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Current
Medicinal Chemistry
ISSN: 0929-8673
Current Medicinal Chemistry
Volume 15, Number 7, 2008
Contents
Malignant Mesothelioma Resistance to Apoptosis: Recent Discoveries
and their Implication for Effective Therapeutic Strategies
Pp. 631-641
F. Villanova, A. Procopio and M. R. Rippo
[Abstract]
The Role of 11Beta-Hydroxysteroid Dehydrogenase
in Metabolic Disease and Therapeutic Potential of 11Beta HSD1
Inhibitors Pp. 642-649
Eddine Saiah
[Abstract]
Nicotinamide Adenine Dinucleotide Based Therapeutics
Pp. 650-670
L. Chen, R. Petrelli, K. Felczak, G. Gao, L. Bonnac, J.S.
Yu, E.M. Bennett and K.W. Pankiewicz
[Abstract]
Therapeutic Potential of Group III Metabotropic
Glutamate Receptors Pp. 671-684
Hilde Lavreysen and Frank M. Dautzenberg
[Abstract]
Polyelectrolyte Multilayer Films: From Physico-Chemical
Properties to the Control of Cellular Processes Pp.
685-697
Catherine Picart
[Abstract]
The Role of Oxytocin in Neuropsychiatric Disorders
Pp. 698-704
D. Marazziti and M. Catena Dell’Osso
[Abstract]
Platensimycin: A Promising Antimicrobial Targeting
Fatty Acid Synthesis Pp. 705-710
D.T. Manallack, I.T. Crosby, Y. Khakham and B. Capuano
[Abstract]
A Possible Placental Factor for Preeclampsia:
sFlt-1 Pp. 711-715
Naoko Kita and Junji Mitsushita
[Abstract]
Lung Transplantation: The Role of Azithromycin
in the Management of Patients with Bronchiolitis Obliterans
Syndrome Pp. 716-723
A.M. Fietta and F. Meloni
[Abstract]
Expression, Regulation and Function of Asporin,
A Susceptibility Gene in Common Bone and Joint Diseases
Pp. 724-728
Shiro Ikegawa
[Abstract]
Abstracts
[Back to top]
Malignant Mesothelioma Resistance to Apoptosis: Recent Discoveries
and their Implication for Effective Therapeutic Strategies
F. Villanova, A. Procopio and M. R. Rippo
Malignant Mesothelioma is an aggressive and fatal type
of tumor. The incidence of mesothelioma has increased in the
past 30 years and is now common as male cancers of the liver,
bone and bladder, especially in Europe and Australia. The
main risk factor is asbestos exposure even if other co-factor,
such as simian virus 40 (SV40) could be implied in its etiology.
Unfortunately, its incidence is expected to continue to increase
for the next decades, also in rapidly industrializing countries,
such as India, where it is not recognised as an occupational
disease. Furthermore, some disastrous events, such as the
World Trade Center Disaster, may contribute to increase future
risk for mesothelioma. The treatment-resistant phenotype of
mesothelioma is largely due to its ability to escape from
the highly regulated apoptotic machinery. The understanding
of the molecular mechanisms responsible of the malignant mesothelioma
resistance to apoptosis is now advancing, allowing developing
new therapeutic strategies to change the natural history and
improve survival of patients. This review gives an overview
of the main anti-apoptotic strategies devised by malignant
mesothelioma and the therapeutic implication and opportunities
for this cancer.
[Back to top]
The Role of 11Beta-Hydroxysteroid Dehydrogenase
in Metabolic Disease and Therapeutic Potential of 11Beta-HSD1
Inhibitors
Eddine Saiah
Glucocorticoids play an essential role in the regulation
of multiple physiological processes, including energy metabolism,
maintenance of blood pressure and stress responses, as well
as cognitive functions. On a tissue-specific level, glucocorticoid
action is controlled by 11beta-hydroxysteroid dehydrogenase
enzymes. The type 1 enzyme (11beta-HSD1) is a NADP(H)-dependent
bidirectional enzyme in vitro and reduces cortisone
to active cortisol in vivo. 11beta-HSD1 is expressed
in many tissues including the liver, adipose and skeletal
muscles. Chronically elevated local glucocorticoid action
as a result of increased 11beta-HSD1 activity has been associated
with the metabolic syndrome, which is characterized by obesity,
insulin resistance, type 2 diabetes and cardiovascular complications.
Recent studies indicate that the inhibition of 11beta-HSD1
mitigates the adverse effects of excessive glucocorticoid
levels on metabolic parameters and provides promising opportunities
for the development of therapeutic interventions. This review
discusses recently disclosed 11beta-HSD1 inhibitors and their
potential for the treatment of metabolic disorders.
[Back to top]
Nicotinamide Adenine Dinucleotide Based Therapeutics
L. Chen, R. Petrelli, K. Felczak, G. Gao, L. Bonnac, J.S.
Yu, E.M. Bennett and K.W. Pankiewicz
Nicotinamide adenine dinucleotide (NAD), generally considered
a key component involved in redox reactions, has been found
to participate in an increasingly diverse range of cellular
processes, including signal transduction, DNA repair, and
post-translational protein modifications. In recent years,
medicinal chemists have become interested in the therapeutic
potential of molecules affecting interactions of NAD with
NAD-dependent enzymes. Also, enzymes involved in de novo
biosynthesis, salvage pathways, and down-stream utilization
of NAD have been extensively investigated and implicated in
a wide variety of diseases. These studies have bolstered NAD-based
therapeutics as a new avenue for the discovery and development
of novel treatments for medical conditions ranging from cancer
to aging. Industrial and academic groups have produced structurally
diverse molecules which target NAD metabolic pathways, with
some candidates advancing into clinical trials. However, further
intensive structural, biological, and medical studies are
needed to facilitate the design and evaluation of new generations
of NAD-based therapeutics. At this time, the field of NAD-therapeutics
is most likely at a stage similar to that of the early successful
development of protein kinase inhibitors, where analogs of
ATP (a more widely utilized metabolite than NAD) began to
show selectivity against target enzymes. This review focuses
on key representative opportunities for research in this area,
which extends beyond the scope of this article.
[Back to top]
Therapeutic Potential of Group III Metabotropic Glutamate
Receptors
Hilde Lavreysen and Frank M. Dautzenberg
Metabotropic glutamate (mGlu) receptors have received
much attention, driven by a strong belief in the potential
of these modulatory glutamate receptors as drug targets. So
far, major drug discovery programs have largely focused on
group I (mGlu1 and 5) and II (mGlu2 and 3) mGlu receptors,
which have been implicated in neuropathological and various
psychiatric disorders. The four group III representatives
(mGlu4, mGlu6, mGlu7 and mGlu8) are less understood, mainly
due to the paucity of specific compounds. Recent advances
in the identification of selective or specific compounds,
and the generation of transgenic animals have, however, revealed
important insights into the potential role of group III receptors
in the pathophysiology of neurological and mood disorders.
Activation of the mGlu4 receptor seems to be beneficial for
treating Parkinson-like symptoms and a potential role in the
treatment of mood disorders is slowly growing. Similarly,
genetic inactivation studies and usage of relatively selective
agonists strongly support the involvement of the mGlu8 receptor
for anxiety disorders. In contrast, controversial data have
been obtained for the mGlu7 receptor. While mGlu7 receptor-deficient
animals show an anxiolytic profile in several in vivo
readouts, the first selective allosteric agonist AMN082 has
also been reported to improve anxiety-like behaviour despite
activating the stress axis. The least investigated receptor
remains the mGlu6 receptor, which is mostly based on its predominant
expression in the retina.
[Back to top]
Polyelectrolyte Multilayer Films: From Physico-Chemical Properties
to the Control of Cellular Processes
Catherine Picart
Polyelectrolyte multilayer films have been well characterized
for almost two decades and there is now a growing interest
for the development of biomimetic films that could be used
in vitro or in vivo to control cellular behaviors. In this
review, the important properties of multilayer films designed
for cell/surface interactions will be highlighted. The first
part will deal with the physico-chemical properties of polypeptide
and polysaccharide multilayer films, including their growth,
swellability, stability and mechanical properties. In the
second part, we will focus on important properties influencing
cellular behaviors: i) film biodegradability, ii) film mechanical
properties, iii) film bioactivity achieved by either the intrinsic
properties of the film components or the insertion of small
peptides, proteins, or DNA. In particular, films thicker than
one micron are particularly well suited for loading bioactive
molecules due to their reservoir capacities.
[Back to top]
The Role of Oxytocin in Neuropsychiatric Disorders
D. Marazziti and M. Catena Dell’Osso
Oxytocin (OT) is a neurohypophysial hormone synthesized
in the paraventricular and supraoptic nuclei of the hypothalamus.
Although OT-like substances have been identified in all vertebrates,
OT has been found only in mammals where it plays a major role
in the onset and maintaining of behaviors which are typical
of these animals, such as labour and lactation. Recently,
several data have suggested the involvement of OT in the formation
of infant attachment, maternal behavior, pair bonding and,
more generally, in linking social signals with cognition,
behaviors and reward.
The aim of this paper was to review critically the role of
OT in the regulation of different physiological functions
and complex behaviors, as well as its possible involvement
in the pathophysiology of some neuropsychiatric disorders.
MEDLINE and PubMed (1972-2007) databases were searched for
English language articles by using the following keywords:
oxytocin, physiology, cognitive functions, attachment, psychopathology,
psychiatric disorders. Papers were examined that addressed
the following aspects of the OT system: synthesis and localization,
receptors, physiology: In addition, latest findings showing
abnormalities of OT and OT system in several neuropsychiatric
disorders, including autism, obsessive-compulsive disorder,
eating disorders, addiction, schizophrenia, post-traumatic
stress disorder and Prader-Willy syndrome, will be also discussed
together with the possible clinical use of OT or its analogues
and/or antagonists.
[Back to top]
Platensimycin: A Promising Antimicrobial Targeting Fatty Acid
Synthesis
D.T. Manallack, I.T. Crosby, Y. Khakham and B. Capuano
Platensimycin was recently discovered by Merck Research
Laboratories and has created considerable interest given its
potent antibacterial activity and mode of action. The use
of RNA gene-silencing techniques and screening libraries of
natural products allowed Merck to find this antibiotic which
may have otherwise been missed using conventional methods.
Interestingly, platensimycin has shown good activity against
a panel of Gram positive organisms which included various
resistant strains. Platensimycin works by inhibiting β-ketoacyl
synthases I/II (FabF/B) which are key enzymes in the production
of fatty acids required for bacterial cell membranes. So far,
a number of groups have explored synthetic strategies for
platensimycin and this work has subsequently lead to the synthesis
of active analogues. Given its mode of action, it is intriguing
as to why Merck themselves patented only a single compound
and have not apparently sought to generate further libraries.
This review will discuss the origins of platensimycin, its
mechanism of action, synthetic schemes and where the future
may take us following this fascinating discovery.
[Back to top]
A Possible Placental Factor for Preeclampsia: sFlt-1
Naoko Kita and Junji Mitsushita
Despite its clinical importance, the mechanism of preeclampsia
is unclear; however, many believe placental pathology might
be related to maternal systemic disease. If this is true,
a factor which mediates information from the placenta to the
maternal circulation can be hypothesized. Among a variety
of such reported factors, soluble fms-like tyrosine kinase-1
(sFlt1) will be the focus of this review. The hypoxic placenta,
which is commonly found in preeclampsia, produces sFlt1; furthermore,
animal experiments suggest its over-expression leads to preeclampsia-like
symptoms.
[Back to top]
Lung Transplantation: The Role of Azithromycin in the Management
of Patients with Bronchiolitis Obliterans Syndrome
A.M. Fietta and F. Meloni
Bronchiolitis obliterans syndrome (BOS) is the leading
cause of death in lung transplant recipients (LTR).
BOS is thought to result from chronic immunologic/inflammatory
insults leading to peri-bronchiolar leukocyte infiltration,
with a subsequent exuberant tissue re-modelling and fibro-obliteration
of the luminal space of the allograft airways. Diagnosis is
based on functional criteria and severity is graded on the
degree of Forced Expiratory Volume in 1 second (FEV1) impairment.
Current strategies to improve pulmonary function once BOS
is established have demonstrated little or no impact on disease
progression and re-transplantation remains the only therapeutic
option. Among the alternative treatments which have been attempted
in the last few years, long-term azithromycin treatment seems
to be the most promising therapeutic device for BOS treatment.
Azithromycin is a macrolide antibiotic, endowed with a broad
spectrum of anti-inflammatory/immunomodulatory activities.
Long-term oral azithromycin therapy can significantly improve
FEV1 in about 42% of patients with established BOS. Moreover,
reduced neutrophilia, chemokine release and bacterial exacerbations
have been demonstrated. These observations suggest that the
drug can down-regulate pulmonary inflammation, even if the
precise underlying mechanisms still need to be determined.
[Back to top]
Expression, Regulation and Function of Asporin, A Susceptibility
Gene in Common Bone and Joint Diseases
Shiro Ikegawa
Asporin is an extracellular matrix protein that belongs
to the small leucine-rich repeat proteoglycan (SLRP) family
of proteins. It is unique among SLRPs in that it lacks a glycosaminoglycan
attachment site and contains an asparatic acid (D) repeat
at its amino terminus. Its biological role has been unclear,
but recent genetic studies have demonstrated association between
asporin and various bone and joint diseases, including osteoarthritis,
rheumatoid arthritis and lumbar disc disease. Each of these
common diseases presents a substantial medical, social and
economical burden to societies worldwide. This paper reviews
recent progress in the study of asporin, focusing on its expression,
regulation and function as well as its role in the molecular
pathogenesis of common bone and joint diseases. Asporin is
found primarily in regions surrounding skeletal tissue and
is up-regulated in disease states. It binds to various growth
factors, including TGF-β
and BMP-2, and negatively regulates their activity. By inhibiting
binding of TGF-β1
to its type II receptor, asporin forms a functional feedback
loop with TGF-β1
and regulates its chondrogenic potential. As an extracellular,
tissue-specific protein, asporin represents a promising target
for phamacogenomic approaches to common bone and joint diseases.
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