Adoptive Immunotherapy Research Articles

Nuclear receptor corepressor 1 controls regulatory T cell subset differentiation and effector function.

FOXP3+ regulatory T cells (Treg cells) are key for immune homeostasis. Here, we reveal that nuclear receptor corepressor 1 (NCOR1) controls naïve and effector Treg cell states. Upon NCOR1 deletion in T cells, effector Treg cell frequencies were elevated in mice and in in vitro-generated human Treg cells. NCOR1-deficient Treg cells failed to protect mice from severe weight loss and intestinal inflammation associated with CD4+ T cell transfer colitis, indicating impaired suppressive function. NCOR1 controls the transcriptional integrity of Treg cells, since effector gene signatures were already upregulated in naïve NCOR1-deficient Treg cells while effector NCOR1-deficient Treg cells failed to repress genes associated with naïve Treg cells. Moreover, genes related to cholesterol homeostasis including targets of liver X receptor (LXR) were dysregulated in NCOR1-deficient Treg cells. However, genetic ablation of LXRβ in T cells did not revert the effects of NCOR1 deficiency, indicating that NCOR1 controls naïve and effector Treg cell subset composition independent from its ability to repress LXRβ-induced gene expression. Thus, our study reveals that NCOR1 maintains naïve and effector Treg cell states via regulating their transcriptional integrity. We also reveal a critical role for this epigenetic regulator in supporting the suppressive functions of Treg cells in vivo.

Cellular therapy for traumatic brain injury in adults: a meta-analysis of controlled clinical trials

IntroductionTraumatic brain injury (TBI) has got no effective treatment. Cellular therapy is the transfer of autologous or allogeneic cells or cellular material into patient(s) for treatment, showed better outcomes in TBI in several clinical and preclinical studies. We performed a meta-analysis on published articles on the topic of cellular therapy for the treatment of TBI in adult patients.Material and MethodsThe literature search was done via selected database with no restrictions on publication year. Studies were included based on selection criteria and quality assessment. The following data were extracted from included articles; author names, publication year and place, type of study, number, sex and age of participants, type of cells used, and post-treatment follow up. The required data related to Fugl-Meyer Motor Scale (FMMS), Disability Rating Scale (DRS) and patients. Overall improvement was pooled and analyzed using RevMan (Ver.5.4.1).ResultsFive studies that met the selection criteria and considered as high quality, containing 367 participants, with an average follow up time of (7.58±6.93) months, were included in meta-analysis. The results showed that cellular therapy significantly improves (OR=0.26; 95% CI=0.15 to 0.48; P=0.0001) the overall performance of the patients. Moreover, the improvements in FMMS (MD=3.79; 95% CI= -2.53 to 10.10; P=0.24) and DRS (MD= -0.16; 95% CI= -1.51 to 1.19; P=0.82) were not statically significant, but they are obviously clinically significant.ConclusionsThis meta-analysis suggests that cellular therapy improves the condition of TBI patients in clinic. Larger, multi-central trials are required to further confirm and detail the use of stem cells in TBI.

Proteogenomic characterization of highly enriched viable leukemic blasts in acute myeloid leukemia: A SWOG report

AbstractIntroductionAcute myeloid leukemia (AML) remains one of the deadliest hematopoietic malignancies. A better understanding of the molecular biology governing AML may lead to improved risk stratification and facilitate the development of novel therapies. Proteins are responsible for much of the biology of cells. Several studies have examined the global proteome in bulk mononuclear cells (MNCs) from AML specimens, which are comprised a heterogenous population of cells at various stages of differentiation.MethodsGiven the potential impact of the nonleukemic cells on protein expression profiles, we applied an integrative proteogenomic approach utilizing next‐generation sequencing and mass spectrometry‐based proteomics to identify novel protein biomarkers in unsorted MNCs and viable leukemic blasts (VLBs) isolated from blood and bone marrow specimens obtained at the time of AML diagnosis.ResultsWe identified significant differences in protein expression between VLBs and MNCs. Subsequent studies (N = 27) focused on proteomic profiling of VLBs that identified novel candidate biomarkers associated with mutational genotypes and clinical outcome, some of which were recapitulated in an independent cohort of patients. Using mass spectrometry, we also detected mutated protein products, some of which were predicted via in silico analyses to be potential neoantigens amenable to adoptive immunotherapy. As previously described, analyses comparing transcript and protein expression showed an overall modest correlation between mRNA and protein dataset, but enriching for genes associated with mutations significantly improved the protein–RNA correlation.ConclusionTogether, the results provide insight into the biology of VLBs and demonstrate the gains derived from examining the proteome in addition to genome and transcriptome.

Integrated Imaging Probe and Bispecific Antibody Development Enables In Vivo Targeting of Glypican-3–Expressing Hepatocellular Carcinoma

Abstract Glypican-3 (GPC3) is a proteoglycan with high sensitivity and specificity for hepatocellular carcinoma (HCC). We describe the integrated development and validation of a GPC3-targeting optical imaging probe and T cell–redirecting antibody (TRAB) as a theranostic strategy for the detection and treatment of HCC. A novel TRAB targeting GPC3 on HCC tumor cells and the CD3 T-cell receptor as well as a distinct GPC3-specific optical imaging probe were developed from a short peptide. The efficacy of GPC3/CD3 TRAB was evaluated in vitro using IFNγ release and calcein-AM assays. Patient-derived xenografts were used to assess the in vivo efficacy of GPC3/CD3 TRAB and the GPC3 imaging probe for the detection of GPC3+ HCC. GPC3/CD3 TRAB caused a dose-dependent escalation in IFNγ release from inactive peripheral blood T cells (P = 0.001) and higher tumor-cell lysis (P = 0.01) compared with controls in vitro. Intratumorally injected GPC3/CD3 TRAB resulted in significant prolongation of tumor doubling time in the GPC3+ tumors, with an associated reduction of tumor fluorescent signal from the HiLyte 488–conjugated GPC3-specific peptide on optical imaging. These data demonstrate that HCC cell targeting using a GPC3/CD3 TRAB derived from a small peptide enabled effective T-cell activation and induction of a cytotoxic response toward GPC3+ HCC tumor cells both in vitro and in vivo. GPC3-specific optical imaging enabled the detection of the GPC3+ HCC cells and noninvasive monitoring of tumor response to adoptive immunotherapy. The integrated development of a targeted therapeutic and molecular imaging probe provides a promising paradigm for the development of cancer theranostics.

Star-Shaped Molecules with a Triazine Core: (TD)DFT Investigation of Charge Transfer and Photovoltaic Properties of Organic Solar Cells

Star-Shaped Molecules with a Triazine Core: (TD)DFT Investigation of Charge Transfer and Photovoltaic Properties of Organic Solar Cells

Abstract A030: CD4 neoantigen mRNA vaccine enhances endogenous CD8 responses and tumor control

Abstract CD4 T cells have long been known to be critical for priming CD8 T cells, a process referred to as CD4 T cell help. Recent data have suggested that CD4 help may be delivered at the surface of conventional type 1 dendritic cells (cDC1s), which can efficiently present antigens (Ag) on both MHC class I and class II molecules. However, the actual mechanisms underlying CD4 T cell help remain poorly characterized. We sought to understand how anti-tumor T cell responses are generated in the context of mRNA vaccines, which have been shown to elicit protective CD4 and/or CD8 T cells. For this purpose, we compared two mRNA-Lipoplex (mRNA-LPX) vaccines that express a single MHC-II-restricted Ag either tumor-specific (neoAg) or tumor-irrelevant. mRNA-LPX is injected intravenously and taken up predominantly by cDCs in the spleen.As expected, both vaccines elicited systemic CD4 T cell responses. However, only the anti-tumor CD4 T cell response elicited the accumulation of tumor-infiltrating CD8 lymphocytes (CD8 TILs) that led to tumor regression in a CD8-dependant manner. Single cell RNA-sequencing revealed higher expression of effector molecules and genes associated with stem-like progenitor T cell states in CD8 TILs following neoAg vaccine. In contrast, inhibitory molecules were down-regulated in CD8 TILs from neoAg-vaccinated mice.We next characterized the role of cDCs in the response to the vaccines. We found that both mRNA-LPX vaccines induced better maturation of cDC1s than cDC2s in the spleen. Surprisingly, priming of CD4 T cells was dependent on cDC1s, rather than cDC2s. cDC1s were also required for neoAg CD4 vaccine-induced CD8 TIL accumulation and for vaccine efficacy. We investigated whether neoAg-specific CD4 T cells were i) sufficient to enhance anti-tumor CD8 responses and ii) needed to maintain effector CD8 TIL activity in situ. Using adoptive cell transfer (ACT) into the tumor, we found that the transfer of neoAg-specific CD4 T cells alone significantly delayed tumor growth, suggesting an increased CD8 TIL activity. Interestingly, while the transfer of CD8 TILs alone was insufficient to control tumors; ACT of both CD4 and CD8 T cells was required for efficient tumor rejection. cDC1s were required for the efficacy of both, the ACT of CD4 T cells alone and the CD4 and CD8 ACT combination. Taken together, our data suggest a novel mechanism whereby immunizing with exogenous CD4 T cell epitopes can produce tumor immunity by generating endogenous CD8 responses. These results emphasize the importance of cDC1s for both, eliciting tumor-specific CD4 T cells in the setting of mRNA-LPX vaccine expressing a single MHC-II-restricted Ag and improving in situ anti-tumor CD8 responses and tumor control. We are currently investigating the mechanisms and location of the MHC-II-restricted neoAg dependent-cDC1 help using both in vivo and cell culture approaches.This model provides fundamental insight for the development of cancer vaccines and highlights the need of tumor-specific CD4 T cells and mature tumor-Ag loaded cDC1s. Citation Format: Camille-Charlotte Balanca, Aude-Hélène Capietto, Catherine Carbone, Alan Gutierrez, Yajun Chestnut, Ellen Duong, Aditya Anand, Anthony Antonelli, Jeanne Cheung, Shiuh Luoh, Ariane Nissembaum, Keiko Hokeness, Sara Wichner, Emily Freund, Vincent Javinal, Romain Bouziat, Joshua Gober, Adel ElSohly, Jon Linehan, Ugur Sahin, Lélia Delamarre, Ira Mellman. CD4 neoantigen mRNA vaccine enhances endogenous CD8 responses and tumor control [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Tumor Immunology and Immunotherapy; 2024 Oct 18-21; Boston, MA. Philadelphia (PA): AACR; Cancer Immunol Res 2024;12(10 Suppl):Abstract nr A030.

MerTK Signaling in Human Primary T cells Modulates Memory Potential and Improves Recall response.

Immune therapy using checkpoint inhibitors or adoptive cell transfer has revolutionized the treatment of several types of cancers. However, response to treatment is currently limited to a fraction of patients. Elucidation of immune modulatory mechanisms might optimize patient selection and present ways to modify anti-cancer immune responses. We recently discovered the expression and an important costimulatory role of TAM receptor MerTK signaling on activated human primary CD8+ T cells. Here we extend our study of the costimulatory role of MerTK expression in human CD8+ T cells. We uncover a clear link between MerTK expression and less differentiated Central Memory T cells based on an increased expression of CCR7, CD45RO, CD28, CD62L, and an altered metabolic profile. In addition, we observe an improved proliferative capacity and elevated expression of effector molecule IFNγ upon recall responses of MerTK-expressing cells in vitro. Finally, using gp100TCR-transduced T cells, we demonstrate how PROS1 treatment results in improved cytotoxicity and killing of tumors. Our findings describe a role of MerTK expression in T cells, which could be exploited in the search for improving immunotherapeutic approaches.

TIL Therapy in Lung Cancer: Current Progress and Perspectives.

Lung cancer remains the most prevalent malignant tumor worldwide and is the leading cause of cancer-related mortality. Although immune checkpoint blockade has revolutionized the treatment of advanced lung cancer, many patients still do not respond well, often due to the lack of functional T cell infiltration. Adoptive cell therapy (ACT) using expanded immune cells has emerged as an important therapeutic modality. Tumor-infiltrating lymphocytes (TIL) therapy is one form of ACT involving the administration of expanded and activated autologous T cells derived from surgically resected cancer tissues and reinfusion into patients and holds great therapeutic potential for lung cancer. In this review, TIL therapy is introduced and its suitability for lung cancer is discussed. Then its historical and clinical developments are summarized, and the methods developed up-to-date to identify tumor-recognizing TILs and optimize TIL composition. Some perspectives toward future TIL therapy for lung cancer are also provided.

Acetylcysteine synergizes PD-1 blockers against colorectal cancer progression by promoting TCF1+PD1+CD8+ T cell differentiation

BackgroundProgrammed cell death protein 1 (PD-1) blockade is essential in treating progressive colorectal cancer (CRC). However, some patients with CRC do not respond well to immunotherapy, possibly due to the exhaustion of CD8+ T cells in the tumor microenvironment. N-Acetylcysteine (NAC) can reduce CD8+ T cell exhaustion in vitro and induce their differentiation into long-lasting phenotypes, thus enhancing the anti-tumor effect of adoptive T cell transfer. However, whether NAC can be combined with PD-1 blockade in CRC treatment and how NAC regulates CD8+ T cell differentiation remain unclear. Hence, in this study, we aimed to investigate whether NAC has a synergistic effect with PD-1 blockers against CRC progression.MethodsWe constructed a mouse CRC model to study the effect of NAC on tumors. The effect of NAC on CD8 + T cell differentiation and its potential mechanism were explored using cell flow assay and other studies in vitro and ex vivo.ResultsWe demonstrated that NAC synergized PD-1 antibodies to inhibit CRC progression in a mouse CRC model mediated by CD8+ T cells. We further found that NAC can induce TCF1+PD1+CD8+ T cell differentiation and reduce the formation of exhausted T cells in vitro and in vivo. Moreover, NAC enhanced the expression of Glut4 in CD8+ T cells, promoting the differentiation of TCF1+PD1+CD8+ T cells.ConclusionsOur study provides a novel idea for immunotherapy for clinically progressive CRC and suggests that Glut4 may be a new immunometabolic molecular target for regulating CD8+ T cell differentiation.Graphical

Xenotransplantation ethical and legal challenges

This work examines xenotransplantation, a rising medical practice that seeks to mitigate the shortage of organs for transplantation. Xenotransplantation essentially involves the transfer of organs, tissues, or cells from animals to humans and represents a promising medical solution. The research will focus on the potential benefits of this technique, highlighting its crucial role in saving lives and improving the quality of life for future patients The analysis will cover aspects of xenotransplantation in Brazil and the experiences of xenotransplantations already conducted worldwide, aiming to understand the scope of the problems and challenges faced by patients and healthcare professionals. The study will seek to understand various perspectives on xenotransplantation, considering the views of different authorities and experts in the field. Finally, it will examine the demand for transplants in Brazil and address issues related to public policies, legislative aspects, and resolutions of competent bodies, to comprehend how xenotransplantation practice is regulated in Brazil.

Potential Therapeutic Targets for the Treatment of HPV-Associated Malignancies

This review article aims to summarize broadly recent developments in the treatment of HPV-associated cancers, including cervical cancer and head and neck squamous cell carcinoma. Relatively new treatments targeting the key HPV E6 and E7 oncoproteins, including gene editing with TALENs and CRISPR/Cas9, are discussed. Given the increased immunogenicity of HPV-related diseases, other therapies such as PRR agonists, adoptive cell transfer, and tumor vaccines are reaching the clinical trial phase. Due to the mechanism, immunogenicity, and reversibility of HPV carcinogenesis, HPV-related cancers present unique targets for current and future therapies.

Light-Controlled Bioorthogonal Chemistry Altered Natural Killer Cell Activity for Boosted Adoptive Immunotherapy.

Natural killer (NK) cell-based immunotherapy has received much attention in recent years. However, its practical application is still suffering from the decreased function and inadequate infiltration of NK cells in the immunosuppressive microenvironment of solid tumors. Herein, we construct light-responsive porphyrin Fe array-armed NK cells (denoted as NK@p-Fe) for cell behavior modulation via bioorthogonal catalysis. By installing cholesterol-modified porphyrin Fe molecules on the NK cell surface, a catalytic array with light-harvesting capabilities is formed. This functionality transforms NK cells into cellular factories capable of catalyzing the production of active agents in a light-controlled manner. NK@p-Fe can generate the active antineoplastic drug doxorubicin through bioorthogonal reactions to enhance the cytotoxic function of NK cells. Beyond drug synthesis, NK@p-Fe can also bioorthogonally catalyze the production of the FDA-approved immune agonist imiquimod (IMQ). The activated immune agonist plays a dual role, inducing dendritic cell maturation for NK cell activation and reshaping the tumor immunosuppressive microenvironment for NK cell infiltration. This work represents a paradigm for the modulation of adoptive cell behaviors to boost cancer immunotherapy by bioorthogonal catalysis.

Current development and trends of cancer immunotherapy

Normally, Tumor cells are able to evade the body's immune system and stifle it using a variety of tactics, which enables them to endure through every phase of the immunological reaction against the tumor. This is because the immune system is capable of identifying and eliminating tumor cells within the tumor microenvironment. This article describes current and future trends in cancer treatment and cancer immunotherapy, as well as the specific processes that occur in the cancer immune cycle. A class of disorders known as cancer is distinguished by aberrant cell division and invasion potential. Cancer immunotherapy has shown immense potential and possibilities in recent years, and its research has grown increasingly focused due to advancements in science and technology. The host organism's immune system generates anticancer defences during tumour development through various progressive and combinatorial mechanisms hence the term cancer-immunity cycle. The aim of this article is to describe the basic process of the cancer immune cycle as well as the various immunotherapies that are commonly used in the clinical setting today, as well as trends and future prospects. This review discusses adoptive cell transfer, cytokine therapy, cancer vaccinations, oncolytic viral treatments, and immune checkpoint inhibitors.

Use of Specific T Lymphocytes in Treating Cytomegalovirus Infection in Hematopoietic Cell Transplant Recipients: A Systematic Review

Cytomegalovirus (CMV) poses a significant threat to post-hematopoietic cell transplantation (HCT). Control strategies include letermovir prophylaxis or ganciclovir pre-emptive therapy (PET). Without prophylaxis, 65–90% of seropositive recipients develop a clinically significant CMV infection. Due to PET drawbacks, letermovir prophylaxis is preferable, as it reduces CMV-related events and improves overall survival. However, refractory or resistant CMV-CS remains a challenge, with maribavir showing limited efficacy. This systematic review followed the Cochrane Manual and PRISMA guidelines and was registered in PROSPERO. Searches were conducted in PubMed, Scopus, Embase, and Web of Science. Out of 1895 identified records, 614 duplicates were removed, and subsequent screening excluded 1153 studies. Eleven included studies (2012–2024) involved 255 HCT recipients receiving adoptive immunotherapy (AI), primarily CMV-specific T-cell therapy. GvHD occurred in 1.82% of cases. Adverse events occurred in 4.4% of cases, while mild CRS was observed in 1.3% of patients. Efficacy, evaluated in 299 patients across eleven studies, showed an average response rate of 78.2%. CMV-CS recurrence was observed in 24.4% of 213 patients, and death due to CMV was reported in 9.7% of 307 patients across nine studies. Adoptive hCMV-specific T-cell immunotherapy appears to be a safe, effective alternative for refractory CMV-CS in HCT.

Functional outcome and histologic analysis of late onset total type brachial plexus injury treated with intercostal nerve transfer to median nerve with local umbilical cord-derived mesenchymal stem cells or secretome injection: a double-blinded, randomized control study.

Intercostal nerve transfer is a surgical technique used to restore function in patients with total brachial plexus injury. Stem cell and secretome therapy has been explored as a potential treatment for brachial plexus injuries. This study aimed to compare the functional and histologic outcome of intercostal nerve transfer to median nerve with local stem cells or secretome injection in total type brachial plexus injuries. This was a double-blinded, randomized controlled study (RCT). We included patients with neglected total type brachial plexus injury (BPI) who underwent nerve transfer and local injection of either umbilical cord-derivedmesenchymal stem cells (UC-MSC) or secretome into median nerve-flexor digitorum superficialis (FDS) neuromuscular junction (NMJ). We measured preoperative and 8-month postoperative FDS muscle strength, SF-36, DASH score, and histologic assessment. We then analyzed the difference outcome between those two groups. A total of 15 patients were included in this study. Our study found that after nerve transfer and implantation with either UC-MSC or secretome, significant postoperative improvements were observed in physical functioning, role limitations, energy/fatigue, emotional well-being, social functioning, pain, general health, and DASH scores, particularly in the overall cohort and the secretome group. When we compared the mean difference of clinical outcome from preoperative to postoperative between UC-MSC and secretome groups, the UC-MSC group showed better improvement of health change in SF-36 subgroup compared to secretome group. From the analysis, there was no significant difference in the histologic outcomes (inflammation, regeneration, and fibrosis) in overall cohort between preoperative and postoperative cohort. There was also no significant difference in mean change of the histologic outcomes (inflammation, regeneration, and fibrosis) preoperative and postoperatively between UC-MSC and secretome groups. Implantation of either UC-MSC or secretome along with nerve transfer may provide clinical improvement, while to achieve histologic improvement, further conditioning should be performed.

From Cancer to Immune Organoids: Innovative Preclinical Models to Dissect the Crosstalk between Cancer Cells and the Tumor Microenvironment

Genomic-oriented oncology has improved tumor classification, treatment options, and patient outcomes. However, genetic heterogeneity, tumor cell plasticity, and the ability of cancer cells to hijack the tumor microenvironment (TME) represent a major roadblock for cancer eradication. Recent biotechnological advances in organotypic cell cultures have revolutionized biomedical research, opening new avenues to explore the use of cancer organoids in functional precision oncology, especially when genomics alone is not a determinant. Here, we outline the potential and the limitations of tumor organoids in preclinical and translational studies with a particular focus on lung cancer pathogenesis, highlighting their relevance in predicting therapy response, evaluating treatment toxicity, and designing novel anticancer strategies. Furthermore, we describe innovative organotypic coculture systems to dissect the crosstalk with the TME and to test the efficacy of different immunotherapy approaches, including adoptive cell therapy. Finally, we discuss the potential clinical relevance of microfluidic mini-organ technology, capable of reproducing tumor vasculature and the dynamics of tumor initiation and progression, as well as immunomodulatory interactions among tumor organoids, cancer-associated fibroblasts (CAFs) and immune cells, paving the way for next-generation immune precision oncology.

Enhanced tumor control and survival in preclinical models with adoptive cell therapy preceded by low-dose radiotherapy.

Effective infiltration of chimeric antigen receptor T (CAR-T) cells into solid tumors is critical for achieving a robust antitumor response and improving therapeutic outcomes. While CAR-T cell therapies have succeeded in hematologic malignancies, their efficacy in solid tumors remains limited due to poor tumor penetration and an immunosuppressive tumor microenvironment. This study aimed to evaluate the potential of low-dose radiotherapy (LDRT) administered before T-cell therapy to enhance the antitumor effect by promoting CAR-T cell infiltration. We hypothesized that combining LDRT with T-cell therapy would improve tumor control and survival compared to either treatment alone. We investigated this hypothesis using two NSG mouse models bearing GSU or CAPAN-2 solid tumors. The mice were treated with engineered CAR-T cells targeting guanyl cyclase-C (GCC) or mesothelin as monotherapy or in combination with LDRT. Additionally, we extended this approach to a C57BL/6 mouse model implanted with MC38-gp100+ cells, followed by adoptive transfer of pmel+ T cells before and after LDRT. Tumor growth and survival outcomes were monitored in all models. Furthermore, we employed atomic force microscopy (AFM) in a small cohort to assess the effects of radiotherapy on tumor stiffness and plasticity, exploring the role of tumor nanomechanics as a potential biomarker for treatment efficacy. Our results demonstrated enhanced tumor control and prolonged survival in mice treated with LDRT followed by T-cell therapy across all models. The combination of LDRT with CAR-T or pmel+ T-cell therapy led to superior tumor suppression and survival compared to monotherapy, highlighting the synergistic impact of the combined approach. Additionally, AFM analysis revealed significant changes in tumor stiffness and plasticity in response to LDRT, suggesting that the nanomechanical properties of the tumor may be predictive of therapeutic response. The findings of this study highlight the transformative potential of incorporating LDRT as a precursor to adoptive T-cell therapy in solid tumors. By promoting CAR-T and pmel+ T-cell infiltration into the tumor microenvironment, LDRT enhanced tumor control and improved survival outcomes, offering a promising strategy to overcome the challenges associated with CAR-T therapy in solid tumors. Additionally, the changes in tumor nanomechanics observed through AFM suggest that tumor stiffness and plasticity could be biomarkers for predicting treatment outcomes. These results support further investigation into the clinical application of this combined approach to improve the efficacy of cell-based therapies in patients with solid tumors.

Comparative analysis of iPSC-derived NK cells from two differentiation strategies reveals distinct signatures and cytotoxic activities.

The ability to generate natural killer (NK) cells from induced pluripotent stem cells (iPSCs) has given rise to new possibilities for the large-scale production of homogeneous immunotherapeutic cellular products and opened new avenues towards the creation of "off-the-shelf" cancer immunotherapies. However, the differentiation of NK cells from iPSCs remains poorly understood, particularly regarding the ontogenic landscape of iPSC-derived NK (iNK) cells produced in vitro and the influence that the differentiation strategy employed may have on the iNK profile. To investigate this question, we conducted a comparative analysis of two sets of iNK cells generated from the same iPSC line using two different protocols: (i) a short-term, clinically compatible feeder-free protocol corresponding to primitive hematopoiesis, and (ii) a lymphoid-based protocol representing the definitive hematopoietic step. Our work demonstrated that both protocols are capable of producing functional iNK cells. However, the two sets of resulting iNKs exhibited distinct phenotypes and transcriptomic profiles. The lymphoid-based differentiation approach generated iNKs with a more mature and activated profile, which demonstrated higher cytotoxicity against cancer cell lines compared to iNK cells produced under short-term feeder-free conditions suggesting that the differentiation strategy must be considered when designing iNK cell-based adoptive immunotherapies.

Optimized Fabrication of Dendritic Mesoporous Silica Nanoparticles as Efficient Delivery System for Cancer Immunotherapy.

In the past decade, cancer immunotherapy has revolutionized the field of oncology. Major immunotherapy approaches such as immune checkpoint inhibitors, cancer vaccines, adoptive cell therapy, cytokines, and immunomodulators have shown great promise in preclinical and clinical settings. Among them, immunomodulatory agents including cancer vaccines are particularly appealing; however, they face limitations, notably the absence of efficient and precise targeted delivery of immune-modulatory agents to specific immune cells and the potential for off-target toxicity. Nanomaterials can play a pivotal role in addressing targeting and other challenges in cancer immunotherapy. Dendritic mesoporous silica nanoparticles (DMSNs) can enhance the efficacy of cancer vaccines by enhancing the effective loading of immune modulatory agents owing to their tunable pore sizes. In this work, an emulsion-based method is optimized to customize the pore size of DMSNs and loaded DMSNs with ovalbumin (OVA) and cytosine-phosphate-guanine (CpG) oligodeoxynucleotides (CpG-OVA-DMSNs). The immunotherapeutic effect of DMSNs is achieved through controlled chemical release of OVA and CpG in antigen-presenting cells (APCs). The results demonstrated that CpG-OVA-DMSNs efficiently activated the immune response in APCs and reduced tumor growth in the murine B16-OVA tumor model.

Cancer immunotherapy by γδ T cells.

The premise of cancer immunotherapy is that cancers are specifically visible to an immune system tolerized to healthy self. The promise of cancer immunotherapy is that immune effector mechanisms and immunological memory can jointly eradicate cancers and inoperable metastases and de facto vaccinate against recurrence. For some patients with hitherto incurable diseases, including metastatic melanoma, this promise is being realized by game-changing immunotherapies based on αβ T cells. Today's challenges are to bring benefit to greater numbers of patients of diverse ethnicities, target more cancer types, and achieve a cure while incurring fewer adverse events. In meeting those challenges, specific benefits may be offered by γδ T cells, which compose a second T cell lineage with distinct recognition capabilities and functional traits that bridge innate and adaptive immunity. γδ T cell-based clinical trials, including off-the-shelf adoptive cell therapy and agonist antibodies, are yielding promising results, although identifiable problems remain. In addressing those problems, we advocate that immunotherapies be guided by the distinctive biology of γδ T cells, as elucidated by ongoing research.