COVID-19 is a severe acute respiratory disease caused by SARS-CoV-2, a new recently emerged sarbecovirus. This virus uses the human ACE2 enzyme as receptor for cell entry, recognizing it with the receptor binding domain (RBD) of the S1 subunit of the viral spike protein. We present the use of phage display to select anti-SARS-CoV-2 spike antibodies from the human naïve antibody gene libraries HAL9/10 and subsequent identification of 309 unique fully human antibodies against S1. 17 antibodies are binding to the RBD, showing inhibition of spike binding to cells expressing ACE2 as scFv-Fc and neutralize active SARS-CoV-2 virus infection of VeroE6 cells. The antibody STE73-2E9 is showing neutralization of active SARS-CoV-2 as IgG and is binding to the ACE2-RBD interface. Thus, universal libraries from healthy human donors offer the advantage that antibodies can be generated quickly and independent from the availability of material from recovering patients in a pandemic situation.
The nuclear export protein (NEP) (NS2) of the highly pathogenic human-derived H5N1 strain A/Thailand/1(KAN-1)/2004 with the adaptive mutation M16I greatly enhances the polymerase activity in human cells in a concentration-dependent manner. While low NEP levels enhance the polymerase activity, high levels are inhibitory. To gain insights into the underlying mechanism, we analyzed the effect of NEP deletion mutants on polymerase activity after reconstitution in human cells. This revealed that the polymerase-enhancing function of NEP resides in the C-terminal moiety and that removal of the last three amino acids completely abrogates this activity. Moreover, compared to full-length NEP, the C-terminal moiety alone exhibited significantly higher activity and seemed to be deregulated, since even the highest concentration did not result in an inhibition of polymerase activity. To determine transient interactions between the N-and C-terminal domains in cis, we fused both ends of NEP to a split click beetle luciferase and performed fragment complementation assays. With decreasing temperature, increased luciferase activity was observed, suggesting that intramolecular binding between the C-and N-terminal domains is preferentially stabilized at low temperatures. This stabilizing effect was significantly reduced with the adaptive mutation M16I or a combination of adaptive mutations (M16I, Y41C, and E75G), which further increased polymerase activity also at 34°C. We therefore propose a model in which the N-terminal moiety of NEP exerts an inhibitory function by back-folding to the C-terminal domain. In this model, adaptive mutations in NEP decrease binding between the C-and N-terminal domains, thereby allowing the protein to "open up" and become active already at a low temperature.
Today, whole genomes are analyzed by Next-Generation Sequencing systems, or displayed by DNA microarray in situ synthesis. However, genomic data are mainly static and do not exactly reveal the complexity of protein interaction networks of any organism or cell. To investigate protein interactions, the generation of protein microarrays, displaying whole proteomes is a prerequisite. But traditional protein microarray generation is time consuming, costly, and is restricted by a wide range of technical difficulties concerning cell culturing, protein purification, and transfer onto microarray. Some of these obstacles can be bypassed by application of cell-free expression systems, enabling fast in situ synthesis of protein microarrays without need for cell culturing. This review provides a historical timeline of the different methods to generate protein microarrays by cell-free expression, highlights differences and similarities, and reports the current state of the different approaches.
Cytomegalovirus (CMV) genome is highly variable and heterosubtypic immunity should be considered in vaccine development since it can enhance protection in a cross-reactive manner. Here, we developed a protein array to evaluate heterosubtypic immunity to CMV glycoprotein B (gB) in natural infection and vaccination. DNA sequences of four antigenic domains (AD1, AD2, AD4/5 and AD5) of gB were amplified from six reference and 12 clinical CMV strains, and the most divergent genotypes were determined by phylogenetic analysis. Assigned genotypes were in vitro translated and immobilized on protein array. Then, we tested immune response of variable serum groups (primarily infected patients, reactivated CMV infections and healthy individuals with latent CMV infection, as well gB-vaccinated rabbits) with protein in situ array (PISA). Serum antibodies of all patient cohorts and gB-vaccinated rabbits recognized many genetic variants of ADs on protein array, including but not limited to the subtype of infecting strain. High-grade cross-reactivity was observed. In several patients, we observed none or neglectable immune response to AD1 and AD2, while the same patients showed high antibody response to AD4/5 and AD5. Among the primary infected patients, AD5 was the predominant antigenic domain, in antibody response. The most successful CMV vaccine to date contains gB and demonstrates only 50% efficacy. In this study, we showed that heterosubtypic and cross-reactive immunity to CMV gB is extensive. Therefore, the failure of CMV gB vaccines cannot be explained by a highly, strain-specific immunity. Our observations suggest that other CMV antigens should be addressed in vaccine design.
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