Increased microRNA-323-3p in IL-22/IL-17-producing T cells and asthma: a role in the regulation of the TGF-ß pathway and IL-22 production.

BACKGROUND: IL-22- and IL-17-producing T cells have important roles in allergic diseases. MicroRNAs (miRNAs) are posttranscriptional regulators of gene expression and modulate numerous biological processes. Little is known about the functions of miRNAs in IL-22/IL-17-producing T cells. MATERIAL AND METHODS: IL-22- and IL-17-positive T cells were sorted from human peripheral blood mononuclear cells (PBMCs) by intracellular staining and dual-secretion assay. miRNA expression profiles were detected with TaqMan array microfluidic cards. T cells were transfected with miRNA mimics. Gene expression was analyzed using RT-qPCR and/or enzyme-linked immunosorbent assay in T-cell subsets and PBMCs from patients with asthma and atopic dermatitis. RESULTS: The increased expression of miR-323-3p and noncoding RNA nc886 and reduced expression of miR-93, miR-181a, miR-26a, and miR-874 were detected in IL-22-producing T cells. The pathway analysis of the putative targets suggested that these differentially expressed miRNAs could impact the proliferation, differentiation, and effector functions of T cells. Further analyses showed the highest expression for miR-323-3p in IL-22- and IL-17-double-positive T cells and its capacity to suppress multiple genes from the transforming growth factor-ß pathway and the production of IL-22 in T cells. An increased expression of miR-323-3p in PBMCs from patients with asthma and reverse correlation between miR-323-3p levels and IL-22 production in PBMCs cultured in T-cell growth conditions was observed. CONCLUSIONS: Our data suggest that miR-323-3p acts in a negative feedback loop to control the production of IL-22 in IL-22/IL-17-producing T cells and might thus impact the T-cell responses in asthma.

PTPN22 gene regulates natural killer cell proliferation during in vitro expansion.

The protein tyrosine phosphatase nonreceptor type 22 (PTPN22) gene is expressed in hematopoietic tissue and peripheral blood mononuclear cells including natural killer (NK) cells. The rs2476601 single nucleotide polymorphism (SNP) in the PTPN22 gene is an important susceptibility marker for autoimmunity but its role in NK cell biology is not yet clear. The aim of the current study was to evaluate in a cohort of healthy individuals, whether allelic variants of the rs2476601 SNP are associated with NK cell expansion in vitro. The CT genotype of the rs2476601 SNP was significantly (P = 0.0013) associated with reduced NK cell CD3(-) CD56(+) fraction in culture. The current study shows that the T variant of the rs2476601 SNP could alter NK vs T-cell balance in vitro and suggests that the PTPN22 gene might have an important immune regulatory role in NK cell function which needs further investigation.

Long-term follow-up of gene-marked CD34+ cells after autologous stem cell transplantation for multiple myeloma.

Gene marking can be used to investigate if progenitor cells harvested from patients are contaminated with tumorigenic cells. It can also provide information about the contribution of hematopoietic stem cells to long-term engraftment and about long-term transgene expression from integrated retroviral vectors. In order to study autologous-infused cell contribution to relapse as well as the long-term persistence of the transgene in hematopoietic cells following autologous bone marrow (BM) transplantation for multiple myeloma, we genetically marked autologous CD34+ enriched BM or peripheral blood cell grafts of eight myeloma patients using retroviral vectors. Six patients were subsequently transplanted with the marked graft and followed with regular time points of analysis. Briefly, mononuclear cells were harvested by leukapheresis during 2-4 consecutive days following priming with granulocyte-macrophage colony-stimulating factor (GM-CSF) or G-CSF. The CD34+ cells separated on Cellpro ceprate avidin-biotin columns were exposed to the G1Na vector coding for neomycin resistance gene at a ratio of five vector particles per cell at three consecutive time points achieving an average transduction efficacy of 2% (0.43-5.1%). The patients were transplanted with a mixture of transduced cells and un-manipulated graft. Vector integration and transgene expression were analyzed by colony assays and polymerase chain reaction. The transgene could be detected for up to 5 years post-transplant in normal BM cells, even in remission following relapse and no side effects related to retroviral gene transfer were observed. There were no marked myeloma cells observed in the patients either in remission or in relapsing disease, which indicates that contribution of infused cells to relapse is unlikely.

OuaSelect, a novel ouabain-resistant human marker gene that allows efficient cell selection within 48 h.

Efficient selection of gene-modified cells is required for a number of potential gene therapy applications, as well as molecular biology studies. Ideally, a clinical selection regimen would combine high selection speed, efficiency and efficacy, in addition to clinical grade selection techniques and low immunogenicity. To our knowledge, a selection marker satisfying all these features is so far not available. Ouabain is a clinically used cardiac glycoside and selective Na(+)/K(+)-ATPase inhibitor. On the basis of the high sensitivity of human Na(+)/K(+)-ATPase proteins to ouabain, and rapid killing of cells upon exposure, we have screened the ubiquitously expressed Na(+)/K(+)-ATPase alpha1 subunit for mutations that could greatly increase its resistance to ouabain. Two amino-acid substitutions, Q118R and N129D were sufficient to confer a two log greater resistance to ouabain in HeLa, Jurkat, U2OS cells and in primary cells. Furthermore, following transduction of primary lymphocytes with the alpha1(Q118R/N129D) gene, >99% pure populations of gene-modified cells were achieved with a recovery rate of >80% after 48 h of exposure to ouabain. These results identify the human alpha1(Q118R/N129D) (OuaSelect) as a promising selection marker gene for safe, rapid and cost-effective selection in clinical gene therapy and molecular biology research.

Intercellular spread of GFP-VP22.

BACKGROUND: The herpes simplex virus type 1 (HSV-1) VP22 polypeptide has been reported to mediate intercellular trafficking of heterologous proteins fused to its C- or N-terminus, a feature making it a useful tool in bystander cell-targeted gene therapy. METHODS: Here we show, by detection of Green Fluorescent Protein (GFP) fused to VP22, its subcellular distribution in living producer (transfected) and recipient (non-transfected) cells as well as in cells after fixation. Four cell lines from different species were used. RESULTS: Different fractions of translocated GFP-VP22 fusion protein could be detected in fixed recipient cells by two different methods of fixation. Functional GFP in live recipient cells could not be detected. CONCLUSIONS: Our study indicates that the VP22-chimeric protein transfer in its present form is suboptimal in terms of protein function. However, after fixation, the GFP signal in 100% of cells in a monolayer can be detected even at moderate transfection efficiency.

Mapping of herpes simplex virus-1 VP22 functional domains for inter- and subcellular protein targeting.

The herpes simplex virus 1 (HSV-1) tegument protein VP22 has been utilised as a vehicle for trafficking proteins. It has a remarkable property of exiting the cell that is producing it and entering the neighbouring cells, which has been used to deliver therapeutic proteins, p53 and herpes simplex virus thymidine kinase (tk). It has a complex pattern of expression and subcellular localisation. Functions of VP22 include intercellular transport, binding to and bundling of microfilaments, inducing cytoskeleton collapse, nuclear translocation during mitosis, and binding to chromatin and nuclear membrane. The regions of VP22 which contain each of these functions have not been characterised. Finding the region carrying the property of intercellular spread would facilitate enhancement of transport function. By constructing a series of deletion constructs of VP22 tagged by the green fluorescent protein (GFP) we have mapped the functions of VP22 to specific regions in the polypeptide as follows: intercellular transport - aa 81-195; binding and reorganisation of cytoskeleton - aa 159-267; nuclear targeting, inhibition of cytoskeleton collapse - aa 81-121; and nuclear targeting and facilitation of intercellular transport - aa 267-301. Separation of VP22 functions enables focus on the mechanism of VP22-mediated transport and improve the transportation efficiency of VP22.

Intercellular delivery of thymidine kinase prodrug activating enzyme by the herpes simplex virus protein, VP22.

We demonstrate that fusion proteins consisting of the herpes simplex virus (HSV) transport protein VP22 linked in frame to HSV thymidine kinase (tk) retain the ability to be transported between cells. In vivo radiolabelling experiments and in vitro assays show that the fusion proteins also retain tk activity. When transfected COS cells, acting as a source of the VP22-tk chimera, were co-plated on to gap junction-negative neuroblastoma cells, ganciclovir treatment induced efficient cell death in the recipient neuroblastoma cell monolayer. No such effect was observed with COS cells transfected with tk alone. Tumours established in mice with neuroblastoma cell lines expressing VP22-tk regressed upon administration of ganciclovir. Furthermore tumours established from 50:50 mixtures of VP22-tk transduced and nontransduced cells also regressed while no significant effect was observed in similar experiments with cells transduced with tk alone. VP22 mediated transport may thus have application in a clinical setting to amplify delivery of the target protein in enzyme-prodrug protocols.

Proximal promoter of the murine syndecan-1 gene is not sufficient for the developmental pattern of syndecan expression in B lineage cells.

Syndecan-1 (CD138) is a cell membrane proteoglycan that binds extracellular matrix components and various growth factors. The role of syndecan-1 in the control of cell growth and morphology has been illustrated by its altered expression in hematological malignancies such as multiple myeloma as well as some solid tumors. It has been reported that the expression of syndecan-1 in cells of the B lineage is developmentally regulated such that pre-B cells and plasma cells express syndecan-1 while mature B cells do not. Thus, we investigated whether the proximal promoter region of the murine syndecan-1 promoter was able to confer the observed on-off-on expression of syndecan-1 in cells of the B lineage as they develop from pre-B cells to plasma cells. Experiments carried out using deletion mutants of the proximal promoter cloned upstream of the CAT reporter gene transfected into murine cell lines, representing the above stages of B-cell development, such as BA/F3 (pro-B cell), 70Z/3 (pre-B cell), 2PK3 (late mature B cell), and MPC-11 (plasma cell), showed detectable levels of CAT expression. The WEHI-231 (mature B cell) cell lines did not show detectable levels of CAT reporter activity. The strong levels of expression were observed with a fragment of the proximal promoter spanning the region from -365 to -95 (from the translation start point). However, Northern analysis of RNA obtained from the five murine B-cell lines, representing various stages of B-cell development, showed that the 70Z/3, MPC-11 but not BA/F3, and 2PK3 cells expressed detectable levels of syndecan-1 mRNA. By FACS analysis, using a rat anti mouse syndecan-1 antibody, syndecan-1 expression on the cell surface was found to correlate with the observed mRNA expression patterns in these cell lines. Our results indicate that the proximal promoter of the murine syndecan-1 promoter is not sufficient for the observed developmental pattern of syndecan expression in B cells.