| Current
Medicinal Chemistry
ISSN: 0929-8673
Current Medicinal Chemistry
Volume 17, Number 5, 2010
Contents
Editor’s Choice
Neurobiological Effects of Hyperforin and its Potential in
Alzheimer's Disease Therapy Pp. 391-406
T.N. Griffith, L. Varela-Nallar, M.C. Dinamarca
and N.C. Inestrosa
[Abstract] [Purchase
Article] [PMID:
20015041 PubMed - indexed for MEDLINE]
The Roles of MicroRNAs in Heart Diseases: A Novel
Important Regulator Pp. 407-411
B. Cai, Z. Pan and Y. Lu
[Abstract] [Purchase
Article] [PMID:
20015039 PubMed - indexed for MEDLINE]
11β-Hydroxysteroid
Dehydrogenase Type 1 Inhibitors as Promising Therapeutic Drugs
for Diabetes: Status and Development Pp. 412-422
R. Ge, Y. Huang, G. Liang and X. Li
[Abstract] [Purchase
Article] [PMID:
20015040 PubMed - indexed for MEDLINE]
Chagas Disease: Progress and New Perspectives
Pp. 423-452
F. Sánchez-Sancho, N.E. Campillo and
J.A. Páez
[Abstract] [Purchase
Article] [PMID:
20015038 PubMed - indexed for MEDLINE]
Bone Mass Gain During Puberty and Adolescence: Deconstructing
Gender Characteristics Pp. 453-466
F.R. Pérez-López, P. Chedraui and
J.L. Cuadros-López
[Abstract] [Purchase
Article] [PMID:
20015037 PubMed - indexed for MEDLINE]
Mechanisms of Action and Medicinal Applications of
Abscisic Acid Pp. 467-478
J. Bassaganya-Riera, J. Skoneczka, D.G.J. Kingston,
A. Krishnan, S.A. Misyak, A.J. Guri, A. Pereira, A.B. Carter,
P. Minorsky, R. Tumarkin and R. Hontecillas
[Abstract] [Purchase
Article]
[PMID:
20015036 PubMed - indexed for MEDLINE]
Thioredoxin System Modulation by Plant and Fungal
Secondary Metabolites Pp. 479-494
F. Dal Piaz, A. Braca, M.A. Belisario, and
N. De Tommasi
[Abstract] [Purchase
Article]
[PMID:
19941471 PubMed - indexed for MEDLINE]
Abstracts
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Article] [PMID:
20015041 PubMed - indexed for MEDLINE]
Neurobiological Effects of Hyperforin and its Potential in
Alzheimer's Disease Therapy
T.N. Griffith, L. Varela-Nallar, M.C. Dinamarca
and N.C. Inestrosa
St. John’s Wort (SJW) has been used medicinally for
over 5,000 years. Relatively recently, one of its phloroglucinol
derivatives, hyperforin, has emerged as a compound of interest.
Hyperforin first gained attention as the constituent of SJW
responsible for its antidepressant effects. Since then, several
of its neurobiological effects have been described, including
neurotransmitter re-uptake inhibition, the ability to increase
intracellular sodium and calcium levels, canonical transient
receptor potential 6 (TRPC6) activation, N-methyl-D-aspartic
acid (NMDA) receptor antagonism as well as antioxidant and
anti-inflammatory properties. Until recently, its pharmacological
actions outside of depression had not been investigated. However,
hyperforin has been shown to have cognitive enhancing and
memory facilitating properties. Importantly, it has been shown
to have neuroprotective effects against Alzheimer’s
disease (AD) neuropathology, including the ability to disassemble
amyloid-β
(Aβ)
aggregates in vitro, decrease astrogliosis and microglia
activation, as well as improve spatial memory in vivo.
This review will examine some of the early studies involving
hyperforin and its effects in the central nervous system (CNS),
with an emphasis on its potential use in AD therapy. With
further investigation, hyperforin could emerge to be a likely
therapeutical candidate in the treatment of this disease.
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[PMID:
20015039 PubMed - indexed for MEDLINE]
The Roles of MicroRNAs in Heart Diseases: A Novel
Important Regulator
B. Cai, Z. Pan and Y. Lu
MicroRNAs (miRNAs) are non-coding single-stranded RNAs with
about 21~23 nucleotides in length, which originate from encoding
genes in nucleus. In most cases miRNAs play an inhibitory
role in gene expression in a post-transcriptional level by
partially complementary binding to the 3’ unstranlated
region (UTR) of target mRNAs. Large bodies of evidence have
shown that miRNAs were involved in various diseases, such
as cancer, infectious diseases, diabetes etc, and rising as
critical modulators of pathological processes. Lately, some
highlight articles revealed that the altered expression of
miRNAs such as miR-1, miR-133, miR-21, miR-208 etc in hearts
also contributed to cardiovascular diseases, such as heart
ischemia, cardiac hypertrophy, and arrhythmias. Moreover,
miRNAs are also identified to regulate heart development.
These exciting findings not only improve our understanding
of the molecular mechanisms of heart diseases, but also provide
a new class of potential molecular targets—miRNAs, for
the development of novel agents to treat heart diseases. Here,
we summarized the recent discoveries about the role of miRNAs
in cardiac physiological and pathological functions, and then
discussed about their therapeutic potentials for heart diseases.
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[Purchase
Article]
[PMID:
20015040 PubMed - indexed for MEDLINE]
11β-Hydroxysteroid
Dehydrogenase Type 1 Inhibitors as Promising Therapeutic Drugs
for Diabetes: Status and Development
R. Ge, Y. Huang, G. Liang and X. Li
Glucocorticoids (GC) play a fundamental role in controlling
physiologic homeostasis and, when present in excess, can have
a detrimental impact on glucose control, blood pressure and
lipid levels. The oxidoreductase 11β-hydroxysteroid
dehydrogenase type 1 (11β-HSD1)
mainly catalyzes the intracellular regeneration of active
GCs (cortisol, corticosterone) from inert inactive 11-keto
forms (cortisone) in liver, adipose tissue and brain, amplifying
local GC action. Multiple lines of evidence have indicated
that 11β-HSD1-mediated
intracellular cortisol production may have a pathogenic role
in type 2 diabetes and its co-morbidities. The 11β-HSD1
becomes a novel target for anti-type 2 diabetes drug developments,
and inhibition of 11β-HSD1
offers a potential therapy to attenuate the type 2 diabetes.
In the past several years, a lot of 11β-HSD1
inhibitors have been designed, synthesized, screened and discovered.
Lowering intracellular glucocorticoid concentrations through
administration of small molecule 11β-HSD1
selective inhibitors, significantly attenuates the signs and
symptoms of disease in preclinical animal models and clinical
trials of diabetes and metabolic syndrome. Among published
inhibitors, DIO-902 from DiObex Inc. and INCB13739 from Incyte
Inc. are now being investigated under Phase 2B clinical trials.
However, the selectivity of current selective 11β-HSD1
inhibitors has been just focused on the difference between
11β-HSD1
and 11β-HSD2.
They inhibit the bi-directional activities of 11β-HSD1,
both 11β-HSD1
reductase (major) and oxidase (minor). In our lab, we have
recently found novel chemicals that not only inhibit 11β-HSD1
reductase activity but also increase its oxidase activity
without inhibition against 11β-HSD2.
We propose that this dual modulation on 11β-HSD1
may provide a better therapeutic strategy for type 2 diabetes.
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[PMID:
20015038 PubMed - indexed for MEDLINE]
Chagas Disease: Progress and New Perspectives
F. Sánchez-Sancho, N.E. Campillo and
J.A. Páez
Chagas disease, also known as American trypanosomiasis, is
caused by infection with the protozoan parasite Trypanosoma
cruzi. The Pan American Health Organization (PAHO) estimates
that currently 7.7 million of people have Trypanosoma
cruzi infection in the 21 endemic countries from the
southern and southwestern United States to central Argentina
and Chile.
The only approved therapeutics for the treatment of Chagas
disease are two nitroheterocyclic compounds as a nitrofuran
(nifurtimox; Lampit) and a nitroimidazole (benznidazole; Rochagan).
However, the anti-Trypanosoma cruzi activities of
these compounds were discovered empirically over three decades
ago. The treatment of Chagas disease with nifurtimox or benznidazole
is unsatisfactory because of their limited efficacy in the
prevalent chronic stage of the disease and their toxic side
effects.
In this context, this article will review the current knowledge
of the different aspects involved in this illness, such as
Trypanosoma cruzi transmission, physiology and biochemistry
of the etiological agent, epidemiological aspects and current
treatments for American trypanosomiasis. An important section
of this review will focus on the different strategies in drug
discovery for Chagas disease, including methodology, in
vitro screening studies against whole parasites, novel
rationally developed approaches on the basis of the increasing
knowledge of the biochemistry of Trypanosoma cruzi
and the recent progress in the understanding and validation
of several targets for the therapy of Chagas disease. A summary
of the most relevant drug targets such as sterol biosynthesis
pathway, cysteine protease pathway, pyrophosphate metabolism
and purine salvage pathway will be reviewed. Moreover, recent
studies regarding other strategies currently under development
including thiol-dependent redox metabolism, lysophospholipid
analogues and DNA binders will also be discussed.
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[Purchase
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[PMID:
20015037 PubMed - indexed for MEDLINE]
Bone Mass Gain During Puberty and Adolescence: Deconstructing
Gender Characteristics
F.R. Pérez-López, P. Chedraui and
J.L. Cuadros-López
Primary prevention of osteoporosis must aim at increasing
bone mass acquisition before late adolescence. During pubertal
years both genders reach peak bone acquisition, though males
develop a greater skeletal mass. This dimorphism is largely
regulated by endocrine factors, with critical roles played
by gonadal steroids, growth hormone and insulin growth factor-1,
amongst the most important. Menstrual history is a surrogate
for the adequacy of hormonal functioning, nutrition and physical
activity that may be a marker of bone status and development
in young women. Adequate levels of adrenal, reproductive and
pituitary hormones, growth factors and leptin are needed for
the initiation and maintenance of regular menstrual cycles
as well as for the achievement of peak bone mass. Adequate
regular exercise and body composition are also pivotal elements
in maintaining normal mechanical bone stimulus during bone
growth. Avoidance of carbonated soft drink consumption, or
excessive alcohol and any tobacco should be considered as
these may interfere reaching adequate bone mass.
[Back to top]
[Purchase
Article]
[PMID:
20015036 PubMed - indexed for MEDLINE]
Mechanisms of Action and Medicinal Applications of
Abscisic Acid
J. Bassaganya-Riera, J. Skoneczka, D.G.J. Kingston,
A. Krishnan, S.A. Misyak, A.J. Guri, A. Pereira, A.B. Carter,
P. Minorsky, R. Tumarkin and R. Hontecillas
Since its discovery in the early 1960’s, abscisic
acid (ABA) has received considerable attention as an important
phytohormone, and more recently, as a candidate medicinal
in humans. In plants it has been shown to regulate important
physiological processes such as response to drought stress,
and dormancy. The discovery of ABA synthesis in animal cells
has generated interest in the possible parallels between its
role in plant and animal systems. The importance of this molecule
has prompted the development of several methods for the chemical
synthesis of ABA, which differ significantly from the biosynthesis
of ABA in plants through the mevalonic acid pathway. ABA recognition
in plants has been shown to occur at both the intra- and extracellularly
but little is known about the perception of ABA by animal
cells. A few ABA molecular targets have been identified
in vitro (e.g., calcium signaling, G protein-coupled
receptors) in both plant and animal systems. A unique finding
in mammalian systems, however, is that the peroxisome proliferator-activated
receptor, PPAR γ,
is upregulated by ABA in both in vitro and in
vivo studies. Comparison of the human PPAR γ
gene network with Arabidopsis ABA-related genes reveal
important orthologs between these groups. Also, ABA can ameliorate
the symptoms of type II diabetes, targeting PPAR γ
in a similar manner as the thiazolidinediones class of anti-diabetic
drugs. The use of ABA in the treatment of type II diabetes,
offers encouragement for further studies concerning the biomedical
applications of ABA.
[Back to top]
[Purchase
Article]
[PMID:
19941471 PubMed - indexed for MEDLINE]
Thioredoxin System Modulation by Plant and Fungal
Secondary Metabolites
F. Dal Piaz, A. Braca, M.A. Belisario, and
N. De Tommasi
Thioredoxin (Trx) is the major cellular protein disulfide
reductase in a broad range of organisms, including humans.
Trx, together with glutaredoxin (Grx), plays critical roles
in the regulation of cellular protein redox homeostasis. Reduced
thioredoxin transfers reducing equivalents to disulphides
in target proteins, leading to reversible oxidation of its
active centre dithiol to a disulphide. The resulting disulphide
bridge is, in turn, reduced to a dithiol by thioredoxin reductase
(TrxR). Increasing attention has been paid to the role of
Trx, as it has been shown to be a signalling intermediate
beyond its intrinsic antioxidant activity. Indeed, this protein
acts as a growth factor, activates a number of transcription
factors regulating cell growth and survival, acts as cofactor
for ribonucleotide reductase, and promotes angiogenesis. In
addition, Trx has been demonstrated to cooperatively inhibit
programmed cell death. Because of the multiple roles of Trx
system in tumorigenesis, this protein represents an emerging
target for anti-cancer drugs. Several Trx system modulators
have been identified: a semi-synthetic Trx inhibitor, PX-12
(1-methylpropyl 2-imidazolyl disulfide), has been placed in
a clinical trial. However, there is a growing interest in
finding new selective ones. Natural products continue to provide
structurally complex, but highly original lead structures
for drug discovery programs: polyphenols, quinones, and terpenoids
showed to affect the Trx/TrxR system at different levels.
The purpose of this review is to provide an overview of the
plant and fungal secondary metabolites interfering with Trx
and TrxR activities, paying particularly attention to their
mechanism of action. Among polyphenols, curcumin and some
flavonoids such as myricetin and quercetin, have been identified
as potential anticancer agents with a mechanism of action
that may be mediated by the Trx system.
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