Siplizumab combination therapy with belatacept or abatacept broadly inhibits human T cell alloreactivity in vitro.

Combined antigen-specific T cell receptor stimulation and costimulation are needed for complete T cell activation. Belatacept and abatacept are nondepleting fusion proteins blocking CD28/B7 costimulation, whereas siplizumab is a depleting antiCD2 immunoglobulin G1 monoclonal antibody targeting CD2/CD58 costimulation. Herein, the effect of siplizumab combination therapy with abatacept or belatacept on T cell alloreactivity in mixed lymphocyte reactions was investigated. In contrast to monotherapy, the combination of siplizumab with belatacept or abatacept induced near-complete suppression of T cell proliferation and increased the potency of siplizumab-mediated T cell inhibition. Furthermore, dual targeting of CD2 and CD28 costimulation enhanced the selective depletion of memory T cells compared with monotherapy. Although siplizumab monotherapy leads to significant regulatory T cell enrichment, high doses of cytotoxic T-lymphocyte-associated antigen 4 and a human IgG1 Fc fragment in the combination therapy reduced this effect. These results support the clinical evaluation of dual costimulation blockade, combining siplizumab with abatacept or belatacept, for the prophylaxis of organ transplant rejection and improvement of long-term outcomes following transplantation. Ongoing investigative research will elucidate when other forms of siplizumab-based dual costimulatory blockade may be able to induce similarly strong inhibition of T cell activation although still allowing for enrichment of regulatory T cells.

Enhanced metabolism and negative regulation of ER stress support higher erythropoietin production in HEK293 cells.

Recombinant protein production can cause severe stress on cellular metabolism, resulting in limited titer and product quality. To investigate cellular and metabolic characteristics associated with these limitations, we compare HEK293 clones producing either erythropoietin (EPO) (secretory) or GFP (non-secretory) protein at different rates. Transcriptomic and functional analyses indicate significantly higher metabolism and oxidative phosphorylation in EPO producers compared with parental and GFP cells. In addition, ribosomal genes exhibit specific expression patterns depending on the recombinant protein and the production rate. In a clone displaying a dramatically increased EPO secretion, we detect higher gene expression related to negative regulation of endoplasmic reticulum (ER) stress, including upregulation of ATF6B, which aids EPO production in a subset of clones by overexpression or small interfering RNA (siRNA) knockdown. Our results offer potential target pathways and genes for further development of the secretory power in mammalian cell factories.

Harnessing secretory pathway differences between HEK293 and CHO to rescue production of difficult to express proteins.

Biologics represent the fastest growing group of therapeutics, but many advanced recombinant protein moieties remain difficult to produce. Here, we identify metabolic engineering targets limiting expression of recombinant human proteins through a systems biology analysis of the transcriptomes of CHO and HEK293 during recombinant expression. In an expression comparison of 24 difficult to express proteins, one third of the challenging human proteins displayed improved secretion upon host cell swapping from CHO to HEK293. Guided by a comprehensive transcriptomics comparison between cell lines, especially highlighting differences in secretory pathway utilization, a co-expression screening of 21 secretory pathway components validated ATF4, SRP9, JUN, PDIA3 and HSPA8 as productivity boosters in CHO. Moreover, more heavily glycosylated products benefitted more from the elevated activities of the N- and O-glycosyltransferases found in HEK293. Collectively, our results demonstrate the utilization of HEK293 for expression rescue of human proteins and suggest a methodology for identification of secretory pathway components for metabolic engineering of HEK293 and CHO.

NET-producing CD16high CD62Ldim neutrophils migrate to tumor sites and predict improved survival in patients with HNSCC.

The concept of functional neutrophil subsets is new and their clinical significance in malignancies is unknown. Our study investigated the role of CD16dim CD62Lhigh , CD16high CD62Lhigh and CD16high CD62Ldim neutrophil subsets in head and neck squamous cell carcinoma (HNSCC) patients. These neutrophil subsets may play different roles in immune-related activity in cancer, based on their profile, activation state and migration ability within a tumor site, which may be important in predicting cancer prognoses. Tumor biopsies and blood were obtained from newly diagnosed untreated HNSCC patients and healthy controls. Neutrophil subsets and their phenotype were characterized using flow cytometry. Isolated granulocytes were assessed for anti-tumor immune functions. Compared to controls HNSCC patients exhibited increased CD16high CD62Ldim neutrophils in blood; this subset displayed a distinct phenotypes with high expression of CD11b and CD18. This subset was prone to migrate into the tumor facilitated by tumor-derived IL-8. Furthermore, IL-8 was also found to activate neutrophils and thereby promoting subset transition. Various assays demonstrated that activated CD16high CD62Ldim neutrophils inhibited migration, proliferation and induced apoptosis of FaDu cancer cells. Neutrophil elastase detected in activated CD16high CD62Ldim neutrophils and tumor biopsies suggested that CD16high CD62Ldim neutrophils impart anti-tumoral activity via neutrophil extracellular traps. Furthermore, increased fraction of CD16high CD62Ldim neutrophils was shown to correlate with an increased survival rate. Our study demonstrates the clinical relevance of the CD16high CD62Ldim neutrophil subset, providing evidence for its increased migration capacity, its anti-tumor activity including increased NET formation and finally its correlation with increased survival in HNSCC patients.