Bernadett Bacsa

Direct Solid-Phase Synthesis of the β-Amyloid (1—42) Peptide Using Controlled Microwave Heating

Standard linear Fmoc/t-Bu solid-phase synthesis of the 42-mer beta-amyloid (1-42) peptide was achieved under controlled microwave conditions at 86 degrees C using inexpensive DIC/HOBt as coupling reagent on ChemMatrix resin. In order to avoid racemization of the sensitive amino acids, the coupling of the three His residues in the difficult peptide sequence was performed at room temperature. The desired peptide was obtained within 15 h overall processing time in high yield and purity (78% crude yield).

Rapid solid-phase synthesis of a calmodulin-binding peptide using controlled microwave irradiation

A rapid and efficient microwave-assisted solid-phase synthesis method for the preparation of a nonapeptide using conventional Fmoc/But orthogonal protection strategy is described. In this protocol, the coupling steps are performed within 5 min at 60 °C and the Fmoc-deprotection steps are completed within 3 min at 60 °C using a dedicated single-mode microwave peptide synthesizer utilizing temperature-controlled conditions. It is demonstrated that the model nonapeptide (containing the calmodulin-binding octapeptide sequence) is synthesized in a shorter time (∼3.5 h) and with high purity (>95%) under microwave irradiation conditions in comparison with a reference peptide that is obtained by standard methods at room temperature (within 11 h).

Nanoparticle Encapsulated Lipopeptide Conjugate of Antitubercular Drug Isoniazid: In Vitro Intracellular Activity and in Vivo Efficacy in a Guinea Pig Model of Tuberculosis

Considering that Mycobacterium tuberculosis (Mtb) can survive in host phagocytes for decades and currently applied drugs are largely ineffective in killing intracellular Mtb, novel targeted delivery approaches to improve tuberculosis chemotherapy are urgently needed. In order to enhance the efficacy of a clinically used antitubercular agent (isoniazid, INH) a novel lipopeptide carrier was designed based on the sequence of tuftsin, which has been reported as a macrophage-targeting molecule. The conjugate showed relevant in vitro activity on Mtb H37Rv culture with low cytotoxicity and hemolytic activity on human cells. The conjugate directly killed intracellular Mtb and shows much greater efficacy than free INH. To improve bioavailability, the conjugate was encapsulated into poly(lactide-co-glycolide) (PLGA) nanoparticles and tested in vivo in a guinea pig infection model. External clinical signs, detectable mycobacterial colonies in the organs, and the histopathological findings substantiate the potent chemotherapeutic effect of orally administered conjugate-loaded nanoparticles.

Enhanced cellular uptake of a new, in silico identified antitubercular candidate by peptide conjugation

Mycobacterium tuberculosis is a successful pathogen, and it can survive in infected macrophages in dormant phase for years and decades. The therapy of tuberculosis takes at least six months, and the slow-growing bacterium is resistant to many antibiotics. The development of novel antimicrobials to counter the emergence of bacteria resistant to current therapies is urgently needed. In silico docking methods and structure-based drug design are useful bioinformatics tools for identifying new agents. A docking experiment to M. tuberculosis dUTPase enzyme, which plays a key role in the bacterial metabolism, has resulted in 10 new antitubercular drug candidates. The uptake of antituberculars by infected macrophages is limited by extracellular diffusion. The optimization of the cellular uptake by drug delivery systems can decrease the used dosages and the length of the therapy, and it can also enhance the bioavailability of the drug molecule. In this study, improved in vitro efficacy was achieved by attaching the TB5 antitubercular drug candidate to peptide carriers. As drug delivery components, (i) an antimicrobial granulysin peptide and (ii) a receptor specific tuftsin peptide were used. An efficient synthetic approach was developed to conjugate the in silico identified TB5 coumarone derivative to the carrier peptides. The compounds were effective on M. tuberculosis H37Rv culture in vitro; the chemical linkage did not affect the antimycobacterial activity. Here, we show that the OT20 tuftsin and GranF2 granulysin peptide conjugates have dramatically enhanced uptake into human MonoMac6 cells. The TB5-OT20 tuftsin conjugate exhibited significant antimycobacterial activity on M. tuberculosis H37Rv infected MonoMac6 cells and inhibited intracellular bacteria.

Population tailored modification of tuberculosis specific interferon-gamma release assay

Summary Objectives Blood-based Interferon-Gamma Release Assays (IGRA) identify Mycobacterium tuberculosis (MTB) sensitisation with increased specificity, but sensitivity remains impaired in human immunodeficiency virus (HIV) infected persons. The QuantiFERON-TB Gold In-Tube test contains peptide 38–55 of Rv2654c, based on data indicating differential recognition between tuberculosis patients and BCG vaccinated controls in Europe. We aimed to fine map the T cell response to Rv2654c with the view of improving sensitivity. Methods Interferon-gamma ELISpot assay was used in HIV uninfected persons with latent and active tuberculosis to map peptide epitopes of Rv2654c. A modified IGRA was tested in two further groups of 55 HIV uninfected and 44 HIV infected persons, recruited in South Africa. Results The most prominently recognised peptide was between amino acids 51–65. Using p51-65 to boost the QuantiFERON-TB Gold In-Tube assay, the quantitative performance of the modified IGRA increased from 1.83 IU/ml (IQR 0.30–7.35) to 2.83 (IQR 0.28–12.2; p = 0.002) in the HIV uninfected group. In the HIV infected cohort the percentage of positive responders increased from 57% to 64% but only after 3 months of ART (p = ns). Conclusions Our data shows the potential to population tailor detection of MTB sensitization using specific synthetic peptides and interferon-gamma release in vitro.