Maryam Asadi; Razie Kiani; Vahid Razban; Seyed Nooreddin Faraji; Amirhossein Ahmadi; Jafar Fallahi; Amin Ramezani; Nasrollah Erfani
Abstract
Background: CD38 is highly expressed on multiple myeloma (MM) cells and has been successfully targeted by different target therapy methods. This molecule is a critical prognostic marker in both diffuse large B-cell lymphoma and chronic lymphocytic leukemia.Objective: We have designed and generated an ...
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Background: CD38 is highly expressed on multiple myeloma (MM) cells and has been successfully targeted by different target therapy methods. This molecule is a critical prognostic marker in both diffuse large B-cell lymphoma and chronic lymphocytic leukemia.Objective: We have designed and generated an anti-CD38 CAR-NK cell applying NK 92 cell line. The approach has potential application as an off-the-shelf strategy for treatment of CD38 positive malignancies.Methods: A second generation of anti-CD38 CAR-NK cell was designed and generated, and their efficacy against CD38-positive cell lines was assessed in vitro. The PE-Annexin V and 7-AAD methods were used to determine the percentage of apoptotic target cells. Flow cytometry was used to measure IFN-γ, Perforin, and Granzyme-B production following intracellular staining. Using in silico analyses, the binding capacity and interaction interface were evaluated.Results: Using Lentivirus, cells were transduced with anti-CD38 construct and were expanded. The expression of anti-CD38 CAR on the surface of NK 92 cells was approximately 25%. As we expected from in silico analysis, our designed CD38-chimeric antigen receptor was bound appropriately to the CD38 protein. NK 92 cells that transduced with the CD38 chimeric antigen receptor, generated significantly more IFN-γ, perforin, and granzyme than Mock cells, and successfully lysed Daudi and Jurkat malignant cells in a CD38-dependent manner.Conclusion: The in vitro findings indicated that the anti-CD38 CAR-NK cells have the potential to be used as an off-the-shelf therapeutic strategy against CD38-positive malignancies. It is recommended that the present engineered NK cells undergo additional preclinical investigations before they can be considered for subsequent clinical trial studies.
Mohsen Mazloomrezaei; Mahsa Sadat Hosseini; Nahid Ahmadi; Elham Mahmoudi Maymand; Ebrahim Eftekhar; Amir Asgari; Amin Ramezani
Abstract
Background: It is advantageous to develop an effective purification procedure to produce recombinant protein drugs (rPDs) without any tags. To remove N- or C-terminus tags from the rPDs, several cleavage site-based endopeptidases were used. Separating the endopeptidase enzyme from the rPDs is a time-consuming ...
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Background: It is advantageous to develop an effective purification procedure to produce recombinant protein drugs (rPDs) without any tags. To remove N- or C-terminus tags from the rPDs, several cleavage site-based endopeptidases were used. Separating the endopeptidase enzyme from the rPDs is a time-consuming and costly process. Objective: To design and develop a new method for the purification of human interleukin (IL)-4 with potential application for other cytokines. Methods: Met-like amino acids were substituted at position 120 to reduce the possibility of alteration in the structure of IL-4 and its biological activity. Based on the in silico analysis, isoleucine was chosen as an alternative amino acid, and the M120I mutant IL-4 (mIL-4) model was selected for the downstream analysis. Recombinant mIL-4 was produced in the E.coli BL21 host and purified with CNBr. Then in vitro evaluations of the native and mutant IL-4 were performed. Results: The results showed that both the native and mutant IL-4 had the same effect on TF-1 cell proliferation. On the other hand, there was no significant difference between the effects of native IL-4 (nIL-4) and mIL-4 on the expression of IL-4 and IL-10 in activated peripheral blood mononuclear cells. Native and mutant IL-4 have similar biological activities. Conclusion: Here, an efficient and straightforward system is introduced to purify IL-4 cytokine using CNBr, which could be applied to other rPDs.
