Genome-Wide Screening Uncovers the Significance of N-Sulfation of Heparan Sulfate as a Host Cell Factor for Chikungunya Virus Infection.

The molecular mechanisms underlying chikungunya virus (CHIKV) infection are poorly characterized. In this study, we analyzed the host factors involved in CHIKV infection using genome-wide screening. Human haploid HAP1 cells, into which an exon-trapping vector was introduced, were challenged with a vesicular stomatitis virus pseudotype bearing the CHIKV E3 to E1 envelope proteins. Analysis of genes enriched in the cells resistant to the pseudotyped virus infection unveiled a critical role of N-sulfation of heparan sulfate (HS) for the infectivity of the clinically isolated CHIKV Thai#16856 strain to HAP1 cells. Knockout of NDST1 that catalyzes N-sulfation of HS greatly decreased the binding and infectivity of CHIKV Thai#16856 strain but not infectivity of Japanese encephalitis virus (JEV) and yellow fever virus (YFV). While glycosaminoglycans were commonly required for the efficient infectivity of CHIKV, JEV, and YFV, as shown by using B3GAT3 knockout cells, the tropism for N-sulfate was specific to CHIKV. Expression of chondroitin sulfate (CS) in NDST1-knockout HAP1 cells did not restore the binding of CHIKV Thai#16856 strain and the infectivity of its pseudotype but restored the infectivity of authentic CHIKV Thai#16856, suggesting that CS functions at later steps after CHIKV binding. Among the genes enriched in this screening, we found that TM9SF2 is critical for N-sulfation of HS and therefore for CHIKV infection because it is involved in the proper localization and stability of NDST1. Determination of the significance of and the relevant proteins to N-sulfation of HS may contribute to understanding mechanisms of CHIKV propagation, cell tropism, and pathogenesis.IMPORTANCE Recent outbreaks of chikungunya fever have increased its clinical importance. Chikungunya virus (CHIKV) utilizes host glycosaminoglycans to bind efficiently to its target cells. However, the substructure in glycosaminoglycans required for CHIKV infection have not been characterized. Here, we unveil that N-sulfate in heparan sulfate is essential for the efficient infection of a clinical CHIKV strain to HAP1 cells and that chondroitin sulfate does not help the CHIKV binding but does play roles at the later steps in HAP1 cells. We show, by comparing previous reports using Chinese hamster ovary cells, along with another observation that enhanced infectivity of CHIKV bearing Arg82 in envelope E2 does not depend on glycosaminoglycans in HAP1 cells, that the infection manner of CHIKV varies among host cells. We also show that TM9SF2 is required for CHIKV infection to HAP1 cells because it is involved in the N-sulfation of heparan sulfate through ensuring NDST1 activity.

Evolution of adaptive immunity: implications of a third lymphocyte lineage in lampreys.

An alternative antigen receptor, named the variable lymphocyte receptor (VLR), was first identified in lampreys in 2004. Since then, the mechanism of VLR diversification via somatic gene assembly and the function of VLR-expressing lymphocytes have been the subject of much research. VLRs comprise leucine-rich repeat (LRR) motifs and are found only in the most phylogenetically distant vertebrates from mammals, lampreys, and hagfish. Previous reports showed that VLRA and VLRB are reciprocally expressed by lymphocytes that resemble T- and B cells; however, more recent reports show that another VLR, VLRC, is expressed on a third lymphocyte lineage, which may be equivalent to γδ T cells. The existence of three major lymphocyte lineages - one B-cell-like and two T-cell-like - and their development in lampreys, parallels the mammalian adaptive immune system. This suggests that these three cell lineages were present in the common vertebrate ancestor approximately 500 million years ago.

Neutralization activity of patient sera collected during the 2008-2009 Chikungunya outbreak in Thailand.

Chikungunya virus (CHIKV) infection typically causes fever, rash, myalgia, and arthralgia and sometimes results in recurrent joint pain or, in severe cases, neurological disorders or death. How CHIKV infection leads to prolonged or severe symptoms is still not well understood. In this study, we examined the neutralization (NT) titer of 98 serum samples collected from patients during the 2008-2009 chikungunya outbreak in Thailand. While all serum samples showed neutralizing activity, virus was detected in 58% of the serum samples. When we analyzed a possible association between virus and antibody titers and the presence of typical symptoms of CHIKV infection, fever and joint pain, there was no significant association except that the number of patients with fever was over three times more than the number of those without fever when CHIKV was detectable in serum. This study indicates that although neutralizing antibody is critical to eliminate CHIKV, it appears not to be the main factor associated with clinical symptoms in some cases, so that other aspects of immune responses, such as those involving proinflammatory mediators and adaptive immune cells, should be considered altogether.

Development of a pseudotyped-lentiviral-vector-based neutralization assay for chikungunya virus infection.

Chikungunya virus (CHIKV) is a mosquito-borne alphavirus that causes chikungunya fever in Africa, South Asia, and Southeast Asia. Because the mosquito vector Aedes albopictus is present in habitats across Europe, North America, and East Asia, CHIKV has become a serious worldwide public health concern. Infection with CHIKV typically causes fever, rash, myalgia, and arthralgia. One of the important questions yet to be answered is how the host immune system is involved in the development of this disease. In this study, we prepared a CHIKV-pseudotyped lentiviral vector for use in a safe and convenient neutralization (NT) assay and analyzed its efficacy. The CHIKV-pseudotyped lentiviral vector was prepared by cotransfection with plasmids encoding the CHIKV glycoproteins E3, E2, 6k, and E1, packaging elements, and a luciferase reporter. This alternative to native CHIKV can be safely handled in a biosafety level 2 facility. The NT assay was optimized using sera from CHIKV-immunized mice and then applied to human patient sera. The majority of the serum samples from patients with chikungunya in Thailand showed robust neutralization activities, with titers that were tightly correlated with those determined by a conventional NT assay. Moreover, there was a strong correlation with the CHIKV antibody titers as determined by enzyme-linked immunosorbent assay. Thus, the CHIKV-pseudotyped-lentiviral-vector-based NT assay system is a powerful tool for examining the neutralization activity of patient sera, which will lead to a better understanding of the immune responses involved in CHIKV infection.

Regulation of antigen-receptor gene assembly in hagfish.

Variable lymphocyte receptors (VLRs) are antigen receptors in the jawless vertebrates lamprey and hagfish. VLR genes are classified into VLRA and VLRB, and lymphocytes expressing VLRA are T-cell-like, whereas those expressing VLRB are B-cell-like in the sea lamprey. Diverse VLR genes are assembled somatically in lymphocytes; however, how the assembly is regulated is still largely unknown. Here, we analyse VLR gene assembly at the single-cell level in the inshore hagfish (Eptatretus burgeri). Each lymphocyte assembles and transcribes only one type of VLR gene, either VLRA or VLRB. In general, monoallelic assembly of VLR was observed, but diallelic assembly was found in some cases--in many of which, one allele was functional and the other was defective. In fact, all VLR-assembled lymphocytes contained at least one functional VLR gene. Together, these results indicate a feedback inhibition of VLR assembly and selection of VLR-positive lymphocytes.

The use of green fluorescent protein-tagged virus-like particles as a tracer in the early phase of chikungunya infection.

To visually examine the early phase of chikungunya virus (CHIKV) infection in target cells, we constructed a virus-like particle (VLP) in which the envelope protein E1 is fused with green fluorescent protein (GFP). This chikungunya VLP-GFP (CHIK-VLP-EGFP), purified by density gradient fractionation, was observed as 60-70 nm-dia. particles and was detected as tiny puncta of fluorescence in the cells. CHIK-VLP-EGFP showed binding properties similar to those of the wild-type viruses. Most of the fluorescence signals that had bound on Vero cells disappeared within 30 min at 37 °C, but not in the presence of anti-CHIKV neutralizing serum or an endosomal acidification inhibitor (bafilomycin A1), suggesting that the loss of fluorescence signals is due to the disassembly of the viral envelope following the internalization of CHIK-VLP-EGFP. In addition to these results, the fluorescence signals disappeared in highly susceptible Vero and U251MG cells but not in poorly susceptible A549 cells. Thus, CHIK-VLP-EGFP is a useful tool to examine the effects of the CHIKV neutralizing antibodies and antiviral compounds that are effective in the entry phase of CHIKV.

Lymphoid tissue-resident Alcaligenes LPS induces IgA production without excessive inflammatory responses via weak TLR4 agonist activity.

Alcaligenes are opportunistic commensal bacteria that reside in gut-associated lymphoid tissues such as Peyer's patches (PPs); however, how they create and maintain their homeostatic environment, without inducing an excessive inflammatory response remained unclear. We show here that Alcaligenes-derived lipopolysaccharide (Alcaligenes LPS) acts as a weak agonist of toll-like receptor 4 and promotes IL-6 production from dendritic cells, which consequently enhances IgA production. The inflammatory activity of Alcaligenes LPS was weaker than that of Escherichia coli-derived LPS and therefore no excessive inflammation was induced by Alcaligenes LPS in vitro or in vivo. Alcaligenes LPS also showed adjuvanticity, inducing antigen-specific immune responses without excessive inflammation. These findings reveal the presence of commensal bacteria-mediated homeostatic inflammatory conditions within PPs that produce optimal IgA induction without causing pathogenic inflammation and suggest that Alcaligenes LPS could be a safe and potent adjuvant.

Intranasal hydroxypropyl-ß-cyclodextrin-adjuvanted influenza vaccine protects against sub-heterologous virus infection.

Intranasal vaccination with inactivated influenza viral antigens is an attractive and valid alternative to currently available influenza (flu) vaccines; many of which seem to need efficient and safe adjuvant, however. In this study, we examined whether hydroxypropyl-ß-cyclodextrin (HP-ß-CD), a widely used pharmaceutical excipient to improve solubility and drug delivery, can act as a mucosal adjuvant for intranasal flu vaccines. We found that intranasal immunization of mice with hemagglutinin split- as well as inactivated whole-virion influenza vaccine with HP-ß-CD resulted in secretion of antigen-specific IgA and IgGs in the airway mucosa and the serum as well. As a result, both HP-ß-CD adjuvanted-flu intranasal vaccine protected mice against lethal challenge with influenza virus, equivalent to those induced by experimental cholera toxin-adjuvanted ones. Of note, intranasal use of HP-ß-CD as an adjuvant induced significantly lower antigen-specific IgE responses than that induced by aluminum salt adjuvant. These results suggest that HP-ß-CD may be a potent mucosal adjuvant for seasonal and pandemic influenza vaccine.

Antigen-receptor genes of the agnathan lamprey are assembled by a process involving copy choice.

Jawless vertebrates have acquired immunity but do not have immunoglobulin-type antigen receptors. Variable lymphocyte receptors (VLRs) have been identified in lamprey that consist of multiple leucine-rich repeat (LRR) modules. An active VLR gene is generated by the assembly of a series of variable gene segments, including many that encode LRRs. Stepwise assembly of the gene segments seems to occur by replacement of the intervening DNA between the 5' and 3' constant-region genes. Here we report that lamprey (Lethenteron japonicum) assemble their VLR genes by a process involving 'copy choice'. Regions of short homology seemed to prime copying of donor LRR-encoding sequences into the recipient gene. Those LRR-encoding germline sequences were abundant and shared extensive sequence homologies. Such genomic organization permits initiation of copying anywhere in an LRR-encoding module for the generation of various hybrid LRRs. Thus, a vast repertoire of recombinant VLR genes could be generated not only by copying of various LRR segments in diverse combinations but also by the use of multiple sites in an LRR gene segment for priming.