افزایش حساسیت کیت الایزای گلیکوپروتئین مرتبط با آبستنی به‌منظور تشخیص سریع‌تر آبستنی در گاو شیری

ایوبی, علیرضا; شاکری, ملک; ژندی, مهدی; قورچیان, هدایت الله

doi:10.22067/ijasr.v1397i1.72079

افزایش حساسیت کیت الایزای گلیکوپروتئین مرتبط با آبستنی به‌منظور تشخیص سریع‌تر آبستنی در گاو شیری

نوع مقاله : علمی پژوهشی- فیزیولوژی

نویسندگان

¹ گروه علوم دامی، پردیس کشاورزی و منابع طبیعی، دانشگاه تهران، تهران، ایران

² دانشگاه تهران

10.22067/ijasr.v1397i1.72079

چکیده

تشخیص سریع آبستنی یکی از فاکتورهای کلیدی مؤثر در افزایش بازدهی تولیدمثل در گاوهای شیری است. گلیکوپروتئینهای مرتبط با آبستنی توسط جفت گاوهای آبستن تولید و تراوش میشوند و در سالهای اخیر در تشخیص آبستنی گاو مورداستفاده قرارگرفته‌اند. با توجه به محدود شدن روش سونوگرافی و سایر روشهای مورداستفاده به حدود روز 30 پس از تلقیح، هدف از این پژوهش کاهش زمان تشخیص آبستنی با استفاده از نانوکیت تشخیص گلیکوپروتئین مرتبط با آبستنی بود. برای این منظور، یک نانوکیت الایزای ساندویچی برای تشخیص گلیکوپروتئینهای مرتبط با آبستنی طراحی و ساخته شد. نانوذرات مگنت به‌منظور افزایش سطح تماس بین آنتیبادی و آنتیژن مورداستفاده قرار گرفت و از ویژگی میل اتصالپذیری بالا بین استرپتاویدین و بیوتین برای اتصال آنتیبادی به نانوذرات استفاده شد. در این پژوهش تعداد 58 گاو شیری نژاد هلشتاین انتخاب و تکنیک همزمانسازی و تلقیح مصنوعی انجام شد. نمونههای خون گاوها از روز 18 تا 30 پس از تلقیح روزانه جمعآوری و پس‌از انتقال به آزمایشگاه نمونههای پلاسمای خون جداسازی شد و وضعیت آبستنی در روز 30 و 60 آبستنی به ترتیب با استفاده از سونوگرافی و لمس راست‌روده بررسی شد. غلظت گلیکوپروتئینهای مرتبط با آبستنی در نمونههای پلاسما با استفاده از نانوکیت اندازهگیری و با استفاده از نرم‌افزار SAS آنالیز شد. نتایج نشان داد، غلظت گلیکوپروتئینها از روز 21 تا 30 پس از تلقیح به‌صورت وابسته به روز در گاوهای آبستن افزایش مییابد. همچنین اولین افزایش چشمگیر در غلظت گلیکوپروتئینها در روز 23 پس از تلقیح مشاهده شد و گاوهایی که تا روز 60 پس از تلقیح آبستن تشخیص داده شدند، در روز 24 پس از تلقیح غلظت گلیکوپروتئین بیشتری در مقایسه با گاوهای غیرآبستن داشتند (به ترتیب ng/ml 15/0±28/2 و 18/0±7/0) .بر اساس این نتایج، غلظت گلیکوپروتئین در روز 24 آبستنی میتواند نشانهای زودهنگام از وضعیت آبستنی در گاوهای شیری باشد. بااین‌حال، مطالعات بیشتری لازم است تا کارایی این روش تأیید شود.

کلیدواژه‌ها

20.1001.1.20083106.1398.11.1.4.4

عنوان مقاله [English]

Enhancement of Pregnancy-Associated Glycoprotein ELISA Kit Sensitivity for Early Pregnancy Diagnosis in Dairy Cows

نویسندگان [English]

Ali Reza Ayoubi ¹
Malek Shakeri ²
Mahdi Zhandi ²
Hedayatollah Ghourchian ²

¹ Department of Animal Sciences, Campus of Agriculture and Natural Resources, University of Tehran, Tehran, Iran

² Tehran

چکیده [English]

Introduction[1] Early pregnancy diagnosis is a key factor in shortening the calving interval through identifying the non-pregnant animals to rebreed them at the earliest time after artificial insemination (AI). Bovine pregnancy-associated glycoproteins (PAGs) are produced by mono- and binucleated trophoblastic cells of the pregnant cow’s placenta. Detection of PAG in the maternal circulation has been used to accurately diagnose pregnancy. Several studies have used commercial PAG tests to determine pregnancy status in dairy cows and heifers. Pregnancy-specific protein B (PSPB) or PAG1 was the first identified member of the PAG family and commercial diagnostic kits still utilize PAG1 as a pregnancy marker. In recent years, the use of nanoparticles in immunosensors has been increased their sensitivity and increased the traceability of antigen-antibody responses. Due to the limitation of using ultrasound and other methods for pregnancy diagnosis in the first 30 days after inoculation, the aim of this study was to apply the pregnancy-associated glycoprotein detection method in order to reduce the time of pregnancy diagnosis. For this purpose, a sandwich ELISA immunosensor was designed for the detection of PAGs and named Nano-kit.
Materials and Methods Magnetic nanoparticles were used to enhance the contact area between antibodies and antigens. Streptavidin and biotin were used for their high binding affinity to bind the antibodies and enzymes to nanomagnet. The synchronization technique and artificial insemination (AI) was performed in Holstein dairy cows (n = 58). Pregnancy status was determined by transrectal ultrasonography (30 days after AI). Furthermore, transrectal palpation was carried out by a skilled veterinarian on day 60 after AI to determine the pregnancy status of cows which were previously detected as pregnant. For PAG1 analysis, blood samples (10 mL) were collected daily from 18 to 30 days after AI. Blood samples were collected by venipuncture from the tail vein into evacuated tubes containing EDTA as an anticoagulant and were processed 1–3 h after sampling. The samples were centrifuged and plasma samples were transferred to fresh tubes and were stored at −20°C until they were assessed. Plasma concentrations of PAG1 were determined by nano- kit and commercial kit. Differences in the level of PAG-1 were evaluated by repeated measures ANOVA (SAS 9.4) over days of sampling (18 to 30). Values of PAG-1 in pregnant cows were considered as the reference. Data were presented as means ± SD and differences were considered significant at P<0.05.
Results and Discussion By doing Ovsynch protocol, of the 54 cows enrolled in the first AI, 48% (26/54) of synchronized cows were diagnosed pregnant 30 days after AI using transrectal ultrasonography. From day 30 to 60 after AI, 73% (19/26) of cows maintained pregnant and the pregnancy loss from day 32 to 60 after AI was 17% (7/26). Measurement of different concentrations of PAG1 (standards) using a commercial kit and nano-kit showed that nano-kit were more sensitive than the commercial kit and detected a concentration of 0.03 ng/mL. The first increase in plasma concentration of PAG1 occurred on d 23 after AI in pregnant cows and PAG1 concentration in serum increased from d 22 to 30 after AI and it was affected by day (P < 0.001). Cows diagnosed as pregnant on day 60 after AI had a higher PAG concentration on day 24 compared with cows that were diagnosed as non-pregnant (2.28 ± 0.15 ng/mL vs 0.7 ± 0.18 ng/mL, respectively; P < 0.001). Accuracy in predicting pregnancy at day 24 of gestation based on circulating concentration of PAGs was 95 % for 1.93 ng/mL. Generally, based on the results of this study, the cows with mean PAG1 concentration more than 2.28 ± 0.07 ng/mL on 24 and mean PAG1 concentration more than 9.2 ± 0.07 ng/mL on day 30 of pregnancy, remained pregnant until day 60 of pregnancy. Furthermore, in cows diagnosed pregnant on day 24 of pregnancy but were not pregnant on day 30 after AI, blood plasma PAG1 concentration on day 24 after AI was 1.03 ± 0.66 ng/ml.
Conclusion Based on these results, PAG concentrations at day 24 of gestation are higher in pregnant compared to non-pregnant dairy cows and could be applied in diagnosing pregnancy at day 24 of gestation; however, further study is needed to determine the potential of PAG1 in pregnancy diagnosis in dairy cows.

کلیدواژه‌ها [English]

abortion
Glycoprotein
Nano-kit
Pregnant cow

مراجع

1- Aires, M., K. Dekagi, V. Dantzer, and A. Yamada. 2014. Bovine placentome development during early pregnancy. Pages 390–396 in Microscopy: Advances in Scientific Research and Education. A. Mendez-Vilas, ed. Formatex, Badajoz, Spain.

2- Ambrose, D. J., J. P. Kastelic, R. Corbett, P. A. Pitney, H. V. Petit, J. A. Small, and P. Zalkovic. 2006. Lower pregnancy losses in lactating dairy cows fed a diet enriched in a-linolenic acid. Journal of Dairy Science, 89 (8): 3066–3074.

3- Barański, W., S. Zduńczyk and T. Janowski. 2012. Late embryonic and foetal losses in eight dairy herds in north-east Poland. Polish Journal of Veterinary Sciences, 15 (4): 735-739.

4- Breukelman, S. P., Z. Perenyi, M. A. Taverne, H. Jonker, G.C. Weijden, P.L. Vos, L. de Ruigh, S.J. Dieleman, J.F. Beckers and O. Szenci. 2012. Characterization of pregnancy losses after embryo transfer by measuring plasma progesterone and bovine pregnancy associated glycoprotein-1 concentrations. Veterinary Journal, 194 (1): 71–76.

5- Chaffaux, S., G.N.S. Reddy, F. Valon and M. Thibier. 1986. Transrectal real-time ultrasound scanning for diagnosing pregnancy and for monitoring embryonic mortality in dairy cattle. Animal Reproduction Science, 10 (3): 193–200.

6- El Amiri, B., N. M. Sousa, A. Alvarez Oxiley, D. Hadarbach and J. F. Beckers. 2015. Pregnancy-associated glycoprotein (PAG) concentration in plasma and milk samples for early pregnancy diagnosis in Lacaune dairy sheep. Research in Veterinary Science, 99: 30-36.

7- Green, J. A., T. E. Parks, M. P. Avalle, B. P. Telugu, A. L. McLain, A. J. Peterson, W. McMillan, N. Mathialagan, R. R. Hook, S. Xie and R. M. Roberts. 2005. The establishment of an ELISA for the detection of pregnancy-associated glycoproteins (PAGs) in the serum of pregnant cows and heifers. Theriogenology, 63 (5):1481–1503.

8- Green, J. A., S. Xie, X. Quan, B. Bao, X. Gan, N. Mathialagan, J. F. Beckers and R. M. Roberts. 2000. Pregnancy-associated bovine and ovine glycoproteins exhibit spatially and temporally distinct expression patterns during pregnancy. Biology of Reproduction, 62 (6):1624–1631.

9- Guirado Dantas, F., K. E. Zechiel, S. T. Reese, G. A. Franco, J. D. Rhinehart and K. G. Pohler. 2016. Using Pregnancy-Associate Glycoprotein (PAG) on Day 24 as Marker for Pregnancy on Beef Cattle. Journal of Animal Science, 95 (1): p.14. (Abstract).

10- Hernandez, J. A., C. A. Risco, F. S. Lima and J. E. P. Santos. 2012. Observed and expected combined effects of clinical mastitis and low body condition on pregnancy loss in dairy cows. Theriogenology, 78 (1): 115–121.

11- Kafi, M., M. Zibaei and A. Rahbari. 2007. Accuracy of estrous detection in cows and its economic impacts on Shiraz dairy farms. Iranian Journal of Veterinary Research, 8 (2): 131-137. (In Persian).

12- Karen, A., N. M. Sousa, J. F. Beckers, A. C. Bajcsy, J. Tibold, I. Madl and O. Szenci. 2015. Comparison of a commercial bovine pregnancy-associated glycoprotein ELISA test and a pregnancy-associated glycoprotein radiomimmunoassay test forearly pregnancy diagnosis in dairy cattle. Animal Reproduction Science, 159: 31–37.

13- Lawson, B. C., A. H. Shahzad, K. A. Dolecheck, E. L. Martel, K. A. Velek, D. L. Ray, J. C. Lawrence and W. J. Silvia. 2014. A pregnancy detection assay using milk samples: Evaluation and considerations. Journal of Dairy Science, 97 (10): 6316–6325.

14- Lopez-Gatius, F., J. M. Garbayo, P. Santolaria, J. Yaniz, A. Ayad, N. M. de Sousa and J. F. Beckers. 2007. Milk production correlates negatively with plasma levels of pregnancy associated glycoprotein (PAG) during the early fetal period in high producing dairy cows with live fetuses. Domestic Animal Endocrinology, 32 (1): 29–42.

15- Nourani, S., H. Ghourchian and S. M. Boutorabi. 2013. Magnetic nanoparticle-based immunosensor for electrochemical detection of hepatitis B surface antigen. Analytical Biochemistry, 441 (1): 1–7.

16- Pohler, K., T. Geary, C. Johnson, J. Atkins, E. Jinks, D. Busch, J. A. Green, M. D. MacNeil and M. F. Smith. 2013. Circulating bovine pregnancy associated glycoproteins are associated with late embryonic/fetal survival but not ovulatory follicle size in suckled beef cows. Journal of Animal Science, 99 (2): 1584-1594.

17- Pohler, K. G., J. A. Green, T. W. Geary, R. F. G. Peres, M. H. C. Pereira, J. L. M. Vasconcelos and M. F. Smith. 2015. Predicting Embryo Presence and Viability. Rodney D. G. and Fuller W. B. ed. Advances in Anatomy, Embryology and Cell Biology. 216: 253-270.

18- Pohler, K. G., M. H. Pereira, F. R. Lopes, J. C. Lawrence, D. H. Keisler, M. F. Smith, J. L. Vasconcelos and J. A. Green. 2016. Circulating concentrations of bovine pregnancy-associated glycoproteins and late embryonic mortality in lactating dairy herds. Journal of Dairy Science, 9 (2): 1584-1594.

19- Reese, S., M. Pereira, J. Vasconcelos, M. Smith, J. Green and T. Geary. 2016. Markers of pregnancy: How early can we detect pregnancies in cattle using pregnancy-associated glycoproteins (pags) and micrornas? Animal Reproduction, 13 (3): 200-208.

20- Reese, S. T., M. C. Pereira, J. L. Edwards, J. L. Vasconcelos and K. G. Pohler. 2018. Pregnancy diagnosis in cattle using pregnancy associated glycoprotein concentration in circulation at day 24 of gestation, Theriogenology, 106:178-185.

21- Rezaee Roodbari, A., h. Kohram and I. Dirandeh. 2015. Evaluating economic losses associated with delayed conception in dairy cows. Iranian Journal of Animal Science, 46 (2): 151-158. (In Persian).

22- Ricci, A., P. D. Carvalho, M. C. Amundson, R. H. Fourdraine, L. Vincenti and P. M. Fricke. 2015. Factors associated with pregnancy associated glycoprotein (PAG) levels in plasma and milk of Holstein cows during early pregnancy and their effect on the accuracy of pregnancy diagnosis. Journal of Dairy Science, 98 (4): 2502–2514.

23- Sasser, R. G., C. A, Ruder., K. A, Ivani., J. E, Butler., and W. C. Hamilton.1986. Detection of pregnancy by radioimmunoassay of a novel pregnancy-specific protein in serum of cows and a profile of serum concentrations during gestation. Biology of Reproduction, 35: 936–942.

24- Silva, E., R. A. Sterry, D. Kolb, N. Mathialagan, M. F. McGrath, J. M. Ballam and P. M. Fricke. 2009. Effect of interval to resynchronization of ovulation on fertility of lactating Holstein cows when using transrectal ultrasonography or a pregnancy-associated glycoprotein enzyme-linked immunosorbent assay to diagnose pregnancy status. Journal of Dairy Science, 92 (8): 3643–3650.

25- Szenci, O., J. F. Beckers, P. Humblot, J. Sulon, G. Sasser, M. A. Taverne, J. Varga, R. Baltusen and G. Schekk. 1998. Comparison of ultrasonography, bovine pregnancy-specific protein B, and bovine pregnancy-associated glycoprotein 1 tests for pregnancy detection in dairy cows. Theriogenology, 50 (1): 77-88.

26- Touzard, E., P. Reinaud, O. Dubois, C. Guyader-Joly, P. Humblot, C. Ponsart and G. Charpigny. 2013. Specific expression patterns and cell distribution of ancient and modern pag in bovine placenta during pregnancy. Reproduction, 146 (4): 347-362.

27- Wallace, R. M., K. G. Pohler, M. F. Smith and J. A. Green. 2015. Placental PAGs: gene origins, expression patterns, and use as markers of pregnancy. Reproduction, 149 (3): 115-126.

28- Zhang, H., M. Xiaoming, H. Shuisheng, L. Yue G. Longhua, Q. Bin, L. Zhenyu and C. Guonan. 2016. Highly sensitive visual detection of Avian Influenza A (H7N9) virus based on the enzyme-induced metallization. Biosensors and Bioelectronics, 79: 874–880.

29- Zhou, C. H., J. Y. Zhao, D. W. Pang and Z. L. Zhang. 2014. Enzyme-Induced Metallization as a Signal Amplification Strategy for Highly Sensitive Colorimetric Detection of Avian Influenza Virus Particles. American Chemical Society, 86 (5): 2752−2759.