WO2023000403A1 - Sars-cov-2 subprotein nano-vaccine, and preparation method therefor and application thereof - Google Patents

Abstract

A Sars-Cov-2 subprotein nano-vaccine, and a preparation method therefor and an application thereof. The nano-vaccine comprises: an organic compound self-assembled from polylactic acid, porphyrin, or a porphyrin derivative, and a Co2+ ion conjugate; Sars-Cov-2 antigen protein; a vaccine adjuvant; and a lipid. The synthetic organic compound has an adjuvant encapsulated in its core and a Sars-Cov-2 antigen protein efficiently loaded on the surface, such that a nano-vaccine system allowing for co-delivery of the Sars-Cov-2 antigen protein and vaccine adjuvant is realized, thereby maximizing the immunogenicity of the Sars-Cov-2 recombinant subprotein and enabling tracking the distribution of the subprotein in an organism by means of fluorescent molecules. In addition, the nano-vaccine is also linked with a polypeptide that can specifically target antigen-presenting cells, so as to promote the uptake of the nano-vaccine by DC cells and promote anti-viral response. The preparation method is simple and efficient and provides a way for effectively preventing Sars-Cov-2 infection.

Description

A kind of novel coronavirus subprotein nano vaccine and its preparation method and application technical field

The invention belongs to the field of biomedicine, and in particular relates to a novel coronavirus subprotein nano-vaccine and its preparation method and application.

Background technique

The novel coronavirus pneumonia (COVID-19) that broke out in the past two years is a respiratory disease caused by a new coronavirus (SARS-CoV-2), and its clinical manifestations range from mild flu-like symptoms to severe life-threatening pneumonia , with a very high infectivity and fatality rate. Its main structure includes spike protein (S, spike), envelope protein (E, envelope), membrane protein/matrix protein (M, membrane/matrix) and nucleocapsid protein (N, uncleocapsid). When the host is infected with the new coronavirus, the S protein will be cleaved by protease into S1 subunit and S2 subunit, and the receptor binding domain (RBD) of the S1 subunit will bind to angiotensin converting enzyme 2 (Angiotensin-converting enzyme 2) on the surface of the host cell. Converting enzyme 2, ACE2) binding, causing fever and pulmonary infection and other clinical manifestations. Neutralizing antibodies against the S protein can block the virus from invading host cells. Therefore, in view of the current situation of the global spread of pneumonia caused by the new coronavirus, inoculation of the new coronavirus vaccine developed against the S protein is an effective way to improve the spread of the epidemic.

In recent years, nano-vaccine platforms dedicated to the co-delivery of antigens and adjuvants have been developed rapidly. Liposomes, albumin, and some amphiphilic block copolymers that have passed the FDA are nanocarriers used in delivery platforms in recent years. Lipids Body refers to amphiphilic phospholipid molecules as the basic material, adding cholesterol and other auxiliary materials, in water, because the hydrophobic segments of amphiphilic phospholipids are gathered together, and the hydrophilic ends are exposed to water, thus self-assembling to form a hydrophobic middle and hydrophilic ends. Bilayer structure vesicles; albumin is the most abundant protein in plasma, using albumin as a carrier for insoluble drugs to prepare drug delivery nanoparticles will make it have low biotoxicity, low immune response, biodegradability and increase half-life and other advantages, the binding force between albumin and hydrophobic small molecule drugs is mainly van der Waals force and hydrogen bond force, hydrophobic small molecule drugs are mainly loaded with the IIA region of bovine serum albumin, which can significantly improve the solubility of drugs in plasma ; Amphiphilic block copolymers also mainly rely on their own hydrophobic domains to load hydrophobic small molecule drugs through hydrophilic and hydrophobic forces, such as PLGA, due to their excellent biocompatibility, low biotoxicity and good in vivo The degradability makes it certified by the US Food and Drug Administration and officially included in the US Pharmacopoeia as a pharmaceutical excipient, and has been approved for the in vivo delivery system of various drugs, but it is difficult for the above-mentioned carriers to achieve the novel coronavirus S protein. Loading, this is due to the large molecular weight (140KD) of the new crown S protein, which has a large steric hindrance effect, and cannot be effectively loaded in a nanosystem in large capacity; and the steric effect of the antigen of the S protein makes it only through adsorption Alternatively, water-in-oil is loaded into the nanoparticle core. The above two loading methods are not only inefficient, but also easier to release and difficult to store stably.

Contents of the invention

The object of the present invention is to provide a novel coronavirus subprotein nano-vaccine and its preparation method and application, by coupling polylactic acid with porphyrins, and chelating Co ²⁺ ions that can be linked to histidine tags , forming an organic compound self-assembled by polylactic acid, porphyrin or porphyrin derivatives, and Co ²⁺ ion conjugates. The core of the organic compound is coated with adjuvant, the core-shell surface is coated with lipid, and the surface is also efficiently loaded with 2019-nCoV antigenic protein, thereby realizing a nano-vaccine system co-delivered with 2019-nCoV antigenic protein and vaccine adjuvant, which can not only maximize the immunogenicity of 2019-nCoV recombinant subprotein, but also display Track its distribution in the organism; further, it is designed and loaded with polypeptides that can specifically target antigen-presenting cells, so as to more effectively promote the body's antiviral response.

In order to achieve the above object, the technical scheme adopted in the present invention is:

The present invention provides a novel coronavirus subprotein nano-vaccine, said nano-vaccine comprising: organic compounds self-assembled by polylactic acid, porphyrin or porphyrin derivatives and Co ²⁺ ion conjugates; novel coronavirus antigenic protein; Vaccine adjuvants and lipids.

Further, the organic compound self-assembled from polylactic acid, porphyrin or porphyrin derivatives and Co ²⁺ ion conjugates in the nano-vaccine has a core-shell structure, the core is a vaccine adjuvant, and the core-shell is wrapped with a lipid , the surface of the nucleocapsid is loaded with novel coronavirus antigenic protein.

Further, the surface of the core-shell is also loaded with a targeting polypeptide targeting antigen-presenting cells, wherein the amino acid sequence of the targeting polypeptide is shown in SEQ ID NO:1. Wherein the antigen-presenting cells include: dendritic cells and macrophages, and the targeting polypeptide is obtained by phage display technology.

Further, the novel coronavirus antigenic protein and the targeting polypeptide are respectively linked to organic compounds through histidine tags.

Further, the novel coronavirus antigenic protein is the RBD protein of the novel coronavirus.

Further, the porphyrin derivative is a porphyrin derivative containing only one carboxyl group.

Further, the porphyrin derivative is pyropheophorbide-α.

Further, the vaccine adjuvant can be selected from: TLR7 agonist, TLR8 agonist, TLR9 agonist, QS-21 adjuvant.

Further, the molecular weight of the polylactic acid is preferably 1500-3000.

Further, the lipid is PEG-phospholipid, preferably PEG-DSPE, more preferably DSPE-PEG2000.

Further, the structural formula of the organic compound is:

The present invention also provides a preparation method of the above-mentioned novel coronavirus subprotein nano-vaccine, comprising:

Step 1, reacting polylactic acid with porphyrin or porphyrin derivatives, making the hydroxyl at the end of polylactic acid condense with the carboxyl groups of porphyrin or porphyrin derivatives, so that porphyrin or porphyrin derivatives are bonded to polylactic acid for polymerization the end of the chain of things;

Step 2, adding Co ²⁺ ions to the product of step 1, so that Co ²⁺ ions are embedded in the porphyrin ring, to obtain organic compounds self-assembled by polylactic acid, porphyrin or porphyrin derivatives and Co ²⁺ ion conjugates ;

Step 3, mixing and dissolving the organic compound, lipid and vaccine adjuvant prepared in step 2, dripping in normal saline, evaporating the organic solvent to obtain a nanocarrier solution containing cobalt ion porphyrin rings evenly distributed in normal saline;

Step 4. Incubate the novel coronavirus antigenic protein linked with the histidine tag with the nanocarrier solution prepared in step 3 overnight, and ultracentrifuge to obtain a nanovaccine bound to the novel coronavirus antigenic protein.

Further, the preparation method also includes: simultaneously incubating the novel coronavirus antigen protein containing histidine tag and the specific targeting polypeptide with the nanocarrier solution overnight, and then ultracentrifuging to obtain the nanovaccine.

Further, in step 1, polylactic acid is added to pyropheophorbide-α, and then 1-(3-dimethylaminopropyl)-3-ethylcarbodiimide hydrochloride and 4 -Dimethylaminopyridine, reacting in an ice bath until the disappearance of the starting alcohol is detected, then the reaction solution is extracted, washed and dried, and the solvent is removed to obtain the product PLA-pyropheophorbide.

The present invention also provides the application of the above novel coronavirus subprotein nano-vaccine in the preparation of immunogenic compositions for diseases related to novel coronavirus infection.

The present invention also provides the application of the above novel coronavirus subprotein nano-vaccine in the preparation of nano-tracers.

Compared with the prior art, the beneficial effect of the present invention is: the present invention is formed by ^polylactic acid, porphyrin or porphyrin derivative and An organic compound self-assembled by a Co ²⁺ ion conjugate, the organic compound is connected to a histidine tag through a Co ²⁺ ion to achieve efficient loading of the new coronavirus antigen protein; and the chemically coupled porphyrin itself can produce The function of fluorescence traces the distribution of nanoparticles in the body; at the same time, the core of the vaccine is wrapped with an adjuvant, and the surface of the core-shell is wrapped with lipids, thus realizing the co-delivery of the new coronavirus antigen protein and vaccine adjuvant nano-vaccine system. Furthermore, the present invention also designs and loads polypeptides that can target antigen-presenting cells on the surface of the compound, thereby promoting the massive uptake of nano-vaccine by DC cells and more effectively promoting the body's antiviral response. That is, the present invention provides a new type of coronavirus subprotein nano-vaccine with the functions of efficiently loading antigen, simultaneously carrying adjuvant and antigen, tracing the distribution of nano-vaccine, and specifically and efficiently targeting DC cells, and its preparation method is simple and efficient , providing a new and efficient approach and option for the effective prevention of novel coronavirus infection and the preparation of novel coronavirus subprotein nano-vaccine.

Description of drawings

Fig. 1 is the nano vaccine NPQ-RBD structural representation prepared in the embodiment of the present invention 1;

Fig. 2 is the acquisition method of the polypeptide specifically targeting antigen-presenting cells in Example 1 of the present invention;

Fig. 3 is the nano vaccine NPQ-RBD-AP structural representation prepared in the embodiment of the present invention 1;

Fig. 4 is the stability detection result of nano vaccine in the embodiment of the present invention 1;

Fig. 5 is the in vitro targeting detection result of the nano-vaccine in Example 2 of the present invention to mouse bone marrow-derived dendritic cells;

Fig. 6 is the detection result of the activation effect of nano-vaccine on mouse bone marrow-derived dendritic cells in Example 2 of the present invention;

Figure 7 is the detection result of the nano-vaccine targeting lymph nodes and antigen-presenting cells in the lymph nodes in Example 2 of the present invention;

Fig. 8 is the detection result of the antibody titer of the anti-RBD fragment produced by the nano-vaccine-induced animal serum in Example 2 of the present invention;

Fig. 9 is the detection result of the antibody titer of the anti-RBD fragment produced by the nano-vaccine NPQ-RBD in Example 2 of the present invention induced by animal serum over time;

Figure 10 is the detection result of the cellular immune effect of the nano-vaccine inducing the body to produce RBD fragments in Example 2 of the present invention;

Fig. 11 is the detection result of the nano-vaccine in Example 2 of the present invention on the resistance of hACE2 human-derived mice to lung infection caused by the new coronavirus COVID-19.

detailed description

The technical solutions of the present invention will be clearly and completely described below in conjunction with the embodiments of the present invention. Obviously, the described embodiments are only some of the embodiments of the present invention, not all of them. Based on the embodiments of the present invention, all other embodiments obtained by persons of ordinary skill in the art without making creative efforts belong to the protection scope of the present invention.

The preparation of embodiment 1 novel coronavirus subprotein nano-vaccine

1. Synthesis of polylactic acid PLA

PLA was synthesized by ring-opening polymerization of L-lactide (L-LA) and D-lactide (D-LA) with n-hexanol as the initiator and stannous octoate (Sn(Oct) ₂ ) as the catalyst. Its synthesis path is as follows:

The specific operation steps are:

Weigh 0.2500g of n-hexanol in the glove box and place it in a dry ampoule, add 2.1180g of L-LA and D-LA, and add 0.31mL of Sn(Oct) ₂ solution with a concentration of 0.02g/mL prepared in advance , and finally add 21.0 mL of dry toluene. The polymerization reaction was carried out at 130° C. under N ₂ environment for 2 days. The solution was settled with 200 mL of glacial ether, and the obtained product was dried at room temperature for 24 h. Then the product was dissolved in N,N-dimethylformamide (DMF), dialyzed in DMF through a dialysis bag (MWCO=1000D) for 48 hours to remove a small amount of unreacted monomer, transferred to deionized water for dialysis to remove organic solvents, and frozen Dry to obtain the final product.

The successful assignment of each peak in ¹ H NMR and the calculation of the peak area proved that the polymer was successfully synthesized. The currently known molecular weight of PLA can range from hundreds to tens of thousands. The larger its own molecular weight, the stronger its hydrophobicity, and the larger the difference between its molecular weight and that of excipients, the weaker its loading capacity. That is, PLA with different molecular weights can be prepared by adjusting the feed ratio, and the nanovaccine prepared based on PLA with different molecular weights has different loading capabilities for the target protein. By preference, the present invention selects PLA with a molecular weight of 1500-3000 to maximize the loading of the novel coronavirus antigenic protein RBD protein.

2. Covalent combination of PLA and porphyrins

In this example, taking the porphyrin substance: pyropheophorbide-α as an example, the PLA prepared above was reacted with pyropheophorbide-α, and the hydroxyl group at the end of PLA reacted with pyropheophorbide-α. The condensation reaction between the carboxyl groups of α makes pyropheophorbide-α bond to the end of the PLA polymer chain, and the synthesis route is as follows:

The specific steps are:

To a solution of pyropheophorbide (53.4 mg) in dry dichloromethane was added 162.3 mg of PLA followed by 38.6 mg of 1-(3-dimethylaminopropyl)-3-ethylcarbodiimide salt salt (EDC), 49.8 mg of 4-dimethylaminopyridine, reacted in an ice bath for 24 hours, and after the disappearance of the initial alcohol was detected by TCL spotting, the reaction solution was poured into water, and the product was extracted several times with dichloromethane, and combined The dichloromethane phase was washed successively with 4% NaHCO ₃ aqueous solution and saturated brine, and dried over anhydrous magnesium sulfate for 12 h. The dichloromethane solution of the product was obtained by suction filtration, and then the solvent was removed by a rotary evaporator to obtain a crude product, which was dialyzed through a dialysis bag (MWCO=1000D) for 48 hours to remove a small amount of impurities, and then freeze-dried to obtain the product PLA-pyropheophorbide. All reaction processes were carried out in the dark.

The successful assignment of the peaks of Ppa and PDLLA in ¹ H NMR, and the disappearance of the carboxyl peak in the reactant Ppa proved that the condensation reaction proceeded successfully. The ultraviolet-visible absorption spectrum (UV-vis) shows that the material has a similar absorption peak position to Ppa.

3. Coordination and chelation of Co ²⁺ ions

By embedding metal ions in the porphyrin ring, using metal ions to realize the combination with the target antigen with histidine tag, the present invention preferably finds that among all divalent metal ions that can bind to histidine tag, divalent Co The binding efficiency of ²⁺ ions is the highest, so Co ²⁺ is selected to be chimerized into the porphyrin ring for binding to antigens containing histidine tags. Co ²⁺ ions can be bound to the N atom in the center of the molecular skeleton in a coordinated manner , the synthesis path is as follows:

The specific steps are:

To the above-prepared PLA-pyropheophorbide (50 mg) in dichloromethane (10.0 mL) was added a saturated methanol solution of cobalt chloride (1.0 mL) and stirred for 12 h. Remove the solvent with a rotary evaporator, then dissolve it with 2.0 mL of dichloromethane, wash with 4% NaHCO ₃ aqueous solution and saturated brine successively, dry over anhydrous magnesium sulfate, filter, and remove the solvent by a rotary evaporator to obtain the product, which is bound to cobalt ions PLA organic compounds with porphyrin rings. UV-vis showed that after Co ²⁺ coordination, the absorption peak position red-shifted.

4. Purification of RBD protein

The RBD fragment is the key domain for the new coronavirus to bind to the ACE2 receptor of human lung epithelial cells, and it is also the most effective region currently routinely used to prepare vaccines. Construct the extracellularly secreted and expressed in cells RBD fragment lentiviral plasmids containing histidine tags, obtain puromycin-resistant lentiviruses capable of infecting cells, transfect CHO cells, and use puromycin to screen for expression CHO cell lines of RBD protein fragments. Expand the cell line to obtain supernatant or cell suspension; if it is cell suspension, add PBS solution combined with ultrasound to obtain PBS supernatant containing whole cell protein. A purification column containing a nickel ion column was used to obtain the RBD protein expressing only the histidine tag, followed by dialysis in saline solution to obtain the final desired RBD protein.

5. Loading of RBD protein

Compared with other adjuvants, saponin adjuvants are considered to be the most promising adjuvants because they can induce both humoral immunity and cellular immunity at a low dose, and have been used in relevant clinical trials of tumor vaccines and virus vaccines Research and development, and due to the hydrophilic and hydrophobic properties of the adjuvant, it can be perfectly combined with the nano system, so this example uses QS-21 as the vaccine adjuvant, and DSPE-PEG2000 phospholipid as the nano system. The present invention found that by adjusting the content ratio of DSPE-PEG2000 and PLA, the ability of the nanosystem to bind to proteins expressing histidine tags can be changed, and the system with the best loading effect is as follows:

Dissolve the above-mentioned organic compound, DSPE-PEG2000 phospholipid and QS-21 adjuvant in 1 mL of tetrahydrofuran, wherein the mass ratio of the organic compound, DSPE-PEG2000 phospholipid and QS-21 adjuvant is 1:10:10. The dissolved solution was dropped dropwise into physiological saline at a temperature of 70°C, and the organic solvent was rotatively evaporated to obtain a nanocarrier NPQ solution containing cobalt ion porphyrin rings evenly distributed in physiological saline;

The 10KD ultrafiltration centrifuge tube was centrifuged at 3000rpm to obtain a high-concentration saline solution containing nanocarriers; the excess RBD fragments were incubated with a solution containing nanocarrier NPQ at 4°C overnight, and then obtained by ultracentrifugation combined with RBD fragments and The nano-vaccine of QS-21 (NPQ-RBD), its structural schematic diagram is shown in Figure 1.

6. Co-loading of RBD protein and targeting peptide

Lymph node dendritic cells (DC) are important antigen-presenting cells in the body. In order to improve the antiviral response of the body promoted by nano-vaccine, a polypeptide that can specifically target antigen-presenting cells was further screened and synthesized by phage technology. The amino acid sequence is: LDLFRELPFEWLEALKQKLK (shown in SEQ ID NO.1), which is connected to the RBD protein with an organic compound through a histidine tag and loaded on the surface of the nano-vaccine. The specific operation steps are:

Obtain the nanocarrier NPQ solution according to the above method, centrifuge the 10KD ultrafiltration centrifuge tube at 3000rpm to obtain the physiological saline solution containing the nanocarrier at a high concentration; The solution was incubated overnight at 4°C, and then ultracentrifuged to obtain a nanovaccine (NPQ-RBD-AP) combined with RBD fragments, targeting polypeptides and QS-21, the schematic diagram of which is shown in Figure 3 .

7. Analysis of the binding efficiency of proteins with different molecular weights and NPQ carrier

In order to verify that the NPQ carrier preferably prepared in the present invention has high binding efficiency for RBD protein fragments, proteins with different molecular weights were selected respectively: His-IL-2 (interleukin-2 containing 6 histidine tags), His-IL-2 -RBD (RBD protein containing 6 histidine tags), His-BSA (bovine serum albumin containing 6 histidine tags), His-spike protein (new coronavirus Spike protein containing 6 histidine tags protein) as the research object; in the nano-carriers of equal concentration, add the above-mentioned protein of the same concentration (50nmol), after reacting at room temperature for 30 minutes, carry out HPLC identification, analyze the content of free protein, and according to the formula: the total protein added Content-free protein content/total protein content*100%, calculate the binding efficiency of different molecular weight proteins and NPQ carrier, the results are shown in Table 1:

Table 1 The binding efficiency of different molecular weights and NPQ carriers

protein name	molecular weight	Molar mass	Binding efficiency with NPQ
His-IL-2	15KD	50nmol	72%
His-RBD	26.1KD	50nmol	92%
His-BSA	66.5KD	50nmol	75%
His-spike protein	190KD	50nmol	62%

The results show that the nanocarrier NPQ prepared by the present invention has the highest loading efficiency for RBD protein, and its binding efficiency with NPQ is as high as 92%.

The effect verification of embodiment 2 nano vaccine NPQ-RBD and NPQ-RBD-AP

1. Characterization of Nano Vaccines

Nano-vaccine NPQ-RBD and NPQ-RBD-AP were respectively prepared by the method described in Example 1, and the particle size was detected to be between 100-200nm, and the nanoparticles in this range can effectively penetrate lymphatic vessels and be drained to the lymph nodes.

In order to verify the stability of the nano-vaccine NPQ-RBD and NPQ-RBD-AP carrying RBD fragments, the amino acid fragments on the nano-NPQ-RBD were labeled with FITC molecules; the nano-particles were dialyzed in saline at 4°C, and the fractions were collected every day Solution, using a microplate reader to detect the relative FITC fluorescence intensity in the nanometer, and set the nanoparticle NP-RBD control group without adjuvant, and the group injected with only RBD antigen. The detection results are shown in Figure 4.

The results show that the nano-vaccine NPQ-RBD and NPQ-RBD-AP prepared by the present invention have good stability, can be stable for more than one week, and still carry more than 70% of RBD fragments;

2. Nanovaccine targets and activates mouse bone marrow-derived dendritic cells (BMDC) in vitro

Extract the bone marrow of male 7-8-week-old mice under sterile conditions, stimulate with 20ug/mL GM-CSF in vitro for 7 days, and then obtain mouse bone marrow-derived dendritic cells BMDC, and place BMDC in a confocal small dish After culturing, FITC staining of NPQ-RBD and NPQ-RBD-AP, using a 20x objective lens to photograph the situation of BMDC uptake of nanometers, the detection results are shown in Figure 5.

The results showed that both NPQ-RBD and NPQ-RBD-AP could be taken up by dendritic cells, and the nanovaccine carrying the polypeptide targeting antigen-presenting cells could be taken up efficiently by dendritic cells.

Add BMDC to a six-well plate, 5×10 ⁵ /well, and add 100 μL of NPQ-RBD and NPQ-RBD-AP suspension to each well. After continuing to culture in the incubator for 24 hours, the expression of CD80 and CD86, the markers of DC cell activation, were detected by flow cytometry, and the expression of untreated DC cells, organic nanoparticles NP without adjuvant and RBD antigen, adjuvant DC cells were treated with QS21 and bacterial lipopolysaccharide LPS that non-specifically activates DC cells as controls, and the results are shown in FIG. 6 .

The results showed that compared with untreated DC cells, the expression of CD80 and CD86 in DC cells treated with NPQ-RBD and NPQ-RBD-AP was significantly increased, which proved that NPQ-RBD and NPQ-RBD-AP nanovaccine could It can significantly activate mouse bone marrow-derived dendritic cells (BMDC) in vitro; in addition, the experimental results also confirm that the nanocarrier NP itself can also activate DC cells to a certain extent.

3. Nanovaccine targets lymph nodes and antigen-presenting cells in lymph nodes

Use rhodamine to label the RBD fragment on the nano-vaccine NPQ-RBD-AP, and then inject 100 μL of the above solution into the base of the tail of the mouse; 24 hours later, use small animal live imaging to detect the extent to which the nano-vaccine reaches the lymph nodes, and the test results are shown in Figure 7 Then the dissected lymph nodes were subjected to frozen sections and immunofluorescence operations, CD11c antibody was used to label DC cells, F4-80 antibody was used to label macrophages, and laser confocal microscopy was used to observe the positioning of nanometers in lymph nodes. The positioning detection results are shown in Figure 7 shown. The results showed that the nanovaccine NPQ-RBD-AP can effectively reach the draining lymph node site, and can be specifically enriched in the area of antigen-presenting cells, such as DC cells and macrophages.

4. Anti-RBD fragment antibody titer detection in animal serum induced by nano-vaccine

100 μL of nanovaccine NPQ-RBD and NPQ-RBD-AP carrying RBD fragments were injected subcutaneously at the base of the tail of C57 mice for two immunizations, and the mouse serum was detected on the 8th and 18th days after the second immunization Antibody titers against RBD fragments, and injection of PBS, adjuvant QS-21, RBD fragments without carrier, and nanoparticle NP-RBD without adjuvant were used as controls.

Acquisition of mouse serum: The method of taking blood from the orbital venous plexus is used to obtain 200-300 μL of mouse blood each time, coagulate at room temperature for half an hour, and then centrifuge at 4000rpm for 30 minutes to obtain mouse serum; use the ELisa reagent for detecting RBD antibodies The box detects the titer of the IgG antibody against the RBD fragment contained in the mouse serum, wherein the detection results of different treatment groups are shown in Figure 8, and the detection results of the antibody titer of the nano-vaccine NPQ-RBD changing over time are shown in Figure 9 Show.

The results show that the nano-vaccine prepared by the present invention can effectively induce the production of antibodies in the RBD region, and the antibody titer produced is more than 3000 times that of the control group, which proves that the vaccine has the potential to prevent new coronaviruses. The titer can exist in the mouse serum for at least 10 days, which proves the persistence of the antibody produced by the nanovaccine.

5. Nano-vaccine induces the body to produce cellular immunity against RBD fragments

100 μL of nanovaccine NPQ-RBD and NPQ-RBD-AP carrying RBD fragments were injected subcutaneously at the base of the tail of C57 mice, and injected with PBS, adjuvant QS-21, RBD fragments without carrier, and adjuvant-free respectively. Nanoparticle NP-RBD served as a control. A total of two immunizations were performed. One month after the second immunization, the mice were sacrificed by vertebral dislocation, the mouse spleen and lymph node cells were extracted, and the erythrocytes were lysed by ACK to make a single cell suspension. Add RBD protein fragments to stimulate T cells again, use flow cytometry to detect the ratio of IL-2, TNF-α and IFN-γ and other cytokines expressed in CD8 positive T cells in cell suspension, and detect CD4 positive T cells at the same time The proportion of cells expressing IFN-γ is used to judge the generation of adaptive immunity in mice. The test results are shown in Figure 10.

The results show that both the nano-vaccine NPQ-RBD and NPQ-RBD-AP prepared by the present invention have a strong effect of inducing the body to produce cellular immunity against RBD fragments.

6. Nano vaccine against lung infection caused by novel coronavirus COVID-19

Using hACE2 human-derived mice, 100 μL of nanovaccine NPQ-RBD and NPQ-RBD-AP carrying RBD fragments were injected subcutaneously at the base of the tail of the mice, and injected with PBS, adjuvant QS-21, and carrier-free respectively. RBD fragment, nanoparticle NP-RBD without adjuvant served as control. A total of two immunizations; two weeks after the second immunization, the human-derived hACE2 mice were challenged, that is, the mice were infected with the COVID-19 virus, and one week after the infection, the mice were lavaged with PBS The mouse lungs were collected to detect the infection of the new coronavirus in the lungs of the mice, and the infection of the mice was determined by detecting the mRNA of the new coronavirus; the mice were sacrificed, and the lungs of the mice were obtained. Perform HE staining to judge the inflammation of the mouse lungs. The detection results are shown in Figure 11, where Figure 11-B is the detection result of the RNA copy number, 11-C is the detection result of the antibody titer, and 11-D is the observation of lung inflammation result.

The results showed that there were no obvious lesions in the lungs of the mice, that is, the nano-vaccine NPQ-RBD and NPQ-RBD-AP prepared by the present invention can effectively prevent hACE2 human-derived mice from being infected with the new coronavirus.

The above is only a preferred embodiment of the present invention, but the scope of protection of the present invention is not limited thereto. Any person skilled in the art can easily conceive of changes or modifications within the technical scope disclosed in the present invention. Replacement should be covered within the protection scope of the present invention.

Claims (10)

1. A novel coronavirus subprotein nano-vaccine, characterized in that the nano-vaccine includes: an organic compound self-assembled by polylactic acid, porphyrin or porphyrin derivatives and Co ^ion conjugates; novel coronavirus antigenic protein; Vaccine adjuvants and lipids.
2. The novel coronavirus subprotein nano-vaccine according to claim 1, characterized in that, in the nano-vaccine, the organic compound self-assembled by polylactic acid, porphyrin or porphyrin derivatives and Co ^ion conjugates is a core-shell Structure, the core is a vaccine adjuvant, the core-shell is wrapped with lipids, and the surface of the core-shell is loaded with novel coronavirus antigenic proteins.
3. The novel coronavirus subprotein nano-vaccine according to claim 2, wherein the surface of the core-shell is also loaded with a targeting polypeptide targeting antigen-presenting cells, wherein the amino acid sequence of the targeting polypeptide is as SEQ ID NO:1 shown.
4. The novel coronavirus subprotein nano-vaccine according to claim 3, wherein the novel coronavirus antigenic protein and the targeting polypeptide are respectively linked to organic compounds through a histidine tag.
5. The novel coronavirus subprotein nano-vaccine according to claim 1, wherein the novel coronavirus antigenic protein is the RBD protein of novel coronavirus.
6. The novel coronavirus subprotein nano-vaccine according to claim 1, wherein the porphyrin derivative is a porphyrin derivative containing only one carboxyl group.
7. The novel coronavirus subprotein nano-vaccine according to claim 6, wherein the structural formula of the organic compound is:

   
8. The preparation method of the novel coronavirus subprotein nano-vaccine as described in any one of claims 1-7, is characterized in that, described method comprises:

   Step 1, reacting polylactic acid with porphyrin or porphyrin derivatives, making the hydroxyl at the end of polylactic acid condense with the carboxyl groups of porphyrin or porphyrin derivatives, so that porphyrin or porphyrin derivatives are bonded to polylactic acid for polymerization the end of the chain of things;

   Step 2, adding Co ²⁺ ions to the product of step 1, so that Co ²⁺ ions are embedded in the porphyrin ring, to obtain organic compounds self-assembled by polylactic acid, porphyrin or porphyrin derivatives and Co ²⁺ ion conjugates ;

   Step 3, mixing and dissolving the organic compound, lipid and vaccine adjuvant prepared in step 2, dropping them into normal saline, evaporating the organic solvent to obtain a nanocarrier solution containing cobalt ion porphyrin rings uniformly distributed in normal saline;

   Step 4. Incubate the novel coronavirus antigenic protein linked with the histidine tag with the nanocarrier solution prepared in step 3 overnight, and ultracentrifuge to obtain a nanovaccine bound to the novel coronavirus antigenic protein.
9. Application of the novel coronavirus subprotein nano-vaccine according to any one of claims 1-7 in the preparation of immunogenic compositions for diseases related to novel coronavirus infection.
10. Application of the novel coronavirus subprotein nano-vaccine as described in any one of claims 1-7 in the preparation of nano-tracers.

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