Isolation Of Cells Research Articles

Strategies and Protocols for Optimized Genome Editing in Potato.

The potato family includes a highly diverse cultivar repertoire and has a high potential for nutritional yield improvement and refinement but must in line with other crops be adapted to biotic and abiotic stresses, for example, accelerated by climate change and environmental demands. The combination of pluripotency, high ploidy, and relative ease of protoplast isolation, transformation, and regeneration together with clonal propagation through tubers makes potato highly suitable for precise genetic engineering. Most potato varieties are tetraploid having a very high prevalence of length polymorphisms and small nucleotide polymorphisms between alleles, often complicating CRISPR-Cas editing designs and strategies. CRISPR-Cas editing in potato can be divided into (i) characterization of target area and in silico-aided editing design, (ii) isolation and editing of protoplast cells, and (iii) the subsequent explant regeneration from single protoplast cells. Implementation of efficient CRISPR-Cas editing relies on efficient editing at the protoplast (cell pool) level and on robust high-throughput editing scoring methods at the cell pool and explant level. Gene and chromatin structure are additional features to optionally consider. Strategies and solutions for addressing key steps in genome editing of potato, including light conditions and schemes for reduced exposure to hormones during explant regeneration, which is often linked to somaclonal variation, are highlighted.

Comparison of Culturing Methods of Primary Vaginal Fibroblasts

Importance Vaginal fibroblast function is altered in people with pelvic organ prolapse. Thus, it is important to study vaginal fibroblasts to better understand the pathophysiology of prolapse. Objective This study aimed to compare 3 culturing methods of primary vaginal fibroblasts. Study Design This was an in vitro study. Patients who were undergoing surgery for vaginal prolapse were recruited. Excess vaginal epithelial tissue that would have otherwise been discarded was collected. The vaginal fibroblasts from each participant were cultured via (1) 3-hour digest, (2) coverslip, and (3) gelatin-coat methods. Differences in the efficiency of cell isolation, expression of known fibroblast-associated genes, and cellular function were compared between the 3 methods using one-way analysis of variance and Tukey test for post hoc pairwise comparisons (P < 0.05). Results Five patients with pelvic organ prolapse were recruited. Fibroblasts cultured via the 3-hour digest method became confluent within 3–5 days in a 100-mm dish compared to 2–3 weeks in a 6-well dish for the coverslip and gelatin-coat methods. Cells from all culture methods expressed similar amounts of vimentin and α smooth muscle actin. There were no significant differences in morphology; gene expression levels of MMP1, MMP2, ACTA2, COL1A1, COL3A1, and LOXL1 on qPCR; cell viability; proliferation; and migration between the 3 culturing methods. Conclusion Culturing primary vaginal fibroblasts via the 3-hour digest, coverslip, and gelatin-coat methods similarly resulted in reliable primary vaginal fibroblast growth and function.

Establishment of Nile Tilapia Primary Cell Culture Methods and In Vitro Cell Knockdown Techniques.

As an important aquaculture species and research model, Nile tilapia (Oreochromis niloticus) has not yet been systematically studied for the isolation, culture, and in vitro gene manipulation techniques of primary cells from various tissues. This study aimed to explore methods for isolating primary cells from various tissues, as well as developing in vitro gene manipulation techniques in Nile tilapia. Four different Nile tilapia tissues were enzymatically digested and separated using trypsin or collagenase. Collagenase (0.1%) was used for the digestion of the gonads, liver, and heart, while trypsin (0.25%) showed better adhesion efficiency for spleen tissue. Moreover, we assessed EGFP fluorescence intensity and cell survival rates following transfection with empty siRNA (siRNA-NC), lentivirus (LV-NC), and six adeno-associated virus (AAV-NC) serotypes (AAV2-NC, AAV5-NC, AAV6-NC, AAV8-NC, AAV9-NC, AAV-DJ-NC) in gonadal cells. The results demonstrated that cells transfected with siRNA-NC and LV-NC showed the highest levels of green fluorescent protein expression and survival rates in primary gonadal cells, compared to AAC-NC. Subsequently, we knocked down the Kdm6bb gene in Nile tilapia primary gonadal cells by transfecting them with LV-Kdm6bb and siRNA-Kdm6bb. qPCR and immunofluorescence analyses demonstrated a significant reduction in Kdm6bb mRNA levels following transfection with siRNA-Kdm6bb compared to siRNA-NC, and with LV-Kdm6bb compared to LV-NC. This study offers valuable tools for the validation of primary cell isolation and in vitro molecular regulatory mechanisms and functions in Nile tilapia.

Biopsy vitrification: New tool for endometrial tissue cryopreservation for research applications

Patient-derived endometrial biopsies serve as a crucial source for molecular studies, highlighting the necessity for tissue cryopreservation methods that preserve cell viability and tissue morphology with minimal to no impact. The passive slow freezing (PSF) protocol has demonstrated efficacy for cryopreserving endometrial biopsies, allowing for the subsequent isolation of viable epithelial and stromal cells. Vitrification (VT) enables the avoidance of ice crystal formation and could therefore potentially prevent mechanical injury to tissues. In this study, PSF and VT techniques were applied to endometrial biopsies, and the effects of cryopreservation on tissue samples were evaluated using traditional histology. In addition, transmission electron microscopy (TEM), gene expression profiling analyses, the viability of endometrial cells, and the ability to form epithelial organoids were compared between PSF and VT endometrial biopsies in a subset of samples. The histology and TEM studies demonstrated relatively mild cellular and sub-cellular damage in both cryopreservation protocols which did not affect tissue functionality and the formation of the organoids. Additionally, the cryopreservation methodology did not affect the gene expression profile of the 68 endometrial-receptivity associated genes studied. In conclusion, our findings indicate that although current cryopreservation methodologies need further improvements, they still allow us to achieve acceptable cell viability and functionality, showing promising potential for facilitating the utilization of cryopreserved endometrial tissue samples for research purposes.

Nano‐Biosensors for mRNA‐Based Cell Sorting Using Intracellular Markers at the Early Stage of Cell Reprogramming

AbstractCell reprogramming and manufacturing have broad applications in tissue regeneration and disease treatment. However, many derived cell types lack unique cell surface markers for protein‐based cell sorting, making it difficult to isolate these cells from mixed populations. Additionally, there is a need to identify and isolate cells of interest at the early stages of cell expansion. To address this challenge, a nucleic acid‐based gold nanorod (NAGNR) fluorescent biosensor was engineered to detect the mRNA expression of intracellular markers for cell sorting. Its application is demonstrated in isolating induced neuronal (iN) cells from dermal fibroblast populations during the early stages of cell reprogramming. Cell sorting based on the mRNA of the neuronal transcriptional factor Ascl1 resulted in an enrichment of iN cells from 3% to 72%, and additional sorting with the transcriptional factor Scn2 further increased iN enrichment. Moreover, NAGNR biosensors can be used in conjunction with protein marker‐based cell sorting. NAGNR‐sorted iN cells show a functional response to electrical stimulation in a co‐culture of iN cells and muscle cells. These findings demonstrate that NAGNR‐based cell sorting offers great potential for cell identification and isolation at an early stage of cell reprogramming and manufacturing.

Human Pulmonary Neuroendocrine Cells Respond to House Dust Mite Extract With PAR-1 Dependent Release of CGRP.

Pulmonary neuroendocrine cells (PNEC) are rare airway epithelial cells that have recently gained attention as potential amplifiers of allergic asthma. However, studying PNEC function in humans has been challenging due to a lack of cell isolation methods, and little is known about human PNEC function in response to asthma-relevant stimuli. Here we developed and characterized an invitro human PNEC model and investigated the neuroendocrine response to extracts of the common aeroallergen house dust mite (HDM). PNEC-enriched cultures were generated from human induced pluripotent stem cells (iPNEC) and primary bronchial epithelial cells (ePNEC). Characterized PNEC cultures were exposed to HDM extract, a volatile chemical odorant (Bergamot oil), or the bacterial membrane component, lipopolysaccharide (LPS), and neuroendocrine gene expression and neuropeptide release determined. Both iPNEC and ePNEC models demonstrated similar baseline neuroendocrine characteristics and a stimuli-specific modulation of gene expression. Most notably, exposure to HDM but not Bergamot oil or LPS, leads to dose-dependent induction of the CGRP encoding gene, CALCB, and corresponding release of the neuropeptide. HDM-induced CALCB expression and CGRP release could be inhibited by a protease-activated receptor 1 (PAR1) antagonist or protease inhibitors and was mimicked by a PAR1 agonist. We have characterized a novel model of PNEC-enriched human airway epithelium and utilized this model to demonstrate a previously unrecognized role for human PNEC in mediating a direct neuroendocrine response to aeroallergen exposure.

Molecular Characterization and Pathogenicity Analysis of Porcine Rotavirus A

Porcine rotavirus A (RVA) is one of the major etiological agents of diarrhea in piglets and constitutes a significant threat to the swine industry. A molecular epidemiological investigation was conducted on 2422 diarrhea samples from Chinese pig farms to enhance our understanding of the molecular epidemiology and evolutionary diversity of RVA. The findings revealed an average RVA positivity rate of 42% (943/2422), and the study included data from 26 provinces, primarily in the eastern, southern and southwestern regions. Genetic evolutionary analysis revealed that G9 was the predominant genotype among the G-type genotypes, accounting for 25.32% of the total. The VP4 genotypes were P[7] (36.49%) and P[23] (36.49%). The predominant genotypic combinations of RVA were G9P[23] and G9P[7]. Eleven RVA strains were obtained via MA104 cell isolation. A rat model was established to assess the pathogenicity of these strains, with three strains exhibiting high pathogenicity in the model. Specifically, the RVA Porcine CHN HUBEI 2022 (Q-1), RVA Porcine CHN SHANXI 2022 (3.14-E), and RVA Porcine CHN HUBEI 2022 (5.11-U) strains were shown to cause diarrhea in the rats and damage the intestinal villi during the proliferation phase of the infection, leading to characteristic lesions in the small intestine. These data indicate that continuous monitoring of RVA can provide essential data for the prevention and control of this virus.

Single-cell transcriptomics: a new frontier in plant biotechnology research.

Single-cell transcriptomic techniques have ushered in a new era in plant biology, enabling detailed analysis of gene expression at the resolution of individual cells. This review delves into the transformative impact of these technologies on our understanding of plant development and their far-reaching implications for plant biotechnology. We present a comprehensive overview of the latest advancements in single-cell transcriptomics, emphasizing their application in elucidating complex cellular processes and developmental pathways in plants. By dissecting the heterogeneity of cell populations, single-cell technologies offer unparalleled insights into the intricate regulatory networks governing plant growth, differentiation, and response to environmental stimuli. This review covers the spectrum of single-cell approaches, from pioneering techniques such as single-cell RNA sequencing (scRNA-seq) to emerging methodologies that enhance resolution and accuracy. In addition to showcasing the technological innovations, we address the challenges and limitations associated with single-cell transcriptomics in plants. These include issues related to sample preparation, cell isolation, data complexity, and computational analysis. We propose strategies to mitigate these challenges, such as optimizing protocols for protoplast isolation, improving computational tools for data integration, and developing robust pipelines for data interpretation. Furthermore, we explore the practical applications of single-cell transcriptomics in plant biotechnology. These applications span from improving crop traits through precise genetic modifications to enhancing our understanding of plant-microbe interactions. The review also touches on the potential for single-cell approaches to accelerate breeding programs and contribute to sustainable agriculture. This review concludes with a forward-looking perspective on the future impact of single-cell technologies in plant research. We foresee these tools becoming essential in plant biotechnology, spurring innovations that tackle global challenges in food security and environmental sustainability. This review serves as a valuable resource for researchers, providing a roadmap from sample preparation to data analysis and highlighting the transformative potential of single-cell transcriptomics in plant biotechnology.

EXPRESS: Effectiveness of stem cells therapy for male infertility restoration: a systematic review.

Cell therapy has emerged as a prominent leader in regenerative medicine, offering potential solutions for various disorders, including infertility. The half of all infertility cases are related to male factors. The objective of this study is to systematically summarize the existing knowledge regarding studies on stem cell-based therapy for the regeneration of impaired spermatogenesis. Initial searching was performed through main databases (e.g., PubMed, Scopus, Cochrane Library, Embase) until December 2023. Articles conducted on stem cell transplantation into the testis of infertile models were considered. The titles and abstracts of articles were carefully evaluated and screened by independent authors. Non-related articles were deleted. The desired outcomes about infertility treatment after stem cell transplantation were attentively evaluated in the final selected articles. In the primary search, 3237 published studies were identified. Finally, 39 studies were included based on the eligibility criteria. In all studies except for two articles, all the outcomes considered, including germ cells/spermatogonia stem cell differentiation, spermatogenesis restoration, defective testicular tissue regeneration, improved sperm quality parameters and hormonal levels, as well as increased expression of fertility-related markers and fertility rate, were observed after stem cell transplantation. Transplantation of stem cells, especially MSCs could be a safe and effective method for the treatment of male infertility patients, such as azoospermic cases. Further research to investigate the efficiency of different stem cells sources, providing nutrient conditions for the isolation and differentiation of stem cells, and exploring the paracrine effects of MSCs in male infertility therapy, could be useful.

Scratch-Based Isolation of Primary Cells (SCIP): A Novel Method to Obtain a Large Number of Human Dental Pulp Cells Through One-Step Cultivation

Scratch-Based Isolation of Primary Cells (SCIP): A Novel Method to Obtain a Large Number of Human Dental Pulp Cells Through One-Step Cultivation

Severe traumatic brain injury temporally affects cerebral blood flow, endothelial cell phenotype, and cilia.

Previous clinical work suggested that altered cerebral blood flow (CBF) in severe traumatic brain injury (sTBI) correlates with poor executive function and clinical outcome. However, the molecular consequences of altered CBF on endothelial cells (ECs) and their blood flow-sensor organelle called cilia are not known. We performed laser speckle contrast imaging, single cell isolation, and single cell RNA sequencing (scRNAseq) after sTBI in a closed skull, linear impact mouse model. Validation of select ciliary target protein changes was performed using flow cytometry. Additionally, in vitro experiments modeled the post-injury hypoxic environment to evaluate the effect on cilia protein ARL13B in human brain microvascular ECs. We detected immediate reductions in CBF that were sustained for at least 100 minutes in both impacted and non-impacted sides of the brain. Our scRNAseq data detected heterogeneity in the brain cortex-derived EC cluster and demonstrated that two of five unique EC sub-clusters changed their relative proportions post-sTBI. Consistent with flow changes, we identified multiple genes associated with the fluid shear stress pathway that were significantly differentially expressed in brain ECs post-injury. Also, ECs displayed activation of ischemic pathway as early as day 1 post-injury, and enrichment of hypoxia pathway at day 7 and 28 post- injury. Arl13b ciliary gene expression was lost on day 1 in ECs cluster and remained lost for the entire course of the injury. We validated the loss of cilia protein ARL13B specifically from brain ECs as early as day 1 post-injury and detected the protein in the peripheral blood of the injured mice. We also determined that hypoxia could induce loss of ARL13B protein from cultured ECs. In severe TBI, blood flow is disrupted in both impacted and non-impacted regions of the brain, creating a hypoxic environment that may influence ciliary gene and protein expression on ECs.

Isolation and identification of patient-derived liver cancer stem cells and development of personalized treatment strategies

BackgroundLiver cancer stem cells (LCSCs) are thought to drive the metastasis and recurrence, however, the heterogeneity of molecular markers of LCSCs has hindered the development of effective methods to isolate them.MethodsThis study introduced an effective approach to isolate and culture LCSCs from human primary liver cancer (HPLC), leveraging mouse embryonic fibroblasts (MEFs) as feeder cells in conjunction with using defined medium. Isolated LCSCs were further characterized by multiple approaches. Transcriptome sequencing data analysis was conducted to identify highly expressed genes in LCSCs and classify different subtypes of liver cancers.ResultsTotal sixteen cell strains were directly isolated from 24 tissues of three types of HPLC without sorting, seven of which could be maintained long-term culture as colony growth on MEFs, which is unique characteristics of stem cells. Even 10 of cloned cells formed the tumors in immunodeficient mice, indicating that those cloned cells were tumorgenic. The histologies and gene expression pattern of human xenografts were very similar to those of HPLC where these cloned cells were isolated. Moreover, putative markers of LCSCs were further verified to all express in cloned cells, confirming that these cells were LCSCs. These cloned LCSCs could be cryopreserved, and still maintained the feature of colony growth on MEFs after the recovery. Compared to suspension culture as conventional approach to culture LCSCs, our approach much better maintained stemness of LCSCs for a long time. To date, these cloned cells could be cultured on MEFs over 12 passages. Moreover, bioinformatics analysis of sequencing data revealed the gene expression profiles in LCSCs, and liver cancers were classified into two subtypes C1 and C2 based on genes associated with the prognosis of LCSCs. Patients of the C2 subtype, which is closely related to the extracellular matrix, were found to be sensitive to treatments such as Cisplatin, Axitinib, JAK1 inhibitors, WNT-c59, Sorafenib, and RO-3306.ConclusionIn summary, this effective approach offers new insights into the molecular landscape of human liver cancers, and the identification of the C2 subtype and its unique response to the treatment pave the way for the creation of more effective, personalized therapeutic strategies.

Force-triggered density gradient sedimentation and cocktail enzyme digestion treatment for isolation of single dermal papilla cells from follicular unit extraction harvesting human hair follicles

BackgroundHair follicles (HFs) are dynamic structures which are readily accessible within the skin that contain various pools of stem cells with broad regenerative potential, such as dermal papilla cells (DPCs), dermal sheath cells, and epithelial HF stem cells. DPCs act as signalling centres for HF regeneration. The current method for isolating human DPCs are inefficient. These methods struggle to obtain freshly isolated original DPCs and do not maintain the characteristics of DPCs effectively.MethodsIn this study, two simple but more efficient methods were explored. Force-triggered density gradient sedimentation (FDGS) and cocktail enzyme digestion treatment (CEDT) were used to isolate purified DP spheres from human HFs, obtaining purified freshly isolated original DPCs from DP spheres. The expression profiles of isolated DPCs were tested, and gene expression of DPC-specific markers were analyzed using immunofluorescence staining, RT-qPCR and western blot.ResultsThe 10% Ficoll PM400 was determined as the optimal concentration for FDGS method. Primary DPCs, DSCs and HFSCs were isolated simultaneously using the FDGS and CEDT method. The expression profiles of fresh DPCs isolated using the FDGS and CEDT methods were similar to those of traditionally isolated DPCs. DP-specific markers were expressed at significantly higher levels in freshly isolated DPCs than in traditionally isolated DPCs.ConclusionsCompared to traditional methods, the presented laboratory protocols were able to isolate fresh DPCs with high efficiency, thereby improving their research potential.

Progesterone supplemented uterine epithelial cell co-culture improves in vitro quality embryo production in buffalo

Objectives: The present study was conducted to study the effect of progesterone and uterine luminal epithelial cells monolayer on blastocyst development and hatching rate. Material and Methods: The isolation, culture, and characterization of slaughterhouse-derived uterine epithelial cells were done using standard protocol. The steroid hormones estrogen and progesterone were supplemented in embryo developmental media (EDM), and day 04 embryos were cultured in different groups as progesterone supplementation (T1), co-cultured with epithelial cell monolayer (T2), co-cultured with progesterone supplemented epithelial cell monolayer (T3), or without any treatment (control). Finally, the effect of different treatments was analyzed in terms of blastocyst and hatching rate. Results: The isolated epithelial cells depicted compact cuboidal or columnar morphology at the confluence. Immunocytochemical localization and polymerase chain reaction study revealed positive expression of cytokeratin and absence of vimentin. Significantly higher blastocyst and hatching rates were noted in the T3 group, followed by T2, T1, and control groups. Conclusion: The present study revealed improved in vitro embryo production after co-culturing embryos with progesterone-supplemented uterine epithelial cells in buffalo.

Spatially Controlled DNA Frameworks for Sensitive Detection and Specific Isolation of Tumor Cells.

High-affinity, specific, and sensitive probes are crucial for the specific recognition and identification of tumor cells from complex matrices. Multivalent binding is a powerful strategy, but the irrational spatial distribution of the functional moieties may reduce the probe performance. Here, we constructed a Janus DNA triangular prism nanostructure (3Zy1-JTP-3) for sensitive detection and specific isolation of tumor cells. Benefiting from spatial features of the triangular prism, the fluorescence intensity induced by 3Zy1-JTP-3 was almost 4 times that of the monovalent structure. Moreover, the DNA triangular prisms were connected to form hand-in-hand multivalent DNA triangular prism structures (Zy1-MTP), in which the fluorescence intensity and affinity were increased to 9-fold and 10-fold of 3Zy1-JTP-3, respectively. Furthermore, 3Zy1-JTP-3 and Zy1-MTP were combined with magnetic beads, and the latter showed higher capture efficiency (> 90%) in whole blood. This work provides a new strategy for the efficient capture of rare cells in complex biological samples.

Spatially Controlled DNA Frameworks for Sensitive Detection and Specific Isolation of Tumor Cells

AbstractHigh‐affinity, specific, and sensitive probes are crucial for the specific recognition and identification of tumor cells from complex matrices. Multivalent binding is a powerful strategy, but the irrational spatial distribution of the functional moieties may reduce the probe performance. Here, we constructed a Janus DNA triangular prism nanostructure (3Zy1‐JTP‐3) for sensitive detection and specific isolation of tumor cells. Benefiting from spatial features of the triangular prism, the fluorescence intensity induced by 3Zy1‐JTP‐3 was almost 4 times that of the monovalent structure. Moreover, the DNA triangular prisms were connected to form hand‐in‐hand multivalent DNA triangular prism structures (Zy1‐MTP), in which the fluorescence intensity and affinity were increased to 9‐fold and 10‐fold of 3Zy1‐JTP‐3, respectively. Furthermore, 3Zy1‐JTP‐3 and Zy1‐MTP were combined with magnetic beads, and the latter showed higher capture efficiency (>90 %) in whole blood. This work provides a new strategy for the efficient capture of rare cells in complex biological samples.

CNSC-58. BIOPROCESSING OF VIABLE SURGICAL PEDIATRIC BRAIN TUMOR SPECIMENS FOR GENOME-GUIDED PERSONALIZED DRUG TESTING

Abstract Novel treatment approaches are urgently needed for pediatric central nervous system (CNS) tumors as they are the leading cause of cancer-related deaths in children. A lack of research materials impedes progress towards developing such therapies. Although various brain cancer biobanks exist, these rarely store viable patient-derived tissue and cells for live cell analyses, including cell fate assays and testing for drug sensitivities. We propose that a biorepository of viable cell dissociates and tissue broadly representing CNS tumor entities overcomes these limitations. From a combination of molecular diagnoses and histopathologic assessment of over 120 samples collected, we generated a biorepository of roughly 35 distinct entities of pediatric CNS tumors in our Stanford neuro-bioprocessing cohort. Based on the Central Brain Tumor Registry of the United States, the proportion of subtypes represented in our cohort match that of the general population with exceptions. We established a standardized bioprocessing pipeline that can be used as a template for tissue collection and model development in the broader disease context and for multiple downstream applications. Our emphasis on cryostorage of viable cells and tissue facilitates ad hoc live cell analyses. In addition to gaining a better understanding of tumor pathophysiology, we attempted a rapid bed-to-bench-to-bedside approach using comparative RNA expression profile analyses in an individual patient’s pilocytic astrocytoma. Novel drug targets were identified by analyzing RNA transcripts that are highly expressed (outliers) compared with a compendium of 12,747 brain and non-brain tumor samples. We validated outliers as drug targets using acute cell isolates, and identified a novel target in recurrent low-grade glioma. These studies illustrate that biobanking of viable patient-derived material enables developing personalized therapies with the goal of improving patient outcomes. As demonstrated here, patient-derived acute cell isolates facilitate identifying drug vulnerability, creating an opportunity for more personalized treatment of patients with CNS tumors.

Perspectives on Ergodic Cancer Therapy Derived from Cloning Genome Chaos via In Vivo Rhabdomyosarcoma RA-2 Models: a Narrative Review.

This review explores articles concerning the experimental research cycle on genome instability in cell populations of highly malignant recurrent organotropic rhabdomyosarcoma RA- 2 in rats. Clonal analysis and cloning were pivotal components of this research, which relies on the frequency of cells with micronuclei and internuclear bridges to gauge the intensity of chromothripsis and break-fusion-bridge cycles. The efficacy of cloning, determined by these indicators, stemmed from the deliberate isolation of tumor stem cells, yielding clones in which chromothripsis activity and breakage-fusion-bridge cycles were sustained. Notably, it is plausible that the stem cells themselves, progenitors of these clones, harbor dicentric chromosomes and chromosomal fragments, contributing to the formation of "fatal micronuclei" in their karyotype. Cloning based on bridges and micronuclei has proven effective up to a certain threshold (15%-18%), reaffirming the predicted reproductive extinction of malignant cell populations under mutational pressure and genome chaos, as posited by the genetic theory of cell populations. Furthermore, this review highlights the potential of ergodic cancer therapy as a novel therapeutic strategy. Ergodic therapy offers promising prospects for late-stage and terminal malignant tumors, where conventional treatments may fall short due to advanced progression. Furthermore, by "enhancing chromothripsis" through the induction of additional micronuclei and bridges, ergodic cancer therapy seeks to increase genome chaos to a critical threshold, potentially halting malignant progression. This innovative approach presents opportunities to explore new drugs and targets for chromothripsis-based oncotherapy, addressing the pressing need for effective treatments in advanced stages of malignancy.

An in vitro investigation into the cytotoxic impact of antigen-presenting dendritic cell-tumor infiltrating lymphocytes on ovarian cancer cells

ObjectiveThe objective of this study is to develop a novel therapeutic approach for the treatment of ovarian cancer while investigating the role of tumor-infiltrating lymphocytes (TILs) in the context of ovarian cancer therapy. The primary aim is to establish a technical procedure for the isolation of tumor cells, lymphocytes, and dendritic cells (DCs) derived from ovarian cancer tissues or ascites. Subsequently, the focus lies on the generation of dendritic cell-tumor infiltrating lymphocytes (DC-TILs) exhibiting specific cytotoxic capabilities aimed at targeted therapeutic interventions. The cytotoxic impact of DC-TIL interactions on tumor cells was investigated through in vitro experimentation. This research aims to provide fundamental experimental insights for the future clinical advancement of TIL therapy in ovarian cancer.MethodsThe experimental samples included fresh surgical specimens and ascites specimens procured from three patients (ranging in age from 32 to 75), sourced from the Department of Gynecology at the Third Bethune Hospital of Jilin University. TILs were extracted through in vitro isolation from solid tumor tissues, while primary tumor cells and DCs were obtained from ascites specimens. Tumor-specific antigens derived from patient tumor cells were utilized to stimulate the maturation of DCs. TILs were subsequently co-cultured with antigen-stimulated DC cells. Subsequently, TILs with specific killing effects were obtained, and the cytotoxic impact of DC-TILs on tumor cells was detected in vitro.Results(1) TILs were successfully obtained through expansion from the tumor tissue of a patient diagnosed with ovarian cancer. (2) DCs were successfully induced from ascites cells harvested from patients diagnosed with ovarian cancer. (3) TILs significantly enhanced the cytotoxicity of tumor cells following DC stimulation.ConclusionTILs have the capacity to augment the cytotoxicity directed towards tumor cells following DC stimulation.

Inactivated Toxoplasma gondii nanovaccine boosts T-cell memory response in a seropositive yellow-footed rock wallaby (Petrogale xanthopus) – A case report from Copenhagen Zoo

Toxoplasma gondii is a ubiquitous parasite causing significant mortality in captive wildlife, especially marsupials. Historically, treatment has been unrewarding and no vaccine was available. An intranasal vaccine based on purified inactivated T. gondii was developed for toxoplasmosis prevention. A vaccination campaign started in early 2017 and was successful in preventing toxoplasma-related mortality in marsupials in many European and South American zoos. Amongst the vaccinated wallabies, about 30% were T. gondii seropositive before the vaccination, and no toxoplasma-related deaths were observed since the administration of the vaccine. The objective of this case study was to assess the potential effect of the vaccination on a seropositive wallaby. It is important to note that this vaccine doesn't induce any humoral response in sheep, and squirrel monkeys but induces a strong T-cell response. A T. gondii seropositive Yellow-footed rock wallaby (Petrogale xanthopus) from Copenhagen Zoo received two doses of the aforementioned intranasal vaccine. Blood samples were collected before each vaccination and used for peripheral blood mononuclear cell isolation. The impact of the vaccination on the lymphocyte phenotype was characterized by flow cytometry. Cell size, represented by forward scatter, and granularity, represented by side scatter parameters were analyzed. Two doses of the vaccine induced a respective 30.1 and 25.6% increase in cell size and granularity in lymphocytes stimulated with T. gondii antigens, as assessed by flow cytometry. These changes were likely correlated with T-cell activation, which indicates that two doses of the vaccine might have boosted the already-existing T-cell memory response against T. gondii in a seropositive animal. No morphological changes were observed in lymphocytes from an unvaccinated seronegative wallaby. This is the first documented case of boosting an already-existing cellular immune response against toxoplasmosis by the vaccine in a seropositive Yellow-footed rock wallaby.