RESUMO
1.The effort to develop vaccines based on economically accessible technological platforms available by developing countries vaccine manufacturers is essential to extend the immunization to the whole world population and to achieve the desired herd immunity, necessary to end the COVID-19 pandemic. Here we report on the development of a SARS-CoV-2 receptor-binding domain (RBD) protein, expressed in yeast Pichia pastoris. The RBD was modified with addition of flexible N- and C-terminal amino acid extensions aimed to modulate the protein/protein interactions and facilitate protein purification. Fermentation with yeast extract culture medium yielded 30-40 mg/L. After purification by immobilized metal ion affinity chromatography and hydrophobic interaction chromatography, the RBD protein was characterized by mass-spectrometry, circular dichroism, and binding affinity to angiotensin-converting enzyme 2 (ACE2) receptor. The recombinant protein shows high antigenicity with convalescent human sera and also with sera from individuals vaccinated with the Pfizer-BioNTech mRNA or Sputnik V adenoviral-based vaccines. The RBD protein stimulates IFN{gamma}, IL-2, IL-6, IL-4, and TNF in mice secreting splenocytes from PBMC and lung CD3+ enriched cells. Immunogenicity studies with 50 {micro}g of the recombinant RBD formulated with alum, induce high levels of binding antibodies in mice and non-human primates, assessed by ELISA plates covered with RBD protein expressed in HEK293T cells. The mouse sera inhibited the RBD binding to ACE2 receptor in an in-vitro test and show neutralization of SARS-CoV-2 infection of Vero E6 cells. These data suggest that the RBD recombinant protein expressed in yeast P. pastoris is suitable as a vaccine candidate against COVID-19. HighlightsO_LIThe RBD protein (C-RBD-H6 PP) is expressed with high purity in P. pastoris. C_LIO_LIPhysico-chemical characterization confirms the right folding of the protein. C_LIO_LIThe recombinant protein shows high antigenicity with sera from convalescents. C_LIO_LIThe sera from animals inhibit the RBD-ACE2 binding and neutralize the virus. C_LIO_LIThe C-RBD-H6 protein stimulates IFN{gamma}, IL-2, IL-6, IL-4, and TNF in mice. C_LI
RESUMO
Coronaviruses constitute a global threat to human population since three highly pathogenic coronaviruses (SARS-CoV, MERS-CoV and SARS-CoV-2) have crossed species to cause severe human respiratory disease. Considering the worldwide emergency status due to the current COVID-19 pandemic, effective pan-coronavirus antiviral drugs are required to tackle the ongoing as well as future (re)emerging virus outbreaks. Protein kinase CK2 has been deemed a promising therapeutic target in COVID-19 supported by its in vitro pharmacologic inhibition and molecular studies on SARS-CoV-2 infected cells. CIGB-325 is a first-in-class synthetic peptide impairing the CK2-mediated signaling whose safety and clinical benefit have been evidenced in Covid-19 and cancer patients after intravenous administration. Here, we explored the putative antiviral effect of CIGB-325 over MDBK cells infected by bovine coronavirus (BCoV) Mebus. Importantly, CIGB-325 inhibited both the cytopathic effect and the number of plaques forming units with a half-inhibitory concentrations IC50 = 3.5 M and 17.7 M, respectively. Accordingly, viral protein accumulation at the cytoplasm was clearly reduced by treating BCoV-infected cells with CIGB-325 over time, as determined by immunocytochemistry. Of note, data from pull-down assay followed by western blot and/or mass spectrometry identification revealed physical interaction of CIGB-325 with nucleocapsid (N) protein and a bona fide cellular CK2 substrates. Functional enrichment and network analysis from the CIGB-325 interacting proteins indicated cytoskeleton reorganization and protein folding as the most represented biological processes disturbed by this anti-CK2 peptide. Altogether, our findings not only unveil the direct antiviral activity of CIGB-325 on coronavirus infection but also provide molecular clues underlying such effect. Also, our data reinforce the scientific rationality behind the pharmacologic inhibition of CK2 to treat coronavirus infections.
RESUMO
Subunit vaccines based on the receptor-binding domain (RBD) of the spike protein of SARS-CoV-2, are among the most promising strategies to fight the COVID-19 pandemic. The detailed characterization of the protein primary structure by mass spectrometry (MS) is mandatory, as described in ICHQ6B guidelines. In this work, several recombinant RBD proteins produced in five expression systems were characterized using a non-conventional protocol known as in-solution buffer-free digestion (BFD). In a single ESI-MS spectrum, BFD allowed very high sequence coverage ([≥] 99 %) and the detection of highly hydrophilic regions, including very short and hydrophilic peptides (2-8 amino acids), the His6-tagged C-terminal peptide carrying several post-translational modifications at Cys538 such as cysteinylation, glutathionylation, cyanilation, among others. The analysis using the conventional digestion protocol allowed lower sequence coverage (80-90 %) and did not detect peptides carrying some of the above-mentioned post-translational modifications. The two C-terminal peptides of a dimer [RBD(319-541)-(His)6]2 linked by an intermolecular disulfide bond (Cys538-Cys538) with twelve histidine residues were only detected by BFD. This protocol allows the detection of the four disulfide bonds present in the native RBD and the low-abundance scrambling variants, free cysteine residues, O-glycoforms and incomplete processing of the N-terminal end, if present. Artifacts that might be generated by the in-solution BFD protocol were also characterized. BFD can be easily implemented and we foresee that it can be also helpful to the characterization of mutated RBD.
RESUMO
Controlling the global COVID-19 pandemic depends, among other measures, on developing preventive vaccines at an unprecedented pace. Vaccines approved for use and those in development intend to use neutralizing antibodies to block viral sites binding to the hosts cellular receptors. Virus infection is mediated by the spike glycoprotein trimer on the virion surface via its receptor binding domain (RBD). Antibody response to this domain is an important outcome of the immunization and correlates well with viral neutralization. Here we show that macromolecular constructs with recombinant RBD conjugated to tetanus toxoid induce a potent immune response in laboratory animals. Some advantages of the immunization with the viral antigen coupled to tetanus toxoid have become evident such as predominant IgG immune response due to affinity maturation and long-term specific B-memory cells. This paper demonstrates that subunit conjugate vaccines can be an alternative for COVID-19, paving the way for other viral conjugate vaccines based on the use of small viral proteins involved in the infection process.
RESUMO
Biological systems are not only controlled by the abundance of individual proteins, but also by the formation of complexes and the dynamics of protein-protein interactions. The identification of the components of protein complexes can be obtained by shotgun proteomics using affinity purification coupled to mass spectrometry. Such studies include the analyses of several samples and experimental controls in order to discriminate true specific interactions from unspecific interactions and contaminants. However, shotgun proteomics have limited quantification capabilities for low abundant proteins on large sample sets due to the undersampling and the stochastic precursor ion selection. In this context, targeted proteomics constitutes a powerful analytical tool to systematically detect and quantify peptides in multiple samples, for instance those obtained from affinity purification experiments. Hypothesis-driven strategies have mainly relied on the selected reaction monitoring (SRM) technique performed on triple quadrupole instruments, which enables highly selective and sensitive measurements of peptides, acting as surrogates of the pre-selected proteins, over a wide range of concentrations. More recently, novel quantitative methods based on high resolution instruments, such as the parallel reaction monitoring (PRM) technique implemented on the quadrupole-orbitrap instrument, have arisen and provided alternatives to perform quantitative analyses with enhanced selectivity.The application of targeted proteomics to protein-protein interaction experiments from plasma and other physiological fluid samples and the inclusion of parallel reaction monitoring (PRM), combined with other recent technology developments opens a vast area for clinical application of proteomics. It is anticipated that it will reveal valuable information about specific, individual, responses against drugs, exogenous proteins or pathogens.
