Abolfazl Jahangiri scite author profile

Aim: Acinetobacter baumannii, an increasingly serious health threat, is considered as one of the six most dangerous microbes of high mortality rate. However, treatment of its infections is difficult because of the lack of efficient antibiotic or commercial vaccines. Passive immunization through administration of specific antibodies such as IgY, could be an attractive practical solution. Methods and Results: In the current study, antigenicity of two recombinant outer membrane proteins (OmpA and Omp34) as well as inactivated whole cell of A. baumannii was assessed by ELISA. Moreover, prophylactic effects of specific IgY antibodies (avian antibody) raised against these antigens were evaluated in a murine pneumonia model. The specific IgY antibodies had various prophylactic effects in the pneumonia model. OmpA was the most potent antigen in terms of triggering antibody and conferring protection. While a synergic effect was observed in ELISA for antibodies raised against a combination of OmpA and Omp34 (which are known as Omp33-36 and Omp34 kDa), an antagonistic effect was unexpectedly seen in challenges. The reason for this phenomenon remains to be precisely addressed. Conclusion: All the specific IgY antibodies could protect mice against pneumonia caused by A. baumannii. Significance and Impact of the Study: The specific IgY antibodies could be employed as a pharmaceutical against pneumonia caused by A. baumannii. emergence of highly antibiotic-resistant strains including multidrug-resistant (MDR) and pan-drug-resistant strains (Wang et al. 2003;Dijkshoorn et al. 2007;Pach on and McConnell 2014). In spite of the increasing prevalence of MDR strains and their high mortality, an efficient antibiotic is not provided by the pharmaceutical industry for the treatment of its infections (Pach on and McConnell 2014). These implications highlight active and passive immunizations as cost-effective approaches to reduce the clinical and economic burden of infections caused by this notorious pathogen (Ahmad et al. 2016).

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In silico Approaches for the Design and Optimization of Interfering Peptides Against Protein–Protein Interactions

Hashemi

Zarei

Fath

et al. 2021

Front. Mol. Biosci.

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Large contact surfaces of protein–protein interactions (PPIs) remain to be an ongoing issue in the discovery and design of small molecule modulators. Peptides are intrinsically capable of exploring larger surfaces, stable, and bioavailable, and therefore bear a high therapeutic value in the treatment of various diseases, including cancer, infectious diseases, and neurodegenerative diseases. Given these promising properties, a long way has been covered in the field of targeting PPIs via peptide design strategies. In silico tools have recently become an inevitable approach for the design and optimization of these interfering peptides. Various algorithms have been developed to scrutinize the PPI interfaces. Moreover, different databases and software tools have been created to predict the peptide structures and their interactions with target protein complexes. High-throughput screening of large peptide libraries against PPIs; “hotspot” identification; structure-based and off-structure approaches of peptide design; 3D peptide modeling; peptide optimization strategies like cyclization; and peptide binding energy evaluation are among the capabilities of in silico tools. In the present study, the most recent advances in the field of in silico approaches for the design of interfering peptides against PPIs will be reviewed. The future perspective of the field and its advantages and limitations will also be pinpointed.

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In silico design of an immunogen against Acinetobacter baumannii based on a novel model for native structure of Outer membrane protein A

Jahangiri

Rasooli

Owlia

et al. 2017

Microbial Pathogenesis

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Antimicrobial peptides as a promising treatment option against Acinetobacter baumannii infections

Neshani

Sedighian

Mirhosseini

et al. 2020

Microbial Pathogenesis

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