IL‐1‐dependent,IL‐1R1‐independent resistance to gastrointestinal nematodes

IL‐1 null mice are unable to expel the intestinal nematode Trichuris muris; whereas WT littermates exhibit sterile immunity. Intriguingly the essential signalling components IL‐1R1 and IL‐1R accessory protein (AcP) are dispensable for expulsion of this parasite. IL‐1 is thus critical for CD4⁺ Th2‐mediated immunity to T. muris; however, this action is independent of the established IL‐1 signalling receptor. We also present data demonstrating that both IL‐1α and IL‐1β induce measurable effects on T. muris primed cells isolated from IL‐1R1 or IL‐1R AcP null mice. MLN cells from these mice restimulated with parasite antigen proliferated at a greater rate and produced more cytokines in response to exogenous IL‐1. This ability to respond to IL‐1 was restricted to these parasite‐primed cells and importantly was not evident in cells from naïve gene null mice. These in vitro data are consistent with the observed ability of mice with compromised IL‐1 signalling to expel the parasite, bolstering the premise that an alternative IL‐1 signalling mechanism is accessible in the context of an intestinal helminth‐driven Th2 immune response.     

Screening of anti‐HPA‐1a antibodies in HPA‐1a‐negative mothers

Results from a study of more than 100 000 pregnant women show that the pathophysiology of neonatal alloimmune thrombocytopenia (NAIT) and haemolytic disease of the newborn (HDN) has many equalities [ 1 ]. It has been reported that NAIT is more than three times more frequent compared with HDN. This makes it tempting to consider a design for screening for HPA 1a negativity and follow up in/after the pregnancy based on the same principles as for RhD‐negative pregnant women. Even without available vaccination, it is strongly indicated that screening and Caesarean section 2–4 weeks prior to term in mothers with the HPA‐1a‐negative platelet type, reduce neonatal morbidity and mortality due to NAIT.     

Thymic emigration: Sphingosine‐1‐phosphate receptor‐1‐dependent models and beyond

The thymus is a primary lymphoid organ supporting the development of self‐tolerant T cells. Key events in T‐cell development in the thymus include lineage commitment, selection events, and thymic emigration. This review discusses the proposed role of sphingosine‐1‐phosphate and its receptors in the emigration of both conventional and unconventional T‐cell subsets from the thymus, and the molecular machinery currently understood to regulate this process. Furthermore, we highlight a role for chemokines and actin‐associated proteins in T‐cell motility as recent data suggest that T‐cell emigration is regulated by more than just a sphingosine‐1‐phosphate receptor‐1‐dependent chemotactic axis.     

Pannexin‐1‐dependent caspase‐1 activation and secretion of IL‐1β is regulated by zinc

Inflammatory processes induced by IL‐1β are critical for host defence responses, but are also implicated in disease. Zinc deficiency is a common consequence of, or contributor to, human inflammatory disease. However, the molecular mechanisms through which zinc contributes to inflammatory disease remain largely unknown. We report here that zinc metabolism regulates caspase‐1 activation and IL‐1β secretion. One of the endogenous mediators of IL‐1β secretion is adenosine triphosphate, acting via the P2X7‐receptor and caspase‐1 activation in cells primed with an inflammatory stimulus such as LPS. We show that this process is selectively abolished by a brief pre‐treatment with the zinc chelator N,N,N′,N′‐tetrakis‐(2‐pyridylmethyl) ethylene diamine (TPEN). These effects on IL‐1β secretion were independent of rapid changes in free zinc within the cell, not a direct effect on caspase‐1 activity, and upstream of caspase‐1 activation. TPEN did however inhibit the activity of pannexin‐1, a hemi‐channel critical for adenosine triphosphate and nigericin‐induced IL‐1β release. These data provide new insights into the mechanisms of caspase‐1 activation and how zinc metabolism contributes to inflammatory mechanisms.     

Control of the radical polymerization by 2,2,15,15‐tetramethyl‐1‐aza‐4,7,10,13‐tetraoxacyclopentadecan‐1‐oxyl and its sodium salt

The control of the radical polymerization of styrene by 2,2,15,15‐tetramethyl‐1‐aza‐4,7,10,13‐tetraoxacyclopentadecan‐1‐oxyl is reported here in bulk at 90 °C, 120 °C and in miniemulsion. Similarly, the control by its sodium complex is reported in bulk at 90 °C.

M _n vs. conversion for 3 , 3Na , and TEMPO.     

The identification of up‐regulated ebv‐miR‐BHRF1‐2‐5p targeting MALT1 and ebv‐miR‐BHRF1‐3 in the circulation of patients with multiple sclerosis

Epstein–Barr virus (EBV) is a well‐documented aetiological factor for multiple sclerosis (MS). EBV encodes at least 44 microRNAs (miRNAs) that are readily detectable in the circulation of human. Previous studies have demonstrated that EBV‐encoded miRNAs regulate host immune response and may serve as biomarkers for EBV‐associated diseases. However, the roles of EBV miRNAs in MS are still unknown. To fill the gap, we conducted a comprehensive profiling of 44 mature EBV miRNAs in 30 relapsing–remitting MS (RRMS) patients at relapse and 30 matched healthy controls. Expression levels of ebv‐miR‐BHRF1‐2‐5p and ebv‐miR‐BHRF1‐3 were elevated significantly in the circulation and correlated positively with the expanded disability status scale (EDSS) scores of MS patients. Receiver operating characteristic (ROC) analyses confirmed that the expression of these two miRNAs distinguished MS patients clearly from healthy controls. Luciferase assays revealed that ebv‐miR‐BHRF1‐2‐5p may directly target MALT1 (mucosa‐associated lymphoid tissue lymphoma transport protein 1), a key regulator of immune homeostasis. In conclusion, we described the expression of EBV miRNAs in MS and preliminarily validated the potential target genes of significantly altered EBV miRNAs. The findings may pave the way for prospective study about the pathogenesis of MS.     

Polymorphism of HLA‐A, ‐B, ‐DRB1, ‐DQA1 and ‐DQB1 haplotypes in a Croatian population

We describe for the first time extended haplotypes in a Croatian population. The present study gives the HLA‐A, ‐B, ‐DRB1, ‐DQA1 and ‐DQB1 allele and haplotype frequencies in 105 families with at least two offspring. All individuals were studied by conventional serology for HLA class I antigens (A and B), while class II alleles (DRB1, DQA1, DQB1) were typed using the PCR–SSOP method. HLA genotyping was performed by segregation in all 105 families. For extended haplotype analysis, 420 independent parental haplotypes were included. Fourteen HLA‐A, 18 HLA‐B, 28 DRB1, 9 DQA1 and 11 DQB1 alleles were found in the studied population. Most of the DRB1 alleles in our population had an exclusive association with one specific DQA1‐DQB1 combination. This strong linkage disequilibrium within the HLA class II region is often extended to the HLA‐B locus. A total of 10 HLA‐A, ‐B, ‐DRB1, ‐DQA1, ‐DQB1 haplotypes were observed with a frequency ≤ 1.0%. The three most frequent haplotypes were HLA‐A1, B8, DRB1*0301, DQA1*0501, DQB1*0201; HLA‐A3, B7, DRB1*1501, DQA1*0102, DQB1*0602 and HLA‐A24, B44, DRB1*0701, DQA1*0201, DQB1*02. These results should provide a useful reference for further anthropological studies, transplantation studies, and studies of associations between HLA and diseases.     

Unexpected mitochondrial matrix localization of Parkinson's disease‐related DJ‐1 mutants but not wild‐type DJ‐1

DJ‐1 has been identified as a gene responsible for recessive familial Parkinson's disease (familial Parkinsonism), which is caused by a mutation in the PARK7 locus. Consistent with the inferred correlation between Parkinson's disease and mitochondrial impairment, mitochondrial localization of DJ‐1 and its implied role in mitochondrial quality control have been reported. However, the mechanism by which DJ‐1 affects mitochondrial function remains poorly defined, and the mitochondrial localization of DJ‐1 is still controversial. Here, we show the mitochondrial matrix localization of various pathogenic and artificial DJ‐1 mutants by multiple independent experimental approaches including cellular fractionation, proteinase K protection assays, and specific immunocytochemistry. Localization of various DJ‐1 mutants to the matrix is dependent on the membrane potential and translocase activity in both the outer and the inner membranes. Nevertheless, DJ‐1 possesses neither an amino‐terminal alpha‐helix nor a predictable matrix‐targeting signal, and a post‐translocation processing‐derived molecular weight change is not observed. In fact, wild‐type DJ‐1 does not show any evidence of mitochondrial localization at all. Such a mode of matrix localization of DJ‐1 is difficult to explain by conventional mechanisms and implies a unique matrix import mechanism for DJ‐1 mutants.     

Copolymerization of N‐(prop‐1‐yne‐3‐yl)‐4‐(piperidine‐1‐yl)‐1,8‐naphthalimide with Arylacetylenes into Fluorescent Polyacetylene‐Type Conjugated Polymers

N‐(prop‐1‐yne‐3‐yl)‐4‐(piperidine‐1‐yl)‐1,8‐naphthalimide (PNPr), i.e., the monomer with a terminal ethynyl group and 1,8‐naphthalimide fluorophore, has been successfully copolymerized with a series of monoethynylarenes into well‐soluble high‐molecular‐weight (M_w up to 210 000) linear polyacetylene‐type copolymers containing from 14 to 51 mol% units derived from PNPr. The copolymerization of PNPr with bifunctional 4,4′‐diethynylbiphenyl provides polyacetylene‐type micro/mesoporous fluorescent network containing 8 mol% PNPr units and exhibiting the Brunauer–Emmett–Teller surface of ≈1000 m² g^?1. The copolymerizations (catalyzed with acetylacetonato(norborna‐2,5‐diene)rhodium complex, [Rh(nbd)acac]) proceed smoothly despite the fact that the homopolymerization of PNPr fails. The fluorescence of PNPr (emission at ≈ 510 nm) has been retained after the incorporation of PNPr into the copolymers. The fluorescence of the copolymers can be induced by a direct excitation of PNPr units or via an energy transfer mechanism. In the latter case, the comonomeric units with aromatic hydrocarbon fluorophores (e.g., of the biphenyl‐type) emitting at 380–400 nm (after irradiation with 300 nm UV radiation) serve as energy donors for fluorescent PNPr acceptors. The difference between the wavelengths of the primary absorbed radiation and the finally emitted radiation is 210 nm.

     

STS‐1 promotes IFN‐α induced autophagy by activating the JAK1‐STAT1 signaling pathway in B cells

Systemic lupus erythematosus (SLE) is an autoimmune disease characterized by the overexpression of IFN‐α. IFN‐α induces autophagy via the JAK1‐STAT1 signaling pathway, contributing to the pathogenesis of SLE. Recent studies reported that B cells from patients with SLE and NZB/W F1 mice had enhanced autophagy activity; however, the mechanism still remains unknown. Here, we show that the protein tyrosine phosphatase STS‐1 (suppressor of T‐cell receptor signaling 1) was significantly overexpressed in B cells from patients with SLE and MRL/lpr mice. Notably, STS‐1 promoted IFN‐α‐induced autophagy in B cells by enhancing the JAK1‐STAT1 signaling activation. STS‐1 inhibited the phosphorylation of the E3 ubiquitin protein ligase c‐cbl, and subsequently promoted IFN‐α‐induced phosphorylation of tyrosine kinase 2, leading to JAK1‐STAT1 signaling activation. Furthermore, STAT1 and JAK1 inhibitors blocked the IFN‐α‐induced autophagy promoted by STS‐1, indicating that STS‐1 promotes IFN‐α‐induced autophagy via the JAK1‐STAT1 signaling. Our results demonstrate the importance of STS‐1 in regulating IFN‐α‐induced autophagy in B cells, and this could be used as a therapeutic approach to treat SLE.     

ATP1A1 mutations cause intermediate Charcot‐Marie‐Tooth disease

Intermediate Charcot‐Marie‐Tooth (CMT) disease is a heterogeneous group of inherited neuropathies characterized by progressive muscle weakness and atrophy of the distal extremities, distal sensory loss. There were still a large proportion of causative genes for intermediate CMT failed to be identified. Here, using whole‐exome sequencing technique, we identified two novel missense mutations in ATP1A1 gene, c.620C>T (p.S207F) and c.2629G>A (p.G877S), in two Chinese CMT families. Further functional analysis revealed that these mutations led to the loss function of the ATP1A1 protein. The two mutations did not affect the levels of messenger RNA but possessed a damaging effect on ATP1A1 protein expression and they downregulated the protein levels of ATP1A1 by promoting its proteasome degradation. Taken together, we confirmed ATP1A1 as a novel causative gene for intermediate CMT.     

Cathepsin X cleaves the β2 cytoplasmic tail of LFA‐1 inducing the intermediate affinity form of LFA‐1 and α‐actinin‐1 binding

The motility of T cells depends on the dynamic spatial regulation of integrin‐mediated adhesion and de‐adhesion. Cathepsin X, a cysteine protease, has been shown to regulate T‐cell migration by interaction with lymphocyte function associated antigen‐1 (LFA‐1). LFA‐1 adhesion to the ICAM‐1 is controlled by the association of actin‐binding proteins with the cytoplasmic tail of the β₂ chain of LFA‐1. Cleavage by cathepsin X of the amino acid residues S⁷⁶⁹, E⁷⁶⁸ and A⁷⁶⁷ from the C‐terminal of the β₂ cytoplasmic tail of LFA‐1 is shown to promote binding of the actin‐binding protein α‐actinin‐1. Furthermore, cathepsin X overexpression reduced LFA‐1 clustering and induced an intermediate affinity LFA‐1 conformation that is known to associate with α‐actinin‐1. Increased levels of intermediate affinity LFA‐1 resulted in augmented cell spreading due to reduced attachment of T cells to the ICAM‐1‐coated surface. Gradual cleavage of LFA‐1 by cathepsin X enables the transition between intermediate and high affinity LFA‐1, an event that is crucial for effective T‐cell migration.     

N‐acetyltransferase ARD1‐NAT1 regulates neuronal dendritic development

ARD1 and NAT1 constitute an N‐acetyltransferase complex where ARD1 holds the enzymatic activity of the complex. The ARD1–NAT1 complex mediates N‐terminal acetylation of nascent polypeptides that emerge from ribosomes after translation. ARD1 may also acetylate the internal lysine residues of proteins. Although ARD1 and NAT1 have been found in the brain, the physiological role and substrates of the ARD1–NAT1 complex in neurons remain unclear. Here we investigated role of N‐acetyltransferase activity in the process of neuronal development. Expression of ARD1 and NAT1 increased during dendritic development, and both proteins colocalized with microtubules in dendrites. The ARD1–NAT1 complex displayed acetyltransferase activity against a purified microtubule fraction in vitro. Inhibition of the complex limited the dendritic extension of cultured neurons. These findings suggest that the ARD1–NAT1 complex has acetyltransferase activity against microtubules in dendrites. Regulation by acetyltransferase activity is a novel mechanism that is required for dendritic arborization during neuronal development.     

Three‐dimensional ultrashort echo time cones T1ρ (3D UTE‐cones‐T1ρ) imaging

We report a novel three‐dimensional (3D) ultrashort echo time (UTE) sequence employing Cones trajectory and T_1ρ preparation (UTE‐Cones‐T_1ρ) for quantitative T_1ρ assessment of short T₂ tissues in the musculoskeletal system. A basic 3D UTE‐Cones sequence was combined with a spin‐locking preparation pulse for T_1ρ contrast. A relatively short TR was used to decrease the scan time, which required T₁ measurement and compensation using 3D UTE‐Cones data acquisitions with variable TRs. Another strategy to reduce the total scan time was to acquire multiple Cones spokes (N_sp) after each T_1ρ preparation and fat saturation. Four spin‐locking times (TSL = 0–20 ms) were acquired over 12 min, plus another 7 min for T₁ measurement. The 3D UTE‐Cones‐T_1ρ sequence was compared with a two‐dimensional (2D) spiral‐T_1ρ sequence for the imaging of a spherical CuSO₄ phantom and ex vivo meniscus and tendon specimens, as well as the knee and ankle joints of healthy volunteers, using a clinical 3‐T scanner. The CuSO₄ phantom showed a T_1ρ value of 76.5 ± 1.6 ms with the 2D spiral‐T_1ρ sequence, as well as 85.7 ± 3.6 and 89.2 ± 1.4 ms for the 3D UTE‐Cones‐T_1ρ sequences with N_sp of 1 and 5, respectively. The 3D UTE‐Cones‐T_1ρ sequence provided shorter T_1ρ values for the bovine meniscus sample relative to the 2D spiral‐T_1ρ sequence (10–12 ms versus 16 ms, respectively). The cadaveric human Achilles tendon sample could only be imaged with the 3D UTE‐Cones‐T_1ρ sequence (T_1ρ = 4.0 ± 0.9 ms), with the 2D spiral‐T_1ρ sequence demonstrating near‐zero signal intensity. Human studies yielded T_1ρ values of 36.1 ± 2.9, 18.3 ± 3.9 and 3.1 ± 0.4 ms for articular cartilage, meniscus and the Achilles tendon, respectively. The 3D UTE‐Cones‐T_1ρ sequence allows volumetric T_1ρ measurement of short T₂ tissues in vivo.