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Current
Drug Targets
ISSN: 1389-4501
Current Drug Targets
Volume 9, Number 1, January 2008
Contents
Diabetic Neuropathy
Guest Editor: Eva L. Feldman
Editorial Pp. 1-2
Criteria for Creating and Assessing Mouse Models of
Diabetic Neuropathy Pp. 3-13
K.A. Sullivan, S.I. Lentz, J.L. Roberts Jr. and E.L. Feldman
[Abstract] [Purchase
Article]
Aldose Reductase, Still a Compelling Target for
Diabetic Neuropathy Pp. 14-36
P.J. Oates
[Abstract] [Purchase
Article]
Is C-Peptide Replacement the Missing Link for
Successful Treatment of Neurological Complications in Type
1 Diabetes? Pp. 37-46
A.A.F. Sima and H. Kamiya
[Abstract] [Purchase
Article]
Growth Factors as Therapeutics for Diabetic Neuropathy
Pp. 47-59
N.A. Calcutt, C.G. Jolivalt and P. Fernyhough
[Abstract] [Purchase
Article]
Pro-Inflammatory Mechanisms in Diabetic Neuropathy:
Focus on the Nuclear Factor Kappa B Pathway Pp. 60-67
N.E. Cameron and M.A. Cotter
[Abstract] [Purchase
Article]
Cyclooxygenase-2 Pathway as a Potential Therapeutic Target
in Diabetic Peripheral Neuropathy Pp. 68-76
A.P. Kellogg, H.T. Cheng and R. Pop-Busui
[Abstract] [Purchase
Article]
The Potential Role of Angiotensin Converting
Enzyme and Vasopeptidase Inhibitors in the Treatment of Diabetic
Neuropathy Pp. 77-84
M.A. Yorek
[Abstract] [Purchase
Article]
Metabotropic Glutamate Receptors (mGluRs) and
Diabetic Neuropathy Pp. 85-93
M. Anjaneyulu, A. Berent-Spillson and J.W. Russell
[Abstract] [Full
Text Article]
The Antioxidant Response as a Drug Target in
Diabetic Neuropathy Pp. 94-100
A.M. Vincent, J.L. Edwards, M. Sadidi and E.L. Feldman
[Abstract] [Purchase
Article]
Abstracts
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Editorial
Diabetes and obesity have reached epidemic levels in the Western
world. In the United States, 20 million people have diabetes,
and this number is increasing annually. The morbidity of diabetes
is secondary to the macrovascular and microvascular complications
that develop in a patient’s lifetime. This edition of
Current Drug Targets is focused on the most common microvascular
complication of diabetes, neuropathy. More than half of all
patients with diabetes develop neuropathy, a progressive loss
of peripheral and autonomic nerve function. Diabetic neuropathy
is the most common cause of foot ulcers and nontraumatic amputations
in the United States; in his or her lifetime, a patient with
diabetes and neuropathy has a greater than 15% likelihood
of undergoing an amputation. Patients with neuropathy of autonomic
nerves experience one or more symptoms of autonomic failure
which can include dehabilitating loss of cardiac, gastrointestinal
and/or genitourinary function.
Despite the morbidity of diabetic neuropathy, there are no
approved treatments for the disease itself other than glucose
control. In the last 25 years, animal and in vitro
experiments have implicated multiple pathways of tissue damage
which can result in the onset and progression of diabetic
neuropathy. The first contribution by Sullivan and colleagues
discusses the development of mouse models of diabetic neuropathy
to provide a tool to screen the therapeutic efficacy of drugs.
The authors point out that a murine model of diabetic neuropathy
should mimic the human disorder and suggest phenotyping parameters
for evaluating diabetic neuropathy in mouse models.
The remaining contributions focus on mechanism based drug
development in diabetic neuropathy. While not all the pathways
underlying the pathogenesis of diabetic neuropathy are presented
in Fig. (1), pivotal pathways that serve
as a framework for mechanism based drug design are presented
in Fig. (1) and addressed in this special
issue of Current Drug Targets. Oates begins with a review
of the aldose reductase pathway. Excess glucose is converted
to sorbitol by aldose reductase, leading to sorbitol and fructose
accumulation, NAD(P)H-redox imbalance, and changes in multiple
intracellular signaling cascades. The NAD(P)H-redox imbalance
leads to depletion of necessary cellular antioxidants, such
as glutathione, promoting accumulation of reactive oxygen
species and oxidative damage. Previous trials of aldose reductase
inhibitors have not proven efficacious, in part due to dose-related
toxicity and accessibility to the nervous system. Newer aldose
reductase inhibitors with a lower toxicity profile and improved
nerve penetration may prove effective in the treatment of
diabetic neuropathy. In the next contribution, Sima and Kamiya
explore the evolving concept that the combined effects of
insulin and C-peptide regulate essential metabolic processes
in the nervous system, including key enzyme activity, nitric
oxide release, and the production and activity of essential
transcription factors, trophic factors and their receptors.
Replacing C peptide can prevent and/or reverse diabetic neuropathy,
supporting the essential role of C peptide in the pathogenesis
of the disorder and identifying C peptide replacement as a
new, promising therapy.
Fig. (1). Current Drug Targets in Diabetic
Neuropathy. Interrelated defects in cellular metabolism and
vascular tone occur in diabetes and lead to diabetic neuropathy.
These defects provide the targets for the development of mechanism
based drugs. These drugs are discussed in this special issue
of Current Drug Targets.
The idea that altered neurotrophic support underlies the development
of diabetic neuropathy is highlighted in the review by Calcutt
and colleagues. Potential blunting of normal neurotrophic
responses in the presence of persistent hyperglycemia may:
1) decrease growth factor synthesis by target organs; 2) disrupt
retrograde transport of growth factors to the neuronal cell
body; 3) affect the signal transduction mechanism of growth
factors in neurons, or 4) alter the ability of neurons or
Schwann cells to produce growth factors required for normal
cell maintenance. Calcutt and colleagues discuss these ideas
in the context of potential neurotrophic therapies. When deficits
are identified, exogenous neurotrophic factors can represent
a replacement therapy in diabetic neuropathy.
The pivotal role of inflammation in the development of diabetic
neuropathy is discussed by both Cameron and Cotter with a
focus on nuclear factor κ
B (NFκB)
and Pop-Busui and coworkers with a focus on glucose-mediated
alteration of cyclooxygenase (COX) pathway activity with subsequent
impaired production and function of prostaglandins (PGs).
NFκB
is produced in response to advanced glycation end product
(AGE) activation of cell surface receptors for AGE. AGE activation
leads to not only NFκB
formation, as discussed by Cameron and Cotter, but also enhanced
intracellular oxidative stress. NFκB
activation can lead to blood flow abnormalities, aberrant
angiogenesis, capillary occlusion and inflammation. In parallel,
tumor necrosis factor (TNF) α
is increased in acute and chronic inflammatory conditions
including diabetes. Collectively, targeting the NFκB
/ TNFα
axis leads to novel therapeutics for diabetic vascular complications,
including diabetic neuropathy. Pop-Busui and coworkers continue
on the theme of inflammation by targeting the inducible COX
isoform, COX-2, in diabetic neuropathy. COX-2 is increased
in the peripheral nervous system of animals with experimental
diabetes and neuropathy and selective inhibition of COX-2
blocks the onset and progression of diabetic neuropathy. The
contributions of Cameron and Cotter and Pop-Busui and coworkers
emphasize the importance of inflammation in the pathogenesis
of diabetic neuropathy, and providing a new area of investigation
and potential drug targets.
Another adverse effective of continued hyperglycemia in diabetes
is the increase in tissue angiotensin II. Yorek explains how
angiotensin II induces oxidative stress, endothelial damage
and other vascular pathologies including vasoconstriction,
thrombosis, inflammation and vascular remodeling. Angiotensin
converting enzyme inhibition and/or blocking of the angiotensin
II receptor are established therapies in diabetic macrovascular
disease and kidney disease. A new class of drugs has been
developed based on the same mechanism to augment existing
therapies. This drug class is known as the vasopeptidase inhibitors.
The vasopeptidase inhibitors block both angiotensin converting
enzyme activity and neutral endopeptidase, a protease that
degrades vasoactive peptides. Yorek provides an informative
discussion on the therapeutic potential of this new class
of drugs in the treatment of diabetic neuropathy.
Russell and colleagues introduce the idea that excessive release
of glutamate, and subsequent activation of ionotropic glutamate
receptors (iGluRs) and some metabotropic glutamate receptors
(mGluRs) underlie nervous system damage in diabetes. An understanding
of the mGluRs appears particularly informative. Activation
of group-II (mGluR2 and -3) or group-III metabotropic glutamate
receptors (mGluR4, -6, -7 and -8) provides protection against
nervous system injury. Of mechanistic interest, antagonism
of group-I mGluRs (mGluR1 and -5) is also necessary for neuroprotection.
This complex interplay between members of the metabotropic
glutamate receptor family affords a unique opportunity for
drug development and therapeutic intervention. Direct or indirect
activation of mGluR2/3 protects again the development and
progression of diabetic neuropathy in experimental animal
models. Russell and colleagues suggest that select metabotropic
glutamate receptor agonists provide a new class of drugs for
the treatment of diabetic neuropathy.
The issue ends by a review by Vincent and coworkers on the
use of antioxidants in the treatment of diabetic neuropathy.
Extensive animal and in vitro experiments suggest
that a series of interrelated defects in protein structure
and function and/or in vascular tone lead to diabetic neuropathy.
One unifying mechanism of nervous system injury lies in the
ability of both metabolic and vascular insults to increase
cellular oxidative stress and impair the function of mitochondria.
Antioxidants that target different components of the oxidative
stress pathways have been used and are currently in clinical
trials for the treatment of diabetic neuropathy. The known
efficacy of these therapies is discussed, along with their
future promise as effective therapies in disease treatment.
In summary, this issue provides a timely review of established
theories on the pathogenesis of diabetic neuropathy leading
to continued drug development as well as introducing novel
concepts of disease pathogenesis that provide new classes
of drug targets for mechanism-based therapies.
Eva L. Feldman
University of Michigan,
Department of Neurology,
Room 5017 BSRB, 109 Zina Pitcher Place,
Ann Arbor, Michigan 48109,
USA;
E-mail: efeldman@umich.edu
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Criteria for Creating and Assessing Mouse Models of Diabetic
Neuropathy
K.A. Sullivan, S.I. Lentz, J.L. Roberts Jr. and E.L. Feldman
Diabetic neuropathy (DN) is a serious and debilitating
complication of both type 1 and type 2 diabetes. Despite intense
research efforts into multiple aspects of this complication,
including both vascular and neuronal metabolic derangements,
the only treatment remains maintenance of euglycemia. Basic
research into the mechanisms responsible for DN relies on
using the most appropriate animal model. The advent of genetic
manipulation has moved mouse models of human disease to the
forefront. The ability to insert or delete genes affected
in human patients offers unique insight into disease processes;
however, mice are still not humans and difficulties remain
in interpreting data derived from these animals. A number
of studies have investigated and described DN in mice but
it is difficult to compare these studies with each other or
with human DN due to experimental differences including background
strain, type of diabetes, method of induction and duration
of diabetes, animal age and gender. This review describes
currently used DN animal models. We followed a standardized
diabetes induction protocol and designed and implemented a
set of phenotyping parameters to classify the development
and severity of DN. By applying standard protocols, we hope
to facilitate the comparison and characterization of DN across
different background strains in the hope of discovering the
most human like model in which to test potential therapies.
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Aldose Reductase, Still a Compelling Target for Diabetic Neuropathy
P.J. Oates
Aldose reductase (AR) enzymatically transforms cytosolic
glucose into sorbitol, a molecule that poorly penetrates cell
membranes and is sometimes slowly metabolized. Hyperglycemia
can cause intracellular accumulation of sorbitol and its metabolite,
fructose, which can create osmotic swelling and cell dysfunction.
Driven by this simple paradigm, the “Osmotic Hypothesis,”
and armed with positive pre-clinical results on prototype
AR inhibitors (ARIs), researchers worldwide have targeted
diabetic neuropathy with ARIs for four decades. However, most
double-blind placebo-controlled ARI diabetic neuropathy trial
outcomes have been disappointing. Ironically, scientific evidence
that AR plays a key pathogenic role in diabetic neuropathy
has continued to mount. Diabetic mice lacking AR exhibit strong
protection of nerve function. Diabetic mice overexpressing
AR have accelerated nerve dysfunction and damage. Human diabetics
with "high AR expression" alleles shows faster loss
of maximum pupillary constriction velocity, an indicator of
autonomic neuropathy, while those with "low AR expression"
alleles have slower loss of foot hot thermal threshold, an
indicator of sensory neuropathy. Evidence is now strong that
the Osmotic Hypothesis and the nerve sorbitol endpoint were
misleading. Reliance on nerve sorbitol to assess AR inhibition
likely caused underestimation of doses needed for clinical
efficacy and overestimation of drug safety margins. Current
recognition of the pathogenic importance of oxidative stress
and its strong link to metabolic flux through AR have led
to a revitalized "Metabolic Flux Hypothesis" emphasizing
cofactor turnover rather than polyol accumulation. Hopefully,
these new insights will lead to novel ARIs that will effectively
and safely slow the progression of diabetic neuropathy.
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Is C-Peptide Replacement the Missing Link for Successful
Treatment of Neurological Complications in Type 1 Diabetes?
A.A.F. Sima and H. Kamiya
In this review we will describe the interaction between
insulin and C-peptide which enhances and attenuates insulin-signaling
functions. We will describe how replenishment of C-peptide
prevents and reverses the early metabolic abnormalities in
type 1 diabetic polyneuropathy, such as Na+/K+-ATPase
activity and endoneurial vascular NO release, resulting in
prevention and reversal of early nerve dysfunction. The effects
on expression of neurotrophic factors and their receptors,
mediated by corrections of early gene responses and transcription
factors, have downstream beneficial effects on cytoskeletal
protein mRNAs and protein expression. Similar effects probably
underlie corrections of cell adhesive molecules. The end-effects
are prevention and reversal of myelinated and unmyelinated
axonal degeneration, atrophy, and loss. Similarly, progressive
degeneration of the node and paranode is prevented and repaired
by C-peptide replacement with normalization of the molecular
constituents of these functionally important structures. Cognitive
dysfunction is now recognized as a complication of type 1
diabetes. Experimentally it is linked to impaired synaptic
plasticity and eventually apoptotic neuronal loss caused by
impaired insulin action and neurotrophic support. C-peptide
replacement partially prevents hippocampal neuronal apoptosis
and cognitive deficits. It is therefore becoming increasingly
clear that C-peptide has major functions in supporting insulin
action with a multitude of beneficial effects on diabetic
polyneuropathy and primary diabetic encephalopathy in type
1 diabetes.
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Growth Factors as Therapeutics for Diabetic Neuropathy
N.A. Calcutt, C.G. Jolivalt and P. Fernyhough
There has been a rapid growth in appreciation of the
diverse array of neurotrophic factors, growth factors and
other biological molecules that have the capacity to support
adult neurons and direct reparative processes after injury
to the nervous system. Understanding the mechanisms by which
these factors operate offers the opportunity to use either
the factors themselves or other agents that manipulate relevant
signal transduction pathways as therapeutics for a wide range
of neurodegenerative diseases, including diabetic neuropathy.
In this review, we aim to summarize current knowledge of the
extent to which loss of neurotrophic support contributes to
the pathogenesis of diabetic neuropathy, present pre-clinical
evidence that supports the potential efficacy of growth factors
or their mimetics against indices of diabetic neuropathy and
highlight the emerging approaches to manipulating neuronal
support mechanisms that show potential for translation to
clinical use. Recent advances in directly assessing the progression
of nerve damage in diabetic patients will hopefully facilitate
renewed clinical evaluation of treatments for degenerative
diabetic neuropathy and provide the framework for advancing
the potential of growth factors as a therapy for this widespread
and currently untreatable condition.
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Pro-Inflammatory Mechanisms in Diabetic Neuropathy: Focus
on the Nuclear Factor Kappa B Pathway
N.E. Cameron and M.A. Cotter
Neuropathy is a common complication of diabetes mellitus,
which reduces the quality of life and may be life-threatening.
The etiology is complex and multifactorial: hyperglycemia
and dyslipidemia give rise to oxidative stress and formation
of advanced glycation and lipoxidation end products. These
stimulate inflammatory processes, nuclear factor κB
(NFκB)
activation being of central importance. Many of the drugs
that have been developed for treatment of diabetic complication
at least in part work through suppressing either NFκB
activation itself, or the production of cytokines that stimulate
NFκB,
such as tumor necrosis factor (TNF) α.
To date there have been few tests of drugs that are specific
inhibitors of the NFκB
/ TNFα
axis. However preliminary results in animal models are encouraging
and go some way in establishing the NFκB
cascade as an important therapeutic target for diabetic vascular
complications in general, and neuropathy in particular.
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Cyclooxygenase-2 Pathway as a Potential Therapeutic Target
in Diabetic Peripheral Neuropathy
A.P. Kellogg, H.T. Cheng and R. Pop-Busui
Diabetic peripheral neuropathy (DPN) is the most common
diabetic complication and is the leading cause of diabetes-related
hospital admissions and non-traumatic amputations. DPN is
also associated with a poor quality of life and high economic
costs for both type 1 and type 2 diabetic patients. An effective
treatment for DPN, besides tight glycemic control, is not
yet available. The pathogenesis of DPN is complex and involves
an intertwined array of mechanisms. Glucose-mediated alteration
of cyclooxygenase (COX) pathway activity with subsequent impaired
production and function of prostaglandins (PGs) is one mechanism
that is implicated in the pathogenesis of DPN. COX-2, the
inducible COX isoform, is upregulated in a variety of pathophysiological
conditions including diabetes. COX-2 upregulation has tissue-specific
consequences and is associated with activation of downstream
inflammatory reactions. We have previously reported that COX-2
is upregulated in the peripheral nerves and dorsal root ganglia
neurons in experimental diabetes and that COX-2 gene inactivation
and/or selective COX-2 inhibition provides protection against
various DPN deficits. This review will summarize current evidence
supporting the role of COX-2 activation in inducing diabetic
neurovascular dysfunction and that modulation of the COX-2
pathway is a potential therapeutic target for DPN.
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The Potential Role of Angiotensin Converting Enzyme and Vasopeptidase
Inhibitors in the Treatment of Diabetic Neuropathy
M.A. Yorek
Diabetic neuropathy is a debilitating disorder that occurs
in more than 50 percent of patients with diabetes. Evidence
suggests that there are at least five major pathways involved
in the development of diabetic neuropathy: metabolic, vascular,
immunologic, neurohormonal growth factor deficiency, and extracellular
matrix remodeling. In light of the complicated etiologies,
an effective treatment for diabetic neuropathy has not yet
been identified. Hyperglycemia increases tissue angiotensin
II, which induces oxidative stress, endothelial damage and
other pathologies including vasoconstriction, thrombosis,
inflammation and vascular remodeling. Angiotensin converting
enzyme inhibition and/or blocking of the angiotensin II receptor
are recognized as first line treatment for nephropathy and
cardiovascular disease in diabetes patients. A new class of
drug in late stages of development is vasopeptidase inhibitors.
This drug inhibits both angiotensin converting enzyme activity
and neutral endopeptidase. Neutral endopeptidase is a protease
that degrades a number of biologically active peptides including
vasoactive peptides. However, little information is available
about the potential benefits of these drugs on diabetic neuropathy.
Pre-clinical studies suggest that these drugs may be useful
in treating diabetic complications involving vascular tissue.
The purpose of this review is to evaluate the use of angiotensin
converting enzyme and vasopeptidase inhibitors in the treatment
of diabetic neuropathy.
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Metabotropic Glutamate Receptors (mGluRs) and Diabetic Neuropathy
M. Anjaneyulu, A. Berent-Spillson and J.W. Russell
Multiple in vivo and in vitro studies
show that excessive release of glutamate, and subsequent activation
of ionotropic glutamate receptors (iGluRs) and some metabotropic
glutamate receptors (mGluRs) cause neuronal cell death through
either necrosis or apoptosis. However, recently alternative
evidence has shown that mGluRs have modulatory effects on
excitotoxicity and neuronal cell death. Metabotropic glutamate
receptors form a family of eight subtypes (mGluR1-8), subdivided
into three groups (I-III) that initiate their biological effects
by G protein-linked intracellular signal transduction. Their
expression throughout the mammalian nervous system implicates
these receptors as essential mediators of a cell's fate during
injury to the nervous system. Activation of group-II (mGluR2
and -3) or group-III metabotropic glutamate receptors (mGluR4,
-6, -7 and -8) has been established to be neuroprotective
in vitro and in vivo. In contrast, group-I
mGluRs (mGluR1 and -5) need to be antagonized in order to
evoke protection. The pathological signaling pathways associated
with diabetic neuropathy are complex and this influences development
of appropriate therapies. The Group II mGluRs target several
signaling pathways affected in diabetic neuropathy, prevent
cellular injury in the peripheral nervous system, and may
provide a novel mechanism for treatment of diabetic neuropathy.
Direct or indirect activation of mGluR2/3 in animal models
protects against development of diabetic neuropathy. The potential
mechanisms and role of mGluRs in protection against diabetic
neuropathy will be reviewed.
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The Antioxidant Response as a Drug Target in Diabetic Neuropathy
A.M. Vincent, J.L. Edwards, M. Sadidi and E.L. Feldman
While increasing antioxidant potential is an attractive
treatment strategy for diabetic neuropathy, many years of
trials using high-dose oral antioxidants have not produced
therapeutic results. An increasing understanding of the innate
antioxidant response and the pharmacological agents that can
regulate this mechanism may open new avenue for drug development.
This review describes the current state of antioxidant trials
and the potential for targeting the antioxidant response.
In combination with antihyperglycemic agents, agents that
regulate the antioxidant response may afford superior protection
against cellular oxidative injury in diabetes.
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