Thomas Matthes

APRIL secreted by neutrophils binds to heparan sulfate proteoglycans to create plasma cell niches in human mucosa

The bone marrow constitutes a favorable environment for long-lived antibody-secreting plasma cells, providing blood-circulating antibody. Plasma cells are also present in mucosa-associated lymphoid tissue (MALT) to mediate local frontline immunity, but how plasma cell survival there is regulated is not known. Here we report that a proliferation-inducing ligand (APRIL) promoted survival of human upper and lower MALT plasma cells by upregulating expression of the antiapoptotic proteins bcl-2, bcl-xL, and mcl-1. The in situ localization of APRIL was consistent with such a prosurvival role in MALT. In upper MALT, tonsillar epithelium produced APRIL. Upon infection, APRIL production increased considerably when APRIL-secreting neutrophils recruited from the blood infiltrated the crypt epithelium. Heparan sulfate proteoglycans (HSPGs) retained secreted APRIL in the subepithelium of the infected zone to create APRIL-rich niches, wherein IgG-producing plasma cells accumulated. In lower MALT, neutrophils were the unique source of APRIL, giving rise to similar niches for IgA-producing plasmocytes in villi of lamina propria. Furthermore, we found that mucosal humoral immunity in APRIL-deficient mice is less persistent than in WT mice. Hence, production of APRIL by inflammation-recruited neutrophils may create plasma cell niches in MALT to sustain a local antibody production.

Expression profiling of human immune cell subsets identifies miRNA-mRNA regulatory relationships correlated with cell type specific expression

Blood consists of different cell populations with distinct functions and correspondingly, distinct gene expression profiles. In this study, global miRNA expression profiling was performed across a panel of nine human immune cell subsets (neutrophils, eosinophils, monocytes, B cells, NK cells, CD4 T cells, CD8 T cells, mDCs and pDCs) to identify cell-type specific miRNAs. mRNA expression profiling was performed on the same samples to determine if miRNAs specific to certain cell types down-regulated expression levels of their target genes. Six cell-type specific miRNAs (miR-143; neutrophil specific, miR-125; T cells and neutrophil specific, miR-500; monocyte and pDC specific, miR-150; lymphoid cell specific, miR-652 and miR-223; both myeloid cell specific) were negatively correlated with expression of their predicted target genes. These results were further validated using an independent cohort where similar immune cell subsets were isolated and profiled for both miRNA and mRNA expression. miRNAs which negatively correlated with target gene expression in both cohorts were identified as candidates for miRNA/mRNA regulatory pairs and were used to construct a cell-type specific regulatory network. miRNA/mRNA pairs formed two distinct clusters in the network corresponding to myeloid (nine miRNAs) and lymphoid lineages (two miRNAs). Several myeloid specific miRNAs targeted common genes including ABL2, EIF4A2, EPC1 and INO80D; these common targets were enriched for genes involved in the regulation of gene expression (p<9.0E-7). Those miRNA might therefore have significant further effect on gene expression by repressing the expression of genes involved in transcriptional regulation. The miRNA and mRNA expression profiles reported in this study form a comprehensive transcriptome database of various human blood cells and serve as a valuable resource for elucidating the role of miRNA mediated regulation in the establishment of immune cell identity.

Activation of the aryl hydrocarbon receptor reveals distinct requirements for IL-22 and IL-17 production by human T helper cells

Ligands of the aryl hydrocarbon receptor (AHR), a transcription factor mediating the effects of dioxin, favor Th17 differentiation and exacerbate autoimmunity in mice. We investigated how AHR ligands affected human T‐cell polarization. We found that the high affinity and stable AHR‐ligand dioxin as well as the natural AHR‐ligand 6‐formylinolo[3,2‐b] carbazole induced the downstream AHR‐target cytochrome P450A1, and without affecting IFN‐γ, they enhanced IL‐22 while simultaneously decreasing IL‐17A production by CD4+ T cells. The specific AHR‐inhibitor CH‐223191 abolished these effects. Furthermore, blockade of IL‐23 and IL‐1, important for Th17 expansion, profoundly decreased IL‐17A but not IL‐22 production. AHR agonists reduced the expression of the Th17 master transcription factor retinoic acid‐related orphan receptor C (RORC), without affecting T‐bet, GATA‐3 and Foxp3. They also decreased the expression of the IL‐23 receptor. Importantly, AHR‐ligation did not only decrease the number of Th17 cells but also primed naïve CD4+ T cells to produce IL‐22 without IL‐17 and IFN‐γ. Furthermore, IL‐22 single producers did not express CD161, which distinguished them from the CD161+ Th17 cells. Hence, our data provide compelling evidence that AHR activation participates in shaping human CD4+ T‐cell polarization favoring the emergence of a distinct subset of IL‐22‐producing cells that are independent from the Th17 lineage.

Growth differentiation factor 15 production is necessary for normal erythroid differentiation and is increased in refractory anaemia with ring-sideroblasts

The disturbed erythropoiesis in patients with refractory anaemia with ring‐sideroblasts (RARS) is characterized by intramedullary apoptosis of erythroid precursors and increased iron accumulation in mitochondria. To gain insight into these pathophysiological mechanisms we compared the gene expression profile (GEP) of erythroid precursors from RARS patients to the GEP of normal erythroid precursors. Three hundred sixty four probe sets were up‐, and 253 probe sets downregulated in RARS cells. Interestingly, Growth Differentiation factor 15 (GDF15), a cytokine from the TGFβ family, was dramatically upregulated in all RARS patients. Measurement of GDF15 in the sera from twenty RARS patients confirmed this finding by showing significantly, 7·2‐fold, increased protein levels (3254 ± 1400 ng/ml vs. 451 ± 87 ng/ml in normals). In vitro studies demonstrated erythroid‐specific production of GDF15 and dependence on erythropoietin. Induction of apoptosis by arsenic trioxide, a drug which acts via reduction of the mitochondrial membrane potential, also stimulated GDF15 production. Downregulation of endogenous GDF15 production in erythoblasts by specific siRNA led to diminished erythroid differentiation. Taken together, our findings demonstrate a new role for GDF15 in normal erythropoiesis as well as in the ineffective erythropoiesis of RARS patients.

Production of the plasma-cell survival factor a proliferation-inducing ligand (APRIL) peaks in myeloid precursor cells from human bone marrow

The bone marrow (BM) is an organ extremely efficient in mediating long-term survival of plasma cells (PCs), ensuring an immune humoral memory. This implies that the BM must provide continuously key PC survival factors. Our results show that the BM is an organ constitutively rich in a proliferation-inducing ligand (APRIL), a member of the tumor necrosis factor superfamily implicated in PC survival. APRIL production is induced during hematopoiesis in myeloid cells by non-lineage-committing factors such as stem cell factor, thrombopoietin, IL-3, and FMS-like tyrosine kinase 3 ligand. Notably, APRIL production, both in the human and mouse systems, peaks in myeloid precursor cells, before dropping in fully mature granulocytes. Myeloid cells secrete APRIL that circulates freely in BM plasma to act on PCs, usually at distance from APRIL production sites. Selective APRIL in vivo antagonism and in vitro coculture experiments further demonstrated that myeloid precursor cells mediates PC survival in an APRIL-dependent manner Thus, APRIL production by myeloid precursor cells shows that the 2 main BM functions, hematopoiesis and long-term PC survival, are linked. Such constitutive and high APRIL production may explain why BM mediates long-term PC survival.

Sideroblastic anemia: molecular analysis of the ALAS2 gene in a series of 29 probands and functional studies of 10 missense mutations.

X‐linked Sideroblastic Anemia (XLSA) is the most common genetic form of sideroblastic anemia, a heterogeneous group of disorders characterized by iron deposits in the mitochondria of erythroid precursors. XLSA is due to mutations in the erythroid‐specific 5‐aminolevulinate synthase (ALAS2) gene. Thirteen different ALAS2 mutations were identified in 16 out of 29 probands with sideroblastic anemia. One third of the patients were females with a highly skewed X‐chromosome inactivation. The identification of seven novel mutations in the ALAS2 gene, six missense mutations, and one deletion in the proximal promoter extends the allelic heterogeneity of XSLA. Most of the missense mutations were predicted to be deleterious, and 10 of them, without any published functional characterization, were expressed in Escherichia coli. ALAS2 activities were assayed in vitro. Five missense mutations resulted in decreased enzymatic activity under standard conditions, and two other mutated proteins had decreased activity when assayed in the absence of exogenous pyridoxal phosphate and increased thermosensitivity. Although most amino acid substitutions result in a clearly decreased enzymatic activity in vitro, a few mutations have a more subtle effect on the protein that is only revealed by in vitro tests under specific conditions. Hum Mutat 32:1–8, 2011.

Missense SLC25A38 variations play an important role in autosomal recessive inherited sideroblastic anemia

Background Congenital sideroblastic anemias are rare disorders with several genetic causes; they are characterized by erythroblast mitochondrial iron overload, differ greatly in severity and some occur within a syndrome. The most common cause of non-syndromic, microcytic sideroblastic anemia is a defect in the X-linked 5-aminolevulinate synthase 2 gene but this is not always present. Recently, variations in the gene for the mitochondrial carrier SLC25A38 were reported to cause a non-syndromic, severe type of autosomal-recessive sideroblastic anemia. Further evaluation of the importance of this gene was required to estimate the proportion of patients affected and to gain further insight into the range and types of variations involved. Design and Methods In three European diagnostic laboratories sequence analysis of SLC25A38 was performed on DNA from patients affected by congenital sideroblastic anemia of a non-syndromic nature not caused by variations in the 5-aminolevulinate synthase 2 gene. Results Eleven patients whose ancestral origins spread across several continents were homozygous or compound heterozygous for ten different SLC25A38 variations causing premature termination of translation (p.Arg117X, p.Tyr109LeufsX43), predicted splicing alteration (c.625G>C; p.Asp209His) or missense substitution (p.Gln56Lys, p.Arg134Cys, p.Ile147Asn, p.Arg187Gln, p.Pro190Arg, p.Gly228Val, p.Arg278Gly). Only three of these variations have been described previously (p.Arg117X, p.Tyr109LeufsX43 and p.Asp209His). All new variants reported here are missense and affect conserved amino acids. Structure modeling suggests that these variants may influence different aspects of transport as described for mutations in other mitochondrial carrier disorders. Conclusions Mutations in the SLC25A38 gene cause severe, non-syndromic, microcytic/hypochromic sideroblastic anemia in many populations. Missense mutations are shown to be of importance as are mutations that affect protein production. Further investigation of these mutations should shed light on structure-function relationships in this protein.

Increased apoptosis in acquired sideroblastic anaemia

Idiopathic acquired sideroblastic anaemias (IASAs) form a subgroup of the myelodysplastic syndromes and are characterized by mitochondrial iron accumulation, bone marrow erythroid hyperplasia and decreased peripheral red blood cell counts. Increased intramedullary apoptosis of erythroid precursors is presumed to constitute the pathophysiological mechanism explaining this ineffective erythropoiesis, but if and how mitochondrial dysfunction is implicated in this process is currently unknown. We therefore studied bone marrow precursor cells obtained from nine patients with IASA for (i) caspase 3 activity, (ii) numbers of Annexin V‐ and 7‐amino‐actinomycin‐positive cells, (iii) numbers of cells with diminished mitochondrial membrane potential, ΔΨm, and (iv) numbers of cells producing reactive oxygen species (ROS), and we compared the results with those of five normal bone marrow samples. Compared with controls, we found increased caspase 3 activity in all IASA samples, which correlated with increased numbers of Annexin‐V‐positive cells (r = 0·7). Analysis of different subpopulations showed increased apoptosis in erythroid populations compared with myeloid and/or lymphoid populations in five out of nine cases, and increased apoptosis in the last two populations in four out of nine cases. As evidence of mitochondrial dysfunction, ΔΨm was found to be diminished in the erythroid subpopulations of all cases of IASA (66·6 ± 17% vs. 34·6 ± 12% in normals). ΔΨm decrease was correlated to Annexin V positivity (r = 0·7). Astonishingly, no difference was found between IASA and normal bone marrows with regard to the number of ROS‐producing cells. In fact, both groups exhibited a similar low proportion of ROS production (10·3 ± 7% in normals vs. 6·8 ± 5% in IASA). Taken together, our results show that mitochondria are clearly implicated in the apoptotic process in IASA patients. Whether this is a result of an intramitochondrial defect (e.g. Fe accumulation, secondary to mitochondrial or nuclear DNA mutations) or is secondary to an extracellular stimulus [e.g. tumour necrosis factor (TNF), Fas ligand (FasL)] remains to be determined.

Expression of transcription factors Pu.1, Spi-B, Blimp-1, BSAP and oct-2 in normal human plasma cells and in multiple myeloma cells

Summary. Differentiation of B lymphocytes into plasma cells is regulated by the interaction of distinct transcription factors (TFs) which activate gene expression in a lineage‐ and stage‐specific pattern. Using reverse transcription polymerase chain reaction, we studied the expression of five TFs (octamer binding factor oct‐2, ets family members PU.1 and Spi‐B, pax gene family member BSAP, and Blimp‐1) in (1) human cell lines with a plasma cell phenotype, (2) primary malignant plasma cells [obtained from patients with plasma cell leukaemia (PCL) and multiple myeloma], and (3) normal human plasma cells generated in vitro or isolated from normal bone marrows. The expression pattern was compared with TFs expressed by normal CD19+ B lymphocytes and by B cells from chronic lymphocytic leukaemia patients. Our results showed that plasma cells expressed a restricted set of TFs compared with CD19+ B lymphocytes, with continued expression of Spi‐B and oct‐2, increased Blimp‐1 expression, and downregulation of BSAP and PU.1. Cells from PCL lost Spi‐B and PU.1 expression completely and expressed only oct‐2 and Blimp‐1, and thus resembled plasma cell lines. Human plasma cell differentiation therefore seems to be positively regulated by Blimp‐1; whether this TF has any oncogenic potential will have to be analysed in future studies.

Paracrine promotion of tumor development by the TNF ligand APRIL in Hodgkin's Disease

A proliferation-inducing ligand (APRIL) from the tumor necrosis factor (TNF) superfamily co-stimulates B-cell activation. When overexpressed in mice, APRIL induces B-cell neoplasia.1 The promoting activity of APRIL for B-cell derived tumors has been recently reported in vitro for human Hodgkins lymphoma (HL) cell lines.2 In this work, we sought to ascertain whether APRIL plays a role in the in situ development of HL with a particular emphasis on the pathway(s) involved.