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Anti-Infective
Agents in Medicinal Chemistry
ISSN: 1871-5214
Anti-Infective Agents in Medicinal
Chemistry
Volume 6, Number 4, October 2007
Contents
Two Different Functions of Doxycycline Which is Both
An Antimicrobial Agent and An Immune Modulator Pp.
222-227
Masaki Fujita and Yoichi Nakanishi
[Abstract]
New Developments in Therapeutic Agents for Legionnaires’
Disease Pp. 228-242
Jorge Roig, Josep M. Arnau, Antoni Vallano and Jordi Rello
[Abstract]
Antibacterial Agents Against Methicillin-Resistant
Staphylococcus aureus (MRSA) and Vancomycin-Resistant
Enterococci (VRE) Pp. 243-247
Miguel O. Mitchell
[Abstract]
Inhibition of Membrane Fusion as a Target for Antiviral
Therapy Pp. 248-262
Richard K. Plemper and Anthea L. Hammond
[Abstract]
Antiidiotype-Derived Killer Peptides As New Potential
Tools to Combat HIV-1 and AIDS-Related Opportunistic Pathogens
Pp. 263-272
W. Magliani, S. Conti, D.L. Maffei, L. Ravanetti and L.
Polonelli
[Abstract]
Structure-Function Relationship of Thiazolides, a Novel Class
of Anti-Parasitic Drugs, Investigated in Intracellular and
Extracellular Protozoan Parasites and Larval-Stage Cestodes
Pp. 273-282
Andrew Hemphill, Norbert Müller and Joachim Müller
[Abstract]
Abstracts
[Back to top]
Two Different Functions of Doxycycline Which
is Both An Antimicrobial Agent and An Immune Modulator
Masaki Fujita and Yoichi Nakanishi
Doxycycline is a semi-synthetic tetracycline, which was invented
and clinically developed in the early 1960s. Doxycycline works
by inhibiting protein synthesis and it is also bacteriostatic.
Doxycycline is highly effective against all of the common
pathogens that cause upper respiratory tract infections. Doxycycline
is particularLY effective for the treatment of atypical pneumonia
due to Mycoplasma, Chlamydia and Legionella.
Recently, doxycycline has been reported to have a biological
function apart from its antimicrobial function. Doxycycline
is known to inhibit the release of reactive oxygen species,
while also inducing apoptosis, decreasing neutrophil chemotaxis
and inhibiting matrix metalloproteinases. Regarding animal
models, doxycycline is able to attenuate lung inflammation
caused by several agents. Recently, several clinical trials
using doxycycline have also been reported.
In this review, we provide a comprehensive, yet concise analysis
of the two different functions of doxycycline, while particularly
focusing on respiratory diseases.
[Back to top]
New Developments in Therapeutic Agents for Legionnaires’
Disease
Jorge Roig, Josep M. Arnau, Antoni Vallano and Jordi Rello
Legionella spp have been identified in many series as responsible
for a variable percentage of community-acquired pneumonia
(CAP) and for some outbreaks of hospital-acquired pneumonia
(HAP). In many geographic areas Legionella ranks second to
pneumococcus on the list of causes of severe CAP (SCAP). Therapeutic
approach remains an important goal since the case-fatality
rate is 5% to 30%, with elderly and immunocompromised patients
at greatest risk of death. Clinicians should be aware of either
dual or mixed infections and extrapulmonary localizations
of Legionella since mortality may increase if these features
continue unrecognized. Optimal therapy against Legionella
infection is based on agents with high intrinsic activity,
an appropriate pharmacokinetic and pharmacodynamic profile,
including the ability to penetrate phagocytic cells, results
of clinical studies, a low incidence of adverse reactions
and an advantageous cost-efficacy relationship. Macrolides
and fluoroquinolones are the first-line therapy. Azithromycin
and clarithromycin present a better pharmacokinetic profile
than erythromycin. The more recent fluoroquinolones, such
as gemifloxacin or moxifloxacin generally show a better intrinsic
activity than the older ones but the clinical relevance of
that data is unclear since most patients with Legionnaires’
disease show a positive outcome when an early administration
of any effective anti-Legionella agent is indicated. Doxycycline
also demonstrates a good intrinsic activity against Legionella.
Recently marketed or under investigation anti-Legionella agents
are ketolides (telithromycin or cethromycin), new fluorquinolones
(garenoxacin, olamufloxacin, ABT-492, DW 286a), glycyclynes
(tygecycline) and everninomycins (ziracin). Although these
new therapeutic agents might be effective in treating pneumonia
caused by Legionella, clinical experience of them is still
quite limited. Combined therapy of rifampicin with macrolides
or quinolones is still a controversial issue.
[Back to top]
Antibacterial Agents Against Methicillin-Resistant
Staphylococcus aureus (MRSA) and Vancomycin-Resistant
Enterococci (VRE)
Miguel O. Mitchell
The emergence of nosocomial infections caused by methicillin-resistant
Staphylococcus aureus (MRSA) and vancomycin-resistant
Enterococci (VRE) has prompted research directed
at the development of novel antibacterial agents to treat
these diseases. This review will examine the literature on
anti-MRSA and anti-VRE antibacterial research published between
2001 and October 2006.
[Back to top]
Inhibition of Membrane Fusion as a Target for Antiviral
Therapy
Richard K. Plemper and Anthea L. Hammond
Entry of enveloped viruses into cells is initiated by virus
binding to a target cell receptor. Subsequent conformational
changes in the viral envelope proteins are triggered either
by receptor binding or by the low pH of the endosome, depending
on the virus family, and facilitate fusion, or merging of
the viral and host cell membranes. This allows transfer of
the viral genome into the target cell, initiating a new infectious
cycle. Inhibitors of viral entry constitute a novel class
of antivirals that target discrete steps of this process.
Although long-studied for their antiviral potential, entry
inhibitors have only recently been brought to market with
the licensing of the first-in-class HIV fusion inhibitor T-20
(enfuvirtide, Fuzeon). Entry inhibitors are currently in development
against major human and animal pathogens such as HIV, SARS
coronavirus, and members of the paramyxovirus family including,
amongst others, measles, respiratory syncytial virus (RSV),
and Nipah virus. This antiviral class includes antibodies,
peptides, and non-peptidic small molecules that act on different
steps of the entry process. This review will concentrate on
peptidic and non-peptidic inhibitors of viral entry, and describe
their mechanisms of action and current development status.
Particular emphasis will be given to the development of peptidic
and small molecule inhibitors of membrane fusion.
[Back to top]
Antiidiotype-Derived Killer Peptides As New Potential
Tools to Combat HIV-1 and AIDS-Related Opportunistic Pathogens
W. Magliani, S. Conti, D.L. Maffei, L. Ravanetti and L.
Polonelli
This review describes the novel experimental observations
on antimicrobial and antiviral activities of a synthetic killer
peptide (KP), derived from the variable region of a recombinant
antiidiotypic antibody mimicking a wide-spectrum microbicidal
yeast killer toxin (KT). The rationale, generation and experimental
use of KT-like antiidiotypic microbicidal antibodies and mimotopes
against the opportunistic pathogen Candida albicans
were previously discussed. Recently, KP has demonstrated an
in vitro microbicidal activity against such diverse
AIDS-related pathogens as Cryptococcus neoformans, Pneumocystis
carinii, Paracoccidioides brasiliensis, Acanthamoeba castellanii,
Leishmania major and L. infantum, Mycobacterium tuberculosis
and other bacteria. KP also demonstrated a significant
therapeutic effect against experimental vaginal and systemic
candidiasis, disseminated cryptococcosis, and paracoccidioidomycosis.
The observation that KP may inhibit ex-vivo HIV-1
replication, opens new perspectives in the simultaneous treatment
of HIV-1 and AIDS-related opportunistic pathogens. Despite
the advent of highly active antiretroviral therapy (HAART)
has dramatically improved the prognosis and quality of life
of HIV-infected people, opportunistic infections still remain
the most common cause of death. Current combination regimens,
moreover, remain hampered by issues of patient compliance,
tolerance, long term toxicity, incomplete viral suppression,
and drug resistance, which are often responsible for therapy
failure. There is an urgent need for new therapeutic strategies
in AIDS. The potential use of KP, endowed with minimal toxicity,
ease of production and manipulation (such as its production
in planta), differential antimicrobial and antiviral
mecha-nism of action, and modulation of immune cell populations
are discussed.
[Back to top]
Structure-Function Relationship of Thiazolides, a Novel Class
of Anti-Parasitic Drugs, Investigated in Intracellular and
Extracellular Protozoan Parasites and Larval-Stage Cestodes
Andrew Hemphill, Norbert Müller and Joachim Müller
The thiazolide nitazoxanide (2-acetolyloxy-N-(5-nitro 2-thiazolyl)
benzamide; NTZ) is a compound that has been synthesized based
on the structures of niclosamide (antihelminthic) and metronidazole
(anti-anaerobic). It is essentially composed of a nitrothiazolering
and a salicylic acid moiety, which are linked together through
an amide bond. NTZ exhibits a broad spectrum of activities
against a wide range of intestinal and tissue-dwelling helminths,
protozoa, and enteric bacteria infecting animals and humans.
The drug has been postulated to act via reduction of its nitro-group
by nitroreductases including pyruvate ferredoxin oxidoreductase
(PFOR), which would then generate a toxic radical that could
have anti-parasitic and anti-bacterial activities. However,
experimental evidence for this mode of action is lacking.
Instead, the drug has been shown to inhibit the functional
activity of PFOR in several extracellular anaerobic organisms,
but the activity against intracellular pathogens appears to
be based on (an)other mechanism(s) of action. Since the first
synthesis of the drug, a number of derivatives of NTZ have
been produced, which are collectively named thiazolides. These
are modified versions of NTZ, which include the replacement
of the nitro-thiazole with other functional groups, and the
differential positioning of methyl- and methoxy-groups on
the salicylate ring. Investigations on the activities of these
thia-zolides were carried out by studying morphological and
ultrastructural changes upon drug treatments, by defining
physiological alterations, and by applying biochemical and
genetic approaches to identify respective targets and the
molecular basis of resistance formation. Collectively, these
studies strongly suggest that NTZ and other thiazolides exhibit
multiple mechanisms of action, targeting differential metabolic
pathways, and each acting specifically against intracellular
and extracellular pathogens, respectively. This could explain
the broad range of activities (anti-parasitic, anti-bacterial
and anti-viral) of the thiazolide class.
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