An engineered SARS-CoV-2 receptor-binding domain produced in Pichia pastoris as a candidate vaccine antigen.

Developing affordable and easily manufactured SARS-CoV-2 vaccines will be essential to achieve worldwide vaccine coverage and long-term control of the COVID-19 pandemic. Here the development is reported of a vaccine based on the SARS-CoV-2 receptor-binding domain (RBD), produced in the yeast Pichia pastoris. The RBD was modified by adding flexible N- and C-terminal amino acid extensions that modulate protein/protein interactions and facilitate protein purification. A fed-batch methanol fermentation with a yeast extract-based culture medium in a 50 L fermenter and an immobilized metal ion affinity chromatography-based downstream purification process yielded 30-40 mg/L of RBD. Correct folding of the purified protein was demonstrated by mass spectrometry, circular dichroism, and determinations of binding affinity to the angiotensin-converting enzyme 2 (ACE2) receptor. The RBD antigen also exhibited high reactivity with sera from convalescent individuals and Pfizer-BioNTech or Sputnik V vaccinees. Immunization of mice and non-human primates with 50 µg of the recombinant RBD adjuvanted with alum induced high levels of binding antibodies as assessed by ELISA with RBD produced in HEK293T cells, and which inhibited RBD binding to ACE2 and neutralized infection of VeroE6 cells by SARS-CoV-2. Additionally, the RBD protein stimulated IFNγ, IL-2, IL-6, IL-4 and TNFα secretion in splenocytes and lung CD3+-enriched cells of immunized mice. The data suggest that the RBD recombinant protein produced in yeast P. pastoris is suitable as a vaccine candidate against COVID-19.

Caracterización del polirribosilribitol fosfato por cromatografía de exclusión molecular de alta eficacia con detección ultravioleta / Characterization of polyribosylribitol phosphate by high efficiency size exclusion chromatography with ultraviolet detection

Haemophilus influenzae tipo b es un importante patógeno del hombre causante de varias de las enfermedades invasivas en niños menores de cinco años, contra el cual fueron autorizadas las vacunas glicoconjugadas a partir del polirribosilribitol fosfato. Quimi-Hib® es la primera y única vacuna contra este patógeno que utiliza el polisacárido obtenido por síntesis química. El Ingrediente Farmacéutico Activo es producido por el Centro de Ingeniería Genética y Biotecnología y se obtiene a partir de su conjugación al toxoide tetánico. En el presente reporte se hizo una caracterización del polirribosilribitol fosfato mediante la técnica de cromatografía de exclusión molecular de alta eficacia con detección ultravioleta a 215 nm. En el estudio se evaluaron tres lotes y se determinó el perfil de elución en una columna SuperdexTM 75 10/300 GL Increase con un porciento de pureza de 77,42 ± 8,97 y una masa molar promedio de 7.381 Da ± 210,93. La principal impureza presente en el polirribosilribitol fosfato es el dimetilsulfóxido, disolvente utilizado en la reacción de activación con el éster N-hidroxisuccinimidilo del ácido β-maleimidopropiónico. El polirribosilribitol fosfato se purificó por filtración con un Amicon Ultra-15 de 2.000 Da hasta una pureza de 99,1 por ciento y se conjugó al toxoide tetánico. El rendimiento de la reacción de conjugación con el polisacárido purificado fue de 30,0 por ciento 1,77 el cual no muestra diferencias significativas con el control que fue 33,7 por ciento ± 3,57 demostrándose que el dimetilsulfóxido no afecta el desempeño de la reacción de conjugación(AU)

Haemophilus influenzae type b is an important human pathogen causing some invasive diseases in children less than five years of age. Glycoconjugate vaccines based on polyribosylribitol phosphate have been licensed against this bacterium. Quimi-Hib® is the first and only vaccine against this pathogen using the chemically synthesized polysaccharide. The Active Pharmaceutical Ingredient is produced by the Center for Genetic Engineering and Biotechnology and is obtained from its conjugation to tetanus toxoid. In the present report a characterization of polyribosylribitol phosphate was performed by high performance molecular exclusion chromatography with ultraviolet detection at 215 nm. Three batches were evaluated in the study and the elution profile was determined on a SuperdexTM 75 10/300 GL Increase column with a purity percentage of 77.42 ± 8.97 and an average molecular weight of 7,381 Da ± 210.93. The main impurity present in polyribosylribitol phosphate was dimethylsulfoxide, the solvent used in the activation reaction with N-hydroxysuccinimidyl ester of β-maleimidopropionic acid. Polyribosylribitol phosphate was purified by filtration using a 2,000 Da cut-off Amicon Ultra-15 to a purity of 99.1 percent and conjugated to tetanus toxoid. The yield of the conjugation reaction with the purified polysaccharide was 30.0 percent ± 1.77 which shows no significant difference with the control which was 33.7 percent ± 3.57 demonstrating that dimethylsulfoxide does not affect the performance of the conjugation reaction(AU)

d-Amino acid substitutions and dimerization increase the biological activity and stability of an IL-15 antagonist peptide.

Interleukin (IL)-15 plays an important role in several inflammatory diseases. We have previously identified an IL-15 antagonist called P8 peptide, which binds specifically to IL-15 receptor alpha subunit. However, the P8 peptide rapidly degraded by proteases, limiting its therapeutic application. Thus, we replaced each P8 peptide l-amino acid by its corresponding d-isomers. First, we determined the biological activity of the resulting peptides in a proliferation assay by using CTLL-2 cells. The substitution of l-Ala by d-Ala ([A4a]P8 peptide) increased the inhibitory effect of the P8 peptide in CTLL-2 cells in five-fold. In addition to that, the [A4a]P8 peptide dimer showed the most inhibitory effect. To protect the [A4a]P8 peptide and its dimer against exopeptidase activity, we acetylated the N-terminal of these peptides. At least a three-fold reduction in antagonist activity of acetylated peptides was exhibited. However, the substitution of the N-terminal l-Lys residue of [A4a]P8 peptide and its dimer by d-Lys ([K1k;A4a]P8 peptide) did not affect the antagonist effect of the aforementioned peptides. The [K1k;A4a]P8 peptide dimer was stable to the degradation of trypsin, chymotrypsin, and pepsin up until 48 min. Also, the safety and immunogenicity studies in healthy BALB/c mice demonstrated that the administration of this peptide did not affect the clinical parameters of the animals nor generated antipeptide antibodies. Our findings reveal that two distinct d-amino acid substitutions and dimerization increase the biological activity and stability of P8 peptide. The resulting peptide constitutes a novel IL-15 antagonist with potential applicability in inflammatory diseases.

In vitro and in vivo characterization of an interleukin-15 antagonist peptide by metabolic stability, 99m Tc-labeling, and biological activity assays.

Interleukin (IL)-15 is an inflammatory cytokine that constitutes a validated therapeutic target in some immunopathologies, including rheumatoid arthritis (RA). Previously, we identified an IL-15 antagonist peptide named [K6T]P8, with potential therapeutic application in RA. In the current work, the metabolic stability of this peptide in synovial fluids from RA patients was studied. Moreover, [K6T]P8 peptide was labeled with 99m Tc to investigate its stability in human plasma and its biodistribution pattern in healthy rats. The biological activity of [K6T]P8 peptide and its dimer was evaluated in CTLL-2 cells, using 3 different additives to improve the solubility of these peptides. The half-life of [K6T]P8 in human synovial fluid was 5.88 ± 1.73 minutes, and the major chemical modifications included peptide dimerization, cysteinylation, and methionine oxidation. Radiolabeling of [K6T]P8 with 99m Tc showed a yield of approximately 99.8%. The 99m Tc-labeled peptide was stable in a 30-fold molar excess of cysteine and in human plasma, displaying a low affinity to plasma proteins. Preliminary biodistribution studies in healthy Wistar rats suggested a slow elimination of the peptide through the renal and hepatic pathways. Although citric acid, sucrose, and Tween 80 enhanced the solubility of [K6T]P8 peptide and its dimer, only the sucrose did not interfere with the in vitro proliferation assay used to assess their biological activity. The results here presented, reinforce nonclinical characterization of the [K6T]P8 peptide, a potential agent for the treatment of RA and other diseases associated with IL-15 overexpression.

Development and validation of a bioanalytical method based on LC-MS/MS analysis for the quantitation of CIGB-814 peptide in plasma from Rheumatoid Arthritis patients.

CIGB-814, originally named as E18-3 APL1 or APL1 in preclinical experiments, is a novel therapeutic peptide candidate for Rheumatoid Arthritis (RA). It is an altered peptide ligand containing a novel CD4+ T-cell epitope of human heat shock protein 60 (83-109, MW 2988.38g/mol) with a mutation (D100→L) that increases its affinity for HLA-II type molecules associated to RA. A bioanalytical method, based on LC-MS/MS analysis, in the SRM mode was developed and fully validated to quantify this peptide in human plasma. An internal standard with the same amino acid sequence but labeled with three (13C615N2)-Lys residues was used for quantitation. The method provides a linear range from 1.5 to 48ng/mL (without matrix effect and carry over) and an accuracy and precision good enough for monitoring more than 80% of the AUC of the PK profile in a phase I clinical trial. The peptide was administered subcutaneously in three dose levels (1, 2.5 and 5mg) not normalized to the body weight of patients with RA. The low doses imposed an analytical challenge; however, a LLOQ of 1.5ng/mL enabled the PK analysis. The Cmax, reached at 0.5h, showed a great variability, that was most likely due to the non-normalized doses; the proposed mechanism for this peptide; and the variability between patients. A rapid clearance of this peptide (4-6h) is advantageous for an immunomodulatory drug, because the therapeutic schedule requires repeated dosages to restore peripheral tolerance.

Bio-analytical method based on MALDI-MS analysis for the quantification of CIGB-300 anti-tumor peptide in human plasma.

A fully validated bio-analytical method based on Matrix-Assisted-Laser-Desorption/Ionization-Time of Flight Mass Spectrometry was developed for quantitation in human plasma of the anti-tumor peptide CIGB-300. An analog of this peptide acetylated at the N-terminal, was used as internal standard for absolute quantitation. Acid treatment allowed efficient precipitation of plasma proteins as well as high recovery (approximately 80%) of the intact peptide. No other chromatographic step was required for sample processing before MALDI-MS analysis. Spectra were acquired in linear positive ion mode to ensure maximum sensitivity. The lower limit of quantitation was established at 0.5 µg/mL, which is equivalent to 160 fmol peptide. The calibration curve was linear from 0.5 to 7.5 µg/mL, with R(2)>0.98, and permitted quantitation of highly concentrated samples evaluated by dilution integrity testing. All parameters assessed for five validation batches met the FDA guidelines for industry. The method was successfully applied to analysis of clinical samples obtained in a phase I clinical trial following intravenous administration of CIGB-300 at a dose of 1.6 mg/kg body weight. With the exception of Cmax and AUC, pharmacokinetic parameters were similar for ELISA and MALDI-MS methods.

Antitumor efficacy, pharmacokinetic and biodistribution studies of the anticancer peptide CIGB-552 in mouse models.

Accumulation of the COMMD1 protein as a druggable pharmacology event to target cancer cells has not been evaluated so far in cancer animal models. We have previously demonstrated that a second-generation peptide, with cell-penetrating capacity, termed CIGB-552, was able to induce apoptosis mediated by stabilization of COMMD1. Here, we explore the antitumor effect by subcutaneous administration of CIGB-552 in a therapeutic schedule. Outstandingly, a significant delay of tumor growth was observed at 0.2 and 0.7 mg/kg (p < 0.01) or 1.4 mg/kg (p < 0.001) after CIGB-552 administration in both syngeneic murine tumors and patient-derived xenograft models. Furthermore, we evidenced that (131)I-CIGB-552 peptide was actually accumulated in the tumors after administration by subcutaneous route. A typical serine-proteases degradation pattern for CIGB-552 in BALB/c mice serum was identified. Further, biological characterization of the main metabolites of the peptide CIGB-552 suggests that the cell-penetrating capacity plays an important role in the cytotoxic activity. This report is the first in describing the antitumor effect induced by systemic administration of a peptide that targets COMMD1 for stabilization. Moreover, our data reinforce the perspectives of CIGB-552 for cancer targeted therapy.

Lysine N(epsilon)-trimethylation, a tool for improving the selectivity of antimicrobial peptides.

The effects of lysine N(epsilon)-trimethylation at selected positions of the antimicrobial cecropin A-melittin hybrid peptide KWKLFKKIGAVLKVL-amide have been studied. All five monotrimethylated, four bis-trimethylated plus the per-trimethylated analogues have been synthesized and tested for antimicrobial activity on Leishmania parasites and on Gram-positive and -negative bacteria, as well as for hemolysis of sheep erythrocytes as a measure of cytotoxicity. The impact of trimethylation on the solution conformation of selected analogues has been evaluated by NMR, which indicates a slight decrease in the alpha-helical content of the modified peptides, particularly in the N-terminal region. Trimethylation also enhances the proteolytic stability of mono- and bis-trimethylated analogues by 2-3-fold. Although it tends to lower antimicrobial activity in absolute terms, trimethylation causes an even higher decrease in hemolytic activity and therefore results in improved selectivity for several analogues. The monotrimethylated analogue at position 6 shows the overall best selectivity against both the Leishmania donovani protozoan and Acinetobacter baumannii, a Gram-negative bacterium of increasing clinical concern.