Book Volume 9
Ribosomally Synthesized Bacteriocins as Potent Anti-infective Agents, Their Medical and Pharmaceutical Applications
Page: 1-23 (23)
Author: Atta-ur-Rahman
DOI: 10.2174/9789815179811123090001
PDF Price: $30
Abstract
The development of multidrug-resistant bacteria (MDRB) and the
emergence of new lethal diseases have raised the need for potent anti-infective agents
with different killing action mechanisms that contribute to treating and/or supporting
the currently used drugs. For this purpose, bacteriocins are considered excellent
candidates with promising potential. Bacteriocins are ribosomally synthesized
antimicrobial peptides that are produced by many bacterial genera. They are
characterized by high thermal stability, being active over a wide pH range, and having
specificity against selected bacterial strains by employing specific receptors on their
cell membrane, which encourages bacteriocins to use in clinical applications as support
and/or alternatives currently used antibiotics. Interestingly, bacteriocins have many
advantages over antibiotics, such as the relative difficulty of developing resistance
compared to broad-spectrum antibiotics. Moreover, due to their simple biosynthetic
mechanisms, bacteriocins can be easily bioengineered, which improves their activity or
specificity against selected microorganisms. Additionally, bacteriocins originating from
lactic acid bacteria have the extra safety advantage because many LAB and their
products are classified by the American Food and Drug Administration (FDA) to be
generally recognized as safe (GRAS). Bacteriocins have promising pharmaceutical
potentials as anti-infective agents, anti-MDRB agents, antileishmanial, and antiviral
agents. Moreover, bacteriocins have been used to treat many ulcers, tumors, and
cancers. In this chapter, we highlight the importance of bacteriocins as anti-infective
agents, describing their common action mechanisms and recent clinical and
therapeutical applications of bacteriocins. Finally, prospects in this field are discussed
to discover and develop more diverse and efficient bacteriocins with potent anti-infective activities.
The Place of Mature Drugs in COVID-19 Era
Page: 1-46 (46)
Author:
DOI: 10.2174/9789815179811123090002
PDF Price: $30
Abstract
COVID-19 infection, caused by the SARS-CoV-2 virus, is associated with
substantial morbidity and mortality. COVID-19 infection has three distinct phases: 1,
early infection phase; 2, pulmonary phase; and 3, the hyperinflammatory phase.
Despite a major focus on vaccines and new therapeutics, existing drugs sharing some
known mechanistic with this virus, have also gained interest. The potential positioning
of three mature innovative drugs, which could be of potential use in this pandemic
environment, is discussed in this chapter: OM-85 and calcium dobesilate, and their salt
form etamsylate, have revealed anti-viral and anti-inflammatory properties. OM-85, a
bacterial extract originating from 21 pathogenic strains isolated from human lungs and
indicated for the prevention of recurrent respiratory tract infections, stimulates both
innate and adaptive immunity, resulting in non-specific loco-regional immune
responses. It has shown anti-viral activity in a number of virus infection models,
including influenza H1N1, rhinovirus, and more recently, coronaviruses. It has also
shown some immunoregulatory properties. Accordingly, there is a rationale for further
investigations on OM-85 to be used as prophylaxis for other respiratory infections and
potentially in long-COVID. For calcium dobesilate, currently indicated for the
treatment of microvascular diseases while preserving microvascular integrity via
antioxidant and anti-inflammatory properties, there are cumulating data that could
promote its potential use for the treatment during phase 2 to protect the vascular
endothelium. Calcium dobesilate has anti-viral properties and was recently shown to
interfere with the SARS-CoV-2 spike-protein binding to the ACE2 receptor.
Accordingly, one could also postulate to use it during phase 1. Etamsylate, an anti-haemorrhagic and antiangiogenic agent that improves platelet adhesiveness and
restores capillary resistance, is indicated for the prevention and treatment of capillary
haemorrhages. Considering its mechanism of action, etamsylate could be envisage for
use as potential treatment during phase 3 for viral-induced complications. Importantly, none of these afore mentioned drugs are currently approved for the prevention or
treatment of SARS-CoV-2 viral infection. Further, the conduction of well-designed
clinical trials is warranted.
Therapeutic Interventions Against Free Radicals in Viral Diseases
Page: 1-37 (37)
Author: Christian Pasquali*, Daniel Zingg*, Stefania Ballarini*, Giovanni A. Rossi and Hermann Haller
DOI: 10.2174/9789815179811123090003
PDF Price: $30
Abstract
The delicate balance between oxidants and antioxidants is a dynamic
process, and when it hampers, oxidative stress occurs. Oxidative stress is now
suggested to have a direct correlation with a viral infection, which in turn induces
several oxidants like nitric oxide radicals, superoxide anions, hydroxyl radicals and
their by-products (viz. hydrogen peroxide). All of these oxidants and their by-products
contribute to viral pathogenesis and ultimately cause infectious diseases. The
consequences of viral diseases account for considerable economic loss worldwide. In
response to this, the scientific fraternity throughout the world is investigating the basic
mechanisms underlying such diseases, as well as identifying novel therapeutic
strategies for the prevention and treatment of such maladies. Over the last few decades,
scientists oriented their research aims mostly towards elucidating the immunological
basis of viral replication and pathogenesis, but a little is written about the implications
of such research for drug development, which provides the impetus behind the creation
of the present chapter enabling the readers to have a comprehensive overview on the
involvement of free radicals in viral diseases along with latest updates towards
developing novel therapeutic strategies against these diseases. The present chapter
summarizes the relationship between oxidative stress, viral infection, and a variety of
therapeutic strategies conferred by antioxidants. Antiviral therapeutic strategies based
on antioxidants are considered to be a promising area of research against viral
infections.
Introduction
Frontiers in Clinical Drug Research – Anti Infectives (Volume 9) is a book series that provides updated reviews on the latest advancements in development of pharmaceutical agents for treating infectious diseases. The series covers various topics, including chemistry, pharmacology, molecular biology, and biochemistry of natural and synthetic drugs. Additionally, it addresses multi-drug resistance and pre-clinical/clinical findings on antibiotics, vaccines, antifungal agents, and antitubercular drugs. This series is an invaluable resource for pharmaceutical scientists and postgraduate students, offering critical information to support clinical trials and research in anti-infective drug discovery and epidemiology. The ninth volume presents five in-depth reviews, with topics including mature drugs and antivirals for COVID-19, bacteriocins as potent anti-infective agents, therapeutic interventions targeting free radicals in viral diseases, and a detailed exploration of natural anti-infective agents. The five reviews included in this volume are: - The role of mature drugs in the COVID-19 era - Antivirals to treat COVID-19 - Ribosomally synthesized bacteriocins as potent anti-infective agents - Therapeutic interventions against free radicals in viral diseases - A comprehensive overview of natural anti-infective agents