TY  - JOUR
AU  - Mladenović Stokanić, Maja
AU  - Simović, Ana
AU  - Jovanović, Vesna
AU  - Radomirović, Mirjana
AU  - Udovički, Božidar
AU  - Krstić Ristivojević, Maja
AU  - Djukić, Teodora
AU  - Vasović, Tamara
AU  - Aćimović, Jelena
AU  - Sabljić, Ljiljana
AU  - Lukić, Ivana
AU  - Kovačević, Ana
AU  - Cujic, Danica
AU  - Gnjatović, Marija
AU  - Smiljanić, Katarina
AU  - Stojadinović, Marija
AU  - Radosavljević, Jelena
AU  - Stanić-Vučinić, Dragana
AU  - Stojanović, Marijana
AU  - Rajković, Andreja
AU  - Ćirkovic Veličković, Tanja
PY  - 2024
UR  - http://intor.torlakinstitut.com/handle/123456789/858
AB  - In this study, a cost-effective sandwich ELISA test, based on polyclonal antibodies, for routine quantification SARS-CoV-2 nucleocapsid (N) protein was developed. The recombinant N protein was produced and used for the production of mice and rabbit antisera. Polyclonal N protein-specific antibodies served as capture and detection antibodies. The prototype ELISA has LOD 0.93 ng/mL and LOQ 5.3 ng/mL, with a linear range of 1.52–48.83 ng/mL. N protein heat pretreatment (56 °C, 1 h) decreased, while pretreatment with 1% Triton X-100 increased analytical ELISA sensitivity. The diagnostic specificity of ELISA was 100% (95% CI, 91.19–100.00%) and sensitivity was 52.94% (95% CI, 35.13–70.22%) compared to rtRT-PCR (Ct < 40). Profoundly higher sensitivity was obtained using patient samples mostly containing Wuhan-similar variants (Wuhan, alpha, and delta), 62.50% (95% CI, 40.59 to 81.20%), in comparison to samples mostly containing Wuhan-distant variants (Omicron) 30.00% (6.67–65.25%). The developed product has relatively high diagnostic sensitivity in relation to its analytical sensitivity due to the usage of polyclonal antibodies from two species, providing a wide repertoire of antibodies against multiple N protein epitopes. Moreover, the fast, simple, and inexpensive production of polyclonal antibodies, as the most expensive assay components, would result in affordable antigen tests.
PB  - MDPI
T2  - International Journal of Molecular Sciences
T1  - Sandwich ELISA for the Quantification of Nucleocapsid Protein of SARS-CoV-2 Based on Polyclonal Antibodies from Two Different Species
IS  - 1
SP  - 333
VL  - 25
DO  - 10.3390/ijms25010333
ER  - 

@article{
author = "Mladenović Stokanić, Maja and Simović, Ana and Jovanović, Vesna and Radomirović, Mirjana and Udovički, Božidar and Krstić Ristivojević, Maja and Djukić, Teodora and Vasović, Tamara and Aćimović, Jelena and Sabljić, Ljiljana and Lukić, Ivana and Kovačević, Ana and Cujic, Danica and Gnjatović, Marija and Smiljanić, Katarina and Stojadinović, Marija and Radosavljević, Jelena and Stanić-Vučinić, Dragana and Stojanović, Marijana and Rajković, Andreja and Ćirkovic Veličković, Tanja",
year = "2024",
abstract = "In this study, a cost-effective sandwich ELISA test, based on polyclonal antibodies, for routine quantification SARS-CoV-2 nucleocapsid (N) protein was developed. The recombinant N protein was produced and used for the production of mice and rabbit antisera. Polyclonal N protein-specific antibodies served as capture and detection antibodies. The prototype ELISA has LOD 0.93 ng/mL and LOQ 5.3 ng/mL, with a linear range of 1.52–48.83 ng/mL. N protein heat pretreatment (56 °C, 1 h) decreased, while pretreatment with 1% Triton X-100 increased analytical ELISA sensitivity. The diagnostic specificity of ELISA was 100% (95% CI, 91.19–100.00%) and sensitivity was 52.94% (95% CI, 35.13–70.22%) compared to rtRT-PCR (Ct < 40). Profoundly higher sensitivity was obtained using patient samples mostly containing Wuhan-similar variants (Wuhan, alpha, and delta), 62.50% (95% CI, 40.59 to 81.20%), in comparison to samples mostly containing Wuhan-distant variants (Omicron) 30.00% (6.67–65.25%). The developed product has relatively high diagnostic sensitivity in relation to its analytical sensitivity due to the usage of polyclonal antibodies from two species, providing a wide repertoire of antibodies against multiple N protein epitopes. Moreover, the fast, simple, and inexpensive production of polyclonal antibodies, as the most expensive assay components, would result in affordable antigen tests.",
publisher = "MDPI",
journal = "International Journal of Molecular Sciences",
title = "Sandwich ELISA for the Quantification of Nucleocapsid Protein of SARS-CoV-2 Based on Polyclonal Antibodies from Two Different Species",
number = "1",
pages = "333",
volume = "25",
doi = "10.3390/ijms25010333"
}

Mladenović Stokanić, M., Simović, A., Jovanović, V., Radomirović, M., Udovički, B., Krstić Ristivojević, M., Djukić, T., Vasović, T., Aćimović, J., Sabljić, L., Lukić, I., Kovačević, A., Cujic, D., Gnjatović, M., Smiljanić, K., Stojadinović, M., Radosavljević, J., Stanić-Vučinić, D., Stojanović, M., Rajković, A.,& Ćirkovic Veličković, T.. (2024). Sandwich ELISA for the Quantification of Nucleocapsid Protein of SARS-CoV-2 Based on Polyclonal Antibodies from Two Different Species. in International Journal of Molecular Sciences
MDPI., 25(1), 333.
https://doi.org/10.3390/ijms25010333

Mladenović Stokanić M, Simović A, Jovanović V, Radomirović M, Udovički B, Krstić Ristivojević M, Djukić T, Vasović T, Aćimović J, Sabljić L, Lukić I, Kovačević A, Cujic D, Gnjatović M, Smiljanić K, Stojadinović M, Radosavljević J, Stanić-Vučinić D, Stojanović M, Rajković A, Ćirkovic Veličković T. Sandwich ELISA for the Quantification of Nucleocapsid Protein of SARS-CoV-2 Based on Polyclonal Antibodies from Two Different Species. in International Journal of Molecular Sciences. 2024;25(1):333.
doi:10.3390/ijms25010333 .

Mladenović Stokanić, Maja, Simović, Ana, Jovanović, Vesna, Radomirović, Mirjana, Udovički, Božidar, Krstić Ristivojević, Maja, Djukić, Teodora, Vasović, Tamara, Aćimović, Jelena, Sabljić, Ljiljana, Lukić, Ivana, Kovačević, Ana, Cujic, Danica, Gnjatović, Marija, Smiljanić, Katarina, Stojadinović, Marija, Radosavljević, Jelena, Stanić-Vučinić, Dragana, Stojanović, Marijana, Rajković, Andreja, Ćirkovic Veličković, Tanja, "Sandwich ELISA for the Quantification of Nucleocapsid Protein of SARS-CoV-2 Based on Polyclonal Antibodies from Two Different Species" in International Journal of Molecular Sciences, 25, no. 1 (2024):333,
https://doi.org/10.3390/ijms25010333 . .

TY  - DATA
AU  - Mladenović Stokanić, Maja
AU  - Simović, Ana
AU  - Jovanović, Vesna
AU  - Radomirović, Mirjana
AU  - Udovički, Božidar
AU  - Krstić Ristivojević, Maja
AU  - Djukić, Teodora
AU  - Vasović, Tamara
AU  - Aćimović, Jelena
AU  - Sabljić, Ljiljana
AU  - Lukić, Ivana
AU  - Kovačević, Ana
AU  - Cujic, Danica
AU  - Gnjatović, Marija
AU  - Smiljanić, Katarina
AU  - Stojadinović, Marija
AU  - Radosavljević, Jelena
AU  - Stanić-Vučinić, Dragana
AU  - Stojanović, Marijana
AU  - Rajković, Andreja
AU  - Ćirkovic Veličković, Tanja
PY  - 2024
UR  - http://intor.torlakinstitut.com/handle/123456789/859
AB  - S1.1. Checking of N protein purity Recombinant N protein purity was checked after imidazole removal and buffer exchange by SDS PAGE (Figure 6.). For comparison, commercial high-purity HSA was also analyzed. S1.2. Identification of N protein Tandem mass spectrometry identification of proteins in an in-gel digested band of N protein (Figure S1, lane 3), confirmed the identity of N protein with high scores and peptide coverage (Fig. S2.). S2. Purification of polyclonal antibodies from mice and rabbit sera For the development of an ELISA test specific for the detection of SARS-CoV-2 N protein, recombinantly produced N protein was used for the immunization of mice and rabbits. Sera obtained from rabbits and mice were then tested for titer and specificity (Figure S3 and Figure 1). To determine the titer of polyclonal sera required to detect N protein in samples, we use wells coated with N protein and serial dilution of sera pools from different animals. After multiple washing steps, we detected the binding of rabbit and mice antibodies using secondary biotinylated antibodies and streptavidin-alkaline phosphatase chimaera or secondary antibodies with previously coupled alkaline phosphatase, where the amount of enzymes’ substrate converted to the product was measured as an increase in absorbance at 405 nm. As shown in Figure S3A, unpurified sera pools from both animals showed very high titers and expected logarithmic decrease of signal with dilution. Based on the obtained data titer for unpurified sera was determined to be X. The same trend was observed for pools purified using AS precipitation and rabbit sera purified using protein A affinity chromatography (Figure S3B and S3C). As shown in Figure S3D, clear bands from antibodies could be observed in both full and purified samples. Western blot analysis showed only one protein band on mass around 40 kDa, a Accession number / Protein Name Score Coverage (%) Unique peptides P0DTC9|NCAP_SARS2 Nucleoprotein OS=Severe acute respiratory syndrome coronavirus 2, 46 kDa 504.9 74.22 183 mass of purified N protein suggesting that the obtained sera is highly specific for N protein (Figure 2). Section S3 Diagnostic validationS3.1. Stabilization of capture antibodies Pre-coated ELISA plates were prepared for usage in clinical practice. To ensure the preservation of the biofunctionality of the surface-bound capture antibodies, the commonly used stabilizing excipient, 3% sucrose with 10% glycerol in MilliQ water was used. The plates were incubated with 300 μL per well of a stabilizing agent for 1 hour at room temperature. After an hour of incubation, the solution was carefully aspirated from each well. The plate was then blotted against clear paper towels to remove any remaining liquid, and the plates were allowed to air dry for 3 hours at RT. Dried plates were wrapped in parafilm and stored at 4 °C for later use. To remove the stabilizing agent coating, wells were washed with slightly acidic distilled water (pH of 6) three times, leaving the plate prepared for subsequent assay steps. Section S4. Characterization of N protein by HRMS S4.1. SDS PAGE and in-gel digestion Characterization of the produced recombinant N protein was done by HRMS after its in-gel digestion. A total of 10 μg of purified protein(s) were loaded in a 0.5 cm wide well and after SDSPAGE gel was stained with Coomassie Brilliant Blue R-250 (CBB). Protein gel bands were washed, reduced with dithiothreitol, and alkylated with iodoacetamide, followed by in-gel trypsin digestion1 (Shevchenko et al. 2006) with some minor modifications. The amount of trypsin was leveled to a trypsin/sample ratio of 1:30 (w/w). The final concentration of MS-grade trypsin (diluted in 25 mM ammonium bicarbonate buffer) was 1 ng/μL. Sample clean-up was performed using zip tips HyperSep C18 (Thermo Fisher Scientific Inc., Bremen, Germany). S5.1 Immunization of rabbits and mice Mice immunization Swiss Webster mice (n=10) were immunized subcutaneously with N protein formulated with Complete Freund`s adjuvant (CFA; 1st dose, 100 μg N protein / dose) or Incomplete Freund`s adjuvant (IFA; 2nd and 3rd doses, 50 μg N protein / dose) in three-week intervals. Mice were housed in small groups of up to six animals and had access to commercial mice food and water ad libitum. N protein solution (500ug/ml in PBS) was sterilized by filtering through 0.22 um filters. Sterile N protein solution was mixed with CFA (Sigma, Cat. No. F5881) at ratio 1:1 (v/v) under aseptic conditions. In total 400 ul of N protein-CFA emulsion (N protein final concentration 250ug/ml) was applied per immunization per mouse. Initial immunization was done by injection of N protein in CFA given subcutaneously (SC) in four sites (thigh pocket, base of tail, and mediastinum) with a 100 ul using 23-25 gauge needle. In total 100 ug of N protein was applied per mouse (25 ug per site). Subsequent immunizations with booster doses were done in the same way, but using IFA (Sigma, Cat. No. F5506) instead of CFA and N protein final concentration was 125 ug/ml. . In total 50 ug of N protein was applied per mouse (12.5 ug per site). Immunizations were done every three weeks. Mice immunization scheme: 1. day 0 – N protein in PBS: CFA = 1:1 (v/v); N protein final concentration was 250 μg/mL; 400 μL per mice (4x100 μL), e.g. 100 μg per mice 2. day 21 - N protein in PBS: IFA = 1:1 (v/v); N protein final concentration was 125 μg/mL; 400 μL per mice (4x100 μL), e.g. 50 μg per mice 3. day 42 - N protein in PBS: IFA = 1:1 (v/v); N protein final concentration was 125 μg/mL; 400 μl per mice (4x100 μL), e.g. 50 μg per mice First bleeding was performed two weeks after the 3rd dose, and then in intervals not shorter than two weeks. The sera obtained after the first bleeding was tested for the production of specific anti-N protein antibodies.
PB  - MDPI
T2  - International Journal of Molecular Sciences
T1  - Supplementary information for the article:       Mladenovic Stokanic, M.; Simovic, A.; Jovanovic, V.; Radomirovic, M.; Udovicki, B.; Krstic Ristivojevic, M.; Djukic, T.; Vasovic, T.; Acimovic, J.; Sabljic, L.; Lukic, I.; Kovacevic, A.; Cujic, D.; Gnjatovic, M.; Smiljanic, K.; Stojadinovic, M.; Radosavljevic, J.; Stanic-Vucinic, D.; Stojanovic, M.; Rajkovic, A.; Cirkovic Velickovic, T. Sandwich ELISA for the Quantification of Nucleocapsid Protein of SARS-CoV-2 Based on Polyclonal Antibodies from Two Different Species. International Journal of Molecular Sciences 2024, 25 (1), 333. https://doi.org/10.3390/ijms25010333.
IS  - 1
VL  - 25
UR  - https://hdl.handle.net/21.15107/rcub_intor_859
ER  - 

@misc{
author = "Mladenović Stokanić, Maja and Simović, Ana and Jovanović, Vesna and Radomirović, Mirjana and Udovički, Božidar and Krstić Ristivojević, Maja and Djukić, Teodora and Vasović, Tamara and Aćimović, Jelena and Sabljić, Ljiljana and Lukić, Ivana and Kovačević, Ana and Cujic, Danica and Gnjatović, Marija and Smiljanić, Katarina and Stojadinović, Marija and Radosavljević, Jelena and Stanić-Vučinić, Dragana and Stojanović, Marijana and Rajković, Andreja and Ćirkovic Veličković, Tanja",
year = "2024",
abstract = "S1.1. Checking of N protein purity Recombinant N protein purity was checked after imidazole removal and buffer exchange by SDS PAGE (Figure 6.). For comparison, commercial high-purity HSA was also analyzed. S1.2. Identification of N protein Tandem mass spectrometry identification of proteins in an in-gel digested band of N protein (Figure S1, lane 3), confirmed the identity of N protein with high scores and peptide coverage (Fig. S2.). S2. Purification of polyclonal antibodies from mice and rabbit sera For the development of an ELISA test specific for the detection of SARS-CoV-2 N protein, recombinantly produced N protein was used for the immunization of mice and rabbits. Sera obtained from rabbits and mice were then tested for titer and specificity (Figure S3 and Figure 1). To determine the titer of polyclonal sera required to detect N protein in samples, we use wells coated with N protein and serial dilution of sera pools from different animals. After multiple washing steps, we detected the binding of rabbit and mice antibodies using secondary biotinylated antibodies and streptavidin-alkaline phosphatase chimaera or secondary antibodies with previously coupled alkaline phosphatase, where the amount of enzymes’ substrate converted to the product was measured as an increase in absorbance at 405 nm. As shown in Figure S3A, unpurified sera pools from both animals showed very high titers and expected logarithmic decrease of signal with dilution. Based on the obtained data titer for unpurified sera was determined to be X. The same trend was observed for pools purified using AS precipitation and rabbit sera purified using protein A affinity chromatography (Figure S3B and S3C). As shown in Figure S3D, clear bands from antibodies could be observed in both full and purified samples. Western blot analysis showed only one protein band on mass around 40 kDa, a Accession number / Protein Name Score Coverage (%) Unique peptides P0DTC9|NCAP_SARS2 Nucleoprotein OS=Severe acute respiratory syndrome coronavirus 2, 46 kDa 504.9 74.22 183 mass of purified N protein suggesting that the obtained sera is highly specific for N protein (Figure 2). Section S3 Diagnostic validationS3.1. Stabilization of capture antibodies Pre-coated ELISA plates were prepared for usage in clinical practice. To ensure the preservation of the biofunctionality of the surface-bound capture antibodies, the commonly used stabilizing excipient, 3% sucrose with 10% glycerol in MilliQ water was used. The plates were incubated with 300 μL per well of a stabilizing agent for 1 hour at room temperature. After an hour of incubation, the solution was carefully aspirated from each well. The plate was then blotted against clear paper towels to remove any remaining liquid, and the plates were allowed to air dry for 3 hours at RT. Dried plates were wrapped in parafilm and stored at 4 °C for later use. To remove the stabilizing agent coating, wells were washed with slightly acidic distilled water (pH of 6) three times, leaving the plate prepared for subsequent assay steps. Section S4. Characterization of N protein by HRMS S4.1. SDS PAGE and in-gel digestion Characterization of the produced recombinant N protein was done by HRMS after its in-gel digestion. A total of 10 μg of purified protein(s) were loaded in a 0.5 cm wide well and after SDSPAGE gel was stained with Coomassie Brilliant Blue R-250 (CBB). Protein gel bands were washed, reduced with dithiothreitol, and alkylated with iodoacetamide, followed by in-gel trypsin digestion1 (Shevchenko et al. 2006) with some minor modifications. The amount of trypsin was leveled to a trypsin/sample ratio of 1:30 (w/w). The final concentration of MS-grade trypsin (diluted in 25 mM ammonium bicarbonate buffer) was 1 ng/μL. Sample clean-up was performed using zip tips HyperSep C18 (Thermo Fisher Scientific Inc., Bremen, Germany). S5.1 Immunization of rabbits and mice Mice immunization Swiss Webster mice (n=10) were immunized subcutaneously with N protein formulated with Complete Freund`s adjuvant (CFA; 1st dose, 100 μg N protein / dose) or Incomplete Freund`s adjuvant (IFA; 2nd and 3rd doses, 50 μg N protein / dose) in three-week intervals. Mice were housed in small groups of up to six animals and had access to commercial mice food and water ad libitum. N protein solution (500ug/ml in PBS) was sterilized by filtering through 0.22 um filters. Sterile N protein solution was mixed with CFA (Sigma, Cat. No. F5881) at ratio 1:1 (v/v) under aseptic conditions. In total 400 ul of N protein-CFA emulsion (N protein final concentration 250ug/ml) was applied per immunization per mouse. Initial immunization was done by injection of N protein in CFA given subcutaneously (SC) in four sites (thigh pocket, base of tail, and mediastinum) with a 100 ul using 23-25 gauge needle. In total 100 ug of N protein was applied per mouse (25 ug per site). Subsequent immunizations with booster doses were done in the same way, but using IFA (Sigma, Cat. No. F5506) instead of CFA and N protein final concentration was 125 ug/ml. . In total 50 ug of N protein was applied per mouse (12.5 ug per site). Immunizations were done every three weeks. Mice immunization scheme: 1. day 0 – N protein in PBS: CFA = 1:1 (v/v); N protein final concentration was 250 μg/mL; 400 μL per mice (4x100 μL), e.g. 100 μg per mice 2. day 21 - N protein in PBS: IFA = 1:1 (v/v); N protein final concentration was 125 μg/mL; 400 μL per mice (4x100 μL), e.g. 50 μg per mice 3. day 42 - N protein in PBS: IFA = 1:1 (v/v); N protein final concentration was 125 μg/mL; 400 μl per mice (4x100 μL), e.g. 50 μg per mice First bleeding was performed two weeks after the 3rd dose, and then in intervals not shorter than two weeks. The sera obtained after the first bleeding was tested for the production of specific anti-N protein antibodies.",
publisher = "MDPI",
journal = "International Journal of Molecular Sciences",
title = "Supplementary information for the article:       Mladenovic Stokanic, M.; Simovic, A.; Jovanovic, V.; Radomirovic, M.; Udovicki, B.; Krstic Ristivojevic, M.; Djukic, T.; Vasovic, T.; Acimovic, J.; Sabljic, L.; Lukic, I.; Kovacevic, A.; Cujic, D.; Gnjatovic, M.; Smiljanic, K.; Stojadinovic, M.; Radosavljevic, J.; Stanic-Vucinic, D.; Stojanovic, M.; Rajkovic, A.; Cirkovic Velickovic, T. Sandwich ELISA for the Quantification of Nucleocapsid Protein of SARS-CoV-2 Based on Polyclonal Antibodies from Two Different Species. International Journal of Molecular Sciences 2024, 25 (1), 333. https://doi.org/10.3390/ijms25010333.",
number = "1",
volume = "25",
url = "https://hdl.handle.net/21.15107/rcub_intor_859"
}

Mladenović Stokanić, M., Simović, A., Jovanović, V., Radomirović, M., Udovički, B., Krstić Ristivojević, M., Djukić, T., Vasović, T., Aćimović, J., Sabljić, L., Lukić, I., Kovačević, A., Cujic, D., Gnjatović, M., Smiljanić, K., Stojadinović, M., Radosavljević, J., Stanić-Vučinić, D., Stojanović, M., Rajković, A.,& Ćirkovic Veličković, T.. (2024). Supplementary information for the article:       Mladenovic Stokanic, M.; Simovic, A.; Jovanovic, V.; Radomirovic, M.; Udovicki, B.; Krstic Ristivojevic, M.; Djukic, T.; Vasovic, T.; Acimovic, J.; Sabljic, L.; Lukic, I.; Kovacevic, A.; Cujic, D.; Gnjatovic, M.; Smiljanic, K.; Stojadinovic, M.; Radosavljevic, J.; Stanic-Vucinic, D.; Stojanovic, M.; Rajkovic, A.; Cirkovic Velickovic, T. Sandwich ELISA for the Quantification of Nucleocapsid Protein of SARS-CoV-2 Based on Polyclonal Antibodies from Two Different Species. International Journal of Molecular Sciences 2024, 25 (1), 333. https://doi.org/10.3390/ijms25010333.. in International Journal of Molecular Sciences
MDPI., 25(1).
https://hdl.handle.net/21.15107/rcub_intor_859

Mladenović Stokanić M, Simović A, Jovanović V, Radomirović M, Udovički B, Krstić Ristivojević M, Djukić T, Vasović T, Aćimović J, Sabljić L, Lukić I, Kovačević A, Cujic D, Gnjatović M, Smiljanić K, Stojadinović M, Radosavljević J, Stanić-Vučinić D, Stojanović M, Rajković A, Ćirkovic Veličković T. Supplementary information for the article:       Mladenovic Stokanic, M.; Simovic, A.; Jovanovic, V.; Radomirovic, M.; Udovicki, B.; Krstic Ristivojevic, M.; Djukic, T.; Vasovic, T.; Acimovic, J.; Sabljic, L.; Lukic, I.; Kovacevic, A.; Cujic, D.; Gnjatovic, M.; Smiljanic, K.; Stojadinovic, M.; Radosavljevic, J.; Stanic-Vucinic, D.; Stojanovic, M.; Rajkovic, A.; Cirkovic Velickovic, T. Sandwich ELISA for the Quantification of Nucleocapsid Protein of SARS-CoV-2 Based on Polyclonal Antibodies from Two Different Species. International Journal of Molecular Sciences 2024, 25 (1), 333. https://doi.org/10.3390/ijms25010333.. in International Journal of Molecular Sciences. 2024;25(1).
https://hdl.handle.net/21.15107/rcub_intor_859 .

Mladenović Stokanić, Maja, Simović, Ana, Jovanović, Vesna, Radomirović, Mirjana, Udovički, Božidar, Krstić Ristivojević, Maja, Djukić, Teodora, Vasović, Tamara, Aćimović, Jelena, Sabljić, Ljiljana, Lukić, Ivana, Kovačević, Ana, Cujic, Danica, Gnjatović, Marija, Smiljanić, Katarina, Stojadinović, Marija, Radosavljević, Jelena, Stanić-Vučinić, Dragana, Stojanović, Marijana, Rajković, Andreja, Ćirkovic Veličković, Tanja, "Supplementary information for the article:       Mladenovic Stokanic, M.; Simovic, A.; Jovanovic, V.; Radomirovic, M.; Udovicki, B.; Krstic Ristivojevic, M.; Djukic, T.; Vasovic, T.; Acimovic, J.; Sabljic, L.; Lukic, I.; Kovacevic, A.; Cujic, D.; Gnjatovic, M.; Smiljanic, K.; Stojadinovic, M.; Radosavljevic, J.; Stanic-Vucinic, D.; Stojanovic, M.; Rajkovic, A.; Cirkovic Velickovic, T. Sandwich ELISA for the Quantification of Nucleocapsid Protein of SARS-CoV-2 Based on Polyclonal Antibodies from Two Different Species. International Journal of Molecular Sciences 2024, 25 (1), 333. https://doi.org/10.3390/ijms25010333." in International Journal of Molecular Sciences, 25, no. 1 (2024),
https://hdl.handle.net/21.15107/rcub_intor_859 .

TY  - GEN
AU  - Ćirković-Veličković, Tanja
AU  - Gnjatović, Marija
AU  - Ćujić, Danica
AU  - Todorović, Aleksandra
AU  - Stanić-Vučinić, Dragana
AU  - Đukić, Teodora
AU  - Mladenović, Maja
AU  - Vasović, Tamara
AU  - Stojadinović, Marija
AU  - Krstić-Ristivojević, Maja
AU  - Jovanović, Vesna
AU  - Simović, Ana
AU  - Radosavljević, Jelena
AU  - Aćimović, Jelena M.
AU  - Radomirović, Mirjana Ž.
AU  - Stojanović, Marijana
PY  - 2023
UR  - http://intor.torlakinstitut.com/handle/123456789/860
AB  - Novi korona virus (SARS CoV-2) koji se pojavio u Vuhanu 2019. godine pripada grupi jednolančanih RNK virusa [1]. Predstavlja novi infektivni agens za humanu populaciju i veoma je brzo detektovan u velikom broju zemalja. Uzročnik je respiratornih infekcija koje mogu da budu praćene i veoma teškom kliničkom slikom. Brzo širenje, odsustvo imuniteta na ovaj virus i odsustvo pouzdanih testova za detekciju virusa u trenutku izbijanja pandemije su bolest izazvanu ovim virusom brzo pretvorili u zdravstveni i društveni problem najvišeg prioriteta na globalnom nivou. Iako su najveće biotehnološke kompanije ubrzano počele sa razvojem i masovnom proizvodnjom dijagnostičkih testova i vakcina, njihova dostupnost u trenucima najveće potražnje je i dalje nedovoljna, a cene istih su limitirajući faktor za bolju kontrolu bolesti i širenja pandemije [2]. Razvoj sopstvenih i održiva proizvodnja testova i vakcina za COVID-19 su od velikog društvenog značaja. Važan preduslov za održivu proizvodnju testova je dostupnost rekombinantnih antigena virusa i mogućnost proizvodnje istih na velikoj skali za potrebe proizvodnje domaćih testova. Ovim tehničkim rešenjem se opisuje dobijanje dva ključna antigena novog korona virusa rekombinantnom tehnologijom i njihova primena u serološkom ELISA testu koji proizvodi Institut za primenu nuklearne energije, INEP, kao i za dobijanje reagenasa za detekciju antigena novog korona virusa (specifičnih antitela). U prvoj fazi, optimizovane su sekvence proteina koje su podigle osetljivost postojećih seroloških testova. Inovativnost našeg pristupa se ogleda i u razrađenim eksperimentalnim protokolima za dobijanje rekombinantnih proteina nukleokapsida na velikoj skali, kao i u solubilnoj formi, što olakšava postupak prečišćavanja. Izbor fragmenta nukleokapsida koji se heterologo eksprimira u solubilnoj formi, a specifično detektuje antitela i generiše jak imuni odgovor tokom imunizacije životinja (imunogenost) na osnovu pregleda poznatih epitopskih sekvenci je ključna inovacija ovog tehničkog rešenja. Ovo je prvi primer uspešno primenjenog rekombinatnog proteina proizvedenog u Srbiji u dijagnostičkom testu koji je registrovankod Agencije za lekove i medicinska sredstva Republike Srbije (broj rešenja 515-02-02370-21-002), a koji je primenu našao i na međunarodnom nivou.
T1  - Dobijanje rekombinantnog imunogenog fragmenta proteina nukleokapsida SARS-CoV-2 virusa za proizvodnju reagenasa i dijagnostičkih testova na novi korona virus
UR  - https://hdl.handle.net/21.15107/rcub_intor_860
ER  - 

@misc{
author = "Ćirković-Veličković, Tanja and Gnjatović, Marija and Ćujić, Danica and Todorović, Aleksandra and Stanić-Vučinić, Dragana and Đukić, Teodora and Mladenović, Maja and Vasović, Tamara and Stojadinović, Marija and Krstić-Ristivojević, Maja and Jovanović, Vesna and Simović, Ana and Radosavljević, Jelena and Aćimović, Jelena M. and Radomirović, Mirjana Ž. and Stojanović, Marijana",
year = "2023",
abstract = "Novi korona virus (SARS CoV-2) koji se pojavio u Vuhanu 2019. godine pripada grupi jednolančanih RNK virusa [1]. Predstavlja novi infektivni agens za humanu populaciju i veoma je brzo detektovan u velikom broju zemalja. Uzročnik je respiratornih infekcija koje mogu da budu praćene i veoma teškom kliničkom slikom. Brzo širenje, odsustvo imuniteta na ovaj virus i odsustvo pouzdanih testova za detekciju virusa u trenutku izbijanja pandemije su bolest izazvanu ovim virusom brzo pretvorili u zdravstveni i društveni problem najvišeg prioriteta na globalnom nivou. Iako su najveće biotehnološke kompanije ubrzano počele sa razvojem i masovnom proizvodnjom dijagnostičkih testova i vakcina, njihova dostupnost u trenucima najveće potražnje je i dalje nedovoljna, a cene istih su limitirajući faktor za bolju kontrolu bolesti i širenja pandemije [2]. Razvoj sopstvenih i održiva proizvodnja testova i vakcina za COVID-19 su od velikog društvenog značaja. Važan preduslov za održivu proizvodnju testova je dostupnost rekombinantnih antigena virusa i mogućnost proizvodnje istih na velikoj skali za potrebe proizvodnje domaćih testova. Ovim tehničkim rešenjem se opisuje dobijanje dva ključna antigena novog korona virusa rekombinantnom tehnologijom i njihova primena u serološkom ELISA testu koji proizvodi Institut za primenu nuklearne energije, INEP, kao i za dobijanje reagenasa za detekciju antigena novog korona virusa (specifičnih antitela). U prvoj fazi, optimizovane su sekvence proteina koje su podigle osetljivost postojećih seroloških testova. Inovativnost našeg pristupa se ogleda i u razrađenim eksperimentalnim protokolima za dobijanje rekombinantnih proteina nukleokapsida na velikoj skali, kao i u solubilnoj formi, što olakšava postupak prečišćavanja. Izbor fragmenta nukleokapsida koji se heterologo eksprimira u solubilnoj formi, a specifično detektuje antitela i generiše jak imuni odgovor tokom imunizacije životinja (imunogenost) na osnovu pregleda poznatih epitopskih sekvenci je ključna inovacija ovog tehničkog rešenja. Ovo je prvi primer uspešno primenjenog rekombinatnog proteina proizvedenog u Srbiji u dijagnostičkom testu koji je registrovankod Agencije za lekove i medicinska sredstva Republike Srbije (broj rešenja 515-02-02370-21-002), a koji je primenu našao i na međunarodnom nivou.",
title = "Dobijanje rekombinantnog imunogenog fragmenta proteina nukleokapsida SARS-CoV-2 virusa za proizvodnju reagenasa i dijagnostičkih testova na novi korona virus",
url = "https://hdl.handle.net/21.15107/rcub_intor_860"
}

Ćirković-Veličković, T., Gnjatović, M., Ćujić, D., Todorović, A., Stanić-Vučinić, D., Đukić, T., Mladenović, M., Vasović, T., Stojadinović, M., Krstić-Ristivojević, M., Jovanović, V., Simović, A., Radosavljević, J., Aćimović, J. M., Radomirović, M. Ž.,& Stojanović, M.. (2023). Dobijanje rekombinantnog imunogenog fragmenta proteina nukleokapsida SARS-CoV-2 virusa za proizvodnju reagenasa i dijagnostičkih testova na novi korona virus. .
https://hdl.handle.net/21.15107/rcub_intor_860

Ćirković-Veličković T, Gnjatović M, Ćujić D, Todorović A, Stanić-Vučinić D, Đukić T, Mladenović M, Vasović T, Stojadinović M, Krstić-Ristivojević M, Jovanović V, Simović A, Radosavljević J, Aćimović JM, Radomirović MŽ, Stojanović M. Dobijanje rekombinantnog imunogenog fragmenta proteina nukleokapsida SARS-CoV-2 virusa za proizvodnju reagenasa i dijagnostičkih testova na novi korona virus. 2023;.
https://hdl.handle.net/21.15107/rcub_intor_860 .

Ćirković-Veličković, Tanja, Gnjatović, Marija, Ćujić, Danica, Todorović, Aleksandra, Stanić-Vučinić, Dragana, Đukić, Teodora, Mladenović, Maja, Vasović, Tamara, Stojadinović, Marija, Krstić-Ristivojević, Maja, Jovanović, Vesna, Simović, Ana, Radosavljević, Jelena, Aćimović, Jelena M., Radomirović, Mirjana Ž., Stojanović, Marijana, "Dobijanje rekombinantnog imunogenog fragmenta proteina nukleokapsida SARS-CoV-2 virusa za proizvodnju reagenasa i dijagnostičkih testova na novi korona virus" (2023),
https://hdl.handle.net/21.15107/rcub_intor_860 .

TY  - CONF
AU  - Smiljanić, Katarina
AU  - Prodić, Ivana
AU  - Đukić, Teodora
AU  - Vasović, Tamara
AU  - Jovanović, Vesna B.
AU  - Ćirković-Veličković, Tanja
PY  - 2021
UR  - http://intor.torlakinstitut.com/handle/123456789/780
C3  - Proteomics and Metabolomics for Personalized Medicine, XV Italian Proteomics Association Annual Meeting, Catholic University of the Sacred Heart, Roma, Italy, 8th-10th September 2021
T1  - Effects of lysin's and arginige's modifications on trypsin proteolytic efficacy imposed before and after the peanut roasting
EP  - 71
SP  - 71
UR  - https://hdl.handle.net/21.15107/rcub_intor_780
ER  - 

@conference{
author = "Smiljanić, Katarina and Prodić, Ivana and Đukić, Teodora and Vasović, Tamara and Jovanović, Vesna B. and Ćirković-Veličković, Tanja",
year = "2021",
journal = "Proteomics and Metabolomics for Personalized Medicine, XV Italian Proteomics Association Annual Meeting, Catholic University of the Sacred Heart, Roma, Italy, 8th-10th September 2021",
title = "Effects of lysin's and arginige's modifications on trypsin proteolytic efficacy imposed before and after the peanut roasting",
pages = "71-71",
url = "https://hdl.handle.net/21.15107/rcub_intor_780"
}

Smiljanić, K., Prodić, I., Đukić, T., Vasović, T., Jovanović, V. B.,& Ćirković-Veličković, T.. (2021). Effects of lysin's and arginige's modifications on trypsin proteolytic efficacy imposed before and after the peanut roasting. in Proteomics and Metabolomics for Personalized Medicine, XV Italian Proteomics Association Annual Meeting, Catholic University of the Sacred Heart, Roma, Italy, 8th-10th September 2021, 71-71.
https://hdl.handle.net/21.15107/rcub_intor_780

Smiljanić K, Prodić I, Đukić T, Vasović T, Jovanović VB, Ćirković-Veličković T. Effects of lysin's and arginige's modifications on trypsin proteolytic efficacy imposed before and after the peanut roasting. in Proteomics and Metabolomics for Personalized Medicine, XV Italian Proteomics Association Annual Meeting, Catholic University of the Sacred Heart, Roma, Italy, 8th-10th September 2021. 2021;:71-71.
https://hdl.handle.net/21.15107/rcub_intor_780 .

Smiljanić, Katarina, Prodić, Ivana, Đukić, Teodora, Vasović, Tamara, Jovanović, Vesna B., Ćirković-Veličković, Tanja, "Effects of lysin's and arginige's modifications on trypsin proteolytic efficacy imposed before and after the peanut roasting" in Proteomics and Metabolomics for Personalized Medicine, XV Italian Proteomics Association Annual Meeting, Catholic University of the Sacred Heart, Roma, Italy, 8th-10th September 2021 (2021):71-71,
https://hdl.handle.net/21.15107/rcub_intor_780 .

TY  - CHAP
AU  - Smiljanić, Katarina
AU  - Mihailović, Jelena
AU  - Prodić, Ivana
AU  - Đukić, Teodora
AU  - Vasović, Tamara
AU  - Jovanović, Vesna B.
AU  - Ćirković-Veličković, Tanja
PY  - 2020
UR  - http://intor.torlakinstitut.com/handle/123456789/764
AB  - Post-translational modifications (PTMs) occur in many forms and shapes, widely influencing protein behavior. High-resolution tandem mass spectrometry (HRMS/MS), coupled with dedicated engines for the identification of unspecified PTMs, is a powerful method for their mapping. A majority of proteomic experiments utilize trypsin for digestion, which cleaves the C-terminal peptide bonds of arginine (Arg) and lysine (Lys) amino acids with high catalytic efficiency and selectivity, unless they are followed with proline. At the same time, Arg and Lys residues are frequently modified during food processing by heat and non-thermal treatments, causing oxidation, carbamylation, and various forms of side chain carbonylation, including the other common PTMs (methylation, acetylation, etc.). Consequently, we explored the possibility to re-assess already generated proteomic data (food protein/allergen tryptic peptides) with respect to the possible modulation of the tryptic intestinal digestion pattern caused by PTMs incorporated at Arg and Lys residues. However, most of the proteomic bottom-up experiments are run with porcine trypsin that has been reductively methylated to increase its stability and minimize autoproteolytic effects. Therefore, in this chapter, the utility of the aforementioned idea was explored, by reviewing the differences in structure, affinity, specificity, and catalytic efficiency of trypsin, primarily from porcine, bovine and human species. Porcine trypsin either from pancreas or in recombinant form showed superior performance compared to human and bovine tryptic counterparts. In addition, set of software tools for identification and analyses of PTMs was reviewed with the aim to isolate those capable of in-depth PTMs profiling and their simultaneous relative quantification, such as PEAKS PTM (PEAKS Studio, Bioinformatics Solution Inc., Ontario Canada). Based on our preliminary experimental results, conclusion is that the proposed idea is plausible, because if potential hindrance effects caused by PTMs are observed with porcine trypsin, then they can be just augmented within human intestinal digestion, with respect to inferior performance of human trypsin.
PB  - New York : Nova Science Publisher
T2  - A Closer Look at Proteolysis: Biochemistry and Molecular Biology in the Post Genomic Era
T1  - Trypsin as a Proteomic Probe for Assessment of Food Protein Digestibility in Relation to Chemical and Post-translational Modifications
SP  - 158
VL  - 4
UR  - https://hdl.handle.net/21.15107/rcub_intor_764
ER  - 

@inbook{
author = "Smiljanić, Katarina and Mihailović, Jelena and Prodić, Ivana and Đukić, Teodora and Vasović, Tamara and Jovanović, Vesna B. and Ćirković-Veličković, Tanja",
year = "2020",
abstract = "Post-translational modifications (PTMs) occur in many forms and shapes, widely influencing protein behavior. High-resolution tandem mass spectrometry (HRMS/MS), coupled with dedicated engines for the identification of unspecified PTMs, is a powerful method for their mapping. A majority of proteomic experiments utilize trypsin for digestion, which cleaves the C-terminal peptide bonds of arginine (Arg) and lysine (Lys) amino acids with high catalytic efficiency and selectivity, unless they are followed with proline. At the same time, Arg and Lys residues are frequently modified during food processing by heat and non-thermal treatments, causing oxidation, carbamylation, and various forms of side chain carbonylation, including the other common PTMs (methylation, acetylation, etc.). Consequently, we explored the possibility to re-assess already generated proteomic data (food protein/allergen tryptic peptides) with respect to the possible modulation of the tryptic intestinal digestion pattern caused by PTMs incorporated at Arg and Lys residues. However, most of the proteomic bottom-up experiments are run with porcine trypsin that has been reductively methylated to increase its stability and minimize autoproteolytic effects. Therefore, in this chapter, the utility of the aforementioned idea was explored, by reviewing the differences in structure, affinity, specificity, and catalytic efficiency of trypsin, primarily from porcine, bovine and human species. Porcine trypsin either from pancreas or in recombinant form showed superior performance compared to human and bovine tryptic counterparts. In addition, set of software tools for identification and analyses of PTMs was reviewed with the aim to isolate those capable of in-depth PTMs profiling and their simultaneous relative quantification, such as PEAKS PTM (PEAKS Studio, Bioinformatics Solution Inc., Ontario Canada). Based on our preliminary experimental results, conclusion is that the proposed idea is plausible, because if potential hindrance effects caused by PTMs are observed with porcine trypsin, then they can be just augmented within human intestinal digestion, with respect to inferior performance of human trypsin.",
publisher = "New York : Nova Science Publisher",
journal = "A Closer Look at Proteolysis: Biochemistry and Molecular Biology in the Post Genomic Era",
booktitle = "Trypsin as a Proteomic Probe for Assessment of Food Protein Digestibility in Relation to Chemical and Post-translational Modifications",
pages = "158",
volume = "4",
url = "https://hdl.handle.net/21.15107/rcub_intor_764"
}

Smiljanić, K., Mihailović, J., Prodić, I., Đukić, T., Vasović, T., Jovanović, V. B.,& Ćirković-Veličković, T.. (2020). Trypsin as a Proteomic Probe for Assessment of Food Protein Digestibility in Relation to Chemical and Post-translational Modifications. in A Closer Look at Proteolysis: Biochemistry and Molecular Biology in the Post Genomic Era
New York : Nova Science Publisher., 4, 158.
https://hdl.handle.net/21.15107/rcub_intor_764

Smiljanić K, Mihailović J, Prodić I, Đukić T, Vasović T, Jovanović VB, Ćirković-Veličković T. Trypsin as a Proteomic Probe for Assessment of Food Protein Digestibility in Relation to Chemical and Post-translational Modifications. in A Closer Look at Proteolysis: Biochemistry and Molecular Biology in the Post Genomic Era. 2020;4:158.
https://hdl.handle.net/21.15107/rcub_intor_764 .

Smiljanić, Katarina, Mihailović, Jelena, Prodić, Ivana, Đukić, Teodora, Vasović, Tamara, Jovanović, Vesna B., Ćirković-Veličković, Tanja, "Trypsin as a Proteomic Probe for Assessment of Food Protein Digestibility in Relation to Chemical and Post-translational Modifications" in A Closer Look at Proteolysis: Biochemistry and Molecular Biology in the Post Genomic Era, 4 (2020):158,
https://hdl.handle.net/21.15107/rcub_intor_764 .