Perichondrial progenitor cells promote proliferation and chondrogenesis of mature chondrocytes

Autologous chondrocytes are effective sources of cell therapy for engineering cartilage tissue to repair chondral defects, such as degenerative arthritis. The expansion of cells with chondrocyte characteristics has become a major challenge due to inadequate donor sites and poor proliferation of mature chondrocytes. The perichondrial progenitor cells (P cells) from the cambium layer of the perichondrium possessed significantly higher mesenchymal stem cell markers than chondrocytes (C cells). In the transwell co-culture system, P cells increased the passaging capacity of C cells from P6 to P9, and the cell number increased 128 times. This system increased the percentage of Alcian blue-positive chondrocytes from 40% in P6 to 62% in P9, contributing about 198 times more Alcian blue-positive chondrocytes than the control group. C cells co-cultured with P cells also exhibited higher proliferation than C cells cultured with P cell-conditioned medium. Similar results were obtained in nude mice that were subcutaneously implanted with C cells, P cells, or a mixture of the two cell types, in which the presence of both cells enhanced neocartilage formation in vivo. In aggregate, P cells enhanced the proliferation of C cells in a dose-dependent manner and prolonged the longevity of mature chondrocytes for clinical applications.

Astrocyte and Oligodendrocyte Responses From the Subventricular Zone After Injury

Under normal conditions, neural stem cells (NSCs or B cells) in the adult subventricular zone (SVZ) give rise to amplifying neural progenitor cells (NPCs or C cells), which can produce neuroblasts (or A cells) that migrate to the olfactory bulb and differentiate into new neurons. However, following brain injury, these cells migrate toward the injury site where they differentiate into astrocytes and oligodendrocytes. In this review, we will focus on recent findings that chronicle how astrocytes and oligodendrocytes derived from SVZ-NSCs respond to different types of injury. We will also discuss molecular regulators of SVZ-NSC proliferation and their differentiation into astrocytes and oligodendrocytes. Overall, the goal of this review is to highlight how SVZ-NSCs respond to injury and to summarize the regulatory mechanisms that oversee their glial response. These molecular and cellular processes will provide critical insights needed to develop strategies to promote brain repair following injury using SVZ-NSCs.

Single-Cell Analysis of Human B Lymphoid and Neutrophil/Monocyte Lineage Restriction

Lifelong production of most types of mature blood cells is sustained by a small population of cells with extensive regenerative potential. However, the detailed steps that restrict multipotent or even bipotent human hematopoietic cells to any single lineage remain poorly understood. Those that segregate the human B-lymphoid and neutrophil/monocyte (NM) lineages are of particular interest as these appear to identify a stage that might control the different properties of human leukemias that display perturbed NM and/or B-cell programs. To undertake a refined analysis of this normal lineage restriction process in human cells, we first devised a culture system that permits it to be tracked clonally and efficiently (50%). Initial experiments showed this could be achieved using a combination of multiple stromal cell types and human growth factor-supplemented medium. To elucidate the intervening transitional steps we then used multiplexed flow cytometry to compare the progeny generated in this culture system over a 2-week time course from previously defined lymphoid progenitor-enriched (P-L), NM progenitor-enriched (P-NM) and less restricted P-mix cord blood (CB) subsets. The results suggested that gain of CD45RA (RA) expression and loss of CLEC12A (C) expression appeared to accompany the sequential restriction of early CD34+ progenitors first to cells with dual NM+B-lineage potential and then just to B-lineage potential. Subsequent tracking of the lineage outputs of CD34+ RA-C- cells initially produced in larger numbers from unfractionated CD34+ CB cells either in vitro or in xenografted immunodeficient mice, confirmed the CD34+ RA-C- subset to be highly enriched in cells with dual NM+B potential. In contrast, co-generated CD45RA+ (RA+C-) and RA+CLEC12A+ (RA+C+) phenotypes displayed separate B- and NM lineage-restricted activity, respectively, as indicated by their largely exclusive clonal outputs of CD19+ pre-B and CD14+/CD15+ NM precursors. In agreement with these phenotypically established separate NM and B-lineage outputs, RA+C- cells were found to contain higher levels of B-lineage-associated gene transcripts (e.g., DNTT, CD79A, and EBF1), whereas RA+C+ cells contained higher levels of the NM transcription factor mRNAs encoded by SPI1 and CEBPA. In a further optimized stroma-free liquid culture system, the RA-C- cells could be shown to produce continuously RA+C- and RA+C+ progeny after another 3-4 days, and also RA-C- progeny which are not produced from more restricted RA+C- and RA+C+ cells, suggesting that the acquired expression of RA precedes the separation of NM and B-lineage potential that is then marked by the differential activation of C expression in RA+ cells. To examine more precisely how the process of B+NM restriction to a single lineage might be related to successive cell cycles, we labeled RA-C- cells with carboxyfluorescein diacetate succinimidyl ester (CFSE) to enable the phenotypes and growth potential of the the progeny obtained after 6 days to be directly related to their prior division histories. This revealed extensive heterogeneity in the overall distribution of the initial progeny cell cycle times but with a clear segregation in the outputs of the faster and slower dividing cells. Notably, the faster dividers produced ultimately small M+B or uni-lineage clones whereas the initially slow dividers subsequently produced larger clones, 25% of which still contained CD34+ cells or N+M+B progeny. Taken together, these findings identify new hallmark phenotypic changes that identify a critical step in the lineage restriction of primitive human hematopoietic cells with dual NM+B-lineage potential and a previously unknown association of this process with a shortening of their cell cycle transit time. Disclosures No relevant conflicts of interest to declare.

RANK-C Expression Sensitizes ER-Negative, EGFR-Positive Breast Cancer Cells to EGFR-Tyrosine Kinase Inhibitors (TKIs)

Background: We have previously shown that overexpression of RANK-c in ER-negative breast cancer cell lines attenuates aggressive properties of cancer cells, partially through a RANK-c /EGFR interaction. EGFR inhibition through TKIs in breast cancer has been tested in triple-negative disease settings with limited clinical benefit for patients. Here we test if expression of RANK-c in ER-negative breast cancer cells in conjunction with treatment with TK inhibitors (erlotinib or gefitinib) can affect survival and colony-forming capacity of cancer cells. Methods: Stably expressing MDA-MB-231-RANK-c and SKBR3-RANK-c cells were employed to test proliferation and colony formation in the presence of TKIs. In addition, Western blot analysis was performed to dissect EGFR related signaling cascades upon TK inhibition in the presence of RANK-c. Results: Interestingly the two RANK-c expressing, ER-negative cells lines presented with a distinct phenotype concerning TKI sensitivity upon treatment. MDA-MB-231-RANK-c cells had a higher sensitivity upon gefitinib treatment, while erlotinib decreased the proliferation rate of SKBR3-RANK-c cells. Further, colony formation assays for MDA-MB-231-RANK-c cells showed a decrease in the number and size of colonies developed in the presence of erlotinib. In addition, RANK-c seems to alter signaling through EGFR after TKI treatment in a cell type-specific manner. Conclusions: Our results indicate that ER-negative breast cancer cells that express RANK-c alter their sensitivity profile against tyrosine kinase inhibitors (erlotinib and gefitinib) in a cell type-specific and culture substrate-dependent manner.

Immune Profiling of Medullary Thyroid Cancer—An Opportunity for Immunotherapy

Medullary thyroid cancer (MTC) is a rare malignancy that arises from calcitonin-producing C-cells. Curative treatment for patients with metastatic MTC is challenging. Identifying the mechanisms by which cancer cells inhibit the activity of immune cells provides an opportunity to develop new therapies that restore anticancer activity. Little is known about the immunological phenomena underlying MTC. Here, we examined the expression profile of 395 genes associated with MTC. The study included 51 patients diagnosed with MTC at a single center. Bioinformatical analysis revealed that CD276 expression in MTC cells was at least three-fold higher than that in normal tissue. The expression of CD276 showed a weak but statistically significant positive correlation with tumor diameter, but we did not find a significant association between CD276 expression and other histopathological clinical factors, or the response to initial therapy. A search of published data identified the monoclonal antibody (inhibitor) enoblituzumab as a potential drug for patients diagnosed with MTC overexpressing CD276.

Calendar Ageing Model for Li-Ion Batteries Using Transfer Learning Methods

Getting accurate lifetime predictions for a particular cell chemistry remains a challenging process, largely dependent on time and cost-intensive experimental battery testing. This paper proposes a transfer learning (TL) method to develop LIB ageing models, which allow for the leveraging of experimental laboratory testing data previously obtained for a different cell technology. The TL method is implemented through Neural Networks models, using LiNiMnCoO2/C laboratory ageing data as a baseline model. The obtained TL model achieves an 1.01% overall error for a broad range of operating conditions, using for retraining only two experimental ageing tests of LiFePO4/C cells.

Image-Based Identification and Genomic Analysis of Single Circulating Tumor Cells in High Grade Serous Ovarian Cancer Patients

In Ovarian Cancer (OC), the analysis of single circulating tumor cells (sCTCs) might help to investigate genetic tumor evolution during the course of treatment. Since common CTC identification features failed to reliably detect CTCs in OC, we here present a workflow for their detection and genomic analysis. Blood of 13 high-grade serous primary OC patients was analyzed, using negative immunomagnetic enrichment, followed by immunofluorescence staining and imaging for Hoechst, ERCC1, CD45, CD11b and cytokeratin (CK) and sCTC sorting with the DEPArrayTM NxT. The whole genome of single cells was amplified and profiled for copy number variation (CNV). We detected: Type A-cells, epithelial (Hoechstpos, ERCC1pos, CD45neg, CD11bpos, CKpos); Type B-cells, potentially epithelial (Hoechstpos, ERCC1pos, CD45neg, CD11bpos, CKneg) and Type C-cells, potentially mesenchymal (Hoechstpos, ERCC1pos, CD45neg, CD11bneg, CKneg). In total, we identified five (38.5%) patients harboring sCTCs with an altered CN profile, which were mainly Type A-cells (80%). In addition to inter-and intra-patient genomic heterogeneity, high numbers of Type B- and C-cells were identified in every patient with their aberrant character only confirmed in 6.25% and 4.76% of cases. Further identification markers and studies in the course of treatment are under way to expand sCTC analysis for the identification of tumor evolution in OC.

Single-cell analyses unravel cell type–specific responses to a vitamin D analog in prostatic precancerous lesions

Epidemiological data have linked vitamin D deficiency to the onset and severity of various cancers, including prostate cancer, and although in vitro studies have demonstrated anticancer activities for vitamin D, clinical trials provided conflicting results. To determine the impact of vitamin D signaling on prostatic precancerous lesions, we treated genetically engineered Pten(i)pe−/− mice harboring prostatic intraepithelial neoplasia (PIN) with Gemini-72, a vitamin D analog with reported anticancer activities. We show that this analog induces apoptosis in senescent PINs, normalizes extracellular matrix remodeling by stromal fibroblasts, and reduces the prostatic infiltration of immunosuppressive myeloid-derived suppressor cells. Moreover, single-cell RNA-sequencing analysis demonstrates that while a subset of luminal cells expressing Krt8, Krt4, and Tacstd2 (termed luminal-C cells) is lost by such a treatment, antiapoptotic pathways are induced in persistent luminal-C cells. Therefore, our findings delineate the distinct responses of PINs and the microenvironment to Gemini-72, and shed light on mechanisms that limit treatment’s efficacy.

A Review of the Significance in Measuring Preoperative and Postoperative Carcinoembryonic Antigen (CEA) Values in Patients with Medullary Thyroid Carcinoma (MTC)

Background and Objectives: Medullary thyroid carcinoma (MTC) accounts for 1–2% of all thyroid malignancies, and it originates from parafollicular “C” cells. Carcinoembryonic antigen (CEA) is a tumor marker, mainly for gastrointestinal malignancies. There are references in literature where elevated CEA levels may be the first finding in MTC. The aim of this study is to determine the importance of measuring preoperative and postoperative CEA values in patients with MTC and to define the clinical significance of the correlation between CEA and the origin of C cells. Materials and Methods: The existing and relevant literature was reviewed by searching for articles and specific keywords in the scientific databases of PubMedCentraland Google Scholar (till December 2020). Results: CEA has found its place, especially at the preoperative level, in the diagnostic approach of MTC. Preoperative CEA values >30 ng/mL indicate extra-thyroid disease, while CEA values >100 ng/mL are associated with lymph node involvement and distant metastases. The increase in CEA values preoperatively is associated with larger size of primary tumor, presence of lymph nodes, distant metastases and a poorer prognosis. The clinical significance of CEA values for the surgeon is the optimal planning of surgical treatment. In the recent literature, C cells seem to originate from the endoderm of the primitive anterior gut at the ultimobranchial bodies’ level. Conclusions: Although CEA is not a specific biomarker of the disease in MTC, itsmeasurement is useful in assessing the progression of the disease. The embryonic origin of C cells could explain the increased CEA values in MTC.