| Current
Drug Targets
ISSN: 1389-4501
Current Drug Targets
Volume 6, Number 1, January 2005
Contents
Role of Gene and Stem Cell Therapies in the Treatment of
Neurological Disorders
Guest Editor: U. Galderisi
[Abstract] [Full
text article]
Stem Cell Therapy for Myelin Diseases Pp.3-19
Tamir Ben-Hur, Ofira Einstein and Jeff W.M. Bulte
[Abstract] [Full
text article]
Small Interfering RNAs and Antisense Oligonucleotides for
Treatment of Neurological Diseases Pp.21-29
A. Forte, M. Cipollaro, A. Cascino and U. Galderisi
[Abstract] [Full
text article]
Integral Therapeutic Potential of Bone Marrow Mesenchymal
Stem Cells Pp.31-41
I. Kan, E. Melamed and D. Offen
[Abstract] [Full
text article]
Huntington’s Disease: New Frontiers for Molecular
and Cell Therapy Pp.43-56
Mariarosa A.B. Melone, Francesco P. Jori and Gianfranco Peluso
[Abstract] [Full
text article]
Stem Cell Therapy for Neurologic Disorders: Therapeutic
Potential of Adipose-Derived Stem Cells Pp.57-62
Kristine M. Safford and Henry E. Rice
[Abstract] [Full
text article]
Adult Stem Cell Application in Spinal Cord Injury Pp.63-73
Sherri S. Schultz
[Abstract] [Full
text article]
Neuropathic Pain: Is the End of Suffering Starting in the
Gene Therapy? Pp.75-80
D. Siniscalco, V. de Novellis, F. Rossi and S. Maione
[Abstract] [Full
text article]
Combining Polymeric Devices and Stem Cells for the
Treatment of Neurological Disorders: A Promising Therapeutic
Approach Pp.81-96
V.M. Tatard, P. Menei, J.P. Benoit and C.N. Montero-Menei
[Abstract] [Full
text article]
Adult Neural Stem Cell Therapy: Expansion In Vitro,
Tracking In Vivo and Clinical Transplantation Pp.97-110
J. Zhu, X. Wu and H.L. Zhang
[Abstract] [Full
text article]
Endogenous and Exogenous CNS Derived Stem/Progenitor
Cell Approaches for Neurotrauma Pp.111-126
I. Kulbatski, A.J. Mothe, H. Nomura and C.H. Tator
[Abstract] [Full
text article]
Abstracts
[Back to top]
Role of Gene and Stem Cell Therapies in the Treatment of
Neurological Disorders
Guest Editor: U. Galderisi
[Full text
article]
Gene and Cell therapies have paved the way to a new era
in the treatment of human diseases. Knowledge about the potentiality
and limits of such therapeutical tools is of great interest.
The use of antisense oligonucleotides and more recently,
of small interfering RNAs (siRNAs) as selective inhibitors
of gene expression, offers a rational approach to the prevention
and treatment of some gene-mediated disorders. In this gene
therapy approach, oligonucleotides or siRNAs block the expression
of specific target genes involved in the development of the
pathological processes.
The use of antisense molecules to modify gene expression
has been found to be variable in its efficacy and reliability,
raising objections about their use as therapeutic agents.
However, several antisense candidate molecules are undergoing
separate clinical trials. It is still too early to tell whether
the entire class of antisense drugs will prove to be clinically
effective. It is, however, quite surprising that all efforts
devoted to clinical trials of dozens of antisense compounds
have so far produced only a commercial drug, targeted against
a side effect of HIV infection and hence, with a limited market
value. Nevertheless, the antisense oligonucleotides could
be one of the few strategies that could be used to treat some
neurodegenerative diseases. In this issue, some contributions
discuss the promises and concerns linked to the development
of a new generation of antisense molecules for treatment of
neural diseases.
Concerns about antisense therapeutics have induced researchers
to focus on other gene therapy tools. Gene expression downregulation
by siRNAs (the so called RNA interference) is one of the most
exciting discoveries of the past decade in functional genomics.
Some authors have reported that the potency, effectiveness,
duration of action, and sequence specificity of siRNAs are
greater than those obtained with antisense molecules.
For this reason, RNA interference is rapidly becoming an
important method for analyzing gene functions in eukaryotes,
and promises the development of therapeutic gene silencing.
This topic is also discussed in this issue.
Stem cell therapy seeks to reverse the ravages of damaged
tissues by injecting living stem cells from animal organs,
embryos or fetuses into patients.
Traditional cell therapy is founded on the belief that, when
healthy cells are injected into patients, cells will automatically
find their way to damaged tissues and stimulate the body's
own healing process. For example, there is evidence that liver
stem cells injected into the human body naturally migrate
to the host liver and stimulate regeneration.
Stem cell therapy is promoted as an alternative therapy for
several pathologies, such as cancer, atherosclerosis, and
several neurodegenerative diseases.
Unfortunately, there are a number of potential side effects
regarding which, the individuals considering this therapy
should be made aware. Indeed, cell therapy may be dangerous
and some cases in medical literature reported of patient deaths
directly linked to the therapy. Patients may contract bacterial
and viral infections carried by the donor cells, and have
experienced life-threatening and even fatal allergic reactions.
Donor cells may seriously compromise the immune system.
Thus, despite extensive research, still there are problems
with stem cell therapy, since in many cases, deep and exhaustive
studies to find out the exact biology of stem cells are omitted,
and there are increasing pressures to start with insufficiently
controlled clinical trials. It is very important to address
all these issues, and therefore, some contributions are focused
on these key topics and give an in-depth contribution to the
knowledge of the state of art in cell therapy, with particular
emphasis on the treatment of neural diseases.
[Back to top]
Stem Cell Therapy for Myelin Diseases
Tamir Ben-Hur, Ofira Einstein and Jeff W.M. Bulte
[Full text article]
Advances in cell biology have encouraged the hope that stem
cell-based therapy can be used to heal central nervous system
(CNS) diseases. Here, we will review the potential application
of neural cell transplantation for the treatment of multiple
sclerosis (MS) and other demyelinating disorders, mention
some problematic issues that still face this therapeutic approach,
and describe novel noninvasive methods for in vivo tracking
of transplanted cells.
[Back to top]
Small Interfering RNAs and Antisense Oligonucleotides for
Treatment of Neurological Diseases
A. Forte, M. Cipollaro, A. Cascino and U. Galderisi
[Full text article]
The complexity of the central nervous system (CNS) exposes
it to a number of different diseases, often caused by only
small variations in gene sequence or expression level.
Antisense oligonucleotides and RNA interference-mediated
therapies hold great promise for the treatment of CNS diseases
in which neurodegeneration is linked to overproduction of
endogenous protein or to synthesis of aberrant proteins coded
by dominant mutant alleles. Nevertheless, difficulties related
to the crossing of the blood-brain barrier, expression vectors,
molecule design and to the choosing of the correct target,
should be effectively solved.
This review summarizes some of the most recent findings concerning
the administration of potential nucleic acid-based therapeutic
drugs, as well as the most promising studies performed both
in vitro and in animal models of disease. Finally,
some current clinical trials involving antisense oligonucleotides
or silencing RNA for therapy of neurological disorders are
illustrated.
Results of current studies and clinical trials are exciting,
and further results will be certainly reached with increasing
knowledge of blood-brain barrier transporters, of genes involved
in neurological disease and in new vectors for efficient delivery
to brain.
[Back to top]
Integral Therapeutic Potential of Bone Marrow Mesenchymal
Stem Cells
I. Kan, E. Melamed and D. Offen
[Full text article]
Bone marrow derived mesenchymal stem cells (MSC) are adult
stem cells that reside within the bone marrow compartment.
In the traditional developmental model, adult stem cells are
able to differentiate only to the tissue in which they reside.
Recent data have challenged the committed fate of the adult
stem cells, presenting evidence for their multilineage differentiation
potential. In addition, potential therapeutic benefits of
MSC administration have been the main concern of much research,
including clinical trials. These studies promote adult stem
cell therapy by shedding some light on the therapeutic potential
of MSC and their mechanism of action.
Many doubts have found their way into MSC research. They
question MSC potency and beneficial contribution. However,
these obstacles should not arrest but set a challenge to MSC
researchers to examine their achievements under a magnifying
glass.
Therapeutic benefits of MSC exogenous delivery do not run
counter to its possible participation in endogenous repair.
Several reports imply MSC involvement in physiological repair
but no explicit data support this hypothesis.
This review tries to put MSC research into perspective. Possible
therapeutic applications of MSC therapy for damaged tissue
replacement, tissue engineering and the underlying repair
mechanisms will be discussed. In addition, reported data about
MSC possible involvement in physiological multiple tissue
repair, their homing to injury and site-specific differentiation
will be presented.
[Back to top]
Huntington’s Disease: New Frontiers for Molecular
and Cell Therapy
Mariarosa A.B. Melone, Francesco P. Jori and Gianfranco
Peluso
[Full text article]
Huntington’s disease (HD) is an incurable, adult-onset,
dominantly inherited neurodegenerative disease, caused by
a CAG expansion in the 5' coding region of the gene HD [encoding
huntingtin (htt), which is ubiquitously expressed in all tissues].
The disease progresses inexorably with devastating clinical
effects on motor, cognitive and psychological functions; death
occurring approximately 18 years from the time of onset. These
clinical symptoms primarily relate to the progressive death
of medium-spiny GABA-ergic neurons of the striatum and in
the deep layers of the cortex; during the later stages of
the disease, the degeneration extends to a variety of brain
regions, including the hypothalamus and hippocampus. The mechanism
by which mutant htt leads to neuronal cell death and the question
of why striatal neurons are targeted both remain to be further
investigated. Certainly htt is required for cell survival
and impairment of wild-type htt function can be involved in
neurodegeneration, but considerable evidence also shows that
trinucleotide repeat expansion into glutamine (polyQ domain)
endows the protein with a newly acquired toxic activity. The
increasing availability of HD animal models have allowed not
only to investigate the function of htt, but also to screen
and test potential therapeutic drugs in the promising area
of neurotherapeutics. So, thorough analysis of these molecular
and biochemical events, assessing the validity of candidate
mechanisms, provides a means to identify effective therapeutic
strategies for cellular repair. Here, the rationale and efficacy
of different therapies are compared and alternative therapies
are reviewed including intrastriatal transplantation of human
fetal striatal tissue to support the cell replacement strategy
in HD. Since functional restoration through neuronal replacement
probably could be combined with neuroprotective strategies
for optimum clinical benefit, in vivo and ex vivo gene therapy
for delivery of neuroprotective growth factor molecules are
also considered.
[Back to top]
Stem Cell Therapy for Neurologic Disorders: Therapeutic
Potential of Adipose-Derived Stem Cells
Kristine M. Safford and Henry E. Rice
[Full text article]
There is growing evidence to suggest that reservoirs of stem
cells may reside in several types of adult tissue. These cells
may retain the potential to transdifferentiate from one phenotype
to another, presenting exciting possibilities for cellular
therapies.
Recent discoveries in the area of neural differentiation
are particularly exciting given the limited capacity of neural
tissue for intrinsic repair and regeneration. Adult adipose
tissue is a rich source of mesenchymal stem cells, providing
an abundant and accessible source of adult stem cells. These
cells have been termed adipose derived stem cells (ASC). The
characterization of these ASCs has defined a population similar
to marrow-derived and skeletal muscle-derived stem cells.
The success seen in differentiating ASC into various mesenchymal
lineages has generated interest in using ASC for neuronal
differentiation. Initial in vitro studies characterized the
morphology and protein expression of ASC after exposure to
neural induction agents. Additional in vitro data suggests
the possibility that ASCs are capable of neuronal activity.
Progress in the in vitro characterization of ASCs has led
to in vivo modeling to determine the survival, migration,
and engraftment of transplanted ASCs.
While work to define the mechanisms behind the transdifferentiation
of ASCs continues, their application to neurological diseases
and injuries should also progress. The subject of this review
is the capacity of adipose derived stem cells (ASC) for neural
transdifferentiation and their application to the treatment
of various neurologic disorders.
[Back to top]
Adult Stem Cell Application in Spinal Cord Injury
Sherri S. Schultz
[Full text article]
The mechanical force incurred by spinal cord injury results
in degenerative neural tissue damage beyond the site of initial
injury. By nature, the central nervous system (CNS) does not
regenerate itself. Cell therapy, in particular, stem cell
implantation has become a possible solution for spinal cord
injury. Embryonic stem cells and fetal stem cells are the
forefathers of the field of stem cell therapy. Isolation and
preparation of specific populations of adult stem cells have
evolved to the point of stable, long-term culturing with the
capability to differentiate into neural phenotypes from all
three of the neural lineages: neurons, astrocytes, and oligodendrocytes.
Thus, adult stem cells will transcend ethical concerns, technical
difficulties, and probably immunorejection. A variety of adult
stem cells have been implanted in a rat model of spinal cord
injury, ranging from olfactory ensheathing cells, cultured
spinal cord stem cells, bone marrow derived stem cells, dermis
derived stem cells, and a few others. Although no definite
decisions on which adult stem cells are most effective for
this CNS injury, their ability to incorporate into the spinal
cord, differentiate, and to improve locomotor recovery hold
promise for a cure.
[Back to top]
Neuropathic Pain: Is the End of Suffering Starting in the
Gene Therapy?
D. Siniscalco, V. de Novellis, F. Rossi and S. Maione
[Full text article]
Neuropathic pain is defined as pain initiated or caused by
a primary lesion or dysfunction in the nervous system. It
is a devastating and difficult to manage consequence of peripheral
nerve injury and has a variety of clinical symptoms.
Neuropathic pain is a major health problem. It has been estimated
that 70% of patients with advanced cancer and inflammatory
pathologies are afflicted by chronic pain. About 95% of patients
with spinal cord injuries have neuropathic pain problems.
Chronic pain is debilitating and cause of depression and decreasing
quality of life.
Pharmacological treatment for the symptoms of painful neuropathy
is difficult, because there has been limited understanding
of the underlying causes and systemic levels that an effective
dose can have on multiple side effects. The use of molecular
methods, such as gene therapy, stem cell therapy and viral
vector for delivery of biologic antinociceptive molecules,
has led to a better understanding of the underlying mechanisms
of the induction of intractable neuropathic pain.
[Back to top]
Combining Polymeric Devices and Stem Cells for the
Treatment of Neurological Disorders: A Promising Therapeutic
Approach
V.M. Tatard, P. Menei, J.P. Benoit and C.N. Montero-Menei
[Full text
article]
Cell therapy will probably become a major therapeutic strategy
for neuronal disorders in the coming years. Nevertheless,
due to poor survival of grafted cells and limited differentiation
and integration in the host tissue, certain ameliorations
must be envisaged. To address these difficulties, several
strategies have been developed and among them, two methods
seem particularly promising : in situ controlled drug delivery
and implantation of cells adhered on biomaterial-based scaffolds.
Indeed, the ability of drugs, such as growth factors, to regulate
neuronal survival and/or plasticity infers the use of these
molecules to treat neurodegeneration associated with human
diseases. Moreover, the synthesis of cell scaffolds which
mimic the extra-cellular matrix can help guide morphogenesis
and tissue repair. Furthermore, cells can be cultivated on
these matrices that may eventually make graft therapy a more
practical approach for the treatment of neurological diseases.
Nevertheless, for those two encouraging approaches multiple
parameters have to be considered, such as the drug targeting
strategy, but also the physical and morphological characteristics
of the scaffold and the type of cells to be conveyed. This
review thus focuses on those two promising strategies and
also on their possible association to improve stem cell therapy
of neurodegenerative disorders. Indeed, tissue replacement
by grafting cells within or adhered onto drug delivering biomaterial-based
devices, has recently been reported and seems to be very promising.
[Back to top]
Adult Neural Stem Cell Therapy: Expansion In Vitro,
Tracking In Vivo and Clinical Transplantation
J. Zhu, X. Wu and H.L. Zhang
[Full text article]
Neural stem cells (NSCs) are present not only in the developing
nervous systems, but also in the adult human central nervous
system (CNS). It is long thought that the subventricular zone
of the lateral ventricles and the dentate gyrus of the hippocampus
are the main sources of human adult NSCs, which are considered
to be a reservoir of new neural cells. Recently adult NSCs
with potential neural capacity have been isolated from white
matter and inferior prefrontal subcortex in the human brain.
Rapid advances in the stem cell biology have raised appealing
possibilities of replacing damaged or lost neural cells by
transplantation of in vitro -expanded stem cells
and/or their neuronal progeny. However, sources of stem cells,
large scale expansion, control of the differentiations, and
tracking in vivo represent formidable challenges.
In this paper we review the characteristics of the adult human
NSCs, their potentiality in terms of proliferation and differentiation
capabilities, as well as their large scale expansion for clinical
needs. This review focuses on the major advances in brain
stem cell–based therapy from the clinical perspective,
and summarizes our work in clinical phase I-II trials with
autologuous transplantation of adult NSCs for patients with
open brain trauma. It also describes multiple approaches to
monitor adult human NSCs labeled superparamagnetic nanoparticles
after transplantation and explores the intriguing possibility
of stem cell transplantation.
[Back to top]
Endogenous and Exogenous CNS Derived Stem/Progenitor Cell
Approaches for Neurotrauma
I. Kulbatski, A.J. Mothe, H. Nomura and C.H. Tator
[Full text article]
Neural stem/progenitor cells capable of generating new neurons
and glia, reside in specific areas of the adult mammalian
central nervous system (CNS), including the ependymal region
of the spinal cord and the subventricular zone (SVZ), hippocampus,
and dentate gyrus of the brain. Much is known about the neurogenic
regions in the CNS, and their response to various stimuli
including injury, neurotrophins (NFs), morphogens, and environmental
factors like learning, stress, and aging. This work has shaped
our current views about the CNS’s potential to recover
lost tissue and function post-traumatically and the therapies
to support the intrinsic regenerative capacity of the brain
or spinal cord. Recently, intensive research has explored
the potential of harvesting, culturing, and transplanting
neural stem/progenitors as a therapeutic intervention for
spinal cord injury (SCI) and traumatic brain injury (TBI).
Another strategy has focused on maximizing the potential of
this endogenous population of cells by stimulating their recruitment,
proliferation, migration, and differentiation in vivo following
traumatic lesions to the CNS. The promise of such experimental
treatments has prompted tissue and biomaterial engineers to
implant synthetic three-dimensional biodegradable scaffolds
seeded with neural stem/progenitors into CNS lesions. Although
there is no definitive answer about the ideal cell type for
transplantation, strong evidence supports the use of region
specific neural stem/progenitors. The technical and logistic
considerations for transplanting neural stem/progenitors are
extensive and crucial to optimizing and maintaining cell survival
both before and after transplantation, as well as for tracking
the fate of transplanted cells. These issues have been systematically
addressed in many animal models, that has improved our understanding
and approach to clinical therapeutic paradigms.
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