|
Current
Pharmaceutical Design
ISSN: 1381-6128
Current Pharmaceutical Design
Volume 14, Number 1, 2008
Contents
New Potential Therapies from Vanilloid Transient Receptor
Cation (TRPV) Channels
Executive Editors: V. Di Marzo and K. Starowicz
Editorial Pp.1
The Role of Natural Products in the Ligand Deorphanization
of TRP Channels Pp. 2-17
G. Appendino, A. Minassi, A. Pagani and A. Ech-Chahad
[Abstract]
Vanilloid Transient Receptor Potential Cation Channels:
An Overview Pp. 18-31
R. Vennekens, G. Owsianik and B. Nilius
[Abstract]
Peripheral TRPV1 Receptors As Targets for Drug Development:
New Molecules and Mechanisms Pp. 32-41
M.J. Gunthorpe and A. Szallasi
[Abstract]
TRPV1 Receptors in the Central Nervous System: Potential
for Previously Unforeseen Therapeutic Applications
Pp. 42-54
K. Starowicz, L. Cristino and V. Di Marzo
[Abstract]
General Articles
Small Molecule Complementarity As A Source
of Novel Pharmaceutical Agents and Combination Therapies
Pp. 55-62
R.S. Root-Bernstein and P.F. Dillon
[Abstract]
Drug Loaded Erythrocytes: As Novel Drug Delivery System
Pp. 63-70
P.D. Patel, N. Dand, R.S. Hirlekar and V.J. Kadam
[Abstract]
Intestinal Immunomodulation. Role of Regulative Peptides
and Promising Pharmacological Activities Pp. 71-95
V. Motilva, E. Talero, J.R. Calvo, I. Villegas, C. Alarcón-de-la
Lastra and S. Sánchez-Fidalgo
[Abstract]
Abstracts
[Back to top]
Editorial: New Potential Therapies from Vanilloid
Transient Receptor Cation (TRPV) Channels
In this issue of Current Pharmaceutical Design the
superfamily of TRP (Transient Receptor Potential) cation channels
is the subject of four detailed reviews. A variety of more
than 30 cation channels, members of the TRP family, permeable
to Ca2+ and other cations
are involved in several pathological and physiological conditions.
Based on sequence homology, this superfamily of cation channels
has been divided in six main subfamilies: canonical (TRPC),
vanilloid (TRPV), melastatin (TRPM), polycystin (TRPP), mucolipin
(TRPML) and the ankyrin (TRPA). The search for the molecular
targets for naturally occurring substances, especially of
plant origin, and studies of the mechanism of the transduction
of physical stimuli such as temperature, mechanical pressure
and light, have allowed the characterization and classification
of many TRP channels. In fact, attempts to understand the
molecular mechanism of action of the pro-nociceptive effects
of vanillyl moiety-containing compounds such as capsaicin,
the pungent component of hot chilli peppers (from Capsicum
sp.), or its potent analogue resiniferatoxin (RTX, from
Euphorbia sp.), led to the cloning of the
“vanilloid” receptor (TRPV1) already 10 years
ago, and of other heat-sensitive TRPV channels soon thereafter.
More recently, TRP channels sensitive to low temperatures,
such as TRPM1 and TRPA1, have also been identified. While
celebrating the first decennium of TRPV1 research, one should
bear in mind that in addition to its expression in primary
sensory afferents and its well documented biological role
in pain perception, a significant number of studies have been
published indicating that functionally active populations
of TRPV1 receptors are expressed also in the central nervous
system (CNS), thus suggesting that they are involved in many
more functions than just nociception.
The four reviews in this issue of the journal highlight and
discuss some important aspects of TRP channel-related issues.
Appendino and colleagues [1] provide an overview of the role
that natural products have played in the identification of
TRP channels and of their function as possible candidates
for drug discovery. Vennekens and coworkers [2] summarize
the fundamental properties of all members of the TRPV subfamily
(TRPV1- TRPV6), in the light of their multi-faceted cellular
functions, expression, molecular structure, regulation and
pharmacology. The subsequent review by Gunthorpe and Szallasi
[3] focusses on the function and potential therapeutic exploitation
of TRPV1 channels located in the peripheral nervous system.
The authors discuss the role of TRPV1 not only in pain but
also in cancer, obesity and diabetes, among others, and the
clinical development of TRPV1 agonists and antagonists. The
issue of TRPV1 as a potential target in non-neuronal tissues
is also reviewed. Finally, Starowicz, Cristino and Di Marzo
[4] discuss current ‘hot’ data on the functional
significance of TRPV1 channels in the brain, where these receptors
are unlikely to be activated by irritant or noxious stimulus
like high temperature or low pH, hence implying the existence
of “endovanilloids”. Starowicz and colleagues
focus not only on the role of potential endovanilloids in
central aspects of pain control, but also on the regulation
of body temperature, cardiovascular and respiratory functions,
emesis, anxiety and locomotion. The common intention to all
authors is to provide the reader with the most up-to-date
and state-of-the-art aspects of TRP, and particularly TRPV,
function under both physiological and pathological conditions,
and emphasize the potential of TRP targeting for therapeutic
purposes.
References
[1] Appendino G, Minassi A, Pagani A, Ech-Chahad A. The Role
of Natural Products in the Ligand Deorphanization of TRP Channels.
Curr Pharm Des 2008; 14(1): 2-17.
[2] Vennekens R, Owsianik G, Nilius B. Vanilloid Transient
Receptor Potential Cation Channels: An Overview. Curr Pharm
Des 2008; 14(1): 18-31.
[3] Gunthorpe MJ, Szallasi A. Peripheral TRPV1 Receptors As
Targets for Drug Development: New Molecules and Mechanisms.
Curr Pharm Des 2008; 14(1): 32-41.
[4] Starowicz K, Cristino L, Di Marzo V. TRPV1 Receptors in
the Central Nervous System: Potential for Previously Unforeseen
Therapeutic Applications. Curr Pharm Des 2008; 14(1): 42-54.
Vincenzo Di Marzo
and
Katarzyna Starowicz
Institute of Biomolecular Chemistry
C.N.R., Via dei Campi Flegrei 34
Comprensorio Olivetti
80078 Pozzuoli (Naples)
Italy
E-mail: vdimarzo@icmib.na.cnr.it
[Back to top]
The Role of Natural Products in the Ligand Deorphanization
of TRP Channels
G. Appendino, A. Minassi, A. Pagani and A. Ech-Chahad
The ligand deorphanization of TRP channels has a tremendous
potential for biomedical and nutritional research, and this
review highlights the role that natural products have played
in the identification of ligands for these targets and their
establishment as viable candidates for drug discovery. Specific
ligands have so far been discovered only for some thermoTRPs,
like TRPV1, TRPV3, TRPV4, TRPM8 and TRPA1, and the lack of
selective pharmacology has been a major drawback for unraveling
the biological role of TRPs. While genetic approaches (transgenic
animal models) have partially compensate for the lack of ligands,
the universal expression of TRPs in living systems and the
success achieved with TRPV1 suggest that a systematic investigation
of the natural products pool might alleviate this shortage,
fostering adoption by small molecules within this
class of still largely orphan biological targets.
[Back to top]
Vanilloid Transient Receptor Potential Cation Channels: An
Overview
R. Vennekens, G. Owsianik and B. Nilius
The mammalian branch of the Transient Receptor
Potential (TRP) superfamily of cation channels consists
of 28 members. They can be subdivided in six main subfamilies:
the TRPC (‘Canonical’), TRPV (‘Vanilloid’),
TRPM (‘Melastatin’), TRPP (‘Polycystin’),
TRPML (‘Mucolipin’) and the TRPA (‘Ankyrin’)
group. The TRPV subfamily comprises channels that are critically
involved in nociception and thermo-sensing (TRPV1, TRPV2,
TRPV3, TRPV4) as well as highly Ca2+
selective channels involved in Ca2+
absorption/reabsorption in mammals (TRPV5, TRPV6). In this
review we summarize fundamental physiological properties of
all TRPV members in the light of various cellular functions
of these channels and their significance in the systemic context
of the mammalian organism.
[Back to top]
Peripheral TRPV1 Receptors As Targets for Dru Development:
New Molecules and Mechanisms
M.J. Gunthorpe and A. Szallasi
Based on the painful effects of exposure to capsaicin,
TRPV1 (transient receptor potential vanilloid subfamily member
1) localization is most readily associated with peripheral
sensory neurons, however, TRPV1 is now known to be expressed,
albeit at lower levels, in the spinal cord, brain and a wide-range
of non-neuronal cells. The latter includes epithelial cells
(e.g. keratinocytes, urothelium, gastric epithelial cells,
enterocytes, and pneumocytes) through vascular endothelium
and cells of the immune system (e.g. T-cells and mast cells)
to smooth muscle, fibroblasts and hepatocytes. Despite extensive
research, the physiological function of TRPV1 in the brain
and in non-neuronal tissues remains elusive. The preliminary
results are exciting, but many are unconfirmed and/or contradictory.
As yet, studies with TRPV1 knock-out mice have proven unhelpful
in clarifying such biological roles. Now that a range of potent
and selective TRPV1 antagonists are available in this rapidly
expanding research field, further understanding of the biological
roles of TRPV1 throughout the body is within reach. In this
article, we will summarize the known roles of peripheral TRPV1
receptors in physiology and disease and review the current
perspectives for the therapeutic potential of TRPV1 agonists
and antagonists in the treatment of a wide range of conditions
such as pain, cancer, migraine, chronic cough, asthma, rectal
hypersensitivity, inflammatory bowel disease, obesity, overactive
bladder and diabetes. New applications of targeting central
TRPV1 receptors are reviewed in the accompanying article by
Starowicz et al. (in this issue).
[Back to top]
TRPV1 Receptors in the Central Nervous System: Potential for
Previously Unforeseen Therapeutic Applications
K. Starowicz, L. Cristino and V. Di Marzo
Increasing evidence exists to support the presence of
functional transient receptor potential vanilloid type 1 (TRPV1)
channels in the brain, where these receptors are unlikely
to be activated by high temperature and low pH. Here we review
this evidence as well as the literature data pointing to the
potential role of endovanilloid-activated brain TRPV1 channels
not only in the supraspinal control of pain, body temperature,
cardiovascular and respiratory functions and emesis, but also
in anxiety and locomotion. This literature provides the first
bases for the possible future development of new therapeutic
approaches that, by specifically targeting brain TRPV1 receptors,
might be used for the treatment of pain as well as affective
and motor disorders.
[Back to top]
Small Molecule Complementarity As A Source
of Novel Pharmaceutical Agents and Combination Therapies
R.S. Root-Bernstein and P.F. Dillon
Many examples of specific binding between small molecules
are known that are associated with modified physiological
and pharmacological activities. Conversely, the antagonism
or synergism of small molecules is often correlated with specific
binding between the molecules. It follows that small molecule
binding can be used as a relatively quick, easy, and specific
screen for functionally useful drug actions and interactions.
These actions and interactions may manifest themselves as
functional antagonisms; binding may correlate with enhancement
or synergism; the formation of some complexes may yield clues
about how drugs may be targeted to specific cell types in
vivo and provide leads for the development of antidotes
for drug overdoses or poisoning; the binding of one molecule
to another may mimic receptor binding; and complexation may
provide novel ways of protecting and delivering drugs. Relevant
examples from each type of application are reviewed involving
peptide-peptide interactions; peptide-aromatic compound interactions;
aromatic-aromatic compound interactions; vitamin-aromatic
compound interactions; and polycyclic compound interactions.
We argue that screening for molecular complementarity of small
molecules turns ligands such as neurotransmitters and their
metabolites, hormones, and drugs themselves, into direct targets
of drug development that can augment screening new compounds
for activity against receptors and second messenger systems.
We believe that the small molecule complementarity approach
is novel, fruitful and under-utilized.
[Back to top]
Drug Loaded Erythrocytes: As Novel Drug Delivery System
P.D. Patel, N. Dand, R.S. Hirlekar and V.J. Kadam
Novel drug delivery systems are one of the widely used
delivery systems. In the present scenario, amongst them, "Drug
Loaded Erythrocytes" is one of the growing and potential
systems for delivery of drugs and enzymes. Erythrocytes are
biocompatible, biodegradable, posses long circulation half-life
and can be loaded with variety of biologically active substances.
Carrier erythrocytes are prepared by collecting blood sample
from the organism of interest and separating erythrocytes
from plasma. By using various physical and chemical methods
the cells are broken and the drug is entrapped into the erythrocytes,
finally they are resealed and the resultant carriers are then
called “resealed erythrocytes". Surface modification
with glutaraldehyde, antibodies, carbohydrates like sialic
acid and biotinylation of loaded erythrocytes (biotinylated
erythrocytes) is possible to improve their target specificity
and to increase their circulation half-life. Upon reinjection
the drug loaded erythrocytes serve as slow circulation depots,
targets the drug to the reticuloendothelial system (RES),
prevents degradation of loaded drug from inactivation by endogenous
chemicals, attain steady state concentration of drug and decrease
the side-effects of loaded drug. Nowadays, Nanoerythrosomes
based drug delivery systems have excellent potential for clinical
application.
[Back to top]
Intestinal Immunomodulation. Role of Regulative Peptides and
Promising Pharmacological Activities
V. Motilva, E. Talero, J.R. Calvo, I. Villegas, C. Alarcón-de-l
Lastra and S. Sánchez-Fidalgo
About 50 peptides, and a similar number of peptide receptors,
are known to be present in the gut and this amount is likely
to rise significantly over the next few years. While there
has been a massive research effort to define their functions
and their anatomical distribution in the central nervous system
(CNS), the understanding of their roles in the gut is far
more limited. Classically, the physiological functions include
the control of motility, fluids, electrolytes, and digestive
enzymes secretion, or vascular and visceral pain function,
and more recently, the role-played in cell proliferation and
survival, and in immune-inflammatory responses.
The term inflammatory bowel disease (IBD) that encompasses
Crohn´s disease and ulcerative colitis, is clearly an
inflammatory disease where several mediators such as cytokines,
chemokines, prostanoids, nitric oxide or free radicals, produced
by infiltrating cells, play a critical role in intestine tissue
alteration. Some peptides, initially known for their neuroregulative
properties, have been suggested to act as endogenous immune
factors, with predominant antiinflammatory effects. Based
on these actions, these molecules are proposed as potential
agents for the treatment of IBD and selective peptide analogs
are being developed as novel therapeutic strategies for IBD
patients.
Patients with IBD have an increased risk for developing colorectal
cancer (CRC). Up to the present time, no known genetic basis
has been identified to explain CRC predisposition in these
IBD. Instead, it is assumed that chronic inflammation is what
causes cancer. This is supported by the fact that colon cancer
risk increases with longer duration of colitis, greater anatomic
extent of colitis, the concomitant presence of other inflammatory
manifestations, and the fact that certain drugs used to treat
inflammation, may prevent the development of CRC. However,
though different regulative peptides play a beneficial role
in experimental IBD, an increasing number of articles about
cancer pathology are starting to implicate different peptides
in tumor initiation and progression. The complexities of cancer
could be described in terms of a small number of underlying
principles and the malignant growth is dependent upon a multi-step
process including different basic essential alterations. The
activities of many peptides that are overexpressed in cancer
cells help them to develop several of the molecular and physiological
features that are now considered the basis of malignant growth.
These collective findings implicate regulative peptides, receptors,
or peptide-levels modulators, as important biological targets
for developing intervention strategies against intestinal
immunological disorders and cancers.
|
