|
Current
Pharmaceutical Biotechnology
ISSN: 1389-2010
Current Pharmaceutical Biotechnology
Volume 9, Number 4, August 2008
Contents
Hyaluronan, A Very Useful Sugar Polymer
Guest Editor: Paul L. DeAngelis
Editorial Pp. 235
Hyaluronan as an Ophthalmic Viscoelastic Device
Pp. 236-238
Endre A. Balazs
[Abstract]
Recombinant Production of Hyaluronic Acid
Pp. 239-241
Stephen H. Brown and Philip E. Pummill
[Abstract]
Chemically-Modified HA for Therapy and Regenerative
Medicine Pp. 242-245
Glenn D. Prestwich and Jing-wen Kuo
[Abstract]
Monodisperse Hyaluronan Polymers: Synthesis
and Potential Applications Pp. 246-248
Paul L. DeAngelis
[Abstract]
Hyaluronan Oligosaccharides as a Potential Anticancer
Therapeutic Pp. 249-252
Bryan P. Toole, Shibnath Ghatak and Suniti Misra
[Abstract]
The Development of Hyaluronan as a Drug Transporter
and Formulation Vehicle for Chemotherapeutic Drugs
Pp. 253-260
Tracey J. Brown
[Abstract]
General Articles
The Use of Phages for the Removal of Infectious Biofilms
Pp. 261-266
J. Azeredo and I. W. Sutherland
[Abstract]
Probiotics: From Functional Foods to Pharmaceutical
Products Pp. 267-287
Tripta Bansal and Sanjay Garg
[Abstract]
Jatropha curcas L., A Multipurpose Stress
Resistant Plant with a Potential for Ethnomedicine and Renewable
Energy Pp. 288-306
Mousumi Debnath and P.S. Bisen
[Abstract]
Hydrolyzates of Silkworm Pupae (Bombyx Mori)
Protein is a New Source of Angiotensin I-Converting Enzyme
Inhibitory Peptides(ACEIP) Pp. 307-314
Wei Wang, Shengrong Shen, Qihe Chen, Bo Tang, Guoqing
He, Hui Ruan and Undurti N. Das
[Abstract]
Therapeutic Biology of Jatropha curcas: A Mini
Review Pp. 315-324
Reena Thomas, Nand K Sah and P. B. Sharma
[Abstract]
Modulation of Cellular Response to Anticancer
Treatment by Caffeine: Inhibition of Cell Cycle Checkpoints,
DNA Repair and More Pp. 325-336
Michal Sabisz and Andrzej Skladanowski
[Abstract]
Abstracts
[Back to top]
Editorial:
In 1934, the polysaccharide hyaluronan
[hyaluronic acid or HA] was extracted from bovine eyes by
Karl Meyer. As of early 2008, >22,000 research papers on
HA-related science, >1,500 US patents with HA claims, and
a ~$1.5 billion/year market (“Global Markets for Hyaluronic
Acid” Millenium Research 2006) definitively prove the
value of HA. This sugar polymer is in the same chemical family
as heparin, an anticoagulant and an antithrombotic
that is the most widely used drug in hospitals. This series
of articles describe aspects, both historical and emerging,
of HA in the world of pharmacology and biotechnology.
The sheer abundance of HA in mammalian tissues in certain
structures such as the vitreus of eye, the synovial fluid
of joints and the dermis of skin spawned the initial idea
that HA was a space filler with superb viscoelastic
and hydrating properties. The simple repeating unit
structure of HA composed of two monosaccharides, (-beta-4-GlcA-1-beta-3-GlcNAc-1)n
, also masked its potential for biological complexity; this
prejudice is reminiscent of the ‘boring’ DNA molecule
composed of just 4 simple bases! HA is also important for
boosting infection by certain microbes; these pathogens coat
themselves with a molecule that is identical to vertebrate
HA to avoid host defenses.
The complex machinery for the synthesis (3 genes) and the
degradation (perhaps 7 genes) of HA in mammals as well as
its effects on the behavior and the proliferation of a variety
of cells suggest that in many circumstances, HA and
its metabolic products contain information. In the
most current hypotheses, the molecular weight (MW), the amount,
and the location of the HA molecule effects its ability to
trigger various signals that appear to cue development as
well as alter inflammation, cell mobility and adhesion in
both health and disease. For example, very large mass (2-
8x106 Da or n=~103-4
) and very small mass (~103
Da or n=~2-20) HA molecules can have opposite effects
on cells with respect to angiogenesis and to cancer cell growth
and metastasis (B. Toole et. al). Thus the recent
availability of pure, defined narrow size distribution HA
preparations (P. DeAngelis) bode well for drug discovery and
development.
Purified HA from a variety of sources is used in a variety
of medical applications. HA was initially isolated from rooster
(chicken) comb and used as medical devices for eye surgeries
(E. Balazs) and arthritic pain. Extraction of native and now
recombinant bacteria (S. Brown & P. Pummill) is now a
significant source of less expensive HA.
In addition to the native polymeric form of HA, a
variety of chemical analogs have been made to alter its physical
properties (G. Prestwich & J. Kuo). Cross-linking
or esterification have been used to convert HA from its normal
extremely viscous liquid state to more solid forms (e.g.,
gels, fabrics, etc) with longer biological half-life that
retain shape or maintain volume. In the near future, more
tissue engineering applications and drug delivery
systems (T. Brown) for HA should be in clinical trials.
Overall, it is a safe wager that the scope of HA applications
will expand with the availability of HA formulations with
improved performance and as more HA-related biology becomes
elucidated.
Paul L. DeAngelis
Guest Editor
Dept. of Biochemistry and Molecular Biology,
Oklahoma Center for Medical Glycobiology,
Univ. of Oklahoma Health Sciences Center,
940 Stanton L. Young Blvd, Oklahoma City, OK 73126
USA,
E-mail: paul-deangelis@ouhsc.edu
[Back to top]
Hyaluronan as an Ophthalmic Viscoelastic Device
Endre A. Balazs
Hyaluronan solutions known as ophthalmic viscoelastic
devices (OVDs) are used in surgical procedures within the
eye and on the surface of the eye to prevent dryness and to
facilitate wound healing. HA and a variety of derivatives
facilitate procedures including vitreoretinal surgery, anterior
segment surgery, glaucoma surgery, and corneal transplantation.
[Back to top]
Recombinant Production of Hyaluronic Acid
Stephen H. Brown and Philip E. Pummill
Presently, the two main commercial sources of hyaluronic
acid (HA) are rooster combs and streptococci. Harvesting from
rooster combs is complex and costly. Streptococci are difficult
to genetically manipulate and require complex media for growth.
Both sources have potential problems with unwanted by-products,
such as allergens and toxins. These problems can be solved
by producing the HA with safe bacilli that are expressing
a recombinant HA synthase (HAS).
[Back to top]
Chemically-Modified HA for Therapy and Regenerative
Medicine
Glenn D. Prestwich and Jing-wen Kuo
Hyaluronan (HA) is a very useful polymer, but its properties
sometimes need to be altered or enhanced by chemical modification
for biomedical applications. A wide variety of HA derivatives
are currently used for eye surgery, joint viscoelastic supplementation,
and anti-adhesion films. The future promises to deliver new
classes of HA-based reagents as well as new polymers that
can be used in situ with living cells or within the
body.
[Back to top]
Monodisperse Hyaluronan Polymers: Synthesis and Potential
Applications
Paul L. DeAngelis
In many cases, the cellular response to hyaluronan (HA)
depends on the molecular weight (MW) of the polymer chain.
Most HA preparations from Nature or its derivatives possess
wide size distributions called polydisperse. New chemoenzymatic
synthesis technology allows the production of very narrow
size distribution polymers called monodis-perse. The use of
stoichiometrically controlled and synchronized polymerization
reactions allows an assortment of new HA reagents in the range
of 10 kDa to 2,500 kDa for answering HA biology questions
or potentially treating disease.
[Back to top]
Hyaluronan Oligosaccharides as a Potential Anticancer Therapeutic
Bryan P. Toole, Shibnath Ghatak and Suniti Misra
Hyaluronan (HA) polysaccharide has differential effects
on cells depending on polymer size. One of the more exciting
findings is that small chains or oligosaccharides of HA (6-18
sugar units), but not large polymers, will kill many types
of cancer cells by triggering apoptosis while leaving normal
cells unaffected. Even chemoresistant cells become drug-sensitive
when cotreated with HA oligosaccharides. Overall, these observations
form the basis for new anticancer therapeutics.
[Back to top]
The Development of Hyaluronan as a Drug Transporter and Formulation
Vehicle for Chemotherapeutic Drugs
Tracey J. Brown
Despite advances in chemotherapeutic regimens, the treatment
of metastatic cancer remains a challenge. A key problem with
chemotherapy drugs is nonspecific drug distribution, resulting
in low tumor concentrations and systemic toxicity. The holy
grail of clinical cancer research has been to establish more
specific ways of directing therapeutics to tumors, whether
through more targeted anti-cancer agents or via the method
of delivery. Many tumor cells show up-regulated expression
of receptors for the polysaccharide hyaluronan (HA), resulting
in HA having a high affinity for tumors. This observation
has led to the preclinical development of HA-cytotoxin bioconjugates
that utilize HA as the tumor recognition moiety. The primary
challenges have been organ-directed toxicity and limited efficacy.
An alternative, simpler strategy has been to use the large
volumetric domain of HA to entrain small chemotherapeutic
drugs within the HA matrix. The resultant HA/drug formulation
accumulates in the microvascular of the tumor, forming a microembolism
that increases drug retention at the tumor site and allows
for active tumor uptake through HA receptors. Clinical trials
of HA formulations of three anti-cancer drugs have been undertaken
and have demonstrated that such formulations are safe and
efficacious. Within these formulations we postulate that HA
is acting as a novel excipient, capable of improving the therapeutic
index of the active anti-cancer agent.
[Back to top]
The Use of Phages for the Removal of Infectious Biofilms
J. Azeredo and I. W. Sutherland
Biofilm formation occurs spontaneously on both inert
and living systems and is an important bacterial survival
strategy. In humans bioflms are responsible for many pathologies,
most of them associated with the use of medical devices. A
major problem of biofilms is their inherent tolerance to host
defences and antibiotic therapies; there is therefore an urgent
need to develop alternative ways to prevent and control biofilm-associated
clinical infections. Several in vitro experiments
have shown that phages are able to infect biofilm cells and
that those phages inducing the production of depolymerases
have an advantage since they can penetrate the inner layers
of the biofilm by degrading components of the biofilm exopolymeric
matrix. In practice clinically relevant biofilms and especially
those associated with the use of medical devices can possibly
be controlled for example by the topic application or the
impregnation of the surface of the device with a phage solution.
Another interesting approach has been the use of a phage encoding
a phage polysaccharide lyase to treat Pseudomonas aeruginosa
biofilms in cystic fibrosis patients by aerosol administration.
All these strategies require prior identification of the phage
and/or polysaccharide depolymerase capable of infecting the
bacterial cells and degrading the polysaccharide within the
biofilm, respectively. The biofilm organisms must therefore
be isolated and screened against a bank of phages. This procedure
is essential and raises important biotechnological challenges:
the existence of a bank of phages well characterised (physiologically
and genetically) whose efficacy in vivo has been
tested and pharmacokinetics studied; the existence of economical
and safe production protocols and purification methods (e.g.
the presence of endotoxins in a phage preparation may compromise
phage therapy). It is however important to consider the fact
that the chances of getting a specific phage with a high lytic
capability and preferential expressing a relevant exopolymer
degrading enzyme is likely to be low. Genetically engineered
phages can play an important role in this process.
Phages can be genetically manipulated to alter their host
range and to induce the production of depolymerases. It is
therefore important to reinforce the application of synthetic
biology to engineer phages able to efficiently degrade medical
biofilms. It is also important to develop efficient methods
of phage delivery and to study “in vivo”
the phage performance against biofilms. It is still not clear
how effective the biofilm can be in protecting the phages
against the immune system. Efficient and economic phage production
and purification protocols need also to be addressed before
one can hope to use phage treatment to prevent or control
infectious biofilms.
[Back to top]
Probiotics: From Functional Foods to Pharmaceutical Products
Tripta Bansal and Sanjay Garg
The concept of probiotics now has been around for more
than a century, with its consumption increasing exponentially;
owing to exciting scientific and clinical findings, limiting
side effects of existing pharmaceutical agents and increased
consumer demand for natural products. But, the evidence for
their safety and efficacy has largely been anecdotal, lacking
an integrated scientific basis. Clinical studies conducted
with probiotics were of inadequate design and resulted in
unreliable data. That is the reason why despite having innumerable
potential therapeutic uses probiotics are not being universally
accepted. The purpose of present article is to amalgamate
various branches of research which would help in development
of “better”, “commercial” and “pharmaceutical”
probiotic products with defined strength, mechanism of action
and indication. Probiotics have been classified into oral
and vaginal in accordance to their route of administration,
describing the health benefits. The article summarizes the
research on significance of strain selection, interactions
with coadministered agents and appropriate clinical studies
uncovering the safety issues. There is a special emphasis
on pharmaceutical issues including probiotic delivery systems,
technological challenges during formulation, regulatory concerns,
quality control and market potential. Developments in the
techniques for in vitro evaluation have also been
discussed.
[Back to top]
Jatropha curcas L., A Multipurpose Stress Resistant Plant
with a Potential for Ethnomedicine and Renewable Energy
Mousumi Debnath and P.S. Bisen
Jatropha curcas is a stress - resistant perennial
plant growing on marginal soils. This plant is widespread
throughout arid and semiarid tropical regions of the world
and has been used as a traditional folk medicine in many countries.
J.curcas is a source of several secondary metabolites
of medicinal importance. The leaf, fruits, latex and bark
contain glycosides, tannins, phytosterols, flavonoids and
steroidal sapogenins that exhibit wide ranging medicinal properties.
The plant products exhibit anti-bacterial and anti-fungal
activities. The paper highlights the ability of various metabolites
present in the plant to act as therapeutic agents and plant
protectants. The plant is designated as an energy plant and
use of J.curcas oil as biodiesel is a promising and
commercially viable alternative to diesel oil. The seeds of
the plant are not only a source of biodiesel but also contain
several metabolites of pharmaceutical importance. Commercial
exploitation for biopharmaceuticals and bio-energy production
are some of the prospective future potential of this plant.
Further reclamation of wastelands and dry lands is also possible
with J.curcas cultivation.
[Back to top]
Hydrolyzates of Silkworm Pupae (Bombyx Mori) Protein is a
New Source of Angiotensin I-Converting Enzyme Inhibitory Peptides(ACEIP)
Wei Wang, Shengrong Shen, Qihe Chen, Bo Tang, Guoqing
He, Hui Ruan and Undurti N. Das
Silkworm pupae protein is a good source of high quality
protein. The hydrolyzates of silkworm pupae protein catalyzed
by neutrase, pepsin, acidic protease (Asperqiius usamii
NO. 537), flavourzyme, alcalase, and trypsin with inhibitory
activity on angiotensin I-converting enzyme (ACE) were identified
by HPLC. The hydrolyzates catalyzed by acidic protease exerted
the highest inhibitory activity on ACE. The hydrolyzing conditions
were optimized by one-factor, factional factorial (FFD), and
center composite (CCD) design methods, and response surface
methodology (RSM). Statistical analyses showed that regression
of the second-order model equation is suitable to describe
ACE inhibitory bioactivity. The predicted inhibitory activity
of hydrolyzates on ACE was 73.5 % at a concentration of 2.0
mg/ml. Optimized RSM technique decreased IC50
of hydrolyzates inhibiting ACE to 1.4 mg/mL from 2.5mg/ml.
The molecular weight of the components of the hydrolyzates
with inhibitory activity on ACE varied from less than 500
to about 1000 Da by ultra-filter analysis. These studies suggest
that hydrolyzates of silkworm protein contain ACE inhibitory
activity that could form a potential source of ACE inhibitor
drugs.
[Back to top]
Therapeutic Biology of Jatropha curcas: A Mini Review
Reena Thomas, Nand K Sah and P. B. Sharma
Jatropha curcas is a drought resistant, perennial plant
that grows even in the marginal and poor soil. Raising Jatropha
is easy. It keeps producing seeds for many years. In the recent
years, Jatropha has become famous primarily for the production
of biodiesel; besides this it has several medicinal applications,
too. Most parts of this plant are used for the treatment of
various human and veterinary ailments. The white latex serves
as a disinfectant in mouth infections in children. The latex
of Jatropha contains alkaloids including Jatrophine, Jatrophamand
curcain with anti-cancerous properties. It is also used externally
against skin diseases, piles and sores among the domestic
livestock. The leaves contain apigenin,vitexin and isovitexin
etc. which along with other factors enable them to be used
against malaria, rheumatic and muscular pains. Antibiotic
activity of Jatropha has been observed against organisms including
Staphylococcus aureus and Escherichia coli.
There are some chemical compounds including curcin (an alkaloid)
in its seeds that make it unfit for common human consumption.
The roots are known to contain an antidote against snake venom.
The root extract also helps to check bleeding from gums. The
soap prepared from Jatropha oil is efficient against buttons.
Many of these traditional medicinal properties of Jatropha
curcas need to be investigated in depth for the marketable
therapeutic products vis-à-vis the toxicological effects
thereof. This mini review aims at providing brief biological
significance of this plant along with its up-to-date therapeutic
applications and risk factors.
[Back to top]
Modulation of Cellular Response to Anticancer Treatment by
Caffeine: Inhibition of Cell Cycle Checkpoints, DNA Repair
and More
Michal Sabisz and Andrzej Skladanowski
Caffeine and other methylxanthines produce multiple physiologic
effects throughout the human body, many of these effects could
potentially modulate the activity of anticancer therapy. Caffeine
may directly interfere with drug transport to tumor cells
by formation of mixed stacking complexes with polyaromatic
drugs. If formed in cells, these complexes may also prevent
of intercalating drugs from DNA binding and, in this way,
lower their antitumor activity. Since many of potent carcinogens
are polyaromatic compounds, formation of stacking complexes
with carcinogens could be associated with anti-genotoxic activity
of caffeine and its use in cancer chemoprevention. Caffeine
has also been reported to inhibit ATM and ATR kinases which
leads to the disruption of multiple DNA damage-responsive
cell cycle checkpoints and greatly sensitizes tumor cells
to antitumor agents which induce genotoxic stress. Caffeine
may inhibit repair of DNA lesions through a direct intereference
with DNA-PK activity and other repair enzymes. A number of
in vitro and in vivo studies demonstrated
that caffeine modulates both innate and adaptive immune responses
via inhibition of cyclic adenosine monophosphate (cAMP)-phosphodiesterase.
Finally, another group of effects induced by caffeine is mediated
through its inhibitory action on adenosine receptors. This
may modulate the stability of HIF1 alpha as well as VEGF and
interleukin-8 expression in tumor cells, which could have
a direct impact on neovascularization of human tumors.
In this review, we present different molecular mechanisms
by which caffeine and other methylxanthines may directly or
indirectly modulate the effect of antitumor treatment in tumor
cells and in cancer patients.
|
