Mapping the Antibody Repertoires in Ferrets with Repeated Influenza A/H3 Infections: Is Original Antigenic Sin Really "Sinful"?

The influenza-specific antibody repertoire is continuously reshaped by infection and vaccination. The host immune response to contemporary viruses can be redirected to preferentially boost antibodies specific for viruses encountered early in life, a phenomenon called original antigenic sin (OAS) that is suggested to be responsible for diminished vaccine effectiveness after repeated seasonal vaccination. Using a new computational tool called Neutralization Landscapes, we tracked the progression of hemagglutination inhibition antibodies within ferret antisera elicited by repeated influenza A/H3 infections and deciphered the influence of prior exposures on the de novo antibody response to evolved viruses. The results indicate that a broadly neutralizing antibody signature can nevertheless be induced by repeated exposures despite OAS induction. Our study offers a new way to visualize how immune history shapes individual antibodies within a repertoire, which may help to inform future universal influenza vaccine design.

Highly pathogenic avian influenza A/Guangdong/17SF003/2016 is immunogenic and induces cross-protection against antigenically divergent H7N9 viruses.

Avian influenza A(H7N9) epidemics have a fatality rate of approximately 40%. Previous studies reported that low pathogenic avian influenza (LPAI)-derived candidate vaccine viruses (CVVs) are poorly immunogenic. Here, we assess the immunogenicity and efficacy of a highly pathogenic avian influenza (HPAI) A/Guangdong/17SF003/2016 (GD/16)-extracted hemagglutinin (eHA) vaccine. GD/16 eHA induces robust H7-specific antibody responses in mice with a marked adjuvant antigen-sparing effect. Mice immunized with adjuvanted GD/16 eHA are protected from the lethal LPAI and HPAI H7N9 challenges, in stark contrast to low antibody titers and high mortality in mice receiving adjuvanted LPAI H7 eHAs. The protection correlates well with the magnitude of the H7-specific antibody response (IgG and microneutralization) or HA group 2 stem-specific IgG. Inclusion of adjuvanted GD/16 eHA in heterologous prime-boost improves the immunogenicity and protection of LPAI H7 HAs in mice. Our findings support the inclusion of GD/16-derived CVV in the pandemic preparedness vaccine stockpile.

Colloidal Properties of Nanoerythrosomes Derived from Bovine Red Blood Cells.

Liposomes are nanoscale containers that are typically synthesized from lipids using a high-shear process such as extrusion or sonication. While liposomes are extensively used in drug delivery, they do suffer from certain problems including limited colloidal stability and short circulation times in the body. As an alternative to liposomes, we explore a class of container structures derived from erythrocytes (red blood cells). The procedure involves emptying the inner contents of these cells (specifically hemoglobin) and resuspending the empty structures in buffer, followed by sonication. The resulting structures are termed nanoerythrosomes (NERs), i.e., they are membrane-covered nanoscale containers, much like liposomes. Cryo-transmission electron microscopy (cryo-TEM) and small-angle neutron scattering (SANS) are employed for the first time to study these NERs. The results reveal that the NERs are discrete spheres (∼110 nm diameter) with a unilamellar membrane of thickness ∼4.5 nm. Remarkably, the biconcave disc-like shape of erythrocytes is also exhibited by the NERs under hypertonic conditions. Moreover, unlike typical liposomes, NERs show excellent colloidal stability in both buffer as well as in serum at room temperature, and are also able to withstand freeze-thaw cycling. We have explored the potential for using NERs as colloidal vehicles for targeted delivery. Much like conventional liposomes, NER membranes can be decorated with fluorescent or other markers, solutes can be encapsulated in the cores of the NERs, and NERs can be targeted to specifically bind to mammalian cells. Our study shows that NERs are a promising and versatile class of nanostructures. NERs that are harvested from a patient's own blood and reconfigured for nanomedicine can potentially offer several benefits including biocompatibility, minimization of immune response, and extended circulation time in the body.

Enhanced endothelial delivery and biochemical effects of α-galactosidase by ICAM-1-targeted nanocarriers for Fabry disease.

Fabry disease, due to the deficiency of α-galactosidase A (α-Gal), causes lysosomal accumulation of globotriaosylceramide (Gb3) in multiple tissues and prominently in the vascular endothelium. Although enzyme replacement therapy (ERT) by injection of recombinant α-Gal improves the disease outcome, the effects on the vasculopathy associated with life-threatening cerebrovascular, cardiac and renal complications are still limited. We designed a strategy to enhance the delivery of α-Gal to organs and endothelial cells (ECs). We targeted α-Gal to intercellular adhesion molecule 1 (ICAM-1), a protein expressed on ECs throughout the vasculature, by loading this enzyme on nanocarriers coated with anti-ICAM (anti-ICAM/α-Gal NCs). In vitro radioisotope tracing showed efficient loading of α-Gal on anti-ICAM NCs, stability of this formulation under storage and in model physiological fluids, and enzyme release in response to lysosome environmental conditions. In mice, the delivery of (125)I-α-Gal was markedly enhanced by anti-ICAM/(125)I-α-Gal NCs in brain, kidney, heart, liver, lung, and spleen, and transmission electron microscopy showed anti-ICAM/α-Gal NCs attached to and internalized into the vascular endothelium. Fluorescence microscopy proved targeting, endocytosis and lysosomal transport of anti-ICAM/α-Gal NCs in macro- and micro-vascular ECs and a marked enhancement of Gb3 degradation. Therefore, this ICAM-1-targeting strategy may help improve the efficacy of therapeutic enzymes for Fabry disease.

Development of a novel DNA SynCon tetravalent dengue vaccine that elicits immune responses against four serotypes.

The increased transmission and geographic spread of dengue fever (DF) and its most severe presentations, dengue hemorrhagic fever (DHF) and dengue shock syndrome (DSS), make it one of the most important mosquito-borne viral disease of humans. Four distinct serotypes of dengue viruses are transmitted to humans through the bites of the mosquitoes. Currently there is no vaccine or antiviral drug against DV infections. Cross-protection between dengue virus serotypes is limited and antibody dependent enhancement (ADE) contributes significantly to the severity of the disease. The major challenge is to induce a broad durable immune response against all four serotypes of dengue virus simultaneously while avoiding the possible exacerbation of risk of developing the severe forms of disease through incomplete or modified responses. In order to address this worldwide concern, we present a synthetic consensus (SynCon) human codon optimized DNA vaccine that elicits immunity against all four dengue serotypes. We cloned consensus DIII domain of E protein from all serotypes and expressed them as a single open reading frame in a mammalian expression vector, called pDV-U-DIII (dengue-vaccine universal). In mice, this dengue-universal construct elicits significant level of anti-DIII antibody that neutralizes all four dengue subtypes and prevents cell death induced by dengue infection. This is the first SynCon DNA vaccine that provides tetravalent immunity against all four serotypes of dengue virus.

Coimmunization with an optimized IL15 plasmid adjuvant enhances humoral immunity via stimulating B cells induced by genetically engineered DNA vaccines expressing consensus JEV and WNV E DIII.

The Japanese encephalitis virus (JEV) and West Nile virus (WNV) are responsible for a large proportion of viral encephalitis in humans. Currently, there is no FDA approved specific treatment for either, though there are attempts to develop vaccines against both viruses. In this study, we proposed novel genetically engineered DNA vaccines against these two neurotrophic flaviviruses. The structural domain III (DIII) of E protein from these viruses is reported to carry dominant epitopes that induce neutralizing antibodies. Therefore we created consensus sequence of DIII domain across numerous strains of JEV and WNV. Based on the consensus amino acid sequence, synthetic codon and RNA optimized DIII-expressing DNA vaccine constructs with an efficient leader sequence were synthesized for immunization studies. In addition, we also constructed a genetically engineered IL15 DNA vaccine molecular adjuvant for co-stimulating the immune response against DIII clones. Vaccine constructs were delivered into BALB/C mice intramuscularly followed by electroporation using the CELLECTRA in vivo electroporator. We have observed that the combined delivery of both WNV DIII and IL15-ECRO DNA vaccine constructs resulted in not only the highest level of antibody against DIII, but also enhanced cross reactivity with two other antigens tested. Also, coimmunization with IL15 plasmid further increased the immune response by four- to five-fold. Importantly, we have shown that IL15 coimmunization adjuvanted humoral responses against DIII antigens by elevating the level of antibody secreting B cells. Such a DNA vaccine approach may better help to control potential travel related infectious agents such as JEV.