Methods: Sixty-six Wistar albino rats were randomly divided into four groups each consisting of 14 to 20 rats. The rats in group 1 (n=20) and group 3 (n=16) were fed with a 1% cholesterol supplemented diet, whereas the rats in group 2 (n=14) and group 4 (Control group) were fed with regular rat chow. Rats' tracheas were surgically explored under anesthesia. Intratracheal inoculation was performed with P. aeruginosa suspension in group 1 and 2 or 0.1 ml saline in groups 3 and 4 via a syringe five times with four-week-intervals during the study period. Cholesterol levels were measured in blood samples collected from the tail under anesthesia.
Results: In histopathological examinations; the segment with greatest luminal narrowing was selected by visual inspection and 8-10 slides prepared from each segment were examined under Olympus CH 40 microscope. Medial and the neointimal areas of the specimens were analyzed by computed image analysis.
Conclusion: The rats in the control group exhibited mainly normal renal artery wall structure on cross sections. The rats that were infected and fed with 1% cholesterol diet developed typical preatherosclerotic changes in the renal arteries. In this study, it was demonstrated for the first time that both chronic lung infection with P. aeruginosa and high cholesterol f eeding a ccelerated the increases of the renal artery intima-media thickness in a rat model. These findings strongly suggest that the distant effects of chronic infection are an etiological factor in genesis of atherosclerosis.
More recently attention has focused on the role of microorganisms in atherosclerosis. Several epidemiologic studies have demonstrated an association between Chlamydia pneumonia (C. pneumonia) infection and cardiovascular disease. Infection can affect the atherosclerotic process directly by inducing a local inflammatory reaction associated with oxidative and proteolytic process and proliferative cell responses, the indirect effects from distant sites by inducing cytokines and systemic inflammation is a question of debate.[3,4] There is little knowledge of the role of infection in the pathogenesis of renal artery atherosclerosis.[5]
This study explores a possible relationship between renal artery atherosclerosis and chronic lung infection with Pseudomonas aeruginosa (P. aeruginosa) in a rat model. The objectives of the present study were to determine whether chronic lung infection with P. aeruginosa in rats fed with regular rat diet (Chow) or 1% cholesterol-rich diet would result in atherosclerosis.
Experimental animals and study design
Three-month-old, pathogen-free Wistar albino rats
(n=66) were used. The rats were randomly divided
into four groups having fourteen to twenty rats in each group. The rats in group 1 (n=20;) and group 3 (n=16)
were fed with a 1% cholesterol-supplemented diet
(Sigma, St. Louis, MO63178, USA), whereas the rats in
group 2 (n=14) and group 4, the control group, were fed
with regular rat chow. Four rats in group 1, two rats in
group 3 and four rats in group 2 died during the experiment.
Using titrated intramuscular doses of ketamine
hydrochloride (30-100 mg/kg) and xylazine hydrochloride
(10-15 mg/kg) the rats' tracheas were surgically
explored under anesthesia and 0.1 ml (1.5x109
CFU/ml) of P. aeruginosa suspension (in group 1
and 2) or 0.1 ml saline (in groups 3 and 4) were given
intratracheally via a syringe five times at four-weekintervals
during the study period. Cholesterol levels
were measured by a blood sample collected from the
tail (0.5 ml) under anesthesia. Animal chow consumption
and weights were recorded monthly. Animal care
and processing were performed under strict adherence
to the Institutional Animal Care and Use Committee
guidelines.
After six months from the first inoculation the rats were sacrificed to proceed to evaluate the renal arteries. First, the chest cavities were opened and the lungs removed under sterile conditions, and half of the lungs were prepared for bacteriological examination. Secondly, after opening abdominal cavities, the renal arteries were excised from the point that renal arteries join the aorta. The renal arteries were sent for histopathological examination.
Bacteriological examination
Samples were appropriately diluted and plated to determine
the numbers of CFU. To prepare the bacterial
sample 0.1 ml of the homogenate was plated. Equal volumes
of phosphate-buffered saline were added to each
of the lung tissue samples, and the mixture was then
homogenized to prepare the lung homogenates.
Histopathological examination
The pathology team that performed histopathological
examinations was blinded to the specimens. The team
first grossly inspected the specimens. Representative
cross-sections of the renal arteries were prepared as
follows: histological specimens were fixed in 10%
buffered formalin, embedded in paraffin, and stained
with hematoxylin and eosin. Five-micrometer(μm)-
thick serial sections were prepared using cryotome
(Shandon AS 325, Cheshire, WA7 1PR, England) after
cross-sections of the specimen from the aorta-renal
artery junction and middle of the renal artery were
removed from each sample. The segment with greatest
luminal narrowing was selected by visual inspection of
the 8-10 slides prepared from each segment and then
examined by Olympus CH 40 microscope (Olympus optical Co, Ltd, Japan). Media and the neointima
regions of the specimens were analyzed by computed
image analysis (Samba 2000, Gateway, GP7-450,
GW-2K, Ireland). After determining three slides having
maximal renal artery wall thickness, computed
image analysis was used to perform three pre-specified
measures including intima plus media and an average
of the three measurements for each section were used
in the statistical analysis.
Statistics
Serum total cholesterol levels, chow consumption and
the weights of the rats were expressed as mean±standard
deviation. Chow consumptions and the weights of the
groups were estimated by analysis of variance in repeated
measures. In addition maximal renal artery wall
thickness, serum total cholesterol levels were evaluated
by variance analysis and the p-value ≤0.05 was considered
significant.
The total serum cholesterol levels of the rats in groups 1, 2, 3 and 4 were 78.76±7.60 mmol/l, 61.10±8.71 mmol/l, 86.68±16.30 mmol/l, 74.75±12.20 mmol/l, respectively. The rats in group 2 (infected-only group) had significantly less serum cholesterol level than the groups 1, 3 and 4 (p<0.0001). Pseudomonas aeruginosa was isolated from the lungs of the seven rats in group 1 and the three rats in group 2 but none from the other groups.
The rats in the control group exhibited mainly normal renal artery wall structure on cross sections (Fig. 1). However, the rats in the infected plus 1% cholesterol diet-fed group developed typical preatherosclerotic lesions in the renal arteries. Cross sectional analysis revealed that lesions were uniformly characteristic of preatherosclerotic lesions with fatty streaks, various proportions of foamy cells, smooth muscle cells and extracellular matrix (Fig. 2).
Fig 1: Renal artery wall structure on cross sections in the control group (H-E x 200).
The intima-media thickness at the middle of the right renal artery had significantly increased in the infected plus 1% cholesterol diet-fed rats (70.04±4.46 μm) when compared with the rats fed 1% cholesterol diet alone (63.94±3.34 μm; p<0.001; Fig 3), the infected-only rats (59.83±1.72 μm; p<0.001; Fig 4), and the rats in the control group (56.51±1.53 μm; p<0.001).
Fig 4: Renal artery wall structure on cross sections the only infected rats (H-E x 200).
The intima-media thickness at the middle of the left renal artery had significantly increased in the infected plus fed 1% cholesterol-diet rats (71.19±4.13 μm) when compared with the rats fed 1% cholesterol-diet alone (64.20±4.35 μm; p<0.001), the only infected rats (60.20±1.21 μm; p<0.001), and the rats in the control group (55.26±1.48 μm; p<0.001).
The intima-media thickness at the junction of the right renal artery aorta had significantly increased in the infected plus fed 1% cholesterol-diet rats (96.97±4.13 μm) when compared with the rats fed 1% cholesterol-diet alone (88.52±2.34 μm; p<0.001), the only infected rats (88.29±2.35 μm; p<0.001), and the rats in the control group (74.21±2.64 μm; p<0.001).
The intima-media thickness at the junction of the left renal artery aorta had significantly increased in the infected plus 1% cholesterol diet-fed rats (97.54±5.25 μm) when compared with the rats fed 1% cholesterol diet alone (89.18±2.49 μm; p<0.001), the infected-only rats (89.49±1.25 μm; p<0.001), and the rats in the control group (74.13±2.54 μm; p<0.001).
It has been shown that atherosclerotic lesions in the hyperlipidemic swine model almost exclusively arise from intimal thickening point, and accelerated increases in the intima-media thickness are important in the genesis of atherosclerosis.[8]
Intima-media thickness of the carotid arteries can be measured noninvasively by using ultrasound techniques. Normally in healthy individuals there is a slow increase of the intima-media thickness with age.[9] Some studies showed that the increases in intima and media thickness are about three times faster in patients with vascular disease.[10] Intimal thickening and intimal xanthomas, which are accepted as preatherosclerotic lesions, are commonly produced in high cholesterol/high fat feeding animal models.[11] In this study we showed that increases in intima-media thickness in high cholesterol/high fat feeding rats were accelerated with chronic lung infection with P. aeruginosa.
There is little knowledge of the role of infection in the pathogenesis of renal artery atherosclerosis. Infection can affect the atherosclerotic process directly by inducing a local inflammatory reaction associated with oxidative and proteolytic process and proliferative cell responses, the indirect effects from distant sites by inducing cytokines and systemic inflammation. The role of infection in the genesis of atherosclerosis was investigated in several animal models. Muhlestein et al.[12] showed that infection with C. pneumonia may accelerate the development of atherosclerosis and treatment with azithromycin may prevent it in a rabbit model. With apoE-deficient mouse model it has been shown that both murine γ-herpes viruses and CMV accelerate atherosclerosis.[13,14] In mice fed the high cholesterol diet, C. pneumonia strain AR39 may stimulate the initial atherosclerotic lesions on vessels, however this is not the case with the C. trachomatis strain mouse pneumonitis (MoPn) organisms.[15] C. pneumonia was isolated from the atherosclerotic plaques. Therefore, C. pneumonia was suggested to possess a unique biologic property for its atherogenesis. But distant effects of infection were not clearly defined. In this study, we chose a non-specific bacterium P. aeruginosa (mucoid phenotype) leading to chronic infection in other systems to evaluate the distant effect of infection, as this microorganism has not been previously isolated from the aortic or other arterial walls.
P. aeruginosa is one of the most frequently isolated bacterial pathogens in patients with chronic pulmonary infections, including cystic fibrosis. The mucoid exopolysaccharide produced by mucoid strains form a matrix arround the bacterium, protecting it from host immune factors such as phagocytic cells.[16] Cash et al.[17] originally developed a model of chronic bronchopulmonary infection in rats using agarose beads embedded with P. aeruginosa. While planning the study we decided to employ repeated administration of the organism as it was done with the rat model of C. pneumonia infection.[12] Direct tracheal inoculation of free P. aeruginosa have resulted in an acute or a transient pulmonary infection.[18] Although the rats challenged with free live P. aeruginosa experienced mild to moderate lung pathology as compared to the rats challenged with P. aeruginosa alginate beads, their antibody responses were comparable and the immunological responses to the antigens used were persistent during the whole 28 day study period.[18]
Finally, this study first demonstrated that both chronic lung infection with P. aeruginosa and high cholesterol/high fat feeding accelerated the increases of the renal artery intima-media thickness in a rat model. Renal artery intima-media thickness was significantly increased in the infected plus 1% cholesterol diet rats compared with the rats fed 1% cholesterol diet alone. These findings strengthened the opinion that the distant effects of chronic infection are an etiological factor in the genesis of atherosclerosis.
Declaration of conflicting interests
The authors declared no conflicts of interest with respect
to the authorship and/or publication of this article.
Funding
The Akdeniz University Scientific Research Projects
Unit, Antalya, Turkey supported this study.
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