Nadia Moretto

Conformation-sensitive Antibodies against Alzheimer Amyloid-β by Immunization with a Thioredoxin-constrained B-cell Epitope Peptide

Immunotherapy against the amyloid-β (Aβ) peptide is a valuable potential treatment for Alzheimer disease (AD). An ideal antigen should be soluble and nontoxic, avoid the C-terminally located T-cell epitope of Aβ, and yet be capable of eliciting antibodies that recognize Aβ fibrils and neurotoxic Aβ oligomers but not the physiological monomeric species of Aβ. We have described here the construction and immunological characterization of a recombinant antigen with these features obtained by tandem multimerization of the immunodominant B-cell epitope peptide Aβ1-15 (Aβ15) within the active site loop of bacterial thioredoxin (Trx). Chimeric Trx(Aβ15)n polypeptides bearing one, four, or eight copies of Aβ15 were constructed and injected into mice in combination with alum, an adjuvant approved for human use. All three polypeptides were found to be immunogenic, yet eliciting antibodies with distinct recognition specificities. The anti-Trx(Aβ15)4 antibody, in particular, recognized Aβ42 fibrils and oligomers but not monomers and exhibited the same kind of conformational selectivity against transthyretin, an amyloidogenic protein unrelated in sequence to Aβ. We have also demonstrated that anti-Trx(Aβ15)4, which binds to human AD plaques, markedly reduces Aβ pathology in transgenic AD mice. The data indicate that a conformational epitope shared by oligomers and fibrils can be mimicked by a thioredoxin-constrained Aβ fragment repeat and identify Trx(Aβ15)4 as a promising new tool for AD immunotherapy.

Potent anti-HPV immune responses induced by tandem repeats of the HPV16 L2 (20-38) peptide displayed on bacterial thioredoxin

The minor capsid protein L2 is a promising candidate for the construction of an anti-human papillomavirus (HPV) broadly protective vaccine for the prophylaxis of cervical cancer. However, L2-derived peptides are usually poorly immunogenic and extensive knowledge on the most relevant (cross)neutralizing epitope(s) is still needed. We systematically examined the immunogenicity and virus neutralization potential of six peptides encompassing the N-terminal (amino acids 1 -- 120) region of HPV16 L2 (20 -- 38; 28 -- 42; 56 -- 75; 64 -- 81; 96 -- 115; 108 -- 120) using bacterial thioredoxin (Trx) as a novel peptide scaffold. Mice antisera generated by 19 different Trx-L2 peptide fusions bearing one or multiple copies of each peptide were analyzed. Internal fusion to thioredoxin conferred strong immunogenicity to all the tested peptides, with a trend toward an increased immunogenicity for the multipeptide vs. the monopeptide forms of the various antigens. All Trx-L2 peptides induced HPV16 neutralizing antibodies in some of the immunized mice, but neutralization titers differed by more than two orders of magnitude. Trx-L2(20 -- 38) antisera were by far the most effective in HPV16 neutralization and did not differ significantly from those induced by a reference polypeptide covering the entire L2 (1 -- 120) region. The same antisera were also the most effective when challenged against the non-cognate HPV 18, 58, 45 and 31 pseudovirions. The data identify L2(20 -- 38) as the best (cross)neutralizing epitope among the six that were examined, and point to thioredoxin fusion derivatives of this peptide as excellent candidates for the formulation of a low-cost, broadly protective HPV vaccine.

A high-affinity ammonium transporter from the mycorrhizal ascomycete Tuber borchii☆

An ammonium transporter cDNA, named TbAMT1, was isolated from the ectomycorrhizal ascomycetous truffle Tuber borchii. The polypeptide encoded by TbAMT1 (52 kDa) functionally complements ammonium uptake-defective yeast mutants and shares sequence similarity with previously characterized ammonium transporters from Saccharomyces (Mep) and Arabidopsis (AtAMT1). Structural characteristics common to the Mep/Amt family and peculiar features of the Tuber transporter have been evidenced by a detailed topological model of the TbAMT1 protein, which predicts 11 transmembrane helices with an N terminus(OUT)/C terminus(IN) orientation. As revealed by uptake/competition experiments conducted in yeast, TbAMT1 is a high-affinity transporter with an apparent K(m) for ammonium of 2 microM. The TbAMT1 mRNA was very slowly, yet specifically upregulated in nitrogen-deprived T. borchii mycelia. Instead, a much faster return to basal expression levels was observed upon resupplementation of either ammonium or nitrate, which thus appear to be utilized as equally effective nitrogen sources by Tuber mycelia.

Novel Class of Benzoic Acid Ester Derivatives as Potent PDE4 Inhibitors for Inhaled Administration in the Treatment of Respiratory Diseases

The first steps in the selection process of a new anti-inflammatory drug for the inhaled treatment of asthma and chronic obstructive pulmonary disease are herein described. A series of novel ester derivatives of 1-(3-(cyclopropylmethoxy)-4-(difluoromethoxy)phenyl)-2-(3,5-dichloropyridin-4-yl) ethanol have been synthesized and evaluated for inhibitory activity toward cAMP-specific phosphodiesterase-4 (PDE4). In particular, esters of variously substituted benzoic acids were extensively explored, and structural modification of the alcoholic and benzoic moieties were performed to maximize the inhibitory potency. Several compounds with high activity in cell-free and cell-based assays were obtained. Through the evaluation of opportune in vitro ADME properties, a potential candidate suitable for inhaled administration in respiratory diseases was identified and tested in an in vivo model of pulmonary inflammation, proving its efficacy.

Discovery and optimization of thiazolidinyl- and pyrrolidinyl- derivatives as inhaled PDE4 inhibitors for respiratory diseases

Phosphodiesterase 4 (PDE4) is a key cAMP-metabolizing enzyme involved in the pathogenesis of inflammatory disease, and its pharmacological inhibition has been shown to exert therapeutic efficacy in chronic obstructive pulmonary disease (COPD). Herein, we describe a drug discovery program aiming at the identification of novel classes of potent PDE4 inhibitors suitable for pulmonary administration. Starting from a previous series of benzoic acid esters, we explored the chemical space in the solvent-exposed region of the enzyme catalytic binding pocket. Extensive structural modifications led to the discovery of a number of heterocycloalkyl esters as potent in vitro PDE4 inhibitors. (S*,S**)-18e and (S*,S**)-22e, in particular, exhibited optimal in vitro ADME and pharmacokinetics properties and dose-dependently counteracted acute lung eosinophilia in an experimental animal model. The optimal biological profile as well as the excellent solid-state properties suggest that both compounds have the potential to be effective topical agents for treating respiratory inflammatory diseases.