| Cardiovascular
& Hematological Agents in Medicinal Chemistry
ISSN: 1871-5257
Current Medicinal Chemistry
- Cardiovascular & Hematological Agents
Volume 3, Number 1, January 2005
Contents
Discovery and Pre-clinical Development of Antithrombotics
from Hematophagous Invertebrates Pp.1-10
Michel Ledizet, Lisa M. Harrison, Raymond A.
Koski and Michael
Cappello
[Abstract] [Full
text article]
Vasoprotective Actions of the Atrial Natriuretic Peptide Pp.11-21
Alexandra K. Kiemer, Robert Furst and Angelika
M. Vollmar
[Abstract] [Full
text article]
Targeting the Renin-angiotensin System: What’s New?
Pp.23-32
B. J. Leckie
[Abstract] [Full
text article]
The Plasma and Tissue Kininogen-kallikrein-kinin System: Role
in the Cardiovascular System Pp.33-44
S. Marcondes and E. Antunes
[Abstract] [Full
text article]
Smoking, Estradiol Metabolism and Hormone Replacement Therapy
Pp.45-54
Alfred O. Mueck and Harald Seeger
[Abstract] [Full
text article]
Influence of Chronic Kidney Disease Development and Renin-angiotensin
System Inhibition on Cardiovascular Prognosis Pp.55-60
J. Segura, C. Campo and L.M. Ruilope
[Abstract] [Full
text article]
Left Ventricular Hypertrophy and Angiotensin II Receptor Blocking
Agents Pp.61-67
K. Yasunari, K. Maeda, M. Nakamura, T. Watanabe, J. Yoshikawa
and K . Hirohashi
[Abstract] [Full
text article]
Dopamine Receptor and Hypertension Pp.69-77
Chunyu Zeng, Gilbert M. Eisner, Robin A. Felder and Pedro
A. Jose
[Abstract] [Full
text article]
Abstracts
[Back to top]
Discovery and Pre-clinical Development of Antithrombotics
from Hematophagous Invertebrates
Michel Ledizet, Lisa M. Harrison, Raymond A. Koski and Michael
Cappello
[Full text article]
Bloodfeeding (hematophagous) parasites have evolved effective
means of inhibiting mammalian thrombosis, thereby facilitating
the acquisition and digestion of a bloodmeal. To date, specific
inhibitors of coagulation and platelet function have been
identified from numerous invertebrate species, representing
an impressive array of convergent functional strategies. These
parasite antithrombotics, in addition to playing a critical
role in the diseases caused or transmitted by bloodfeeding
invertebrates, may also serve as potentially useful therapeutic
agents for the treatment of a variety of conditions associated
with activation of thrombosis. A number of naturally occurring
anticoagulants and platelet inhibitors have been evaluated
in vivo, with some currently in varying stages of
preclinical and clinical development. Because of the unique
specificity and potency of parasite antithrombotics, these
invertebrate natural products hold great promise for improving
the treatment of a variety of human illnesses, including heart
disease, stroke, and cancer.
[Back to top]
Vasoprotective Actions of the Atrial Natriuretic
Peptide
Alexandra K. Kiemer, Robert Furst and Angelika M. Vollmar
[Full text article]
The Natriuretic Peptide (NP) family, especially its best-characterized
member Atrial Natriuretic Peptide (ANP), plays an important
role in the regulation of blood pressure homeostasis and salt
and water balance. Besides their action in cardiovascular
physiology, NPs have been described as anti-inflammatory regulators
of macrophage function: they have been reported to inhibit
the induction of inflammatory mediators, such as iNOS, COX-2,
and TNF-α. In the following review we will focus on a
rather novel aspect of NP action: NPs, especially ANP, will
be presented as vasoprotective agents. We will specifically
focus on ANP’s interaction with the complex intracellular
signalling networks responsible for proliferation, vascular
permeability, attraction and adhesion of leukocytes, and the
induction of cytoprotective proteins. We will also discuss
the critical mediator systems involved in mediating ANP’s
benefical actions. Recently, ANP as well as BNP, another member
of the NP family, have been introduced as cardiovascular therapeutics.
In this context, we will highlight the physiological and pharmacological
relevance of NPs, particularly ANP, as endogenous vasoprotective
agents.
[Back to top]
Targeting the Renin-angiotensin System: What’s
New?
B. J. Leckie
[Full text article]
The renin-angiotensin system is a key target for drugs combating
cardiovascular disease. Angiotensinconverting enzyme (ACE)
inhibitors and angiotensin receptor type-1 (AT1 receptor)
blockers are well known. However, angiotensin peptides can
be generated through a number of pathways besides the classic
system. This review outlines some of these pathways, their
relation to the classic system and the likely effect of inhibiting
them. Renin is still the key enzyme in angiotensin peptide
generation and seems to be the only route to angiotensin I
formation in vivo. Renin inhibitors may have some
advantages in terms of specificity. Also, by blocking angiotensin
I generation, the production of downstream bioactive angiotensin
I metabolites should also be blocked. Chymase, a mast cell
serine protease, cleaves angiotensin I to produce angiotensin
II and may be important at sites of inflammation such as atherosclerotic
plaque. Angiotensin-converting enzyme 2 (ACE2), a carboxypeptidase
structurally related to ACE but resistant to ACE inhibitors,
has a protective effect on cardiac function. Neutral endopeptidase
24.11 breaks down both atrial natriuretic peptide and angiotensin
II. Inhibiting it potentiates the action of endogenous atrial
peptide but only affects circulating angiotensin II when basal
levels are above normal. Dual inhibitors of ACE and endopeptidase
24.11 may be of value where there is both sodium retention
and increased angiotensin II. Targeting the renin-angiotensin
system by gene therapy or antibody treatment may provide a
longer-term treatment for hypertension.
[Back to top]
The Plasma and Tissue Kininogen-kallikrein-kinin System:
Role in the Cardiovascular System
S. Marcondes and E. Antunes
[Full text article]
Bradykinin and Lys-bradykinin are potent peptide mediators
implicated in several physiopathological effects in mammals.
They act through activation of G-protein-coupled constitutive
B2 or inducible kinin B1 receptors linked
to signaling pathways involving increased intracellular Ca++
concentrations and/or release of mediators including arachidonic
acid metabolites, NO and EDHF. In the cardiovascular system,
the kallikrein-kinin system exerts a fine control of vascular
smooth muscle tone and arterial blood pressure, and plays
a significant cardioprotective effect. This has been lately
confirmed in experimental studies employing transgenic mice
overexpressing human tissue kallikrein and animals with knockout
of kinin B1 and B2 receptor gene. Disturbances
in this system are associated with arterial hypertension,
myocardial ischaemia and other clinical complications. Inhibitors
of kininase II (angiotensin-converting enzyme) have been prescribed
successfully to patients with cardiovascular diseases, but
there is still a great interest in developing drugs or pharmacological
strategies that augment the activity of kininogen-kallikrein-kinin
system in pathological conditions. Delivery of adenovirus
vector containing the human tissue kallikrein gene (gene kallikrein
therapy) has emerged as a great potential to satisfy these
conditions. This review provides a summary of plasma and tissue
kallikrein-kinin system, focusing on the pharmacological properties,
kinin receptors and drugs reported to interfere with their
actions. The modulatory effects of the kallikrein-kinin system
on cardiovascular system, particularly in regulating smooth
muscle tone and arterial blood pressure and in preventing
myocardium ischaemia have also been explored in the review.
[Back to top]
Smoking, Estradiol Metabolism and Hormone Replacement Therapy
Alfred O. Mueck and Harald Seeger
[Full text article]
Many women receiving hormone replacement therapy (HRT) smoke;
in the Women’s Health Initiative (WHI), one of the largest
interventional studies on HRT to date and which recently had
to be discontinued, 50% of the 8,500 women on HRT had smoked
before or continued to smoke during the study. Remarkably,
there is little knowledge about the impact smoking has on
the efficacy and side effects of HRT. However, it has been
proven that, depending on the type, duration and intensity
of nicotine consumption, smoking can reduce or completely
cancel the efficacy of orally administered estrogens. Not
only does smoking diminish the otherwise well-established
beneficial effects of estrogen on hot flashes and urogenital
symptoms and its positive effects on lipid metabolism, i.e.
by reducing cholesterol, but smoking also specifically reduces
estrogen’s ability to prevent osteoporosis.
The reduction or loss of therapeutic efficacy is mainly caused
by dose-dependent elevated hepatic clearance, partially in
conjunction with lower estrogen levels, and has been demonstrated
only with oral estrogen applications. This failure of therapeutic
action should not be compensated for by increasing the dose
in smokers as this might result in the production of toxic,
even potentially mutagenic estrogen metabolites – compounds
recently associated with a higher risk of breast cancer. The
favorable effects of estrogens are not lost in smokers when
they are applied transdermally. This route enables low dosage
and also avoids the formation of unphysiological metabolites
by bypassing the liver. Women who continue to smoke despite
all warnings should therefore only be treated via the transdermal
route. Oral contraceptives, but not HRT, are contraindicated
in elderly smokers. However, the principal conclusion of the
WHI study was that the lowest dose possible should be chosen,
especially in patients with an increased cardiovascular risk,
as is the case in smokers.
[Back to top]
Influence of Chronic Kidney Disease Development and Renin-angiotensin
System Inhibition on Cardiovascular Prognosis
J. Segura, C. Campo and L.M. Ruilope
[Full text article]
Recently published guidelines recognize the relevance of
the development of chronic kidney disease in the stratification
of risk of the hypertensive patient. Adequate assessment of
renal function, including estimation of glomerular filtration
rate, is mandatory in order to ensure an adequate evaluation
of global cardiovascular risk in the hypertensive patient.
The presence of subtle elevations of serum creatinine concentrations
is a potent predictor of a poor cardiovascular prognosis.
Clustering of associated risk factors seems to justify the
elevated cardiovascular risk observed in patients with essential
hypertension and mild renal function derangement.
Chronic kidney disease is associated with a significant increase
in cardiovascular risk attributable to the simultaneous existence
of other risk factors related to the metabolic syndrome. The
inhibition of the effects of angiotensin II is necessary to
ensure the best degree of renal protection. It has demonstrated
to improve the long-term renal outcome of patients with nephrosclerosis
and to reduce the appearance of cardiovascular complications
in high risk patients The high prevalence of chronic kidney
disease in the general and in the hypertensive populations
forces the recognition of its relevance and the need for an
integrative therapeutic approach to protect simultaneously
renal and cardiovascular systems.
[Back to top]
Left Ventricular Hypertrophy and Angiotensin II Receptor Blocking
Agents
K. Yasunari, K. Maeda, M. Nakamura, T. Watanabe, J. Yoshikawa
and K . Hirohashi
[Full text article]
Angiotensin II plays a significant role in cell growth and
proliferation in model systems and in humans. Numerous studies
have shown that left ventricular hypertrophy (LVH) increases
the risk of coronary heart disease, congestive heart failure,
stroke or transient ischemic attack; all-cause deaths, and
sudden death. The use of angiotensinconverting enzyme (ACE)
inhibitors and angiotensin receptor blockers (ARBs) has provided
beneficial effects on LVH regression and on cardiac remodeling
in the presence of hypertension and heart failure. The new
class of ARBs appears to provide cardioprotective effects
that are similar to those of the ACE inhibitors. Most of the
beneficial effects provided by these agents appear to be related
to a more complete blockade of the angiotensin II type 1 (AT1)
receptor. However, costimulation of the angiotensin II type
2 (AT2) receptor appears to increase nitric oxide and thus
causes some bradykinin-like effects. Evidence for the role
of angiotensin II in promoting LVH as well as abnormal regulation
of the angiotensin II signal transduction pathways in model
systems and in humans has been reviewed. Secondly, the mechanisms
for the beneficial effects of angiotensin II receptor blockers
studied in model systems and in humans, including possible
involvement in the formation of reactive oxygen species by
mononuclear cells, are presented. Finally, results from large-scale
interventions such as the Losartan Intervention For Endpoint
reduction (LIFE) study, as well as an overview of the Valsartan
Antihypertensive Long-term Use Evaluation (VALUE) trial involving
the use of ARB in highrisk patients, are presented.
[Back to top]
Dopamine Receptor and Hypertension
Chunyu Zeng, Gilbert M. Eisner, Robin A. Felder and Pedro
A. Jose
[Full text article]
Dopamine plays an important role in the pathogenesis o fhypertension
by regulating epithelial sodium transport and reactive oxygen
and by interacting with vasopressin, renin-angiotensin, and
the sympathetic nervous system. Decreased renal dopamine production
and/or impaired dopamine receptor function have been reported
in hypertension. Disruption of any of the dopamine receptors
(D1, D2, D3, D4,
and D5) results in hypertension. In this paper,
we review the mechanisms by which hypertension develops when
dopamine receptor function is perturbed.
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