SERUM ADIPONECTIN AND IRISIN LEVELS IN OVARIECTOMIZED OSTEOPOROTIC RAT MODEL

Document Type : Original Article

Authors

Department of Physiology, Faculty of Medicine, Zagazig University

Abstract

Background: Post-menopausal osteoporosis (PMOP) is the most common bone disease in females characterized by decreased bone mineral density (BMD). However, the exact pathogenesis remains unclear.
Objective: Investigating the relationship between serum levels of adiponectin and irisin, and their relation to BMD in ovariectomy induced osteoporosis rat model.
Material and Methods: Three equal groups of adult female albino rats (n=15) were used; i.e. control, sham operated and ovariectomized (OVX) groups. Nine weeks after ovariectomy, serum analysis of adiponectin, irisin, FSH, estradiol, Ca++, phosphorus (P), alkaline phosphatase (ALP), glucose, and insulin were estimated. Final BMI and HOMA-IR were calculated. Bone BMD measurements (dry and ash femur weight, bone Ca++ and P together with femur histopathological examination) were done.
Results: In OVX osteoporotic rat model, while serum levels of adiponectin significantly elevated and negatively correlated with BMD, serum irisin levels significantly reduced, and showed significant positive correlation with BMD. Changes in OVX adiponectin and irisin levels were significantly associated with the elevated insulin resistance. However, they were not association with FSH or estradiol levels.
Conclusion: OVX induced osteoporosis was associated with a significant increase in adiponectin levels, and decrease in irisin levels which are associated with changes in insulin resistance rather than sex hormones. It can be hypothesized that the exact causative of PMOP extends beyond pituitary; ovarian axis to be metabolic, muscle and adiposity cross talks which needs more detailed investigations.

Keywords


SERUM ADIPONECTIN AND IRISIN LEVELS IN OVARIECTOMIZED OSTEOPOROTIC RAT MODEL

 

By

 

Abeer A. Khalefa and Nadine A. Raafat

Department of Physiology, Faculty of Medicine, Zagazig University

 

ABSTRACT

Background: Post-menopausal osteoporosis (PMOP) is the most common bone disease in females characterized by decreased bone mineral density (BMD). However, the exact pathogenesis remains unclear.

Objective: Investigating the relationship between serum levels of adiponectin and irisin, and their relation to BMD in ovariectomy induced osteoporosis rat model.

Material and Methods: Three equal groups of adult female albino rats (n=15) were used; i.e. control, sham operated and ovariectomized (OVX) groups. Nine weeks after ovariectomy, serum analysis of adiponectin, irisin, FSH, estradiol, Ca++, phosphorus (P), alkaline phosphatase (ALP), glucose, and insulin were estimated. Final BMI and HOMA-IR were calculated. Bone BMD measurements (dry and ash femur weight, bone Ca++ and P together with femur histopathological examination) were done.

Results: In OVX osteoporotic rat model, while serum levels of adiponectin significantly elevated and negatively correlated with BMD, serum irisin levels significantly reduced, and showed significant positive correlation with BMD. Changes in OVX adiponectin and irisin levels were significantly associated with the elevated insulin resistance. However, they were not association with FSH or estradiol levels.

Conclusion: OVX induced osteoporosis was associated with a significant increase in adiponectin levels, and decrease in irisin levels which are associated with changes in insulin resistance rather than sex hormones. It can be hypothesized that the exact causative of PMOP extends beyond pituitary; ovarian axis to be metabolic, muscle and adiposity cross talks which needs more detailed investigations.

Key words: Ovariectomy, osteoporosis, adiponectin, irisin, rats.

 

 

INTRODUCTION

     Osteoporosis is one of senile degenera-tive diseases affects more than 200 million individuals worldwide. It is a growing major public health problem that characterized by reduction of the bone mineral density (BMD), disruption of the bone micro-architecture that increases the possibility of fractures and osteo-pathology (Aaseth et al., 2012, Appelman-Dijkstra & Papapoulos 2014, Emkey & Epstein, 2014, Xin et al., 2014, and Iliou et al., 2015). Postmenopausal osteoporosis (PMOP) is recognized to be secondary to alterations in the pituitary-bone axis, whereas postmenopausal reduced estrogen is claimed as the main pathogenesis (Seibel et al., 2006).

     Adipose tissue secretes a variety of biologically active molecules which are named adipocytokines (won Muhlen et al., 2007). This may regulate bone metabolism and be involved in osteoporosis pathophysiology. Cumulative evidence has shown that there is an association between BMD and fat mass (Ho-Pham et al., 2014 and Mohiti-Ardekani et al., 2014)

    Adiponectin is one of the adipocyto-kines, highly expressed in visceral and bone marrow fat deposits and abundantly present in plasma (Araneta et al., 2009). So, it has been proposed to share in the regulation of energy homeostasis and insulin sensitivity (Williams et al., 2009 and Jiang et al., 2011). Previous studies have shown crosstalk between adiponectin and bone metabolism (Kanazawa et al., 2007 and Mohiti-Ardekani et al., 2014).

     Richards et al. (2007) have demons-trated that adiponectin exerts an indepen-dent negative effect on BMD. However; other investigators have shown that there was no independent relationship between adiponectin and BMD (Basurto et al., 2009). 

     Adiponectin is significantly associated with BMD at total body, lumbar spine, total hip, and total forearm in post-menopausal women. This association is not related to fat mass or other hormonal factors studied (Zhang et al., 2010). Therefore, it was suggested that adipo-nectin is an independent predictor of BMD in post-menopausal women (Zhang et al., 2010 and Tohidi et al., 2012). Moreover, Mohiti-Ardekani et al. (2014) showed that serum adiponectin had a significant negative correlation with BMD of the femoral neck and lumbar spine in osteoporotic patients.

    It has been widely shown that increased muscle mass, measured as lean body mass, is related to increased BMD and a reduction in vertebral fracture risk. In addition, brown adipose tissue volume is known to be a positive predictor of femoral bone structure and correlates positively with thigh muscle suggesting that sarcopenia is related to osteoporosis (Kaji, 2013 and Bredella et al., 2014). Irisin is a myokine and adipokine induced in exercise and stimulates adipose tissue browning (Boström et al., 2012 and Roca-Rivada et al., 2013).

     The circulating irisin levels have been associated with the incidence fractures in postmenopausal women with low bone mass (Anastasilakis et al., 2014). Also, Palermo et al. (2015) have confirmed an inverse correlation between irisin levels and vertebral fragility fractures in postmenopausal women, but no significant correlation was found with BMD or lean mass. Furthermore, it has been shown that irisin enhances the differentiation of bone marrow stromal cells into osteoblasts in vitro (Colaianni et al., 2014).

     The present study aimed to evaluate serum levels of adiponectin and irisin in postmenopausal osteoporosis rat model (OVX), and investigate whether serum adiponectin and/or irisin levels were associated with BMD and bone turnover biochemical markers or not.

MATERIALS AND METHODS

Animals: Forty five healthy adult female albino wistar rats weighing 198 ± 8.5gm were obtained from the animal house in Faculty of Veterinary Medicine, Zagazig University. Animals were kept in nine steel wire cages (40 x 28 x18 Cm. 5 rats /cage) under hygienic conditions w in animal house of Faculty of Medicine, Zagazig University. All animals received care in accordance with the guide to the care and use of experimental animals of Institute of Laboratory Animal Resources (1996). The experimental protocol was approved by the Institutional Review Board and research ethics committee of Faculty of Medicine, Zagazig University (IRB). Animals were fed standard chow and had free access to water. The rats were accommodated to animal house conditions for one week before the experiments going on.Rats were divided randomly into three equal groups, control sham operated and OVX groups.

Rat model of osteoporosis

     Bilateral ovariectomy and sham ovari-ectomy were done according to the methods of Nishizawa et al. (2002) and Gui et al. (2004).

     At the end of experiments (Nine weeks after ovariectomy), rats were weighed, and BMI were calculated according to the equation: body weight (gm)/length2 (nose to anus length) (cm2) (Novelli et al., 2008), and then blood and tissue samples were obtained.

Blood sampling: All animals were fasted overnight, anesthetized by diethyl ether; blood was collected from retro-orbital venous plexus and allowed to clot for 2 hours at room temperature before serum was separated by centrifugation of clotted blood at 3000 rpm for 20 minutes. The separated serum was stored at -80° C until used for further analysis.

    Rats were sacrificed by cervical dis-location and then both femurs were obtained.

Serum was analyzed for irisin levels according to Boström et al. (2012) using rat irisin ELISA rat kit (Catalog # K4761-100), biovision, Milpitas Blvd., Milpitas, CA 95035 USA, Adiponectin levels according to Arita et al. (1999) using rat Adiponectin ELISA rat kit (Cat. # EZRADP-61K), Follicle stimulating hormone (FSH), Estradiol (E2), and Progesterone (PROG) according to the method of Tietz  (1995) using ELISA rat kits: BC-1029 and BC-1115, respectively, BioCheck Inc 323 Vintage Park Dr. Foster City, CA 94404, serum glucose level according to Tietz (1995) using glucose enzymatic- liquizyme rat kits (Biotechno-logy, Egypt), insulin level according to Temple et al. (1992) using KAP1251-INS-EASIA rat Kits (BioSource Europe S.A., Belgium). Homeostatic model assessment of insulin resistance index (HOMA-IR) based on serum insulin level (μIU/ml) and serum glucose level (mg/dl) was calculated according to the formula described by Matthews et al. (1985): HOMA- IR = fasting serum glucose (mg/dl) X fasting serum insulin (μIU/ml) /405, serum calcium (Ca++) levels by colorimetric method according to Gindler et al. (1972) using kits supplied by Bio-diagnostic Co. (Cairo, Egypt), serum phosphorus (P) levels by colorimetric method according to Goldenberg, (1966) using kits supplied by Bio-diagnostic Co. (Cairo, Egypt), and serum alkaline phosphates (ALP) levels according to Belfied and Goldberg (1971).

Bone density was determinedaccording to Doster et al. (1969). Calcium and phosphorus levels in bones were detected by colorimetric methods using spectronic 21 according to Garcia-Contreras et al. (2000).

Bone histolopathological examination:

     Left femur was dissected from each rat, fixed and placed in 10% formaline solution for one day (Raab et al., 1991). Tissues were processed in ascending grades of alcohol, cleaned in xylol and embedded in paraffin blocks. Four microns sections were cut on a standard rotatory microtome and stained by Heamatoxylin and Eosin (H and E) stain as described by Bancroft and Cook (1984).

Statistical analysis: Results were presented as mean ± standard deviation (SD). Statistical analysis was performed using the Statistical Package for the Social Sciences (SPSS), version 20.0 (SPSS Inc., Chicago, IL, United States). Repeated measures of analysis of variance (ANOVA) were applied followed by the Stude nt-least significant deference (LSD), post hoc test to compare means of each two different groups. Pearson's correlation analysis was performed to screen potential relations between serum levels of adiponectin and irisin and all measured parameters. For all statistical tests done, P value < 0.05 was considered to be statistically significant.

RESULTS

     No significant difference was detected between sham operated group and negative control group in all parameters measured (P>0.05). OVX group showed significant elevation of the mean values of serum levels of adiponectin (12.14±2.32 n/mL), FSH (8.63±1.00 mIU/ml) and alkaline phosphatase "ALP" (179.19± 9.62Im/ L) in comparison to those of sham operated group (10.82±1.32, 5.02±0.70 and 142.56±7.38 respectively) (P<0.05, P<0.001 and P<0.001 respec-tively). Serum levels of irisin (0.75±0.15 μg/ml) and estradiol (14.36 ±2.11 pg/ml) in OVX group were significantly lower when compared to that of sham operated group (1.42±0.17 and 26.29±4.61 mg/dL respectively) (P<0.001). Moreover, among the three studied groups, serum levels of Ca++ (10.51± 0.38, 10.52±0.37 and 10.21± 0.51 respectively) and P (5.39±0.68, 5.37± 0.71 and 5.09±0.77 mg/dL, respectively) showed non-significant difference (P>0.05- Table 1).

     No significant difference could be detected between sham operated group and negative control group in all parameters measured (P>0.05). OVX group revealed significant increase in the mean values of BMI (0.64±0.56 gm/Cm2), serum insulin (13.59±2.05 mIU/mL) and calculated HOMA-IR (5.03± 0.63) when compared to those of sham operated group (0.49±0.02gm/Cm2, 7.87±1.36,mIU/mL, 2.13± 0.25 respectively) (P< 0.001, P<0.001 and P<0.01 respectively). However, BMD parameters of OVX group were significantly lower (dry weight 334.87±43.64, mg/femur, ash weight 203.13±29.06, mg/femur, bone Ca++ 91.28±8.4 mg/femur and bone P 31.54±1.93 mg/femur) than those of sham operated group (504.86±40.06mg/femur, 309.8±37.03 mg/femur, 146.24±11.89 mg/ femur, 39.48±4.47 mg/femur respectively) (P<0.001). However, serum glucose levels (mg/dL) did not show any significant changes among the three studied groups (76.32±8.33, 74.19±9.61 and 81.32±9.66 respectively) (P>0.05- Table 2).

   Pearson's correlation analysis between both of serum adiponectin and serum irisin with the measured parameters in OVX group (table 3) showed a significant negative correlation between the serum adiponectin levels and BMI (r = -0.616, P=0.009), insulin (r = -0.639, P=0.007), HOMA-IR (-0.701, P=0.001), serum ALP (r= -0.773, P<0.001) (Table 3). Dry femur weight was r = -0.981 (P<0.001), ash femur weight was r = -0.703 (P<0.001) (figure 1A), bone Ca++ was r= -0.694 (P = 0.001) and bone P (r = -0.893 (P<0.001) (figure 1B). However, no significant association, could be detected between serum adiponectin and serum FSH
(r = 0.395, P=0.054) or serum estradiol
(r = 0.358, P=0.058), while serum irisin showed significant negative correlation with BMI (r= -0.653, P=0.004), serum insulin (r= -0.676, P=0.001) and HOMA-IR (r= -0.733, P=0.001), it revealed significant positive correlation with serum ALP (r= 0.901, P< 0.001), dry femur weight (r= 0.982, P<0.001), ash femur weight ( r= 0.863, P<0.001) (figure 2A), bone Ca++ (r = 0.826, P<0.001) and bone P (r= 0.875, P<0.001) (figure 2B).  However, no significant association, could be detected between serum irisin and serum FSH (r= 0.383, P=0.059) or serum estradiol (r= 0.372, P=0.055).

Histopathological examination:

    The photomicrographs of control and sham operated groups showed normal compact bone tissues with normal haversian system, the haversian canal surrounded by normal osteoblasts (Figure 3 and 4). The OVX groups showing thin atrophic bone trabeculae with wide marrow spaces (Figure 5).

 

 

Table (1): Statistical analysis of serum levels of irisin (μg/ml), adiponectin (ng/ml), FSH (mIU/ml), E2 (pg/ml), Ca++ (mg/dL), P (mg/dL), and ALP activity (Iu/ L) in the three studied groups.

Groups

Parameters

Control

Sham operated

OVX

Adiponectin (ng/ml)

10.84±1.36

10.82±1.32, P= 0.97a

12.14±2.32, P= 0.046 a,P=0.043b

Irisin  (μg/ml)

1.41±0.16

1.42±0.17, P= 0.91a

0.75±0.15, P<0.001 a,b

FSH (mIU/ml)

5.03±0.74

5.02±0.70, P= 0.99a

8.63±1.00, P<0.001a,b

Estradiol (pg/ml)

27.29±4.88

26.29 ±4.61, P= 0.92a

14.36±2.11,P<0.001a,b

Ca++ (mg/dL)

10.51± 0.38

10.52±0.37, P= 0.99a

10.21±0.51, P= 0.59a, P = 0.060b

P (mg/dL)

5.39±0.68

5.37 ± 0.71, P= 0.92a

5.09±0.77, P= 0.25a, P = 0.29b

ALP (Im/ L)

143.44±7.39

142.56±7.38, P= 0.96a

179.19± 9.62, P<0.001 a,b

a = p value of significance versus control, b = p value of significance versus sham operated group.

 

Table (2): Statistical analysis of calculated BMI (gm/Cm2), serum glucose (mg/dL), serum insulin (mIU/mL) and calculated HOMA-IR and bone mineral density (BMD) parameters in the three studied groups.

Groups

 

Parameters

Control

Sham operated

OVX

BMI (gm/Cm2)

0.48±0.02

0.49±0.02 P= 0.62a

0.64±0.56, P=0.000 a,b

Glucose (mg/dL)

76.32±8.33

74.19±9.61, P= 0.73a

81.32±9.66, P= 0.55a,b

Insulin (mIU/mL)

8.07±1.19

7.87±1.36 , P= 0.32a

13.59±2.05, P=0.001 a,b

HOMA-IR

2.02± 0.13

2.13± 0.25 , P= 0.54a

5.03± 0.63, P= 0.01 a,b

Dry wt (mg/femur)

510.80±39.00

504.86±40.06, P= 0.69a

334.87±43.64, P<0.001 a,b

Ash wt (mg/femur)

310.00±36.0

309.8±37.03, P= 0.80a

203.13±29.06, P<0.001 a,b

Bone Ca++ (mg/femur)

147.83±10.59

146.24±11.89, P= 0.68a

91.28±8.4, P<0.001 a,b

Bone P (mg/femur)

40.67±3.54

39.48±4.47, P= 0.35a

31.54±1.93, P<0.001 a,b

a = p value of significance versus negative control, b = p value of significance versus sham operated group, P< 0.05 is considered significant.

Table (3): Pearson's correlation analysis between serum adiponectin (ng/ml) and serum irisin (μg/ml) levels with calculated BMI (gm/Cm2), serum insulin (mIU/mL), calculated HOM A-IR, serum FSH (mIU/ml), serum E2 (pg/ml), Serum ALP (Im/ L), dry weight (mg/femur), ash weight (mg/femur), bone Ca++ (mg/femur), bone Phosphorus (P) (mg/femur) in OVX group.

Sera

Parameters

Adeponectin (ng/ml)

Irisin (μg/ml)

r

P

r

P

BMI (gm/Cm2)

-0.616

P= 0.009

-0.653

P= 0.004

Insulin (mIU/mL)

-0.639

P= 0.007

-0.687

P= 0.001

HOMA-IR

-0.701

P= 0.001

-0.733

P<0.01

FSH (mIU/ml)

0.395

P= 0.054

0.383

P= 0.059

E2 (pg/ml)

-0.358

P= 0.058

-0.372

P= 0.055

Serum ALP (Im/ L)

-0.773

P< 0.001

0.901

P<0.001

Dry weight (mg/femur)

-0.981

P<0.001

0.982

P<0.001

Ash weight (mg/femur)

-0.703

P<0.001

0.863

P<0.001

Bone Ca++ (mg/femur)

-0.694

P<0.001

0.826

P<0.001

Bone P (mg/femur)

-0.893

P<0.001

0.875

P<0.001

 

 

               
         
 
 

Figure (1A): Pearson's correlation analysis between both of dry femur weight (mg/femur) and ash femur weight (mg/femur) with serum adiponectin levels (ng/ml) in OVX group.

 
 

Figure (1B): Pearson's correlation analysis between both of bone calcium content (mg/femur) and bone phosphorus content (mg/femur) with serum adiponectin levels (ng/ml) in OVX group.

 
 
 

 

 

 

 

 

 

 

 

 

 

 


         

 

 

 

       
     
   
 
 

 

 

 


      

 

 

 

 

 

 

 

 

 

 

       
       
 

 

 

 

 

 

 

 

 


      

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 


DISCUSSION

     In the present results, the statistical comparison between shame operated and control groups revealed no significant difference in all studied parameters. The present study revealed that BMD decreased in OVX group in the form of a significant decrease in the mean values of femur dry weight, ash weight and calcium and phosphorus contents of bony ashes accompanied by a significant increase in serum alkaline phosphatase activity in comparison with that of the control and sham operated groups, These diagnostic criteria of decrease in BMD are in line with the results of OVX rat model of osteoporosis done by Griffith et al. (2010) and Ce et al. (2014a).

     Serum FSH levels were significantly increased, while estradiol significantly decreased in OVX rats compared with that of sham operated group and a significant negative correlation between FSH serum levels with BMD parameters was noted. These results come in accordance with previous studies of Gallagher et al. (2010), Cheung et al. (2011), and Garcia-Martin et al. (2012) who reported that serum FSH levels were significantly increased and negatively correlated with BMD in PMOP independently of estrogen. In addition Wang et al. (2015) concluded that FSH may play an important role in the acceleration of bone loss in postmenopausal women and increase osteoclastogenesis in vitro. Sun et al. (2006) proved t hat female mice lacking either FSHβ or the FSH receptor were resistant to bone loss despite hypogonadism. Sowers et al. (2013) and Imai (2014) also stated that the rate of bone mass loss during perimenopause is greater than that in postmenopause, whereas estrogen serum levels during perimenopause are normal (Sowers et al., 2006). However, inconsistentstudies of Seibel et al. (2006), Ritter et al. (2008) and Gourlay et al. (2012) indicated that FSH does not appear to modulate bone mass regulation in vivo and does not act directly on osteoclastogenesis in vitro.

    Rouach et al. (2011) reported thatestrogen deficiency is the dominant cause of bone loss in OVX rats, but FSH may be closely related to hypogonadal bone loss. Liu et al. (2010a &b) found that FSH can aggravate alveolar bone loss by FSH receptor activation independently of estrogen. In addition, FSH inhibitors prevent bone loss in ovariectomized rats. However, the etiology of postmenopausal osteoporosis extends beyond pituitary and ovarian sex hormones.

     Current results showed a significant elevation in serum levels of adiponectin in OVX rats in comparison to control and sham operated groups. Moreover, these elevated level of adiponectin showed significant negative correlation with BMI, insulin levels and HOMA-IR. However, it failed to be correlated with FSH or estradiol. The present finding was in line with the results of Ce et al. (2014b) who proved an increase in serum adiponectin and visceral adiposity in OVX rats. The significant increase in serum adiponectin levels could be explained by a physiological response to preserve systemic insulin sensitivity (Ainslie et al., 2001), as ovariectomy in the present study was accompanied by significant elevation in HOMA-IR (decrease in insulin sensitivity). In the same context Saengsirisuwan et al. (2009) reported metabolic alterations mimicking features of the insulin resistance syndrome in ovariectomy rats.

     Siri and Ginsberg(2003) reported significant increase in insulin resistance in human after ovariectomy, Moreover, Prasannarong et al. (2012) stated thatprolonged ovariectomy resulted in dyslipidemia, impaired glucose tolerance and reduced insulin-stimulated skeletal muscle glucose transport. It has also been reported that adiponectin levels were significantly higher in late postmeno-pausal women (Moorthy et al., 2004). Interestingly, estrogen treatment after ovariectomy protects against fatty liver and may improve pathway selective insulin resistance (Zhu et al., 2013), and is able to attenuate the increase of serum adiponectin levels in OVX rats (Ce et al., 2014b). However, no significant association between adiponectin levels and the elevated serum levels FSH or decreased serum levels of estradiol could be detected the present work.

     Regarding the association between adiponectin and BMD, the present research found significant negative correlation between the elevated serum adiponectin levels and decreased BMD parameters in OVX group, and these data were consistent with those of Mohiti-Ardekani et al. (2014) and Mpalaris et al. (2016) who found that serum adiponectin level was high in osteoporosis and negatively correlated with lumbar and femur BMD. While more studies showed a negative correlation between adiponec-tin and BMD (Richards et al., 2007, Ealey et al., 2008, Pang et al., 2008, Zhang et al., 2010 and Tohidi et al., 2012), some researcher reported no correlation or positive correlations (Zhong et al., 2005 and Parm et al., 2011).

      The negative association between adiponectin and BMD in osteoporosis could be an indicator for bone resorption activity. Berner et al. (2004) proved the presence of adiponectin receptor on osteoblasts. Also, Luo et al. (2006) showed that adiponectin enhances the receptor activator of nuclear factor- kappa Bligand (RANKL) expression so, indirectly increasing osteoclast formation and inhibiting osteoprotegerin (OPG) production in osteoblasts. OPG prevents RANKL from binding to receptor activator of nuclear factor kappa B (RANK) and results in the suppression of osteoclastogenesis (Secchiero et al., 2006).

     Adiponectin could be considered as one of the body responses to increased bone resorption induced by insulin resistance. Insulin is an anabolic hormone, which acts on bone through insulin receptors (IRs) expressed by osteoblasts IRS-1 and IRs-2 (insulin-like substrate). Stimulation of IRs-1 affects bone turnover, while stimulation of IRs-2 shifts the balance towards resorption. Insulin stimulates osteoblast proliferation, promotes collagen synthesis, and increases glucose uptake (Nyman et al., 2011).

     In T2DM, hyperinsulinism coupled with insulin resistance has a negative effect on BMD (Räkel et al., 2008, Arikan et al., 2012 and Hamann et al., 2012). The mirror image of adiponectin levels and HOMA-IRhas been proved in human,monkey, and rodents that adiponectin is an insulin-sensitizinghormone (Kubota et al., 2006 and Nway etal., 2016). In support with the hyposthesis of compensatory role of adiponectin is the study of Williams et al. (2009) who reported that adiponectin enhances human osteoblast proliferation and differentiation (osteoblastogenesis) in cultured osteoblasts. Furthermore, the introduction of recombinant adiponectin to human osteoblasts has been demons-trated to induce osteoblast formation, as well as stimulate the osteoclast RANKL pathway, while inhibiting its decoy receptor OPG. Thus, adiponectin may be exerting its effect on bone metabolism through the RANKL pathway in osteoporosis (Atalay et al., 2012; Ochoa et al., 2012 and Mohiti-Ardekani et al., 2014).

     Kajimura et al. (2013) reported that adiponectin has the unusual ability of being able to regulate the same function in two opposite manners depending on where it acts and what it opposes. Shinoda et al. (2006) suggested that circulating adiponectin induces a positive action through the indirect pathway via enhancement of the insulin signaling and a negative action through the direct pathway.

     Regarding serum irisin levels in OVX rats, it was significantly lower as com-pared with that of sham operated and control groups and negatively correlated with BMI and HOMA-IR. However, no significant association between serum irisin levels and FSH or estradiol levels could be detected. Our results were confirmed by Anastasilakis et al. (2014) who have shown lower serum irisin levels in postmenopausal women with previous osteoporotic fractures. Aubertin-Leheudre et al. (2008) speculated that low irisin levels may result from sarcopenic (muscle weakness) obesity and decreased muscle strength.  Moreno-Navarrete et al. (2013) stated that FNDC5 (fibronectin [type 3] domain-containing [protein] 5) gene expression in muscle significantly decreased in association with T2DM obese participants. Thus, circulating irisin levels were negatively associated with obesity and insulin resistance. Further-more, Li et al. (2015) proved that metformin which is known by improving insulin sensitivity, up-regulated intracellular FDNC5 mRNA/protein expression and promoted irisin release.

    There was a significant positive correla-tion between irisin serum levels and dry femur weight, ash femur weight and bone Ca++ level(BMD parameters). This result was in agreement with that of Singhal et al. (2014) who found a significant positive correlation between irisin levels and some bone quality parameters (volumetric bone mineral density, stiffness and failure load) measured by high resolution peripheral quantitative CT and finite element analysis. Moreover, Gao et al. (2016) found a positive correlation between serum irisin levels and bone mineral density in the control group, and a negative correlation in the polycystic ovary group after BMI and age adjusted.In addition, Colaianni et al. (2015) observed significant increases in cortical bone mass and strength of male mice bone after injection with recombinant irisin. Üstün et al. (2016) stated that postmeno-pausal osteoporosis was associated with decreased levels of circulating irisinand chemerin. Palermo et al. (2015) also detected an inverse correlation between irisin levels and vertebral fragility fractures. However; they failed to found any significant correlation with BMD, lean massor daily physical activity.

     In vitro, studyof Zhang et al. (2013) revealed that irisin increased bone trabecular density and cortical thickness in mice by activating osteoblasts differentia-tion via the Wnt/β-catenin pathway in osteoblastic MC3T3-E1 cells.In addition, irisin inhibits osteoclast differentiation via suppression RANKL/nuclear factor of activated T cells (Kawao and Kaji, 2015).

     Also, Colaianni et al. (2014) proved thatirisin directly targets osteoblast enhancing their proliferation and differentiation.In continuation, Colaianni  and Grano (2015) reported that irisin exerts its effect on osteoblast lineage by enhancing differentiation and activity of bone-forming cells through the increase in activating expression of transcription factor 4. Moreover, irisin increases the expression of osteoblastic transcription regulators such as Runt-related transcription factor-2, osterix/sp7; and osteoblast differentiation markers, including alkaline phosphatase, collagen type 1 alpha-1, osteocalcin, and osteopontin. It also increases ALP activity and calcium deposition in cultured osteoblast (Qiao et al., 2016).

CONCLUSION

    Ovariectomy induced osteoporosis is associated with a significant increase in serum levels of adiponectin and decrease in serum levels of irisin. While serum levels of adiponectin were negatively associated with BMD, serum irisin levels showed a significant positive correlation with BMD. These changes in serum adiponectin and irisin levels may be related to metabolic rather than sex hormones disturbance. It can be hypothesized that the exact causative of postmenopausal osteoporosis extends beyond pituitary and ovarian sex hormones to be metabolic, muscle and adipose tissue cross talks which need more detailed investigations.

ACKNOWLEDGMENT

    To Prof. Kamal Eleshishi, Pathology Department, Faculty of Medicine, Zagazig University for performing the histological study, and to Prof. Somiaa Hassan Biochemistry Department Faculty of Medicine, Zagazig University for performing the laboratory tests.

REFERENCES

1. Aaseth J, Boivin G and Andersen O (2012): Osteoporosis and trace elements an overview, J. Trace Elem. Med. Biol., 26 (2): 149–152.

2. Ainslie DA, Morris MJ and Wittert G (2001): Estrogen deficiency causes central leptin insensitivity and increased hypothalamic neuropeptide Y. Int J Obes., 25(11): 1680-1688.

3. Anastasilakis AD, Polyzos SA, Makras P, Gkiomisi A, Filippaios A and Mantzoros CS (2014): Circulating irisin is associated with osteoporotic fractures in postmenopausal women with low bone mass but is not affected by either teriparatide or denosumab treatment for 3 months. Osteoporos Int., 25:1633–1642.

4. Appelman-Dijkstra NM and Papapoulos SE (2014): Novel approaches to the treatment of osteoporosis. Best Pract. Res. Clin. Endocrinol. Metab., 28 (6):843–857.

5. Araneta MR, von Muhlen D and Barrett-Connor E (2009): Sex differences in the association between adiponectin and BMD, bone loss, and fractures: the Rancho Bernardo study. J Bone Miner Res., 24:2016–2022.

6. Arikan S, Tuzcu A, Bahceci M, Ozmen S and Gokalp D (2012): Insulin resistance in type 2 diabetes mellitus may be related to bone mineral density. Journal of Clinical Densitometry, 15 (2):186–190.

7. Arita Y, Kihara S, Ouchi N, Takahashi M, Maeda K, Miyagawa J, Hotta K and Shimomura Nakamura T (1999): Paradoxical decrease of an adipose-specific protein, adiponectin, in obesity. Biochem Biophys Res Commun., 257:79–83.

8. Atalay A, Elic H, Kayadibi N and Nurettin A (2012): Diagnostic utility of osteocalcin, under carboxylated osteocalcin and alkaline phosphatase for osteoporosis in premenopausal and postmenopausal women. Ann Lab Med., 32:23–30.

9. Aubertin-Leheudre M, Lord C, Labonté M, Khalil A and Dionne IJ (2008): Relationship between sarcopenia and fracture risks in obese postmenopausal women. J Women Aging,  20:297–308.

10. Bancroft, D and Cook J (1984): Organic chelating agents for decalciflcation of bone. Stain Technology,28: 285-289.

11. Basurto L, Galvan R, Cordova N, Saucedo R, Vargas C, Campos S, Halley E, Avelar F and Zarate A (2009): Adiponectin is associated with low bone mineral density in elderly men. European Journal of Endocrinology, 160:289–293.

12. Belfield A and Goldberg DM (1971): Colourimetric determination of serum alkaline phosphatase. Enzyme, 12: 651-656.

13. Berner HS, Lyngstadaas SP, Spahr A, Monjo M, Thommesen L, Syversen U and Reseland JE (2004): Adiponectin and its receptors are expressed in bone-forming cells. Bone, 35:842–849.

14. Boström P, Wu J and Jedrychowski MP (2012): A PGC1-α-dependent myokine that drives brown-fat-like development of white fat and thermogenesis. Nature, 481:463–468.

15. Bredella MA, Gill CM, Rosen CJ, Klibanski A and Torriani M (2014): Positive effects of brown adipose tissue on femoral bone structure. Bone, 58:55–58.

16. Ce C, Zhou L, Yu D, Zhao Y, and Yang N (2014a): Serum osteocalcin levels and bone mineral density in ovariectomized rats. International Journal of Innovation and Scientific Research, ISSN 2351-8014 5 (1): 1-8.

17. Ce C, Zhou L-Y, Ma Y, Zhu L, Yu D, Zhao Y-W and Yang N-H. (2014b): Effect of ovariectomy on serum adiponectin levels and visceral fat in rats. J Huazhong Univ Sci Technol., 34(6):825-829.

18. Cheung E, Tsang S, Bow C, Soong C and Yeung S (2011): Bone loss during menopausal transition among southern Chinese women. Maturitas, 69: 50–56.

19. Colaianni G, Cuscito C, Mongelli T, Oranger A, Mori G, Cinti S and Grano M (2014): Irisin enhances osteoblast differentiation in vitro. Int J Endocrinol., 2014:e902186-92.

20. Colaianni G, Cuscito C, Mongelli T, Pignataro P, Lu P, Sartini L, Di Comite M, Mori G and Di Benedetto A (2015): The myokine irisin increases cortical bone mass. Proc Natl Acad Sci U S A., 112(39):12157-12162.

21. Colaianni Gand Grano M (2015): Role of Irisin on the bone-muscle functional unit. Bonekey Rep., 4:765-769.

22. Doster GR, Yorke RE and Randle PJ. (1969): Ashing procedures for biological materials. Current Science, 3: 206-209.

23. Ealey KN, Kaludjerovic J, Archer MC and Ward WE (2008): Adiponectin is a negative regulator of bone mineral and bone strength in growing mice. Exp Biol Med., 233:1546–1553.

24. Emkey G.R. and Epstein S (2014): Secondary osteoporosis: pathophysiology & diagnosis, Best. Pract. Res. Clin. Endocrinol. Metab., 28 (6) 911–935.

25. Gallagher CM, Moonga BS and Kovach JS (2010): Cadmium, follicle-stimulating hormone, and effects on bone in women age 42–60 years. Environ Res., 110: 105–111.

26. Gao S, Cheng Y, Zhao L, Chen Y and Liu Y (2016): The relationships of irisin with bone mineral density and body composition in PCOS patients. Diabetes Metab Res Rev.,  32(4):421-428.

27. García-Contreras F, Paniagua R, Avila-Díaz M, Martínez-Muñiz I, Foyo-Niembro E and Amato D (2000): Cola beverage consumption induces bone mineralization reduction in ovariectomized rats. Arch Med Res., 31(4):360-365.

28. Garcia-Martin A, Reyes-Garcia R, Garcia-Castro JM and Escobar-Jimenez F (2012): Role of serum FSH measurement on bone resorption in postmenopausal women. Endocrine, 41: 302–308.

29. Gindler, H, Pollard, FM and Martin, JV (1972): Colourimetric determination of serum calcium. Ann. Biochem., 20: 521.

30. Goldenberg H. (1966): Colourimetric determination of serum phosphorus. Clin. Chem., 12 : 871-878.

31. Gourlay ML, Specker BL, Li C, Hammett-Stabler CA and Renner JB (2012): Follicle-stimulating hormone is independently associated with lean mass but not BMD in younger postmenopausal women. Bone, 50: 311 –316. 

32. Griffith JF, Wang YJ, Zhou H, Kwong WH, Wong WT, Sun YL Huang Y, Qin L and Ahuja AT (2010): Reduced bone perfusion in osteoporosis: likely causes in an ovariectomy rat model . Radiology, 254(3): 739- 746.

33. Gui Y, Silha J V and Murphy L J (2004): Sexual dimorphism and regulation of resistin, adiponectin, and leptin expression in the mouse.Obesity Research, 12:1481-1491.

34. Hamann S, Kirschner S, Günther KP and Hofbauer LC (2012): Bone, sweet bone osteoporotic fractures in diabetes mellitus. Nature Reviews Endocrinology, 8 (5): 297–305.

35. Ho-Pham LT, Nguyen U D T and Nguyen T V (2014): Association between lean mass, fat mass, and bone mineral density: A Meta-analysis. J Clin Endocrinol Metab., 99(1):30–38.

36. Iliou T, Anagnostopoulos CN, Stephanakis IM and Anastassopoulos GA (2015): novel data preprocessing method for boosting neural network performance: a case study in osteoporosis prediction, Inf. Sci., 380: 92–100.

37. Imai Y (2014): Bone metabolism by sex hormones and gonadotropins. Clin Calcium, 24: 815–819.

38. Institute of laboratory animal resources, Commission on life sciences and National research council (1996): Guide for the care and use of laboratory animals, 8th Edition. Pbl: National academy press, Washington DC., PP. 21-55.

39. Jiang X, Song D, Ye B, Wang X, Song G and Yang S (2011): Effect of intermittent administration of adiponectin on bone regeneration following mandibular osteodistraction in rabbits. J Orthop Res., 29:1081–1085.

40. Kaji H (2013): Linkage between muscle and bone: common catabolic signals resulting in osteoporosis and sarcopenia. Curr Opin Clin Nutr Metab Care, 16:272-277.

41. Kajimura D, Lee HW, Riley KJ, Arteaga-Solis E, Ferron M, Zhou B, Clarke CJ, Hannun YA, Depinho RA, Guo EX, Mann JJ and Karsenty G (2013): Adiponectin regulates bone mass via oppositecentral and peripheral mechanism through FoxO1. Cell Metab.,17:901–915.

42. Kanazawa I, Yamaguchi T, Yano S, Yamauchi M, Yamamoto M and Sugimoto T (2007): Adiponectin and AMP kinase activator stimulate proliferation, differentiation, and mineralization of osteoblastic MC3T3-E1 cells. BMC Cell Biol., 8:51–62.

43. Kawao N1 and Kaji H (2015): Interactions between muscle tissues and bone metabolism. J Cell Biochem., 116(5):687-695.

44. Kubota N, Yamauchi T,Tobe K and Kadowaki T (2006): Adiponectin-Dependent and -Independent Pathways in Insulin-Sensitizing and Antidiabetic Actions of Thiazolidinediones. Diabetes,. 55 (2): S3- S38 .

45. Li DJ, Huang F, Lu WJ, Jiang GJ, Deng YP and Shen FM (2015): Metformin promotes irisin release from murine skeletal muscle independently of AMP-activated protein kinase activation. Acta Physiologica, 213(3): 711–721.

46. Liu S, Cheng Y, Fan M, Chen D and Bian Z (2010a): FSH aggravates periodontitis-related bone loss in ovariectomized rats. J Dent Res., 89: 366–371.

47. Liu S, Cheng Y, Xu W and Bian Z (2010b): Protective effects of follicle-stimulating hormone inhibitor on alveolar bone loss resulting from experimental periapical lesions in ovariectomized rats. J Endo., 36: 658– 663.

48. Luo XH, Guo LJ and Xie H (2006): Adiponectin stimulates RANKL and inhibits OPG expression in human osteoblasts through the MAPK signaling pathway. J Bone Miner Res., 21: 1648-56.

49. Matthews D, Hosker J, Rudenski A, Naylor B and Turner R (1985): Homeostasis model assessment: insulin resistance and beta-cell function from fasting plasma glucose and insulin concentrations in man. Diabetologia, 28:412-419.

50. Mohiti-Ardekani J, Soleymani-Salehabadi H, Owlia MB and Mohiti A (2014): Relationships between serum adipocyte hormones (adiponectin, leptin, resistin), bone mineral density and bone metabolic markers in osteoporosis patients J Bone Miner Metab., 32:400–404.

51. Moorthy K, Yadav UCS and Mantha AK (2004): Estradiol and progesterone treatment change the lipid profile in naturally menopausal rats from different age groups. Biogerontology, 5(6):411-419.

52. Moreno-Navarrete JM, Ortega F, Serrano M, Guerra E, Pardo G, Tinahones F, Ricart W, and Fernández-Real JM (2013):  Irisin is expressed and produced by human muscle and adipose tissue in association with obesity and insulin resistance. J Clin Endo Met., 98(4):E769–E778.

53. Mpalaris V, Anagnostis P, Anastasilakis AD, Goulis DG, Doumas A and Iakovou I (2016): Serum leptin, adiponectin and ghrelin concentrations in post-menopausal women: Is there an association with bone mineral density?,Maturitas, 88:32-36.

54. Nishizawa H, Shimomura I, Kishida K, Maeda N, Kondo H, Furuyama N, Kihara S, Tochino Y, Funahashi T and Matsuzawa N (2002): Androgens decrease plasma adiponectin, an insulin-sensitizing adipocyte derived protein. Diabetes, 51:2734–2741.

55. Novelli E, Padovani C and Cicogna A (2008): Misclassification probability as obese or lean in hypercaloric and normocaloric diet. Biol. Res., 41: 253-259.

56. Nway NC, Sitticharoon C, Chatree S and Maikaew P (2016): Correlations between the expression of the insulin sensitizing hormones, adiponectin, visfatin, and omentin, and the appetite regulatory hormone, neuropeptide Y and its receptors in subcutaneous and visceral adipose tissues. Obesity Research and clinical practice, 10 (3): 256–263.

57. Nyman JS, Even JL and Jo CH (2011): Increasing duration of type 1 diabetes perturbs the strength-structure relationship and increases brittleness of bone. Bone, 48(4): 733–740.

58. Ochoa S, Arantazu F, Diego R, Rebeca M, Raya M and Manuel M (2012): osteoporoticpostmenopausal women treated with reloxifene or alendronate. Menopause, 19:172–177.

59. Palermo A1, Strollo R, Maddaloni E, Tuccinardi D, D'Onofrio L, Briganti SI, Defeudis G, De Pascalis M, Lazzaro MC, Colleluori G, Manfrini S, Pozzilli P and Napoli N (2015): Irisin is associated with osteoporotic fractures independently of bone mineral density, body composition or daily physical activity. Clin Endocrinol (Oxf), 82(4):615-619.

60. Pang XD, Xian H, Zhao Q, Wu XP, Sun ZQ and Liao EY (2008): Relationships between serum adiponectin, leptin, resistin, visfatinlevels and bone mineral density, and bone biochemical markers inChinese men. Clin Chim Acta, 387:31–35.

61. Parm AL, Jurimae J, Saar M, Parna K, Tillmann V, Maasalu K, Neissaar I and Jurimae T (2011): Plasma adipocytokine and ghrelinlevels in relation to bone mineral density in prepubertal rhythmicgymnasts. J Bone Miner Metab., 9:717–724.

62. Prasannarong M, Saengsirisuwan V, Piyachaturawat P and Suksamrarn A (2012): Improvements of insulin resistance in ovariectomized rats by a novel phytoestrogen from Curcuma comosa Roxb. BMC Complementary and Alternative Medicine, 12:12-28.

63. Qiao X, Nie Y, Ma Y, Chen Y, Cheng R, Yin W, Hu Y, Xu W and Xu L (2016): Irisin promotes osteoblast proliferation and differentiation via activating the MAP kinase signaling pathways. Sci. Rep., 6: 18732-18739.

64. Raab, JK, Alan, ST and Drury W (1991): Histological methods for bone, 5th ed., pbl. Oxford University Press, New York, Toronto, P. 185.

65. Räkel S, Sheehy O, Rahme E, and LeLorier J (2008): Osteoporosis among patients with type 1 and type 2 diabetes. Diabetes and Metabolism, 34(3):193–205.

66. Richards JB, Valdes AM, Burling K, Perks UC and Spector TD (2007): Serum adiponectin and bone mineral density in women. J Clin Endocrinol Metab., 92:1517–1523.

67. Ritter V, Thuering B, Saint Mezard P, Luong-Nguyen NH and Seltenmeyer Y (2008): Follicle-stimulating hormone does not impact male bone mass in vivo or human male osteoclasts in vitro. Calcif Tissue Int.,  82: 383–391.

68. Roca-Rivada A, Castelao C, Senin LL, Landrove MO, Baltar J, Belén Crujeiras A, Seoane LM, Casanueva FF and Pardo M (2013): FNDC5/irisin is not only a myokine but also an adipokine. PLoS One, 8:e60563.

69. Rouach V, Katzburg S, Koch Y, Stern N and Somjen D (2011) Bone loss in ovariectomized rats: dominant role for estrogen but apparently not for FSH. J Cell Biochem., 112: 128–137.

70. Saengsirisuwan V, Pongseeda S, Prasannarong M, Vichaiwong K and Toskulkao C (2009): Modulation of insulin resistance in ovariectomized rats by endurance exercise training and estrogen replacement. Metabolism, 58(1): 38–47.

71. Secchiero P, Corallini F and Pandolfi A (2006): An increased osteoprotegerin serum release characterizes the early onset of diabetes mellitus and may contribute to endothelial cell dysfunction. American Journal of Pathology, 169( 6): 2236–2244.

72. Seibel MJ, Dunstan CR, Zhou H, Allan CM and Handelsman DJ (2006): Sex steroids, not FSH, influence bone mass. Cell, 127: 1079.

73. Shinoda Y, Yamaguchi M and Ogata N (2006): Regulation of bone formation by adiponectin through autocrine/paracrine and endocrine pathways. J Cell Biochem., 99:196–208.

74. Singhal V, Lawson EA, Ackerman KE, Fazeli PK, Clarke H, Lee H, Eddy K, Marengi DA, Derrico NP, Bouxsein ML and Misra M (2014): Irisin levels are lower in young amenorrheic athletes compared with eumenorrheic athletes and non-athletes and are associated with bone density and strength estimates. PLos One 13:9(6):e100218.

75. Siri PW and Ginsberg HN (2003): Ovariectomy leads to increased insulin resistance in human apolipoprotein B transgenic mice lacking brown adipose tissue. Metabolism, 52 (6):, , 659–661.

76. Sowers MR, Jannausch M, McConnell D, Little R and Greendale GA (2006): Hormone predictors ofbone mineral density changes during the menopausal transition. J Clin Endocrinol Metab., 91: 1261–1267.

77. Sowers MR, Zheng H, Greendale GA, Neer RM and Cauley JA (2013): Changes in bone resorption across the menopause transition: effects of reproductive hormones, body size, and ethnicity. J Clin Endocrinol Metab., 98: 2854–2863.

78. Sun L, Peng Y, Sharrow AC, Iqbal J and Zhang Z (2006): FSH directly regulates bone mass. Cell, 125: 247–260.

79. Temple R, Clark P and Hales C (1992): Measurement of insulin secretion in type 2 diabetes: problems and pitfalls. Diabetic Medicine, 9: 503-511.

80. Tietz N (1995): Clinical Guide to Laboratory Tests, 3rd Ed., pbl. W.B. Saunders Company, Philadelphia, pp.509–580.

81. Tohidi M., Akbarzadeh S. and Larijani B (2012): Omentin-1, visfatin and adiponectin levels in relation to bone mineral density in Iranian postmenopausal women. Bone, 51: 876–881.

82. Üstün Y E, Çağlayan EK, Göçmen A Y and Polat MF (2016): Postmenopausal Osteoporosis Is Associated with Serum Chemerin and Irisin but Not with Apolipoprotein M Levels. Journal of Menopausal Medicine, 22:76-79.

83. Wang J, Zhang W, Yu C, Zhang X, Zhang H, Guan Q, Zhao J and Xu J (2015): Follicle-Stimulating Hormone Increases the Risk of Postmenopausal Osteoporosis by Stimulating Osteoclast Differentiation. PLoS One, 10(8):e0134986.

84. WilliamsGA, Wang Y, Callon KE, Watson M, Lam JB, Lin JM, Janice BB, Costa JL, Orpe A, Broom N, Naot D, Reid IR and Cornish J (2009): In vitro and in vivo effects of adiponectin on bone. Endocrinology, 150:3603–3610.

85. Won Muhlen D, Safii S, Jassal SK, Svartberg J and Barrett-Connor E (2007):Associations between the metabolic syndrome and bonehealth in older men and women: the Rancho Bernardo Study.Osteoporos Int., 18:1337–1344.

86. Xin FENG, Shengqiang LI, Yulian LAI and Jirong GE (2014): Correlational study between knee osteoarthritis and osteoporosis in postmenopausal women, Chin. J. Osteoporos./Zhongguo Guzhi Shusong Zazhi, 20 (4).

87. Zhang H, Xie H, Zhao Q, Xie GQ, Wu XP, Liao EY and Luo XH (2010): Relationships between serum adiponectin, apelin, leptin, resistin, visfatin levels and bone mineral density, and bone biochemical markers in post-menopausal Chinese women. J Endocrinol Invest., 33(10):707-11.

88. ZhangJ, Cheng J, Tu Q and Chen JJ (2013): Effects of irisin on bone metabolism and its signal mechanism. J Bone Miner Res., 28 (1):S127-S133.

89. Zhong N, Wu XP, Xu ZR, Wang AH, Luo XH, Cao XZ, Xie H, Shan PF and Liao EY (2005): Relationship of serum leptin with age,body weight, body mass index, and bone mineral density inhealthy mainland Chinese women. Clin Chim Acta, 351:161–168.

90. Zhu L, BrownW C, Cai Q, Krust A, Chambon P, McGuinness OP. and Stafford JM (2013): Estrogen treatment after ovariectomy protects against fatty liver and may improve pathway-selective insulin resistance. Diabetes, 62(2): 424-434.


مستویات الأدیبونیکتین والأیرزین فی مصل دم نموذج هشاشة العظام المحدث بإستئصال المبیضین فی الجرذان

 

عبیر البیومی خلیفة - نادین أحمد رأفت

قسم الفسیولوجی- کلیة الطب البشری- جامعة الزقازیق

 

خلفیة البحث: تمثل هشاشة العظام بعد إنقطاع الطمث مرض العظام الأکثر شیوعا فی الإناث , ویتسم هذا المرض بإنخفاض کثافة المعادن فی العظام  ومع ذلک لا تزال الأسباب الدقیقة غیر واضحة.

الهدف من البحث:  التعرف على العلاقة بین مستویات الادیبونیکتین والأیرزین فی مصل دم نموذج هشاشة العظام المحدث باستئصال المبیضین بالجرذان وعلاقتهما  بدلائل کثافة العظام.

طرق و مواد البحث: تم استخدام ثلاث مجموعات متساویة من الجرذان الإناث البالغات البیضاء (العدد = 15) و المجموعات هی . المجموعة الضابطة والمجموعة الصوریة  والمجموعة المستأصلة المبایض.

 وبعد 9 أسابیع من إستئصال المبایض، تم أخذ عینات الدم من حزمة الأوردة خلف العین و فصل مصل الدم منها. و قد تم قیاس مستویات هرمون الأدیبونکتین و هرمون الأیرزین وهرمون تحفیز جریبات المبیض و هرمون الاسترادیول والجلوکوز وهرمون الإنسولین و مستوی الکالسیوم والفوسفور ،وإنزیم الفوسفاتیز القلوی. وقد تم حساب کل من  مؤشر کتلة الجسم و معدل المقاومة للإنسولین. وقد تم قیاس دلائل هشاشة العظام  (الوزن الجاف ووزن الرماد لعظم الفخذ  ومستوی الکالسیوم و الفوسفور فی العظام) جنبا إلى جنب مع فحص الأنسجة فی عظم الفخذ.

نتائج البحث: بالنظر إلی نموذج هشاشة العظام بالجرذان، فی حین أن مستویات مصل ادیبونیکتین کانت مرتفعة بشکل ملحوظ وله دلالة إحصائیة  وتناسب عکسیا مع کثافة المعادن بالعظام، إلا أن مستویات الإیرزین قد انخفضت  بالدلیل الإحصائی, وأظهرت ارتباطاً إیجابیاً بدلالة إحصائیة مع کثافة المعادن بالعظام. و قد إرتبطت التغیرات فی مستویات الأدیبونیکتین و الإیریسین بشکل کبیر مع مقاومة الإنسولین المرتفعة. ومع ذلک، فإنها لم تظهر إرتباطا مع مستویات هرمون تحفیز جریبات المبیض أو هرمون الإسترادیول.

الإستنتاج: ترتبط هشاشة العظام التی یسببها استئصال المبیضین فی زیادة کبیرة فی مستویات أدیبونیکتین وإنخفاض فی مستویات إیرزین. و قد ارتبطت هذه التغیرات مع التغیرات فی مقاومة للإنسولین ولیس الهرمونات الجنسیة. ویمکن الإفتراض أن المسبب الدقیق لهشاشة العظام فیما بعد إنقطاع الطمس یتجاوز محور الغدة النخامیة- المبیض بأن یکون تبادل علاقات فیما بین التمثیل الغذائی والعضلات والسمنة والذی یحتاج إلی تحقیقات أکثر تفصیلا.

 

REFERENCES
1. Aaseth J, Boivin G and Andersen O (2012): Osteoporosis and trace elements an overview, J. Trace Elem. Med. Biol., 26 (2): 149–152.
2. Ainslie DA, Morris MJ and Wittert G (2001): Estrogen deficiency causes central leptin insensitivity and increased hypothalamic neuropeptide Y. Int J Obes., 25(11): 1680-1688.
3. Anastasilakis AD, Polyzos SA, Makras P, Gkiomisi A, Filippaios A and Mantzoros CS (2014): Circulating irisin is associated with osteoporotic fractures in postmenopausal women with low bone mass but is not affected by either teriparatide or denosumab treatment for 3 months. Osteoporos Int., 25:1633–1642.
4. Appelman-Dijkstra NM and Papapoulos SE (2014): Novel approaches to the treatment of osteoporosis. Best Pract. Res. Clin. Endocrinol. Metab., 28 (6):843–857.
5. Araneta MR, von Muhlen D and Barrett-Connor E (2009): Sex differences in the association between adiponectin and BMD, bone loss, and fractures: the Rancho Bernardo study. J Bone Miner Res., 24:2016–2022.
6. Arikan S, Tuzcu A, Bahceci M, Ozmen S and Gokalp D (2012): Insulin resistance in type 2 diabetes mellitus may be related to bone mineral density. Journal of Clinical Densitometry, 15 (2):186–190.
7. Arita Y, Kihara S, Ouchi N, Takahashi M, Maeda K, Miyagawa J, Hotta K and Shimomura Nakamura T (1999): Paradoxical decrease of an adipose-specific protein, adiponectin, in obesity. Biochem Biophys Res Commun., 257:79–83.
8. Atalay A, Elic H, Kayadibi N and Nurettin A (2012): Diagnostic utility of osteocalcin, under carboxylated osteocalcin and alkaline phosphatase for osteoporosis in premenopausal and postmenopausal women. Ann Lab Med., 32:23–30.
9. Aubertin-Leheudre M, Lord C, Labonté M, Khalil A and Dionne IJ (2008): Relationship between sarcopenia and fracture risks in obese postmenopausal women. J Women Aging,  20:297–308.
10. Bancroft, D and Cook J (1984): Organic chelating agents for decalciflcation of bone. Stain Technology,28: 285-289.
11. Basurto L, Galvan R, Cordova N, Saucedo R, Vargas C, Campos S, Halley E, Avelar F and Zarate A (2009): Adiponectin is associated with low bone mineral density in elderly men. European Journal of Endocrinology, 160:289–293.
12. Belfield A and Goldberg DM (1971): Colourimetric determination of serum alkaline phosphatase. Enzyme, 12: 651-656.
13. Berner HS, Lyngstadaas SP, Spahr A, Monjo M, Thommesen L, Syversen U and Reseland JE (2004): Adiponectin and its receptors are expressed in bone-forming cells. Bone, 35:842–849.
14. Boström P, Wu J and Jedrychowski MP (2012): A PGC1-α-dependent myokine that drives brown-fat-like development of white fat and thermogenesis. Nature, 481:463–468.
15. Bredella MA, Gill CM, Rosen CJ, Klibanski A and Torriani M (2014): Positive effects of brown adipose tissue on femoral bone structure. Bone, 58:55–58.
16. Ce C, Zhou L, Yu D, Zhao Y, and Yang N (2014a): Serum osteocalcin levels and bone mineral density in ovariectomized rats. International Journal of Innovation and Scientific Research, ISSN 2351-8014 5 (1): 1-8.
17. Ce C, Zhou L-Y, Ma Y, Zhu L, Yu D, Zhao Y-W and Yang N-H. (2014b): Effect of ovariectomy on serum adiponectin levels and visceral fat in rats. J Huazhong Univ Sci Technol., 34(6):825-829.
18. Cheung E, Tsang S, Bow C, Soong C and Yeung S (2011): Bone loss during menopausal transition among southern Chinese women. Maturitas, 69: 50–56.
19. Colaianni G, Cuscito C, Mongelli T, Oranger A, Mori G, Cinti S and Grano M (2014): Irisin enhances osteoblast differentiation in vitro. Int J Endocrinol., 2014:e902186-92.
20. Colaianni G, Cuscito C, Mongelli T, Pignataro P, Lu P, Sartini L, Di Comite M, Mori G and Di Benedetto A (2015): The myokine irisin increases cortical bone mass. Proc Natl Acad Sci U S A., 112(39):12157-12162.
21. Colaianni Gand Grano M (2015): Role of Irisin on the bone-muscle functional unit. Bonekey Rep., 4:765-769.
22. Doster GR, Yorke RE and Randle PJ. (1969): Ashing procedures for biological materials. Current Science, 3: 206-209.
23. Ealey KN, Kaludjerovic J, Archer MC and Ward WE (2008): Adiponectin is a negative regulator of bone mineral and bone strength in growing mice. Exp Biol Med., 233:1546–1553.
24. Emkey G.R. and Epstein S (2014): Secondary osteoporosis: pathophysiology & diagnosis, Best. Pract. Res. Clin. Endocrinol. Metab., 28 (6) 911–935.
25. Gallagher CM, Moonga BS and Kovach JS (2010): Cadmium, follicle-stimulating hormone, and effects on bone in women age 42–60 years. Environ Res., 110: 105–111.
26. Gao S, Cheng Y, Zhao L, Chen Y and Liu Y (2016): The relationships of irisin with bone mineral density and body composition in PCOS patients. Diabetes Metab Res Rev.,  32(4):421-428.
27. García-Contreras F, Paniagua R, Avila-Díaz M, Martínez-Muñiz I, Foyo-Niembro E and Amato D (2000): Cola beverage consumption induces bone mineralization reduction in ovariectomized rats. Arch Med Res., 31(4):360-365.
28. Garcia-Martin A, Reyes-Garcia R, Garcia-Castro JM and Escobar-Jimenez F (2012): Role of serum FSH measurement on bone resorption in postmenopausal women. Endocrine, 41: 302–308.
29. Gindler, H, Pollard, FM and Martin, JV (1972): Colourimetric determination of serum calcium. Ann. Biochem., 20: 521.
30. Goldenberg H. (1966): Colourimetric determination of serum phosphorus. Clin. Chem., 12 : 871-878.
31. Gourlay ML, Specker BL, Li C, Hammett-Stabler CA and Renner JB (2012): Follicle-stimulating hormone is independently associated with lean mass but not BMD in younger postmenopausal women. Bone, 50: 311 –316. 
32. Griffith JF, Wang YJ, Zhou H, Kwong WH, Wong WT, Sun YL Huang Y, Qin L and Ahuja AT (2010): Reduced bone perfusion in osteoporosis: likely causes in an ovariectomy rat model . Radiology, 254(3): 739- 746.
33. Gui Y, Silha J V and Murphy L J (2004): Sexual dimorphism and regulation of resistin, adiponectin, and leptin expression in the mouse.Obesity Research, 12:1481-1491.
34. Hamann S, Kirschner S, Günther KP and Hofbauer LC (2012): Bone, sweet bone osteoporotic fractures in diabetes mellitus. Nature Reviews Endocrinology, 8 (5): 297–305.
35. Ho-Pham LT, Nguyen U D T and Nguyen T V (2014): Association between lean mass, fat mass, and bone mineral density: A Meta-analysis. J Clin Endocrinol Metab., 99(1):30–38.
36. Iliou T, Anagnostopoulos CN, Stephanakis IM and Anastassopoulos GA (2015): novel data preprocessing method for boosting neural network performance: a case study in osteoporosis prediction, Inf. Sci., 380: 92–100.
37. Imai Y (2014): Bone metabolism by sex hormones and gonadotropins. Clin Calcium, 24: 815–819.
38. Institute of laboratory animal resources, Commission on life sciences and National research council (1996): Guide for the care and use of laboratory animals, 8th Edition. Pbl: National academy press, Washington DC., PP. 21-55.
39. Jiang X, Song D, Ye B, Wang X, Song G and Yang S (2011): Effect of intermittent administration of adiponectin on bone regeneration following mandibular osteodistraction in rabbits. J Orthop Res., 29:1081–1085.
40. Kaji H (2013): Linkage between muscle and bone: common catabolic signals resulting in osteoporosis and sarcopenia. Curr Opin Clin Nutr Metab Care, 16:272-277.
41. Kajimura D, Lee HW, Riley KJ, Arteaga-Solis E, Ferron M, Zhou B, Clarke CJ, Hannun YA, Depinho RA, Guo EX, Mann JJ and Karsenty G (2013): Adiponectin regulates bone mass via oppositecentral and peripheral mechanism through FoxO1. Cell Metab.,17:901–915.
42. Kanazawa I, Yamaguchi T, Yano S, Yamauchi M, Yamamoto M and Sugimoto T (2007): Adiponectin and AMP kinase activator stimulate proliferation, differentiation, and mineralization of osteoblastic MC3T3-E1 cells. BMC Cell Biol., 8:51–62.
43. Kawao N1 and Kaji H (2015): Interactions between muscle tissues and bone metabolism. J Cell Biochem., 116(5):687-695.
44. Kubota N, Yamauchi T,Tobe K and Kadowaki T (2006): Adiponectin-Dependent and -Independent Pathways in Insulin-Sensitizing and Antidiabetic Actions of Thiazolidinediones. Diabetes,. 55 (2): S3- S38 .
45. Li DJ, Huang F, Lu WJ, Jiang GJ, Deng YP and Shen FM (2015): Metformin promotes irisin release from murine skeletal muscle independently of AMP-activated protein kinase activation. Acta Physiologica, 213(3): 711–721.
46. Liu S, Cheng Y, Fan M, Chen D and Bian Z (2010a): FSH aggravates periodontitis-related bone loss in ovariectomized rats. J Dent Res., 89: 366–371.
47. Liu S, Cheng Y, Xu W and Bian Z (2010b): Protective effects of follicle-stimulating hormone inhibitor on alveolar bone loss resulting from experimental periapical lesions in ovariectomized rats. J Endo., 36: 658– 663.
48. Luo XH, Guo LJ and Xie H (2006): Adiponectin stimulates RANKL and inhibits OPG expression in human osteoblasts through the MAPK signaling pathway. J Bone Miner Res., 21: 1648-56.
49. Matthews D, Hosker J, Rudenski A, Naylor B and Turner R (1985): Homeostasis model assessment: insulin resistance and beta-cell function from fasting plasma glucose and insulin concentrations in man. Diabetologia, 28:412-419.
50. Mohiti-Ardekani J, Soleymani-Salehabadi H, Owlia MB and Mohiti A (2014): Relationships between serum adipocyte hormones (adiponectin, leptin, resistin), bone mineral density and bone metabolic markers in osteoporosis patients J Bone Miner Metab., 32:400–404.
51. Moorthy K, Yadav UCS and Mantha AK (2004): Estradiol and progesterone treatment change the lipid profile in naturally menopausal rats from different age groups. Biogerontology, 5(6):411-419.
52. Moreno-Navarrete JM, Ortega F, Serrano M, Guerra E, Pardo G, Tinahones F, Ricart W, and Fernández-Real JM (2013):  Irisin is expressed and produced by human muscle and adipose tissue in association with obesity and insulin resistance. J Clin Endo Met., 98(4):E769–E778.
53. Mpalaris V, Anagnostis P, Anastasilakis AD, Goulis DG, Doumas A and Iakovou I (2016): Serum leptin, adiponectin and ghrelin concentrations in post-menopausal women: Is there an association with bone mineral density?,Maturitas, 88:32-36.
54. Nishizawa H, Shimomura I, Kishida K, Maeda N, Kondo H, Furuyama N, Kihara S, Tochino Y, Funahashi T and Matsuzawa N (2002): Androgens decrease plasma adiponectin, an insulin-sensitizing adipocyte derived protein. Diabetes, 51:2734–2741.
55. Novelli E, Padovani C and Cicogna A (2008): Misclassification probability as obese or lean in hypercaloric and normocaloric diet. Biol. Res., 41: 253-259.
56. Nway NC, Sitticharoon C, Chatree S and Maikaew P (2016): Correlations between the expression of the insulin sensitizing hormones, adiponectin, visfatin, and omentin, and the appetite regulatory hormone, neuropeptide Y and its receptors in subcutaneous and visceral adipose tissues. Obesity Research and clinical practice, 10 (3): 256–263.
57. Nyman JS, Even JL and Jo CH (2011): Increasing duration of type 1 diabetes perturbs the strength-structure relationship and increases brittleness of bone. Bone, 48(4): 733–740.
58. Ochoa S, Arantazu F, Diego R, Rebeca M, Raya M and Manuel M (2012): osteoporoticpostmenopausal women treated with reloxifene or alendronate. Menopause, 19:172–177.
59. Palermo A1, Strollo R, Maddaloni E, Tuccinardi D, D'Onofrio L, Briganti SI, Defeudis G, De Pascalis M, Lazzaro MC, Colleluori G, Manfrini S, Pozzilli P and Napoli N (2015): Irisin is associated with osteoporotic fractures independently of bone mineral density, body composition or daily physical activity. Clin Endocrinol (Oxf), 82(4):615-619.
60. Pang XD, Xian H, Zhao Q, Wu XP, Sun ZQ and Liao EY (2008): Relationships between serum adiponectin, leptin, resistin, visfatinlevels and bone mineral density, and bone biochemical markers inChinese men. Clin Chim Acta, 387:31–35.
61. Parm AL, Jurimae J, Saar M, Parna K, Tillmann V, Maasalu K, Neissaar I and Jurimae T (2011): Plasma adipocytokine and ghrelinlevels in relation to bone mineral density in prepubertal rhythmicgymnasts. J Bone Miner Metab., 9:717–724.
62. Prasannarong M, Saengsirisuwan V, Piyachaturawat P and Suksamrarn A (2012): Improvements of insulin resistance in ovariectomized rats by a novel phytoestrogen from Curcuma comosa Roxb. BMC Complementary and Alternative Medicine, 12:12-28.
63. Qiao X, Nie Y, Ma Y, Chen Y, Cheng R, Yin W, Hu Y, Xu W and Xu L (2016): Irisin promotes osteoblast proliferation and differentiation via activating the MAP kinase signaling pathways. Sci. Rep., 6: 18732-18739.
64. Raab, JK, Alan, ST and Drury W (1991): Histological methods for bone, 5th ed., pbl. Oxford University Press, New York, Toronto, P. 185.
65. Räkel S, Sheehy O, Rahme E, and LeLorier J (2008): Osteoporosis among patients with type 1 and type 2 diabetes. Diabetes and Metabolism, 34(3):193–205.
66. Richards JB, Valdes AM, Burling K, Perks UC and Spector TD (2007): Serum adiponectin and bone mineral density in women. J Clin Endocrinol Metab., 92:1517–1523.
67. Ritter V, Thuering B, Saint Mezard P, Luong-Nguyen NH and Seltenmeyer Y (2008): Follicle-stimulating hormone does not impact male bone mass in vivo or human male osteoclasts in vitro. Calcif Tissue Int.,  82: 383–391.
68. Roca-Rivada A, Castelao C, Senin LL, Landrove MO, Baltar J, Belén Crujeiras A, Seoane LM, Casanueva FF and Pardo M (2013): FNDC5/irisin is not only a myokine but also an adipokine. PLoS One, 8:e60563.
69. Rouach V, Katzburg S, Koch Y, Stern N and Somjen D (2011) Bone loss in ovariectomized rats: dominant role for estrogen but apparently not for FSH. J Cell Biochem., 112: 128–137.
70. Saengsirisuwan V, Pongseeda S, Prasannarong M, Vichaiwong K and Toskulkao C (2009): Modulation of insulin resistance in ovariectomized rats by endurance exercise training and estrogen replacement. Metabolism, 58(1): 38–47.
71. Secchiero P, Corallini F and Pandolfi A (2006): An increased osteoprotegerin serum release characterizes the early onset of diabetes mellitus and may contribute to endothelial cell dysfunction. American Journal of Pathology, 169( 6): 2236–2244.
72. Seibel MJ, Dunstan CR, Zhou H, Allan CM and Handelsman DJ (2006): Sex steroids, not FSH, influence bone mass. Cell, 127: 1079.
73. Shinoda Y, Yamaguchi M and Ogata N (2006): Regulation of bone formation by adiponectin through autocrine/paracrine and endocrine pathways. J Cell Biochem., 99:196–208.
74. Singhal V, Lawson EA, Ackerman KE, Fazeli PK, Clarke H, Lee H, Eddy K, Marengi DA, Derrico NP, Bouxsein ML and Misra M (2014): Irisin levels are lower in young amenorrheic athletes compared with eumenorrheic athletes and non-athletes and are associated with bone density and strength estimates. PLos One 13:9(6):e100218.
75. Siri PW and Ginsberg HN (2003): Ovariectomy leads to increased insulin resistance in human apolipoprotein B transgenic mice lacking brown adipose tissue. Metabolism, 52 (6):, , 659–661.
76. Sowers MR, Jannausch M, McConnell D, Little R and Greendale GA (2006): Hormone predictors ofbone mineral density changes during the menopausal transition. J Clin Endocrinol Metab., 91: 1261–1267.
77. Sowers MR, Zheng H, Greendale GA, Neer RM and Cauley JA (2013): Changes in bone resorption across the menopause transition: effects of reproductive hormones, body size, and ethnicity. J Clin Endocrinol Metab., 98: 2854–2863.
78. Sun L, Peng Y, Sharrow AC, Iqbal J and Zhang Z (2006): FSH directly regulates bone mass. Cell, 125: 247–260.
79. Temple R, Clark P and Hales C (1992): Measurement of insulin secretion in type 2 diabetes: problems and pitfalls. Diabetic Medicine, 9: 503-511.
80. Tietz N (1995): Clinical Guide to Laboratory Tests, 3rd Ed., pbl. W.B. Saunders Company, Philadelphia, pp.509–580.
81. Tohidi M., Akbarzadeh S. and Larijani B (2012): Omentin-1, visfatin and adiponectin levels in relation to bone mineral density in Iranian postmenopausal women. Bone, 51: 876–881.
82. Üstün Y E, Çağlayan EK, Göçmen A Y and Polat MF (2016): Postmenopausal Osteoporosis Is Associated with Serum Chemerin and Irisin but Not with Apolipoprotein M Levels. Journal of Menopausal Medicine, 22:76-79.
83. Wang J, Zhang W, Yu C, Zhang X, Zhang H, Guan Q, Zhao J and Xu J (2015): Follicle-Stimulating Hormone Increases the Risk of Postmenopausal Osteoporosis by Stimulating Osteoclast Differentiation. PLoS One, 10(8):e0134986.
84. WilliamsGA, Wang Y, Callon KE, Watson M, Lam JB, Lin JM, Janice BB, Costa JL, Orpe A, Broom N, Naot D, Reid IR and Cornish J (2009): In vitro and in vivo effects of adiponectin on bone. Endocrinology, 150:3603–3610.
85. Won Muhlen D, Safii S, Jassal SK, Svartberg J and Barrett-Connor E (2007):Associations between the metabolic syndrome and bonehealth in older men and women: the Rancho Bernardo Study.Osteoporos Int., 18:1337–1344.
86. Xin FENG, Shengqiang LI, Yulian LAI and Jirong GE (2014): Correlational study between knee osteoarthritis and osteoporosis in postmenopausal women, Chin. J. Osteoporos./Zhongguo Guzhi Shusong Zazhi, 20 (4).
87. Zhang H, Xie H, Zhao Q, Xie GQ, Wu XP, Liao EY and Luo XH (2010): Relationships between serum adiponectin, apelin, leptin, resistin, visfatin levels and bone mineral density, and bone biochemical markers in post-menopausal Chinese women. J Endocrinol Invest., 33(10):707-11.
88. ZhangJ, Cheng J, Tu Q and Chen JJ (2013): Effects of irisin on bone metabolism and its signal mechanism. J Bone Miner Res., 28 (1):S127-S133.
89. Zhong N, Wu XP, Xu ZR, Wang AH, Luo XH, Cao XZ, Xie H, Shan PF and Liao EY (2005): Relationship of serum leptin with age,body weight, body mass index, and bone mineral density inhealthy mainland Chinese women. Clin Chim Acta, 351:161–168.
90. Zhu L, BrownW C, Cai Q, Krust A, Chambon P, McGuinness OP. and Stafford JM (2013): Estrogen treatment after ovariectomy protects against fatty liver and may improve pathway-selective insulin resistance. Diabetes, 62(2): 424-434.