In vivo targeting of porcine reproductive and respiratory syndrome virus antigen through porcine DC-SIGN to dendritic cells elicits antigen-specific CD4T cell immunity in pigs

Immunogenicity of protein subunit vaccines may be dramatically improved by targeting them through antibodies specific to c-type lectin receptors (CLRs) of dendritic cells in mice, cattle, and primates. This novel vaccine development approach has not yet been explored in pigs or other species largely due to the lack of key reagents. In this study, we demonstrate that porcine reproductive and respiratory syndrome virus (PRRSV) antigen was targeted efficiently to dendritic cells through antibodies specific to a porcine CLR molecule DC-SIGN (dendritic cell-specific intercellular adhesion molecule-3-grabbing non-integrin) in pigs. A recombinant PRRSV antigen (shGP45M) was constructed by fusing secretory-competent subunits of GP4, GP5 and M proteins derived from genetically-shuffled strains of PRRSV. In vaccinated pigs, when the PRRSV shGP45M antigen was delivered through a recombinant mouse-porcine chimeric antibody specific to the porcine DC-SIGN (pDC-SIGN) neck domain, porcine dendritic cells rapidly internalized them in vitro and induced higher numbers of antigen-specific interferon-γ producing CD4T cells compared to the pigs receiving non-targeted PRRSV shGP45M antigen. The pDC-SIGN targeting of recombinant antigen subunits may serve as an alternative or complementary strategy to existing vaccines to improve protective immunity against PRRSV by inducing efficient T cell responses.     

DC-SIGN/DC-SIGNR基因多态性与病原微生物感染

DC-SIGN和DC-SIGNR是两种表达于DC表面的蛋白,被认为是许多病原微生物的黏附受体,参与很多病原微生物的感染.DC-SIGN和DC-SIGNR(DC-SIGN/DC-SIGNR)的多态性或许影响病原微生物的感染过程和结果.此文对DC-SIGN/DC-SIGNR的结构功能以及与HIV、HCV感染、肺结核、登革热的关系进行了综述.     

Cell type-dependent retention and transmission of HIV-1 by DC-SIGN

DC-SIGN (CD209) is a C-type lectin expressed by several groups of dendritic cells (DC), including those derived from blood monocytes and DC found beneath genital epithelium. DC-SIGN binds the envelope glycoprotein of HIV-1 and facilitates transmission of infectious virus to permissive CD4(+) T cells. We have compared the capacity of DC-SIGN in different cell types to bind, retain and transmit infectious HIV-1 to T cells. The analyzed cells included monocyte-derived DC, and three different DC-SIGN-expressing transfectants termed THP, 293 and HOS. Our results show that DC-SIGN transfectants were able to bind HIV-1 virions comparably to DC. However, only the THP monocytic cell line shared with DC the capacity to retain for several days virus that was infectious for T cells. In both THP-DC-SIGN transfectants and DC, but not in 293 cells, HIV-1 was localized to intracellular compartments that did not double label for endosomal and lysosomal markers or for DC-SIGN itself. Virus remained detectable in these compartments for at least 2 days. Anti-DC-SIGN antibodies blocked the binding and transmission of HIV-1 in DC-SIGN transfectants, as monitored by PCR for HIV LTR/gag and p24 ELISA. However anti-DC-SIGN antibodies did not block virus binding and transmission to T cells as well in DC as in THP-DC-SIGN transfectants. Thus, the function of DC-SIGN in HIV-1 transmission depends on its cellular context, since only DC and the THP monocyte cell line, but not 293 and HOS, are able to use DC-SIGN to retain HIV-1 in a highly infectious state for several days.     

Expression of the chemokine receptor CCR1 in human renal allografts.

BACKGROUND: Chemokines are involved in the recruitment of leukocytes to vascularized allografts. CCR1 is a receptor for various proinflammatory chemokines and CCR1 blockade reduces renal allograft injury in rabbits. The purpose of the study was to characterize CCR1-positive cells in human renal allografts. METHODS: Formalin-fixed, paraffin-embedded allograft nephrectomies (n = 9) and non-involved parts of tumour nephrectomies (n = 10) were studied. Immunohistochemistry for CCR1, CD3 and CD68 was performed on consecutive sections. Double immunofluorescence for CCR1 and CD3, CD20, CD68, DC-SIGN and S100 was used on selected cases. Expression of CCR1 mRNA and the ligands CCL3 and CCL5 was studied in renal allograft biopsies with acute rejection (n = 10), with chronic allograft nephropathy (n = 8) and controls (n = 8). RESULTS: CCR1 protein was expressed by circulating cells in glomerular and peritubular capillaries, colocalizing with CD68. In renal allografts CCR1-positive cells were present within glomerular tufts, but only scattered CCR1-positive cells were found in tubulointerstitial infiltrates. CCR1 did not colocalize with the majority of CD68-positive cells in the interstitium. The small number of CCR1-positive interstitial cells were identified as CD20- or DC-SIGN-positive by double immunofluorescence. CCR1 mRNA was significantly increased in renal biopsies with acute allograft rejection (P < 0.001), and with chronic allograft nephropathy (P < 0.05), it correlated with the expression of CCL3 and CCL5, and with serum-creatinine. CONCLUSIONS: CCR1 mRNA expression was associated with renal function in allografts. CCR1 protein expression was restricted to monocytes, CD20-positive B cells and DC-SIGN-positive dendritic cells. Thus most interstitial macrophages were CCR1 negative, which may relate to down-regulation after migration into the interstitium in human renal allografts.     

小鼠DC-SIGN研究进展

DC-SIGN是一类重要的细胞膜表面蛋白;目前,小鼠DC-SIGN及其相关蛋白正在被广泛研究,其中染色体定位、表达方式、各个同系物的结构和功能是研究的主要方面.现对小鼠DC-SIGN的研究进展综述.     

Ligand-targeted particulate nanomedicines undergoing clinical evaluation: Current status

Since the introduction of Doxil® on the market nearly 20 years ago, a number of nanomedicines have become part of treatment regimens in the clinic. With the exception of antibody–drug conjugates, these nanomedicines are all devoid of targeting ligands and rely solely on their physicochemical properties and the (patho)physiological processes in the body for their biodistribution and targeting capability. At the same time, many preclinical studies have reported on nanomedicines exposing targeting ligands, or ligand-targeted nanomedicines, yet none of these have been approved at this moment. In the present review, we provide a concise overview of 13 ligand-targeted particulate nanomedicines (ligand-targeted PNMs) that have progressed into clinical trials. The progress of each ligand-targeted PNM is discussed based on available (pre)clinical data. Main conclusions of these analyses are that (a) ligand-targeted PNMs have proven to be safe and efficacious in preclinical models; (b) the vast majority of ligand-targeted PNMs is generated for the treatment of cancer; (c) contribution of targeting ligands to the PNM efficacy is not unambiguously proven; and (d) targeting ligands do not cause localization of the PNM within the target tissue, but rather provide benefits in terms of target cell internalization and target tissue retention once the PNM has arrived at the target site. Increased understanding of the in vivo fate and interactions of the ligand-targeted PNMs with proteins and cells in the human body is mandatory to rationally advance the clinical translation of ligand-targeted PNMs. Future perspectives for ligand-targeted PNM approaches include the delivery of drugs that are unable or inefficient in passing cellular membranes, treatment of drug resistant tumors, targeting of the tumor blood supply, the generation of targeted vaccines and nanomedicines that are able to cross the blood–brain barrier.     

DC-SIGN (CD209) Carbohydrate Recognition Domain Is Not Polymorphic in Dengue Virus-Infected Indonesian Patients

Dengue virus (DENV) infection is a significant burden in Indonesia and other tropical countries. DENV infection has a wide spectrum of clinical manifestations, i.e. asymptomatic, dengue fever, dengue hemorrhagic fever and dengue shock syndrome. The variety of clinical manifestations may be due to the diversity of genetic constitution of the host. The C-type lectin DC-SIGN (CD209) has been identified as the major dengue receptor on human dendritic cells. There are at least five polymorphisms in exon 5 and 6 of the DC-SIGN encoded gene which have been identified and recorded in dbSNP. The aim of this work is to measure the frequency of these polymorphisms among asymptomatic and hospitalized DENV-infected patients. We enrolled 23 hospitalized and 73 asymptomatic DENV-infected patients. Among the subjects, we performed PCR amplification and DNA direct seqencing for 23 hospitalized DENV-infected patients and 24 asymptomatic DENV-infected patients. The result showed that there were no polymorphic nucleotides in the CD209 encoded gene among the patients.     

Suppression of DC-SIGN and gH Reveals Complex,Subset-Specific Mechanisms for KSHV Entry in Primary B Lymphocytes

Kaposi sarcoma-associated herpesvirus (KSHV) is the causative agent of multiple cancers in immunocompromised patients including two lymphoproliferative disorders associated with KSHV infection of B lymphocytes. Despite many years of research into the pathogenesis of KSHV associated diseases, basic questions related to KSHV molecular virology remain unresolved. One such unresolved question is the cellular receptors and viral glycoproteins needed for KSHV entry into primary B lymphocytes. In this study, we assess the contributions of KSHV glycoprotein H (gH) and the cellular receptor DC-SIGN to KSHV infection in tonsil-derived B lymphocytes. Our results show that (1) neither KSHV-gH nor DC-SIGN are essential for entry into any B cell subset, (2) DC-SIGN does play a role in KSHV entry into tonsil-derived B cells, but in all B cell subtypes alternative entry mechanisms exist, (3) KSHV-gH can participate in KSHV entry into centrocytes via a DC-SIGN independent entry mechanism, and (4) in the absence of KSHV-gH, DC-SIGN is required for KSHV entry into centrocytes. Our results provide a first glimpse into the complexity of KSHV entry in the lymphocyte compartment and highlight that multiple subset-dependent entry mechanisms are employed by KSHV which depend upon multiple cellular receptors and multiple KSHV glycoproteins.     

DC-SIGN:C型凝集素中的新成员

DC SIGN是一种树突状细胞特征性的且具有多种功能免疫新分子 ,不但可以参与树突状细胞的迁移、粘附以及对抗原的识别与内化 ,还可以参与许多病原体的免疫逃避 ,本文拟就有关内容作一综述。     

Antiviral activity of carbohydrate-binding agents and the role of DC-SIGN in dengue virus infection

Dendritic cell-specific intercellular adhesion molecule 3-grabbing non-integrin (DC-SIGN) is an important binding receptor for dengue virus (DENV) that recognizes N-glycosylation sites on the viral E-glycoprotein. DENV cannot bind nor infect the human B-cell line Raji/0. However, DENV productively infects Raji/DC-SIGN⁺ cells that constitutively express DC-SIGN on their surface. IL-4-treated monocytes, expressing high levels of DC-SIGN, are also susceptible for DENV infection. Several carbohydrate-binding agents (CBAs), such as the plant lectins HHA, GNA (mannose-specific) and UDA (N-acetylglucosamine-specific), inhibited dose-dependently the binding of DENV and subsequently viral replication in Raji/DC-SIGN⁺ cells (EC₅₀: 0.1-2.2 μM). These CBAs were clearly more active against DENV in IL-4-treated monocytes (EC₅₀: 4-56 nM). However, the CBAs were devoid of antiviral activity in DENV-susceptible Vero-B (DC-SIGN⁻) cells, demonstrating cell type-dependent differences in viral entry mechanisms.