CN108686221B - Synergistic antitumor drug - Google Patents

Synergistic antitumor drug Download PDF

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CN108686221B
CN108686221B CN201810824134.3A CN201810824134A CN108686221B CN 108686221 B CN108686221 B CN 108686221B CN 201810824134 A CN201810824134 A CN 201810824134A CN 108686221 B CN108686221 B CN 108686221B
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颜光美
肖晓
贺嵩敏
龚守芳
林子青
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Guangzhou Virotech Pharmaceutical Co Ltd
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Abstract

The invention belongs to the field of biological medicines, relates to a synergistic antitumor drug, and particularly relates to application of the antitumor drug such as a DNA-PK (DNA-dependent protein kinase) inhibitor and an oncolytic virus in preparation of the antitumor drug. The invention discovers for the first time that anti-tumor drugs with various targets, such as DNA-PK inhibitor, can be used for preparing an oncolytic virus anti-tumor synergist. The invention also relates to a pharmaceutical composition containing the anti-tumor drug and the oncolytic virus, a drug set containing the anti-tumor drug and the oncolytic virus, and application of the anti-tumor drug and the oncolytic virus in treating tumors, in particular tumors insensitive to the oncolytic virus.

Description

Synergistic antitumor drug
Technical Field
The invention belongs to the field of biological medicine, and relates to application of combination of an antitumor drug such as a DNA-PK protein inhibitor and the like and an oncolytic virus in preparation of the antitumor drug.
Background
Oncolytic viruses (oncolytics) are a class of replication-competent viruses that selectively infect and kill tumor cells without damaging normal cells. Oncolytic virus therapy (oncolytical virotherapy) is an innovative tumor-targeted therapeutic strategy that utilizes natural or genetically engineered viruses to selectively infect and replicate in tumor cells to achieve the effects of targeted lysis and killing of tumor cells, but without damage to normal cells.
Oncolytic virus M1 is a Togaku virus of genus Alavirus of Togaviridae, isolated from Moso mosquitos of genus Katsu, Hainan, China. Our previous studies showed that virus M1 has high selectivity and good safety. The application of the compound in the aspect of preparing the antitumor drug is already described in Chinese patent application 201410425510.3. The M1 virus can selectively cause tumor cell death without affecting normal cell survival, and has a very good application prospect in the aspect of tumor resistance. However, different tumors have different sensitivities to the M1 virus, and for some tumors, the oncolytic effect of the M1 virus alone is not ideal. For example, as described in chinese patent application 201410425510.3, when M1 is used as an antitumor agent, the effect on colorectal cancer, liver cancer, bladder cancer and breast cancer is not as significant as that on pancreatic cancer, nasopharyngeal cancer, prostate cancer and melanoma; glioma, cervical cancer and lung cancer are the second; gastric cancer is the least significant.
Screening of compounds that increase the tumor therapeutic effect of oncolytic viruses is expected to increase the anti-tumor spectrum and anti-tumor intensity of oncolytic viruses. In the previous Chinese patent application 201510990705.7, chrysophanol and its derivatives are used as antitumor synergist of oncolytic virus, and the combination of chrysophanol and its derivatives can reduce the survival rate of tumor cells to 39.6%, but there is great space for improving the anticancer strength. In addition, the mechanism of action of such a combination is not clear, nor is it known which other substances that have not been reported to potentiate oncolytic viruses, which substances may produce a potentiation with them, and the magnitude of the potentiation.
Disclosure of Invention
An object of the present invention is to provide an oncolytic virus antitumor potentiator.
It is another object of the present invention to provide an anticancer potentiator capable of selectively enhancing the killing effect of oncolytic viruses on tumor cells without affecting normal cells.
The invention also aims to provide application of the antitumor drug in preparing an alphavirus antitumor synergist.
It is another object of the present invention to provide an anti-neoplastic pharmaceutical composition or kit which allows the oncolytic virus to exert a better anti-neoplastic effect.
The invention also aims to provide a safe and effective oncolytic virus synergistic medicine for tumors insensitive to oncolytic viruses.
The invention realizes the purpose through the following technical scheme:
the inventor discovers, through research and screening, that the anti-tumor drugs with various target spots can enhance the oncolytic effect of the oncolytic virus. The target may be ATM (ataxia-telangiectasia mutated), ALK (adaptive methylation kinase), Akt (protein kinase B), Bcr-Abl (branched linker gene-ablson kinase 1), Chk (checkpoint kinase), c-MET (platelet growth regulator), DNA-PK, DNA synthesis, DHFR (platelet kinase), EGFR (epidermal growth regulator), FGFR (fibroblast growth regulator), GSK-3 (glycosylation kinase-3), HDAC (mammalian cell kinase/kinase), protein kinase B (kinase/kinase), protein kinase B, protein kinase/kinase B, protein kinase, protein kinase, protein, PDGFR (platelet derived growth factor receptor), proteaseme, PI3K (phosphorinoside 3-kinase), PKC (protein kinase C), p38MAPK (p38mitogen-activated protein kinases), PLK (polar lipid kinase), Syk (macromolecular associated tyrosine kinase), topoisomerease, TGF-beta/Small (transforming growth factor-beta/small), VEGFR (vascular endothelial growth factor). Different target anti-cancer drugs show the oncolytic enhancement effect of oncolytic viruses with different strengths. Among them, the most prominent synergistic effect is DNA-dependent protein kinase (DNA-PK). DNA-dependent protein kinase (DNA-PK) is a serine/threonine protein kinase consisting of 3 subunits, belongs to phosphatidylinositol-3 kinase-related kinase family (PIKK), is a key enzyme for repairing DNA damage, mainly participates in non-homologous end connection to repair broken DNA double chains, and also participates in an apoptosis signal transduction pathway induced by ionizing radiation, immune cells V (D) J recombination, immune cell differentiation, cell response under insulin stimulation and other processes, and has the function of maintaining telomere stability. There have been many reports in the literature that DNA-PK is highly expressed in tumor cells, and inhibition of DNA-PK can hinder DNA repair and thus induce tumor cell death.
The inventor uses DNA-PK interference fragment (Si RNA) to inhibit the expression of the gene and reduce the expression amount of the corresponding protein, and as a result, the inventor finds that the single interference of the DNA-PK and the non-interference do not cause the cell morphological lesion, the single application of the M1 virus does not cause the cell morphological lesion, and the single combined application of the interference of the DNA-PK and the M1 virus group causes the remarkable cell morphological lesion.
The inventors further can significantly enhance the oncolytic effect of oncolytic virus by inhibiting DNA-PK. The inventor adopts a series of compounds (such as NU7441, NU7026, KU-0060648 and the like) for inhibiting DNA-PK activity to act on tumor cells in a synergistic way with oncolytic virus, particularly M1 virus, and finds that the DNA-PK activity compounds can enhance the anti-tumor effect in a synergistic way with the oncolytic virus.
The invention discovers for the first time that anti-tumor drugs with various target points such as DNA-PK inhibitor and the like can be used as anti-tumor synergist/drug resistance reversal agent of oncolytic virus.
The invention provides application of an antitumor drug in preparation of a oncolytic virus antitumor synergist/drug resistance reversal agent.
The invention also provides the application of the oncolytic virus in the preparation of an antitumor drug synergist or a drug resistance reversal agent.
The anti-tumor drug is selected from one or more of ATM inhibitors, ALK inhibitors, Akt inhibitors, Bcr-Abl inhibitors, Chk inhibitors, c-MET inhibitors, DNA synthesis inhibitors, DHFR inhibitors, EGFR inhibitors, FGFR inhibitors, FAK inhibitors, GSK-3 inhibitors, HDAC inhibitors, Hedgehog inhibitors, HSP90 inhibitors, IkB/IKK inhibitors, JAK inhibitors, Kinesin inhibitors, MEK inhibitors, mTOR inhibitors, Microtubuli Associated inhibitors, Mutant pan Raf inhibitors, Wnt/beta-catenin inhibitors, PDGFR inhibitors, Proteasome inhibitors, PI3K inhibitors, PKC inhibitors, p38MAPK inhibitors, PLK inhibitors, Syk inhibitors, Topoisomere inhibitors, TGF-a/Smad inhibitors, VEGFR inhibitors and DNA-PK inhibitors.
The antitumor agents may be substances or means for inhibiting the production of the above-listed targets, inhibiting the activity of the targets, or degrading the targets, and include chemical and biological substances or means. As exemplary embodiments, the ATM inhibitor is selected from KU-60019 or CP-466722; the ALK inhibitor is selected from Crizotinib; the Akt inhibitor is selected from MK-2206; the Bcr-Abl inhibitor is selected from Ponatinib; the Chk inhibitor is selected from AZD 7762; the c-MET inhibitor is selected from SU 11274; the DNA synthesis inhibitor is selected from Gemcitabine or Oxaliplatin; the DHFR inhibitor is selected from Pemetrexed; the EGFR inhibitor is selected from Lapatinib Ditosylate or Gefitinib; the FGFR inhibitor is selected from PD 173074; the FAK inhibitor is selected from PF-562271; the GSK-3 inhibitor is selected from CHIR-99021 HCl; said HDAC inhibitor is selected from Vorinostat; the Hedgehog inhibitor is selected from Vismodegib; the HSP90 inhibitor is selected from Ganetespib or AUY 922; the IkB/IKK inhibitor is selected from TPCA-1; the JAK inhibitor is selected from Tofacitinib or Cyt 387; the Kinesin inhibitor is selected from SB 743921; the MEK inhibitor is selected from GSK 1120212; the mTOR inhibitor is selected from Rapamycin; the Microtubule Associated inhibitor is selected from Paclitaxel or Docetaxel; the Mutant pan Raf inhibitor is selected from Vemurafenib; the Wnt/beta-catenin inhibitor is selected from FH 535; the PDGFR inhibitor is selected from Imatinib; the Proteasome inhibitor is selected from Bortezomib; the PI3K inhibitor is selected from CAL-101 or GDC-0941; the PKC inhibitor is selected from Sotrastaurin; the p38MAPK inhibitor is selected from BIRB 796; the PLK inhibitor is selected from BI 6727; the Syk inhibitor is selected from R935788; the Toposisomerase inhibitor is selected from Doxorubicin; the TGF-beta/Smad inhibitor is selected from LY 2157299; the VEGFR inhibitor is selected from Axitinib or Vandetanib.
Drug resistance reversal agents are those in which, when some oncolytic viruses are used as an antineoplastic agent to treat tumors, some tumors are less sensitive to the oncolytic viruses or are resistant to the oncolytic viruses, and in such cases, the oncolytic viruses can be used in combination with antineoplastic agents such as DNA-PK inhibitors (as drug resistance reversal agents) to reverse the resistance of the tumors to the oncolytic viruses; alternatively, conversely, when some antineoplastic drugs are used to treat tumors in which the presence of the tumor is not too sensitive to the drug, or in which the tumor is resistant to the drug, an oncolytic virus (as a resistance-reversing agent) may be used in conjunction with the drug to reverse the resistance of the tumor to the drug.
In a preferred embodiment, the invention provides, inter alia, the use of a DNA-PK inhibitor for the preparation of an oncolytic anti-neoplastic potentiator/resistance-reversal agent.
The DNA-PK inhibitor refers to a substance which can inhibit the activity of DNA-PK, or inhibit the activity or expression of any subunit (such as DNA-PKcs subunit, KU70 subunit or KU80 subunit), or block the assembly of the subunits, or degrade DNA-PK.
The DNA-PK inhibitors include those disclosed up to now. Possibly, there may be other DNA-PK inhibitors that have been studied to have similar inhibitory effects on DNA-PK in the future, and combinations of these DNA-PK inhibitors with oncolytic viruses are also within the scope of the present invention.
As a preferred embodiment, the DNA-PK inhibitor includes, but is not limited to, the following compounds or derivatives thereof having DNA-PK inhibitory effect, or pharmaceutically acceptable salts, solvates, tautomers, isomers thereof: NU7441(KU-57788), NU7026(LY293646), KU-0060648, LTURM34, CC-115, PIK-90, Wortmannin (Wortmannin), LY302341, M3814 (nedistertib), SF2523, Compound 401. The mode of obtaining the compound may be selected from, but is not limited to: chemically isolated or synthesized by itself or purchased from commercial sources.
In some embodiments of the invention, the DNA-PK protein inhibitor is NU7441 (formula 1), NU7026 (formula 2), KU0060648 (formula 3), or a combination thereof.
Figure BDA0001742071500000061
Alternatively, the DNA-PK protein inhibitor may be LTURM34 (formula 4), CC-115 (formula 5), PIK-90 (formula 6), Wortmannin (Wortmannin, formula 7), LY302341 (formula 8), M3814 (nedistertib, formula 9), SF2523 (formula 10), Compound 401 (formula 11), or the like.
Figure BDA0001742071500000071
Figure BDA0001742071500000081
In some preferred embodiments of the present invention, the DNA-PK inhibitor further comprises means or materials for DNA-PK gene expression inhibition, including but not limited to means or materials for gene interference, gene editing, gene silencing or gene knock-out.
As an alternative embodiment, the DNA-PK gene expression suppressing means is selected from one or more of DNA, RNA, PNA, DNA-RNA hybrid. They may be single-stranded or double-stranded.
DNA-PK inhibitors may include small inhibitory nucleic acid molecules, such as short interfering rna (sirna), double-stranded rna (dsrna), microrna (mirna), ribozymes, and small hairpin rna (shrna), all of which reduce or eliminate gene expression of any subunit of DNA-PK.
In one embodiment of the invention, the DNA-PK inhibitor is selected from gene interfering materials. As a more preferred embodiment, the DNA-PK inhibitor is selected from any one of SEQ ID NO 1, SEQ ID NO 2 or SEQ ID NO 3.
These small inhibitory nucleic acid molecules may include first and second strands that hybridize to each other to form one or more double-stranded regions, each strand being about 18-28 nucleotides in length, about 18-23 nucleotides in length, or 18, 19, 20, 21, 22 nucleotides in length. In addition, single strands may also include regions that are capable of hybridizing to each other to form a duplex, such as in shRNA molecules.
These small inhibitory nucleic acid molecules may include modified nucleotides while maintaining this ability to attenuate or eliminate the expression of DNA-PK. Modified nucleotides can be used to improve in vitro or in vivo properties, such as stability, activity and/or bioavailability. These modified nucleotides may include deoxynucleotides, 2 ' -methyl nucleotides, 2 ' -deoxy-2 ' -fluoro nucleotides, 4 ' -trinucleotides, Locked Nucleic Acid (LNA) nucleotides, and/or 2 ' -O-methoxyethyl nucleotides, etc. Small inhibitory nucleic acid molecules, such as short interfering RNA (siRNA), may also contain 5 '-and/or 3' -cap structures to prevent degradation by exonucleases.
In some embodiments, the double-stranded nucleic acid of the small inhibitory nucleic acid molecule contains blunt-ended, or pendent, nucleotides. Other nucleotides may include nucleotides that result in misplacement, bulge, cycling, or wobble base pairs. The small inhibitory nucleic acid molecules may be formulated for administration, for example, by liposome encapsulation, or incorporated into other carriers (e.g., biodegradable polymer hydrogels, or cyclodextrins).
In other preferred embodiments of the present invention, the DNA-PK inhibitor further comprises one or more of an antibody, a functional fragment of an antibody, a peptide, and a peptidomimetic. For example, an antibody, functional fragment of an antibody, peptide, or peptidomimetic that binds to any functional domain of any subunit of DNA-PK. For example, DNA-binding domain, catalytic domain or Ku protein binding domain of DNA-PK. Wherein the antibody may be a monoclonal antibody, a polyclonal antibody, a multivalent antibody, a multispecific antibody (e.g., bispecific antibody), and/or an antibody fragment linked to DNA-PK. The antibody may be a chimeric antibody, a humanized antibody, a CDR-grafted antibody or a human-type antibody. Antibody fragments may be, for example, Fab, Fab ', F (ab') 2, Fv, Fd, single chain Fv (scFv), disulfide-bonded FV (sdFv), or VL, VH domains. The antibody may be in a conjugated form, e.g., conjugated to a label, a detectable label, or a cytotoxic agent. The antibody may be of the IgG isotype (e.g., IgG1, IgG2, IgG3, IgG4), IgA, IgM, IgE, or IgD.
In another preferred embodiment of the invention, the DNA-PK protein inhibitor is an interfering RNA fragment of DNA-PK. As a more preferred embodiment, the DNA-PK inhibitor is selected from any one of SEQ ID NO 1, SEQ ID NO 2 or SEQ ID NO 3.
The oncolytic virus is selected from one or more of alphavirus, Getavirus, adenovirus, vaccinia virus, measles virus, vesicular stomatitis virus and herpes simplex virus; preferably an alphavirus, more preferably selected from the group consisting of M1 virus, togavirus, or a combination thereof.
A single oncolytic virus strain may also be administered. In other embodiments, multiple strains and/or types of oncolytic viruses may also be used.
In some embodiments, the M1 virus is an M1 virus having a collection number of CCTCC V201423 (deposited at the chinese culture collection, collection date 2014, 7 months and 17 days). The deposited virus is also described in chinese patent application No. 201410425510.3. As a virus that is likely to be derived from the same strain, Genbank access No. ef011023 records the sequence of one strain M1. Getavirus is a virus with homology as high as 97.8% with M1 virus (Wen et al viruses genes.2007; 35(3): 597-. The alphavirus of the invention comprises M1 or Getavirus with the sequence identity of 97.8 percent or more with the M1 strain.
The oncolytic virus of the present invention may particularly refer to an existing oncolytic virus, but does not exclude natural variations or viruses with mutations, modifications, sequence additions, deletions, etc. Such viruses with variations, mutations, modifications, sequence additions or deletions are likely to have similar oncolytic effects, or even slightly reduced, or enhanced effects, and the like. These situations are within the scope of the present invention. The inhibitor for inhibiting DNA-PK is a substance (such as a compound, an amino acid sequence, a nucleotide sequence and the like) or a tool and the like which can knock down or influence the gene expression of any subunit of the DNA-PK, the protein amount or the protein activity of any subunit, block the assembly of the subunits, or degrade the DNA-PK. Modifications, substitutions, changes and the like of inhibitory compounds or genetic tools may be made by those skilled in the art, and are intended to be within the scope of the invention as defined by the appended claims.
The invention also provides the application of the combination of the anti-tumor medicament and the oncolytic virus in the preparation of the medicament for treating tumors.
The invention also provides a pharmaceutical composition for treating tumors, which comprises the anti-tumor medicament and the oncolytic virus, in particular a DNA-PK inhibitor and the oncolytic virus.
The invention also provides a pharmaceutical kit for treating tumors, which comprises the anti-tumor medicament as described above and an oncolytic virus, in particular a DNA-PK inhibitor and an oncolytic virus.
A pharmaceutical package differs from a composition in that an anti-tumor drug, such as a DNA-PK inhibitor, is in a different dosage form than the oncolytic virus, but is packaged separately (e.g., in a pill, or capsule, or tablet or ampoule, containing the anti-tumor drug, such as a DNA-PK inhibitor; and another pill, or capsule, or tablet or ampoule, containing the oncolytic virus). In some embodiments, the oncolytic virus, an antineoplastic agent, such as a DNA-PK inhibitor, and a combination of the oncolytic virus and the antineoplastic agent, such as a DNA-PK inhibitor, may also contain one or more adjuvants. The adjuvant refers to a component which can assist the curative effect of the medicament in the medicament composition. The pharmaceutical kit may also contain separately packaged antineoplastic drugs, such as DNA-PK inhibitors, and separately packaged oncolytic viruses. Administration of the antineoplastic drug, e.g., a DNA-PK inhibitor, and the oncolytic virus in the pharmaceutical kit may be simultaneous administration or administration in any sequential order, e.g., administration of the antineoplastic drug, e.g., a DNA-PK inhibitor, prior to oncolytic virus, or administration of the antineoplastic drug, e.g., a DNA-PK inhibitor, after oncolytic virus, or both. In various embodiments, the patient may be a mammal. In some embodiments, the mammal may be a human.
As an embodiment, the pharmaceutical composition or the pharmaceutical kit may further comprise a pharmaceutically acceptable carrier.
In one embodiment, the dosage form of the pharmaceutical composition or the pharmaceutical kit includes, but is not limited to, lyophilized powder for injection, tablet, capsule, patch, etc.; preferably in the form of an injectable formulation; more preferably an intravenous injection.
As a preferred embodiment, the pharmaceutical kit comprises an independently packaged antineoplastic drug, such as a DNA-PK protein inhibitor or derivative thereof, or a combination thereof, and an independently packaged oncolytic virus.
As a preferred embodiment, the antineoplastic agents include, but are not limited to, KU-60019, CP-466722, Crizotinib, MK-2206, Ponatinib, AZD7762, SU11274, Gemcitabine, Oxaliplatin, Pemetrexed, Lapatinib Ditosylate, Gefitinib, PD173074, PF-562271, CHIR-99021HCl, Vorinostat, Vismodegib, Ganetespib, AUY922, TPCA-1, Tofacitin, Cyt387, SB 743921, GSK1120212, Rapamycin, Paclitaxel, Docetaxel, Vemurafenib, FH535, Imatinib, Bortezomib, CAL-101, GDC-0941, Sotramycin, BInetration 796, BIcity 6727, Vemurafenib, WO 705726, Vemurafenib, WO 5726, Vemurafenib 705726, Vemurafenib 705726, Vemurafenib 5726, Vemurafenib 705726, or a pharmaceutically acceptable salt thereof, or a tautomer thereof.
As a preferred embodiment, the antitumor drug includes, but is not limited to, compounds inhibiting DNA-PK protein activity, such as NU7441 (formula 1), NU7026 (formula 2), KU0060648 (formula 3), LTURM34 (formula 4), CC-115 (formula 5), PIK-90 (formula 6), Wortmannin (Wortmannin, formula 7), LY302341 (formula 8), M3814 (nedistertib, formula 9), SF2523 (formula 10), Compound 401 (formula 11). Or means or materials for DNA-PK gene expression suppression tools, including but not limited to, gene interference, gene silencing, and gene editing or knockout. The DNA-PK inhibitor may preferably be NU7441, KU0060648, NU7026 or a combination thereof.
In the composition or the medicine set, the ratio of the antitumor drug (such as NU7441, KU0060648, NU7026, LTURM34, CC-115, PIK-90, Wortmannin, LY302341, M3814, SF2523 or Compound 401 and the like) to the oncolytic virus is optionally: 0.01-200 mg:103~109PFU; preferably 0.1-200 mg:104~109PFU; further preferably 0.1-100 mg:105~109PFU;
The preferred dosages used are: the antitumor drug (such as NU7441, KU0060648, NU7026, LTURM34, CC-115, PIK-90, Wortmannin, LY302341, M3814, SF2523 or Compound 401) is used in the range of 0.01mg/kg to 200mg/kg, and the oncolytic virus is used at an MOI titer of 10 to 103To 109(PFU/kg); more preferably, DNA-PK inhibitors (e.g., NU7441, KU0060648, NU7026, LTURM34, CC-115, PIK-90, Wortmannin, LY302341, M3814, SF2523, Compound 401, etc.) are used in the range of 0.1mg/kg to 200mg/kg, while oncolytic viruses are used at titers of MOI of from 104To 109(PFU/kg); still more preferably, DNA-PK inhibitors (e.g., NU7441, KU0060648, NU7026, LTURM34, CC-115, PIK-90, Wortmannin, LY302341, M3814, SF2523, and Compound 401, etc.) are used in the range of 0.1mg/kg to 100mg/kg, while oncolytic virus use titers are MOI from 105To 109(PFU/kg)。
In one embodiment, the oncolytic virus is selected from one or more of alphavirus, togavirus, adenovirus, vaccinia virus, measles virus, vesicular stomatitis virus and herpes simplex virus. Preferably, the oncolytic virus is an alphavirus, more preferably an M1 virus, a togavirus or a combination thereof.
In one embodiment, the tumor is a solid tumor or a hematological tumor. In one embodiment, the solid tumor is liver cancer, colorectal cancer, bladder cancer, breast cancer, cervical cancer, prostate cancer, glioma, melanoma, pancreatic cancer, nasopharyngeal cancer, lung cancer, or gastric cancer. In a preferred embodiment, the tumor is an oncolytic virus insensitive tumor. In a more preferred embodiment, the tumor is a tumor that is not susceptible to M1 oncolytic virus.
Compared with the prior art, the invention has the following beneficial effects:
the invention discovers that the anti-tumor drug such as DNA-PK inhibitor (such as NU7441, KU0060648 or NU7026 and the like) can increase the anti-tumor effect of the oncolytic virus so as to improve the treatment effectiveness of the oncolytic virus as the anti-tumor drug. Cytological experiments prove that the oncolytic virus is respectively combined with a DNA-PK inhibitor (such as NU7441, KU0060648, NU7026 and the like) to be applied, so that morphological lesion of tumor cells can be obviously caused, and the inhibiting effect on the tumor cells is obviously enhanced.
Unexpectedly, NU7441, KU0060648 or NU7026, etc. as antiviral compounds, when used in combination with oncolytic viruses, can enhance the oncolytic ability of the viruses. For example, in example 3, the antiviral compound NU7441 or KU0060648 or NU7026 and M1 virus was used in combination to act on human colorectal cell carcinoma HCT116 strain, significantly reducing the survival rate of tumor cells. In examples 2 and 3, when colorectal cancer cells were treated with M1 virus (MOI ═ 1) alone, tumor cell survival was 93.8%; when 1 mu M NU7441 is used for treating colorectal cancer cells, the survival rate of tumor cells is 76.7%; when 1 μ M NU7441 is used together with M1 virus with the same titer, the tumor cells with cytomorphosis are obviously increased, and the survival rate of the tumor cells is greatly reduced to 23.1%. Compared with the anti-tumor effect of the M1 virus alone, the anti-tumor effect of the NU7441 and the M1 is obviously improved when the NU7441 and the M1 are used together. It can be seen that the greatly improved oncolytic effect of NU7441 in combination with M1 is derived from the synergistic mechanism between NU7441 and M1 viruses, and does not act through the anti-tumor mechanism of NU 7441.
The inventor uses chrysophanol and derivatives thereof as an anti-cancer synergist of M1 virus, and tests show that the survival rate of tumor cells is reduced to 39.6% after 50 mu M chrysophanol is combined with M1 virus, while the invention shows that the survival rate of tumor cells is reduced to 23.1% after 1 mu M NU7441 is combined with M1(MOI is 1) virus. Compared with chrysophanol and derivatives thereof, the M1 anti-tumor synergist provided by the invention has the advantages that the tumor killing rate is remarkably improved, meanwhile, the NU7441 has only one fiftieth of the pharmaceutical effective dose of chrysophanol, the effect is quick, the medicine is two thirds of the effect of chrysophanol when in use (the chrysophanol is treated for 72 hours, and the NU7441 is treated for 48 hours), and the medicine has remarkable superiority.
Furthermore, the inventor also uses the mTOR inhibitor everolimus as a reference of the M1 virus anticancer synergist, and found that the survival rate of tumor cells is reduced to 36.7% by experiment after 10 μ M of everolimus is combined with (MOI ═ 1) M1 virus, while the survival rate of tumor cells is significantly reduced to 23.1% by combination of 1 μ M of NU7441 and M1 virus (MOI ═ 1) (see example 3). Compared with everolimus, the M1 anti-tumor synergist provided by the invention has the advantages that the tumor killing rate is obviously improved, and meanwhile, the effective dose of NU7441 in the medicine is only one tenth of that of everolimus, so that the M1 anti-tumor synergist has obvious superiority.
Drawings
FIG. 1 Multi-target screening of oncolytic Virus M1 synergist NU 7441;
A. drug screening flow charts; HCT116 cells were seeded in 96-well plates and divided into two groups: a single drug adding group: treatment with different doses of the compound; combination group: treating with different doses of compound and virus, and detecting the survival rate of cells by using an MTT method after 72 hours;
B. comparing the areas under the curves; drawing a cell survival curve by using the cell survival rate, and calculating the area under the curve;
C. the scatter plot was plotted using the area under the curve, with the first compound ranked as NU 7441.
FIG. 2DNA-PK inhibitor NU7441 increases the oncolytic effect of oncolytic virus M1 on various tumor cells without affecting normal cells.
FIG. 3 the oncolytic effect of various DNA-PK inhibitors in synergy with M1 oncolytic virus.
FIG. 4 knock-down of the DNA-PKcs subunit enhances the oncolytic effect of M1 virus;
A. inhibition of DNA-PKcs on colorectal HCT116 enhances the oncolytic effect of the virus;
B. inhibition of DNA-PKcs in pancreatic cancer BxPC-3 enhances the oncolytic effect of the virus.
Figure 5NU7441 combined treatment with M1 virus significantly inhibited human graft tumor growth;
A. dosing schedule on colorectal cancer HCT116 animal model;
the combined treatment of NU7441 and M1 virus can obviously inhibit the growth of transplanted tumor of human colorectal cancer strain;
the combined treatment of the NU7441 virus and the M1 virus has no obvious influence on the body weight of tumor-bearing (HCT116) nude mice;
D. dosing schedule on BxPC-3 animal dosing model for pancreatic cancer;
the combined treatment of the NU7441 virus and the M1 virus obviously inhibits the growth of the transplanted tumor of the human pancreatic cancer strain;
the combined treatment of the NU7441 virus and the M1 virus has no obvious influence on the body weight of tumor-bearing (BxPC-3) nude mice;
G. comparing the volume of the rectal tumor at the end point;
H. pancreatic tumor volume size at the end node was compared.
Detailed Description
The following embodiments are further illustrative of the present invention, but the embodiments of the present invention are not limited to the following examples, and any equivalent changes or modifications made in accordance with the principles and concepts of the present invention should be considered as the scope of the present invention.
The materials and experimental procedures used in the present invention are, unless otherwise specified, conventional materials and procedures.
Example 1 Multi-target screening of oncolytic Virus M1 potentiator NU7441
Materials:
high-glucose DMEM medium (available from Corning), human colorectal cancer cell HCT116 (available from ATCC cell bank), M1 virus (accession number CCTCC V201423), 47 compounds (available from seleck, table 1) for different targets, inverted phase contrast microscope, and automatic enzyme-linked immunosorbent assay plate reader.
TABLE 1 anti-cancer drugs at different targets
Figure BDA0001742071500000151
Figure BDA0001742071500000161
The method comprises the following steps: as shown in FIG. 1A
a) And (3) culturing the cells: human colorectal cancer HCT116 was grown in DMEM complete medium containing 10% FBS, 100U/ml penicillin and 0.1mg/ml streptomycin; all cell lines were placed in 5% CO2Culturing and subculturing in a constant-temperature closed incubator (relative humidity 95%) at 37 ℃, and observing the growth condition by an inverted microscope. And (4) carrying out passage once in about 2-3 days, and taking the cells in the logarithmic growth phase for formal experiments.
b) Cell processing and morphological observation: selecting cells in logarithmic growth phase, preparing cell suspension with DMEM complete culture solution (containing 10% fetal calf serum and 1% double antibody), and culturing at 2.5 × 104Density per well was seeded in 24-well culture plates. For each compound in table 1, cells were treated with different concentrations of compound alone, M1 virus (MOI ═ 1), M1 virus (MOI ═ 1) in combination with different concentrations of drug, and changes in cell morphology were observed under an inverted phase contrast microscope after 48 hours, with no addition of M1 virus and compound as controls.
c) MTT reacts with intracellular succinate dehydrogenase: at 48h of culture, 20 μ l of MTT (5mg/ml) was added to each well and incubation continued for 4 hours, at which time particulate blue-violet formazan crystals formed within viable cells were observable under microscopic examination.
d) Dissolving formazan particles: the supernatant was carefully aspirated, the crystals formed were dissolved in DMSO (100. mu.l/well), shaken on a micro-shaker for 5min, and then the optical density (OD value) of each well was measured on an enzyme-linked detector at a wavelength of 570 nm. Each set of experiments was repeated 3 times. Cell survival rate-OD value of drug-treated group/OD value of control group × 100%.
As a result:
according to the experimental results, a survival rate curve is respectively drawn for single-use drugs and combined drugs, the area between the curve and the x axis of the coordinate axis is the area under the curve (AUC), and the difference of the area under the curve (DAUC) is calculated according to a formula (AUC is used alone-AUC combined use)/AUC combined use (shown in figure 1B). A scatter plot was prepared based on the difference in area under the curve, and it can be seen from FIG. 1C and Table 1 that the difference in AUC of the DNA-PK inhibitor NU7441 was as high as 2.58, ranking 1. The oncolytic effect of the NU 7441-sensitized virus M1 is most obvious and most probable.
Example 2DNA-PK inhibitor NU7441 increases the oncolytic effect of oncolytic virus M1 on various tumor cells without affecting normal cells
Materials:
high-glucose DMEM medium (purchased from Corning), human bladder cancer cell line T24 (purchased from ATCC cell bank), human glioma cell line U-87MG (purchased from ATCC cell bank), human pancreatic cancer cell line BxPC-3 (purchased from Shanghai academy of sciences), human hepatoma cell line Hep3B (purchased from ATCC cell bank), human colorectal cancer cell HCT116 (purchased from ATCC cell bank), human normal liver cell line L-02 (distributed to Zhongshan university), M1 virus (accession number CCTCC V201423), DNA-PK inhibitor NU7441 (purchased from Selleck corporation, USA), and inverted phase contrast microscope.
The method comprises the following steps:
cell inoculation and administration treatment: selecting cells in logarithmic growth phase, preparing cell suspension with DMEM complete culture solution (containing 10% fetal calf serum and 1% double antibody) at 2 × 10 per well5Density per well was seeded in 6-well culture plates. After 12 hours, the cells were completely attached, and the experiment was divided into a control group, a 1. mu.M NU7441 group alone, an M1-infected group, and a NU7441/M1 combination group. The dosages used were: m1 virus (MOI ═ 1) infected cells; 1 μ MNU 7441.
As a result:
as shown in FIG. 2, the single treatment of different tumor cells (human colorectal cancer cell HCT116, human liver cancer cell line Hep3B, human bladder cancer cell line T24, human glioma cell line U-87MG, human pancreatic cancer cell line BxPC-3, M1 virus or NU7441 has smaller survival rate inhibition effect, however, when 1 μ M NU7441 is combined with M1 virus of the same MOI (NU7441+ M1), the survival tumor cells are greatly reduced, therefore, the cell level shows that the DNA-PK protein inhibitor can enhance the oncolytic effect of the M1 virus.
Example 3 combination treatment of various DNA-PK inhibitors and M1 oncolytic virus reduced cell viability material:
high-sugar DMEM medium (purchased from Corning), M1 virus (accession number CCTCC V201423), human colorectal cancer cell HCT116 (purchased from ATCC), compounds NU7441, NU7026 or KU0060648 (purchased from seleck, usa), automatic enzyme-linked immunosorbent assay plate reader, tetramethylazodicarbonyl blue (3- (4, 5-dimethylthiazolo-2-yl) -2, 5-diphenyltetrazolium bromide, MTT)
The method comprises the following steps:
a) cell inoculation and administration treatment: selecting cells in logarithmic growth phase, preparing cell suspension with DMEM complete culture solution (containing 10% fetal calf serum and 1% double antibody) at 4 × 10 per well3Density per well was seeded in 6-well culture plates. After 12 hours, the cells are completely attached, and the experiment is divided into a control group, a NU7441/NU7026/KU0060648 group, an M1 infection group, a NU7441/M1 group, a NU7026/M1 combination group or a KU0060648/M1 combination group. The dosages used were: the dosages used were: m1 virus (MOI ═ 1) infected cells; NU7026/KU0060648 different dose gradients were set up.
b) MTT reacts with intracellular succinate dehydrogenase: at 48h of culture, 20 μ l of MTT (5mg/ml) was added to each well and incubation continued for 4 hours, at which time microscopic examination of the particulate blue-violet formazan crystals formed within the viable cells could be observed.
c) Dissolving formazan particles: the supernatant was carefully aspirated, the crystals formed were dissolved in DMSO (100. mu.l/well), shaken on a micro-shaker for 5min, and then the optical density (OD value) of each well was measured on an enzyme-linked detector at a wavelength of 570 nm. Each set of experiments was repeated 3 times. Cell survival rate-OD value of drug-treated group/OD value of control group × 100%.
As a result:
as shown in fig. 3. The inhibition rate of the cells of the M1 group (MOI is 1) is low, and the cell survival rate of the inhibitor is reduced by no more than 25% compared with that of the control group; the cell survival rate of the combined group (M1+ inhibitor) is greatly reduced by over 50 percent. This shows that DNA-PK inhibitors NU7441, NU7026 and KU0060648 can enhance the anti-tumor effect of virus M1.
Example 4 knockdown of DNA-PKcs subunits promotes the oncolytic Effect of Virus M1
Materials:
three fragments of high-glucose DMEM medium (purchased from Corning), M1 virus (with the preservation number of CCTCC V201423), human colorectal cancer cell line HCT116 (purchased from ATCC), human pancreatic cancer cell line BxPC-3 (purchased from Shanghai academy of sciences), and SiRNA DNA-PKcs are respectively:
Si-1SEQ ID NO:1
(CCTGAATGCTCTAGAAGAA),
Si-2SEQ ID NO:2
(GTGTTGAAGTCCAGGTTTA),
Si-3SEQ ID NO:3
(GTACAGCTTTAACAGAAA)。
the method comprises the following steps:
selecting cells in logarithmic growth phase, preparing DMEM complete culture solution into cell suspension, and culturing the cells at 1 × 105Seeded in 6-well plates. After 24 hours, after the liposome-encapsulated Si RNA target gene fragment was added 24 hours, M1 virus was infected. The samples were processed 48 hours after infection.
a) Collecting protein samples, and carrying out Western blot detection on interference efficiency;
b) cell survival was calculated by MTT method using One way ANOVA statistics, indicating p < 0.01. As a result:
as shown in FIG. 4, Western blot detection shows that the expression level of the gene DNA-PKcs is reduced remarkably after siRNA fragments are used for interfering with the subunits of the DNA-PKcs. The interference of DNA-PKcs alone or the application of M1 virus did not cause a large reduction in cells, and only the interference of DNA-PKcs in combination with the M1 virus group caused a significant decrease in the survival rate of human colorectal HCT116 (FIG. 4A) and pancreatic cancer BxPC-3 (FIG. 4B). Indicating that the suppression of the DNA-PKcs subunit enhances the oncolytic effect of virus M1.
Example 5 the combined use of NU7441 and M1 virus significantly inhibited the growth of human colorectal and pancreatic cancer transplantable tumors.
Materials:
high-sugar DMEM medium (purchased from Corning), M1 virus (with the preservation number of CCTCC V201423), human colorectal cancer cell strain HCT116 (purchased from ATCC), human pancreatic cancer cell strain BxPC-3 (purchased from ATCC), and 4-week-old female BALB/c nude mice.
The method comprises the following steps:
this experiment employed a randomized, single blind design. Will be 5X 106HCT116 or 1 × 107BxPC-3 cells were injected subcutaneously into the dorsal side of 4-week-old BALB/c nude mice.
The administration was carried out in the manner shown in FIGS. 5A and 5D, when the tumor size reached 50mm3The group was divided into untreated control group, NU7441 group (intraperitoneal injection 10 mg/kg/day) alone and M1 infected group (tail vein injection M1 virus 2X 10)6PFU/time) and NU7441/M1 combination group (same dose of NU7441 and M1 virus was given in the same manner), 4 injections were performed consecutively. The length, width and weight of the tumor were measured every two days, and the volume of the tumor was determined according to the formula (length. times. width)2)/2. One way ANOVA statistics were performed after tumor volume measurements, representing p<0.01。
As a result:
pathological anatomical determination of tumor volume in two tumor cell-transplanted tumor animals showed that the NU7441 alone and M1 alone infected group caused only a slight decrease in tumor volume compared to the control group, while the NU7441/M1 combined group caused a significant decrease in tumor volume (fig. 5B, 5E, 5G, and 5H). In addition, there was no significant difference in body weight of nude mice in the different treatment groups (fig. 5C and 5F). This indicates that the DNA-PK inhibitor NU7441 can enhance the oncolytic effect of M1 virus in vivo without influencing the body weight of nude mice.
The embodiments of the present invention are described as illustrative examples, and the embodiments of the present invention are not limited to the above-described embodiments, and any other changes, modifications, substitutions, combinations, and simplifications which do not depart from the spirit and principle of the present invention should be construed as equivalents and are included in the scope of the present invention.
Sequence listing
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Claims (37)

1. The application of the antitumor drug in the preparation of an oncolytic virus antitumor synergist or a drug resistance reversal agent;
the anti-tumor drug is selected from a DNA-PK inhibitor;
the oncolytic virus is selected from M1 virus and/or Getavirus.
2. The application of the oncolytic virus in the preparation of an antitumor drug synergist or a drug resistance reversal agent;
the anti-tumor drug is selected from a DNA-PK inhibitor;
the oncolytic virus is selected from M1 virus and/or Getavirus.
3. The use of claim 1 or 2, wherein the DNA-PK inhibitor is a substance that inhibits DNA-PK activity, or inhibits the activity or expression of any one of the subunits, or blocks the assembly of subunits, or degrades DNA-PK.
4. The use of claim 1 or 2, wherein the DNA-PK inhibitor is a means for inhibiting gene expression of any subunit of DNA-PK.
5. The use of claim 1 or 2, wherein the DNA-PK inhibitor is selected from the following compounds or pharmaceutically acceptable salts thereof having DNA-PK inhibitory effect: NU7441, NU7026, KU-0060648, LTURM34, CC-115, PIK-90, Wortmannin, LY3023414, M3814, SF2523, Compound 401.
6. The use of claim 1 or 2, wherein the DNA-PK inhibitor is gene interference, gene editing, gene silencing or gene knock-out material.
7. The use of claim 1 or 2, wherein the DNA-PK inhibitor is a gene interfering material.
8. The use of claim 1 or 2, wherein the DNA-PK inhibitor is selected from SEQ ID NO 1, SEQ ID NO 2 or SEQ ID NO 3.
9. A pharmaceutical composition for treating a tumor, comprising:
(a) an anti-tumor drug;
the anti-tumor drug is selected from a DNA-PK inhibitor;
(b) an oncolytic virus;
the oncolytic virus is selected from M1 virus and/or Getavirus.
10. A pharmaceutical kit comprising:
(a) an anti-tumor drug;
the anti-tumor drug is selected from a DNA-PK inhibitor;
(b) an oncolytic virus;
the oncolytic virus is selected from M1 virus and/or Getavirus.
11. The kit of claim 10, wherein the kit comprises an individually packaged anti-neoplastic agent and an individually packaged oncolytic virus.
12. The composition/pharmaceutical kit according to any one of claims 9-11, wherein said DNA-PK inhibitor is a substance that inhibits DNA-PK activity, or inhibits the activity or expression of any one of the subunits, or blocks the assembly of subunits, or degrades DNA-PK.
13. The composition/pharmaceutical kit according to any of claims 9 to 10, wherein said DNA-PK inhibitor is a means for inhibiting gene expression of any subunit of DNA-PK.
14. The composition/pharmaceutical package according to any one of claims 9 to 10, wherein said DNA-PK inhibitor is selected from the following compounds or pharmaceutically acceptable salts thereof having DNA-PK inhibitory effect: NU7441, NU7026, KU-0060648, LTURM34, CC-115, PIK-90, Wortmannin, LY3023414, M3814, SF2523, Compound 401.
15. The composition/pharmaceutical package of any one of claims 9-10, wherein said DNA-PK inhibitor is gene interference, gene editing, gene silencing or knock-out material.
16. The composition/package according to any one of claims 9 to 10, wherein said DNA-PK inhibitor is a gene interfering material.
17. The composition/package according to any one of claims 9 to 10, wherein said DNA-PK inhibitor is selected from SEQ ID NO 1, SEQ ID NO 2 or SEQ ID NO 3.
18. The composition/package according to any one of claims 9 to 10, further comprising a pharmaceutically acceptable carrier.
19. The composition/package according to any one of claims 9 to 10, wherein the dosage form of the composition/package is selected from the group consisting of an injection, a tablet, a capsule, and a patch.
20. The composition/package according to any one of claims 9-10, wherein the dosage form of the composition/package is selected from lyophilized powder injection.
21. The composition/package according to any one of claims 9-10, wherein the ratio of the anti-neoplastic agent to the oncolytic virus is: 0.01-200 mg:103~109 PFU。
22. The composition/package according to any one of claims 9-10, wherein the ratio of the anti-neoplastic agent to the oncolytic virus is: 0.1-200 mg:104~109 PFU。
23. The composition/package according to any one of claims 9-10, wherein the ratio of the anti-neoplastic agent to the oncolytic virus is: 0.1-100 mg:105~109 PFU。
24. The composition/package according to any of claims 9 to 10, wherein the dosages used are: the application range of the antitumor drug is 0.01mg/kg to 200mg/kg, and the using titer of the oncolytic virus is MOI from 103To 109(PFU/kg)。
25. The composition/pharmaceutical package according to any of claims 9 to 10, wherein the dosages used are: the application range of the antitumor drug is 0.1mg/kg to 200mg/kg, and the using titer of the oncolytic virus is MOI from 104To 109(PFU/kg)。
26. Composition/pharmaceutical kit according to any one of claims 9 to 10,the preparation is characterized in that the dosage is as follows: the application range of the antitumor drug is 0.1mg/kg to 100mg/kg, and the using titer of the oncolytic virus is MOI from 105To 109(PFU/kg)。
27. The composition/kit according to any one of claims 9 to 10, wherein the antineoplastic drug is selected from the following compounds or pharmaceutically acceptable salts thereof having an antineoplastic effect: one or more of NU7441, NU7026 and KU-0060648.
28. The application of the combination of the anti-tumor drug and the oncolytic virus in the preparation of the drug for treating tumor;
the anti-tumor drug is selected from a DNA-PK inhibitor;
the oncolytic virus is selected from M1 virus and/or Getavirus.
29. The use of claim 28, wherein the DNA-PK inhibitor is a substance that inhibits DNA-PK activity, or inhibits the activity or expression of any one of the subunits, or blocks the assembly of subunits, or degrades DNA-PK.
30. The use of claim 28, wherein said DNA-PK inhibitor is a means for inhibiting gene expression of any subunit of DNA-PK.
31. The use of claim 28, wherein the DNA-PK inhibitor is selected from the group consisting of: NU7441, NU7026, KU-0060648, LTURM34, CC-115, PIK-90, Wortmannin, LY3023414, M3814, SF2523, Compound 401.
32. The use of claim 28, wherein the DNA-PK inhibitor is gene interference, gene editing, gene silencing or gene knock-out material.
33. The use of claim 28, wherein said DNA-PK inhibitor is a gene interfering material.
34. The use of claim 28, wherein said DNA-PK inhibitor is selected from SEQ ID No. 1, SEQ ID No. 2 or SEQ ID No. 3.
35. The use/composition/pharmaceutical kit according to any one of claims 1, 2, 9, 10 or 28, wherein said tumor is a solid tumor or a hematological tumor.
36. The use/composition/pharmaceutical kit according to claim 35, wherein said solid tumor is colorectal cancer, pancreatic cancer, liver cancer, bladder cancer, breast cancer, cervical cancer, prostate cancer, glioma, melanoma, nasopharyngeal cancer, lung cancer or gastric cancer.
37. The use/composition/pharmaceutical kit according to any one of claims 1, 2, 9, 10 or 28, wherein said tumor is an oncolytic virus-insensitive tumor.
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