| Current
Medicinal Chemistry
ISSN: 0929-8673
Current Medicinal Chemistry
Volume 17, Number 1, 2010
Contents
Mechanisms of Allostery and Membrane Attachment in Ras GTPases:
Implications for Anti-Cancer Drug Discovery Pp.
1-9
A.A. Gorfe
[Abstract] [Full
text article]
A Review on Biomedical Applications of Single-Walled
Carbon Nanotubes Pp. 10-24
F. Liang and B. Chen
[Abstract] [Full
text article]
Molecular Recognition and Drug-Lead Identification:
What Can Molecular Simulations Tell Us? Pp. 25-41
G. Morra, A. Genoni, M.A.C. Neves, K.M. Merz, Jr. and
G. Colombo
[Abstract] [Full
text article]
Neglected Diseases Caused By Bacterial
Infections Pp. 42-60
M. Bechtle, S. Chen and T. Efferth
[Abstract] [Full
text article]
Pharmacological Modulation of Nitric Oxide Release:
New Pharmacological Perspectives, Potential Benefits and Risks Pp. 61-73
R. Scatena, P. Bottoni, A. Pontoglio and B. Giardina
[Abstract] [Full
text article]
Design and Development of Nanovehicle-Based Delivery
Systems for Preventive or Therapeutic Supplementation with
Flavonoids Pp. 74-95
G. Leonarduzzi, G. Testa, B. Sottero, P. Gamba and
G. Poli
[Abstract] [Full
text article]
Abstracts
[Back to top]
Mechanisms of Allostery and Membrane Attachment
in Ras GTPases: Implications for Anti-Cancer Drug Discovery
A.A. Gorfe
[Full
text article]
Ras GTPases are membrane-anchored molecular switches that
mediate signaling pathways controlling a variety of cellular
processes, including cell division and development. Despite
their prominent role in many forms of cancer, little is known
about the structure of the membrane bound protein or the mechanism
and thermodynamics of membrane insertion. The modulation of
membrane binding by the catalytic domain is another area of
on-going scrutiny. Recent computational and experimental efforts
that have begun to shed some light on these issues are the
subject of this review. The bulk of the available structural
and thermodynamic information on membrane-bound Ras has been
obtained by studying peptides derived from the membrane-anchoring
regions of N-ras and H-ras proteins. However, those results
have been complemented by data, though limited, on the membrane
binding of the full-length Ras as well as by predictions about
putative communication routes between the GTP-hydrolyzing
catalytic domain and the membrane-interacting C-terminus.
A tentative mechanistic picture of Ras signaling that is emerging
from these studies will be discussed in connection with allostery
and implication for the design of selective anti-cancer drugs.
[Back to top]
A Review on Biomedical Applications of Single-Walled
Carbon Nanotubes
F. Liang and B. Chen
[Full
text article]
Single-walled carbon nanotubes (SWNTs), a member of the
carbon family, are the one-dimensional analogues of zero-dimensional
fullerene molecules with unique structural and electronic
properties. Since the discovery of SWNTs, they have been extensively
studied for biomedical applications. In biological media SWNTs
have unique near-infrared intrinsic fluorescence, inherent
Raman spectroscopy and photoacoustic signal associated with
the graphene in SWNTs which makes them ideal for noninvasive
and high sensitivity detection. SWNTs have been broadly investigated
as imaging agents for the evaluation of tumor targeting and
localization of SWNTs in vitro and in vivo.
Rational functionalization can also endow SWNTs with desired
properties for biomedical applications. Functionalized SWNTs
with significantly reduced toxicity have been employed as
carriers to deliver various anticancer drugs, proteins and
nucleic acids to the diseased tissues specifically and maximize
the bioavailability of the drugs by improving solubility and
increasing circulation time. This manuscript will highlight
the recent employment of SWNTs in the field of nanomedicine
and bioimaging, and also outline the challenges and future
opportunities for biomedical applications of SWNTs.
[Back to top]
Molecular Recognition and Drug-Lead Identification:
What Can Molecular Simulations Tell Us?
G. Morra, A. Genoni, M.A.C. Neves, K.M. Merz, Jr. and
G. Colombo
[Full
text article]
Molecular recognition and ligand binding involving proteins
underlie the most important life processes within the cell,
such as substrate transport, catalysis, signal transmission,
receptor trafficking, gene regulation, switching on and off
of biochemical pathways.
Despite recent successes in predicting the structures of many
protein-substrate complexes, the dynamic aspects of binding
have been largely neglected by computational/theoretical investigations.
Recently, several groups have started tackling these problems
with the use of experimental and simulation methods and developed
models describing the variation of protein dynamics upon complex
formation, shedding light on how substrate or inhibitor binding
can alter protein flexibility and function. The study of ligand-induced
dynamic variations has also been exploited to review the concept
of allosteric changes, in the absence of major conformational
changes.
In this context, the study of the influence of protein motions
on signal transduction and on catalytic activities has been
used to develop pharmacophore models based on ensembles of
protein conformations. These models, taking flexibility explicitly
into account, are able to distinguish active inhibitors versus
nonactive drug-like compounds, to define new molecular motifs
and to preferentially identify specific ligands for a certain
protein target.
The application of these methods holds great promise in advancing
structure-based drug discovery and medicinal chemistry in
general, opening up the possibility to explore broader chemical
spaces than is normally done in an efficient way.
In this review, examples illustrating the extent to which
simulations can be used to understand these phenomena will
be presented along with examples of methodological developments
to increase physical understanding of the processes and improve
the possibility to rationally design new molecules.
[Back to top]
Neglected Diseases Caused By Bacterial Infections
M. Bechtle, S. Chen and T. Efferth
[Full
text article]
Bacterial infections represent a major health problem, especially
in third world countries. In endemic regions, large populations
of people are greatly affected, but the medical care is very
limited. In this review, the neglected diseases buruli ulcer
and trachoma are elucidated.
Buruli ulcer is caused by Mycobacterium ulcerans
which produces an outstanding immunosuppressive toxin mycolactone
that induces an ulcerative, necrotic skin disease. Until today,
only the combination of rifampin/streptomycin is used to treat
buruli ulcer. However, this therapy is ineffective and expensive.
Here, we report new findings that suggest pharmaceutical formulations
such as rifapentine, in combination with clarithromycin or
moxifloxacin that have shown promising results in mice footpad
trials. Moreover, alternative treatment options such as heat
therapy, nitric oxide cremes and French clay show bactericidal
effects. The genotyping of M. ulcerans also promises
new ways of finding drug targets and vaccines.
Trachoma, induced by the bacterium Chlamydia trachomatis,
is the primary infectious cause of blindness worldwide. Recurrent
infections lead to chronic inflammation of the upper tarsal
conjunctiva. As a consequence, scarring and distortion of
the eye lids occur, eventually resulting in blindness. First-line
medications for trachoma treatment are bacteriostatic agents
such as topically applied tetracylines and systematically
administered azithromycin. Surgery, environmental improvements
and personal hygiene are further crucial factors in controlling
trachoma. Moreover, efforts are being under-taken towards
the development of vaccine systems, with the major outer membrane
protein and the polymorphic membrane protein acting as attractive
candidates.
[Back to top]
Pharmacological Modulation of Nitric Oxide
Release: New Pharmacological Perspectives, Potential Benefits
and Risks
R. Scatena, P. Bottoni, A. Pontoglio and
B. Giardina
[Full
text article]
Nitric oxide is becoming an increasingly important signalling
molecule implicated in a growing number of physiological and
pathophysiological processes. Moreover, with the recent advances
in nitric oxide biochemistry, many well known drugs have been
shown to act totally or partially by modulating NO metabolism
with varying therapeutic results. The classic organic nitrates
have been shown to exhibit beneficial therapeutic but suffer
from some well known pitfalls (tolerability induction, abrupt
cephalea and hypotension). Similarly, sydnonimines, another
well known class of NO donor drugs, have a characteristically
low therapeutic index (i.e., cyanide toxicity).
At present, pharmacological researchers are designing and
synthesising various chemical compounds capable of modulat-ing
NO metabolism for therapeutic purposes that also possess an
optimal therapeutic index.
Specifically, various new classes of NO donors are under intense
pharmacological investigation (such as S-nitrosothiols, diazeniumdiolates,
furoxans, zeolites and so on), each characterised by a particular
pharmacokinetic and pharmacodynamic profile. To know the pharmacological
development of these new NO donor drugs could help to ameliorate
the use of these molecules in various therapeutic protocols.
In fact, the pharmacologically modulated nitric oxide release
showed to have an important therapeutic impact in the treatment
of diseases such as arteriopathies, various acute and chronic
inflammatory conditions, and several degenerative diseases.
At present, the most important obstacle in the field of new
NO donor drugs seems to be carefully targeting NO release
to a particular tissue at an optimal concentration, so as
to achieve a beneficial action and to limit possible toxic
effects.
[Back to top]
Design and Development of Nanovehicle-Based Delivery
Systems for Preventive or Therapeutic Supplementation with
Flavonoids
G. Leonarduzzi, G. Testa, B. Sottero, P. Gamba and
G. Poli
[Full
text article]
To date more than 4000 compounds are recognized to belong
to the class of flavonoids. These natural phenolic drugs are
poorly soluble in water and are rapidly degraded and metabolized
in the human body, but nevertheless are very promising for
their potential contribution to the prevention and therapy
of major chronic diseases, including cardiovascular and neurodegenerative
diseases and cancer. In recent years a number of flavanols
(e.g. catechins), flavonols (e.g. quercetin, myricetin) and
isoflavones (e.g. genistein, daidzein) have been confirmed
to possess strong antioxidant, anti-inflammatory, anti-proliferative
and anti-aging activities. Incorporation into lipidic or polymer-based
nanoparticles appears to markedly help the oral delivery of
flavonoids, as these particles can protect the drug from degradation
in the gastrointestinal tract and, by virtue of their unique
absorption mechanism through the lymphatic system, also from
first-pass metabolism in the liver. In addition, both oral
and parenteral administration of flavonoids exploits a pharmacologic
delivery route that guarantees sustained release of the active
principle at the desired site of action. A comprehensive review
of studies currently available on the in vitro and
in vivo experimental administration of flavonoids
by means of nanovectors may be of use as a foundation for
the development of advanced delivery systems for these powerful
compounds, in view of their adoption in primary and secondary
disease prevention.
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