Chimeric antigen receptor (CAR) T cells have shown great promise in the treatment of hematologic malignancies but more variable results in the treatment of solid tumors and the persistence and expansion of CAR T cells within patients has been identified as a key correlate of antitumor efficacy. Lack of immunological "space", functional exhaustion, and deletion have all been proposed as mechanisms that hamper CAR T-cell persistence. Here we describe the events following activation of third-generation CAR T cells specific for GD2. CAR T cells had highly potent immediate effector functions without evidence of functional exhaustion in vitro, although reduced cytokine production reversible by PD-1 blockade was observed after longer-term culture. Significant activation-induced cell death (AICD) of CAR T cells was observed after repeated antigen stimulation, and PD-1 blockade enhanced both CAR T-cell survival and promoted killing of PD-L1(+) tumor cell lines. Finally, we assessed CAR T-cell persistence in patients enrolled in the CARPETS phase 1 clinical trial of GD2-specific CAR T cells in the treatment of metastatic melanoma. Together, these data suggest that deletion also occurs in vivo and that PD-1-targeted combination therapy approaches may be useful to augment CAR T-cell efficacy and persistence in patients.
We have synthesized a series of copolymers containing both positively charged (amine, guanidine) and hydrophobic side chains (amphiphilic antimicrobial peptide mimics). To investigate the structure-activity relationships of these polymers, low polydispersity polymethacrylates of varying but uniform molecular weight and composition were synthesized, using a reversible addition-fragmentation chain transfer (RAFT) approach. In a facile second reaction, pendant amine groups were converted to guanidines, allowing for direct comparison of cation structure on activity and toxicity. The guanidine copolymers were much more active against Staphylococcus epidermidis and Candida albicans compared to the amine analogues. Activity against Staphylococcus epidermidis in the presence of fetal bovine serum was only maintained for guanidine copolymers. Selectivity for bacterial over mammalian cells was assessed using hemolytic and hemagglutination toxicity assays. Guanidine copolymers of low to moderate molecular weight and hydrophobicity had high antimicrobial activity with low toxicity. Optimum properties appear to be a balance between charge density, hydrophobic character, and polymer chain length. In conclusion, a suite of guanidine copolymers has been identified that represent a new class of antimicrobial polymers with high potency and low toxicity.
Regulatory T (Treg) cells facilitate maternal immune tolerance of the semiallogeneic conceptus in early pregnancy, but the origin and regulation of these cells at embryo implantation is unclear. During the preimplantation period, factors in the seminal fluid delivered at coitus cause expansion of a CD4(+)CD25(+) putative Treg cell population in the para-aortic lymph nodes draining the uterus. Using flow cytometry, immunohistochemistry, and real-time quantitative PCR (qPCR) for the signature Treg cell transcription factor FOXP3, we confirmed the identity of the expanded lymph node population as FOXP3(+) Treg cells and showed that this is accompanied by a comparable increase in the uterus of FOXP3(+) Treg cells and expression of Foxp3 mRNA by Day 3.5 postcoitum. Seminal plasma was necessary for uterine Treg cell accumulation, as mating with seminal vesicle-deficient males failed to elicit an increase in uterine Treg cells. Furthermore seminal fluid induced expression of mRNA encoding the Treg chemokine CCL19 (MIP3beta), which acts through the CCR7 receptor to regulate Treg cell recruitment and retention in peripheral tissues. Glandular and luminal epithelial cells were identified as the major cellular origins of uterine CCL19, and exposure to both seminal plasma and sperm was required for maximum expression. Together, these results indicate that Treg cells accumulate in the uterus prior to embryo implantation and that seminal fluid is a key regulator of the uterine Treg cell population, operating by both increasing the pool of available Treg cells and promoting their CCL19-mediated recruitment from the circulation into the implantation site.
Zika and chikungunya viruses have caused major epidemics and are transmitted by Aedes aegypti and/or Aedes albopictus mosquitoes. The “Sementis Copenhagen Vector” (SCV) system is a recently developed vaccinia-based, multiplication-defective, vaccine vector technology that allows manufacture in modified CHO cells. Herein we describe a single-vector construct SCV vaccine that encodes the structural polyprotein cassettes of both Zika and chikungunya viruses from different loci. A single vaccination of mice induces neutralizing antibodies to both viruses in wild-type and IFNAR−/− mice and protects against (i) chikungunya virus viremia and arthritis in wild-type mice, (ii) Zika virus viremia and fetal/placental infection in female IFNAR−/− mice, and (iii) Zika virus viremia and testes infection and pathology in male IFNAR−/− mice. To our knowledge this represents the first single-vector construct, multi-pathogen vaccine encoding large polyproteins, and offers both simplified manufacturing and formulation, and reduced “shot burden” for these often co-circulating arboviruses.
The nature of the
protein corona forming on biomaterial surfaces
can affect the performance of implanted devices. This study investigated
the role of surface chemistry and wettability on human serum-derived
protein corona formation on biomaterial surfaces and the subsequent
effects on the cellular innate immune response. Plasma polymerization,
a substrate-independent technique, was employed to create nanothin
coatings with four specific chemical functionalities and a spectrum
of surface charges and wettability. The amount and type of protein
adsorbed was strongly influenced by surface chemistry and wettability
but did not show any dependence on surface charge. An enhanced adsorption
of the dysopsonin albumin was observed on hydrophilic carboxyl surfaces
while high opsonin IgG2 adsorption was seen on hydrophobic hydrocarbon
surfaces. This in turn led to a distinct immune response from macrophages;
hydrophilic surfaces drove greater expression of anti-inflammatory
cytokines by macrophages, whilst surface hydrophobicity caused increased
production of proinflammatory signaling molecules. These findings
map out a unique relationship between surface chemistry, hydrophobicity,
protein corona formation, and subsequent cellular innate immune responses;
the potential outcomes of these studies may be employed to tailor
biomaterial surface modifications, to modulate serum protein adsorption
and to achieve the desirable innate immune response to implanted biomaterials
and devices.
Synthetic materials employed for enhancing, replacing, or restoring biological functionality may be compromised by the host immune responses that they evoke. Surface modification has attracted substantial attention as a tool to modulate the host response to synthetic materials; however, how surface nanotopography combined with chemistry affects immune effector cell responses is still poorly understood. To address this open question, a unique set of model surfaces with controlled surface nanotopography in the range of 16, 38, and 68 nm has been generated. Tailored outermost surface chemistry that was amine, carboxyl, or methyl group rich has been provided. The combinations of these properties yield 12 surface types that are subject to functional assays assessing key immune effector cells, namely, primary neutrophil and macrophage responses in vitro. The data demonstrate that surface nanotopography leads to enhanced matrix metalloproteinase-9 production from primary neutrophils, and a decrease in pro-inflammatory cytokine secretion from primary macrophages. Together, these results are the first to directly compare the immunomodulatory effects of the cooperative interplay between surface nanotopography and chemistry.
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