Patent Application
20250180580
The present invention relates to methods for selecting cells that express multi-specific binding molecules, such as antibodies, and in particular bispecific antibodies, with high levels of correctly assembled protein.
Bispecific antibodies have shown much promise as a therapeutic approach: bispecific antibodies are entering clinical studies in record numbers, with most developed for cancer. Such molecules, unlike naturally occurring IgG molecules, contain at least 2 and usually at least 4 different chains (e.g., two heavy and two light chains). Therefore, there are a number of different permutations for assembly of the complete product, whereas for naturally occurring IgG molecules there is only one.
A number of solutions have been proposed to solve these chain pairing problems. Knob into holes is commonly used to direct heavy chain-heavy chain pairing. Various techniques have been used to direct heavy-light chain pairing, such as the CrossMabs approach. Nonetheless there is a need to select clonal production cell lines that efficiently express bi-specifics where a high level of correct assembly is achieved and correctly paired molecules can be readily separated from incorrectly paired molecules during downstream processing. The present invention fulfils this need.
Multi-specific therapeutic molecules bind to at least two different antigens on the cancer cell as well as recruiting at least one effector cell (NK- or T-cell) to the tumour site. Protein engineering tools employed to generate such complex molecules therefore involve complex design of multiple polypeptide chains that need to come together in the correct ratio to form a fully functional multi-specific molecule. This poses a significant challenge to the cellular machinery.
In the present disclosure, we also describe a method to determine the correct assembly of a tri-specific molecule (for example: an IgG molecule that binds to HER1 (Antigen 1), HER2 (Antigen 2) on the cancer cell, and recruits a T-cell through an scFv that binds to CD3 (Antigen 3) on the T-cell receptor), using for example an In-Beacon assay and a plate-based assay.
The present invention provides a method that enables individual cell clones to be analysed in vitro whilst growing and secreting recombinant protein. By using reagents that bind specifically to the correctly paired regions of the product, different producing clones can be assessed and compared to enable selection of cells that efficiently produce improved ratios of correctly formed product to incorrectly formed product.
Accordingly, in a first aspect, the present invention provides a method of selecting a cell for expression of a multi-specific binding molecule comprising the following steps:
In another aspect, the present invention provides a method of selecting a cell for expression of a multi-specific binding molecule comprising the following steps:
In a further aspect, the invention relates to a method of selecting a cell for expression of a multi-specific binding molecule comprising the following steps:
In one embodiment, the third and fourth polypeptides are the same.
In one embodiment, the host cells comprise the same one or more nucleic acid sequences encoding the at least two or at least four polypeptides.
In one embodiment, the multi-specific binding molecules are secreted by the host cells.
In one embodiment, the multi-specific binding molecule is a multi-specific antibody or a bi-specific antibody.
In one embodiment, the first and/or second labelled reagent comprises a target antigen of the multi-specific binding molecule.
In one embodiment, the labels for the first and second reagents are different.
In one embodiment, the first and/or second labelled reagent is a fluorescently-labelled reagent.
In one embodiment, the first and/or second labelled reagent is an anti-idiotypic antibody-fluorophore conjugate.
In one embodiment, the host cells are mammalian cells.
In one embodiment, the host cells are cultured in a volume of between about 0.3 nanoliters and about 500 microliters.
In one embodiment, the host cells are cultured in a microplate or in a fluidic device.
In one embodiment, the host cells are cultured in a microfluidic device, optionally wherein the microfluidic device comprises a microfluidic channel to which a plurality of sequestration pens are fluidically connected, optionally wherein the host cells are loaded into the microfluidic device such that a plurality of the sequestration pens are each loaded with one host cell.
In one embodiment, the method further comprises incubating a host cell selected according to step (d) under conditions that allow for expression of the at least two different polypeptides and assembly into a multi-specific binding molecule, and isolating the multi-specific binding molecule.
In one aspect, the invention relates to a method of expressing in a host cell a multi-specific binding molecule, which method comprises incubating a host cell selected according to the method described herein under conditions that allow for expression of the at least two different polypeptides and assembly into a multi-specific binding molecule, and isolating the multi-specific binding molecule.
In a further aspect, the invention relates to a multi-specific binding molecule prepared by the method of expressing in a host cell a multi-specific binding molecule described herein.
In a first aspect, the present invention provides a method of selecting a cell for expression of a multi-specific binding molecule comprising the following steps:
In another aspect, the present invention provides a method of selecting a cell for expression of a multi-specific binding molecule comprising the following steps:
In another aspect, the present invention provides a method of selecting a cell for expression of a multi-specific binding molecule comprising the following steps:
The first, second, third and fourth polypeptides may be referred to herein as polypeptides (i), (ii), (iii) and (iv), respectively.
In some embodiments, the methods described herein are for selecting a host cell for expression of a correctly assembled multi-specific binding molecule.
In some embodiments, when correctly assembled, the multi-specific binding molecule comprises one copy of each, the first and the second polypeptide, or one copy of each, the first, second, third and fourth polypeptide.
In some embodiments, the at least two polypeptides or the at least four polypeptides are heterologous polypeptides. As used herein, a heterologous polypeptide is a polypeptide that is not natively expressed by the host cells, i.e., a polypeptide that is derived from a different organism or cell type as compared to the host cells.
In some embodiments, the third and fourth polypeptides are the same.
In some embodiments, the target molecule to which the first binding site (formed by the first polypeptide or by the first and third polypeptides) binds, is different to the target molecule to which the second binding site (formed by the second polypeptide or by the second and fourth polypeptides) binds.
In some embodiments, the first binding site is a first immunoglobulin antigen binding region, and the second binding site is a second immunoglobulin antigen binding region.
In some embodiments, the at least two polypeptides each comprise three immunoglobulin complementarity determining regions (CDRs). For example, the first polypeptide may comprise a first set of three CDRs, and the second polypeptide may comprise a second set of three CDRs. The third polypeptide may comprise a third set of three CDRs, and the fourth polypeptide may comprise a fourth set of three CDRs.
In some embodiments, the first polypeptide comprises a first immunoglobulin heavy chain Fab region and the second polypeptide comprises a second immunoglobulin heavy chain Fab region. In further embodiments, the third polypeptide comprises a first immunoglobulin light chain Fab region and the fourth polypeptide comprises a second immunoglobulin light chain Fab region. In yet further embodiments, the first polypeptide comprises a first immunoglobulin heavy chain Fab region, the second polypeptide comprises a second immunoglobulin heavy chain Fab region, the third polypeptide comprises a first immunoglobulin light chain Fab region and the fourth polypeptide comprises a second immunoglobulin light chain Fab region.
In some embodiments, at least one of the polypeptides comprises a signal peptide that leads to secretion of the multi-specific binding molecule from the host cells.
In some embodiments, the multi-specific binding molecules are secreted by the host cells.
In some embodiments, the multi-specific binding molecule is a multi-specific antibody or a bi-specific antibody.
The first and second labelled reagent generally comprise a moiety that binds selectively to the first or second binding site, respectively, and a label. Selective binding of the first and second labelled reagent to the first or second binding site, respectively, generally requires correct assembly of the first or second binding site after expression of the polypeptides by the host cells.
In some embodiments, the first and/or second labelled reagent comprises a target antigen of the multi-specific binding molecule, i.e., the labelled reagents comprise the target molecule to which the first and the second binding site bind, or a fragment thereof. Preferably, the first and second labelled reagents comprise the target antigens of the multi-specific binding molecule.
In some embodiments, the first and/or second labelled reagent is an anti-idiotypic antibody or antibody fragment (e.g., Fab or scFv molecules). Preferably, the first and second labelled reagents are anti-idiotypic antibodies or antibody fragments.
In some embodiments, the labels for the first and second reagents are different.
In some embodiments, the first and/or second labelled reagent is a fluorescently-labelled reagent. Preferably, the first and second labelled reagents are fluorescently-labelled reagents.
In some embodiments, the first and/or second labelled reagent is an anti-idiotypic antibody-fluorophore conjugate. Preferably, the first and second labelled reagents are anti-idiotypic antibody-fluorophore conjugates.
In some embodiments, the host cells are mammalian cells.
In some embodiments, the host cells are cultured in a volume of between about 0.3 nanoliters (nL) and about 500 microliters (μL). Preferably, the cells are cultured in a volume of between about 0.4 nanoliters and about 250 microliters, more preferably between about 0.5 nanoliters and about 200 microliters.
In some embodiments, the host cells are cultured in a microplate.
In some embodiments, the host cells are cultured in a fluidic device (e.g., a microfluidic device such as the Beacon® Optofluidic System from Berkeley Lights).
In some embodiments, the microfluidic device comprises a microfluidic channel to which a plurality of sequestration pens are fluidically connected. The host cells may be loaded into the microfluidic device such that a plurality of the sequestration pens are each loaded with one host cell.
The methods of the invention can be used to screen populations of the cells that express multi-specific binding molecules to identify high performing clones. A multi-specific binding molecule in the context of the present invention is a complex of two or more different polypeptide components that comprises at least two different binding sites which bind to target molecules. In other words, the present invention is applicable to molecular complexes where there are multiple components which could assemble in different ways with one another, and it is desired to maximise the correct assembly of the molecule.
As used herein, a clone is a host cell or a host cell population that is genetically homogenous.
Each polypeptide component comprises a binding region for a target molecule of interest. The binding region of each component can pair with a binding region of another component to form a binding site for the target molecule. The overall molecular complex has at least two different binding sites, which may be for a different site on the same target molecule or, more commonly, two different target molecules. Examples of target molecules include cell surface molecules, such as receptors, spike proteins, extracellular proteins or any antigen protein.
In one embodiment, the first target molecule (Antigen 1) of the multi-specific binding molecule is HER1 and the second target molecule (Antigen 2) of the multi-specific binding molecule is HER2 on the cancer cell. In a further embodiment, the multi-specific binding molecule recruits a T-cell through an scFv that binds to CD3 (Antigen 3) on the T-cell receptor.
Accordingly, in one embodiment, the method of selecting a cell for expression of a multi-specific binding molecule further comprises incubating a host cell selected as described herein under conditions that allow for expression of the at least two different polypeptides and assembly into a multi-specific binding molecule, and isolating the multi-specific binding molecule.
In another aspect, the present invention provides a method of expressing in a host cell a multi-specific binding molecule, which method comprises incubating a host cell selected according to a method described herein under conditions that allow for expression of the at least two different polypeptides and assembly into a multi-specific binding molecule, and isolating the multi-specific binding molecule.
In another aspect, the present invention provides a multi-specific binding molecule prepared by a method of selecting a cell for expression of a multi-specific binding molecule or a method of expressing in a host cell a multi-specific binding molecule described herein.
In some embodiments, the polypeptides are single-domain antibodies.
In some embodiments, the multi-specific binding molecule is a multi-specific antibody or a bi-specific antibody. In some embodiments, the multi-specific binding molecule is an IgG-like bispecific antibody such as a DVD-IgG, IgG-scFv-scFv, scFv4, IgG-Fab, IgG-VH/VL or DVI-IgG.
In some embodiments, the target molecule to which the first binding site (formed by the first polypeptide or by the first and third polypeptides) binds, is different to the target molecule to which the second binding site (formed by the second polypeptide or by the second and fourth polypeptides) binds.
A typical example of the multi-specific binding molecule is a bispecific antibody which commonly comprises two different heavy chains and two different light chains such that, by contrast to a naturally-occurring IgG antibody, has two different antigen binding regions. In some implementations, a common light chain is used and so there are only three different chains, i.e., the third and fourth polypeptides may comprise an immunoglobulin light chain Fab region and may be identical.
Some formats of bispecific antibodies do not include full length heavy or light chains and therefore the polypeptide chains may comprise immunoglobulin antigen binding regions (i.e., the complementarity determining regions (CDRs)) optionally with some associated immunoglobulin constant region sequences. For example, the polypeptide chains may comprise the Fab regions of an immunoglobulin without any Fc regions—these may be omitted or substituted with alternative sequences that provide for pairing such as other types of polypeptides that dimerize (e.g., a leucine zipper). Naturally occurring immunoglobulins generally have 3 CDRs on each polypeptide chain such that 6 CDRs form an antigen binding site. Accordingly, the immunoglobulin antigen binding region of each of the polypeptides typically includes 3 CDRs.
In another embodiment, the polypeptide chains are complete, or substantially complete immunoglobulin chains, such as immunoglobulin light chains or heavy chains. The sequences may be engineered to enhance correct heavy chain to heavy chain pairing by substitutions in the Fc region, e.g., mutations that create cysteine residues to provide for disulphide linkages; “knobs-in-holes” type mutations such as the WSAV approach; and/or substitutions that direct electrostatic interactions (electrostatic steering).
The sequences may be engineered to enhance correct heavy chain to light chain pairing by substitutions in the Fab region (constant or variable domains), e.g., mutations that create cysteine residues to provide for disulphide linkages; electrostatic steering; and/or domain swapping, such as the CrossMAbs approach.
Other formats exist that provide for more than two different binding sites, e.g., three or four binding sites. Such approaches are well known in the art.
Various formats also exist where additional sequences are added to the immunoglobulin sequences, e.g., appended IgG-like bispecific antibodies such as DVD-IgG, IgG-scFv-scFv, scFv4, IgG-Fab, IgG-VH/VL, DVI-IgG; and fusions such as dock and lock (see Bratt et al., 2017, BioProcess International 15 (11): 36-42).
Any suitable host cell type may be used in the methods of the invention which can be genetically manipulated to express and secrete multi-specific binding molecules. Preferred host cells are those that can be used to express the multi-specific binding molecules on a large scale, for commercial production of the multi-specific molecule.
Preferably, the host cell is not a bacterial cell.
In some embodiments, the host cell is a eukaryotic cell, for example mammalian, yeast or insect cell.
In one embodiment, the host cell is a mammalian cell. Example species from which host cell can be derived include human, mouse, rat, Chinese hamster, Syrian hamster, monkey, ape, dog, horse, ferret, and cat.
In a particular embodiment, the mammalian host cell is a Chinese hamster ovary (CHO) cell. In one embodiment, the host cell is a CHO-K1 cell, a CHOK1SV cell, a DG44 CHO cell, a DUXB11 CHO cell, a CHO-S, a CHO GS knock-out cell, a CHOK1SV FUT8 knock-out cell, a CHOZN, or a CHO-derived cell. The CHO GS knock-out cell (e.g., GSKO cell) is, for example, a CHO-K1SV GS knockout cell (Lonza Biologics, plc). The CHO FUT8 knockout cell is, for example, the Potelligent® CHOK1SV FUT8 knock-out (Lonza Biologics, plc).
Other mammalian host cells include HeLa, MDCK, HEK293, HEK293T, HT1080, H9, HepG2, MCF7, Jurkat, NIH3T3, PC12, PER.C6, BHK (baby hamster kidney), VERO, SP2/0, NSO, YB2/0, YO, EB66, C127 and COS (e.g., COS1 and COS7).
In other embodiments, the host cell is a cell other than a mammalian cell, such as avian, fish, insect, plant, fungus, or yeast cell.
In embodiments, the eukaryotic cell is a lower eukaryotic cell such as, e.g., a yeast cell (e.g., Pichia genus (e.g., Pichia pastoris, Pichia methanolica, Pichia kluyveri, and Pichia angusta), Komagataella genus, Saccharomyces genus (e.g. Saccharomyces cerevisae, Saccharomyces kluyveri, Saccharomyces uvarum), or Kluyveromyces genus (e.g. Kluyveromyces lactis, Kluyveromyces marxianus). In some embodiments, the eukaryotic cell is of the species Pichia pastoris. Examples for Pichia pastoris strains include but are not limited to X33, GS115, KM71, KM71H, and CBS7435.
In embodiments, the eukaryotic cell is an insect cell (e.g., Sf9, Mimic™ Sf9, Sf21, High Five™ (BT1-TN-5B1-4), or BT1-Ea88 cells).
Suitable host cells are commercially available, for example, from culture collections such as the DSMZ (Deutsche Sammlung von Mikroorganismen and Zellkulturen GmbH, Braunschweig, Germany) or the American Type Culture Collection (ATCC).
Population of Host Cells Transformed with Nucleic Acid Sequences Expressing Multi-specific Binding Molecules
Nucleic acid sequences encoding the different components of the multi-specific binding molecules can be introduced into populations of host cells using techniques well known in the art. The sequences encoding the constituent polypeptide chains, operably linked to regulatory control elements that drive expression of the polypeptides in the host cells are typically present in one or more nucleic acid vectors. One or more of the polypeptides will also typically include a signal sequence that directs secretion of the polypeptide from the host. The vectors typically include one or more selectable markers to enable selection of host cells that have taken up the nucleic acid vectors. Examples of selectable markers include dhfr and amino acid auxotrophy-based markers such as glutamine synthetase (GS).
Following cell selection for the presence of the introduced nucleic acid sequences into the host cells, a population of cells may be generated wherein a plurality of the cells comprise one or more nucleic acid sequences encoding (i) a first polypeptide comprising a first immunoglobulin antigen binding region, such as an immunoglobulin CDR; (ii) a second polypeptide comprising a second immunoglobulin antigen binding region, such as an immunoglobulin CDR; (iii) a third polypeptide comprising a third immunoglobulin antigen binding region, such as an immunoglobulin CDR; and (iv) a fourth polypeptide comprising a fourth immunoglobulin antigen binding region, such as an immunoglobulin CDR, wherein the first and third immunoglobulin antigen binding regions (e.g., CDRs) together form a first antigen binding site and the second and fourth immunoglobulin antigen binding regions (e.g., CDRs) together form a second antigen binding site different to the first antigen binding site.
The purpose of the selection process is to identify and develop further particular clones that produce high levels of correctly paired molecular complexes of interest (e.g., multi-specific binding molecules). Various genetic factors may mean that in a population of clones that have been transformed with the same sequences, not all clones behave in the same manner.
The selection process is not based on testing for the binding of different sequences where different cells have different variants of the polypeptide components; rather, the cells in the population/pool have all been transformed with the same set of sequences.
Accordingly, the host cells within the population of host cells used in the methods according to the invention comprise the same one or more nucleic acid sequences encoding the polypeptides described herein. In one embodiment, the host cells used in the methods according to the invention comprise the same one or more nucleic acid sequences encoding the at least two polypeptides. In another embodiment, the host cells used in the methods according to the invention comprise the same one or more nucleic acid sequences encoding the at least four polypeptides.
For example, the host cells have all been transformed with the same one or more nucleic acid sequences. In one embodiment, providing a population of host cells comprising one or more nucleic acid sequences comprises introduction of the one or more nucleic acid sequences into the host cells. In a specific embodiment, providing a population of host cells comprising one or more nucleic acid sequences further comprises selecting host cells for successful introduction of the one or more nucleic acid sequences into the host cells.
The variation comes from the host cells themselves. Thus, the population of cells that is subject to testing and selection contains the same sequences encoding the first, second, and, where applicable, third and fourth polypeptides. Due to transformation efficiencies, it is possible that not every cell in the population contains all of the sequences but those cells would in any case not be of interest.
The CDRs may be part of an immunoglobulin Fab region and accordingly the plurality of the cells may comprise (i) a first polypeptide comprising a first immunoglobulin heavy chain Fab region; (ii) a second polypeptide comprising a second immunoglobulin heavy chain Fab region; (iii) a third polypeptide comprising a first immunoglobulin light chain Fab region; and (iv) a fourth polypeptide comprising a second immunoglobulin light chain Fab region. The first immunoglobulin heavy chain Fab region and the first immunoglobulin light chain Fab region together form a first immunoglobulin antigen binding region; and the second immunoglobulin heavy chain Fab region and the second immunoglobulin light chain Fab region together form a second immunoglobulin antigen binding region different to the first immunoglobulin antigen binding region.
As noted further above, some approaches include a common chain such that there are 3 different polypeptides rather than 4 or more. Accordingly, one of the polypeptides (i) to (iv) may be identical to one or the others. For example, the third and the fourth polypeptide may be identical and there are in reality three different polypeptides: a first, a second and a third polypeptide such that the first polypeptide pairs with the third polypeptide for the first antigen binding site and the second polypeptide also pairs with the third polypeptide for the second antigen binding site.
The polypeptides may also comprise Fc regions to form full length heavy and light chains.
As discussed above, different regions of the polypeptides may have been modified to promote heavy chain-heavy chain pairing and/or heavy light chain pairing.
The host cells to be screened for expression of a correctly assembled multi-specific binding molecule according to the methods of the invention may be cultured in various suitable formats or devices known to the skilled artisan, including microplates or fluidic devices (e.g., in a microfluidic device or in a nanofluidic device).
Selection of one or more cells expressing a multi-specific binding molecule based on a comparison of the levels of labelled reagents bound to their respective binding sites is generally facilitated by loading individual cells into compartments of a device used for culturing of the cells (e.g., individual well of a microplate or sequestration pen of a fluidic device), such that, after clonal expansion, each compartment comprises a population of cells resulting from clonal expansion of a single cell. Thus, in one embodiment, the host cells are loaded into compartments of a device (e.g., a microplate or a fluidic device) used for culturing of the cells, such that a plurality of the compartments are each loaded with one host cell. A compartment may be a well of a microplate or a sequestration pen of a fluidic device.
Preferably, the host cells are clonally expanded to obtain a plurality of host cell populations, each of which is genetically homogenous. Thus, in one embodiment of the methods disclosed herein, providing a population of host cells comprises clonally expanding the host cells to obtain a plurality of host cell populations, each of which is genetically homogenous. In a preferred embodiment, the host cells are loaded into compartments of a device (e.g., a microplate or a fluidic device) used for culturing of the cells, such that a plurality of the compartments are each loaded with one host cell, wherein the host cells are subsequently clonally expanded to obtain a plurality of host cell populations, each of which is genetically homogenous.
In one embodiment, the host cells are cultured in a microplate (also referred to as multiwell plate or microtiter plate), e.g., a 24-well plate, a 48-well plate, 96-well plate, a 384-well plate or a 1536-well plate. In a preferred embodiment, the host cells are cultured in a 96-well plate or a 384-well plate, more preferably in a 96-well plate.
In a further embodiment, the host cells are cultured in a fluidic device (e.g., in a microfluidic device or in a nanofluidic device).
In a specific embodiment, a population of cells is introduced into a fluidic device (such as a microfluidic device or a nanofluidic device) which comprises a channel (such as a microchannel or a nanochannel) to which a plurality of sequestration pens are fluidically connected. The fluidic device comprises a substrate and the channel and pens are part of a fluidic structure which is disposed on a surface of the substrate. Cells suspended in a liquid medium can flow along the channel and pass the sequestration pens. The device is configured to enable individual cells to be loaded into a sequestration pen so that each sequestration pen contains only one cell, and also to enable the cells within a particular sequestration pen to be released into the channel and collected. The pens may be between about 0.3 nanoliters and about 500 microliters in volume, for example between about 0.3 and about 10 nL in volume for a microfluidic device.
The sequestration pens may comprise a fluidic isolation structure comprising an isolation region having a single opening and a connection region fluidically connecting said isolation region to the channel, the connection region comprising a proximal opening into the channels.
The substrate may be tilted at a small angle from the horizontal so that cells settle to the bottom of the sequestration pens and away from the narrow single opening into the channel.
An example of microfluidic device technology for achieving this is the use of OptoElectricPositioning (OEP), such as the Berkeley Lights Inc., Emeryville, CA Beacon system, e.g., as described in U.S. Pat. No. 9,857,333; Mocciaro et al., 2018, Light-activated cell identification and sorting (lacis) for selection of edited clones on a nanofluidic device. Commun Biol. 1:41; and Le et al., 2018, A novel mammalian cell line development platform utilizing nanofluidics and optoelectro positioning technology. Biotechnol Prog. 34:1438-46. OEP is based on a microfluidic device which includes a transparent electrode on a silicon substrate with a fluidic chamber sandwiched between the two. The substrate is fabricated with an array of photosensitive transistors. When focused light hits the transistors and a voltage is applied, a non-uniform electric field is generated. This imparts a negative dielectrophoresis (DEP) force that repels particles (including cells) using light-induced OEP (
The microfluidic device may, as per any manufacturer's instructions, be pre-wetted with a suitable wetting solution that creates an environment compatible with the host cells and allows for good penning efficiency. The device can then be primed with cell culture media suitable for the growth of the host cells and protein expression.
Once cells have been loaded into a suitable device (e.g., microplate or fluidic device) and positioned into individual compartments (e.g., wells or sequestration pens), the cells are incubated to allow for cell growth and clonal expansion, as well as the production of the multi-specific binding molecules. Monitoring of the different compartments can be used to ensure monoclonality in each compartment and also to ensure that the cells do not overfill the compartments prior to analysis of the multi-specific binding molecules.
Cells are then analysed by introduction into the device (e.g., microplate or fluidic device) of reagents that bind specifically to a correctly formed first binding site or to a correctly formed second binding site in the multi-specific molecule. In one embodiment, the reagents comprise the corresponding target antigen for the binding sites, e.g., the target molecule or a fragment thereof. In another embodiment, the reagents are anti-idiotypic antibodies, including fragments thereof such as Fab, scFv molecules, specific to one of the correctly formed binding sites in the multi-specific molecule. Other reagents include aptamers-oligonucleotide or peptide molecules that have the requisite binding specificity.
The binding molecules each need to be specific for the different binding sites so that binding can be distinguished.
The reagents are typically labelled with a detectable label to enable binding of the reagent to its target to be measured in situ in the device. In one embodiment, the label is a chemiluminescent label. In another embodiment the label is a fluorescent label, such as a fluorophore or a fluorescent protein. In one embodiment, the detectable label is fluorescein or a derivative thereof (e.g., fluorescein isothiocyanate). Exemplary fluorescent proteins are blue fluorescent proteins such as BFP and mTagBFP, cyan fluorescent proteins such as ECFP and TagCFP, green fluorescent proteins such as EGFP and ZsGreen, yellow fluorescent proteins such as EYFP and ZsYellow, red fluorescent proteins such as mRFP and mCherry, far-red proteins such as E2-Crimson.
Each different reagent may be labelled with the same or a different detectable label. Preferably, each different reagent is labelled with a different detectable label.
Each reagent can be introduced into the device separately or at the same time, (which may depend on whether different labels are used as well as the ability of the imaging system to distinguish between different labels, such as different fluorescent (or chemiluminescent) signals, to enable simultaneous measurement).
In one embodiment, the first reagent is introduced into the device such that it is able to enter the compartments (e.g., wells or sequestration pens) and contact the multi-specific molecule produced by the host cells in the compartment. The reagent is present in the compartments for a period of time to provide sufficient binding to the multi-specific molecule (e.g., 45 to 60 minutes). After a suitable washing step, if required, the binding of the first reagent to the first binding site in the molecule is determined, e.g., by fluorescent imaging of the device. A wash step is then used to remove the first reagent and the process is repeated with the second reagent and so on.
The extent of binding of the first and second reagents is determined, e.g., using image analysis algorithms or scripts. This can be used to determine an intensity score (e.g., a normalized signal intensity) for each compartment (e.g., well or sequestration pen) for each reagent, adjusted as necessary to actual binding amounts depending on the performance of the labels used so that an accurate comparison of the intensity score for the different reagents can be made.
In one embodiment, the intensity score is determined by normalizing each level (e.g., signal intensity) of first labelled reagent and second labelled reagent to a standard. In one embodiment, the standard is a titration curve for each labelled reagent across the relevant concentration range. In one embodiment, the standard is a sample representative of a correctly assembled multi-specific binding molecule (e.g., a purified correctly assembled multi-specific binding molecule). In another embodiment, an individual standard is used for each labelled reagent, wherein each standard is a sample representative of correct assembly of the binding site that is selectively bound by the respective labelled reagent. For example, the level measured for the first labelled reagent is normalized using a standard which is a sample representative of correct assembly of the first binding site that is selectively bound by the first labelled reagent and the level measured for the second labelled reagent is normalized using a standard which is a sample representative of correct assembly of the second binding site that is selectively bound by the second labelled reagent.
The intensity scores for each reagent are then compared to obtain a pairing score, e.g., a percentage obtained by dividing the lowest intensity score by the highest intensity score for each pen. A similar score, e.g., greater than or equal to 90 or 95%, indicates high levels of correctly paired chains since similar amounts of correctly formed first and second binding sites in the multi-specific molecule are present in the compartment (e.g., well or sequestration pen). Expressed in another way, if the intensities are within +/−20%, such as +/−10% or +/−5% of each other, then this would be considered a similar score. Conversely, a score outside of a similar score is indicative of significant levels of mispaired molecules, e.g., greater than +/−20% referring to the calculations above. Accordingly, in one embodiment, levels of first labelled reagent and second labelled reagent bound to their respective binding sites that are within +/−20% of each other (i.e., have intensity scores within +/−20% of each other), preferably within +/−10% of each other and most preferably within +/−5% of each other indicate correctly-paired multi-specific binding molecules (i.e., multi-specific binding molecules comprising both a first binding site for a target molecule, and a second binding site for a target molecule).
In one embodiment, selecting one or more host cells expressing a multi-specific binding molecule based on a comparison of the two levels (e.g., signal intensities) measured for the first labelled reagent and the second labelled reagent bound to their respective binding sites comprises selecting one or more host cells according to the level of correctly assembled multi-specific binding molecule. In other words, selecting one or more host cells expressing a multi-specific binding molecule involves ranking host cells according to the level (e.g., signal intensity) ratio of the first labelled reagent and second labelled reagent. Host cells with a level (e.g., signal intensity) ratio closer to 1 are generally preferred in this process. In a specific embodiment, one or more host cells are selected according to their pairing score(s), e.g., one or more host cells are selected that have been determined to exhibit the highest pairing score(s). In one embodiment, the pairing score is obtained by comparing the level (e.g., intensity scores) of the first labelled reagent and the second labelled reagent.
Typically, cells in particular compartments are scored for productivity (total levels of multi-specific molecule production) since it is advantageous for industrial production for the cells to be able to produce high titers of the product of interest. The scoring may be a relative score between the various clones. The Beacon system provides SpotLight™ Human Fc and kappa light chain assays. These are fluorophores that bind to the Fc and/or the kappa light chain constant region and give a fluorescence signal directly proportional to the amount of antibody expressed in that particular clone. A “score” value is created by measuring the change in fluorescence in the or close to the neck of the pen in the (what they call diffusion gradient assay). A higher slope value means higher titre. The maximum score is normalized to 100 and the minimum to 0. The values in between are the percent of the total and the score is calculated from these values. The rQp is the relative production per cell of the last DiGr assay, i.e., the score divided by the number of cells.
Thus, in one embodiment, selecting one or more host cells expressing a multi-specific binding molecule based on a comparison of the two levels measured for the first labelled reagent and the second labelled reagent bound to their respective binding sites further comprises selecting one or more host cells according to their productivity (total levels of multi-specific molecule production). In a specific embodiment, productivity is determined by determining a relative score between a plurality of clones. The relative score may be a signal (e.g., a fluorescent signal) that is representative for the amount of multi-specific molecule expressed in that particular clone. In one embodiment, the signal is a fluorescent signal determined using fluorophores that bind to the Fc and/or the kappa light chain constant region and give a fluorescence signal directly proportional to the amount of antibody expressed in that particular clone.
The relative score may be normalized to a standard, e.g., normalized to the clone with the highest absolute productivity. In one embodiment, to generate a relative score, the signal (e.g., fluorescent signal) is normalized by dividing the signal determined for an individual clone by the highest signal determined for any of the clones. The clone possessing the highest productivity is thus assigned a productivity of 100% and a clone possessing a lower productivity would be assigned a corresponding lower value (e.g., 90%, 70%, 50%, etc.).
Individual clones that meet the threshold for correct pairing, and typically the threshold for productivity can then be exported from the device, e.g., into 96-well plates, for further growth. Typically, selected clones are then further assessed to identify the highest producing clones (high Qp).
Clones may optionally be subject to further analysis to confirm the high levels of correct pairing. For example, assessment of purified molecule by limited digestion (e.g., with Lys-C) and mass spectroscopy (LC-MS) can be used to check for quantitate in more detail the levels and configuration of non-correctly paired variants.
Selected clones can then be used to establish stable cell lines for use in manufacturing recombinant multi-specific binding molecules of interest, for example at a scale of greater than 500 g per batch, e.g., in a bioreactor having a volume of at least 10 L such as at least about 100, 200, 500, 1000 or 2000 L.
The present invention will be illustrated further with reference to the following examples, which are non-limiting.
This procedure can also be performed with a single fluorophore since measurements can be taken sequentially and the first reagent will then be washed out before the second reagent is introduced.
Mean and standard deviation (SD) of triplicate measurements were obtained. Fluorescence intensity obtained from null-CCS were subtracted from those obtained from the rest of the samples. Intensities obtained for mAb1-binding Antigen 1 FITC-conjugated were normalized against mAb1, and those obtained for mAb1-binding Antigen 2 FITC-conjugated were normalized against mAb2 (Tables 1 and 2). Normalized intensities were plotted as bar graphs (
Data show that the plate assay can be used to assess the degree of heterogeneity in various CCS samples.
Mean and SD of triplicate measurements were obtained. Fluorescence intensity obtained from null-CCS were subtracted from those obtained from the rest of the samples. Intensities obtained for mAb1-binding Antigen 1 FITC-conjugate (Ag1-FITC) were normalized against mAb1, and those obtained for mAb1-binding Antigen 2 FITC-conjugate (Ag2-FITC) were normalized against mAb2 (Table 3). Normalized intensities were plotted as bar graphs (
The plate-based format to distinguish the degree of heterogeneity in bispecific cultures is feasible. When proprietary bs molecules were tested using this method the ratio of intensities obtained for mAb1-binding Antigen 1 FITC-conjugated and mAb2-binding Antigen 2 FITC-conjugated correlates with LCMS data obtained by those specific molecules.
The workflow of the method is schematically depicted in
Single cells with the required nucleotide sequences to express a tri-specific molecule are loaded into individual pens, and they are allowed to grow over a period of 4 days by perfusing media into the chip. On day 4, fluorescently labelled Antigen 1, Antigen 2 and Antigen 3 antigens are prepared at a concentration>10×KD of the interaction. Estimation of the clones expressing tri-specifics can be determined by two workflows:
Plate based assays can be used to assess the degree of multi-specificity binding using both the sequential as well as the multiplexed approach. In a plate based assay, the IgG tri-specific is immobilized on a Protein A coated 96-well plate, and the excess molecule washed off the plate using an appropriate buffer. In both the sequential and the multiplexed format, the workflow is similar to the Beacon workflow described above, except that a fluorescence plate reader is used to measure the fluorescence intensity.
The disclosures of each and every patent, patent application, and publication cited herein are hereby incorporated herein by reference in their entirety. While this invention has been disclosed with reference to specific aspects, it is apparent that other aspects and variations of this invention may be devised by others skilled in the art without departing from the true spirit and scope of the invention. Features and embodiments in different sections can be combined mutatis mutandis.
| Number | Date | Country | Kind |
|---|---|---|---|
| 22160066.1 | Mar 2022 | EP | regional |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2023/055345 | 3/2/2023 | WO |
