Andrea Quaiser

Clinical Grade Purification and Expansion of NK Cell Products for an Optimized Manufacturing Protocol

Allogeneic natural killer (NK) cells are used for adoptive immunotherapy after stem cell transplantation. In order to overcome technical limitations in NK cell purification and activation, the following study investigates the impact of different variables on NK cell recovery, cytotoxicity, and T-cell depletion during good manufacturing practice (GMP)-grade NK cell selection. Forty NK cell products were derived from 54 unstimulated donor leukaphereses using immunomagnetic CD3 T-cell depletion, followed by a CD56 cell enrichment step. For T-cell depletion, either the depletion 2.1 program in single or double procedure (D2.11depl, n = 18; D2.12depl, n = 13) or the faster depletion 3.1 (D3.1, n = 9) was used on the CliniMACS instrument. Seventeen purified NK cell products were activated in vitro by IL-2 for 12 days. The whole process resulted in a median number of 7.59 × 108 CD56+CD3− cells with both purity and viability of 94%, respectively. The T-cell depletion was significantly better using D2.11depl/2depl compared to D3.1 (log 4.6/log 4.9 vs. log 3.7; p < 0.01) and double procedure in two stages led always to residual T cells below 0.1%. In contrast D3.1 was superior to D2.11depl/2depl with regard to recovery of CD56+CD3− NK cells (68% vs. 41%/38%). Concomitant monocytes and especially IL-2 activation led to increased NK cell activity against malignant target cells compared to unstimulated NK cells, which correlated with both up-regulation of natural cytotoxicity receptors and intracellular signaling. Overall, wide variations in the NK cell expansion rate and the distribution of NK cell subpopulations were found. In conclusion, our results indicate that GMP-grade purification of NK cells might be improved by a sequential processing of T-cell depletion program D2.1 and D3.1. In addition NK cell expansion protocols need to be further optimized.

Advanced flowcytometric analysis of regulatory T cells: CD127 downregulation early post stem cell transplantation and altered Treg/CD3+CD4+-ratio in severe GvHD or relapse

Regulatory T cells (Tregs) are of crucial importance to suppress graft versus host disease (GvHD) post allogeneic stem cell transplantation (SCT), but are also known to impair antitumor immunity. However, Treg longitudinal studies are rare and in this respect advanced flowcytometric approaches for Treg characterization are necessary. To investigate the relation of both the percentage and the absolute numbers of Tregs on GvHD or relapse we measured CD4(+)CD25(+/hi)CD127(lo/-) Tregs in 239 peripheral blood (PB) samples of 16 patients during the first two years post-SCT. A 10-color flowcytometric panel was established to evaluate Treg subpopulations and has been tested in ten healthy individuals. In patients we demonstrated a decrease in CD127 expression on T cells early post-SCT which increases during the first year. Moreover, Tregs reached higher absolute numbers in patients with GvHD≤grade I compared to those with GvHD grades II-IV. In contrast, the percentage of Tregs was significantly higher in patients with GvHD grades II-IV or disease relapse compared to those without GvHD. These patients fit into the range of healthy individuals where a median value of 7.5% and 6.4% of T helper cells were characterized as CD4(+)CD25(+/hi)CD127(lo/-) and CD4(+)CD25(+/hi) Tregs, respectively. Furthermore, Tregs could be further subdivided into 40% naïve, 51% central memory and 9% effector memory Tregs. Our results showed for the first time a downregulation of CD127 expression on T cells including Tregs in patients early post-SCT. Additionally, new insights into the recovery of Tregs regarding GvHD and relapse were provided.

Automated Enrichment, Transduction, and Expansion of Clinical-Scale CD62L+ T Cells for Manufacturing of Gene Therapy Medicinal Products

Multiple clinical studies have demonstrated that adaptive immunotherapy using redirected T cells against advanced cancer has led to promising results with improved patient survival. The continuously increasing interest in those advanced gene therapy medicinal products (GTMPs) leads to a manufacturing challenge regarding automation, process robustness, and cell storage. Therefore, this study addresses the proof of principle in clinical-scale selection, stimulation, transduction, and expansion of T cells using the automated closed CliniMACS® Prodigy system. Naïve and central memory T cells from apheresis products were first immunomagnetically enriched using anti-CD62L magnetic beads and further processed freshly (n = 3) or split for cryopreservation and processed after thawing (n = 1). Starting with 0.5 × 108 purified CD3+ T cells, three mock runs and one run including transduction with green fluorescent protein (GFP)-containing vector resulted in a median final cell product of 16 × 108 T cells (32-fold expansion) up to harvesting after 2 weeks. Expression of CD62L was downregulated on T cells after thawing, which led to the decision to purify CD62L+CD3+ T cells freshly with cryopreservation thereafter. Most important in the split product, a very similar expansion curve was reached comparing the overall freshly CD62L selected cells with those after thawing, which could be demonstrated in the T cell subpopulations as well by showing a nearly identical conversion of the CD4/CD8 ratio. In the GFP run, the transduction efficacy was 83%. In-process control also demonstrated sufficient glucose levels during automated feeding and medium removal. The robustness of the process and the constant quality of the final product in a closed and automated system give rise to improve harmonized manufacturing protocols for engineered T cells in future gene therapy studies.

Optimization of individualized graft composition: CD3/CD19 depletion combined with CD34 selection for haploidentical transplantation

Excessive T‐cell depletion (TCD) is a prerequisite for graft manufacturing in haploidentical stem cell (SC) transplantation by using either CD34 selection or direct TCD such as CD3/CD19 depletion.

Automated enrichment, transduction and expansion of clinical-scale CD62L+ T cells for manufacturing of GTMPs.

Multiple clinical studies have demonstrated that adaptive immunotherapy using redirected T cells against advanced cancer has led to promising results with improved patient survival. The continuously increasing interest in those advanced gene therapy medicinal products (GTMPs) leads to a manufacturing challenge regarding automation, process robustness, and cell storage. Therefore, this study addresses the proof of principle in clinical-scale selection, stimulation, transduction, and expansion of T cells using the automated closed CliniMACS® Prodigy system. Naïve and central memory T cells from apheresis products were first immunomagnetically enriched using anti-CD62L magnetic beads and further processed freshly (n = 3) or split for cryopreservation and processed after thawing (n = 1). Starting with 0.5 × 108 purified CD3+ T cells, three mock runs and one run including transduction with green fluorescent protein (GFP)-containing vector resulted in a median final cell product of 16 × 108 T cells (32-fold expansion) up to harvesting after 2 weeks. Expression of CD62L was downregulated on T cells after thawing, which led to the decision to purify CD62L+CD3+ T cells freshly with cryopreservation thereafter. Most important in the split product, a very similar expansion curve was reached comparing the overall freshly CD62L selected cells with those after thawing, which could be demonstrated in the T cell subpopulations as well by showing a nearly identical conversion of the CD4/CD8 ratio. In the GFP run, the transduction efficacy was 83%. In-process control also demonstrated sufficient glucose levels during automated feeding and medium removal. The robustness of the process and the constant quality of the final product in a closed and automated system give rise to improve harmonized manufacturing protocols for engineered T cells in future gene therapy studies.

Percentiles of Lymphocyte Subsets in Preterm Infants According to Gestational Age Compared to Children and Adolescents.

Preterm newborns show an increased susceptibility to infections, conceivably related to their immature immune system. To gain further knowledge about the immune development in early preterm infants, we aimed to establish references for lymphocyte subsets and compare the maturation process during hospitalization to healthy term‐born children and adolescents. For this purpose, peripheral blood samples (n = 153) were collected from 40 preterm infants, gestational age (GA) 26–30 week between 2nd and 6th day of life, and were monitored in intervals of every 2 or rather 4 weeks until the end of hospitalization. Furthermore, we analysed single sample controls of 10 term neonates. We compared these data with results of a study in healthy children and adolescent (n = 176). Flow cytometry of immune cell subsets was performed as single‐platform analysis using 10‐colour flow cytometry. Based on preterms age, our percentile model allows readout of absolute cell count for lymphocytes, B cells, T cells, NK cells, T8 and T4 cells. The median (minimum) value of T‐, B‐ and NK cells after birth was 2800 (600), 790 (120) and 140 (20) cells/μl, respectively. Major differences were found in absolute cell numbers of B cells, and in the frequency of regulatory T cells, most pronounced in the earliest preterm infants (GA 26). Compared to healthy children and adolescents, preterm infants reached lymphocyte counts in between the 5th and 50th percentile when discharging the hospital. This prospective observational study provides reference percentiles for lymphocytes subsets of preterm infants. These data are conducive to interpret immunological capability of preterm infants with possible immune disorders appropriate.

An Exponential Regression Model Reveals the Continuous Development of B Cell Subpopulations Used as Reference Values in Children

B lymphocytes are key players in humoral immunity, expressing diverse surface immunoglobulin receptors directed against specific antigenic epitopes. The development and profile of distinct subpopulations have gained awareness in the setting of primary immunodeficiency disorders, primary or secondary autoimmunity and as therapeutic targets of specific antibodies in various diseases. The major B cell subpopulations in peripheral blood include naïve (CD19+ or CD20+IgD+CD27−), non-switched memory (CD19+ or CD20+IgD+CD27+) and switched memory B cells (CD19+ or CD20+IgD−CD27+). Furthermore, less common B cell subpopulations have also been described as having a role in the suppressive capacity of B cells to maintain self-tolerance. Data on reference values for B cell subpopulations are limited and only available for older age groups, neglecting the continuous process of human B cell development in children and adolescents. This study was designed to establish an exponential regression model to produce continuous reference values for main B cell subpopulations to reflect the dynamic maturation of the human immune system in healthy children.