http://orcid.org/0000-0003-2347-0411
Figures
Abstract
Systemic lupus erythematosus (SLE) is a disease that mostly affects women. Accelerated atherosclerosis is a high-risk factor associated with SLE patients. SLE associated with cardiovascular disease is one of the most important causes of death. In this study, we demonstrated that Lactobacillus paracasei GMNL-32 (GMNL-32), a probiotic species, exhibits anti-fibrosis and anti-apoptotic effects on the cardiac tissue of NZB/WF1 mice. Female NZB/W F1 mice, a well-known and commonly used lupus-prone mouse strain, were treated with or without GMNL-32 administration for 12 weeks. Oral administration of GMNL-32 to NZB/WF1 mice significantly increased the ventricular thickness when compared to that of NZB/WF1 mice. Administration of GMNL-32 significantly attenuated the cardiac cell apoptosis that was observed in exacerbate levels in the control NZB/WF1 mice. Further, the cellular morphology that was slightly distorted in the NZB/WF1 was effectively alleviated in the treatment group mice. In addition, GMNL-32 reduced the level of Fas death receptor-related pathway of apoptosis signaling and enhanced anti-apoptotic proteins. These results indicate that GMNL-32 exhibit an effective protective effect on cardiac cells of SLE mice. Thus, GMNL-32 may be a potential therapeutic strategy against SLE associated arthrosclerosis.
Citation: Hu W-S, Rajendran P, Tzang B-S, Yeh Y-L, Shen C-Y, Chen R-J, et al. (2017) Lactobacillus paracasei GMNL-32 exerts a therapeutic effect on cardiac abnormalities in NZB/W F1 mice. PLoS ONE 12(9): e0185098. https://doi.org/10.1371/journal.pone.0185098
Editor: Yi-Hsien Hsieh, Institute of Biochemistry and Biotechnology, TAIWAN
Received: June 20, 2017; Accepted: September 6, 2017; Published: September 21, 2017
Copyright: © 2017 Hu et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the paper.
Funding: This work is supported by Taiwan Ministry of Health and Welfare Clinical Trial and Research Center of Excellence (MOHW105-TDU-B-212-133019) and GenMont Biotech Incorporation, Taiwan. (1044EI). The funding organization provided support in the form of salaries for Y-H.C. and research materials (L. paracasei GMNL-32), but did not have any additional role in the study design, data collection and analysis, decision to publish, or preparation of the manuscript. The specific roles of these authors are articulated in the ‘author contributions’ section.
Competing interests: The author Y-H.C. was employed by the commercial organization GenMont Biotech Incorporation, Taiwan that provided the probiotic stain. The commercial affiliation does not alter our adherence to all PLOS ONE policies on sharing data and materials.
Introduction
Systemic lupus erythematosus (SLE) is an autoimmune disorder that only affects women. SLE patients may show modulations in cardiac tissue including the pericardium, coronary arteries, valves, myocardium, and conduction system [1]. The occurrence of Coronary heart diseases in SLE can be due to many pathophysiologic mechanisms, including arteritis, thrombosis, abnormal coronary flow, embolization, and atherosclerosis [2]. Patients with SLE have a high rate of coronary heart disease [3], generally as pericarditis and myocarditis and Cardiovascular disease is considered to be the primary cause of morbidity and mortality in SLE [4]. It has been reported that women of 44–50 years of age have a 50-fold increased risk of myocardial infarction [5].
Autoantibodies, including anti-phospholipid antibodies and anti-endothelial antibodies are known to inflict cardiac damages [4,6–9]. In SLE patients apoptosis has been firmly related with different autoantibodies such as anti-phospholipids and anti-oxidized low-density lipoprotein antibodies and the engagement of these autoantibodies with self-tissue is considered to enact the supplement framework, cell-interceded cytotoxicity, and cardiomyocyte apoptosis [10,11]. For this reason, restraint of cardiovascular apoptosis is recommended to improve autoantibody-incited heart injuries in SLE patients.
Several studies have proven that probiotics detain the crucial not only to health and a stronger immune system but also for the treatment of metabolic diseases [12–14]. Lactobacilli comprise various probiotic strains that exert beneficial effects through anti-inflammatory actions, intestinal barrier stabilization, and possible attenuation of liver disorders[15]. Administering live probiotics in immunocompromised patients is a risky affair. While healthy individuals can tolerate the presence of effects of probiotics in their gastrointestinal system, patients with modulated immune response may be at a risk of infection [16]. Many studies have shown that heat-killed probiotics have greater beneficial effects [17–22].
Recently probiotics have been shown to have the ability to affect metabolic fat and improve the immune response and stress resistance [23,24]. By decreasing absorption and inflammatory status, Lactobacillus gasseri SBT2055 can able to decrease body weight, obesity, and adiposity in obese adults who consumed fermented milk with this bacterium for 12 weeks [25]. To-shimitsu et al. reported that treatment of KKAy mice with the L. plantarum strain OLL2712 was effective in alleviating metabolic disorders by suppressing chronic inflammation in the KKAy mice [26]. Likewise, probiotic bacteria may impact various components of atherogenesis, e.g., Lactobacilli have been appeared to bring down blood cholesterol levels in both rodents and in humans [27,28], by balancing cholesterol re-absorption from the gut through its effects on the bile-digestion system. Very few studies have explored probiotic interventions on atherosclerosis advancements in animal models. Portugal LR et al., [28] treated the Apoe−/− mouse model with L. delbruecki but observed to no significant changes in the lesion size. However, the bacterium caused no change in blood cholesterol levels, and the mice were colonized with L. delbruecki for approximately 4 to 10 weeks of age, which can be considered moderately early in disease progression [29].
Feeding heat-killed L. acidophilus and L. casei had showed ameliorative effect on Candida albicans-colonized immune-deficient mice, although the immunomodulatory effects of these candidate probiotic bacteria showed that differences exist between them [30]. Wang et.al, shown that L. paracasei ssp paracasei F19 (F19) block diet-induced obesity in mice [31]. L. paracasei has also been known to exhibit cardio-protection in murine models. Our previous study shows that heat killed L. paracasei effectively improves the cardiac function and inhibits the myocardial apoptosis in high-fat-diet fed hamsters and rat models. They are also effective in ameliorating the cardiac as well as hepatic fibrosis effects associated with high calorie-diet feeding and are also known to strongly suppress the inflammation mediators [32–34]. In the present study, we therefore investigate the impacts of L. paracasei GMNL-32 strain on the hearts of NZB/W F1 mice, with respect to modulation in apoptosis and survival signaling pathways.
Materials and methods
All the protocols of animal experiments were reviewed and approved by the Institutional Review Board (IRB), and the Animal Care and Use Advisory Group of the China Medical University, Taichung, and Republic of China.
Preparation of Lactobacillus paracasei GMNL-32 (GMNL-32)
GMNL-32 was stored in the Bioresource Collection and Research Center, Taiwan (BCRC 910220), and the China Center for Type Culture Collection, China (M204012). GMNL-32 was provided by Gen Mont Biotech Inc., Tainan, Taiwan. GMNL-32 was diluted with PBS and 109 CFU/mouse per day by oral gavage.
Mice and diets
Female NZB/W F1 mice-an outstanding and commonly used lupus-prone mouse strain–was obtained from the animal center, National Taiwan University, Taiwan and housed in an animal room at 22 ±2°C with a 12/12 h light-dim cycle under supervision of the Institutional Animal Care. The diseased state of mice was determined by observing proteinuria with Albustix test strips every other week from the age of 12 weeks as previously described [17]. Animals were separated randomly into two groups (n = 10 each). Group I was the control group mice that were provided with oral saline solution and group II was orally administered with GMNL-32 (1 × 109CFU/mL per day). From the 8th week, SLE-developing mice (group II) were treated orally with GMNL-32, continuously up to the 20th week. After 3 weeks treatment, all rats were sacrificed by decapitation under terminal anaesthesia and hearts were collected. Heart tissues of the mice were obtained and stored at– 80°C until use.
Hematoxylin and eosin staining
The hearts of the test mice were removed, fixed in formalin, dehydrated by alcohol gradient (100%, 95%, and 75%) and were embedded in paraffin wax. The tissue squares were cut into 0.2 μm-thick slices and deparaffinized by submersion in xylene. The slices were stained with hematoxylin and eosin (H&E) and washed with water. Each slide was dried using an alcohol gradient and rinsed twice with xylene. Photomicrographs were acquired using a Zeiss Axiophot magnifying lens (Carl Zeiss Microscopy, Thornwood, NY, USA).
DAPI staining and TUNEL assay
For the terminal deoxynucleotidyltransferase2'-Deoxyuridine,5'-Triphosphate (dUTP)- nick end labeling (TUNEL) assay, the sections were treated with proteinase K, washed in PBS, incubated with permeabilization solution, followed by blocking buffer, and washed two times with PBS. The sections were then treated for 60 min at 37°C with terminal deoxynucleotidyl transferase and fluorescein isothiocyanate-dUTP from an apoptosis detection kit (Roche Applied Science, Indianapolis, IN, USA). Under light (excitation wavelength of 460 nm) and detection in the range of 515–565 nm, TUNEL-positive cells (divided DNA) were identified as brilliant green. The tissue sections were stained with 0.1 μg/mL 4, 6-diamidino-2-phenylindole (DAPI) for 5 min, and the cell nuclei were identified by UV light microscopy at 454 nm. Photomicrographs were acquired using a Zeiss Axio photo magnifying instrument.
Tissue protein extraction
Cardiovascular tissue concentrates of the mice were acquired by homogenizing the heart (100 mg/mL). The homogenates were put on ice and then centrifuged at 12,000 g for 40 min. The proteins in the supernatants were collected and stored at -80°C for further analyses.
Western blot
Protein concentrations of the heart tissue concentrates were determined by Lowry's protein assay. Proteins were separated by 12% SDS polyacrylamide gel electrophoresis (SDS-PAGE) with a consistent supply of 75 and were then transferred to a poly vinylidene difluoride (GE Healthcare Life Sciences, Pittsburgh, PA, USA) membrane using a 50 V current for 3h. The membrane was treated with 3% bovine serum albumin (BSA) in Tris-buffered saline solution followed by incubation with primary antibodies to particular proteins (Santa Cruz Biotechnology, Santa Cruz, CA, USA). Horseradish peroxidase-labeled secondary antibodies were used for detection, and pictures were taken with Fujifilm LAS-3000 (GE Health Mind Life Sciences).
Immunofluorescence
After the fixation, rehydration, and blocking of the slides, the primary antibody MMP9 was added for detection of the lysosomes in heart sections. After that, a goat anti-rabbit IgG secondary antibody, Alexa Fluor® 488 conjugate (A-11008, Thermo Fisher, USA), was used to detect the bound MMP9 primary antibody. The cell nuclei were stained with DAPI as the last step before mounting the sections. The pictures were acquired using an Immunofluorescence microscope (CKX53, Olympus, Tokyo, Japan).
Masson’s trichrome staining
Masson's trichrome recoloring the heart tissue from each gathering was put away in 10% formalin for 2 weeks, got dried out utilizing a alcohol gradient (75%, 85%, 90%, and 100% liquor, 5 min each) and inserted in paraffin wax. Paraffin sections that were 0.2 μm thick were then cut from these paraffin-installed tissue squares. The tissue areas were de-paraffinized by dipping in xylene (3 times, 5 min each) and rehydrated utilizing an alcohol gradient (100%, 90%, 85%, and 75% ethanol, 5 min each). Tissue sections were then stained utilizing Masson's trichrome stain to examine heart morphologic and fibrotic changes; blue staining indicated collagen thickening. The results were acquired using an OLYMPUS microscope.
Results
GMNL-32 induces weight gain in lupus-prone mice
GMNL-32 nourishing adequately instigated weight pick up in lupus inclined mice groups. The rate of weight pick up did not altogether contrast between NZB/W F1 control and GMNL-32 treated mice groups, but the whole heart weight was significantly increased in GMNL-32 treated animals compared to the NZB/W F1 mice. Left ventricular weight (LVW) and the proportions of entire heart weight to tibia length (WHW/Tibia) and left ventricular weight to tibia length (LVW/Tibia) in the GMNL-32 groups did not show much difference when compared to the SLE control group (Table 1).
GMNL-32 strain increases the ventricular wall thickness
Histopathological tomography analyses of whole heart tissues were performed using H&E staining (Fig 1). Images were viewed under a microscope. Fig 1A shows that the left ventricular wall thickness of the control SLE mice is smaller than that of the SLE + GMNL-32 mice, and the difference is statistically significant (Fig 1B). From the results of the above cross-section view, SLE + GMNL-32 tissue wall thickness is greater than the wall thickness of the SLE group.
A). left ventricular wall thickness measured by imagej software, B). left ventricular wall thickness significance. Values are Mean ± S.E., n = 10. * p< 0.05 represents significance when compared to NZB/W F1 mice group.
Cardiac histopathological changes and Fas Death receptor-related components in NZB/W F1 mice treated with GMNL-32
To explore whether the myocardial design and cardiovascular apoptosis were expanded in the hearts of NZB/W F1 mice treated with GMNL-32, a histopathological analysis of the left cardiac tissue was performed with hematoxylin and eosin staining and TUNEL assay. NZB/W F1 mice group exhibited a more abnormal architecture. In contrast, a less abnormal architecture was seen in the NZB/W F1 mice + GMNL-32 group compared to the NZB/W F1 mice group (Fig 2A). Additionally, NZB/W F1 hearts stained by TUNEL assay showed increased TUNEL-positive cardiac cells in the NZB/W F1 mice, whereas decreased TUNEL-positive nuclei were observed in the GMNL-32 group (Fig 2B). The average percentages of TUNEL-positive cardiac nuclei in the GMNL-32 groups were 9.91± 1.81 and 8.23± 0.93, (Fig 2C). To determine the Fas death receptor involved apoptosis in the hearts of NZB/WF1 mice, Western blotting was performed. The levels of TNF-R1, Fas receptors, and FADDs in the hearts of NZB/W F1 mice group were significantly increased (Fig 2D). In contrast, TNF-R1, Fas receptors, and FADDs were all found to be reduced in the GMNL-32 administered group (Fig 2D). The fold change in the ratios of the protein products of TNF-R1, Fas receptors, and FADDs relative to the internal control are shown in Fig 2E.
A). Histopathological analysis of tissue section slides stained by hematoxylin and eosin staining B). Recolored apoptotic cells of cardiovascular areas with TUNEL test in NZB/W F1 mice encouraged with supplementation. C).The rates of apoptotic cells were computed. The pictures of myocardial design were amplified 100 times. Protein products of TNF-R1, Fas, and FADD in the left ventricles of hearts from NZB/W F1 mice encouraged with GMNL-32 were measured by Western blotting investigation. α-tubulin filled in as an inward control. D).The relative protein evaluation of TNF-R1, Fas, and FADD on the premise of fold change. Bars exhibit the rate of TUNEL-positive cells relative to add up to cells (10 mice X10 scope field number in each gathering) and show mean esteems (SD ± * p< 0.05 represents significance when compared to NZB/W F1 mice group.
Changes in cell survival components in the hearts of NZB/W F1 mice treated with GMNL-32
To examine the variety of cardiovascular survival protein segments in the hearts of NZB/W F1 mice, the levels of PI3K, Bcl-xl, and Bcl2 were examined as shown in Fig 3. The levels of PI3K, Bcl-xl, and Bcl2 (Fig 3A) were significantly decreased in the hearts from the NZB/W F1 mice. In contrast, these protein levels were significantly increased in the NZB/W F1 + GMNL-32 group. The relative protein quantification expressed as fold change is show in Fig 3B.
A). Protein products of PI3K, Bcl-xl, and Bcl2 in the hearts from NZB/W F1 mice treated with GMNL-32 were measured by Western blotting analysis. α-tubulin filled in as an inside control. B). the relative protein quantification of PI3K, Bcl-xl, and Bcl2 on the basis of α –tubulin. * p< 0.05 represents significance when compared to NZB/W F1 mice group.
Change in cardiac fibrosis in the hearts of NZB/W F1 mice treated with GMNL-32
In the hearts of NZB/W F1 Mice, fibrosis proteins MMP-9 and Cox2 were examined by Western blotting (Fig 4). The protein levels of MMP-9 and Cox2 in NZB/W F1 mice were significantly increased, whereas in NZB/W F1 mice treated with GMNL-32, the levels of these proteins were decreased (Fig 4A). Transformation of cardiac fibroblasts into myofibroblasts is a critical event in the initiation of myocardial fibrosis. Further to detect the effects of GMNL-32 on the events associated with cardiac remodeling in NZB/W F1 mice, the level of MMP9 was determined by immune-fluorescence staining (Fig 4C). Elevated levels of MMP9 and CoX2 observed in NZB/W F1 mice group were found to be downregulated in the GMNL-32 treated group.
A). Protein products of MMP9 and COX2 in the hearts from NZB/W F1 mice treated with GMNL-32 were measured by Western blotting analysis. α-tubulin filled in as an inward control. B). the relative protein measurement of MMP9 and COX2 on the basis of α -tubulin. * p< 0.05 represents significance when compared to NZB/W F1 mice group.(B) Panel A shows the immunofluorescence images of MMP-2 in NZB/W F1 mice and GMNL-32 treatment.
Change in cardiac collagen accumulation in the hearts of NZB/W F1 Mice treated with GMNL-32
Cardiac tissue sections from the NZB/W F1 control mice and GMNL-32 treated mice NZB/W F1 mice were stained by Masson’s trichrome staining and the results showed that cardiac cellular arrangement was disordered, with noticeably high collagen accumulation (blue color) (Fig 5). Supplementation with GMNL-32 probiotics however, rescued the heart tissue as evident from the reduction in the collagen accumulation.
Masson trichrome staining shows fibrosis of hearts from NZB/W F1 mice treated with GMNL-32.
Discussion
Systemic lupus erythematosus is an immune system inflammatory illness influencing different organs and is characterized by aggressive inflammation and reduction in the life expectancy. Hereditary, hormonal, and natural elements creating chronic inflammation are considered as causes of SLE. In its course, the illness affects different organs, including the lungs, heart, kidneys, mind, fringe nerves and skin [35,36]. SLE has a female dominance (9:1) and has a prevalence of 15–50/100,000 people, with side effects generally showing up between the second and third decades of life [37]. Early mortality in SLE is ascribed to either renal failure because of uncontrolled disease or high vulnerability to infections, while late mortality is because of cardiac complications and hematological malignancies [38,39]. The effect of contaminations and high infection impact on mortality has decreased drastically in the most recent decades. Not with standing, cardiovascular disease (CVD) has emerged as an essential contributor to mortality [40], as has been proven by the high occurrence of myocardial localized necrosis in young women with SLE [40]. Our results reveal that there was a significant increase in body weight in NZB/W F1 mice groups treated with GMNL-32 however there was no significant change observed in the heart weight or the left ventricle weight. Body Weight loss is a well-known effect in patients with active SLE however weight gain may also be noticed in the patients due to corticosteroid treatment provided against inflammation[9]. In our SLE model, GMNL-32-treatment caused weight gain may reflect the reduction in the pathological effects of SLE either in the form of reduced autoimmunity or due to reduction in the mediators of inflammatory. Observation on increased ventricular mass in SLE patients has been associated with hypertension and modulation in LV are not observed in normotensive patients [41]. In our results there was no significant difference observed in the whole heart weight or the left ventricle weight.
CVD in SLE is thought to occur as the consequence of increase in the conventional risk factors of CVD along with disease progression. Concerning that, a systemic investigation and meta-analysis on 17,187 SLE patients for a subsequent time of eight years demonstrated that CVD events happened in 25.4% of the patients [36]. The pathological variations in the heart include histopathological changes, cellular apoptosis, and elevated fibrotic lesions in the heart tissue. In this study, L. paracasei strain GMNL-32 diminished apoptosis in the heart tissues of NZB/W F1 mice and potentially enhanced cardiac function. The finding gives some convincing insight into the probiotic potential of L. paracasei strain GMNL-32 and reveals the protective effect of GMNL-32 against cardiovascular apoptosis related in SLE.
Despite the fact that L. paracasei has been considered to be effective against various pathological conditions little is known about how the L. paracasei strain balances the immune system, atopic ailments and autoimmunity improvement. Presently, only limited studies are available characterizing the impacts of probiotics in murine or human models of atopy and autoimmunity. Therefore, it is essential to investigate the impact of probiotics in different trial and clinical atopic and immune system disease models [42–48]. The L. paracasei strain has been shown to deliver ideal probiotic impacts [29]. Past reviews have demonstrated that L. paracasei diminishes reactive oxygen species to protect against hepatocyte injury [33] and attenuates the production of pro-inflammatory cytokines [49,50]. The protective effects of L. paracasei in decreasing serum lipid, lipid oxidation and keeping the arrangement of the caspase-9 apoptosome [51] were previosuly reported. Another report demonstrated that L. paracasei lessens cardiovascular break down and apoptosis incited by Ca2+by means of decreasing MAPK and apoptotic signaling segments [52,53]. Altogether, decreased apoptotsis positive cells were distinguished in heart tissues of the GMNL-32 group compared to the NZB/W F1 mice. Both Fas-and mitochondria-dependent mediators such as TNF-R, Fas ligand, and FADD, were altogether diminished in heart tissues of the GMNL-32 treated mice groups when compared to the NZB/W F1 mice group. Additionally, reduced fibrosis and diminished fibrotic signaling molecules, such as MMP-9 and COX2, were seen in the heart tissues of the GMNL-32 group compared to the NZB/W F1 mice. Matrix metalloproteinase-9 (MMP-9) has been hypothesized with the pathogenesis of immune system infections including SLE. Different examinations have detailed that hoisted MMP-9 movement assumes urgent part being developed of SLE in both human and lupus-inclined mice. COX-2 is likewise known to assume crucial parts being developed of incendiary ailments and related with the pathogenesis of SLE. COX-2 and MMP-9 expression is managed by inflammation and a useful connection between COX-2 action and MMP-9 generation has been portrayed in various cell sorts, including endothelial cells, proposing COX-2 and related MMP-9 as vital helpful focuses for heart anomaly hindrance. Late reports have highlighted the mutual pathology of cardiovascular diseases and SLE, both of which speak to incendiary issue. A few reports have additionally given truly necessary understanding into the malicious effect that select treatments (counting cyclo-oxygenase-2-specific inhibitors) may have as far as the danger of cardiovascular illness in SLE [54]. Further MMP9 levels can be correlated with the level of collagen accumulation and risk of cardiac remodeling after cardiac injury [55]. Our results clearly show that GMNL-32 provide cardio–protective effects in SLE diminishing the pathways of cardiac apoptosis. The initiation of the PI3K/Akt pro-survival pathway plays an important role in cardio protection [56]. In the present review, the levels of survival protein expression were too low in NZB/W F1 mice, whereas L. paracasei strain GMNL-32 treatment in mice caused a change in the expression of these ACE and anti-apoptotic proteins, particularly Bcl-2, Bcl-xl. The PI3K/Akt flagging pathway may be involved in the regulation of the expression of antiapoptotic proteins in L. paracasei strain GMNL-32-treated mice. L. paracasei has been known to be effective in the treatment of organ disorders, particularly, against liver injury, and in cardio protection [33]. Nonetheless, L. paracasei GMNL-32 uncovers the effects on cardiovascular tissue by diminishing the histopathological changes, Fas-subordinate apoptosis, fibrosis, and fibrotic aggregations in the heart tissues of NZB/W F1 mice and also by expanding cardiovascular survival flagging segments in NZB/W F1 mice. These discoveries may provide significant information for understanding the cardiovascular protective function of L. paracasei GMNL-32 and suggest the capability of GMNL-32 in treating SLE patients with CVD.
Financial disclosure
This work is supported by Taiwan Ministry of Health and Welfare Clinical Trial and Research Center of Excellence (MOHW105-TDU-B-212-133019) and GenMont Biotech Incorporation, Taiwan. (1044EI). The funding organization provided support in the form of salaries for authors [Y-H.C] and research materials (L. paracasei GMNL-32), but did not have any additional role in the study design, data collection and analysis, decision to publish, or preparation of the manuscript. The specific roles of these authors are articulated in the ‘author contributions’ section.
References
- 1. Haque S, Bruce IN (2005) Therapy insight: systemic lupus erythematosus as a risk factor for cardiovascular disease. Nature Clinical Practice Cardiovascular Medicine 2: 423–430. pmid:16119705
- 2. Zeller CB, Appenzeller S (2008) Cardiovascular disease in systemic lupus erythematosus: the role of traditional and lupus related risk factors. Curr Cardiol Rev 4: 116–122. pmid:19936286
- 3. Huang CY, Hsu TC, Kuo WW, Liou YF, Lee SD, Ju DT, et al. (2015) The Root Extract of Gentiana macrophylla Pall. Alleviates Cardiac Apoptosis in Lupus Prone Mice. PLoS One 10: e0127440. pmid:25985203
- 4. Tincani A, Rebaioli CB, Taglietti M, Shoenfeld Y (2006) Heart involvement in systemic lupus erythematosus, anti-phospholipid syndrome and neonatal lupus. Rheumatology (Oxford) 45 Suppl 4: iv8–13.
- 5. Esdaile JM, Abrahamowicz M, Grodzicky T, Li Y, Panaritis C, du Berger R, et al. (2001) Traditional Framingham risk factors fail to fully account for accelerated atherosclerosis in systemic lupus erythematosus. Arthritis Rheum 44: 2331–2337. pmid:11665973
- 6. Manzi S, Meilahn EN, Rairie JE, Conte CG, Medsger TA Jr., Jansen-McWilliams L, et al. (1997) Age-specific incidence rates of myocardial infarction and angina in women with systemic lupus erythematosus: comparison with the Framingham Study. Am J Epidemiol 145: 408–415. pmid:9048514
- 7. Urowitz MB, Bookman AA, Koehler BE, Gordon DA, Smythe HA, Ogryzlo MA (1976) The bimodal mortality pattern of systemic lupus erythematosus. Am J Med 60: 221–225. pmid:1251849
- 8. Tzang BS, Lin TM, Tsai CC, Hsu JD, Yang LC, Hsu TC (2011) Increased cardiac injury in NZB/W F1 mice received antibody against human parvovirus B19 VP1 unique region protein. Mol Immunol 48: 1518–1524. pmid:21555155
- 9. Cojocaru M, Cojocaru IM, Silosi I, Vrabie CD (2011) Manifestations of systemic lupus erythematosus. Maedica (Buchar) 6: 330–336.
- 10. Zhao P, Sharma AC, Ren J (2009) Pathogenesis and therapy of autoimmunity-induced dilated cardiomyopathy. Front Biosci (Landmark Ed) 14: 1708–1715.
- 11. Jahns R, Boivin V, Schwarzbach V, Ertl G, Lohse MJ (2008) Pathological autoantibodies in cardiomyopathy. Autoimmunity 41: 454–461. pmid:18781471
- 12. Cani PD, Delzenne NM (2009) The role of the gut microbiota in energy metabolism and metabolic disease. Curr Pharm Des 15: 1546–1558. pmid:19442172
- 13. Kumar M, Babaei P, Ji B, Nielsen J (2016) Human gut microbiota and healthy aging: Recent developments and future prospective. Nutr Healthy Aging 4: 3–16. pmid:28035338
- 14. Wegielska I, Suliburska J (2016) The role of intestinal microbiota in the pathogenesis of metabolic diseases. Acta Sci Pol Technol Aliment 15: 201–211. pmid:28071010
- 15. Xu RY, Wan YP, Fang QY, Lu W, Cai W (2012) Supplementation with probiotics modifies gut flora and attenuates liver fat accumulation in rat nonalcoholic fatty liver disease model. J Clin Biochem Nutr 50: 72–77. pmid:22247604
- 16. MacGregor G, Smith AJ, Thakker B, Kinsella J (2002) Yoghurt biotherapy: contraindicated in immunosuppressed patients? Postgrad Med J 78: 366–367. pmid:12151695
- 17. Chuang L, Wu KG, Pai C, Hsieh PS, Tsai JJ, Yen JH, et al. (2007) Heat-killed cells of lactobacilli skew the immune response toward T helper 1 polarization in mouse splenocytes and dendritic cell-treated T cells. J Agric Food Chem 55: 11080–11086. pmid:18038979
- 18. Huang L, Duan C, Zhao Y, Gao L, Niu C, Xu J, et al. (2017) Reduction of Aflatoxin B1 Toxicity by Lactobacillus plantarum C88: A Potential Probiotic Strain Isolated from Chinese Traditional Fermented Food "Tofu". PLoS One 12: e0170109. pmid:28129335
- 19. Paiva AD, Fernandes KM, Dias RS, Rocha AS, de Oliveira LL, Neves CA, et al. (2012) Effects of the oral administration of viable and heat-killed Streptococcus bovis HC5 cells to pre-sensitized BALB/c mice. PLoS One 7: e48313. pmid:23144752
- 20. Ettinger G, Burton JP, Gloor GB, Reid G (2017) Lactobacillus rhamnosus GR-1 Attenuates Induction of Hypertrophy in Cardiomyocytes but Not through Secreted Protein MSP-1 (p75). PLoS One 12: e0168622. pmid:28085895
- 21. Mortaz E, Adcock IM, Ricciardolo FL, Varahram M, Jamaati H, Velayati AA, et al. (2015) Anti-Inflammatory Effects of Lactobacillus Rahmnosus and Bifidobacterium Breve on Cigarette Smoke Activated Human Macrophages. PLoS One 10: e0136455. pmid:26317628
- 22. Aoki-Yoshida A, Yamada K, Hachimura S, Sashihara T, Ikegami S, Shimizu M, et al. (2016) Enhancement of Oral Tolerance Induction in DO11.10 Mice by Lactobacillus gasseri OLL2809 via Increase of Effector Regulatory T Cells. PLoS One 11: e0158643. pmid:27472281
- 23. Dawood MA, Koshio S, Ishikawa M, Yokoyama S (2015) Effects of partial substitution of fish meal by soybean meal with or without heat-killed Lactobacillus plantarum (LP20) on growth performance, digestibility, and immune response of amberjack, Seriola dumerili juveniles. Biomed Res Int 2015: 514196. pmid:25705667
- 24. Wutzke KD, Berg D, Haffner D (2008) The metabolic fate of doubly stable isotope labelled heat-killed Lactobacillus johnsonii in humans. Eur J Clin Nutr 62: 197–202. pmid:17356556
- 25. Kadooka Y, Sato M, Imaizumi K, Ogawa A, Ikuyama K, Akai Y, et al. (2010) Regulation of abdominal adiposity by probiotics (Lactobacillus gasseri SBT2055) in adults with obese tendencies in a randomized controlled trial. Eur J Clin Nutr 64: 636–643. pmid:20216555
- 26. Toshimitsu T, Mochizuki J, Ikegami S, Itou H (2016) Identification of a Lactobacillus plantarum strain that ameliorates chronic inflammation and metabolic disorders in obese and type 2 diabetic mice. J Dairy Sci 99: 933–946. pmid:26686731
- 27. Andrade S, Borges N (2009) Effect of fermented milk containing Lactobacillus acidophilus and Bifidobacterium longum on plasma lipids of women with normal or moderately elevated cholesterol. J Dairy Res 76: 469–474. pmid:19825213
- 28. Portugal LR, Goncalves JL, Fernandes LR, Silva HP, Arantes RM, Nicoli JR, et al. (2006) Effect of Lactobacillus delbrueckii on cholesterol metabolism in germ-free mice and on atherogenesis in apolipoprotein E knock-out mice. Braz J Med Biol Res 39: 629–635. pmid:16648901
- 29. Fak F, Backhed F (2012) Lactobacillus reuteri prevents diet-induced obesity, but not atherosclerosis, in a strain dependent fashion in Apoe-/- mice. PLoS One 7: e46837. pmid:23056479
- 30. Wagner RD, Pierson C, Warner T, Dohnalek M, Hilty M, Balish E (2000) Probiotic effects of feeding heat-killed Lactobacillus acidophilus and Lactobacillus casei to Candida albicans-colonized immunodeficient mice. J Food Prot 63: 638–644. pmid:10826722
- 31. Wang Z, Klipfell E, Bennett BJ, Koeth R, Levison BS, Dugar B, et al. (2011) Gut flora metabolism of phosphatidylcholine promotes cardiovascular disease. Nature 472: 57–63. pmid:21475195
- 32. Liao PH, Kuo WW, Hsieh DJ, Yeh YL, Day CH, Chen YH, et al. (2016) Heat-killed Lactobacillus Reuteri GMNL-263 Prevents Epididymal Fat Accumulation and Cardiac Injury in High-Calorie Diet-Fed Rats. Int J Med Sci 13: 569–577. pmid:27499689
- 33. Ting WJ, Kuo WW, Hsieh DJ, Yeh YL, Day CH, Chen YH, et al. (2015) Heat Killed Lactobacillus reuteri GMNL-263 Reduces Fibrosis Effects on the Liver and Heart in High Fat Diet-Hamsters via TGF-beta Suppression. Int J Mol Sci 16: 25881–25896. pmid:26516851
- 34. Ting WJ, Kuo WW, Kuo CH, Yeh YL, Shen CY, Chen YH, et al. (2015) Supplementary heat-killed Lactobacillus reuteri GMNL-263 ameliorates hyperlipidaemic and cardiac apoptosis in high-fat diet-fed hamsters to maintain cardiovascular function. Br J Nutr 114: 706–712. pmid:26234728
- 35. Ansari A, Larson PH, Bates HD (1985) Cardiovascular manifestations of systemic lupus erythematosus: current perspective. Prog Cardiovasc Dis 27: 421–434. pmid:2860699
- 36. Ballocca F, D'Ascenzo F, Moretti C, Omede P, Cerrato E, Barbero U, et al. (2015) Predictors of cardiovascular events in patients with systemic lupus erythematosus (SLE): a systematic review and meta-analysis. Eur J Prev Cardiol 22: 1435–1441. pmid:25139772
- 37. Bernatsky S, Boivin JF, Joseph L, Manzi S, Ginzler E, Gladman DD, et al. (2006) Mortality in systemic lupus erythematosus. Arthritis Rheum 54: 2550–2557. pmid:16868977
- 38. Kosiewicz MM, Zirnheld AL, Alard P (2011) Gut microbiota, immunity, and disease: a complex relationship. Front Microbiol 2: 180. pmid:21922015
- 39. Ciou SY, Hsu CC, Kuo YH, Chao CY (2014) Effect of wild bitter gourd treatment on inflammatory responses in BALB/c mice with sepsis. Biomedicine (Taipei) 4: 17.
- 40. Tursi A, Brandimarte G, Papa A, Giglio A, Elisei W, Giorgetti GM, et al. (2010) Treatment of relapsing mild-to-moderate ulcerative colitis with the probiotic VSL#3 as adjunctive to a standard pharmaceutical treatment: a double-blind, randomized, placebo-controlled study. Am J Gastroenterol 105: 2218–2227. pmid:20517305
- 41. Winslow TM, Ossipov MA, Fazio GP, Foster E, Simonson JS, Schiller NB (1993) The left ventricle in systemic lupus erythematosus: initial observations and a five-year follow-up in a university medical center population. Am Heart J 125: 1117–1122. pmid:8465737
- 42. He B, Hoang TK, Wang T, Ferris M, Taylor CM, Tian X, et al. (2017) Resetting microbiota by Lactobacillus reuteri inhibits T reg deficiency-induced autoimmunity via adenosine A2A receptors. J Exp Med 214: 107–123. pmid:27994068
- 43. Ahl D, Liu H, Schreiber O, Roos S, Phillipson M, Holm L (2016) Lactobacillus reuteri increases mucus thickness and ameliorates dextran sulphate sodium-induced colitis in mice. Acta Physiol (Oxf) 217: 300–310.
- 44. Collins FL, Irwin R, Bierhalter H, Schepper J, Britton RA, Parameswaran N, et al. (2016) Lactobacillus reuteri 6475 Increases Bone Density in Intact Females Only under an Inflammatory Setting. PLoS One 11: e0153180. pmid:27058036
- 45. Gao C, Major A, Rendon D, Lugo M, Jackson V, Shi Z, et al. (2015) Histamine H2 Receptor-Mediated Suppression of Intestinal Inflammation by Probiotic Lactobacillus reuteri. MBio 6: e01358–01315. pmid:26670383
- 46. Gao K, Liu L, Dou X, Wang C, Liu J, Zhang W, et al. (2016) Doses Lactobacillus reuteri depend on adhesive ability to modulate the intestinal immune response and metabolism in mice challenged with lipopolysaccharide. Sci Rep 6: 28332. pmid:27323686
- 47. Lee J, Yang W, Hostetler A, Schultz N, Suckow MA, Stewart KL, et al. (2016) Characterization of the anti-inflammatory Lactobacillus reuteri BM36301 and its probiotic benefits on aged mice. BMC Microbiol 16: 69. pmid:27095067
- 48. Sun J, Qiao Y, Qi C, Jiang W, Xiao H, Shi Y, et al. (2016) High-fat-diet-induced obesity is associated with decreased antiinflammatory Lactobacillus reuteri sensitive to oxidative stress in mouse Peyer's patches. Nutrition 32: 265–272. pmid:26620713
- 49. Szkaradkiewicz AK, Stopa J, Karpinski TM (2014) Effect of oral administration involving a probiotic strain of Lactobacillus reuteri on pro-inflammatory cytokine response in patients with chronic periodontitis. Arch Immunol Ther Exp (Warsz) 62: 495–500.
- 50. Sydora BC, MacFarlane SM, Lupicki M, Dmytrash AL, Dieleman LA, Fedorak RN (2010) An imbalance in mucosal cytokine profile causes transient intestinal inflammation following an animal's first exposure to faecal bacteria and antigens. Clin Exp Immunol 161: 187–196. pmid:20345974
- 51. Takeuchi K, Motoda Y, Ito F (2006) Role of transcription factor activator protein 1 (AP1) in epidermal growth factor-mediated protection against apoptosis induced by a DNA-damaging agent. FEBS J 273: 3743–3755. pmid:16911523
- 52. Iyer C, Kosters A, Sethi G, Kunnumakkara AB, Aggarwal BB, Versalovic J (2008) Probiotic Lactobacillus reuteri promotes TNF-induced apoptosis in human myeloid leukemia-derived cells by modulation of NF-kappaB and MAPK signalling. Cell Microbiol 10: 1442–1452. pmid:18331465
- 53. Thomas CM, Hong T, van Pijkeren JP, Hemarajata P, Trinh DV, Hu W, et al. (2012) Histamine derived from probiotic Lactobacillus reuteri suppresses TNF via modulation of PKA and ERK signaling. PLoS One 7: e31951. pmid:22384111
- 54. McMahon M, Hahn BH, Skaggs BJ (2011) Systemic lupus erythematosus and cardiovascular disease: prediction and potential for therapeutic intervention. Expert Rev Clin Immunol 7: 227–241. pmid:21426260
- 55. Phatharajaree W, Phrommintikul A, Chattipakorn N (2007) Matrix metalloproteinases and myocardial infarction. Can J Cardiol 23: 727–733. pmid:17622396
- 56. Dhanasekaran A, Gruenloh SK, Buonaccorsi JN, Zhang R, Gross GJ, Falck JR, et al. (2008) Multiple antiapoptotic targets of the PI3K/Akt survival pathway are activated by epoxyeicosatrienoic acids to protect cardiomyocytes from hypoxia/anoxia. Am J Physiol Heart Circ Physiol 294: H724–735. pmid:18055514