing fluorescent enveloped virus particles comprising at least one selected marker, the method comprising: infecting a host cell expressing the at least one selected marker with enveloped virus particles, and recovering enveloped virus particles produced by the infected host cell, wherein the recovered enveloped virus particles comprise the at least one selected marker, and wherein the recovered enveloped virus particles are fluorescent.
In this context, the term “expressing” is not intended to limit the marker to an endogenous marker. The marker may be endogenous. However, the cell may also be expressing and exogenous marker, e.g. stably or transiently. In some embodiments, the method comprises a step of manipulating the host cell to express the at least one marker. For example, the host cell may be transformed, infected, or modified (e.g. by CRISPR), as non-limiting examples.
In one embodiment, the method further comprises labelling the recovered enveloped virus particles with a fluorescent dye.
In one embodiment, the recovered enveloped virus particles each comprise one or more fluorescent protein. In one embodiment, the fluorescent protein is enhanced green fluorescent protein (eGFP). In one embodiment, the enveloped virus particles each comprise viral envelope proteins, each labelled with the fluorescent protein. The fluorescent protein may be encoded by a modified viral genome. However, the virus may also be pseudotyped with the fluorescent protein in some embodiments.
In one embodiment, the viral envelope proteins are M-MLV envelope proteins.
In one embodiment, the enveloped virus particles are pseudotyped with the viral envelope proteins.
In one embodiment, the viral envelope proteins labelled with fluorescent protein are as encoded by SEQ ID NO: 1.
In one embodiment, the pseudotyping is accomplished with a vector comprising SEQ ID NO: 2.
In one embodiment, the enveloped virus particles are pseudotyped to be non-infectious to humans.
In one embodiment, the enveloped virus particles are encoded by a nucleic acid comprising at least one sequence modification that reduces or abrogates expression of the endogenous viral envelope proteins.
In one embodiment, the enveloped virus particles comprise MLV, ALV, HIV, HSV, Influenza, and/or VSV particles.
In one embodiment, the enveloped virus particles comprise gammaretrovirus particles. In one embodiment, the gammaretrovirus is CAS-BR-E, MLV 1313 (Amphotropic MLV), Pmv11 (Polytropic MLV), Xmx15 (Xenotropic MLV), FrMLV (Friend MLV), M-MLV (Moloney MLV), DG-75, AKV MLV (AKV MLV), SL3-3 MLV, E-MLV (Ecotropic MLV), Rauscher MLV, Mus Dunni endogenous virus, Abelson MLV, XMRV, Porcine endogenous type C, Gibbon leukemia virus, Baboon endogenous virus strain M7, Feline leukemia virus, Koala retrovirus, or Wooly monkey virus.
In one embodiment, the enveloped virus particles comprise M-MLV particles.
In one embodiment, the enveloped virus particles are encoded by the recombinant nucleic acid described above or the vector as described above.
In one embodiment, the at least one selected marker is endogenous to the host cell.
In one embodiment, the at least one selected marker is exogenous to the host cell.
In one embodiment, the at least one selected marker may be characteristic of a particular cell type or cellular state. In one embodiment, the at least one selected marker may be operationally specific to a particular cell type or cellular state. In one embodiment, the at least one selected marker may be unique to a particular cell type or cellular state.
In one embodiment, the at least one marker expressed by the host cell comprises a plurality of markers of a selected profile, and the recovered enveloped virus particles comprise the plurality of markers of the selected profile.
In one embodiment, the selected profile may be characteristic of a particular cell type or cellular state. In one embodiment, the selected profile may be operationally specific to a particular cell type or cellular state. In one embodiment, the selected profile may be unique to a particular cell type or cellular state.
In some embodiments, the at least one marker may be modified to increase incorporation into the viral envelope upon egress, in some embodiments. For example, the at least one marker may be a recombinant protein comprising the transmembrane (TM) domain of the native viral envelope glycoprotein. In other embodiments, the marker may be modified with a membrane signal peptide In order to direct the insertion of a protein into a membrane and increase incorporation into viral particles upon egress.
In some embodiments, the at least one selected marker(s) may be characteristic of disease cells. For example, marker may be indicative of infection with a pathogen, a state of inflammation, an altered metabolic state, apoptosis, pre-cancer, or cancer. The marker(s) may indicate the presence, stage, or severity of disease; or may provide information about the affected cell type (e.g., the location of an infection).
In one embodiment, the at least one selected marker is a recombinant protein that is modified to promote incorporation of the marker into the recovered enveloped virus particles. In one embodiment, the recombinant protein comprises a transmembrane (TM) domain of a native viral envelope glycoprotein. In one embodiment, the recombinant protein comprises a membrane signal peptide.
In some embodiments, there are provided recovered enveloped virus particles produced by the forgoing method.
In one aspect, there a is a method providing a method of producing a control for the detection of extracellular vesicles (EVs) or virus particles comprising at least one marker, the method comprising carrying out the above method, wherein the at least one selected marker is determined based on the marker of the extracellular vesicles (EVs) or enveloped virus particles to be detected. In one embodiment, the at least one marker comprises markers of a selected profile, which are determined based on a marker profile of the extracellular vesicles (EVs) or enveloped virus particles to be detected.
In some embodiments, method comprise a step of profiling a disease sample to determine the at least one marker or marker profile.
In some embodiments, there is provided a control produced by the forgoing method. The control may be compared to MESF beads to determine the number of markers per control particle, as described here.
Retroviruses, such as the human immunodeficiency virus (HIV), are enveloped RNA viruses that range between 90-150 nm in diameter, depending on the species. When nascent virions egress from the surface of infected cells, they bear contents of the parental cell, most notably the cellular membrane to form the viral envelope. As such, by profiling and characterizing the abundance of antigens at the surface of viruses it is possible to identify the infected parental cell type. This is of particular interest for the field of HIV research, where a significant hurdle to curing the disease remains the clearance of elusive infected cell reservoirs. Infected reservoir cells are likely distributed throughout the infected host and are present in various tissues. The very small number of these cells in patients treated with combinational antiretroviral therapy (cART), make their identification notoriously difficult.
Nanoscale flow cytometry (NFC), also called flow virometry, is a new and powerful tool in the field of virology that enables the phenotypic analysis of markers at the surface of individual virions28-36. Virus populations can now be profiled and sorted in multi-parameter analyses, much in the same way as cells29,31,34,36,37. However, in first attempts to analyze murine leukemia virus (MLV) particles by NFC, numerous challenges were encountered. These included high background noise, poor resolution and sensitivity, contaminations by extracellular vesicles (EVs), and particle counts that often did not reflect the titer of the input virus. EV is a broad term that describes a particle with a membrane bilayer released from cells; these can include exosomes, microvesicles, and apoptotic vesicles38,39. Small EVs, that are in the size range of retroviruses, are biochemically and biophysically similar to retroviruses in terms of their refractive indices and buoyant densities, and constitute a major contaminant of virus preparations.
Part of the challenges in analyzing viruses and other nanoparticles, such as (EVs), by NFC is the lack of standardized instruments, acquisition settings, and labeling procedures. To complicate matters, instruments of different make will have different optics, fluidics, electronics, detectors, and software. Even using the same instrument model, variations in sensitivity and resolution are common given that the instruments are operating at the threshold of their physical limits of detection. This is often much lower than the published manufacturer's specifications. Most commercial conventional flow cytometers claim that 300 nm is the minimum size limit for the detection of nanoparticles by scattered light. Despite these caveats, several groups are currently using conventional flow cytometers designed for cells to analyze nanoparticles in the 90-150 nm size range28-37,40-49. Common instrument hardware requirements for small particle detection include greater laser power and the use of photomultiplier tubes (PMTs) instead of photodiodes for forward scatter detection. However, there is currently no consensus in the field as to the minimum laser power and voltages required for the detection and resolution of nanoparticles, or whether it more favourable to trigger on fluorescence or scattered light. While conventional flow cytometers clearly have the capacity to detect nanoparticles to varying degrees of sensitivity, standardization of instrument settings and sample acquisition procedures is necessary for cross-laboratory data validation and reproducibility.
Here, a systematic approach was undertaken to analyze viruses by NFC using a BD LSR Fortessa flow cytometer. The model virus for our study is Moloney MLV (M-MLV), as it is a well-studied and characterized retrovirus that is non-infectious for humans. Optimal settings for laser power and voltage were identified to provide maximum particle resolution and sensitivity, as well as sample dilutions and flow rates to minimize coincidence. Data acquired using either fluorescence or side scattered light (SSC) as a trigger for the detection was then compared. Finally, various dyes and staining methods were compared in an attempt to discriminate MLVs from the EV contaminants.
A mutant murine leukemia virus (MLV) has been engineered. A modified
Moloney murine leukemia virus (M-MLV) (derived from NCBI: NC_001501) has been modified or mutated so as to contain a CTG-to-CTA mutation that abolishes the alternative initiation of translation site of the viral glyco-Gag (gPr80) protein. The virus also has the eGFP coding sequence inserted in the proline-rich region of the env gene. The eGFP reporter is therefore present on the external surface of the virus and is antibody accessible. This CTG viral mutant expresses higher green fluorescence than the parental virus and displays a more homogenous cluster of virions. M-MLV is approximately 120 nm in size, as determined by electron cryo-microscopy.
This MLV is fluorescent (MLVeGFP) and released from infected cells as a tight cluster in the 120 nm size range (
The use of MLVeGFP(CTG) to optimize flow cytometer instrument settings. The distinct virus population allows for easy optimization of voltages and laser power for NFC.
The MLVeGFP(CTG) produced share similar biophysical properties (e.g., buoyant density, refractive index) as extracellular vesicles (EVs) of similar size, most notably exosomes (
MLVeGFP(CTG) viruses scatter light (as detected by SSC) similarly to EVs of the same size due to the very similar refractive indices of these particles.
SORP BD LSRFortessa for small particle detection with a PMT for forward scatter detection. Specifications for laser wavelengths and power are as follows: 405 nm-50 mW, 488 nm-300 mW, 561 nm-50 mW, and 640 nm-40 mW. Acquisition was done with BD FACSDiva version 8.0.1. BD Coherent Connection software was used for laser power adjustments. Samples, unless otherwise indicated, were acquired on low (at 5 turns on the fine adjustment knob), which equated to a measured flow rate of 20 μl/min. This instrument is run with a BD FACSFlow Supply System (FFSS) for day to day acquisition of cells, however for small particle detection, a dedicated steel sheath tank with a 0.1 μm inline filter was used along with a separate waste tank. This was done because we found the FFSS contributed to excess fluctuations in instrument background noise. Surfactant-free, ultra-filtered, low particle count sheath fluid was used for acquisition (Clearflow Sheath Fluid-Leinco). CS&T was run using the dedicated tank to obtain appropriate laser delays for use with the tank, since there is a difference in pressure between the FFSS and the steel tank. Instrument cleaning procedure prior to acquisition: 10 mins distilled water, 30 min FACSClean (BD Biosciences), 10 min distilled water, 60 min 10% Decon™ Contrad™ 70 Liquid Detergent (Thermo Fisher Scientific), and 10 min distilled water.
The fluorescence index was calculated as the difference of the median fluorescence intensity of the positive and negative population divided by the standard of deviation of the negative population. Fluorescence index=(MFIpos−MFIneg)/SDneg.
Flow cytometry data was displayed in height for all figures. For small particle analysis, height is the preferred parameter over area. Area is the integrated value of an electronic pulse based on the height and width (time of flight). However, since the particles of interest are very small, the width or time of flight measurements become less precise. This leaves height as the intensity of the signal as the most accurate parameter for analysis of submicron-sized particles.
In the instrument platform, side-scatter was chosen over forward-scattered light detection for the approximation of particle sizes. As approximated by Mie Scatter Theory, the angle of light scatter from a particle in the 100-200 nm size range is such that more light is captured at the side-scatter angle rather than forward, whereas with a cell-sized particle (10 μm) the opposite is true45,61. It was found that, despite having a PMT for FSC detection, resolution in SSC was still superior for the particles of interest. Flow cytometry data was analysed using Flowjo VX (FLOWJO, LLC). GraphPad Prism v6 was used for the generation of graphs (GraphPad Software).
Megamix-Plus SSC fluorescently labeled beads (Biocytex, Marseille, France #7803) with 160 nm, 200 nm, 240 nm, and 500 nm size populations was used. The 500 nm bead population was off scale when run at settings optimized for MLVeGFP resolution.
Human embryonic kidney (HEK) 293T and mouse embryonic fibroblast NIH 3T3 cells were cultured in phenol-red free DMEM High Glucose Medium (Wisent, St Bruno, Canada), supplemented with 10% Fetal Bovine Serum (FBS, Gibco by Thermo Fischer Scientific, Waltham, Mass.), 100 U/mL penicillin and 100 μg/mL streptomycin (Wisent, St Bruno, Canada). This media will be referred to as complete media. Propagation was continued at 37° C. in a 5% CO2 incubator.
Moloney-MLV, referred to as MLVeGFP throughout this study, was produced from the pMOV-eGFP expression plasmid62-64. The eGFP is located on the exterior surface of the virus, within the proline-rich region of the viral envelope glycoprotein, and does not alter infectivity nor ecotropic receptor specificity62. The plasmid eGFP-C3 (Clontech, Mountain View, Calif.) was used for cytoplasmic eGFP expression. For the construction of an Env-eGFP plasmid, Env-eGFP of MLVeGFP was amplified by PCR using the following primers: GCTAGCGCCGCCACCATGGCGCGTTCAAC GCTCTCAAAACC (forward) and CTCGAGCTATGGCTCGTACTCTATAGGCTTCAGCTG GTG (reverse). The amplification product was then inserted between the NheI and XhoI restriction sites of the expression vector pcDNA 3.1 (−) downstream of the CMV promoter.
For virus or EV production, 293T cells were transfected with MLVeGFP, Env-eGFP or eGFP-C3. 24 h before transfection, 293T cells were seeded at a density of 1.25×105 cells/well in a 24-well plate in complete media. For each well, a total of 500 ng of DNA was transfected using GeneJuice (Novagen, EMD Millipore, Billerica, Mass.) according to manufacturer's instructions. After 36 h, the media was changed to 0.1 μm-filtered, serum and phenol red-free DMEM (Wisent), to allow for virus or EV production with minimal contaminants. After 3 h, the cell supernatant was harvested and cleared through a 0.45pm acrodisc syringe filter with SuPor (PES) membrane (Pall Corporation, Port Washington, N.Y., cat. #PN4614) unless otherwise specified. For analysis of the effects of microfiltration on viral sample, supernatants were filtered through 0.1 μm (cat. #PN4612), 0.2 μm (cat. #PN4612) or 0.45 μm filters (all Pall Corporation). Samples produced from transfections were diluted 1:10 prior to analysis by NFC.
To generate cells chronically infected with MLVeGFP, NIH 3T3 cells were infected with MLVeGFP at a high multiplicity of infection (MOI). In short, 10 mL of MLVeGFP containing cell supernatant was produced by transfection for 72 h. The supernatant was cleared through a 0.45 μm filter and was ultra-centrifuged at 100,000×g for 3 h in a 70Ti rotor at 4° C. The entire viral pellet was used to infect NIH 3T3. Uninfected control cells or chronically infected NIH 3T3 cells were seeded at a density of 5×105 cells/well in 6-well plates. After 18 h, cells were washed 3 times with 0.1 μm filtered PBS and incubated in 0.1 μm filtered, serum and phenol red-free DMEM for 3 h.
VVDD-mCherry stocks were obtained from John C. Bell (OHRI). Briefly, virus stocks were produced by infecting HeLa cells at a low MOI (0.01). Infected cells were lysed by repeat freeze-thaw cycles (−80° C./37° C.), cell debris was removed by centrifugation, and virus was clarified through a sucrose cushion at 20,700 RCF with a JS-13.1 rotor for 80 min at 4° C.32,65.
Nanoparticle tracking analysis (NTA) was carried out using the ZetaView PMX110 Multiple Parameter Particle Tracking Analyzer (Particle Metrix, Meerbusch, Germany) in size mode using ZetaView software version 8.02.28. Samples were diluted in PBS to ˜107 particles/ml. The system was calibrated using 105 and 500 nm polystyrene beads and then videos were recorded and analyzed at all 11 camera positions with a 2 second video length, a camera frame rate of 30 fps and a temperature of 21° C. Analysis was performed using Particle Explorer version 1.6.9 (Particle Metrix). Analysis parameters were: segmentation-fixed, centroid estimation-blob, drift compensation-auto, log detection threshold-0.0175, max particle size-1000, min particle size-6.0, segment threshold-18. Results are displayed as the percentage of particles within 25 nm segments and as mean particle size.
Dyes were added directly to undiluted control or MLVeGFP containing supernatant at optimized concentrations. The dye-labeled control or viral supernatants were diluted 1:10 and 1:100 in 0.1 μm filtered PBS, respectively. These were then filtered with a 0.45 μm pore-size syringe filter prior to acquisition on the cytometer. DiD and Dil solutions were used at 10 μM while DHPE-Rhodamine, FM 4-64X and BODIPY TR Ceramide were used at 10 μg/mL (all Thermo Fisher Scientific).
Uninfected and infected NIH 3T3s were cultured overnight with dye. The following day, cells were washed 3 times with 0.1 μm-filtered PBS to remove excess dye. Following washing, the cells were placed back in the 37° C. incubator with 0.1 μm filtered, serum and phenol red-free media. After 3 h, supernatant was collected, 0.45 μm-filtered (unless otherwise indicated), and analyzed by NFC. As before, control or viral supernatants were diluted 1:10 and 1:100 in 0.1 μm filtered-PBS, respectively. DiD and Dil solutions were used at 25 μM, DHPE-Rhodamine and FM 4-64X were used at 25 μg/mL, and BODIPY TR Ceramide was used at 12.5 μg/mL. DiD and Dil were dissolved in ethanol, while DHPE-Rhodamine, FM 4-64X and BODIPY TR Ceramide were dissolved in methanol. Titrations were performed for both the direct and indirect labeling methods, optimal concentrations were chosen (data not shown).
The protocol for nucleic acid labeling with SYBR Green was adapted from Brussard et al.26,29. Briefly, supernatants were fixed in 2% methanol-free paraformaldeyde (PFA) solution (Thermo Fisher Scientific, cat. #28906). Virus samples were stained with 1× SYBR Green I (DNA) or SYBR Green II (RNA) at 80° C. for 10 minutes. For dual labeling of
MLVeGFP, lipophilic dye was loaded onto the virus by indirect labeling prior to nucleic acid staining. For dual labeling of VV, virus particles were labeled using the direct method post SYBR Green I staining. Samples were diluted and 0.45 μm-filtered after staining for analysis by NFC.
Uninfected NIH3T3 cells were labeled as described above for the indirect staining method, but scaled down to fit 35 mm dishes (Ibidi, Fitchburg, Wis.). The Zeiss LSM 880 was used for live imaging confocal microscopy, ImageJ (1.8.0) was used to generate the images.
For this study, Moloney MLV expressing a chimeric envelope-eGFP surface glycoprotein (MLVeGFP) was used. Moloney MLV is an enveloped virus that is nearly spherical with a mean diameter of 124 nm as measured by cryo-electron microscopy. It is estimated that there are approximately 100 envelope glycoprotein spikes per virion of MLV, which is nearly an order of magnitude more than the 7-14 gp120 spikes found at the surface of HIV-1. It has been shown previously that enveloped viruses can form aggregates when subject to centrifugation and repeat freeze thaw36. Similarly, EVs form aggregates when centrifuged61. For this reason, and to reduce other contaminants, the virus was produced from chronically infected NIH 3T3 cells cultured in 0.1 μm filtered, serum and phenol red-free media.
The effect of microfiltration on the virus samples was ascertained (
It was then assessed whether eGFP+ particles are indeed mostly viruses. It is well documented that EVs can acquire viral proteins and nucleic acids when they are released from cells. Because MLV viruses are labeled by acquiring Env-eGFP into their envelope, the coding sequence of this protein was cloned in an expression vector and transfected it into 293T cells in order to measure EV uptake of the protein. The virus was also produced by transfection so that experimental conditions would be similar. All the samples were passed through a 0.45 μm filter prior to NFC analysis. It was found that Env-eGFP particles are more abundant in the cell supernatant when the virus is present (
In order to have analyzed eGFP+ particles in the previous section, several NFC parameters had first needed to be optimized which include voltage, laser power, flow rates and sample dilutions. The following sections describe in detail how these settings were determined and also how they affect data acquisition.
Coincidence occurs when two or more particles are interrogated by a laser simultaneously43,45,46. Flow cytometers are specifically designed to create a stream of single cells that are individually analyzed by the instrument. Because nanoparticles are much smaller than cells, several particles can coincidentally be interrogated at the same time if the sample is too concentrated. Additionally, when a particle crosses the path of the laser and is interrogated over a given time frame, photons are scattered by the particle and are then captured by PMTs that convert them into an electromagnetic pulse. If this pulse does not return to a baseline value before it increases again, this will generate an electronic abort event and the data will not be recorded. Therefore, if a very concentrated sample is analyzed, a large number of electronic aborts will be generated and data events will be discarded. This constitutes a major concern in NFC analysis of viruses and EVs. Furthermore, because the signal generated by nanoparticles is very dim, the threshold for detection is set at or near the lower limit. Low threshold values translate into reduced stringency of what is considered an event and this results in increased background noise.
An additional layer of complexity that comes into play that can affect coincidence is thresholding, also called trigger. When thresholding using SSC, the wavelength of the laser interrogating the particle is the same as the one that is captured by the PMTs. Fluorescence, therefore, does not play a role in SSC thresholding. When thresholding off of fluorescence, the particles are interrogated with a laser emitting at the desired fluorochrome excitation wavelength and the PMTs capture only photons with the appropriate emission wavelength. Because there are generally fewer fluorescent particles than total particles in a sample, fluorescent thresholding may provide the benefit of minimizing electronic aborts. However, the compromise is losing information about total particles in the sample, fluorescent and non-fluorescent. Here a systematic comparison of the effects of sample dilutions and flow rates on both SSC and fluorescence thresholding was therefore made.
Serial dilutions of 0.45 μm-filtered supernatants containing MLVeGFP produced from chronically infected NIH 3T3 cells were analyzed using the low flow rate setting, and the undiluted sample was analyzed using the low, medium (med) and high settings. The average virus titer in the undiluted filtered supernatant remained constant throughout replicate experiments at approximately 1.5-3×106 transducing units (TU)/mL. The samples were analyzed using fluorescence thresholding (
(
The effect of increasing voltage and laser power on diluted and filtered virus preparations was systematically measured (
When comparing data collected for a given SSC voltage setting, increase in laser power resulted in an increase in the separation of SSC signal intensities between the eGFP+ and eGFP-populations (
When laser power and voltage on the green fluorescence channel were increased, it was evident that signal intensities of both the eGFP+ and eGFP− populations were also increased (
To date, several groups have demonstrated the ability to label EVs and viruses through the use of commercially available dyes. Dyes that target different cellular components, such as proteins, lipids and nucleic acids, have been proven effective to stain EVs and viruses in flow cytometry applications30,36,37,46,62. However it has yet to be demonstrated that these methods can be used to discriminate between viruses and EVs.
To identify both virus and EV populations in our infected supernatants, fluorescent dyes were used that target cellular membrane components. Dyes were selected over the use of antibodies due to their ability to stain particles based on their biochemical constituents. Dyes are also not subject to some of the limitations of antibodies such as low surface antigen expression, epitope heterogeneity, and particle aggregation36. There is currently a large number of commercially available dyes which target different molecules and cellular components. Using MLVeGFP, and first tested the lipid membrane targeting dyes DiD, Dil, FM4-64, fluorescent sphingolipid (Ceramide-BODIPY TR) and fluorescent phospholipid (DHPE-Lissamine Rhodamine). Several groups have published methods to directly label virus with dye63-66, however these studies did not account for EV contamination in virus sample preparations or the possibility that the dyes may form micelles. In our system, virus particles will be detectable by Env-eGFP expressed on their surface, and by fluorescence coming from the tested dye. EVs, are largely devoid of Env-eGFP (
Our next approach was to stain virus infected cells in vitro such that the virus would bud directly from fluorescently labeled lipid membranes. This method has been shown to label extracellular vesicles, but has yet been shown to label virus, as far as is known. The same panel of dyes as above were tested. Staining on cells was confirmed by fluorescence confocal microscopy (
Next it was assessed if stained viruses remained infectious. This could be of use for downstream applications that may investigate virus targeting to certain cells. Dil stained cells were excluded from this assessment as it is chemically analogous to DiD. The effects of solvents were included as controls. The infectivity of viral supernatants produced in DiD and Ceramide labeled cells was abrogated, while Rhodamine-PE and FM4-64 labeled cells produced virus with significantly reduced infectivity (
With the indirect staining method, it was clear that some of the dyes were able to resolve the MLVeGFP population. However, EVs were also being labeled by all the dyes tested. It was next attempted to discriminate EVs from viruses based on their nucleic acid content. SYBR Green is a dye that has a strong affinity for nucleic acids, with subtypes that have been developed with higher affinities/quantum yields for RNA (SYBR II) or DNA (SYBR I). Nucleic acid dyes such as SYBR Green have been shown previously to label virus, however in those studies it was unclear whether the dye-labeled virus samples were contaminated with EVs (ref). To discriminate EVs from viruses, MLVeGFP was first labeled with the lipid membrane dye DiD followed by SYBR II, and vaccinia virus (VV) was stained with Dil and then with SYBR I. MLV packages two copies of its 9 Kb single stranded RNA genome (Ref), while the VV harbours a double-stranded DNA genome of about genome 200 Kb (ref). It was predict that the higher genomic content of our viruses should distinguish them from the EV contaminants, which have been reported to carry up to 2 Kb in dsDNA cargo (Confirm amount & ref). While many different types of RNA species have been identified in EVs, relative abundance varies based on cellular origin (ref). Furthermore, their total capacity for packaging nucleic acid remains to be determined. The nucleic acid labeling procedure, as described previously (ref), required fixation of the virus followed by staining at 80° C. This exposure to heat denatured the eGFP on the MLVeGFP and it was no longer fluorescent (
While Dil labeling of VV was unable to distinguish the virus from other cellular vesicles, the use of SYBR I distinctly resolves a defined population (
The fluorescent labeling method of the MLVs can be used to label or pseudotype other enveloped viruses (e.g., ALV, HIV, HSV, Influenza, and VSV) of slightly different sizes, and make it therefore possible to construct a molecular size ladder in a narrow 90-200 nm size range (
Careful optimization of instrument settings is often underappreciated to obtain the best performance from a flow cytometer. In conventional flow cytometers, this optimization is standardized with beads as a reference material. In BD instruments the one used herein, this is achieved with the automated BD CS&T program and beads, however CS&T target values are optimized for cells. Therefore voltages and laser settings for the analysis of nanoscale particles need to be optimized manually with relevant reference materials, especially since the particles of interest are at the limit of detection of current flow cytometry hardware (90-200 nm). In fact, there exists a large discrepancy in both fluorescence intensity and refractive index (RI) between most calibration beads and biological nanoparticles of interest (REF). As such, a fluorescently tagged virus was chosen as the standard, which allowed us to optimize the instrument settings on a biologically relevant particle. Alternatively, other groups have been successful at analyzing nanoparticles through conjugation with fluorescent beads. The benefits of these bead conjugates are the improved detection capabilities on a wide range of flow cytometers, however it may also introduce a bias into data collection. Most notably, non-bound particles may be below the threshold of the detectors. Additionally, our group has previously demonstrated that antibody labeling of nanoparticles can induce aggregation (Tang et al., 2016). For this reason, the NFC study was carried on viruses having undergone a minimal amount of manipulation, which was limited to being filtered and diluted.
There are advantages and disadvantages in selecting light scatter as the threshold parameter. On the one hand it allows for the detection of all non-fluorescent particles, but on the other, it increases the overall abort rate, at least with our instrument and acquisition software. This increased abort rate resulted in a 3-fold reduction in the total eGFP+ events in comparison to fluorescence thresholding (
When analyzing MLVeGFP viruses that contain approximately 100 Env-eGFP molecules on its surface60, the greatest gain in fluorescent particle resolution was observed when the power of the 488 nm laser increases from 100 mW to 200mW (
Retroviruses share many physical properties with EVs such as buoyant density and refractive index due to their overlapping biochemical composition and size. Yet despite these similarities, MLVs as a population are distinct from EVs in that they are slightly more homogeneous in light scattering properties (
In this work, it is clearly demonstrated that a fluorescent tag on the viral envelope glycoprotein can serve as an excellent identifier. While providing some specificity to detect viral particles, our MLVeGFP virus enable us to evaluate the efficacy of other staining methods. As evidenced by
While there was success in staining our viral population, there was a clear overlap with the eGFP− EV population. To further distinguish populations, the relative uniformity of nucleic acid packaging in viruses was taken advantage of. Though MLVeGFP was unable to be resolved from EVs by lipid and nucleic acid staining, it did show superior particle homogeneity (
With technical advancements in flow cytometry it is possible to now visualize nanoparticles down to 120 nm or 90 nm using NFC. This innovation now opens a wide array of new possibilities that result from single particle analysis of viruses, but also of EVs. These applications can include the individual profiling of surface antigens, sorting of particles with distinct markers, or even the precise enumeration of particles displaying certain fluorescence of light scattering characteristics. NFC has the potential to bring new understanding to the fields of virology and EV research, as it provides a tool to answer questions that were not previously possible to address.
As described herein, mutant murine leukemia virus with a G->A mutation at position 836 (a numbering convention for the provirus, corresponding to position 95 of GenBank Accession NC_001501) and an eGFP coding sequence inserted into the proline-rich region of the env gene22 produces the fluorescent MLVeGFP(CTG). These fluorescent viruses can be used as biological size standards to calibrate and set-up flow cytometers for the analysis of fluorescently labeled particles, including biological particles such as EVs and viruses, in the 90-200 nm size range.
Flow cytometry, or more specifically nanoscale flow cytometry (NFC) is becoming a method of choice for the phenotypic analysis of extracellular vesicles (EVs). EVs can range in size from approximately 50 nm to 1 μm in diameter, which places them at the lower end limit of detection for the majority of commercial flow cytometers. Optimization of flow cytometer settings for the analysis of EVs can therefore be challenging. Reference materials such as fluorescently labeled polystyrene or silica beads are often used in the optimization of flow cytometer settings at the acquisition stage. However, synthetic beads have a higher refractive index and often display much more intense fluorescence than biological samples of equivalent size, thereby skewing baseline cytometer settings outside the range of fluorescent EV samples. Here we demonstrate the utility of an eGFP-tagged enveloped virus as a reference material for instrument set-up. Optimization of detector gain and threshold for side-scatter (SSC) and fluorescence was compared using an eGFP-tagged mouse leukemia virus (124 nm in size as established by EM), and the Apogee Bead Mix—a mix of silica (not fluorescent) and polystyrene (fluorescent) beads (110 nm-585 nm). EVs isolated from urine (80 nm median size measured by NTA) and cell-culture media (HUVEC, 67 nm median size measured by NTA) labeled with DiO were analyzed by NFC. EV counts and MFI obtained through instrument settings based on beads vs. virus were compared. Overall use of eGFP-tagged virus for instrument set-up enabled the detection of 10-fold more UVEC EVs and 8-fold more urine-derived EVs.
Flow cytometry is carried out on a Beckman Coulter Cytoflex S.
Fixation: Viruses in the cell supernatant were fixed by adding 2% formaldehyde for 1 h at RT.
Dialysis to remove formaldehyde: 3 ml of fixed virus were then dialysed in 3 L of 0.1 μm-filtered PBS for 17 h at 4° C. using a 3.5 kD dialysis membrane (Spectrum Laboratories, CA, USA).
Stabilization: Virus was then mixed at a ratio of 1:1 with 10% (w/v) 0.1 μm-filtered sorbitol. 200 μl aliquots were frozen in 1 ml glass vials sealed with perforated parafilm at −80° C.
Lyophilization: Frozen samples were then lyophilized on dry-ice for 18 h at a pressure range from 0.019 to 0.031 mbar. For reconstitution, 200 μl of 0.1 μm-filtered MiliQ H2O was added to lyophilized sample.
NTA is carried out using a Zeta View PMX110. Setup with 105 and 500 nm polystyrene beads, analysis with 11 camera positions, 2 s video length, 30 fps @21° C.
EVs are obtained with the following protocol:
Spin 50 ml of human urine/HUVEC cell culture supernatants @2500 g for 10min to remove cellular debris
Spin supernatant 20,000 g for 20 min @4° C. to obtain microparticle pellet (MP), keep supernatant (SN1)
Resuspend MP in isolation solution (250 mM sucrose, 10 mM triethanolamine, pH7.6) with 200 mg/ml of DTT, incubate at room temperature for 10 min. Spin @20,000 g for 20 minutes, keep supernatant (SN2).
Pool SN1 and SN2 (urine only), spin at 100,000 g for 90 min to obtain exosome pellet.
Resuspend exosomes in 0.1 μm-filtered PBS
For labelling, Dio solution is directly added to 300 μl of resuspended exosomes (10 μg) to obtain a final concentration of 10 μM, and incubated for 1.5 hour at 37° C. Exosomes are spun down at 100,000 g for 90 minutes (4° C.), resuspended in PBS
Mouse leukemia virus (MLV-GFP): Virus collected from supernatants of chronically infected NIH 3T3 cells in serum & phenol red-free DMEM, diluted in 0.1 μm-filtered PBS
Avian leukosis virus (ALV-sfGFP): 293T cells were transfected with RCASb for 36 hrs, cells were washed and re-plated in serum & phenol red-free DMEM, virus was produced for 3 hrs, supernatants were collected and then diluted in 0.1 μm-filtered PBS
fluorescence from Anti-GFP antibodies conjugated with various fluorophores. Since the viruses are homogeneous in size, they are readily detected using light scatter (side scatter or SSC) and green fluorescence.
Method 1: NIST (National Institute of Standards and Technology) certified FITC-MESF (FITC molecules of equivalent soluble fluorophores) beads were run with MLVeGFP and ALVsfGFP and used as a reference for green fluorescence (A). Each bead population is associated with a specific number of FITC molecules. By correlating the median fluorescence intensity of green fluorescence of each bead population with the number of associated FITC molecules, the equivalent FITC molecules of fluorescence of both MLVeGFP and ALVsfGFP was extrapolated by linear regression. The fluorescence associated with the equivalent FITC molecules of both virus populations was converted to molecules of eGFP and superfolder GFP (sfGFP). This was done through a calculation for particle brightness (B) as a function of the extinction coefficient and the quantum yield of each fluorophore. The values for FITC, eGFP, and sfGFP are published (C).
Method 2: Quantibrite PE beads (BD Biosciences) were run with MLVeGFP and ALVsfGFP viruses labeled with anti-GFP-PE antibody (D). Quantibrite PE beads are similar to the FITC MESF beads in that each of the three populations are associated with a specific number of PE molecules. Antibody concentrations for virus labeling were determined by titration and the stain index was determined. Molecules of PE were extrapolation by linear regression using the median fluorescence intensities in correlation to PE molecules in each bead population. Because there is a range of antibody concentrations where all positive viruses are labeled (i.e. epitope saturation), the average between the highest and lowest PE molecules per virus was taken.
Using Method 1, we find that eGFP expression on MLV is about 150 molecules of fluorescent eGFP per virus particle and ALV expresses on the order of 400 molecules of sfGFP. The number of sfGFP expressed by ALV is validated with Method 2.
Method 2 estimates close to 400 eGFP expressed on MLVeGFP, which appears to be an over estimation. However eGFP is known to oligomerization in secretory pathway of cells to form non-fluorescent mixed disulfides, while sfGFP does not. Since viruses are produced through this pathway it is very likely that not all eGFP expressed on MLVeGFP are fluorescent. These non-fluorescent eGFP will still be detected by the anti-GFP antibody. Since Method 2 is dependent on antibody detection of GFP molecules and not GFP fluorescence itself, it is feasible that this method will detect more GFP molecules in MLVeGFP than Method 1 which relies on the fluorescence of the fluorophore.68 The finding of approximately 400 molecules of GFP per virus also correlates with values reported in literature. Expression of the eGFP molecule is associated with the MLV envelope glycoprotein gp85. Three gp85 proteins get cleaved to form a trimeric envelope protein spike on the surface of the virus. CryoEM studies to enumerate envelope glycoprotein spikes on MLV have found the expression level to be on the order of 120 spikes per virus. Since there should be 3 eGFP per envelope glycoprotein spike, our estimate of 400 eGFP molecules means approximately 130 spikes per virion.
Thus, by comparing to a NIST standard having defined number of fluorescent molecules, the number of molecules of the fluorescent marker on the virus control can be deduced by linear regression. The virus controls can thereafter act as NIST surrogates, in that they can be used to enumerate markers on the surface of microparticles (e.g., EVs or viruses). An advantage of using the virus controls described herein over NIST standards is that NIST standards are quite bright and contain much higher numbers of molecules than what is at the surface of the virus controls and other microparticles to be measured. Using a fluorescent standard that is closer in fluorescence to the particles being measured increases accuracy. The virus controls described herein would therefore, in some embodiments, be more suitable than NIST standards to measure low levels of fluorescence on microparticles and enumerate markers, receptors, etc.
A&B) Detector gain and threshold were optimized for analysis of MLVeGFP and ALVsfGFP viruses which are 124 nm and 90 nm by EM, respectively. C) Settings were similarly optimized to display all ApogeeMix bead populations (polystyrene-PS, and silica). D&E) ALVsfGFP and MLV-GFP samples were re-run using bead optimized settings. F) ApogeeMix beads were re-run with virus optimized settings. Events were collected for 1 min at 10 ul/min. G) Detector gain and threshold values for virus and beads (ApogeeMix) settings. Viruses are largely undetectable when the instruments are set-up using ApogeeMix beads.
MLV (non-fluorescent), MLVeGFP, and ALVsfGFP and vaccinia virus were labeled with a combination of anti-CD81, -CD63, and -CD9 antibodies. CD81, CD63, and CD9 are all part of a family of transmembrane proteins known as tetraspanins. Tetraspanins play a role in the cellular endocytic pathway, which is implicated in the production of exosomes and are currently used as identifying markers for extracellular vesicles, specifically exosomes. Retroviruses share many biosynthetic pathways with extracellular vesicles for particle production. Tetraspanins have been found to be associated with the retrovirus protein (Gag) in virus assembly and release.
Violet Proliferation Dye 450 is an esterase sensitive dye used for labeling cellular amine groups. This dye is only fluorescent when cleaved by esterases and therefore is dependent on the presence of intracellular esterases in the particle to be labeled. It is also is currently one of the dyes used to identify microparticles, a subpopulation of extracellular vesicles. Since microparticles are believed to be produced by budding from the surface of cells, and are in general larger than exosomes, it is thought that more cellular esterases are packaged into these extracellular vesicles, which then allows for them to be identified by esterase-sensitive dyes. The production of microparticles is also associated with cell death such as apoptosis and necrosis. Vaccinia virus buds through the cell surface membrane and induces cell lysis through apoptosis and necrosis.
These findings suggest that retroviruses (MLV and ALV) share identifying markers for extracellular vesicles, making them an ideal positive control particle for EV labelling assays for flow cytometry, some of which will be discussed.
Markers on the surface of viruses and EVs are indicative of the cell type that is releasing these particles and also, these markers provide a glimpse at the state/heath of a cell (e.g., healthy, dying, necrotic, stressed, cancerous, etc.).
For example, markers on the surface of HIV virions released from infected patients can be profiled in the context of latency reversal therapy that has the objective of purging HIV reservoirs. Reservoirs are cells infected with HIV that don't necessarily release virus, but that may be stimulated to do so (for example when a patient has another simultaneous infection). The reservoirs are elusive, and not all ell types that harbour latent virus have yet been identified. The first viruses released during latency reversal will bear the hallmarks (surface markers) of their parental cell. These markers and receptors on the viruses can be profiled, permitting the reservoir cells to be identified.
For influenza virus, some virus subtypes infect the upper or lower respiratory tract. These often correlate with severity of disease. It is possible to harvest blood plasma from an infected person and profile markers on influenza to quickly determine the site of the infection and the health of the infected epithelial cells.
As a further example, dying virus-infected cells express apoptosis markers (ie. Annexin V) on their surface. If the virus also expresses these markers, the severity of the infection can be deduced.
For diagnostic applications pertaining to extracellular vesicles, plasma could be screened EVs based on the expression of surface markers related to a specific disease. This could help early diagnosis and prognostic of liver and kidney disease for example, also cancer, diabetes.
In all these examples, a positive and negative control of similar size as the particles of interest (EVs or viruses) must be used to calibrate the flow cytometer. Fluorescent virus standards, described herein in some embodiments, can be designed to express any given marker. This may be achieved by serendipitous hijacking of a marker of interest when the virus is released from a specific cell type. The marker may be endogenous or exogenous to the cell type. This may also be achieved by engineering surface markers to be specifically captured by egress virus. This can be done by inserting (e.g., by cloning) the transmembrane (TM) domain of the native viral envelope glycoprotein to the membrane-bound extremity of the surface marker of interest. When the recombinant protein is expressed at the surface of the cell (by transfection or retroviral expression), the egress virus will uptake the marker of interest as it will think that it is its own glycoprotein. Fluorescent virus standards expression such proteins would be useful positive controls in diagnostic-type applications.
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All references cited herein are expressly incorporated by reference.
In the preceding description, for purposes of explanation, numerous details are set forth in order to provide a thorough understanding of the embodiments. However, it will be apparent to one skilled in the art that these specific details are not required. In other instances, well-known electrical structures and circuits are shown in block diagram form in order not to obscure the understanding. For example, specific details are not provided as to whether the embodiments described herein are implemented as a software routine, hardware circuit, firmware, or a combination thereof.
The above-described embodiments are intended to be examples only. Alterations, modifications and variations can be effected to the particular embodiments by those of skill in the art. The scope of the claims should not be limited by the particular embodiments set forth herein, but should be construed in a manner consistent with the specification as a whole.
This application claims the benefit of priority of U.S. Provisional Patent Application No. 62/563,957 entitled FLUORESCENT ENVELOPED VIRAL PARTICLES AS STANDARDS FOR NANOSALE FLOW CYTOMETRY and filed on Sep. 29, 2017, which is hereby incorporated by reference.
Filing Document | Filing Date | Country | Kind |
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PCT/CA2018/000080 | 4/27/2018 | WO | 00 |