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ACTAUNIVERSITATIS
UPSALIENSISUPPSALA
2013
Digital Comprehensive Summaries of Uppsala Dissertationsfrom the Faculty of Pharmacy 178
Effects of Dehydration andBlockade of the Renin-Angiotensin System in theOne-humped Camel (Camelusdromedarius)
MAHMOUD AL HAJ
ISSN 1651-6192ISBN 978-91-554-8757-7urn:nbn:se:uu:diva-207574
Dissertation presented at Uppsala University to be publicly examined in C8:321, Biomedicalcenter, Husargatan 3, Uppsala, Wednesday, October 16, 2013 at 13:15 for the degree ofDoctor of Philosophy (Faculty of Pharmacy). The examination will be conducted in English.
AbstractAl Haj, M. 2013. Effects of Dehydration and Blockade of the Renin-Angiotensin Systemin the One-humped Camel (Camelus dromedarius). Acta Universitatis Upsaliensis. DigitalComprehensive Summaries of Uppsala Dissertations from the Faculty of Pharmacy 178.52 pp. Uppsala. ISBN 978-91-554-8757-7.
The one-humped or the dromedarian camel is a pseudo-ruminant mammal, well adapted to thehot and dry climates of the desert. Its ability to withstand torrid heat and extreme desiccationis of paramount importance to its survival. The studies presented in this thesis were designedto investigate and document the effect of dehydration in the presence or absence of angiotensinII (Ang II) AT1 receptor blocker (losartan) on blood constituents, electrolytes, hormones,neurotransmitters as well as liver and kidney enzymes in a subset of dehydrated camels and tocompare them with hydrated camels. Additionally, we studied the response of atrial natriureticpeptide (ANP) and B-type natriuretic peptide (BNP) and revealed for the first time the cardiacstorage form of BNP in the camel heart. Dehydration induced significant increments in packedcell volume (PCV), white blood cells (WBC), gamma glutamyl-transferase (GGT), serumsodium, creatinine and urea levels, and a doubling in plasma cortisol and arginine vasopressin(AVP) levels. At the same time dehydration caused significant decrease in body weights, plasmainsulin like growth factor-1 (IGF-1) and its binding protein-3 (IGFBP-3), and a 50% decrementin ANP and BNP levels. Moreover, dehydration with and without losartan resulted in significantchanges in stress hormones and anti-oxidants in plasma, liver and kidney homogenates. Losartanon one hand enhanced the effect of dehydration resulting in significant increases in sodium,creatinine and urea levels. In addition losartan raised the binding affinity of Ang II AT2receptors in the small intestine with 8-fold and with 16-fold for liver AT1 receptors, indicatingthat Ang II AT1 and AT2 receptor binding sites were present in camel's small intestine whileonly AT1 receptor binding sites were found in the camel liver. One the other hand losartanresulted in significant decrease in body weights impaired the rise in anti-diuretic hormone andreduced aldosterone level. Finally, we showed that the proBNP is the storage form of BNP inthe camel heart.
Keywords: Blood, biochemical analysis, catecholamine, colorimetric assay, cortisol,dehydration, dromedary camel, glutathione, hematological analysis, HPLC, insulin- likegrowth factor-1, losartan, plasma, receptors, radioimmunoassay, serum
Mahmoud Al Haj, Uppsala University, Department of Pharmaceutical Biosciences, Box 591,SE-751 24 Uppsala, Sweden.
© Mahmoud Al Haj 2013
ISSN 1651-6192ISBN 978-91-554-8757-7urn:nbn:se:uu:diva-207574 (http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-207574)
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My deep sense of gratitude
To great many people who helped and
Supported me without whom this project would have been
A distant reality
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List of Papers included in the thesis
This thesis is based on the following Papers, which are referred to in the text by their Roman numerals:
I. Al Haj M, Kazzam E, Nagelkerke NJ, Nyberg F, Nicholls MG and Adem A. Effect of Dehydration in the Presence and Absence of the Angiotensin Receptor Blocker Losartan on Blood Constituents in the Camel. Journal of Medical Sciences(2011); 4(2): 73-78.
II. Al Haj M, Adem A, Chandranath IS, Benedict S, Pathan JY, Nagelkerke N, Nyberg F, Lewis LK, Yandle TG, Nicholls GM, Frampton CM, Kazzam E. Responses to Dehydration in the One-Humped Camel and Effects of Blocking the Renin-Angiotensin System. PLoS One. 2012; 7(5):e37299. Epub 2012 May 18.
III. Al Haj M, Kazzam E, Amir N, Nyberg F, Adem A. Changes in insulin-like growth factor-1 and IGF-binding protein-3 in camel plasma during dehydration in the presence and absence of losartan. Comp Clin Pathol(2012) 21:1745–1749 DOI 10.1007/s00580-012-1562-y.
IV. Adem A, Al Haj M, Benedict S, Yasin J, Nagelkerke N, Nyberg F, Yandle TG, Frampton CM, Lewis LK, Nicholls MG, Kazzam E. ANP and BNP Responses to Dehydration in the One-Humped Camel and Effects of Blocking the Renin- Angiotensin System. PLoS ONE 2013; 8(3): e57806. doi:10.1371/journal.pone.0057806.
V. Al Haj M, Kazzam E, Amir N, Nyberg F, Nicholls MG, Adem A. Effects of Dehydration and Blockade of Angiotensin II AT1 Receptor on Stress Hormones and Anti-Oxidants in the one-humped camel (manuscript submitted)
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List of additional papers
I. Rizk DE, Mensah-Brown EP, Chandranath SI, Ahmed I, Shafiullah M, Patel M, Al-Haj M, Adem A. Effects of ovariectomy and hormone replacement on collagen and blood vessels of the urethral submucosa of rats. Urol Res. 2003 Jul; 31(3):147-51. Epub 2003 Apr 1.
II M. Alhaj Ali, E. Mensah-Brown, S.I. Chandranath, E. Adeghate and A. Adem. Distribution of Insulin like Growth Factor-1 (IGF-1) and its Receptor in the Intestines of the One-humped Camel (Camelus dromedarius). Growth Factors, September– December 2003 Vol. 21 (3–4), pp. 131–137.
III Al Ali MA, Nyberg F, Chandranath SA, Ponery AS, Adem A, Adeghate E. (2006). Effect of high- calorie diet on the prevalence of diabetes mellitus in the one-humped camel (Camelus dromedarius). Annals of New York Academy of Sciences 1084:402-410.
IV Ali MA, Nyberg F, Chandranath SI, Dhanasekaran S, Tariq S, Petroianu G, Hasan
MY, Adeghate EA, Adem A. Distribution of neuroendocrine cells in the small and large intestines of the one-humped camel (Camelus dromedarius). Neuropeptides. 2007 Oct; 41(5):293-9. Epub 2007 Aug 3.
V T.A. Abbas, M. Alhaj Ali and H. Abu Damir. Thiamine (vitamin B1) status in the blood of young, pregnant, lactating and racing dromedary camels (Camelus Dromedarius) in UAE. Revue Méd. Vét. 2008, 159, 11, 545-550.
VI Abu Damir H, Abbas TA, Alhaj Ali M. Copper status in breeding and racing camels (Camelus dromedarius) and response to cupric oxide needle capsules. Trop Anim Health Prod. 2008 Dec; 40(8):643-8. doi: 10.1007/s11250-008-9143-4. Epub 2008 Mar 13.
VII Hassen Abu Damir, M. Alhaj Ali, T. A. Abbas, E. A. Omer, A. M. Fihail. Narasin poisoning in the dromedary camel. Comparative Clinical Pathology (10 January 2012), pp. 1-7, doi: 10.1007/s00580-011-1403-4 Key: citeulike: 10221098
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Contents
1. Introduction ………………………………………………………………….9
Definition ……………………………………………………………...…......9
Classification ………………………………………………………………...10
Domestication………………………………………………………………..10
Distribution …………………………………………………………………..10
General anatomy ……………………………………………………………..11
Physiological and behavioral adaptations ………………….……………..….12
Blood constituents …………………………………………………………....12
Renin-Angiotensin system …………………………………………………....13
Insulin-like growth factor-1 …………………………………………………..14
Catecholamines …………………………………………………………….....14
Oxidative stress ……………………………………………………………….15
Natriuretic peptides …………………………………………………………...15
2. Aims ……………………………………………………………………………...16
3. Materials and methods …………………………………………………………17
Experimental Animal procedures ……………………………………………...17
Body weights and Blood sampling ……………………………………17
Tissue collection …………………………………………...………….18
Techniques used ……………………………………………………….. ……...18
Complete Blood Count (CBC)………………………………………….18
Serum biochemical examination ……………………………………….18
Radioimmunoassay technique ………………………………………….19
HPLC technique ………………………………………………………..19
Receptor binding assay…………………………………………………..20
Colorimetric assay...………………………………………………..……21
Statistics ………………………………………………………………….........21
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4. Results and discussion ……………………………………………………………22
Effect of Dehydration in the Presence and Absence of Angiotensin Receptor Blocker Losartan on Blood Constituents in the Camel (Paper I)……………………....22
Responses to Dehydration in the One-Humped Camel and Effects of Blocking the Renin-Angiotensin System (Paper II)……………………………………………...…25
Changes in insulin-like growth factor-1 and IGF-binding protein-3 in camel plasma during dehydration in the presence and absence of losartan (Paper III)…………….. 30
ANP and BNP Responses to Dehydration in the One-Humped Camel and Effects of Blocking the Renin- Angiotensin System (Paper IV)........................................33
Effects of Dehydration and Blockade of Angiotensin II AT1 Receptor on Stress Hormones and Anti-Oxidants in the one-humped camel (Paper V)…………..37
5. Conclusions ………………………………………………………………………43
6. Acknowledgements ……………………………………………………….………44
7. References …………………………………………………………………………45
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Abbreviations
ACTH Adrenocorticotropic hormone
ALB Albumin
ALP Alkaline phosphatase
ALT Alanine aminotransferase
AST Aspartate aminotransferase
ANP Atrial natriuretic peptide
BNP B-type natriuretic peptide
CBC Complete blood count
Cr Creatinine
FAO Food and agricultural organization
GH Growth hormone
GGT Gamma glutamyl transferase
GSH Glutathione
HB Hemoglobin
HPLC High-performance liquid chromatography
IGF-1 Insulin-like growth factor-1
IGFBP-3 Insulin-like growth factor Binding Protein-3
LDH Lactate dehydrogenase
MCH Mean corpuscular hemoglobin
MCHC Mean corpuscular hemoglobin concentration
MCV Mean corpuscular volume
PCV Packed cell volume
RBC Red blood cells count
RAS Renin-angiotensin system
RAAS Renin-angiotensin-aldosterone system
RIA Radioimmunoassay
TP Total protein
WBC White blood cells count
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Introduction
Definition and Description
A camel is a large hornless, long necked pseudo-ruminant mammal having even-toed hooves and
fatty deposits known as hump on its back with long cushion footed spindly legs. The term camel
is derived from the Arabic word “Gamal” meaning “beauty”. Camels are considered as pseudo-
ruminants, because they differ from true ruminants in a few anatomical features: Adult camels
have two incisor teeth in their upper jaw, while, true ruminants do not have. Camels lack an
omasum (the third division of the stomach in true ruminants) which is considered the water
reabsorbing portion of the stomach. Camels do not have gallbladder and their hooves have been
reduced to claw-like toes, projecting beyond the pads [1].
Figure. 1- One-humped camel (Dromedarius)
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Classification:
Camels of the world comprise two broad groups, the old-world group and the new-world group.
Both groups are members of the order: Artiodactyla (even-toed ungulates); Suborder: Tylopoda
(pad-footed); Family: Camelidae and Genuses: Camelus. The genus Camelus comprises both old
and new-world Camelids. The old world group comprises two species: the Dromedarius (one-
humped) and the Bactrianus (two-humped) and the New-World group comprise four species
(Alpaca, Guanaco, Llama, and Vicuna) all new world Camelids are hump-less. All members of
the Camelidae family have the same number of chromosomes (74), but the evolutionary changes
that occurred due to gene mutation or minor chromosome rearrangements resulted in the existing
variation in Camelids [2].
Domestication
The one-humped camel was domesticated around 3000 B.C. in southern Arabia [3], mainly for
its meat and milk [4]. Scientists believe that ancestors of the modern camel lived in North
America 40 million years ago, wandering across the Alaskan' land bridge' to Asia and eventually
Africa. Remains of camels have been found in old Palestine, dating to 1800 B.C. [5]. The two-
humped camel was domesticated on the borders of Iran and Turkmenistan and spread to southern
Siberia, Mongolia and China. The Bactrian camel is stockier than the dromedary and its body is
covered by thick wool and has two-humps. This thesis deals mainly with the one-humped camel
or the dromedary that lives in the hot deserts and semi-desert areas of the world. Camels are still
valued for their ability as transportation of package, riding and working animals; in addition, they
are kept as providers of milk, meat, wool and hides in many parts of Africa and Asia.
Distribution
The One-Humped Camel is widely distributed in the hot arid areas of Africa, Middle East, and
Asia, whereas the Two-Humped Camel is found in the cold parts of China, India, USSR and
Australia. According to the United Nations animal distribution statistics in 2009, Food and
Agricultural Organization (FAO) showed that the total number of camel population in the World
is around 19 million [6]. 89% of the camel population (17 million) is the one-humped camel
while, 11% (2 million) is the two-humped camel. Around 12.1 million heads of the one-humped
camel are found in Africa and 4.9 million heads in Asia. 84% of African camels and 60.1% of the
world's one-humped camel population is found in five East African countries (Somalia, Sudan,
Kenya, Eritrea and Djibouti). Camel population is declining in many parts of the world;
particularly in the non-tropical areas [7].
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Figure. 2 Camel world distributions (Redrawn from Köhler-Rollefson, 1991)
General anatomy
Dromedaries are noted for their thick eyelashes and small, hairy ears. Their eyes are large and
are protected by a double row of long curly eyelashes that keep out dust and thick eyebrows
shield the eyes from the desert sun. Their flat and leathery pads have two toes. While walking
the pads spread and prevent their feet from sinking in the desert sand. They walk by moving
both legs on one side, simultaneously hence the rolling motion gait. Adult males grow to a
height of 1.8–2.0 meters, and females to 1.7–1.9 m. Body weight is usually in the range of 400–
600 kg for males, with females being 10% lighter. They come in colours varying from brown to
almost black. Male dromedaries have a soft palate, which they inflate to produce a deep pink
sack, called “laha” in Arabic, hanging out of their mouth to attract females during the mating
season. The gestation period is 13 months and the newborn walks immediately after birth.
Camels chew cud like ruminants, but they differ from true ruminants in a few anatomical
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features, such as adult camel has two incisor teeth in their lower jaws; they lack an omasum, the
third stomach division of ruminants, which is considered the water reabsorbing portion of the
stomach; they have no gallbladder; and the hooves have been reduced to claw-like toes,
projecting beyond the pads [1].
Physiological and behavioral adaptations
The camel's physiological adaptation to its desert environment is due to its extremely low rate of
water turnover, which is accomplished by minimal use of evaporative cooling, low urinary
output, and its ability to extract water from undigested feed residues [8]. Camels can lose up to
30 percent of their body weights without ill effects, while other mammals may die from
circulatory failure when water loss involves 12% of their body weights [9, 10]. Moreover, this
loss can be replenished in a matter of minutes when it gets access to water [11]. The camel has
the lowest water-turnover of all animals [12] and is able to regulate water and salt uptake from
the colon and their excretion from the kidneys [13]. Camels do not need to sweat to lower body
temperature; they can increase their body temperature from 34°C in the early morning to 41°C in
the late afternoon, at which time the environment cools greatly, thus conserving water [10]. The
water-deprived camel reduces its body metabolism [14] thus conserving water. Camels can also
reduce heat effect by presenting the smallest possible body surface area to the sun-rays by being
less active during the hot hours of the day [15]. In addition, camels can change their body
covering from wool in the winter to a smooth shiny reflecting hair in the summer. The hump does
not serve as water reservoir, nor as an energy reserve, but it is an accumulation of body fat that
leaves the subcutaneous tissues without fat, thus allowing an efficient cooling [1]. The
mechanism involved in water conservation by the one-humped camel is not well understood, but
probably it involves several body systems including central and peripheral nervous system,
urinary and digestive systems.
Blood constituents
Haematological and biochemical analysis of blood can often provide valuable information
regarding health and sickness of an animal. Since the camel is an adaptable species, standard
hematological and serum biochemical values need to be determined in a number of animals in
variable environmental and physical conditions. Measurements of hematological indices such as
packed cell volume (PCV), hemoglobin (HB), red blood cells (RBC), white blood cells (WBC),
mean corpuscular volume (MCV), mean corpuscular hemoglobin (MCH) and mean corpuscular
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hemoglobin concentration (MCHC) were measured using fully automatic hematology analyzer.
Determination of biochemical indices such as blood urea, creatinine, TP, GGT, ALT and TBili
was performed using an ACE chemistry analyzer. A camel’s RBC is nucleated and has an oval
shape, unlike other mammals, which have circular and anucleated RBC. The advantage of having
oval blood cell is to facilitate their flow in the dehydrated camel. They can also withstand high
osmotic variation, making them much less likely to burst when a camel drinks a large quantity of
water.
Renin-Angiotensin system (RAS)
RAS or RAAS is a hormone system that regulates blood pressure and fluid or water balance. The
circulating and central RAS contribute to water and sodium balance through a constellation of
actions and interactions. Ang II acts through two receptor subtypes, AT1 and AT2 receptors that
are cloned and characterized pharmacologically [16, 17]. Most of the classic physiological effects
of Ang II, such as sodium and water retention, vasoconstriction, aldosterone and vasopressin
release are mediated by the AT1 receptor [18]. In addition RAS is an important contributor to
arterial pressure, activity of the sympathetic nervous system, and secretion of ACTH,
aldosterone, cortisol, ANP and BNP. In some species, RAS is an important regulator of thirst and
AVP secretion and controller of water excretion by the kidney [19]. Drinking is controlled by a
number of factors dominant amongst which are tissue osmolality and vascular (fluid) volume
[20]. Dehydration causes low blood volume, and this leads to an increase of renin secretion from
the kidneys. Renin cleaves plasma angiotensinogen into angiotensin I, which is then hydrolyzed
to the highly active octapeptide angiotensin II, which in turn elicits drinking. Dehydration in
camel is known to stimulate the activity of RAS [21]. It is unclear, however, whether this
activation of the RAS contributes importantly to maintenance of water and electrolyte
homeostasis and to the neurohormonal and renal responses to water deprivation in the camel. The
unique ability of the camel to survive extreme water deprivation suggests that extrapolation of
data from other species might not be applicable to the camel. With the advent of drugs such as
losartan, which specifically block the AT1 receptor, it is possible to dissect the physiological role
of RAS under various circumstances including dehydration. Accordingly, we have studied blood
constituents, serum electrolytes, and the hormonal and renal responses to dehydration in camels
with and without blockade of the AT1 receptor. Our hypothesis was that the RAS is an important
regulator of neurohormonal and electrolyte balance and renal function during water deprivation
in camels. Therefore, we predicted that camels with blockade of the AT1 receptors would retain
less water during dehydration (as a result, they lose more body weight and exhibit a greater rise
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in plasma sodium, urea and creatinine) and would display lower plasma levels of ADH, cortisol,
aldosterone, ANP and BNP than camels, which did not have blockade of the RAS.
Insulin-like growth factor-1
Insulin like growth factor-1 (IGF-1), a mediator of growth hormone (GH), is a low molecular
mass polypeptide, found in highest concentration in serum [22]. It is synthesized and secreted
primarily by the liver via a GH dependent process and circulates in the blood complexed to a
specific carrier protein [23], the so-called IGF binding protein (IGFBP) family. IGF-1 is
homologous to insulin regarding its amino acid sequence and biological activity [24]. It exerts
insulin like metabolic activities, such as glucose and amino acid transport and promotes DNA
synthesis [25] and thus regulates reproduction and differentiation in a variety of cell types and
tissues [26]. Camel diet comprises dry and coarse feed from the desert environment that is well
known for its scarcity of water and green roughages. It would be justified therefore to expect the
camel gut to require a very high rate of proliferation and differentiation and these require the
presence of high level of IGF-1 and its receptors [27].
Catecholamines
The catecholamines represent a group of signaling compounds derived from the amino acid
tyrosine and contain a catechol group. They are important as neurotransmitters and hormones in
the sympatho-adrenal nervous system. They are present in the central nervous system but are also
produced and released by the adrenal glands into the blood circulatory system during physical or
emotional stress. The adrenal gland is divided into cortex and medulla. The cortex is divided into
three distinct layers that produce steroid hormones and accessory sex hormones, while the
adrenal medulla has two cell types that produce the two important catecholamines epinephrine
(EP) and norepinephrine (NE) [28, 29]. EP results in an increase in heart rate, contraction of
blood vessels, and dilatation of the respiratory air passages, in addition to its role in fight-or-
flight response of the sympathetic nervous system [30]. Norepinephrine is secreted by certain
nerve endings of the sympathetic nervous system, and by the medulla of the adrenal glands. Its
primary function is to help in maintaining a constant blood pressure by stimulating certain blood
vessels to constrict when the blood pressure falls below normal. A third member of the
catecholamine family is dopamine (DA), a simple organic neurotransmitter, which plays a
number of important physiological roles in the body. DA is synthesized in the body mainly by
neurons and cells in the medulla of the adrenal glands. It plays a major role in the brain system
that is responsible for reward-driven learning. DA is a neurotransmitter as well as a biochemical
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precursor of NE, in many non-neural tissues it cannot be converted to NE and is synthesized
independently of nerve activity [31]. DA regulates fluid and electrolyte balance by direct and
indirect actions in the kidney, blood vessels, adrenal glands gastrointestinal tract, sympathetic
nervous system and brain centers [31]. The free form of plasma DA is nearly equivalent to that of
EP and 20% that of NE and this free form makes up less than 2% of total plasma DA [32].
Dehydration causes an increase in catabolic stress hormones that are correlated with an increase
in vascular resistance [32].
Oxidative stress
Oxidative stress is any disturbances in the normal redox state of cells that will cause toxic effect
due to production of peroxides and free radicals leading to damage of all components of the cell,
including proteins, lipids, and DNA. Thus, oxidative stress can cause disruptions in normal
mechanisms of cellular ability to detoxify the reactive intermediates or to repair the resulting
damage. Glutathione (GSH) is considered as the mother antioxidants with different functions, it
is the major endogenous antioxidant produced by cells to neutralize the free radicals and reactive
oxygen compounds, it is also essential for the immune system to exert its full potential and
participates in proliferation of lymphocytes [32]. Glutathione exists in reduced (GSH) and
oxidized (GSSG) states, in healthy cells and tissue, more than 90% of the total glutathione pool is
in GSH form and less than 10% exists in GSSG form. The ratio of the GSH/GSSG is used to
evaluate oxidative stress status in biological systems [33]. Dehydration is mentioned to cause
oxidative damage to body cells by either random formation of intermolecular disulphide bridges,
or by uncontrolled oxidation of thiols to sulphonic acids [34]. GSH as cellular anti-oxidant can
protect thiol-containg enzymes and can directly scavenge free radicals [35].
Natriuretic peptides
Natriuretic peptides are also called cardiac hormones. They belong to a family of endogenous
polypeptide mediators mainly of cardiac origin with natriuretic and vasodilator effects. Atrial
natriuretic peptide (ANP) is a 28-amino acid polypeptide secreted by atrial myocytes in response
to distension. While, brain natriuretic peptide (BNP) is a 32-amino acid mainly secreted by
ventricles in response to stretch. They Increase glomerular filtration resulting in aqueous diuresis
and natriuresis (sodium excretion in urine). They cause vasodilation and decrease of arterial
pressure. They are also involved in inhibition of aldosterone and renin secretion and perhaps of
antidiuretic hormone. ANP and BNP could decrease the feeling of thirst and appetite for salt. It
has overall opposite effects to Ag II.
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Aims
The general aim of this thesis was to investigate the effect of dehydration in the presence and
absence of the Angiotensin II AT1 receptor blocker losartan on vascular and neuro-hormonal
systems in the one-humped camel as well as to characterize and elucidate the amino acid
structure of the camel B-type natriuretic peptide (BNP) and its storage form in the camel heart.
The specific aims of this thesis were to:
- Study the Effect of Dehydration in the Presence and Absence of the Angiotensin Receptor Blocker Losartan on Blood Constituents in the Camel.
- Study the Responses to Dehydration in the One-Humped Camel and Effects of Blocking the Renin-Angiotensin System.
- Measure changes in insulin-like growth factor-1 and IGF-binding protein-3 in camel plasma during dehydration in the presence and absence of losartan.
- Study ANP and BNP Responses to Dehydration in the One-Humped Camel and Effects of Blocking the Renin- Angiotensin System.
- Study Stress Hormones and Anti-oxidant Responses to dehydration and Blockade of Angiotensin II AT1 Receptor in the One-humped Camel (Camelus dromederius) (manuscript).
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Materials and Methods
Experimental animal procedures:
Thirty male camels, aged 4-5 years and weighing 290 – 348 kg were used for these studies. Male
camels were selected because males are normally used as meat providers and they are not
expensive to buy, while females are kept for breeding, milk production and in racing activities, so
they are very expensive. The camels were divided into three groups: the first group was the
control (n=6), they were allowed free access to feed and water. The second group (n=6) and the
third group (n=18) were given food ad-libitum and were denied free access to water for 20 days.
The second group was daily injected with Ag II AT1 receptor blocker losartan at a dose of
5mg/Kg I/V. (Merck, USA) for 20 days (Treated group). Six camels from the third group
(Dehydrated group) were allowed free access to water on day 21 (rehydrated) for 24 hours
(Rehydrated group). All camels were maintained on dry hay for the first week of the experiment
and green-hay for the remainder of the study period. All camels were kept under shade in a corral
during the hot summer months of June and July in the Arab gulf region when the ambient
temperatures varied between 400C and 480C and the humidity reaches up to 30%. Losartan was
used in the second group of camels in order to dissect the role of Ag II in the dehydrated camels.
The study protocol for this thesis was approved by the animal ethics committee of the United
Arab Emirates University. The approval ID was AE/03/38. The camels were daily visited by an
experienced veterinarian to ensure their wellbeing.
Body weights and Blood samples:
Measuring Body weights for the live camels in the field was very difficult, if not practically
impossible. Therefore, we calculated the body weights of our camels, using the formula live
weight (kg) = Shoulder height x chest girth x hump girth x 50 [36] on basal day and then every
third day during the 20 days of the experiment. Blood samples were obtained without apparent
discomfort to the camels from the external jugular vein, daily between 0800 and 1000 AM, two
days before the start of the experiment (baseline values) and then on the 3rd, 5th, 10th, 15th, and
20th day of water deprivation. A total of 50 ml whole blood was collected from each camel on
each occasion in different vacutainers, one as whole blood with anticoagulant (K3-EDTA), the
second vacutainer without anticoagulant for serum biochemical analysis. Another 10 ml is stored
as a whole blood in –80oC. The remaining 20 ml were centrifuged at -10 0C and separated in 2
different tubes as Plasma (CP + code) and Serum (CS + code), and stored in -80oC. Six samples
were drawn from each camel (50 x 6 = 300 ml WB) at six time points. Blood for the
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measurement of hormones were collected in a special vacutainer with k3-EDTA placed on ice,
centrifuged at + 4ºC within one hour after collection and plasma aliquots were stored at -80ºC
until analyzed. Blood from the rehydrated group was collected at four time points that is at 1st,
4th, 12th, and 24 hour after rehydration.
Tissue collection:
All camels except the rehydrated group were sacrificed on day 21 from the starting day of the
experiment. Tissue samples collected from each camel were whole brain, cortex, thalamus,
hypothalamus, pituitary gland, spinal cord, dorsal-ganglions, kidneys, pancreas, liver and from
different parts of the digestive tract. Some of the samples were kept in Zamboni fixative and
some were kept in dry ice and stored at -80°C until further use for Western-blot,
immunohistochemistry, receptor-binding, colorimetric assay and receptor autoradiographic
studies. The rehydrated camels were sacrificed after 24 hours of rapid rehydration and similar
tissues were collected.
Techniques used
Complete Blood Count (CBC)
In the study presented in paper I complete blood count (CBC) analysis was done using fully
automatic hematology and chemistry analyzers. Body weights were calculated at baseline and
thereafter every third day. Whole blood with anticoagulant (K3-EDTA) was used for
hematological examination including; packed cell volume (PCV), hemoglobin (HB), red blood
cells (RBC), white blood cells (WBC), mean corpuscular volume (MCV), mean corpuscular
hemoglobin (MCH) and mean corpuscular hemoglobin concentration (MCHC) using fully
automatic hematology analyzer (CELL-DYN 3700 system-ABBOTT-USA).
Serum biochemistry analysis
In the studies presented in papers I and II. Whole blood without anticoagulant was used for
serum biochemical analysis using ACE chemistry analyzer (Alfa Wassermann-USA). The blood
was centrifuged and serum was collected within one hour after blood withdrawal. The
biochemical analysis include urea, creatinine (Cr), sodium (Na), potassium (K), total protein
(TP), alkaline phosphatase (ALP), GGT, calcium (Ca), and inorganic phosphorus (P), iron (Fe),
Copper (Cu), using ACE chemistry analyzer (Alfa Wassermann-USA). Hematological
examination and serum chemistry analyses were carried out within one hour of venipuncture.
19
Radioimmunoassay technique
In the studies presented in papers III, IV & V assays for plasma hormone levels were performed
using commercial radioimmunoassay (RIA) kits for aldosterone, antidiuretic hormone (ADH),
cortisol, IGF-1and IGFBP-3 in addition to ANP and BNP levels in plasma, all reagents were
purchased from Diagnostics Systems Laboratories, USA and plasma renin activity (PRA) from
Diasorin, USA. For the examination of cardiac immunoreactive BNP, hearts from 2 healthy
camels with free access to feed and water were obtained immediately upon slaughter, placed on
dry ice and stored at -800C. Plasma and camel heart tissue were couriered on dry ice to the
Endolab in Christchurch New Zealand for measurements of ANP and BNP. Briefly, plasma
samples were extracted on solid-phase C18 cartridges (Sep-Pak, Waters Corp., Milford, MA),
prior to RIA the assay for BNP used an antiserum to porcine BNP-26 (Bacxhem cat number T-
4195), porcine BNP-26 for standards and radiolabelled porcine BNP-26 as tracer. ANP was
measured in the same extracts as BNP employing a locally raised antiserum (R31) [37, 38].To
characterize the form of BNP in camel heart, approximately 1g of left or right atrial or ventricular
tissue was diced, boiled for 5 minutes in 10 volumes of distilled water containing 0.1% Triton X-
100, acidified to 1M with acetic acid and homogenized for 2 minutes at 24,000 rpm (Ultra-
Turrax T25, IKA). Following centrifugation, the extract was separated on a size exclusion HPLC
column (Toyo Soda, Tokyo, Japan), equilibrated with 0.1% TFA in 20% acetonitrile at 0.5
ml/minute and collected in 0.5ml fractions into tubes containing 10µl of 1% triton X100. The
fractions were dried, re-suspended in assay buffer and measured by RIA. The column was
calibrated with the following standards (molecular weight): recombinant human proBNP
containing an additional methionine residue at its N-terminus (12,037), human amino terminal
proBNP (8,457), human BNP (3,464) and human angiotensin II (1,046). Parallelism of extract
dilutions with the RIA standard curve were performed on serial 2-fold dilutions of left and right
atrial and ventricular tissue extracts. Plasma samples were extracted on Sep-Pak cartridges and
reconstituted as concentrated solutions, then serially diluted prior to RIA. All hormone
measurements from all camels were measured in the same assay to avoid inter-assay variability.
The intra-assay coefficient of variation varied between 4.5% for aldosterone to and 7% for
cortisol.
HPLC technique
In the study presented in paper V plasma catecholamine levels were determined using a high
performance liquid chromatography (HPLC) as described by Eldrup et al., [39]. Briefly, 2ml
20
plasma was added to 15mg acid washed alumina and 1.0 ml Tris buffer (1.5M, 8.5 pH), vortex
mixed for 5 seconds, and mixed for a further 5 min in a rotary mixture. Alumina was allowed to
settle and the supernatant aspirated to waste. The alumina was washed twice with double distilled
water. After centrifugation the washing was discarded and the catecholamines eluted with 100ul
of 0.1M acetic acid, and 50ul of this solution injected into the system.
Receptor binding assay
In the studies presented in papers II, III, IV & V, competition binding assays were performed. In
order to determine whether the dose of losartan administered was sufficient to affect AT1
receptors, liver and intestine sections were obtained at slaughter from 3 camels of each group.
Measurement of Ang II receptor binding to camel intestine and liver tissues was determined
using receptor binding assay as described by Rosenstrom et al., [40]. Aliquots of a prepared tissue
fraction (0.2 mg of protein/sample) were incubated with varying concentrations of unlabeled Ang
II with 36 pM 125I-Ang II in a final volume of 0.5 ml of binding buffer containing 50mM Tris-
HCl (pH 7.4), 100mM NaCl, 10mM MgCl2, 1mM EDTA, 0.2% BSA, 0.025% Bacitracin, 10µM
leupeptin, 10µM bestin, 10µM pepstatin A and 1µM PMSF in the presence of 1µM losartan
(AT1 selective antagonist) to block AT1 receptors or 1µM PD-123319 (AT2 selective
antagonist) to block AT2 receptors. After incubation in a shaking water bath for 120 min (AT1)
and 90 min (AT2) at 25°C, the samples were immediately filtered under vacuum through
Whatman GF/B glass fiber filters that had been presoaked in 0.3% PEI using a Brandel automatic
36-sample cell harvester and washed 3 times with 3 ml of ice cold Tris-HCl buffer (pH 7.4)
containing 1% BSA. Both filtration and washing were completed within 20 seconds. The filters
were then dried, transferred to tubes and the amount radioactivity trapped on the filters was
measured by a gamma counter (1470 WIZARD). Specific binding was determined as total
binding minus nonspecific binding. The total binding measured in the absence of unlabeled Ang
II was less than 10% of the total radioactivity in the sample. Nonspecific binding of 125I-Ang II to
membrane preparations determined in the presence of 1µM unlabeled Ang II was less than 15%
of the total binding. The characteristics of Ang II binding was determined by using six different
concentrations (0.001-100n M). IC50 values were obtained using the non-linear curve-fitting
program GraFit (Erithacus Software, UK). Ki values were calculated from IC50 values using
Cheng and Prusoff equation: Ki = IC50/1 + [L]/Kd. All results were presented as mean ± SEM of
three experiments each done in triplicate.
21
Colorimetric assay
In the study presented in Paper V glutathione (GSH) concentrations in plasma, and liver
homogenate were determined spectrophotometrically as described by Tietze, F. [41]. Briefly
Liver specimens were homogenized using a polyteron homogenizer (ultra turrax,T-25,IKA
laboratories) in 5% 5-sulfosalicylic acid (SSA) on ice with 3 volumes, using Sigma (St. Louis,
USA) colorimetric GSH assay kit according to manufacturer’s protocol. Another seven volumes
of 5% SSA Solution were added till even suspension was achieved. Incubated for 10 min at 4ºC
and centrifuged at 10,000 x g for 10 min at 4ºC, the supernatant were immediately stored at -70
ºC until the GSH assay. The amount of GSH was measured spectrophotometrically by its reaction
with 5,5¢-dithiobis (2-nitrobenzoic acid) to yield a yellow chromophore. The absorbance was
read at 412 nm and total GSH concentration was expressed as µM/ml.
Statistical analysis
All data were presented as means ± SEM. In papers I, II, III and IV differences between the three
groups of camels for body weight, serum biochemistry and plasma hormone levels were
determined using 2-way analysis of variance (ANOVA) with time as a repeated measures factor.
Significant differences were identified by ANOVA; the level of significance at individual time
points was established by Fisher’s protected least-significant difference tests. P-values of less
than 0.05 were considered to be statistically significant. In paper V calculations were performed
with the SPSS, Version 18.0 statistical software package.
22
Results and discussion
Effect of Dehydration in the Presence and Absence of Angiotensin Receptor Blocker Losartan on Blood Constituents in the Camel (Paper I)
Camels are adapted to endure water deprivation for sustained periods of time without ill effects
[8]. A number of studies have been carried out on blood chemistry and hematology of the one-
humped camel with and without dehydration [42, 43] the results are often conflicting presumably
because of disparate methods of analysis, differences in seasons chosen for the studies as well as
gender and age of the camels. In addition, we are not aware of studies assessing directly the
potential role of the renin-angiotensin system in responses to sustained dehydration in the camel.
Accordingly, we have examined hematological and biochemical variables before and during 20
days of dehydration and determined whether these responses are affected by blockade of the AT1
receptors. Differences in the measured indices at baseline between the three (Control, Treated
and Dehydrated) groups were small and not statistically significant (Table-1). The mean body
weight for the control animals increased progressively during the study period from 302±16 to
318±14 Kg. By contrast, the mean body weight for both dehydrated groups decreased
progressively across dehydration. The decrease on day 20 reached 39.1% for the treated (348±21
to 212±5 Kg) and 34.5% for the dehydrated (290±8 to 190±6 Kg). Whole blood analysis showed
that PCV did not change significantly during the 20 days of the experiment in control and
dehydrated animals; this result is in line with the observations of Yagil and Zine Filali [44, 45].
However, a significant increase (p<0.05) was observed in the treated camels at the end of the
dehydration period. The most obvious explanation is that treated camels lost more water and
hence developed a lower plasma volume than the dehydrated animals. This possibility is
supported by the greater loss of body weight in this group of camels. In addition, serum
creatinine was significantly increased in both treated and dehydrated camels compared to control.
Furthermore, plasma protein concentration, a useful indicator of plasma water volume [45]
increased slightly (7.14+0.4 g/dl) compared to control camels, though not significantly in the
treated versus dehydrated or control groups. The change in plasma protein concentration with
dehydration in the present study was greater by 5% than in other reported studies [46] most likely
because the period of dehydration was longer for our camels. WBC revealed significant increase
(p<0.01) in both treated and dehydrated camels compared to time matched control (Table 1). The
increase in WBC observed in the dehydrated camels could possibly be due to the stimulation of
the RAS. However, the significant increase of WBC observed in the treated group could possibly
23
be due to the effect of RAS mediated through a different receptor than that blocked by losartan.
Since, it was reported that angiotensin receptors (AT1 and AT2) antagonists alone or in
combination failed to block completely the effects of Ang II suggesting that another Ang II
receptor may be functional in WBC [47]. Alternatively, it is possible that the size and/or shape of
RBC might also be affected during dehydration in the presence of losartan indicating that the
renin-angiotensin system may play a role in the morphology of red blood cells during
dehydration in the camel.
Table 1. Changes in hematological parameters of control, losartan treated and dehydrated camels. All Values are mean ± SE. Significance from control is denoted by * P<0.05 &** P<0.01.
The biochemical analysis in the three groups revealed statistically significant increase in serum
urea and creatinine levels (p<0.01 and p<0.05 respectively) in both treated and dehydrated
groups compared to control. No significant differences between the treated and dehydrated
groups were seen. Our results also showed that GGT level was significantly lower (p<0.01) on
day 20 in the treated group compared to control and the dehydrated groups. All other parameters
including iron, copper, calcium, alanine, total bilirubin and aminotransferase were not
significantly changed between the three groups by the end of the study period (Table-2).
Control Losartan Dehydrated
Basal day Day 20 Basal day Day 20 Basal day Day 20
PCV (%) 25.9±0.9 25.7±0.5 26.1±1.1 30.5±1.9 * 26.7±0.7 28.9±1.9
Hb g/liter 12.1±0.4 12.1±0.3 12.3±0.6 14.3±1.2 13.2±0.4 13.5±0.6
MCH Pg 13.5±0.3 13.6±0.2 13.5±0.3 13.5±0.2 13.9±0.2 14.2±0.2
MCHC g/dl 46.4±0.6 46.9±0.3 47.2±0.6 46.6±0.9 46.9±0.4 46.6±0.3
MCV Fl 29.2±0.7 28.9±0.3 28.7±0.7 29.0±0.5 29.8±0.4 30.5±0.5
RBC M/ul 8.9±0.4 8.9±0.1 9.1±0.4 10.6±0.8 9.5±0.3 9.7±0.4
WBC K/ul 10.7±1.2 11.6±0.7 10.5±1.6 15.3±0.7** 10.2±1.2 13.4±0.9**
24
Finally, 20 days of dehydration with or without losartan in camels caused significant loss in body
weights for both dehydrated groups compared with time matched control. Weight loss was more
pronounced in the treated group than in the dehydrated, albeit no significant differences were
seen between them. Losartan enhanced the effect of dehydration and resulted in significant
increase in PCV, Urea and creatinine levels. These data suggest that blockade of AT1 receptors
compromises water retention during dehydration in the camel and that dehydration with or
without losartan has major effects on biochemical, hematological, kidney and liver enzymes and
that the renin–angiotensin system plays a role during dehydration.
Table 2. Biochemical changes in serum of control, losartan treated and dehydrated camels. All Values are mean ± SE. Significance from control is denoted by * P<0.05, and from Basal day is denoted by # P<0.05.
Control Losartan Dehydrated
Basal day Day 20 Basal day Day 20 Basal day Day 20
GGT u/l 20.8± 2.2 33.6±2.4 18.2±1.6 15.2±5.4*# 19.3±2.6 33.3±3.5
ALT u/l 19.3±1.7 16.0±2.4 21.5± 3.4 21.0 ±4.3 20.1± 0.9 21.1± 1.9
T-bill Mg/dl 0.2± 0.03 0.2±0.02 0.17± 0.01 0.2±0.09 0.16± 0.01 0.2±0.04
T.P g/dl 6.3± 0.2 5.6± 0.1 6.19± 0.2 7.14±0.4 6.6± 0.2 6.76±0.1
Urea Mg/dl 15.7± 0.4 11.2±1.3 13.3±1.3 39.1± 6.8** 16.5+ 0.9 34.9 ± 3**
Creatinine Mg/dl
1.4± 0.1 1.5±.0.5 1.3± 0.1 3.7±1.3* 1.3± 0.06 2.4±0.3*
Albumin g/dl 3.1± 0.07 2.8±0.01 3.1± 0.1 3.4±0.10 3.1± 0.1 3.3±0.1
Fe (µg/dl) 59.3±4.3 62.8±5.3 52.5±6.4 60.3±5.3 60.8±3.3 59.1±3.4
Cu (µg/dl) 68.7± 1.7 79.2±2.5 61.8±1.2 75.8±6.5 65.4±1.4 75.2±2.2
Ca Mg/dl 8.9± 0.7 9.2±0.05 10.1±0.2 10.9±0.2 10.2± 0.2 10.9±0.1
25
Responses to Dehydration in the One-Humped Camel and Effects of Blocking the Renin-Angiotensin System (Paper II)
In this study we investigated the role of RAS in plasma electrolytes, renal function and hormonal
responses after long term (20 days) dehydration with or without AT1 receptor blocker (losartan)
in a subset of dehydrated camels versus hydrated camels (control). We hypothesized that the
RAS might play a central role in maintaining water and electrolytes homeostasis during
dehydration. It is well known that Ang II acts through two receptor subtypes, AT1 and AT2 that
have been cloned and characterized pharmacologically [48, 49]. The most common physiological
effects of Ang II, such as sodium and water retention, vasoconstriction, aldosterone and
vasopressin release are mediated by AT1 receptor [21]. In order to determine whether the dose of
losartan administered was sufficient to affect the binding of Ang II to AT1 receptors we used
Ang II receptor binding assay [40]. The results of the displacement study showed that Ang II
receptors in the camel liver were exclusively of the AT1 subtype. Our earlier results (paper I)
showed that body weights of the camels decreased by 34.5% across 20 days of water deprivation
in the dehydrated group and by 39.1% in the losartan treated group. In addition changes in serum
sodium level revealed significant increase (p<0.001) in both losartan treated and dehydrated
groups of camels (Table 3). The overall increase was greater in the losartan group versus
dehydrated, albeit, no significant differences were seen between the two dehydrated groups.
These results indicate that there was an effect of losartan on these receptors, as anticipated. Renal
function was also affected by dehydration and losartan, because serum urea and creatinine levels
were significantly increased (p<0.001) across dehydration in both losartan treated and dehydrated
groups compared to control (Table 3). Likewise, it had been reported in the camel, that
dehydration resulted in an increase in serum urea and creatinine reflecting, a major decline in
glomerular filtration rate [51]. Plasma renin activity (PRA) increased significantly on day 20 of
dehydration for the losartan treated group (P<0.05), while for the dehydrated group was (P<
0.01) without any significant difference between the treated and dehydrated groups (Fig. 3). The
hormone systems including PRA, arginine vasopressin (AVP) and aldosterone together with the
RAS, under most circumstances serve to retain water and/or sodium and to maintain circulatory
and renal status.
26
Table 3. Plasma levels of Na, Urea and Creatinine in control, losartan treated and dehydrated camels. Data are shown as Mean ±SEM. Significance from control is denoted by *P<
0.05, **P< 0.01 and ***P< 0.01.
Group of camels Base-line level
Day 20 level
Na (mM/L) control 141.3 ± 1.2 145.2 ± 1.1
losartan 144.2 ± 1.2 180.7 ± 4.3***
dehydrated 144.6 ± 0.7 175.3 ± 2.2***
UREA (mg/dL) Control 15.7 ± 1.3 11.2 ± 1.3
Losartan 16.4 ± 0.8 39.2 ± 6.8**
Dehydrated 13.3 ± 1.4 34.9 ± 3.1**
CREATININE (mg/dL) Control 1.43 ± 0.1 1.5 ± 0.1
Losartan 1.33 ± 0.07 2.5 ± 0.4*
Dehydrated 1.28 ± 0.2 2.2 ± 0.1*
Although earlier studies in camels have documented responses in AVP, RAS and aldosterone to
dehydration [51, 21, 13], the duration of these studies has been relatively brief (8–14 days), time-
matched controls (non-dehydrated animals) were not used. In this study, we have documented
changes in all of these hormones after a longer period (20 days) of water deprivation. Plasma
aldosterone concentrations remained steady over 20 days in control animals; however, they
increased variably but not statistically significant in both dehydrated groups (Fig. 4). The modest
rise in aldosterone levels in the dehydrated camels contrasted with a decline in losartan- treated
camels compared with control camels. In congruence with earlier observations [52, 53], we noted
little change in the circulating levels of aldosterone in the dehydrated camels despite vigorous
activation of the RAS.
27
Figure 3. Plasma renin activity in control, losartan treated and dehydrated animals on day 20 of dehydration. Data are shown as mean ± SEM. Significant difference from control is denoted by *P<0.05, **P<0.01.
One possible explanation for this minimal response in circulating aldosterone levels in the
dehydrated animals is the substantial rise in serum sodium and presumed, though not measured,
increase in plasma osmolality. Studies from the 1960s and 1970s in experimental animals and
man demonstrated that an increase in extracellular sodium concentration can itself suppress
aldosterone production and also inhibit the stimulatory actions of its known secretagogues. It had
been observed that an increase in the plasma sodium concentration of 6–15 mmol/L in blood
supplying the auto-transplanted sheep adrenal gland inhibited the aldosterone secretory response
to sodium depletion [54].
28
Figure 4. Plasma aldosterone levels in control, losartan-treated and dehydrated camels on day 20 of dehydration. Data are shown as mean ± SEM. Changes in aldosterone level in dehydrated camels is not statistically significant compared to control camels.
Furthermore, the aldosterone secretory response to infused Ang II in this sheep model was
inversely related to the plasma sodium concentration [55]. Increases in plasma sodium
concentration of lesser magnitude than in the current study were shown to inhibit the aldosterone
secretory response to Ang II or potassium by the isolated perfused canine adrenal gland [56].
Furthermore, studies in healthy humans [57] and in a patient with diabetes insipidus and adipsia
[58] indicate that an increase in serum sodium concentration reduces aldosterone levels and
inhibits it responsiveness to known stimuli. Finally, support for a modulating effect of circulating
sodium concentration on aldosterone secretion comes indirectly from studies of volume depletion
in camels induced by the intravenous injection of furosemide where, in contrast to the present
situation of water depletion, plasma sodium levels declined [59] and PRA and plasma
aldosterone levels increased vigorously (more than 4-fold) and in parallel.
29
Figure 5. Plasma arginine-vasopressin levels in control, losartan treated and dehydrated camels on day 20 of dehydration. Data are shown as mean ± SEM. Significant difference from control is denoted by **P<0.05, ***P<0.01.
In this study, dehydration stimulated a significant increase in plasma AVP (Fig. 5). The most
obvious explanation for this is the rise in serum sodium (and osmolality) together with the
inevitable, though unmeasured fall in circulating volume and arterial pressure. It is also possible
that the substantial increase in RAS activity contributed a high level of Ag II concentration, that
resulted in stimulating AVP secretion [60], an effect enhanced during water deprivation and
inhibited by water-loading [60, 61]. Some support for this contention comes from our
observation that plasma AVP levels were lower after 20 days of dehydration in camels receiving
losartan compared with those without losartan, although no significant differences were seen
between the two dehydrated groups. These results suggest that RAS plays an important role in
the maintenance of water and electrolytes balance during dehydration and shows that our
hypothesis is correct, since we found greater disturbances in water balance, electrolytes,
hormones and renal function in the dehydrated group when the RAS was blocked using losartan.
30
Changes in insulin-like growth factor-1 and IGF-binding protein-3 in camel
plasma during dehydration in the presence and absence of losartan (Paper III)
The aim of the study presented in paper III was to determine the effect of dehydration in the
presence and absence of the angiotensin II AT1 receptor antagoniost losartan on plasma IGF-1
and IGFBP-3 in the dromedary camel and to compare them with a group of hydrated controls.
All vertebrates maintain plasma osmolality and extra cellular volume primarily by regulating the
ingestion and excretion of water and electrolytes; an elevation in plasma osmolality, and
consequent cellular dehydration, is the most potent stimulus of thirst [62]. Insulin-like growth
factor-I (IGF-I) is produced primarily by the liver as an endocrine hormone and in target tissues
as a paracrine or autocrine. IGF-1production is stimulated by growth hormone (GH) and can be
retarded by under nutrition. IGF-1 mediates chondrogenic effects of GH in promoting long bone
growth, and regulates the proliferation and differentiation of various cell types, including bone
marrow cells. Regarding its amino acid sequence IGF-1 shows partial homology with the pro-
insulin peptide, and also exhibits insulin-like bioactivities [63, 64]. IGF-1 is expressed at low
concentrations in the stromal elements of normal pancreas tissue [65, 66]. IGFBP is a family of
proteins that possess unique biological properties, and are well-described modulators of IGF
activity at the cellular level [67]. A number of studies have been carried out on IGF-1 and its
receptors in the one-humped camel as well as hormonal levels with and without dehydration, we
are not aware of studies assessing directly IGF-1 and IGFBP-3 responses in presence of Ang II
AT1 receptor antagonist to sustained dehydration in the camel. In previous study [68] we showed
that the one-humped camel unlike other mammalians has a high concentration of IGF-1 receptors
in the duodenal mucosa compared to other parts of the digestive tract. It also possesses a higher
concentration of IGF-1 receptors in its mucosa compared to the muscle layer. This could be a
significant feature necessary for the regenerative ability of the duodenal mucosa in the one-
humped camel; as the duodenum is the first part of the gut that comes in contact with the
roughages. In the present study we observed no significant changes in the level of plasma IGF-1
concentration in the control animals compared with their base-line level after 20 days of the
experiment. In contrast, the effect of dehydration with or without losartan on the circulating
levels of IGF-1 in the losartan treated and dehydrated groups were profound from the early days
of dehydration. On day 5 of dehydration both groups showed a decrease of 45% for the
dehydrated and 60% for the treated compared to their baseline and control. The level of IGF-1
decreased progressively as the days of dehydration continued. On day 20 of dehydration the IGF-
1 level for the dehydrated group reached 80% from the base line level as well as from the time-
31
matched control; while, the losartan treated group showed higher reduction (89%) in IGF-1 level
(Table.4) . The exact reason for this major drop in IGF-1 is not well known, but one possible
explanation could be due to the reduced basal metabolic rate as a result of reduced food and
water intake. This may affect the liver function resulting in decreased IGF-1 synthesis. Another
possible explanation could be that these dehydrated camels reduce most of their body synthetic
processes as an adaptation mechanism to preserve water and reduce energy required. It is known
that the endocrine system mediates many of the physiological responses to the homeostatic and
climatic demands of salt and water transport [69]. Previous studies have suggested a role for IGF-
1 in the regulation of intestinal water uptake reduction and osmoregulation in fishes [70]. It was
also reported that hyperosmotic stress may increase the GH sensitivity in the gills and liver of
flounders, and consequently improve IGF-I production [71].
Table-4. Plasma IGF-1 (ng/ml) levels in control, losartan treated and dehydrated camels. Data are shown as Mean ± SEM. Significance of Basal versus losartan and dehydrated is
denoted by *P< 0.05 &
**P<0.01. While, significance of Control versus losartan and
dehydrated is denoted by $$P<0.01 & $$$P<0.001).
Camels Group Baseline level (n=3)
Day 5 level (n=5)
Day 10 level (n=6)
Day 20 level (n=6)
Control 331.0±92 319.8±79 326.3±54 334.7±33
Losartan 319.7±25 126.5±19* 82.8±15
**$$$ 32.4±11***$$$
Dehydrated 315.7±25 173.0±73 118.3±28**$$$ 62.0±22
***$$$
The effect of 20 days of dehydration in presence of losartan on the circulating IGFBP-3 was 26%
decrease compared to their basal values and their controls. The effect of both dehydration and
losartan on the treated camels was significant on day 10 of dehydration and remained steady
(26%) to the last day of the experiment. The dehydrated group showed 22% decrease on day 10
and 29% on day 20 of dehydration compared to their baseline value and to time-matched control.
The decrease in IGFBP-3 level for the dehydrated group was greater than the treated group;
albeit, no significant differences were seen between them (Table 5). Previous studies have
suggested a role for IGF-1 in the regulation of intestinal water uptake reduction and
osmoregulation in fishes [70].
32
Table-5. Plasma IGFBP-3 (ng/ml) levels in control treated and dehydrated camels at baseline,
day 5, 10 and 20 of dehydration. Data are presented as Mean ± SEM. Significance of
Basal versus losartan and dehydrated is denoted by (*P< 0.05, **P<0.01 and ***
P<0.001) and Control versus losartan and dehydrated by ($$P<0.01, $$$P<0.001).
Camels Group Baseline level (n=3)
Day 5 level (n=5)
Day 10 level (n=6)
Day 20 level (n=6)
Control 410.0±19 396.8±32 406.2±21 405.0±13
Losartan 406.7±71 387.8±15 300.4±15*$$ 302.6±21
***$$$
Dehydrated 396.0±31 397.0±42 308.6±13*$$ 281.6±19
***$$$
The ratio of GH/IGF-1 axis has been suggested to be essential in water homeostasis. Little is
known about the role of IGF-1 in dehydration. From the present study it is evident that
dehydration resulted in a reduction in both levels of IGF-1 and IGFBP-3, which may reflect a
disturbance in growth hormone level in this dehydrated camels. The effects caused by losartan on
the IGF-1 and IGFBP-3 levels suggest a possible role of RAS in the present context. It was
indicated that endurance horses with dehydration and electrolyte disturbances exhibited
activation of the renin-angiotensin-aldosterone-vasopressin axis [72]. Moreover, studies in
several species have demonstrated that intracerebroventricular administration of AT1 receptor
antagonist inhibited homeostatic responses to thermal dehydration [73]. The effects of the AT1
blocker on IGF-1 is not clear but earlier studies have shown that IGF-1 may up-regulate the AT1-
receptor [74] and this may account for an important interaction that may have implications for
the observed effect of losartan.
33
ANP and BNP Responses to Dehydration in the One-Humped Camel and Effects of Blocking the Renin- Angiotensin System (Paper IV)
The objective of the study presented in paper IV was to investigate and compare the response of
ANP and BNP in the circulation of hydrated, losartan treated and dehydrated camels; and to
document the cardiac storage form of BNP in the camel heart. For measurements of plasma BNP,
we first determined which antibody and standard should be used in our radioimmunoassay. This
is vital since, by contrast with ANP, the amino acid structure of BNP is known to vary
considerably across species and even amongst mammals. Using polyclonal antibody raised to
porcine BNP, camel plasma from control, losartan and dehydrated camels together with extracts
from left and right ventricle and left and right atria diluted in parallel with standard porcine
BNP1-32 (Figure 6). In contrast, there was no cross reactivity to standard human BNP1-32 and
hence no parallelism, for camel heart extracts in a radioimmunoassay which used an antibody to
human BNP1-32 (data not shown). Size exclusion HPLC of extracts from camel atrial tissue
demonstrated a single immunoreactive peak in fractions 24-26 (Figure 7) which eluted one
fraction later than recombinant human proBNP standard but well ahead of synthetic human
NTproBNP and BNP1-32 standards. This indicates that immunoreactive BNP in the camel heart
is in the form of proBNP with an approximate molecular weight of 11,600 Da, and close to the
theoretical molecular weight of camel proBNP (11,734 Da) calculated from the dromedary
sequence provided by Osman et al and in Gene bank: BAD21300.1 [75]. Further, it is evident
that little or no immunoreactive BNP is stored as smaller molecular weight BNP or NT-proBNP.
Our observations in this regard are congruent with an earlier study of camel natriuretic peptide
cDNA which concluded that camel BNP has 94% identity with porcine BNP [75]. Our additional
observation, using size-exclusion HPLC is that, as in many species including sheep [76], the
dominant form of immunoreactive BNP in camel heart is a large molecular weight form
consistent with the proBNP hormone.
With regard to previous studies of the cardiac natriuretic peptides, 14 days of dehydration in
camels was reported to have no effect on circulating levels of ANP [53]. In contrast, we observed
that plasma ANP levels were substantially and statistically significant lower after 20 days of
dehydration compared with time-matched controls. This response is unsurprising given that
stretch of the cardiac chambers, generally considered the major stimulus to ANP release [77],
would certainly have decreased across the dehydration period and, presumably, overcame any
stimulatory action from increased activity of the RAS [77].
34
Figure 6. Dilutions of extracts of plasma (top panel) and heart (lower panel) from two camels in
a radioimmunoassay utilizing standard pig BNP1-32 and antiserum raised to pig BNP.
35
Figure 7. A single peak of immunoreactive BNP on size exclusion HPLC using camel atrial tissue extract by radioimmuno assay with standard porcine BNP and antibody directed against porcine BNP. This peak corresponded exactly with that of large molecular weight proBNP, well separated from BNP1-32 and NT-proBNP, using the same technique for extracts of human heart (data not shown).
Plasma levels of ANP were approximately 6-fold higher than concomitant BNP levels at baseline
(Figure 8). Whereas both ANP and BNP levels tended to rise over 20 days in control camels but
not significantly, they decreased substantially and similarly across 20 days of dehydration with
and without losartan administration (Figure 8). As for ANP, dehydration resulted in a clear-cut
decline in circulating levels of BNP. Again, as for ANP, we presume that any stimulatory action
on BNP synthesis and release from activation of the RAS was overcome by reduced stretch of
cardiac chambers during prolonged dehydration. Teleologically, these responses in plasma ANP
and BNP levels would be seen as logical in being protective against excessive sodium and water
loss. If, as would be expected, arterial pressure declined across dehydration in our camels, the
natriuretic and diuretic actions of these peptides would be diminished [78, 79] thereby tending to
further limit urinary loss of sodium and water. Nevertheless, caution is needed in this discussion
since, to our awareness; there are no in-depth studies in camels regarding the regulation neither
of cardiac natriuretic peptide release nor on their renal effects under conditions of water-
depletion versus repletion.
36
Figure 8. Plasma levels of ANP (top panel) and BNP (lower panel) in pmol/L at baseline and 20
days in control, losartan treated and dehydrated camels. Data are shown as
mean±SEM. *P< 0.05, **P<0.01 denotes basal versus treated and dehydrated. While ##P<0.01, ###P<0.001 denotes control versus treated and dehydrated.
37
In summary, 20 days of dehydration induced substantial suppression of plasma ANP and BNP
concentrations. Blockade of the AT1 receptor had little or no effect on the plasma ANP and BNP
responses to dehydration. Finally, the storage form of B-type natriuretic peptide in the one-
humped camel is large molecular weight proBNP.
lEffects of Dehydration and Blockade of Angiotensin II AT1 Receptor on Stress Hormones and Anti-Oxidants in the one-humped camel
(Paper V) In the study presented in paper V we documented and compared plasma levels of catecholamines
cortisol, glutathione and malondialdehyde in plasma, liver and kidney homogenates after long
term dehydration in the presence and absence of Ag II AT1 receptor blocker (losartan) versus
levels in non-dehydrated camels, using HPLC, radioimmunoassay and colorimetric assays.
Catecholamines as neurotransmitters and adrenomedullary hormones influence almost all tissues
and many body functions. Together with other neuronal and hormonal systems they play a
significant role in regulating a number of physiological processes. Our results demonstrated that
dehydration activated some components of the sympathetic nervous system as reflected in the
circulating levels of norepinephrine and dopamine and deactivated the circulating plasma level of
epinephrine (Figure 9). Blockade of AngII AT1 receptors tended to overstress the effects of
dehydration, although differences from dehydration alone failed to reach levels of statistical
significance. The main cause for the increased level of plasma norepinephrine in these
dehydrated camels is not immediately apparent. The most apparent explanation could be due to
the physical stress caused by dehydration alone or in combination with the effect of losartan.
This increase in norepinephrine and dopamine levels may have played a positive role in the
regulation of their cardiovascular and metabolic systems. Recently it was reported that hormones
released during stressful conditions are used to supply the body with the energy required for
breaking down the body metabolites [22-80]. On the other hand, plasma dopamine level was
significantly increased after 20 days of dehydration in both treated and dehydrated groups
compared to time matched control. Dopamine was reported to regulate fluid and electrolyte
balance by direct and indirect actions in the kidney, blood vessels, gastrointestinal tract, adrenal
glands, sympathetic nervous system, hypothalamus and other brain centers [23-30].
38
Figure 9. Catecholamines concentration (pg/ml) in plasma of Control, Treated and Dehydrated
Camels. Data shown are mean ± SEM. Asterisks denote * P<0.05, ** P<0.01 and
*** P<0.001. Significant difference from control values
Plasma cortisol levels increased during dehydration to more than 2-fold for the dehydrated and 3-
fold for the treated group when compared with time-matched control (Figure 10). The increase in
cortisol level was higher in the treated versus dehydrated camels, albeit, no significant difference
between them was observed. The main cause for the vigorous rise in plasma cortisol in these
dehydrated camels is not immediately apparent. The most obvious possibility is that the
hypothalamic-pituitary axis was stimulated during dehydration resulting in a rise in plasma
adrenocorticotropic hormone (ACTH) and thence cortisol. This could be the result of “stress” or
possibly due to activation of the renin-angiotensin system since angiotensin II, at least under
some circumstances, can stimulate or enhance the release of corticotropin-releasing factor [81]
and ACTH [82, 83] and, in addition, is capable of stimulating cortisol secretion directly from the
*
**
***
*
**
***
0
50
100
150
200
250
300
350
400
450
500
Epinephrine Norepinephrine Dopamine
Cat
echo
lam
ines
(pg/
ml)
Control Losartan Dehydrated
39
adrenal fasciculata [84, 85] or augmenting the effect of ACTH on cortisol production [86]. It had
been reported that cortisol had the capacity to interfere with a principal mechanism of resistance
to dehydration, by inhibiting the effects of arginine vasopressin in dogs [87]. Other studies
showed that effect of external heat load could be associated with significant increments of
plasma cortisol [88].
Fig. 10. Plasma Cortisol concentration (µg/dl) in Control, Treated and Dehydrated camels. Data
are shown as percentage concentrations compared to control.
Dehydration enhanced by losartan activated body antioxidants resulting in a significant increase
in plasma GSH levels after 20 days of dehydration compared to control (Figure 11). Liver
homogenate GSH level was also significantly increased in both treated and dehydrated groups
compared to control. However, liver homogenate GSH level was more affected by losartan than
dehydration alone. The liver is known to have the highest content of antioxidant and antioxidant
enzymes indicating that it plays an important role in pro-oxidants detoxification [89]. GSH level
0
100
200
300
400
500
600
Control Losartan Dehydrated
Cor
tisol
,% D
iffer
ence
fro
m C
ontr
ol
40
in kidney homogenate was higher in both treated and dehydrated camels compared to time-
matched control. Dehydration is known to cause an increase in production of reactive oxygen
species that leads to lipid peroxidation and nucleic acid damage causing severe consequences on
over all metabolism [90].Thus, the increase in glutathione level in plasma and liver homogenate
in the treated and dehydrated camels indicate that there is an increased level of oxidative stress in
these dehydrated camels.
Figure 11. GSH (µM/ml) activity in plasma, liver and kidney homogenates in control, treated
and dehydrated camels. Data are Mean ± SEM. * Asterisk denotes significance from
control *P<0.05.
The present study also revealed higher increase in MDA concentrations in plasma, liver and
kidney homogenates in both treated and dehydrated camels compared to control (Figure 12). It
had been reported that increased production or decreased removal of hydrogen peroxide lead to
lipid peroxidation and this result in an increased production of plasma MDA level [91]. It was
* *
* *
*
*
0
2000
4000
6000
8000
10000
12000
Control Treated Dehydrated
GSH
µM
Plasma Liver Kidney
41
reported that dehydration causes high production of reactive oxygen species that trigger high
lipid peroxidation resulting in an increased MDA formation [91]. Analysis of kidney
homogenate also revealed higher increase in MDA level for both treated and dehydrated camels
compared to time matched control.
Conclusion, our study indicates that dehydration alone or in the presence of Ag II AT1 receptor
blocker (losartan), caused significant changes in plasma concentrations of stress hormones in
treated and dehydrated camels. In addition, dehydration with and without losartan enhanced
significant increase in GSH and MDA concentration in plasma, liver and kidney homogenates.
Suggesting that dehydration alone or together with losartan induced the production of free
radicals and this initiates the production of the anti-oxidant GSH and MDA.
Figure 12. Malondialdehyde (µM/ml) activity in camel plasma, liver and kidney homogenates in
Control, Treated and Dehydrated camels. Data shown are Mean ± SE. *Asterisk
denotes significance from control (* P<0.05, ** P<0.01 & *** P<0.001).
*** **
** $
*
0
5
10
15
20
25
30
35
40
Control Treated Dehydrated
Mal
ondi
alde
hyde
µM
Plasma Liver Kidney
***
42
General Conclusion: 1- 20 days of dehydration in the one-humped camel resulted in a marked decline in body
weight with changes in hematological and biochemical indexes, losartan enhanced the
effect of dehydration compared to time-matched controls. The size and shape of RBC
were more affected by dehydration in the presence of losartan, indicating that RAS plays
a role in the morphology of red blood cells during dehydration.
2- 20 days of dehydration with losartan administration induced profound increments in
serum sodium, urea and creatinine levels, along with the activation of RAS and increased
circulating levels of AVP. Plasma aldosterone level was slightly altered despite
stimulation from its known secretagogues presumably due to the increased sodium level.
The effect seen for losartan may suggest that the RAS contributes to the maintenance of
water and electrolyte homeostasis and kidney function.
3- Dehydration alone or in presence of losartan caused significant and progressive decrease
in plasma levels of IGF-1 and IGFBP-3, suggesting a linear correlation between the state
of dehydration and the decrease in IGF-1 and IGFBP-3 levels. Hence, our results suggest
an essential role of IGF-1and its IGFBP-3 in water and electrolyte homeostasis in the
one-humped camel.
4- 20 days of dehydration induced substantial decrease in plasma ANP and BNP
concentrations. Blockade of Ag II AT1 receptors with losartan had little or no effect on
the plasma ANP and BNP responses to dehydration. Finally, the storage form of BNP in
the heart of the one-humped camel is a large molecular weight proBNP.
5- Dehydration alone or in the presence of losartan caused substantially significant changes
in plasma stress hormones in both treated and dehydrated group of camels compared to
control. In addition, dehydration with and without losartan caused a significant increase
in GSH and MDA concentrations in plasma, liver and kidney homogenates. Suggesting
that dehydration with or without losartan induced the production of the anti-oxidant GSH
and MDA to neutralize the toxic effects of the free radicals.
43
Acknowledgements The studies presented in this thesis were carried out at the Department of Pharmacology and
Therapeutics, College of Medicine and Health Science United Arab Emirates University, in
collaboration with the Department of Pharmaceutical Biosciences, Faculty of Pharmacy, Uppsala
University, Sweden. Great thanks to God as he helped me to complete this thesis after a long
journey of hopes and frustrations. It’s true “Life is moving and doesn’t stand still, nor wait until
you are finished and have time to manage it. Much has happened and changed in the time I’ve
been involved with this project.
I would like to express my sincere appreciation to all the people who have played a part in the completion of this thesis, especially: My supervisors, Professor Abdu Adem and Prof. Fred Nyberg, for providing me with all the
required items for the project starting from the funds to the smallest laboratory items, for their
kind permission to let me use their laboratories to do my project, and for providing a PhD
education with the possibility of free-thinking. Thank you for always believing in my abilities
and for the great care you provided.
To all my co-authors and all colleagues, none mentioned but none forgotten, at the Department
of Pharmaceutical Biosciences Uppsala University, Uppsala, Sweden; Departments of
Pharmacology and Therapeutics, Internal Medicine and Community Medicine, United Arab
Emirates University, Al Ain, United Arab Emirates; and Department of Medicine, Christchurch
Hospital, Otago University, Christchurch, New Zealand. In addition, I have been very privileged
to get to know and to collaborate with many other great people who became friends over the last
several years. I learned a lot from you about life, research, how to tackle new problems and how
to develop techniques to solve them. Thanks to all my brothers, sisters and friends for their
constant support.
Finally, I would like to acknowledge the most important persons in my life – My mother Fatima,
my wife Hawa, my four flowers (Najat, Najla, Abeer and Asma) and my friend and son Osman.
They were a constant source of strength and inspiration in my long journey. Their determination
and constant encouragement that ultimately made it possible for me to see this project through to
the end.
44
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Uppsala University, Digital Comprehensive Summaries of Uppsala Dissertations from the Faculty of Pharmacy Editor: The Dean of the Faculty of Pharmacy A doctoral dissertation from the Faculty of Pharmacy, Uppsala University, is usually a summary of a number of papers. A few copies of the complete dissertation are kept at major Swedish research libraries, while the summary alone is distributed internationally through the series Digital Comprehensive Summaries of Uppsala Dissertations from the Faculty of Pharmacy. (Prior to January, 2005, the series was published under the title “Comprehensive Summaries of Uppsala Dissertations from the Faculty of Pharmacy”.)
Acta Universitatis UpsaliensisDigital Comprehensive Summaries of Uppsala Dissertationsfrom the Faculty of Pharmacy 178
Editor: The Dean of the Faculty of Pharmacy
A doctoral dissertation from the Faculty of Pharmacy, UppsalaUniversity, is usually a summary of a number of papers. A fewcopies of the complete dissertation are kept at major Swedishresearch libraries, while the summary alone is distributedinternationally through the series Digital ComprehensiveSummaries of Uppsala Dissertations from the Faculty ofPharmacy.
Distribution: publications.uu.seurn:nbn:se:uu:diva-207574
ACTAUNIVERSITATIS
UPSALIENSISUPPSALA
2013