Iraqi Journal of Veterinary Sciences

Current Issue

By Issue

By Subject

Keyword Index

Author Index

Indexing Databases XML

About Journal

Aims and Scope

Editorial Board

Editorial Staff

Facts and Figures

Publication Ethics

Indexing and Abstracting

Related Links

FAQ

Peer Review Process

News

Effect of plasma isolated Orexin-A on the regulation of metabolites in male rats

Iraqi Journal of Veterinary Sciences, 2021, Volume 35, Issue 3, Pages 451-457
10.33899/ijvs.2020.127001.1429

Abstract

This research includes the isolation and purification of Orexin-A from the plasma of healthy human via various biochemical techniques, it was proposed the therapeutic role of orexin on hyperlipidemia and lipid peroxidation and it has been suggested to study the effect of isolated orexin A on the metabolism of lipids and glucose in normal and hyperlipidemic rats, a high level of orexin-A had been found only in second peak (B) isolated by gel filtration chromatography (using Sephadex G-50) and showed (34.5) fold of purification, also, the effect of isolated orexin-A on some clinical parameters had been studied in normal and hyperlipidemic male rats. The rats were injected intraperitoneally with orexin-A at a dose of 1μmol/kg of body weight/day for one month. The results, obtained before treatment and after two and four weeks of treatment, had been showing a significant decrease in the concentration of total cholesterol, triglycerides, low and very low-density lipoprotein cholesterol, glucose, malondialdehyde and hyperinsulinemia, while there was a significant increase in the concentration of high-density lipoprotein cholesterol in normal and hyperlipidemic rats. It was concluded that orexin-A had an important role in regulating the metabolism of glucose and lipids, treatment of hyperinsulinemia and insulin resistance, and decreasing lipid peroxidation in normal and hyperlipidemic rats.
Keywords:
Main Subjects:

Effect of plasma isolated Orexin-A on the regulation of metabolites in male rats

 

R.F. Jasim1 and T.A. Allwsh2

 

1Department of chemistry, Collage of Education for Girls, 2Department of chemistry, Collage of Science, University of Mosul, Mosul, Iraq

 

ra.fadhel@uomosul.edu.iq, 0000-0003-1364-1344, corresponding author

allwsh2007@yahoo.com, 0000-0002-3479-8001

 

2020-04-24

2020-07-14

 

Abstract

 

This research includes the isolation and purification of Orexin-A from the plasma of healthy human via various biochemical techniques, it was proposed the therapeutic role of orexin on hyperlipidemia and lipid peroxidation and it has been suggested to study the effect of isolated orexin A on the metabolism of lipids and glucose in normal and hyperlipidemic rats, a high level of orexin-A had been found only in second peak (B) isolated by gel filtration chromatography (using Sephadex G-50) and showed (34.5) fold of purification, also, the effect of isolated orexin-A on some clinical parameters had been studied in normal and hyperlipidemic male rats. The rats were injected intraperitoneally with orexin-A at a dose of 1μmol/kg of body weight/day for one month. The results, obtained before treatment and after two and four weeks of treatment, had been showing a significant decrease in the concentration of total cholesterol, triglycerides, low and very low-density lipoprotein cholesterol, glucose, malondialdehyde and hyperinsulinemia, while there was a significant increase in the concentration of high-density lipoprotein cholesterol in normal and hyperlipidemic rats. It was concluded that orexin-A had an important role in regulating the metabolism of glucose and lipids, treatment of hyperinsulinemia and insulin resistance, and decreasing lipid peroxidation in normal and hyperlipidemic rats.

 

Keywords:Cholesterol, Hyperlipidemic rats, Hypocretin, Orexin-A, OXA purification

 

تأثیر اورکسین - أ المعزول من البلازما على تنظیم النواتج الأیضیة فی ذکور الجرذان

 

 رنا فاضل جاسم1 و ذکرى علی عوش2

 

1قسم الکیمیاء، کلیة التربیة للبنات، 2قسم الکیمیاء، کلیة العلوم، جامعة الموصل، الموصل، العراق

 

الخلاصة

 

تضمن البحث محاولة عزل وتنقیة الاورکسین-أ من بلازما شخص سلیم باستخدام عدة تقنیات حیاتیة، وقد افترض الدور العلاجی للأورکسین لعلاج فرط الدهون فی الدم والبیروکسدة الدهنیة کما تم اقتراح دراسة تأثیر الأوریکسین المعزول على عملیة التمثیل الغذائی للدهون والجلوکوز فی الجرذان السلیمة والمصابة بارتفاع دهون الدم. وقد لوحظ مستوى عالی للاورکسین-أ فقط فی الحزمة ب المفصولة بواسطة تقنیة کروماتوغرافیا الترشیح الهلامی (باستخدام سیفادیکس ج-50) مع عدد مرات تنقیة تصل إلى 34.5 مرة. کما تم دراسة تأثیر الاورکسین-أ المعزول على بعض المتغیرات السریریة لدى ذکور الجرذان السلیمة والمصابة بارتفاع الدهون. حقنت الجرذان بالاورکسین-أ المعزولة بجرعة واحد مایکرو مول /کغم من وزن الجسم/یوم داخل الغشاء البریتونی ولمدة شهر واحد. أظهرت النتائج المستحصلة قبل العلاج وبعد اسبوعین وأربع أسابیع من العلاج، وجود انخفاض معنوی فی ترکیز الکولستیرول الکلی والکلیسیریدات الثلاثیة والبروتین الدهنی للکولستیرول واطئ الکثافة وواطئ الکثافة جدا والکلوکوز والمالوندایالدیهاید وفرط الأنسولین. بینما کان هناک ارتفاع معنوی فی ترکیز البرتین الدهنی للکولسترول عالی الکثافة لدى الجرذان السلیمة والمصابة بارتفاع الدهون. تستنتج الدراسة الدور المهم للاورکسین-أ فی تنظیم أیض الکلوکوز والدهون وعلاج فرط الأنسولین ومقاومة الأنسولین وتقلیل بیروکسدة الدهون لدى الجرذان السلیمة والمصابة بارتفاع الدهون.

 

Introduction

 

Orexin is a pair of neuropeptides (Orexin-A and Orexin-B) derived mainly from neurons distributed in the lateral hypothalamus (LH))1(. In 1998, two researcher’s groups discovered the new peptides in the lateral hypothalamus of the rat brain (2). One group of researchers named it ''Hypocretin'' derived from the hypothalamus, based on its anatomic location and the amino acid sequence similar to the gut hormone, secretin. Another group called it ''Orexin'' came from orexis, the Greek word meaning appetite (3). There are two type of orexin: Orexin-A (OXA), 33-amino acid, molecular mass 3562 Da, contains 4 Cys residues which form two intra-chain disulfide, and has identical sequences in human, rat, mouse, and cow (4,5). Orexin-B (OXB), 28-amino acid, molecular mass 2937 Da, is a liner peptide, and human OXB have different sequences that of the rodents (6(. Orexin-A and -B initially identified as endogenous ligands for orphan G-protein coupled receptors (GPCRs) OX1R and OX2R (7). The widespread of orexinneurons and receptors in tissues shows the important role of this hormone. OXA controls body weight through regulation of food intake according to the levels of plasma fuel to maintain energy homeostasis (3) thus, OXA protects against obesity (8) also OXA has a certain role in the metabolism of glucose, improvement of insulin receptors function, preserving insulin sensitivity, regulating lipid metabolism and controlling sleep-waking cycle (8,9). Orexin-A increases the cytoplasmic calcium Ca+2, Orexin-A initially binds to the receptors which in turn activate G-protein and subsequently enhances the influx of Ca+2 through channels of the plasma membrane (3,10). The aim of the research was study the effect of isolated OXA from the human plasma on the metabolism of lipids and glucose in normal and hyperlipidemic rats, since there are a few studies in Iraq about OXA in experimental animals.

 

Materials and methods

 

Samples

Fresh plasma (50 ml) was obtained from one healthy male person with age (37 years) with the assistance of the blood bank in Mosul city (the plasma was taken ready and frozen).

 

Organic solvent precipitation

Cold acetone at 4ºC (40:60v/v) was used to precipitate proteinous material (11). Cold acetone added to plasma gradually with slowly stirring at 4ºC for 60 min. The mixture was left for 24 h in the refrigerator at 4ºC. Cooling centrifuge for 30 minutes at 12000xg was used to isolate the precipitated protein, which was dissolved in the lowest volume of distilled water. The protein and orexin-A concentration were estimated (12,13). The protein solution then kept in a tight test tube for a subsequent step.

 

Gel filtration chromatography

 The column used in this technique has a dimension of 2*60 cm and filled with a gel (Sephadex G-50). The protein solution (prepared previously) was applied to this column, and the fractions were collected at a flow rate 58 ml/h. Protein and orexin- A concentration were estimated at each step of isolation.

 

Lyophilization technique

Peaks A and B obtained from the column was dried using freeze-drying, which was performed in the department of pathological analysis, technical institute, Northern University in Mosul.

 

Orexin A assay

Orexin-A level determined by a competitive-enzyme linked immunosorbent assay (ELISA) technique (12) using Elabscience biotechnology, Inc. kit (USA). This assay performed in an immunity laboratory in Al-Salam hospital in Mosul city.

 

Determination of protein concentration:

Protein concentration used standard bovine serum albumin by modified Lowry method (13).

 

The animals

Albino rats were obtained from the Animal House, College of Veterinary Medicine, University of Mosul. Twenty fourth healthy male rats with age 10±1 weeks and weight 200-250 g were divided into four groups (6 each), housed in cages under standard environmental conditions with providing water and pelleted food ad libitum.

 

Induction of hyperlipidemia: High fat diet

The high-fat diet was prepared by adding five grams of cholesterol, 1 g of Cholic acid, 10 ml of coconut oil, 1 kg of standard diet (14). Rats fed on the high-fat diet for 14 weeks and lipid profile was determined every week.

 

Experimental design

The dose used for intraperitoneally injection of isolated orexin-A hormone was 1μmol/kg bw/d (15). The rats were divided randomly into four groups, each contained six rats and all groups were treated for one month. Control group (CG), the first group was normal rats fed on a standard diet and injected intraperitoneally with physiological saline solution. Normal group with Orexin- A (NGO), the second group was normal rats fed on a standard diet and injected intraperitoneally with isolated Orexin-A (peak B). Hyperlipidemic group (HG), the third group was fed on a high-fat diet and after induction of hyperlipidemia; it was injected intraperitoneally with physiological saline solution and served as control hyperlipidemic group. Hyperlipidemic group with orexin A (HGO), the fourth group was fed on a high-fat diet and after induction of hyperlipidemia; it was injected with isolated Orexin-A (peak B).

 

Collection of blood

The Blood samples were collected from the four groups after fasting for 16 h using a capillary tube without anticoagulant via the orbital sinus puncture technique. Serum separated and used to estimate the following biochemical analysis (16).

 

Biochemical analysis

Collected sera were being aliquot to several aliquots for biochemical analysis, which includes the following tests; Fasting blood glucose was determined immediately using the Spinreact kit (Spain) by spectrophotometer at 500 nm (17). Insulin concentration was measured by Monobind ELISA kit USA (18). Total cholesterol was determined by enzymatic colorimetric method using the BIOLABO kit (France) by spectrophotometer at 500 nm (19). Triglycerides TG were determined by enzymatic colorimetric method using the BIOLABO kit (France) by spectrophotometer at 500 nm (20). Very low-density lipoprotein-cholesterol (VLDL-C) was calculated using the equation: VLDL-C [(mmol/L) = TG (mmol/L)/2.2] (21). High-density lipoprotein-cholesterol (HDL-C) was estimated by precipitation method using the BIOLABO kit (France) by spectrophotometer at 500 nm (22). Low-density lipoprotein-cholesterol (LDL-C) was calculated using Friedewald equation [LDL-C (mmol/L) =Total cholesterol-HDL-C-TG/2.2] (17). Malondialdehyde (MDA) determined using Thiobarbituric acid test (23), MDA react with Thiobarbituric acid to produce colored compound measured at 532 nm. Aspartate Aminotransferase (AST) and Alanine Aminotransferase (ALT) activity were determined by the Reflotron Plus system using reflation strips (24,25). Uric acid was determined by enzymatic colorimetric method using the Spinreact kit (Spain) by spectrophotometer at 520 nm (26).

 

Statistical analysis

Data were analyzed by SPSS software and expressed as mean ± SE. To compare between more than two treatments, one-way ANOVA and Duncan-test were used, and the results considered to be significant at P≤0.05 (27).

 

Result

 

Isolation and purification of orexin A from human plasma

The protein precipitate solution obtained from plasma by cold acetone contains a level of orexin-A 402.7 pg/ml compared to plasma 313.9 pg/ml, while there wasn't any level of orexin-A in the filtrate thus, it was neglected.

 

The gel filtration chromatography technique

 Gel filtration chromatography was used to separate the protein precipitate solution obtained by precipitation method using cold acetone from human plasma. As shown in, the elution of proteinous precipitate solution shows two peaks A and B. he elution volume of peaks A and B were 71.1, 155.1 ml respectively. Only the obtained peak B has a high level of orexin-A. The results in a table 1 showed purification steps of orexin-A hormone. The level of orexin-A was increased from 313.9 pg/ml in plasma to 402.7 pg/ml in protein precipitate solution to 614.3 pg/ml in peak B, while the protein concentration was decreased (Figure 1) (Table 1).

 

 

 

 

Figure 1: Elution of protein precipitate solution obtained from plasma by cold acetone on Sephadex G-50. The dimension of the column is 2×60 cm at the flow rate is 58 ml/h.

 

Table 1: Partial purification of orexin A in human plasma

 

Purification Steps

Volume (ml)

Total protein

(mg)

Total con.

of OXA (pg)

Total specific Con. of OXA (pg/mg)

Recovery %

Times of purification

Plasma

50

410

15695

38.2

100

1

Proteinous

precipitate solution

35

214

14096

65.8

89.8

1.7

Gel filtration

/Sephadex G-50

(peak B) after

Lyophilizer

20

9.3

12286

1321.1

78.2

34.5

 

Effect of isolated orexin A on some clinical parameters in normal and hyperlipidemic male rats

The intraperitoneal injection of 1μmol/kg b.w. /day of isolated orexin-A in normal and hyperlipidemic rats showed the following results:

 

The effect of orexin A on lipid profile and malondialdehyde

The results in tables 2 and 3 showed that there was a significant decrease in TC, TG, VLDL-C and LDL-C concentration in NGO compared to CG after 4 weeks and in HGO compared to HG after 2 and 4 weeks of treatment.

 

Table 2: Effect of isolated orexin-A on TC and TG concentration after 2 and 4 weeks of treatment

 

Groups

TC conc. (mmol/L) Mean ± S.E

TG conc. (mmol/L) Mean ± S.E

Pre-treatment

zero time

Post-treatment

Pre-treatment

zero time

Post-treatment

Week 2

Week 4

Week 2

Week 4

CG

4.0±0.26

3.92±0.21

3.99±0.19

1.92±0.06

1.79±0.18

1.80±0.14

NGO

3.98±0.1

3.33±0.26

3.16±0.22 b

1.97±0.21

*1.41±0.09

*1.11±0.02 b

HG

5.01±0.29 b

*6.0±0.18 b

*7.01±0.3 c

2.46±0.02 b

*2.85±0.06 c

*3.02±0.13 c

HGO

5.14±0.26 b

*3.96±0.26

*3.05±0.14 b

2.69±0.07 b

*2.23±0.04 b

*1.92±0.1

* indicate significant differences at (p≤0.05) between time zero and treatment groups.

Small different letters indicate significant differences between control and treatment groups at (p≤0.05), SE: stander error.

 

 

Table 3: Effect of isolated orexin-A on VLDL-C and LDL-C concentration after 2 and 4 weeks of treatment

 

Groups

VLDL-C conc. (mmol/L) Mean ± S.E

LDL-C conc. (mmol/L) Mean ± S.E

Pre-treatment

zero time

Post-treatment

Pre-treatment

zero time

Post-treatment

Week 2

Week 4

Week 2

Week 4

CG

0.86±0.02

0.8±0.08

0.81±0.06

1.85±0.27

1.91±0.3

1.94±0.17

NGO

0.88±0.09

*0.63±0.04

*0.5±0.01 b

1.69±0.15

1.16±0.27

0.92±0.22 b

HG

1.11±0.01 b

*1.28±0.02 c

*1.36±0.06 c

2.97±0.29 b

*3.91±0.19 b

*4.91±0.26 c

HGO

1.21±0.03 b

*1.01±0.02 b

*0.86±0.04

3.02±0.25 b

*1.96±0.27

*1.06± 0.16 b

* indicate significant differences at (p≤0.05) between time zero and treatment groups.

Small different letters indicate significant differences between control and treatment groups at (p≤0.05)

 

On the other hand, the results in a table 4 showed a significant increase in HDL-C concentration in NGO compared to CG after 2 and 4 weeks and in HGO compared with HG after 4 weeks of treatment. Also the results showed a significant decrease in malondialdehyde concentration in NGO compared to CG after 4 weeks and in HGO compared to HG after 2 and 4 weeks of treatment (Table 4).

 

Table 4: Effect of isolated orexin-A on HDL-C and MDA concentrations after 2 and 4 weeks of treatment

 

Groups

HDL-C conc. (mmol/L) Mean ± S.E

MDA (μmol/L) con. Mean ± S.E

Pre-treatment

zero time

Post-treatment

Pre-treatment

zero time

Post-treatment

Week 2

Week 4

Week 2

Week 4

CG

1.29±0.11

1.21±0.09

1.23±0.07

1.83±0.16

1.61±0.26

1.71±0.12

NGO

1.22±0.01

*1.54±0.02 c

*1.73±0.02 c

1.26±0.16

*0.87±0.06

*0.73±0.02 b

HG

0.92±0.01 b

*0.8±0.01 b

*0.73±0.01 b

2.74±0.19 b

*3.58±0.22 b

*4.35±0.19 c

HGO

0.9±0.01 b

*0.98±0.02 b

*1.13±0.01

2.65±0.11 b

*1.85±0.16

*1.50±0.13

* indicate significant differences at (p≤0.05) between time zero and treatment groups.

Small different letters indicate significant differences between control and treatment groups at (p≤0.05)

 

The effect of Orexin-A on Blood glucose (BG) and insulin concentration

The results in a table 5 showed a significant decrease in glucose concentration in NGO compared with CG and in HGO compare with HG after 2 and 4 weeks of treatment. While, there was a non-significant increase in insulin concentration in NGO, and HG has hyperinsulinemia. Also, there was a significant decrease in insulin at HGO compared to HG after 2 and 4 weeks of treatment

 

Table 5: Effect of isolated orexin-A on blood glucose and insulin concentration after 2 and 4 weeks of treatment

 

Groups

BG con. (mmol/L) Mean ± S.E

Insulin con.(μlU/ml) Mean ± S.E

Pre-treatment

zero time

Post-treatment

Pre-treatment

zero time

Post-treatment

Week 2

Week 4

Week 2

Week 4

CG

5.83±0.11

5.91±0.11

5.96±0.15

12.66±0.45

12.85±0.53

13.0±0.48

NGO

5.62±0.14

*4.98±0.20 b

*4.68±0.13 b

12.96±0.86

13.19±0.54

13.22±016

HG

7.47±0.15 b

*8.06±0.13 c

*8.80±0.16 c

17.15±0.78 b

18.52±0.29 b

*21.25±0.9 b

HGO

7.75±0.09 b

*6.12±0.05

*5.07±0.10 b

16.96±0.27 b

*14.79±0.61

*14.03±0.59

* indicate significant differences at (p≤0.05) between time zero and treatment groups.

Small different letters indicate significant differences between control and treatment groups at (p≤0.05)

 

The effect of Orexin-A on AST and ALT activity and uric acid concentration

As shown in a tables 6 and 7 there was a non-significant difference in AST, ALT activity, and uric acid concentration at NGO and HGO after treatment with Orexin-A.

 

 Table 6: Effect of isolated Orexin-A on AST and ALT activity after 2 and 4 weeks of treatment

 

Groups

AST activity (U/L) Mean ± S.E

ALT activity (U/L) Mean ± S.E

Pre-treatment

zero time

Post-treatment

Pre-treatment

zero time

Post-treatment

Week 2

Week 4

Week 2

Week 4

CG

10.57±0.89

11.07±0.69

10.86±0.83

6.04±0.92

6.1±0.89

5.97±0.77

NGO

10.43±0.8

10.87±0.62

9.98±0.98

5.89±0.73

5.67±0.81

5.41±0.70

HG

15.42±1.17 b

19.71±1.29 b

*20.99±1.74 b

10.2±0.83 b

*15.62±1.98 b

*16.02±1.3 b

HGO

16.17±1.62 b

15.95±1.17 b

16.11±1.21 b

11.83±1.29 b

11.56±1.24 b

12.0±1.61 b

* indicate significant differences at (p≤0.05) between time zero and treatment groups.

Small different letters indicate significant differences between control and treatment groups at (p≤0.05)

 

Table 7: Effect of isolated Orexin-A on uric acid after 2 and 4 weeks of treatment

 

Groups

Uric acid con. (mg/dL) Mean ± S.E

Pre-treatment

zero time

Post-treatment

Week 2

Week 4

CG

1.51±0.13

1.45±0.11

1.55±0.1

NGO

1.65±0.17

1.41±0.15

1.46±0.15

HG

2.16±0.23 b

2.87±0.16 b

*3.5±0.14b

HGO

2.88±0.2 b

2.74±0.24 b

2.96±0.22 b

* indicate significant differences at (p≤0.05) between time zero and treatment groups.

Small different letters indicate significant differences between control and treatment groups at (p≤0.05)

 

 Discussion

 

The treatment of rat groups with isolated Orexin-A for one month caused a significant decrease in TC, TG, VLDL-C and LDL-C concentration, these results are agreement with (28). This might be due to the role of OXA in activation of AMP-activity protein kinase (AMPK) by increasing the concentration of intracellular calcium (Ca+2) (1,29). AMPK inhibits HMG-CoA reductase and acetyl-CoA carboxylase which involved in the synthesis of cholesterol and de novo pathway of fatty acid and TG synthesis respectively (30), or because OXA decreases hormone-sensitive lipase (HSL) and inhibits lipolysis in adipose tissue (31), also OXA increases lipogenesis by decreasing the release of glycerol from adipose tissue and increasing glucose uptake (32). Also, it can be due to that Orexin-A promotes adiponectin secretion which increases LPL activity and VLDL-C receptors and decreases Apo CIII, so increases catabolism of VLDL-C and reduces serum TG (33).

On the other hand, the rats treated with isolated Orexin-A showed an increase in concentration of HDL-C and this might be due to that Orexin-A increases LPL activity which in turn increases HDL-C (32), or due to that Orexin-A promotes expression and secretion of adiponectin which correlates positively with HDL-C (34). In addition, there was a significant decrease in malondialdehyde concentration and this agrees with Butterick et al. (35) that Orexin-A decreases lipid peroxidation by its neuroprotective mechanisms due to the induction of the transcription factor hypoxia inducible factor-1α (HIF-1α) in the hypothalamus which decreased lipid peroxidation (36).

Glucose concentration decreased in treated rats and that constant with Skrzypski et al. (34), Orexin-A promotes glucose uptake and synthesis of glycogen in skeletal muscle. Orexin-A suppresses the secretion of glucagon thus, Orexin-A regulates the concentration of glucose and dysfunction in Orexin-A is an effective factor in homeostasis of glucose and induce of diabetes (8), while insulin increased slightly in NGO when treated with isolated Orexin-A (34). Feeding with the high-fat diet for long-time might cause hyperinsulinemia in HG, which constant with Barclay et al. (37). High-fat diet can cause reduction in the expression of Orexin-A in the hypothalamus, which exacerbates insulin resistance (3). Furthermore, HGO showed a significant decrease in insulin compared to HG after treatment and that is in agreement with Kaczmarek et al. (38), Orexin-A decreases hyperinsulinemia, enhancing insulin sensitivity and attenuates apoptosis of pancreatic β-cells by decrease the activity and production of caspase 3, which induces β-cells death (38).

While there were non-significant differences in AST, ALT activity, and uric acid concentration at NGO and HGO after treatment with Orexin-A, and this might be due to the time of treatment that might be not enough or the dose was not sufficient.

 

Conclusion

 

It was concluded that Orexin-A (isolated from human plasma) had an important role in the control of glucose and lipids metabolism, treatment of hyperinsulinemia and increasing insulin sensitivity in normal and hyperlipidemic rats. Orexin-A had a critical role in decreasing lipid peroxidation.

 

Acknowledgment

 

The authors are very grateful to the University of Mosul, College of Science for providing the facilities that helped improve the quality of this research

 

Conflict of interests

 

The authors declare no conflict of interest.

  1. Orexin A (isolated from plasma human) had important role in the control of glucose and lipid metabolism.
  2. Orexin A used in treatment of hyperinsulinemia and increasing of insulin sensitivity in normal and hyperlipidemic rats.
  3. Orexin A had a critical role in decreasing of lipid peroxidation.

  1. Wang C, Wang Q, Ji B, PanY, Xu C, Cheng B, Bai B, Chen J. The orexin / Receptor system :Molecular mechanism and therapeutic potential for neurological diseases. Front Mol Neurosci. 2018;11(220):1-16. DOI: 10.3389/fnmol.2018.00220
  2. Sakurai T, Amemiya A, Ishii M, Matsuzaki I, Chemelli RM. Orexins and orexin receptors: A family of hypothalamic neuropeptides and g protein-coupled receptors that regulate feeding behavior. Cell.1998;92:573-585. [available at]
  3. Jain S, Jain A K. Orexin neuropetides :Physiology and significance in food metabolism. Astro. 2016;3:148- 152. DOI: 10.4103/2349-0977.201002
  4. Khaldi S. Effects of acute heat and oxidative stress on the hepatic expression of orexin and its related receptors. Theses Dissertations. 2016: 1849. [available at]
  5. Chieffi S, Carotenuto M, Monda V, Valenzano A, Villano I, Precenzano F. Orexin system :The key for a healthy life. Front Physio. 2017;8(357): 1-9. DOI: 10.3389/fphys.2017.00357
  6. Graybill NL, Weissig V. A review of orexin’s unprecedented potential as a novel highly-specific treatment for various localized and metastatic cancers. SAGE Open Med. 2017;5:1-9. DOI: 10.1177/2050312117735774
  7.  Becquet L, Abad C, Leclercq M, Miel C, Jean L, Riou G, Couvineau A, Boyer O, Tan Y-V. Systemic administration of orexin A ameliorates established experimental autoimmune encephalomyelitis by diminishing neuroinflammation. J Neuroinflammation. 2019;16(64):1-12. [available at]
  8.  Alizadeh AA, Rahmani-nia F, Mohebbi H, Zakerkish M. Acute aerobic exercise and plasma levels of orexin a, insulin, glucose, and insulin resistance in males with type 2 diabetes. Jundishapur J Health Sci. 2016;8(1):e32217. DOI: 10.17795/jjhs-32217
  9.  Messina G, Dalia C, Tafuri D, Monda V, Palmieri F, Dato A, Russo A, Russo L, De Blasio S, Messina A, De Luca V, Chieffi S, Monda M. Orexin system modulates resting energy expenditure, autonomic nervous system and cardiovascular disease in menopause. J Anesth Clin Res. 2014;5(11):472. DOI: 10.4172/2155-6148.1000472
  10. Liu L, Wang Q, Liu A, Lan X, Huang Y, Zhao Z. Physiological implications of orexins/hypocretins on energy metabolism and adipose tissue development. ACS Omega. 2020;5(1):547-555. [available at]
  11.  Robyt FJ, White JB. Biochemical techniques theory and practice. USA: Books Cole Publishing Co; 1987. [available at]
  12. Tsuchimine S, Hattori K, Ota M, Hidese S, Teraishi T, Sasayama D, Hori H, Noda T, Yoshida S, Yoshida F, Kunugi H. Reduced plasma orexin-a levels in patients with bipolar disorder. Neuropsychiatr Dis Treat. 2019;15:2221-2230. [available at]  
  13.  Schacterle GR, Pollack RL. A simplified method for the quantitatiue assay of small amounts of protein biological material. J Anal Biochem.1973;51:654-655. DOI: 10.1016/0003-2697(73)90523-x
  14.  Rachh PR, Rachh MR, Ghadiya, Modi DC, Patel MN. Antihyperlipidemic activity of gymenma syslvestre r. br. leaf extract on rats feed with high cholesterol diet. Inter J Pharma. 2010;6(2):138-141. DOI: 10.3923/ijp.2010.138.14
  15.  Blais A, Drouin G, Chaumontet C, Voisin T, Couvelard A, Even PC, Couvineau A. Impact of orexin-a treatment on food intake, energy metabolism and body weight in mice. PLoS ONE. 2017;12(1):1-14. DOI: 10.1371/journal.pone.0169908
  16. Al-abdaly1 YZ, Saeed MG, Al-Hashemi HM. Effect of methotrexate and aspirin interaction and its relationship to oxidative stress in rats. Iraqi J Vet Sci. 2021;35(1):151-156. DOI: 10.33899/ijvs.2020.126490.1335
  17.  Burtis CA, Ashwood ER, Bruns DE. Tietz textbook of clinical chemistry and molecular diagnostics. 4th ed. USA: Elsevier Saunders; 2005. [available at]
  18.  Sacks BD. Tietz textbook of clinical chemistr. 2nd ED. Philadelphia: Saunders Co; 1994. [available at]
  19.  Maty HN. Effect of supplementation of rumen protected methionine and lysine on some physiological aspects of fattening calves. Iraqi J Vet Sci. 2021;35(1):177-181. DOI: 10.33899/ijvs.2020.126580.1344
  20.  Hassan MG, Abdullah TA. The effect of Propolis addition to broiler feeds on some blood biochemical parameters and intestinal flora. Iraqi J Vet Sci.2020;24(1):29-35. DOI: 10.33899/ijvs.2019.125483.1015
  21. Fischbach F. A manual of Laboratory and Diagnostic Tests. 7th ed. USA: Lippincott Williams and Wilkins; 2003. 472 p. [available at]
  22. Jameel AH, Mohammed MJ, Mahdi MS, Thal KM. Physiological effects of lactic acid bacteria against melamine induced toxicity in female albino rats. Iraqi J Vet Sci. 2021;35(1):1-7. DOI: 10.33899/ijvs.2020.126183.1259
  23. Al-Bajar SHA, Al- Akash MA, Ismail HKh. Experimental detection of antioxidant and atherogenic effects of grapes seeds extracts in rabbits. Iraqi J Vet Sci. 2019;33(2):243-249. DOI: 10.33899/ijvs.2019.162881
  24.  AL-Mashhadani ZI, Mukhlis AJA, A-Razaq AAS. Estimation of ALP, GPT and GOT activities in iraqi patients female with breast cancer. Ibn Al Haitham J for Pure and Appl Sci. 2012;25(1):1-3. [available at]
  25.  Koller PU, Tritschler W, Carstensen CA. Interference studies on the R eflotron system. Lab Med. 1989;13:399-402. [available at]
  26.  Fossati P, Prencipe L, Berti G. Use of 3,5-dichloro-2-hydroxybenzenesulfonic acid/4-aminophenazone chromogenic system in direct enzymic assay of uric acid in serum and urine. Clin Chem. 1980;26:227-231. DOI: 10.1093/clinchem/26.2.0227
  27.  Kirkwood BR. Essentials of Medical Statistics. 1st Ed. Black well Scientific Publication, Oxford;1988:43-56. [available at]
  28.  Abd El-Ghany MA, Hanaa FE, Nagib RM, Hagar ME. Effect of Orexin drug and some minerals on rats exposed to obesity and ALzheimer disease. WJPPS. 2017;6(1):21-37. DOI: 10.20959/wjpps20171-8217
  29.  Wu WN, Wu PF, Zhou J, Guan XL, Zhang Z, Yang YJ, Long LH, Xie N, Chen J, Wang F. Orexin-A activates hypothalamic AMP-activated protein kinase signaling through a Ca2+-dependent mechanism involving voltage-gated L-type calcium channel. Mol Pharmacol. 2013;84(6):879-887. [available at]
  30.  López M, Nogueiras R, Tena-Sempere M, Dieguez C. Hypothalamic AMPK:A canonical regulator of whole-body energy balance. Nat Rev Endocrinol. 2016;12(7):421-432. DOI: 10.1038/nrendo.2016.67
  31.  Digby JE, Chen J, Tang JY, Lehnert H, Matthews RN, Randeva HS. Orexin receptor expression in human adipose tissue:effects of orexin-a and orexin-b. J Endocrinol. 2006;191(1):129-36. DOI: 10.1677/joe.1.06886
  32.  Pruszynska-Oszmalek E, Kolodziejski PA, Kaczmarek P, Sassek M. Orexin a but not orexin b regulates lipid metabolism and leptin secretion in isolated porcine adipocytes. Domest Anim Endocrinol. 2018;63. DOI: 10.1016/j.domaniend.2017.12.003
  33.  Yanai H, Yoshida H. Beneficial effects of adiponectin on glucose and lipid metabolism and atherosclerotic progression:Mechanisms and perspectives. Int J Mol Sci. 2019;20(1190):1-25. DOI: 10.3390/ijms20051190
  34.  Skrzypski M, Billert M, Nowak KW, Strowski MZ. The role of orexin in controlling the activity of the adipo-pancreatic axis. J Endocrinol. 2018;238:R95-108. [available at]
  35.  Butterick TA, Nixon JP, Billington CJ, Kotz CM. Orexin A decreases lipid peroxidation and apoptosis in a novel hypothalamic cell model. Neurosci Lett. 2012;524(1):30-34. DOI: 10.1016/j.neulet.2012.07.002
  36. Butterick TA, Billington CJ, Kotz CM  Nixon JP. Orexin:Pathways to obesity resistance?. Rev Endocr Metab Disord. 2013;14(4):357-364. DOI: 10.1007/s11154-013-9259-3
  37.  Barclay JL, Shostak A, Leliavski A, Tsang AH, Jöhren O, Muller-Fielitz H, Landgraf D, Naujokat N, Van der Horst GTJ, Oster H. High-fat diet-induced hyperinsulinemia and tissue-specific insulin resistance in Cry-deficient mice. Am J Physiol Endocrinol Metab. 2013;304(10):1053-1063. DOI: 10.1152/ajpendo.00512.2012
  38. 38.  Kaczmarek P, Skrzypski M, Pruszynska-Oszmalek E, Sassek M, Kolodziejski PA, Billert M. Chronic orexin-a (Hypocretin-1) treatment of type 2 diabetic rats improves glucose control and beta-cell functions. JPP. 2017;68(5):669-681. [available at]

  • Article View: 756
  • PDF Download: 284