Patent Application
20220041739
The present invention relates to modulators of the NLRP3 inflammasome pathway, particularly antibodies and fragments thereof as well as aptamer molecules (small RNA/DNA molecules that can form secondary and tertiary structures capable of specifically binding proteins or other cellular targets), each of which have binding specificity for members of the NLRP3 inflammasome. In particular, the invention extends to use of such antibodies and aptamers, and their fragments, for the treatment and prevention of inflammatory diseases mediated by NLRP3 inflammasome signalling and activation, particularly inflammatory eye diseases such as glaucoma.
Inflammasomes are a group of protein complexes that recognize a large variety of inflammation inducing stimuli that include pathogen-associated molecular patterns (PAMPs) and danger associated molecular patterns (DAMPs). Different inflammasome complexes are known; among these, NLRP3 is the most studied inflammasome due to the large variety of signals that activate it, including LPS, bacterial toxins, dust, stress signals such as ATP, crystallized and particulate materials, cholesterol crystals, oxidised LDL, amyloid beta, prion protein fibrils and fibrillar alpha synuclein, shear stress, pressure.
The NLRP3 (nucleotide-binding oligomerization domain (NACHT)), leucine rich repeat (LRR) domain, and pyrin domain-containing protein 3 inflammasome is implicated in a number of infectious diseases and a plethora of degenerative inflammatory type diseases including Atherosclerosis, Diabetes, Inflammatory eye disease, other eye diseases such as dry eye syndrome, Glaucoma, Age related macular degeneration, Depression, Alzheimer's Disease, Parkinson's Disease, Inflammatory Bowel Diseases, Arthritic conditions such as Rheumatoid Arthritis, Ageing, Dermatological conditions and Cancer.
The main role of the NLRP3 protein is to sense danger signals or foreign material, and relay the signal to caspase 1 in turn activating the secretion of the pro-inflammatory cytokine IL-1β, which then initiates inflammation in an attempt to protect the body. IL-1β is the most studied of all cytokines because of its central role in the inflammatory process. Although it is useful for the body to activate IL-1β, in many diseases this inflammation can get out of control and be responsible for the pathogenesis of the disease. Most therapeutic strategies to date have concentrated on developing therapies against IL-1β to dampen the inflammation, but as we propose here, there are number of advantages of targeting the upstream controllers of this cytokine, namely the NLRP3 inflammasome.
The mechanism of activation is not yet fully understood, but the processing of IL-1β via the inflammasome has been demonstrated to involve two pathways. First, the NFκB pathway is activated by a DAMP or PAMP via Toll-like receptors (TLRs) and or CD36 receptors. This leads to the transcription and expression of the pro form of IL-1β and NLRP3.
A second signal is also thought to be required whereby purinergic receptor stimulation by a DAMP such as ATP leads to increases in intracellular calcium and cell swelling that results in potassium efflux from the cell, lysosomal destabilisation, membrane permeabillisation, mitochondrial damage and subsequent generation of reactive oxygen species, leading to NLRP3 activation. Other work has demonstrated that oxidized LDL cholesterol can indeed itself act as the two signals required for NLRP3 activation. In all studies, potassium efflux appears to be the sole common denominator for NLRP3 activation.
The NLRP3 protein subsequently interacts with ASC (apoptosis-associated speck-like protein) through homotypic interactions of the pyrin domain. ASC then interacts with pro caspase 1 resulting in cleavage and activation of caspase 1, which in turn cleaves pro IL-1β to its active form. IL-1β is then cleaved to produce the biologically active and secreted form.
The current best treatments for inflammasome-related disorders target the main product of inflammasome activity, IL-1β. In the past 20 years, a number of anti-IL-1β therapies have been developed. However, there are several disadvantages of anti-IL-1β therapies. Host defence against opportunistic organisms as well as routine bacterial infections have become a major concern for all anti-cytokine agents because of the indolent and dangerous nature of these infections. Anti-IL-1β therapies have other side effects such as nausea, neutrophilia and adverse allergic responses.
Some advantages of an anti-NLRP3 therapy over the IL-1β therapies are as follows:
NLRP3 is a nod like receptor so dampening the recognition of the root cause of a disease, i.e. recognition of the foreign/danger material may be advantageous over dampening the response. This would mean that no IL-1β would be secreted via the NLRP3 pathway activated by disease specific stimuli, e.g. oxidized LDL, β amyloid or alpha synuclein or a particular pathogen. However, IL-1β could still be activated via other pathways in response to other non-disease-related stimuli as needed in extreme circumstances (such as large scale or opportunistic infections), since there are other pathways responsible for IL-1β activation.
The inflammasome has been associated with specialized forms of cell death, pyronecrosis (caspase1 independent) and pyroptosis, which may occur in cases of exacerbated inflammation. Therefore, an anti-NLRP3 therapy will also decrease such death pathways, which have been evidenced to be involved in the pathogenesis of certain diseases such as atherosclerosis. Pyroptosis is a risk factor for plaque disruption in this disease in response to oxidized LDL.
Several previously characterized small molecule inhibitors have more recently also been shown to affect NLRP3 inflammasome function. Glyburide, a sulfonylurea drug, is an example of such an inhibitor. MCC950 (illustrated below) is another example of a specific small molecule inhibitor of NLRP3 inflammasome:
However, there are several problems with currently available inhibitors. Indeed many of these currently available inhibitors of inflammasome function have either not been clinically successful, are nonspecific and importantly have very short half lives.
The development of humanized antibody type therapy could prove more advantageous than small molecule inhibitors for the NLRP3 inflammasome.
Some advantages of humanized antibodies over small molecule inhibitors are as follows:
NLRP3 (also known as NALP3 and cryopyrin) is a cytosolic protein; therefore, in order to target this protein, any therapy must gain entry to the cell. Humanized antibodies are quite large in size and entry to the cytosol may prove difficult. Small antibody fragment development also present a possibility to overcome such a challenge where an antibody fragment may be a Fab fragment, which is the antigen-binding fragment of an antibody, or a single-chain variable fragment, which is a fusion protein of the variable region of heavy and the light chain of an antibody connected by a peptide linker. As discussed further below, the present inventor has devised additional strategies to ensure the therapeutic antibody or aptamer, and their fragments, can gain entry to the cell.
There are some reports in the field describing the targeting of the NLRP3 inflammasome or related molecules using various agents. For example, WO2013/007763A1 discloses an inhibitor capable of intracellular localisation and cytosolic binding to a member of the inflammasome group including NLRP3, for use in a method for the prevention/treatment of acne.
US20080008652A1 discloses methods and compositions for modulating immune responses and adjuvant activity, and in particular, via modulation of cryopyrin (NPRL3) signalling. Humanized antibodies that target cryopyrin modulating proteins, or cryopyrin signal pathway components, are mentioned, and methods of producing cryopyrin antibodies are disclosed.
WO2002026780A2 discloses antibodies that bind to PAAD-domain containing polypeptides, as well as methods of treating various pathologies, including inflammation, by administering an anti-PAAD antibody. Single chain antibodies, chimeric, bifunctional and humanized antibodies, as well as antigen-binding fragments thereof are also mentioned.
WO2011109459A2 discloses a method of treating an inflammatory disease of skin/hair by providing a composition including at least one antibody that specifically binds to a component(s) of a mammalian inflammasome, such as ASC or NLRP1. Commercially available antibodies to ASC and NPRL1 are mentioned.
EP2350315B1 discloses methods and kits for the early diagnosis of atherosclerosis, involving the measurement of the expression levels of NLRP3, ASC and/or caspase-1. Expression levels may be measured by methods involving antibodies, including human antibodies, humanized antibodies, recombinant antibodies and antibody fragments, which in turn include Fab, Fab′, F(ab)2, F(ab′)2, Fv and scFv.
WO2013119673A1 discloses a method of evaluating a patient suspected of having a CNS injury comprising measuring the level of at least one inflammasome protein such as NLRP1 (NALP-1), ASC, and caspase-1. Commercially available antibodies to NPRL-1, ASC and caspase-1 are mentioned.
WO2007077042A1 discloses a method for the treatment of gout or pseudogout, comprising administering a NALP3 inflammasome inhibiting agent. The NALP3 inflammasome inhibiting agents are described as acting downstream of the NALP3 inflammasome and selected from among antibodies that inhibit the activity of IL-1.
WO2013138795A1 discloses a fusion protein comprising a Surf+Penetrating Polypeptide and an antibody or antibody-mimic moiety (AAM moiety) that binds to an intracellular target, wherein the fusion protein penetrates cells and binds to the intracellular target to inhibit binding between the target and another protein inside the cells.
The present invention provides novel and effective modulators of the NLRP3 inflammasome for the treatment and prevention of inflammatory diseases mediated by NLRP3 inflammasome signalling and activation, particularly inflammatory eye diseases such as glaucoma. Such modulators include a bi-antibody or aptamer, and their fragments, targeted to both of IL-1R1 and NLRP3. The bi-antibody first gains entry into the cell by binding to the IL-1R1 which triggers rapid internalisation and, once internalised, the bi-antibody then targets the intracellular protein NLRP3 inhibiting the assembly of the NLRP3 inflammasome, in turn preventing IL-1β secretion from the cells, and reducing the initiation/amplification of inflammation.
Accordingly, in a first aspect of the present invention, there is provided an NLRP3 inflammasome modulator which is capable of binding to both of IL-1R1 and NLRP3 for use in the treatment or prophylaxis of an inflammatory eye disease.
Optionally, the inflammatory eye disease is glaucoma.
Optionally, the modulator is also capable of binding to the PYD domain of NLRP3.
Optionally, the modulator is selected from the group comprising: a polyclonal antibody, a monoclonal antibody, a humanized antibody, a chimeric antibody, a fusion protein, or an aptamer molecule, a combination thereof, and fragments of each thereof.
The modulator may be a bi-antibody capable of binding to both of: IL-1R1 and NLRP3. Optionally, the modulator is a recombinant humanized bi-antibody capable of binding to both of: IL-1R1 and NLRP3.
Optionally, the modulator is a bi-antibody comprising one or more of the binding regions of a first antibody capable of binding IL-1R1 and one or more of the binding regions of a second antibody capable of binding NLRP3. Optionally, the modulator is a bi-antibody comprising one or more complementary determining regions (CDRs) of a first antibody capable of binding IL-1R1 and one or more CDRs of a second antibody capable of binding NLRP3. Optionally, the first and/or second antibody is a monoclonal antibody.
Optionally, the modulator is selected from an antibody fragment capable of binding to both: IL-1R1 and NLRP3. Optionally, the antibody fragment is selected from one or more of Fab, Fv, Fab′, (Fab′)2, scFv, bis-scFv, minibody, Fab2, and Fab3.
Optionally, the modulator is selected from a recombinant humanized antibody or antibody fragment capable of binding to both of: IL-1R1 and NLRP3.
Optionally, the modulator is an antibody or antibody fragment raised against one or more antigens selected from both of IL-1R1 and NLRP3. Optionally, the modulator is raised against one or more antigens selected from all or part of both of IL-1R1 and NLRP3. Optionally, the modulator is raised against one or more antigens selected from NLRP3, optionally conjugated to a carrier protein such as Keyhole Limpet Haemocyanin (KLH) (hereinafter, the NLRP3 immunogen), and IL-1R1, optionally recombinant IL-1R1.
Optionally, the extracellular domain of IL-1R1 (hereinafter, the IL-1R1 immunogen) comprises the sequence:
Optionally, the NLRP3 immunogen comprises the sequence:
Optionally, the NLRP3 immunogen comprises a carrier protein conjugated to the sequence EDYPPQKGCIPLPRGQTEKADHVD (SEQ ID NO: 30), optionally conjugated to the N-terminal end of the sequence EDYPPQKGCIPLPRGQTEKADHVD (SEQ ID NO: 30).
A carrier protein, conjugated to a peptide, is known in the art to help the peptide generate a stronger immune response. Optionally, the carrier protein is KLH.
Optionally, the carrier protein is conjugated to the sequence EDYPPQKGCIPLPRGQTEKADHVD (SEQ ID NO: 30) via a linker, optionally the linker is Hydrazide-Ahx.
Optionally, the NLRP3 immunogen is:
As is understood in the art, a hydrazide is a class of organic compounds characterized by a nitrogen-nitrogen covalent bond with four substituents with at least one of them being an acyl group. Ahx denotes a 6-carbon linear aminohexanoic linker.
Optionally, the modulator is raisable, optionally raised, against one or more immunogens selected from NLRP3 immunogen and IL-1R1 immunogen, wherein the IL-1R1 immunogen comprises the sequence:
and the NLRP3 immunogen comprises the sequence:
Optionally, the modulator is a bi-antibody comprising one or more of the binding regions of a first antibody raisable, optionally raised, against IL-1R1 immunogen and comprising the sequence:
and one or more of the binding regions of a second antibody raised against NLRP3 immunogen comprising the sequence:
Optionally, the modulator is a bi-antibody comprising one or more complementary determining regions (CDRs) of a first antibody raisable, optionally raised, against IL-1R1 immunogen and comprising the sequence:
and one or more CDRs of a second antibody raised against NLRP3 immunogen comprising the sequence:
Optionally, the first and/or second antibody is a monoclonal antibody.
Optionally, the consensus sequence of the heavy chain of the first antibody (to IL-1R1) is
TVRISCKASGYPFTTAGLQINVQKMSGKGLKWIGW
MNTQSEVPKYAEEFKGRIAFSLETAASTAYLQINN
LKTEDTATYFCAKSVYFNWRYFDVWGAGTTVTVSS
Optionally, the heavy chain CDRs of the first antibody comprise: GYPFTTAG (SEQ ID NO: 60); MNTQSEVP (SEQ ID NO: 61); and AKSVYFNWRYFDV (SEQ ID NO: 62).
Optionally, the consensus sequence of the light chain of the first antibody (to IL-1R1) is
GDRVSLSCRASQSISDYLSWYQQRSHESPRLIIKY
ASQSISGIPSRFSGSGSGSDFTLSINSVEPEDVGV
YYCQHGHSFPLTFGSGTKLELKRADAAPTVSIFPP
Optionally, the light chain CDRs of the first antibody comprise: QSISDY (SEQ ID NO: 63); YAS; and QHGHSFPLT (SEQ ID NO: 64).
Optionally, the consensus sequence of the heavy chain of the second antibody (against NLRP3) is
SLKLSCAASGFTFSDYYMYWVRQTPEKRLEWVATI
SDGGTYTYYPDSVKGRFTISRDNAKNNLYLQMNSL
KSEDTAMYYCARGWVSTMVKLLSSFPYWGQGTLVT
VSAAKTTPPSVYPLA.
Optionally, the heavy chain CDRs of the second antibody comprise: GFTFSDYY (SEQ ID NO: 65); ISDGGTYT (SEQ ID NO: 66); and ARGWVSTMVKLLSSFPY (SEQ ID NO: 67).
Optionally, the consensus sequence of the light chain of the second antibody (to NLRP3) is
TVTLTCRSSTGAVTTSNYANWVQEKPDHLFTGLIG
IYFCALWYSNYWVFGGGTKLTVLGQPKSSPSVTLF
Optionally, the light chain CDRs of the second antibody comprise: TGAVTTSNY (SEQ ID NO: 68); GTN; and ALWYSNYWV (SEQ ID NO: 69).
Optionally, the modulator is capable of binding simultaneously to IL-1R1 and NLRP3. Optionally, or additionally, the modulator is capable of binding sequentially to IL-1R1 and NLRP3.
Optionally, the light chain of a bi-specific antibody of the present invention has the amino acid sequence:
Optionally, the heavy chain of a bi-specific antibody of the present invention has the amino acid sequence:
By “binding simultaneously” to both of IL-1R1 and NLRP3, it is meant that the modulator is capable of binding to each of IL-1R1 and/or NLRP3, whether said IL-1R1 and/or NLRP3 are formed as a complex, or whether they are not formed as a complex.
In a second aspect, the invention provides an NLRP3 inflammasome modulator as defined herein in relation to the first aspect of the invention for use in the treatment or prophylaxis of an inflammation-related disorder, optionally an inflammatory eye disease, such as glaucoma, as described in the first aspect of the invention, in which the NLRP3 inflammasome is known to play a key role in the disease pathogenesis.
An advantage of the bispecific antibody as the modulator is that it can be used at lower, and thus less toxic, concentrations than single antibodies, therefore, reducing cytotoxicity potential. Being bi-specific allows for a more stable antibody with greater purity.
Being a biological has a longer half live thus confers a major advantage over small molecule inhibitors.
In a third aspect, the present invention provides a method for the treatment and/or prophylaxis of an inflammation-related disorder, optionally an inflammatory eye disease, such as glaucoma, the method comprising the steps of:
providing a therapeutically effective amount of an NLRP3 inflammasome modulator as defined herein in relation to the first aspect of the invention which suppresses activation and/or signalling of the NLRP3 inflammasome, and
administering the therapeutically effective amount of said compound to a subject in need of such treatment.
In a fourth aspect, the present invention provides for use of an NLRP3 inflammasome modulator as defined herein in relation to the first aspect of the invention in the preparation of a medicament for the treatment of an inflammation-related disorder, optionally an inflammatory eye disease, such as glaucoma.
In a fifth aspect, the present invention provides a method to reduce or prevent or treat at least one symptom of an inflammation-related disorder, optionally an inflammatory eye disease, such as glaucoma, in a subject comprising selectively inhibiting and/or reducing activation of the inflammasome pathway by the use of an NLRP3 inflammasome modulator as defined herein in relation to the first aspect of the invention.
Optionally, the modulator is for use in the treatment or prevention of at least one symptom of an inflammation-related disorder in a subject comprising selectively inhibiting and or reducing activation of the inflammasome pathway by the use of the modulator.
Optionally, the light chain of a bi-specific antibody has the amino acid sequence of SEQ ID NO: 57 and the heavy chain of a bi-specific antibody the amino acid sequence of SEQ ID NO: 59 and may be referred to herein as InflaMab or Inflamab.
Optionally, InflaMab may have disease modifying effects in systemic conditions such as but not limited to Atherosclerosis, whereby it prevents/inhibits inflammation therefore preventing plaque build up and/or plaque rupture thus reducing risk of myocardial infarction.
Optionally, InflaMab may have disease modifying effects in eye diseases such as but not limited to Glaucoma, whereby it prevents/inhibits inflammation, reduces intraocular pressure and/or prevents loss of retinal ganglion cells and axons, protecting the optic nerve and preserving visual acuity, and/or preventing blindness.
Optionally, InflaMab may have disease modifying effects in neurological conditions such as but not limited to Alzheimer's Disease, whereby it prevents/inhibits inflammation, reduces/inhibits amyloid plaque load, and/or prevents of cognitive dysfunction.
The modulator as defined herein may have utility in individuals with multi-morbidities or co-morbidities associated with inflammation.
Optionally, the modulator as defined in relation to of any of the aforementioned aspects of the invention, denoted as Inflamab, is a 210 kiloDalton (kDa) bispecific mouse antibody composed of two pairs of light chain and two pairs of heavy chains with scFv domains fused to the N-terminal, complexed together via disulphide bonds.
As used herein, an “inflammation-related disorder” includes, but is not limited to, Atherosclerosis, inflammatory eye conditions such as Age-Related Macular degeneration, Dry Eye Syndrome, Glaucoma, Sjogren's syndrome, Diabetes, Inflammatory eye disease, Depression, Alzheimer's Disease, Parkinson's Disease, Inflammatory Bowel Disease, Rheumatoid Arthritis, Ageing, Dermatological conditions and Cancer.
Optionally, the subject is a mammal, such as a human.
The term “antibody” should be construed as covering any binding member or substance having a binding domain with the required specificity. The antibody of the invention may be a monoclonal antibody, or a fragment, functional equivalent or homologue thereof. The term includes any polypeptide comprising an immunoglobulin binding domain, whether natural or wholly or partially synthetic. Chimeric molecules comprising an immunoglobulin binding domain, or equivalent, fused to another polypeptide are therefore included.
Fragments of a whole antibody can perform the function of antigen binding. Examples of such binding fragments are; a Fab fragment comprising of the VL, VH, CL and CH1 antibody domains; an Fv fragment consisting of the VL and VH domains of a single antibody; a F(ab′)2 fragments, a bivalent fragment comprising two linked Fab fragments; a single chain Fv molecule (scFv), wherein a VH domain and a VL domain are linked by a peptide linker which allows the two domains to associate to form an antigen binding site; or a bi- or tri-specific antibody, which may be multivalent or multispecific fragments constructed by gene fusion.
A fragment of an antibody or of a polypeptide for use in the present invention, generally means a stretch of amino acid residues of at least 5 to 7 contiguous amino acids, often at least about 7 to 9 contiguous amino acids, typically at least about 9 to 13 contiguous amino acids, more preferably at least about 20 to 30 or more contiguous amino acids and most preferably at least about 30 to 40 or more consecutive amino acids.
The term “antibody” includes antibodies which have been “humanized”. Methods for making humanised antibodies are known in the art.
Aptamers are peptide molecules that bind to specific target molecules. Aptamers are in the realm between a small molecule and a biologic. They exhibit significant advantages relative to antibody therapeutics in terms of size, synthetic accessibility and modification.
Modulators as described herein may be used in assays, such as ELISAs, to detect NLRP3 from human blood or tissue samples. Thus, in a further aspect, the present invention provides a kit comprising one or more modulators of the first aspect of the invention. Optionally, the kit further comprises instructions for use of said kit. Optionally, the kit is for detecting NLRP3 in human cells, in blood or tissue samples.
In the drawings:
In a particular use or method of treatment, the modulator of the invention, e.g. the bi-specific antibody, acts according to steps which include:
1. Targeting the bispecific antibody to IL-1R1 to allow internalisation and entry of the antibody into the cell.
2. Targeting the antibody to NLRP3 in order to inhibit NLRP3 inflammasome assembly and subsequent IL-1β release from the cell, thus reducing inflammation.
3. Targeting the antibody to IL-1R1 triggers internalisation of the IL-1R1, thus making less IL-1R1 available for IL-1β binding resulting in further inhibiting the potentiation and amplification of inflammation.
Such a modulator of the first aspect of the invention provides a surprisingly additive inhibitory effect upon the inflammasome as a whole, not only the NLRP3 protein portion and thus will provide a more effective inhibitor of inflammasome-related diseases.
IL-1R1 Fc is transiently expressed and purified in HEK293 cells. The purified protein is evaluated for size and purity by SDS PAGE and tested for endotoxin levels. Finally the protein is evaluated for activity by ELISA.
A mammalian expression vector encoding interleukin-1 receptor (IL-1R1) Fc fusion protein was transfected into HEK293 cells. The expressed Fc fusion protein was subsequently purified from cell culture supernatant using standard chromatography techniques. The concentration and purity were determined for the purified product.
DNA coding for the amino acid sequence of IL-1R1 Fc (see Example 1A) was synthesised and cloned into a mammalian transient expression plasmid pD2610-v1 (DNA2.0). IL-1R1 Fc was expressed using a HEK293 cell based transient expression system and the resulting antibody containing cell culture supernatants was clarified by centrifugation and filtration. Two lots of IL-1R1 Fc were purified (using AKTA chromatography equipment) from cell culture supernatants via protein A affinity chromatography. Purified protein was dialysed/buffer exchanged into phosphate buffered saline solution. The purity of the recombinant protein was determined to be >95%, as judged by Sodium Dodecyl Sulphate Polyacrylamide gels (
Abbreviations are as follows; ND, not determined.
The aim of this project is to generate a monoclonal antibody against IL-1R1. A population of 5 mice were immunised and screened for positive immune responses. After selecting a suitable candidate for fusion, splenocytes were fused with partner cells to produce a population of hybridomas. This population underwent a series of limiting dilutions and screening assays to produce fully monoclonal cell lines.
The product name “F237 5D1-1A8-2A5” refers to one of the 10 chosen monoclonal hybridoma cell lines. The name is comprised of components describing the production pathway at each stage. Each hybridoma selected from the post-fusion screening and each limiting dilution was given a number corresponding to the plate number and well location on that plate for which the hybridoma was chosen (i.e. 5D1-1A8-2A5). This nomenclature traces the derivation of each individual hybridoma allowing for clear differentiation in the screening process.
1This is the media that was used for all cultures following fusion and screening.
Once the immunogen (IL-1R1) was purified, these solutions were diluted to 200 μg/ml in sterile, EF-PBS and aliquoted in volumes of 600 μl for immunisation and 150 μl for boosts and ELISA screening. These aliquots were labelled and stored at −20° C.
A population of 5 BalbC mice were immunised subcutaneously with 200 μl of a 1:1 emulsion of Freund's Adjuvant Complete (Sigma) and a 600 μl aliquot of IL-1R1 prepared herein. Two weeks after the 1st immunisation, the population was immunized with a 2nd injection at the same volumes and concentrations as the original injection only using Freund's Adjuvant Incomplete (Sigma) instead. One week after the 2nd immunisation, the mice were tagged by ear punches (NP, RP, LP, LRP, 2LP), and test bleeds were screened as described herein for preliminary results. Three weeks after the 2nd immunisation, the population was immunised a 3rd time using the same method as the 2nd injection. One week after the 3rd immunisation, test bleeds were screened, and the mouse with an ear tag of RP was then selected for fusion.
Tail bleeds were taken from the population of 5 BalbC mice and centrifuged at 8000 rpm for 10 min at RT (room temperature). The blood serum from each mouse was collected, loaded onto the plate the same day as screening, and stored at −20° C. This screening was performed twice for the selection of a suitable mouse for fusion.
The day prior to screening, a Maxi Sorp plate was coated by adding 100 μl/well of 50 mM sodium carbonate coating buffer (pH 9.5) containing the IL-1R1 at 1 μg/ml. A separate coating solution was prepared by diluting APO-A1 in the same coating buffer at 1 μg/ml. These solutions were loaded onto the plate in alternating rows so as to provide two wells to load each sample that demonstrates a positive and negative result. This plate was incubated overnight at 4° C. in static conditions.
The following morning, coating buffer was removed, and 200μl/well of blocking solution (4.0% w/v semi skim milk powder, 1×PBS) was added and agitated at 150 rpm for 2 hr at RT. The plate was washed three times with PBS-T (0.1% v/v Tween 20). PBS was loaded into each well at 100 μl/well, and 1 μl of each test bleed serum was loaded into each positive and negative well. The plate was incubated at 150 rpm (Grant Shaker) for 2 hrs at room temperature. These samples were then removed and washed four times with PBS-T. 100 μl/well, GAM-HRP diluted 1:5000 (Sigma, UK) was added, and the plate was incubated for 1 hr with agitation at 150 rpm at RT. The secondary antibody was removed, and the plate was washed four times with PBS-T and once in PBS. 100 μl/well of TMB substrate solution was added and incubated at 37° C. for 10 minutes. 50 μl M HCl was added per well and the plate immediately read at 450 nm on a Tecan Sunrise plate reader.
After the second test bleed ELISA screening, the mouse with an ear tag of RP was selected for fusion by expressing the most positive immune response.
One week after the 3rd and final immunization, a boost injection was given to BalbC mouse RP by injecting 100 μl of aliquoted IL-1R1 at 200 μg/ml without any adjuvant.
One week before fusion, SP2 cells were broken out from liquid nitrogen and were passaged in 10% FCS DMEM supplemented with 1% Pen/Strep, 1% L-glutamine until 3×12 ml T75 flasks were 75%-90% confluent on the day of fusion. On the day of the fusion, SP2 cells were dislodged by tapping the flask and were centrifuged at 1000 rpm for 5 min at 37° C. The cells were resuspended in 20 ml SFM DMEM, centrifuged again, and resuspended in 10 ml SFM DMEM. SP2 cells were stored in a Sterilin tube in SFM at 37° C., 6% CO2 until needed.
After euthanasia, the spleen was aseptically removed from the mouse that showed the strongest immune response. Splenocytes were extracted by puncturing both ends of the spleen with a fine gauge needle and flushing 10-15 ml SFM DMEM. Splenocytes were transferred to a sterilin tube and washed twice with 20 ml serum free DMEM by centrifugation at 1300 rpm for 5 min at 37° C. and gently removing the supernatant. The splenocytes were resuspended in 10 ml Serum free DMEM in a sterilin tube.
Using the SP2 cells stored at 37° C., the SP2 cells were added to the splenocytes. This SP2/splenocytes culture was centrifuged at 1300 rpm for 5 min at 37° C. After discarding the supernatant, 1 ml PEG was added to the SP2/splenocytes culture dropwise while stirring continuously over a period of 3 min. 1 ml SFM DMEM was added to the fusion mixture and stirred for 4 min. 10 ml SFM DMEM was added dropwise to the fresh culture and incubated for in 37° C. water bath for 5 min. The cells were then centrifuged at 1000 rpm for 5 min at 37° C. The pellet was resuspended in 200 mL HATR media and was plated at 200 μl/well in 10×96 well culture plates which were incubated 11 days at 37° C. in 6% CO2 prior to screening.
Eleven days after fusion, protoclones were screened by ELISA. 20× Maxi Sorp 96 well plates were coated as described herein using APO-A1 at 1 μg/ml as the negative control for specificity. The coating solution was removed and the plates were blocked as described herein. Samples were prepared by removing 160 μl of supernatant from each well of the ten fusion plates, limiting dilution plates, or 24-well plates and transferring to fresh 96 well culture plates containing 50 μl 1×PBS. After 2 hours of blocking, the blocking solution was removed, and the plates were washed 3× with PBS-T. The samples from each dilution plate were loaded onto the ELISA plates at 100 μl/well by adding 1 row from each dilution plate per 2 rows on the ELISA plates to account for specificity of the coating antigens. Two wells per ELISA were incubated with 100 μl 1×PBS as a negative control. These samples were incubated at 150 rpm for 2 hours at room temperature.
Once the hybridoma populations were expanded in 24-well plates and growing well, a secondary screen was performed to select the most specific and highest producing populations for rounds of limiting dilutions.
Both limiting dilutions were performed for 1-3 protoclones each by seeding 2-4×96-well plates at 1 cell/well in 200 μl culture/well. The plates were prepared by counting each culture in the 24-well plate and were diluted 10× as an intermediate dilution, then were diluted to 200 cells in 40 ml. The culture was plated at 200 μl/well and left to incubate at 37° C., 6% CO2 for 7-10 days until the wells were 80%-90% confluent. Each well for both limiting dilutions were screened by ELISA as described herein.
Following the second limiting dilution, 10 clones were selected for expansion in a 24 well plate. Each clone was left to grow in 37° C., 6% CO2 for 6 days until each well became 80%-90% confluent. When the clones were well established in the 24-well plates, each clone at 1 ml/well was transferred to a T25 flask containing 5 ml fresh 10% HATR DMEM for cryopreservation.
Once the clones were well established (80%-90% confluency) in T25 flasks, each 5 ml culture was centrifuged at 1000 rpm for 5 min at 37° C. and was resuspended in 1 ml of fresh 10% DMEM HATR media. Each 1 ml culture was transferred to a cryovial containing 300 μl of a 1:1 ratio of FCS to DMSO. The vials were sealed and placed in a Mr. Frosty and transferred to the −70° C. freezer for short-term storage.
Anti-IL-1R1 produced from clone F237 5D1-1A8-2A5 was selected for sequencing. Once the culture was confluent in the T25 flask, the supernatant was discarded. The cells were dislodged by cell scraping into 2 ml fresh media and were centrifuged at 7,600 rpm for 5 min at RT. The supernatant was then discarded and the pellet was flash frozen in liquid nitrogen and placed in −70° C. until ready for mRNA extraction.
A colony of mice were immunised with an IL-1R1 immunogen (produced in house in CHO cells) and regular test bleeds were taken over an 11 week period. Test bleeds were screened for IL-1R1 mAb expression levels using ELISA and internalisation capability using the pHrodo fluorescent assay (Thermo Fisher Scientific, UK https://www.thermofisher.com/order/catalog/product/P35369 and https://www.sigmaaldrich.com/catalog/product/sigma/m4280?lang=en®ion=GB).
One week after the 2nd immunisation, a tail bleed was taken from each of the 5 mice and screened against IL-1R and APO-A1 for determination of a suitable animal for fusion and a relative specificity of the polyclonal antibody produced—see
After screening sera from tail bleeds, the mouse with an ear tag of RP was selected for the fusion of its splenocytes to fusion partner SP2 culture as it demonstrated the best immune response—see
Once the wells in each plate had reached 70%-80% confluency, the plates were screened by ELISA against IL-1R1 and APO-A1. The hybridoma population producing the highest responses were selected for expansion in a 24-well plate—see
Clones were selected from the post-fusion screening and were arrayed into a 24 well plate for expansion followed by a secondary screening that determines suitable protoclones for the first round of limiting dilutions—see
Once the 1st limiting dilution plates were confluent, the limiting dilution was screened by ELISA against IL-1R1 and APO-A1. Eleven hybridoma populations were selected from F237 2H12, F237 5D1, and F237 7E6 that demonstrated the highest and most specific response—see
When the clones became confluent in the 24-well plate, each clone was screened by ELISA against IL-1R1 and APO-A1. F237-5D1-1A8 was selected for the 2nd round of limiting dilution over 4×96 well plates—see
Once the wells in each plate had reached 70%-80% confluency, the plates were screened by ELISA against IL-1R1 and APO-A1. The hybridoma population producing the highest response and highest specificity were selected for expansion in a 24-well plate and cryopreservation—see
Fluorescence microscopic images taken from THP1 macrophages treated with LPS and ATP to induce the expression of the IL-1R1—see
THP1 macrophages (see
The aim of the project was to produce a range of antibodies against IL-1R1. Once the mice were immunised and screened, RP was selected for fusion. 10 monoclonal hybridoma cell lines were produced from two rounds of limiting dilutions. Each population was selected by highest production and highest specificity for IL-1R1. These final cell lines have been frozen down, and the antibody expressed by this cell line will be sequenced.
mRNA was extracted from the hybridoma cell pellets. Total RNA was extracted from the pellets using a conventional RNA extraction protocol. Cell pellets were homogenised using RNA STAT-60 reagent. Upon addition of chloroform, the homogenate separated into an aqueous phase and an organic phase, and total RNA was isolated in the aqueous phase. Isopropanol was used to precipitate the RNA, followed by ethanol washes and solubilisation in water.
cDNA was created from the RNA by reverse-transcription with an oligo(dT) primer. PCR reactions are set up using variable domain primers to amplify both the VH and VL regions of the monoclonal antibody DNA giving the following bands—see
The VH and VL products were cloned into the Invitrogen sequencing vector pCR2.1 and transformed into TOP10 cells and screened by PCR for positive transformants. Selected colonies were picked and analyzed by DNA sequencing on an ABI3130×1Genetic Analyzer, the result may be seen below.
TVRISCKAS
GYPFTTAG
LQINVQKMSGKGLKWIGW
MNTQSEV
PKYAEEFKGRIAFSLETAASTAYLQINN
LKTEDTATYFC
AKSVYFNWRYFDV
WGAGTTVTVSS
The variable domain is highlighted in BOLD.
The Complementarity Determining Regions (CDRs) are underlined as determined by the IMGT numbering system (Lefranc, M.-P. et al., Nucleic Acids Research, 27, 209-212 (1999))—see
Key to amino acid shading, in
Blue shaded circles are hydrophobic (non-polar) residues in frameworks 1-3 at sites that are hydrophobic in the majority of antibodies.
Yellow shaded circles are proline residues.
Squares are key residues at the start and end of the CDR.
Red amino acids in the framework are structurally conserved amino acids.
VL Consensus Amino Acid Sequence:
GDRVSLSCRASQSISDYLSWYQQRSHESPRLIIK
Y
AS
QSISGIPSRFSGSGSGSDFTLSINSVEPEDVGV
YYC
QHGHSFPLT
FGSGTKLELKRADAAPTVSIFPP
The variable domain is highlighted in BOLD.
The Complementarity Determining Regions (CDRs) are underlined as determined by the IMGT numbering system (Lefranc, M.-P. et al., Nucleic Acids Research, 27, 209-212 (1999))—see
Key to amino acid shading, in
Blue shaded circles are hydrophobic (non-polar) residues in frameworks 1-3 at sites that are hydrophobic in the majority of antibodies.
Yellow shaded circles are proline residues.
Squares are key residues at the start and end of the CDR.
Red amino acids in the framework are structurally conserved amino acids.
Design of a peptide (antigen) to NLRP3 that will generate an antibody response capable of inhibiting formation of the NLRP3 inflammasome.
The NLRP-3 inflammasome is a heterogenous protein complex that forms in mammalian cells in response to inflammatory stimulus, the ability to regulate and attenuate its formation could have important therapeutic potential for a range of inflammatory disorders. A peptide will be designed, derived from the NALP3 protein sequence which should generate antibodies capable of blocking the binding of NALP3 to the other protein components in the NLRP3 inflammasome complex.
NLRP3 activation occurs by the self-assembly of NLRP protein with ASC, which is a hetero-complex of CARD, PYD and Caspase-1 domains. NLRP3 and ASC interact through their respective PYD domains, which contain a large proportion of highly conserved charged amino acid residues which interact to form electrostatic interactions, which stabilize the complex—see
Peptide selection was concentrated on the sequence region from 1-61 which has been studied extensively and is involved in the interaction with ASC (Vajjhala et al, 2012). The region has also been well modelled by crystallography, with a number of PDB structures available for this domain. PDB model 3QF2, which consists of the PYR domain of NLRP3 was selected as the most useful PDB structural reference. Initial peptide candidate sequences were selected on the basis of accessibility and visibility as potential epitopes, and also degree of similarity between mouse and human sequence, whilst maintaining difference with other NLRP variants. These initial 3 peptides were modelled into 3D structures using NovaFold.
NovaFold is a 3D protein modelling software that uses the I-TASSER algorithm, a combination of template based threading (from PDB) and ab initio methods to predict the folding of a protein or peptide. It is used in this context to predict the presence of secondary structural features within a peptide which are known to be exhibited by the sequence in situ within the parent protein. This can help optimise the selection of a peptide sequence which best reflects the folding and proximity based relationships within the parent protein, helping to maximize the potential of the immunogenic protein resulting in an antibody with full activity towards the corresponding epitope in the full length protein.
Four distinct sequences were modelled using NovaFold, and the resulting highest scoring models were assessed and then aligned to the parent NLRP3 structure as represented by PDB:3QF2.
The modelling and comparison indicates that peptide FUS_746_001 is the preferred candidate for use as a peptide immunogen. In addition to demonstrating the greatest alignment with the model of the parent protein, it also demonstrates high similarity in prediction of secondary structure and is an accessible epitopic target.
Peptide FUS_746_001 Alignment using a Novafold predicted structure is shown in
The modelling of the software should always be taken as advisory, rather than definitive and interpreted on this basis, particularly if strong secondary structural features are not known to be found within the parent molecule. With this in mind, however, the modelling suggests that peptide FUS_746_001, sequence EDYPPQKGCIPLPRGQTEKADHVD (SEQ ID NO: 30) would be a best candidate for selection as the immunogen for this project on the basis of alignment to the parent protein, and predicted antigenicity. The peptide also shows only a few points of difference between the mouse and human sequence, which supports the production of an antibody response in mice that may allow for cross reactivity between these species, which is also a desirable feature, whilst minimising cross reactivity to other NLRP types. Note: It is recommended to add an N-terminal Cys residue for cross-linking to KLH.
The NLRP3 peptide was synthesised by bioSynthesis Inc, Texas, conjugated to KLH using maleimide coupling through an additional C-terminal cysteine residue.
ELISA screening results of 1st bleed from mice immunised with NLRP3 immunogen—see
A population of 5 mice were immunised and screened for positive immune responses. After selecting a suitable candidate for fusion, splenocytes were fused with partner cells to produce a population of hybridomas. This population underwent a series of limiting dilutions and screening assays to produce fully monoclonal cell lines.
The product name “F226 7A7-1E1-2D5” refers to one of the 10 chosen monoclonal hybridoma cell lines. The name is comprised of components describing the production pathway at each stage. Each hybridoma selected from the post-fusion screening and each limiting dilution was given a number corresponding to the plate number and well location on that plate for which the hybridoma was chosen (i.e. 7A7-1E1-2D5). This nomenclature traces the derivation of each individual hybridoma allowing for clear differentiation in the screening process.
1This is the media that was used for all cultures following fusion and screening.
Once the immunogen; NLRP3 peptide-KLH conjugate (bioSynthesis Inc, Texas) was received, these solutions were diluted to 400 μg/ml in sterile, EF-PBS and aliquoted in volumes of 600 μl for immunisation and 150 μl for boosts and ELISA screening. These aliquots were labelled and stored at −20° C.
A population of 5 BalbC mice were immunised subcutaneously with 200 μl of a 1:1 emulsion of Freund's Adjuvant Complete (Sigma) and a 600 μl aliquot of NLRP3 peptide-KLH conjugate prepared herein. Two weeks after the 1st immunisation, the population was immunized with a 2nd injection at the same volumes and concentrations as the original injection only using Freund's Adjuvant Incomplete (Sigma) instead. One week after the 2nd immunisation, the mice were tagged by ear punches (NP, RP, LP, LRP, 2LP), and test bleeds were screened as described herein for preliminary results. Three weeks after the 2nd immunisation, the population was immunised a 3rd time using the same method as the 2nd injection. One week after the 3rd immunisation test bleeds were screened, and RP was then selected for fusion.
Tail bleeds were taken from the population of 5 BalbC mice and centrifuged at 8000 rpm for 10 min at RT. The blood serum from each mouse was collected, loaded onto the plate the same day as screening, and stored at −20° C. This screening was performed twice for the selection of a suitable mouse for fusion.
The day prior to screening, a Maxi Sorb plate was coated by adding 100 μl/well of 50 mM sodium carbonate coating buffer (pH 9.5) containing the free NLRP3 peptide at 1 μg/ml. A separate coating solution was prepared by diluting APO-A1 in the same coating buffer at 1 μg/ml. These solutions were loaded onto the plate in alternating rows so as to provide two wells to load each sample that demonstrates a positive and negative result. This plate was incubated overnight at 4° C. in static conditions.
The following morning coating buffer was removed, and 200μl/well of blocking solution (4.0% w/v semi skim milk powder, 1×PBS) was added and agitated at 150 rpm for 2 hr at RT. The plate was washed three times with PBS-T (0.1% v/v Tween 20). PBS was loaded into each well at 100 μl/well, and 1 μl of each test bleed serum was loaded into each positive and negative well. The plate was incubated at 150 rpm (Grant Shaker) for 2 hrs at room temperature. These samples were then removed and washed four times with PBS-T. 100 μl/well GAM-HRP diluted 1:5000 (Sigma, UK) was added, and the plate was incubated for 1 hr with agitation at 150 rpm at RT. The secondary antibody was removed, and the plate was washed four times with PBS-T and once in PBS. 100 μl/well of TMB substrate solution was added and incubated at 37° C. for 10 minutes. 50 μl 1M HCl was added per well and the plate immediately read at 450 nm on a Tecan Sunrise plate reader.
After the second test bleed ELISA screening, RP was selected for fusion by expressing the most positive immune response.
One week after the 3rd and final immunization, a boost injection was given to BalbC mouse RP by injecting 100 μl of aliquoted IL-1R at 200 μg/ml without any adjuvant.
One week before fusion, SP2 cells were broken out from liquid nitrogen and were passaged in 10% FCS DMEM supplemented with 1% Pen/Strep, 1% L-glutamine until 3×12 ml T75 flasks were 75%-90% confluent on the day of fusion. On the day of the fusion, SP2 cells were dislodged by tapping the flask and were centrifuged at 1000 rpm for 5 min at 37° C. The cells were resuspended in 20 ml SFM DMEM, centrifuged again, and resuspended in 10 ml SFM DMEM. SP2 cells were stored in a Sterilin tube in SFM at 37° C., 6% CO2 until needed.
After euthanasia, the spleen was aseptically removed from the mouse that showed the strongest immune response. Splenocytes were extracted by puncturing both ends of the spleen with a fine gauge needle and flushing 10-15 ml SFM DMEM. Splenocytes were transferred to a sterilin tube and washed twice with 20 ml serum free DMEM by centrifugation at 1300 rpm for 5 min at 37° C. and gently removing the supernatant. The splenocytes were resuspended in 10 ml Serum free DMEM in a sterilin tube.
Using the SP2 cells stored at 37° C., the SP2 cells were added to the splenocytes. This SP2/splenocytes culture was centrifuged at 1300 rpm for 5 min at 37° C. After discarding the supernatant, 1 ml PEG was added to the SP2/splenocytes culture dropwise while stirring continuously over a period of 3 min. 1 ml SFM DMEM was added to the fusion mixture and stirred for 4 min. 10 ml SFM DMEM was added dropwise to the fresh culture and incubated for in 37° C. water bath for 5 min. The cells were then centrifuged at 1000 rpm for 5 min at 37° C. The pellet was resuspended in 200 mL HATR media and was plated at 200 μl/well in 10×96 well culture plates which were incubated 11 days at 37° C. in 6% CO2 prior to screening.
Eleven days after fusion, protoclones were screened by ELISA. 20× Maxi Sorb 96 well plates were coated as described in section 0 using APO-A1 at 1 μg/ml as the negative control for specificity. The coating solution was removed and the plates were blocked as described herein. Samples were prepared by removing 160 μl of supernatant from each well of the ten fusion plates, limiting dilution plates, or 24-well plates and transferring to fresh 96 well culture plates containing 50 μl 1×PBS. After 2 hours of blocking, the blocking solution was removed, and the plates were washed 3× with PBS-T. The samples from each dilution plate were loaded onto the ELISA plates at 100 μl/well by adding 1 row from each dilution plate per 2 rows on the ELISA plates to account for specificity of the coating antigens. Two wells per ELISA were incubated with 100 μl 1×PBS as a negative control. These samples were incubated at 150 rpm for 2 hours at room temperature.
Once the hybridoma populations were expanded in 24-well plates and growing well, a secondary screen was performed to select the most specific and highest producing populations for rounds of limiting dilutions.
Both limiting dilutions were performed for 1-3 protoclones each by seeding 2-4×96-well plates at 1 cell/well in 200 μl culture/well. The plates were prepared by counting each culture in the 24-well plate and were diluted 10× as an intermediate dilution, then were diluted to 200 cells in 40 ml. The culture was plated at 200 μl/well and left to incubate at 37° C., 6% CO2 for 7-10 days until the wells were 80%-90% confluent. Each well for both limiting dilutions were screened by ELISA as described in section 0.
Following the second limiting dilution, 10 clones were selected for expansion in a 24 well plate. Each clone was left to grow in 37° C., 6% CO2 for 6 days until each well became 80%-90% confluent. When the clones were well established in the 24-well plates, each clone at 1 ml/well was transferred to a T25 flask containing 5 ml fresh 10% HATR DMEM for cryopreservation.
Once the clones were well established (80%-90% confluency) in T25 flasks, each 5 ml culture was centrifuged at 1000 rpm for 5 min at 37° C. and was resuspended in 1 ml of fresh 10% DMEM HATR media. Each 1 ml culture was transferred to a cryovial containing 300 μl of a 1:1 ratio of FCS to DMSO. The vials were sealed and placed in a Mr. Frosty and transferred to the −70° C. freezer for short-term storage.
Anti-NLRP3 produced from clone F226 7A7-1E1-2D5 was selected for sequencing. Once the culture was confluent in the T25 flask, the supernatant was discarded. The cells were dislodged by cell scraping into 2 ml fresh media and were centrifuged at 7,600 rpm for 5 min at RT. The supernatant was then discarded and the pellet was flash frozen in liquid nitrogen and placed in −70° C. until ready for mRNA extraction.
A colony of mice were immunised with NLRP3 peptide-KLH conjugate (designed by bioinformatics and synthesised by bioSynthesis Inc, Texas) and regular test bleeds were taken over an 11 week period. Test bleeds were then screened against the antigen.
Upon identification of positive mice, a fusion was performed and supernatant from hybridoma clones were then validated. The specific antibodies then underwent limiting dilution and cloning to produce a stable hybridoma cell line against NLRP3.
The antibodies were screened using ELISA against the target protein—NLRP3—and clones with a signal of at least 3 times the background were selected. Antibodies from 24 clones were selected and further in house testing was performed to pick the best 6 clones.
One week after the 2nd immunisation, a tail bleed was taken from each of the 5 mice and screened against unconjugated NLRP3 peptide and APO-A1 for determination of a suitable animal for fusion and a relative specificity of the polyclonal antibody produced—see
After screening sera from tail bleeds, 2RP was selected for the fusion of its splenocytes to fusion partner SP2 culture as it demonstrated the best immune response—see
Once the wells in each plate had reached 70%-80% confluency, the plates were screened by ELISA against NLRP3 peptide and APO-A1. The hybridoma population producing the highest responses were selected for expansion in a 24-well plate—see
Clones were selected from the post-fusion screening and were arrayed into a 24 well plate for expansion followed by a secondary screening that determines suitable protoclones for the first round of limiting dilutions. 3 clones were selected and limiting dilutions prepared—see
Once the 1st limiting dilution plates were confluent, the limiting dilution was screened by ELISA against NLRP3 Peptide and APO-A1. 31 hybridoma populations were selected from F226 5B7 and 7A7 that demonstrated the highest and most specific response. No clones from 3D4 were suitable—see
When the clones became confluent in the 24-well plate, each clone was screened by ELISA against NLRP3 peptide and APO-A1. F226 5137-1E10, 5B7-1G2, 7A7-1C4 and 7A7-1E1 selected for the 2nd round of limiting dilution over 2×96 well plates per clone—see
Once the wells in each plate had reached 70%-80% confluency, the plates were screened by ELISA against NLRP3 peptide and APO-A1. The 24 hybridoma populations producing the highest response and highest specificity were selected for expansion in a 24-well plate and cryopreservation—see
Dot Blot analysis is shown in
Western Blot Analysis is shown in
The aim was to produce a range of antibodies against NLRP3 that were functional in preventing assembly of the NLRP3 inflammasome. Once the mice were immunised and screened, 2RP was selected for fusion. 24 monoclonal hybridoma cell lines were produced from two rounds of limiting dilutions. Each population was selected by highest production and highest specificity for NLRP3. The clone F226 7A7-1E1-2D5 was shown to be most active in preventing NLRP3 assembly in the in vitro assay. These final cell lines have been frozen down, and the antibody expressed by this 7A7-1E1-2D5 will be sequenced for the next stage in the production of the bi-specific, InflaMab.
mRNA was extracted from the hybridoma cell pellets on 23 Feb. 2016. Total RNA was extracted from the pellets using Fusion Antibodies Ltd in-house RNA extraction protocol (see Example 3).
cDNA was created from the RNA by reverse-transcription with an oligo(dT) primer. PCR reactions are set up using variable domain primers to amplify both the VH and VL regions of the monoclonal antibody DNA giving the following bands (see
The VH and VL products were cloned into the Invitrogen sequencing vector pCR2.1 and transformed into TOP10 cells and screened by PCR for positive transformants. Selected colonies were picked and analyzed by DNA sequencing on an ABI3130×1 Genetic Analyzer, the result may be seen below.
YY
MYWVRQTPEKRLEWVAT
ISDGGTYT
YYPDSVKGRFTISRDNAKNNLYL
QMNSLKSEDTAMYYC
ARGWVSTMVKLLSSFPY
WGQGTLVTVSAAKTTPPS
The variable domain is highlighted in BOLD.
The Complementarity Determining Regions (CDRs) are underlined as determined by the IMGT numbering system (Lefranc, M.-P. et al., Nucleic Acids Research, 27, 209-212 (1999))—see
Key to amino acid shading, in
Blue shaded circles are hydrophobic (non-polar) residues in frameworks 1-3 at sites that are hydrophobic in the majority of antibodies.
Yellow shaded circles are proline residues.
Squares are key residues at the start and end of the CDR.
Red amino acids in the framework are structurally conserved amino acids.
SNY
ANWVQEKPDHLFTGLIG
GTN
NRAPGVPARFSGSLIGDKAALTITGAQ
TEDEAIYFC
ALWYSNYWV
FGGGTKLTVLGQPKSSPSVTLFPPSTEELSL
The variable domain is highlighted in BOLD.
The Complementarity Determining Regions (CDRs) are underlined as determined by the IMGT numbering system (Lefranc, M.-P. et al., Nucleic Acids Research, 27, 209-212 (1999))—see
Key to amino acid shading, in
Blue shaded circles are hydrophobic (non-polar) residues in frameworks 1-3 at sites that are hydrophobic in the majority of antibodies.
Yellow shaded circles are proline residues.
Squares are key residues at the start and end of the CDR.
Red amino acids in the framework are structurally conserved amino acids.
The variable domain sequences of the monoclonal antibodies IL-1R1 and NLRP3 were sequenced.
The antibody was constructed using the IL-1R1 antibody with an IgG2a mouse constant domain sequence. A short linker was added to the C-terminal end of the heavy chain and the NLPR3 variable domains in an ScFv format with the linker (GGGGS)3 was attached to create the bispecific. The DNA and amino acid sequences can be found below.
The constructs were cloned into ATUM vector pD2610-v5 and verified by sequencing.
The aim was to carry out transient transfections of InflaMab vector DNA in ExpiCHO cells. Following culture, expressed InflaMab was purified from the culture supernatant and QC analysis carried out on the purified protein.
InflaMab is a 210 kiloDalton (kDa) bispecific mouse antibody composed of two pairs of light chain and two pairs of heavy chains with ScFv domains fused to the N-terminal, complexed together via disulphide bonds. A mammalian expression vector encoding InflaMab was transfected into ExpiCHO cells. The expressed antibody was subsequently purified from clarified culture supernatant via protein A affinity chromatography. The concentration of purified antibody was measured using a NanoDrop Lite, Thermofisher and purity was evaluated using SDS-PAGE.
DNA coding for the amino acid sequences of InflaMab was synthesised and cloned into the mammalian transient expression plasmid pD2610-v5 (Atum).
Suspension adapted ExpiCHO cells (Thermo Fisher, UK) were routinely cultured at 1.0-3.0×105 cells/ml every 2-3 days in 500 ml vented Erlenmeyer flasks (Corning, Netherlands) agitated at 135 rpm at 37° C. 8% CO2. Plasmid DNA for transfection was isolated using a Purelink Hipure plasmid filter maxiprep kit (Thermo Fisher, UK) as per the manufacturer instructions. DNA was quantified using a Nano Drop lite spectrophometer as per the manufacturer instructions.
Twenty-four hours prior to transfection, ExpiCHO cells were seeded at a concentration of 4.0×106 cells/ml in ExpiCHO expression medium and grown overnight at 135 rpm, 37° C. 8% CO2. On the day of transfection, 250 ml ExpiCHO cells were diluted to a final density of 6.0×106 cells/m1 in ExpiCHO expression medium. 1.0 μg/ml of plasmid DNA and 0.32% (v/v) Expifectamine CHO reagent (Thermo Fisher) were diluted separately in 4% (v/v) OptiPro SFM (Thermo Fisher). The Expifectamine CHO/Optipro complex was added to the Plasmid DNA/Optipro complex dropwise. The transfection mixture was immediately added to the ExpiCHO cells. Transfected cells were incubated overnight at 135 rpm, 37° C., 8% CO2.
Twenty hours post transfection, cultures were supplemented with 0.6% (v/v) Expi CHO enhancer (Thermo Fisher, UK) and 24% ExpiCHO feed (Thermo Fisher, UK). The viability of the cells were closely monitored and cultures were harvested on day 8 by centrifugation at 4000 rpm for 40 minutes at room temperature.
Purifications were performed using AKTA (GE Healthcare) chromatography equipment. Prior to use, all AKTA equipment was thoroughly sanitized using 1M NaOH. Following centrifugation, filtered (0.22 pm) cell culture supernatant was applied to an AKTA system fitted with a 1 ml HiTrap Protein A column (equilibrated with wash buffer). Following loading, the column was washed with 20 column volumes of wash buffer. Bound antibody was step eluted with 10 column volumes of elution buffer. All eluted fractions were neutralised with Tris pH 9.0 buffer. Eluted fractions corresponding to elution peak were selected for overnight dialysis into PBS. The purity of the antibody was >95%, as judged by SDS-polyacrylamide midi gels.
Sodium Dodecyl Sulphate Polyacrylamide Electrophoresis (SDS PAGE) was carried out on purified antibody using standard methods.
Molecular weight marker shown in kilodaltons. Lanes, in
InflaMab is ≥95% pure as judged by analysis of SDS-polyacrylamide gels. Under reducing conditions, both heavy and the light chains of the antibody are visible and are observed at the expected molecular weight of approximately 80 and 27 kDa, respectively. Under non-reducing conditions, a single major band and several minor bands are observed. The additional bands (impurities) are likely the result of non-glycosylated IgG and IgG degradation products (e.g. a single [partial] light chain, a combination of two heavy and one light chain, two heavy chains, two heavy and one light chain).
Purified InflaMab was quantified using a Nanodrop Lite spectrophotometer and the extinction coefficient 330,685 M−1 cm−1 (or 1.0 mg/ml=A280 of 1.7 [assuming a MW=184,276 Da]), as per the manufacturer instructions. A total of 17.5 mg of InflaMab was purified from 0.3 litres of transfected cell culture supernatant.
Material: Purified Antibody
Origin: Produced in a Chinese Hamster (Cricetulus griseus) Ovary cell line (no hamster or animal component added)
Purity: 95% pure (as determined by SDS-polyacrylamide gels [
Endotoxin (EU/mg): Not determined
Concentration (mg/ml): 3.15 (as determined by measurement of absorbance at 280 nm)
Mycoplasma: Not determined
Volume (ml): 5.57
Total (mg): 17.55
Container: 2 ml tube×3
Volume per container: 2.0 ml×2; 1.57 ml×1
Net weight: Not determined
Formulation: Provided as a 0.2 pm sterile-filtered solution in PBS.
Shipped: Ice packs (+4° C.)
Storage: 4° C. refrigerated
Non-hazardous, non-infectious. For research use only.
Inflamab prevents IL-1β release—see
Inflamab prevents caspase-1 activation in THP1 cells—see
Internalization of Inflamab—see
Glaucoma is the leading cause of irreversible blindness worldwide, characterized by the progressive loss of retinal ganglion cells (RGCs). A recent study estimates that approximately 60 million people worldwide currently suffer from glaucoma and with the rapidly growing aging population this number is predicted to exceed 100 million by 2040 [1]. Unfortunately, there is no cure for glaucoma and intraocular pressure (IOP) reduction remains the only treatment strategy for all types of glaucoma [2]. However, while elevated IOP is a major risk factor for the development of glaucoma, lowering IOP alone does not prevent disease progression and many patients still experience significant vision loss even after IOP has been successfully lowered [3]. Moreover, the increasing incidence of normal tension glaucoma [4, 5] and the absence of neurodegeneration in some patients with elevated IOP [6] indicate that IOP-independent mechanisms also contribute to the development and progression of glaucoma and highlight the need for developing IOP-independent neuroprotective therapies to prevent disease progression and preserve vision.
Glaucoma is a complex multifactorial disease and while the exact mechanisms that mediate axon degeneration and death of RGCs are not well understood, there is growing evidence that axon damage in the optic nerve head (ONH) precedes death of the RGCs [7, 8]. Moreover, the axon damage in the ONH has been linked to glial activation and inflammation [9, 10]. In human and experimental models of glaucoma, activated astrocytes [10, 11] and activated microglia [9, 12] are detected in ONH and coincides with increased expression of proinflammatory cytokines such as IL-1β and TNFα and neurotoxic mediators such as Nitric Oxide (NO), Reactive Oxygen Species (ROS), and Glutamate [12-14]. However, how elevated IOP triggers glial activation and how the inflammatory cascade is amplified and sustained is not well understood.
The NLRP3 inflammasome is an intracellular multi-protein complex that triggers inflammation in response to signals generated by infectious organisms, as well as endogenous signals associated with cell stress and tissue damage [15]. Dysregulation of the NLRP3 inflammasome has been implicated in several neurodegenerative diseases, including Alzheimer's disease and multiple sclerosis [16] but, most recently, activation of the NLRP3 inflammasome has been associated with the death of RGCs following retinal ischemia reperfusion injury and optic nerve crush [17, 18].
Focusing specifically on the ONH region, where glial activation and inflammation has been linked to early axon damage, it has been demonstrated that NLRP3 is constitutively expressed in the ONH of mouse and human [
In vitro studies clearly demonstrate the ability of Inflamab (NLRP3/IL1R1) to inhibit inflammasome activation (
NLRP3 is constitutively expressed in the mouse and human optic nerve head—see
NLRP3 is constitutively expressed in optic nerve head astrocytes of normal (non-glaucomatous) human eyes—see
NLRP 3 inflammasome assembly in the ONH coincides with induction of inflammatory mediators at 7 days post microbead injection—see
Macrophage infiltration and inflammatory gene expression in WT and ASC KO mice following elevated IOP—see
RGC and axon analysis in WT, ASC KO, and NLRP3 KO mice—see
RGC analysis in WT mice treated with the NLRP3 inhibitor MCC950—see
RGC function in WT mice treated with the NLRP3 inhibitor InflaMab—see
The invention is not limited to the embodiments described herein but can be amended or modified without departing from the scope of the present invention.
| Number | Date | Country | Kind |
|---|---|---|---|
| 1815045.8 | Sep 2018 | GB | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2019/074744 | 9/16/2019 | WO | 00 |
