WO2017031760A1 - Interference fragment and applications thereof - Google Patents

Abstract

Provided are an interference fragment and an application thereof. The target of action of the interference fragment is a nucleotide sequence as shown below: 5'-GCCTGTGTTCTCTGTGGACTA-3' (SEQ ID NO: 5).

Description

Interference fragment and its application Technical field

The invention relates to the field of immunobiology technology, in particular to interference fragments and their applications.

Background technique

Malignant tumors are the main type of fatal disease in humans and the mortality rate remains high. The latest statistics from the Ministry of Health indicate that malignant tumors rank first in the top ten causes of death among Chinese residents. In 2010, there were 2.68 million patients with malignant tumors in China and 1.97 million deaths. At present, there are more than 6 million patients with malignant tumors nationwide. The annual medical expenses for patients with malignant tumors account for about 20% of the total health expenditure, which is the largest medical burden for the whole society. The current treatments are still very limited in achieving the goals of curing, prolonging the survival of patients with malignant tumors and improving the quality of life. Especially for some types of malignant tumors, even early diagnosis is difficult to obtain satisfactory results. As for metastasis, whole body Sexual or advanced malignancies are more difficult to cure.

In current cancer treatment strategies, local treatments such as surgery and radiotherapy have a good effect on localized tumors, while systemic treatment of chemotherapy- or immunotherapy is mainly used for minimally residual lesions after systemic, metastatic or local treatment. Tumor onset is the result of multi-step, multi-gene action, tumor cells show uncontrolled growth, differentiation and apoptosis. Clinically, the diversity of patient symptoms and individual genetic heterogeneity, as well as the emergence of distant metastatic lesions, make the treatment of tumors must adopt a comprehensive treatment plan based on the concept of systemic diseases. That is, according to the characteristics of each tumor patient, local treatment combined with systemic treatment; not only to eliminate local tumors, but also to control tumor recurrence, metastasis and tumor invasion of important organs, in order to truly improve tumor patients Cure rate and survival time. Usually, the treatment of local tumor lesions can be eliminated by surgery and physical therapy (including radiofrequency ablation, hyperthermia, radiotherapy, cryotherapy, ultrasound and laser treatment), but for tumor microscopic lesions that cannot be found in imaging (such as metastatic recurrence, local The residual lesions after treatment, the cancer cells in the blood), the above local treatments are powerless and must be solved by systemic treatment. Because tumor metastasis, recurrence, and spread are more deadly, systemic treatment is particularly important and urgent. At present, systemic treatment includes traditional chemotherapy, molecular targeted drug therapy, biological therapy (including stem cell transplantation therapy and immune cell therapy), and gene therapy. Although traditional chemotherapy has made some progress in the treatment of certain tumors, it still contributes little to prolonging the survival of cancer patients. Moreover, the natural resistance of tumor cells to chemotherapeutic drugs and acquired multidrug resistance and chemotherapy toxicity have seriously hindered the development of chemotherapy. Clinical practice over the years has proven that it is not an advantage program for systemic therapy.

Immune cell therapy has been developed for nearly two decades. Because of its wide therapeutic range (can be used for solid tumors and leukemia), it is especially effective for small tumor lesions (including metastasis, recurrence, cancer cells in the blood). Side effects, but also applicable to all stages of the tumor (such as late release, chemotherapy can not be used), so it is an advantage of systemic treatment. Immune cell therapy has a significant effect on improving quality of life and prolonging survival. It is highly praised at home and abroad and is one of the best methods for systemic therapy at present. The clinical potential is huge.

Programmed cell death-1 (PD-1) belongs to costimulatory molecule 28 (CD28)/cytotoxic lymphocyte associated antigen (Cytotoxic lymphocyte associated antigen). An inhibitory receptor of the CTLA-4) family. PD-1 is not only a marker of programmed cell death, but also expressed on the surface of B lymphocytes, T lymphocytes, NK cells, NKT cells, and macrophages. In recent years, it has been found that the surface of T lymphocytes activated by antigens transiently expresses PD-1, and the sustained expression of PD-1 may cause T cell dysfunction. The extensive expression and immunosuppressive function of PD-1 has made it the focus of immunotherapy in recent years. PD-1 plays an important role in the treatment of diseases such as cancer, autoimmune diseases, and chronic viral infections. At present, the main application of PD-1 is mainly to develop antibodies that specifically block PD-1 signaling, and then to use such antibody drugs for the treatment of advanced cancer and metastatic cancer. Although the therapeutic effect is acceptable, it is often Drug-related adverse events occur.

Therefore, the current application of PD-1 in immunotherapy still needs to be improved.

Summary of the invention

First, it should be noted that the present invention has been completed based on the following findings of the inventors:

Antibody drugs that specifically block PD-1 signaling are used in the treatment of advanced cancer and metastatic cancer. Although the therapeutic effect is acceptable, the total incidence of drug-related adverse events (AEs) is 41%, 3/4. The grade of serious drug AEs is 5%, including: skin (16%), gastrointestinal reactions (12%), and lungs (7%). The incidence of drug-related pneumonia was (6%), and the incidence of grade 3/grade pneumonia was 2% (2/129). Two patients died of pneumonia in the early stage of the trial.

Moreover, some patients responded to antibody therapy, and some patients showed no significant changes in their indicators after receiving antibody therapy. Some patients have incomplete response after receiving antibody therapy. For example, a 72-year-old male with multiple organ cancers has a significantly reduced cancer metastasis after a course of treatment, but no change in cancer at other sites. . Some patients respond to antibody therapy completely and tumor regression occurs. In addition, some cases have complicated response to this antibody treatment. For example, a 52-year-old woman with multiple lymph node liver cancers has undergone antibody treatment, and many cancers have declined but one lymph node has become cancerous.

Antibodies that block the PD-1 signaling pathway do not act directly on tumor tissue but act by activating anti-tumor immunity. Due to the complexity of the immune response and individual differences, the therapeutic effects of these antibodies vary widely among different types of cancer patients and between individuals. As mentioned earlier, the side effects of PD-1 inhibitors (antibodies) after intravenous reinfusion are present, and patients with systemic immune disease should not use this drug because PD-1 inhibitors can enhance the killing ability of immune cells. Increase the immune response and worsen the condition. There are also some patients who have incomplete response after antibody treatment.

The present invention aims to solve at least one of the technical problems existing in the prior art. To this end, an object of the present invention is to provide a means for effectively inhibiting the expression of PD-1 in an immune cell, thereby inhibiting the expression of PD-1 in an immune cell, thereby further suppressing the obtained immune cell of PD-1 expression. It is used for preparing immunotherapeutic drugs and is used for immunotherapy of tumors, thereby effectively solving the above problems and improving the application range and application effect of PD-1 in immunotherapy.

Specifically, in order to solve the above problems, the present invention successfully constructs a lentiviral vector targeting shRNA of PD-1 by using genetic engineering technology, and screens a target sequence with an interference efficiency of more than 90%; and then, based on the interference obtained by screening The target sequence is transferred to the immune cells, T lymphocytes (including CTL, TIL, CD8+T, NKT cells, etc.) by the pd-1 shRNA lentiviral vector carrying the corresponding interference fragment. The expression of PD-1 is inhibited for a long period of time, and the immune cells inhibiting the expression of PD-1 are obtained. The expression of the proliferating cell PD1 obtained after the cells enter the human body is also inhibited; further, the inventors return the modified T cells. Human or tumor local, and found that It can effectively improve the effect of immunotherapy and minimize side effects.

Thus, in accordance with one aspect of the invention, the invention provides an interference segment. According to an embodiment of the invention, the target of the interference segment is a nucleotide sequence as shown below:

5'-GCCTGTGTTCTCTGTGGACTA-3' (SEQ ID NO: 5).

The inventors have surprisingly found that the interference fragment of the present invention has good targeting properties against the above-mentioned target, and the interference suppressing effect on PD-1 is outstanding. Moreover, according to an embodiment of the present invention, transferring the above interference fragment into an immune cell, T lymphocytes (for example, CTL, TIL, CD8+T, NKT cells, etc.), can cause long-term suppression of PD-1 expression in the immune cell. The immune cells inhibiting the expression of PD-1 are obtained, and the expression of the proliferating cell PD1 obtained after the cells enter the human body is also inhibited, whereby the obtained immune cells inhibiting the expression of PD-1 can be effectively used for the preparation of immunotherapeutic drugs. Furthermore, it is used for immunotherapy of tumors, effectively improving the effect of immunotherapy and minimizing side effects.

In addition, the interference segment according to the above embodiment of the present invention may also have the following additional technical features:

According to an embodiment of the invention, the interference segment consists of a sense strand and an antisense strand having the nucleotide sequence:

Justice strand: 5'-GATCCGCCTGTGTTCTCTGTGGACTATTCAAGAGATAGTCCACAGAGA ACACAGGCTTTTTTG-3' (SEQ ID NO: 6),

Antisense strand: 5'-AATTCAAAAAAGCCTGTGTTCTCTGTGGACTATCTCTTGAATAGTCCAC AGAGAACACAGGCG-3' (SEQ ID NO: 7).

According to another aspect of the present invention, the present invention also provides a method of inhibiting PD-1 expression in an immune cell. According to an embodiment of the invention, the method comprises: transferring the interference segment described above into the immune cell.

The inventors have found that the method can effectively inhibit the expression of PD-1 in immune cells and obtain immune cells with inhibition of PD-1 expression. Furthermore, the obtained immune cells inhibiting the expression of PD-1 can be effectively used for the preparation of immunotherapeutic drugs, thereby obtaining an immunotherapeutic agent having a good therapeutic effect and low side effects; in addition, the immune cells inhibiting the expression of PD-1 can also be directly used. It is used to return to the human body or the tumor, so that it can effectively treat or prevent tumors.

According to an embodiment of the present invention, in the method of the present invention, the method of transferring the interference fragment into the immune cell is not particularly limited. According to some specific examples of the invention, the interference fragment is transferred into the immune cell using a lentiviral vector system. Thereby, the interference fragment is easily transferred into the immune cell, thereby effectively improving the interference efficiency and realizing the inhibition of PD-1 expression in the immune cell.

According to an embodiment of the invention, the immune cell is a lymphocyte, preferably a T cell, a B cell, an NK cell, an NKT cell, more preferably a tumor infiltrating T lymphocyte or a CTL cell. Thereby, the immune cells inhibiting the expression of PD-1 can be efficiently obtained, and further, the obtained immune cells inhibiting the expression of PD-1 can be used for the preparation of an immunotherapeutic drug, and an immunotherapeutic agent having a good therapeutic effect and a low side effect can be effectively obtained. It can be directly used; the immune cells inhibited by PD-1 expression can also be directly used for reintroduction of human or tumor parts, thereby effectively treating or preventing tumors.

In addition, it should be noted that the term "immune cells" as used herein mainly refers to lymphocytes in human blood, such as T lymphocytes, B lymphocytes, NK lymphocytes, and NKT lymphocytes. Among them, the T lymphocytes may be tumor infiltrating T lymphocytes, and various T cells, such as CTL cells, cultured or induced in vitro. The term "CTL cell" as used herein refers to a cytotoxic T lymphocyte that is stimulated by autologous lymphocytes by DC cells loaded with tumor antigen and mixed with autologous lymphocytes.

According to still another aspect of the present invention, the present invention also provides the use of the aforementioned interference fragment for the preparation of an immunotherapeutic drug. According to an embodiment of the present invention, the drug comprises an immune cell in which PD-1 expression is inhibited. Therefore, the administration of the drug to a tumor patient can effectively inhibit the expression of PD-1 in the tumor cells of the patient, thereby effectively treating the tumor; in addition, the drug can be effectively used for the prevention of the tumor, and the effect of treating or preventing the tumor is good, and the side effect is good. low.

According to an embodiment of the present invention, the immune cell in which PD-1 expression is inhibited is obtained by transferring the interference fragment described above into the immune cell to obtain an immune cell in which PD-1 expression is inhibited. Thereby, immune cells in which PD-1 expression is inhibited can be efficiently obtained.

According to an embodiment of the invention, the interference fragment is transferred into the immune cell using a lentiviral vector system. Thereby, the interference fragment is easily transferred into the immune cell, the interference efficiency is high, and the inhibitory effect on the expression of PD-1 in the immune cell is good.

According to an embodiment of the invention, the immune cell is a lymphocyte, preferably a T cell, a B cell, an NK cell, an NKT cell, more preferably a tumor infiltrating T lymphocyte or a CTL cell. Thereby, immune cells in which PD-1 expression is inhibited can be efficiently obtained, and further, the immune cells inhibited by the PD-1 expression can be used for preparation of an immunotherapeutic drug.

According to another aspect of the present invention, the present invention also provides an immunotherapeutic drug. According to an embodiment of the present invention, the immunotherapeutic drug comprises immune cells inhibited by PD-1 expression, and the immune cells inhibited by the PD-1 expression inhibit the immune cells by the method of inhibiting PD-1 expression in the immune cells as described above. Obtained in PD-1 expression. Therefore, the administration of the immunotherapeutic agent of the present invention to a tumor patient can effectively inhibit the expression of PD-1 in the tumor cells of the patient, thereby effectively treating the tumor; in addition, the medicament can be effectively used for the prevention of tumors, and for treating or preventing tumors. Good effect and low side effects.

The additional aspects and advantages of the invention will be set forth in part in the description which follows.

DRAWINGS

The above and/or additional aspects and advantages of the present invention will become apparent and readily understood from

1 shows a schematic structural view of an LV3 carrier according to an embodiment of the present invention;

Figure 2 shows the results of western detection of PD-1 protein in cells of interest transfected with each shRNA lentiviral vector, according to one embodiment of the present invention;

Figure 3 shows the results of flow cytometry analysis of the number of PD-1 positive cells in the cells of interest transfected with each shRNA lentiviral vector, in accordance with one embodiment of the present invention.

detailed description

The solution of the present invention will be explained below in conjunction with the embodiments. Those skilled in the art will appreciate that the following examples are merely illustrative of the invention and are not to be considered as limiting the scope of the invention. In the examples, the specific techniques or conditions are not mentioned, according to the techniques or conditions described in the literature in the field (for example, refer to J. Sambrook et al., Huang Peitang et al., Molecular Cloning Experimental Guide, Third Edition, Science Press) or in accordance with the product manual. The reagents or instruments used are not specified by the manufacturer, and are conventional products that can be obtained commercially, for example, from Illumina.

Example 1

First, the plasmid construction:

A control RNA (negative control) was set up, and three PD-1 shRNA lentiviral vectors were constructed as follows:

(1) Experimental materials

1. DNA oligo was designed using Designer3.0 (Genepharma) software, and the synthetic primers were completed by Shanghai Jima Pharmaceutical Technology Co., Ltd.

2. List of instruments used in the experiment:

3. List of reagents used in the experiment:

(two), the construction process

1, Oligo Designer3.0

When the inventor designed the template, the loop structure in the LV3-shRNA template selected TTCAAGAGA to avoid the formation of a termination signal; the 5' end of the sense strand template added GATCC, which is complementary to the sticky end formed by BamHI digestion; the antisense strand template AATTC was added to the 5' end to complement the sticky ends formed by EcoRI digestion, as follows:

Justice chain:

5'-GATCC-(GN ₁₈ )-(TTCAAGAGA)-(N ₁₈ C)-TTTTTTG-3';

Antisense chain:

3'-G(CN ₁₈ )-(AAGTTCTCT)-(N ₁₈ G)-AAAAAACTTAA-5'.

Among them, the specific information of shUN and three PD-1 shRNA lentiviral vectors are as follows:

(1) The specific information of the control shNC is:

Target sequence: 5'-TTCTCCGAACGTGTCACGT-3' (SEQ ID NO: 1);

Sequence of justice chains:

GATCCGTTCTCCGAACGTGTCACGTTTCAAGAGAACGTGACACGTTCGGAGAACTTTTTTG (SEQ ID NO: 2);

Antisense strand sequence:

AATTCAAAAAAGTTCTCCGAACGTGTCACGTTCTCTTGAAACGTGACACGTTCGGAGAACG (SEQ ID NO: 3);

Transcript sequence:

GTTCTCCGAACGTGTCACGTTTCAAGAGAACGTGACACGTTCGGAGAACTT (SEQ ID NO: 4).

(2) Plasmid information of three PD-1 shRNA lentiviral vectors: PDCD1-Homo-694, PDCD1-Homo-791 and PDCD1-Homo-238 are shown in Table 1-3, respectively.

2. Annealing of LV3-shDNA template

The DNA oligo was dissolved with TE (pH 8.0) at a concentration of 100 μM. The corresponding sense chain and antisense strand oligo solution were taken, and the annealing reaction system was configured according to the following ratio:

Component	Volume (μl)
		10X shDNA annealing buffer	5
Justice chain (100μM)	5
		Antisense strand (100μM)	5
ddH 2 O	35
		total capacity	50

Annealing was carried out on a PCR machine according to the following procedure: 95 ° C for 5 min; 85 ° C for 5 min; 75 ° C for 5 min; 70 ° C for 5 min; 4 ° C for storage. After annealing, a shRNA template was obtained at a concentration of 10 μM. The resulting template solution was diluted 50-fold to a final concentration of 200 nM for the ligation reaction.

3. Linearization of LV3 carrier

Take 10 μg of LV3 vector and perform enzyme digestion according to the following system:

Component	Volume (μl)
		2×Buffer Tango	10
BamHI	5
		EcoRI	5
LV3	10μg
		ddH 2 O	Make up to 100
total capacity	100

After digestion at 37 ° C for 1 hour, agarose electrophoresis, recovery using Agarose Gel DNA Purification Kit Ver2.0, electrophoretic detection of the estimated concentration, dilution to 50 ng / μl.

4. Construction of LV3-shRNA vector

The ligation reaction of the vector was carried out according to the following system:

Component	Volume (μl)
		10×T4 ligation buffer	2
LV3 (BamHI+EcoRI)	1
		shDNA template (100nM)	1
T4DNA ligase (5weissU/μl)	1

ddH 2 O	15
		total capacity	20

Conversion to E. coli Top10 (transform to Top10competent cells) at 22 ° C for 1 hour

5. Preparation of competent cells: (calcium chloride method)

Competent cells are prepared by the calcium chloride method, and the specific steps are as follows:

5.1 Pick a single colony from fresh plates incubated at 37 ° C for 16 hours and transfer to a 1 L flask containing 100 ml of LB medium. Incubate for 3 hours at 37 ° C with vigorous shaking (rotary shaker, 300 rpm).

5.2 Under sterile conditions, the bacteria were transferred to a sterile, single-use, ice-cold 50 ml polypropylene tube, placed on ice for 10 minutes, and the culture was allowed to cool to 0 °C.

5.3 The cells were recovered by centrifugation at 4000 rpm for 10 minutes at 4 °C.

5.4 Pour out the culture solution and invert the tube for 1 minute to allow the last trace of the remaining culture to run out.

5.5 Resuspend each fraction with 10 ml of ice-cold 0.1 mol/L CaCl ₂ and place on an ice bath.

5.6 The cells were recovered by centrifugation at 4000 rpm for 10 minutes at 4 °C.

5.7 Pour out the culture solution and invert the tube for 1 minute to allow the last trace of the remaining culture to run out.

5.8 Each 50 ml initial culture was resuspended in each cell pellet with 2 ml of ice pre-cooled 0.1 mol/L CaCl ₂ (containing 20% glycerol).

5.9 The cells were divided into small portions (100 μl/branch) and stored frozen at -70 °C.

6, the conversion of the connecting product

Follow the steps below to convert the linked product:

6.1 Remove the competent cells from -70 °C, place the centrifuge tubes containing the competent cells on ice for 4 minutes. After the cells are thawed, add 10 μl of the ligation product, gently mix the contents, and place in ice for 30 minutes. .

6.2 Place the centrifuge tube on the test tube rack placed in a water bath pre-warmed to 42 ° C for 90 seconds. Do not shake the tube.

6.3 Transfer the tube to the ice bath quickly and allow the cells to cool for 3 minutes.

6.4 Add 800 μl of LB medium (without antibiotics) to each tube, then transfer the tube to a 37 ° C shaker at 250 rpm for 45 minutes to resuscitate the bacteria.

6.5 200 μl of the cultured cells were uniformly coated on a 50 μg/ml Ampicillin LB plate.

After the liquid on the plate was absorbed, the plate was poured into a 37 ° C incubator and cultured for 16 hours.

7. Identification and sequencing of positive clones

The positive clones were screened by the following steps and verified by sequencing:

7.1 Five colonies were picked from each plate, inoculated into LB medium containing 50 μg/ml Ampicillin (ampicillin), and cultured at 37 ° C for 16 hours.

7.2 Extract the plasmid using alkaline lysis.

7.3 The resulting plasmid was identified by single enzyme digestion with EcoRI. The results of restriction enzyme digestion indicated that the positive clones were cut by EcoRI, and each group of clones was sequenced and identified. The sequencing results are shown in Table 1-3.

7.4 The correct sequencing strains were extracted using a high-purity plasmid medium extraction kit, and the resulting plasmids can be used in conventional molecular biology experiments and cytological experiments. If the cytotoxicity is large when used for cell transfection, re-transform into E. coli Top10, and then prepare a higher purity plasmid using the kit or CsCl ultracentrifugation.

Table 1, PDCD1-Homo-694 Plasmid Information

Table 2, PDCD1-Homo-791 Plasmid Information

Table 3, Plasmid information for PDCD1-Homo-238

Second, target screening

(1) Preparation of lentiviral vector:

Follow the steps below to prepare for lentiviral vector:

1. Lentiviral packaging cell transfection The 293T cells in the logarithmic growth phase were digested with trypsin, plated in 6-well plates, cultured in a 50 mL/L CO ₂ incubator at 37 ° C, and the cell density was 60% to 70%. Dyeing. Wash cells twice with PBS before transfection.

2. Preparation of three plasmid DNA solutions (VSVG 2 μg, P8.7.4 μg, target gene 10 μg) in the lentiviral packaging system.

3, sterile water to 25μL, then add 25μL of CaCl ₂ (2.5mol / L) solution, mix, placed on ice for 4min.

4. Add 50 μL of 2×HBS buffered saline solution dropwise, and leave it at room temperature for 30 min.

5. Transfer the DNA calcium phosphate mixture to the culture medium containing the monolayer cells, mix and incubate for 16 hours, then discard the culture medium containing the transfection mixture and replace with fresh culture medium.

6. Cell supernatant (1.5 ml) was taken 48 hours after transfection.

(2) Preparation of target cells:

1. Separation of peripheral blood mononuclear cells

The cells isolated from 100 ml of peripheral blood collected from 1 AFP-positive liver cancer patient were transferred to a 50 ml centrifuge tube for centrifugation (1800 rpm, 10 min), the supernatant was aspirated, and the supernatant was slowly added to the lymphocyte separation. On a liquid Ficoll solution (GE), the volume ratio is 1:1, centrifuged (2000 rpm, 20 min);

Next, the white floc cells of the collection interface were added to the PBS, gently pipetted and mixed, and centrifuged (1500 rpm, 10 min);

Next, repeat the centrifugal washing a total of 3 times;

Then, the collected cells were gently pipetted and mixed, and 20 ml of the basal medium was added and uniformly blown, transferred to a 75 cm ² culture flask, and cultured at 37 ° C in a 5% CO ₂ incubator for 2 hours.

2. Separation of lymphocytes and monocytes

Remove the 75 cm ² culture flask, gently place the 75 cm ² culture flask upright, and pipet 18 ml of the culture solution into a new 175 cm ² flask for activation culture of lymphocytes;

The remaining 2 ml of the remaining solution in the original vial (75 cm ² flask) will be used to induce differentiation of monocytes into DC cells.

3. Cultivation of lymphocytes

In a 175 cm ² flask for culturing lymphocytes, 20 ml of CTL1 cell culture medium was added, and after 24 hours, 20 ml of CTL2 medium was added, and then the CTL3 medium was reconstituted in equal amounts every 2 to 3 days.

Among them, the preparation methods of CTL1 medium, CTL2 medium and CTL3 medium are:

CTL1 medium: Take 1 tube of CTL1 factor from -20 degrees, melt at room temperature, add to 20ml of basal medium, And add 10% of the customer's serum, which is filtered using a 0.22um needle filter.

CTL2 medium: One tube of CTL2 factor was taken out from -20 degrees, melted at room temperature, and added to 20 ml of basal medium, and a 0.22 um needle filter was filtered and used.

CTL3 medium: One tube of CTL3 factor was taken out from -20 degrees, melted at room temperature, and added to 500 ml of basic medium, wherein a 0.22 um needle filter was used for filtration, and three tubes were used for the entire culture process.

CTL1 factor (including gamma interferon, 1000 U/ml): 1 ml, long-term storage at -20 °C, and stored at 4 °C for 2 weeks.

CTL2 factor (including IL-1, 1000 U/ml; IL-2, 1000 U/ml; CD3 antibody, 100 ng/ml; CD28 antibody, 100 ng/ml): 1 ml, long-term storage at -20 ° C, and stored at 4 ° C for 2 weeks.

CTL3 factor (including IL-2, 1000 U/ml; IL-7, 20 ng/ml; IL-15, 20 ng/ml): 1 ml, long-term storage at -20 ° C, and stored at 4 ° C for 2 weeks.

Thereby, the target cells are obtained. Then, the cells of interest were divided into 6-well plates, 10 ⁶ cells per well, and used.

(3) Viral vector infection:

1. The collected virus supernatant was added to the target cells obtained by the above preparation, and an equal volume of fresh medium (CTL3 medium) was added to culture the cells of interest (total 3 ml).

2. Change the fluid after 24 hours and normal culture.

3. After 96 hours of infection, the cells were collected and protein was extracted.

(4) Western identification of PD-1 protein:

1, reagent

1) 0.01 M PBS (pH 7.4): NaCl 8.0 g; KCl 0.2 g; Na ₂ HPO ₄ 1.44 g; KH ₂ PO ₄ 0.24 g;

Add ddH ₂ O to 1000 ml.

2) Protease inhibitors:

Protease Inhibitor Cocktail: Calbiochem, Ref. 539134

3) RIPA:

137 mM NaCl, 1.4 mM KH ₂ PO ₄ , 1.7 mM KCl,

5.0 mM EDTA, 5.0 mM EGTA, 4.3 mM Na ₂ HPO _4.

0.1% SDS, 1% Triton X-100, 1 mM NaVO4, 50 mM NaF.

4) Bio-Rad Bradford dye solution, article number 500-0006.

5) 10% SDS-PAGE separation glue, concentrated glue,

Among them, 10 ml of separation gel was prepared according to the following formula:

ddH2O 4.0ml; 30% acrylamide 3.3ml; 1.5M Tris (pH 8.8) 2.5ml;

10% SDS 0.1 ml; 10% ammonium persulfate 0.1 ml; TEMED 0.004 ml.

Prepare 2ml of concentrated gel according to the following formula:

ddH ₂ O 1.4ml; 30% acrylamide 0.33ml; 1M Tris (pH 6.8) 0.25ml;

10% SDS 0.02 ml; 10% ammonium persulfate 0.02 ml; TEMED 0.002 ml.

6) 2X SDS-PAGE Loading Buffer:

7) Protein marker, Bio-Rad, article number 161-0324.

8) Electrophoresis fluid:

With 5X Tris-Glycine Buffer stock solution, diluted when used.

Stock solution: 0.125M Tris, 1.25M Glycine, 0.5% (W/V) SDS,

The preparation method is as follows:

Weigh 13.1g of Tris; Glycine 94g; SDS 5.0g, placed in a 1L beaker, then add about 800ml of deionized water, stir to dissolve, add to deionized water to make up to 1L, and store at room temperature.

9) PVDF membrane, Millipore Corporation, article number IPVH00010.

10) Transfer buffer:

Glycine 2.9g; Tris 5.8g; SDS 0.37g; methanol 200ml; add ddH2O to 1000ml.

11) TBST preparation method:

It is called NaCl 8g; KCl 0.2g; Tris 3g, dissolved in 800ml of distilled water, adjusted to pH 7.4 with HCl, and made up to 1 liter. Then add 1ml Tween20 and mix.

12) Blocking solution: TBST containing 5% skim milk powder.

13) ECL reaction substrate, Pierce, supersignal west pico chemilumiscent sunstrate, article number prod #34080.

2, the instrument

1) Determination of protein concentration, Eppendorf Biophotometer;

2) Bio-Rad powerpac 3000 for electrophoresis and transfer film;

3, the main steps

1) Sample preparation

Wash the cells with PBS. After de-PBS, total protein extraction reagent RIPA containing protease inhibitor (1:200) was added and lysed on ice for 30 min. The cells were scraped with cells, pipetted into a 1.5 ml EP tube, and centrifuged at 13,000 g for 15 min at 4 °C. Take the supernatant as a sample. Protein concentration was determined by Bradford colorimetry.

2) Electrophoresis: An electrophoresis gel was prepared and subjected to SDS-PAGE.

Prepare PAGE gel in advance.

Take the same quality protein sample, add an equal volume of 2×loading buffer, and boil for 5 min in a boiling water bath.

Load, and protein marker, excess empty with 1 × loading buffer to fill. 90V, 20min, until all samples were pressed into a line; 120V, 100min.

3) Transfer film

A, cut the appropriate size of the PVDF membrane, methanol activation for a few seconds, immersed in the transfer buffer for use. Other related equipment, such as sponges, filter paper, plywood, etc., are also immersed in the transfer buffer beforehand.

B. Lay the sponge and filter paper under the plywood and roll the test tube back and forth to remove the bubbles.

C. Carefully peel off the PAGE gel on the electrophoresis slide and place it on the filter paper. The PVDF film was covered with glue, coated with filter paper and sponge, and rolled with a test tube to remove air bubbles.

D. Put the sponge/filter paper/gel into the electrophoresis device according to the manufacturer's recommended method, and the gel faces the cathode.

E. Place the above device in a buffer tank and fill the transfer buffer to submerge the gel.

F. Turn on the power as shown by the manufacturer and start film transfer at the ice box, 100V, 2hr.

4) Immune response:

A. Wash the membrane with TBST for 5 min.

B. Add blocking solution and shake gently at room temperature for 1 hr.

C, TBST wash film, 5min.

D. Add PDPD1 human primary antibody (diluted with TBST containing 3% skim milk powder), and leave at room temperature for 1 hr or 4 °C for 12 hr.

E, discard the primary antibody, TBST wash the membrane, 15min × 3 times.

F. Horseradish peroxidase-conjugated secondary antibody (rat anti-human) (diluted with TBST) was added and shaken smoothly for 2 hr at room temperature.

G, discard the secondary antibody, TBST wash film, 15min × 3 times.

5) ECL exposure

Prepare for exposure: film, exposure, development, fixer, etc. According to the ECL product specification, two components are mixed in equal volume, and a total volume of 1 ml can be used for one membrane. The X-ray film was exposed in a dark room for 1 to 2 minutes (depending on the light intensity after the reaction), washed with water and placed in a fixing solution until the film was completely transparent. Dry the film after washing.

The western detection results of PD-1 protein of the target cells transfected with each shRNA lentiviral vector are shown in Fig. 2.

Then, based on the western detection results, the interference efficiencies of the three shRNA lentiviral vectors were calculated, and the results were as follows:

Interference efficiency of PDCD1-Homo-791 (target sequence SEQ ID NO: 10: GCCACCATTGTCTTTCCTAGC): 78%;

Interference efficiency of PDCD1-Homo-238 (target sequence SEQ ID NO: 15: GCTAAACTGGTACCGCATGAG): 8%;

Interference efficiency of PDCD1-Homo-694 (target sequence SEQ ID NO: 5: GCCTGTGTTCTCTGTGGACTA): 88%.

6) Detection of the number of PD1 positive cells

At the same time, the target cells transfected with each shRNA lentiviral vector were subjected to flow cytometry analysis, and the number of PD1 positive cells was detected. The results are shown in Fig. 3.

Thus, by combining the results of western and flow cytometry, it is known that the high-effect interference PD1 target is:

PD791: GCCACCATTGTCTTTCCTAGC (SEQ ID NO: 10),

PD694: GCCTGTGTTCTCTGTGGACTA (SEQ ID NO: 5),

The PD238 has no interference effect on PD1. Two important PD1 interference targets are obtained in the present invention.

Example 2

Taking the PD694 lentiviral vector obtained in Example 1 as an example, the interference fragment carried by the PD694 lentiviral vector was transferred into an immune cell to prepare an immune cell which inhibited the expression of PD-1, and the specific steps were as follows:

1 separation of peripheral blood mononuclear cells

The cells isolated from 100 ml of peripheral blood collected from 1 AFP-positive liver cancer patient were transferred to a 50 ml centrifuge tube for centrifugation (1800 rpm, 10 min), the supernatant was aspirated, and the supernatant was slowly added to the lymphocyte separation. On a liquid Ficoll solution (GE), the volume ratio is 1:1, centrifuged (2000 rpm, 20 min);

Next, the white floc cells of the collection interface were added to the PBS, gently pipetted and mixed, and centrifuged (1500 rpm, 10 min);

Next, repeat the centrifugal washing a total of 3 times;

Then, the collected cells were gently pipetted and mixed, and 20 ml of the basal medium was added and uniformly blown, transferred to a 75 cm ² culture flask, and cultured at 37 ° C in a 5% CO ₂ incubator for 2 hours.

2 separation of lymphocytes and monocytes

Remove the 75 cm ² culture flask, gently place the 75 cm ² culture flask upright, and pipet 18 ml of the culture solution into a new 175 cm ² flask for activation culture of lymphocytes;

The remaining 2 ml of the remaining solution in the original vial (75 cm ² flask) will be used to induce differentiation of monocytes into DC cells.

3 lymphocyte culture

In a 175 cm ² flask for culturing lymphocytes, 20 ml of CTL1 cell culture medium was added, and after 24 hours, 20 ml of CTL2 medium was added, and then the CTL3 medium was replenished every 2 to 3 days to verify the activity. qualified.

The cell culture medium was aspirated, washed once with PBS, fresh 15 ml of CTL3 medium was added, and 5*10 ⁸ PD694 lentiviral vector was added to the culture flask for mixing, and the solution was changed after 24 hours.

4. Treatment of monocytes

a. Add 15 ml of DC medium to the original bottle (75 cm ² flask) with 2 ml of residual liquid, continue to culture for 4 days, and change the solution once every 2 to 3 days to induce differentiation of monocytes into immature DCs. cell.

b. Transfection of antigen gene mRNA by PEI transfection method: On day 5, immature DC cells were collected in a 50 ml centrifuge tube (centrifugation at 1500 rpm for 10 min), and the supernatant was discarded, and the lower layer cells were transferred to a 1.5 ml centrifuge tube. Then directly add 100 ul of reagent A (ie, the mixture obtained by mixing AFP mRNA and PEI at a mass ratio of 1:3), thoroughly mix the bottom cells, cover the centrifuge tube, and incubate in a cell incubator for 30 minutes every 10 minutes. Remove it upside down several times.

For the preparation method of AFP mRNA, please refer to Example 1 of the patent application with the application date of 201510225512.2, which is filed on May 5, 2015.

PEI (1 μg / μl) Polysciences (CAT#23966-2 formulated into a stock solution) was prepared according to the following steps: First, the endotoxin-free sterile water was heated to about 80 ° C to dissolve the PEI, and cooled to room temperature; Adjust the pH to 7.0, filter and sterilize with a 0.22μm filter, store at -20 °C after dispensing, and store the working solution at 4 °C for later use.

c. The centrifuge tube was taken out, and the cell suspension was taken out into a culture flask (75 cm ² ) with a pipette, and DC medium was added thereto, and the culture was continued for 3 days to obtain mature DC cells.

5. Co-cultivation

After the 8th day, the mature DC cells were mixed with the aforementioned activated cultured lymphocytes at a volume ratio of 1:20. Co-culture with CTL3 medium for seven days induced the production of CTL cells and other killer cells.

After seven days of co-culture, the cells were subjected to flow cytometry. The results showed that the immune cell population (PD694-CTL cells) prepared in this example contained not only a large number of CTL cells, but also various immune cells such as NK and CIK cells. : CTL cells (CD8+, CD3+CD8+CD28+), CIK cells (CD3+CD56+), NK cells (CD3-CD56+), that is, the immune cell population not only has CTL cells that strongly kill specific tumor cells, but also CIK, NK Immune cells.

Thus, the inventors have found that the present invention not only prepares AFP-specific CTL cells (PD694-CTL cells) in vitro, but also NKT cells. These lymphocytes have been modified by PD694's lentiviral vector prior to antigen stimulation, and their PD1 has been inhibited by more than 90%.

Example 3: Clinical experiment

The PD694-CTL cells prepared in Example 1 were returned to the patient, and the reinfusion effect was observed as follows:

20 patients with AFP-positive liver cancer were divided into 2 groups (10 in group A and 10 in group B), wherein for group A, sufficient CTL cells were obtained on day 14 and day 15 according to the method in Example 1. , return to the patient, the amount of cells returned each time is 1 ~ 2 * 10 ⁹ ; Group B does not return cells. Blood collection is repeated twice a time for a course of treatment. After the end of the 3 courses, observe.

The results showed that there were significant differences between group A and group B after three courses of treatment. All patients in group A felt reduced body fatigue after returning, increased appetite, pain relief, and weight gain. Among them, 8 patients had AFP indicators decreased; one patient found that 3 primary megas in the liver disappeared by CT. One patient index showed no progress. The symptoms of all patients in group B did not improve, and the AFP index increased in 10 patients. It can be clearly seen that after the PD694-CTL cells were returned, the symptoms of the patients were significantly relieved.

Industrial applicability

The interference fragment of the present invention has good targeting property against its target (SEQ ID NO: 5), has outstanding interference inhibition effect on PD-1, and can be effectively used for inhibiting PD-1 expression of immune cells, thereby obtaining PD- 1 The expression-inhibited immune cells can be effectively used for the preparation of immunotherapeutic drugs.

Although specific embodiments of the invention have been described in detail, those skilled in the art will understand. Various modifications and alterations of the details are possible in light of the teachings of the invention. The full scope of the invention is given by the appended claims and any equivalents thereof.

In the description of the present specification, the description with reference to the terms "one embodiment", "some embodiments", "illustrative embodiment", "example", "specific example", or "some examples", etc. Particular features, structures, materials or features described in the examples or examples are included in at least one embodiment or example of the invention. In the present specification, the schematic representation of the above terms does not necessarily mean the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in a suitable manner in any one or more embodiments or examples.

Claims (10)

1. An interference fragment whose target is a nucleotide sequence as shown below:

   5'-GCCTGTGTTCTCTGTGGACTA-3' (SEQ ID NO: 5).
2. The interference fragment according to claim 1, wherein the interference fragment is composed of a sense strand and an antisense strand having the nucleotide sequence:

   Justice chain: 5'-GATCCGCCTGTGTTCTCTGTGGACTATTCAAGAGATAGTCCACAGAGAACACAGGCTTTTTTG-3' (SEQ ID NO: 6),

   Antisense strand: 5'-AATTCAAAAAAGCCTGTGTTCTCTGTGGACTATCTCTTGAATAGTCCACAGAGAACACAGGCG-3' (SEQ ID NO: 7).
3. A method for inhibiting PD-1 expression in an immune cell, comprising:

   The interference fragment of claim 1 or 2 is transferred into the immune cell.
4. The method of claim 3 wherein said interference fragment is transferred to said immune cell using a lentiviral vector system.
5. The method according to claim 3, wherein the immune cells are lymphocytes, preferably T cells, B cells, NK cells, NKT cells, more preferably tumor infiltrating T lymphocytes or CTL cells.
6. The use of the interference fragment according to claim 1 or 2 for the preparation of an immunotherapeutic drug comprising an immune cell in which PD-1 expression is inhibited.
7. The use according to claim 6, wherein the immune cells inhibited by PD-1 expression are obtained by the following steps:

   The interference fragment of claim 1 or 2 is transferred into the immune cells to obtain immune cells in which PD-1 expression is inhibited.
8. The use according to claim 7, characterized in that the interference fragment is transferred into the immune cell using a lentiviral vector system.
9. The use according to claim 7, characterized in that the immune cells are lymphocytes, preferably T cells, B cells, NK cells, NKT cells, more preferably tumor infiltrating T lymphocytes or CTL cells.
10. An immunotherapeutic agent comprising: an immune cell comprising inhibition of PD-1 expression, wherein the immune cell inhibiting expression of PD-1 is capable of inhibiting PD- in immune cells by the method according to any one of claims 3-5. 1 expression obtained.

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