PLANT BIOLOGY
ANIMAL BIOLOGY
SUBSCRIPTION
E-SUBSCRIPTION
 
MAP
MAIN PAGE

 

 

 

 

Karseka S.A., Davydova E.E., Novikova T.V., Voyevodina Yu.A., Ryzhakina T.P., Shipulin G.A. Optimization of the method for detecting Cryptosporidium spp. DNA in fecal samples from calves using PCR and comparison of the obtained results with the results of microscopy. Sel'skokhozyaistvennaya Biologiya [Agricultural Biology], 2025, Vol. 60, № 4, p. 756-771.
(how to cite this article)

doi: 10.15389/agrobiology.2025.4.756eng

UDC: 579.62:57.08:577.2

 

OPTIMIZATION OF THE METHOD FOR DETECTING Cryptosporidium spp. DNA IN FECAL SAMPLES FROM CALVES USING PCR AND COMPARISON OF THE OBTAINED RESULTS WITH THE RESULTS OF MICROSCOPY

S.A. Karseka1 , E.E. Davydova1, T.V. Novikova2,
Yu.A. Voyevodina2, T.P. Ryzhakina2, G.A. Shipulin1

1Centre for Strategic Planning and Management of Biomedical Health Risks of the Federal Medical and Biological Agency, 10/1, ul. Pogodinskaya, Moscow, 119121 Russia, e-mail skarseka@cspmz.ru (✉ corresponding author), EDavydova@cspfmba.ru, Shipulin@cspfmba.ru;
2VereshchaginVologda State Dairy Farming Academy, 2, ul. Shmidta,
s. Molochnoe, Vologda, 160555 Russia, e-mail parazitology@yandex.ru, yulkavo@mail.ru, vologdatp@yandex.ru

ORCID:
Karseka S.A. orcid.org/0000-0002-9988-6918
Voyevodina Yu.A. orcid.org/0000-0001-6204-1914
Davydova E.E. orcid.org/0000-0003-2926-0490
Ryzhakina T.P. orcid.org/0000-0001-5841-3770
Novikova T.V. orcid.org/0000-0001-7894-3656
Shipulin G.A. orcid.org/0000-0002-3668-6601

Final revision received December 03, 2024
Accepted March 26, 2025

Intestinal infections cause significant damage to cattle farms; one of the most acute problem is cryptosporidiosis. But the early diagnostics can significantly reduce the incidence of cryptosporidiosis in neonatal calves. The most sensitive are molecular methods based on polymerase chain reaction (PCR), but an inappropriate DNA preparation protocol can reduce it. Currently, this problem prevents the spread of the PCR in the routine diagnosis of parasitosis. In the present study, for the first time in Russia various methods of DNA extraction from feces were compared and the most optimal one was selected: with preliminary bead-beating and DNA sorption on the spin-column. Further this method was used as basic for real-time PCR developed for diagnosing cryptosporidiosis. Our new system was tested on real samples from calves and compared with classical microscopy; that was our target. 20 fecal samples from calves (Holstein breed) were collected directly from rectum on farms located in Vologda region, in 2023, after cryptosporidiosis outbreak. Each sample was divided in two aliquots, first for microscopy detection by Ziehl-Neelsen staining using Diakhim kit («Abris+», Russia), second was fixed in 70% ethanol for molecular detection. Stained sliders were observed with Olympus cx33 light microscope (Olympus, Japan) at x1000 magnification using oil immersion. The degree of infection was assessed. To develop a PCR-based test-system primers for 18S rRNA Cryptosporidium spp. Crypt-F 5´-TAATCAAGAACGAAAGTTAGGGGA-3´ Crypt-R 5´-GAGTAAGGAACAACCTCCAATCT-3´, probe Crypt-P R6G-5´-ATGGTTAAGACTACGACGGTATCTGA-3´-BHQ1 were designed allow detection of all species of Cryptosporidium. A few modified DNA extraction protocols of fecal samples were evaluated: using conventional concentrates HEM (LLC HEM, Russia), concentrates HEM without formaldehyde or washing by phosphate buffer without concentration. Then QIAamp PowerFecal Pro DNA Kit (QIAgen, Germany) were used to extract DNA from the received fecal sediment, including a stage of DNA purification on spin columns. Clarified fecal extract was obtained in accordance with the guidelines MU 1.3.2569-09, DNA was extracted by precipitation method using AmpliTest RIBO-prep kit (Centre for Strategic Planning and Management of Biomedical Health Risks, of the Federal medical and biological agency, Russia). As a result sample preparation using HEM concentrators had no advantages, and sample preparation in the presence of formalin had a negative effect on PCR. Obtaining the supernatant of the clarified fecal extract and then DNA extraction using AmpliTest RIBO-prep kit allow only poor detection of Cryptosporidium due to the high loss of oocytes in the sedimentary fraction of feces. Extraction of DNA from crude feces using bead-beating and purification on spin columns proved to be effective for receiving of parasitic DNA. Homogenization of feces, cell disruption and release of nucleic material are carried out during bead-beating on a TissueLyser LT homogenizer (QIAgen, Germany). Cryptosporidium oocysts were detected in 15 of 20 samples, but 4 of them have extremely low concentration of oocysts. Using the most effective PCR-based assay, 15 of 20 samples also were positive. Accordingly, all samples with high and medium level of Cryptosporidium oocysts were PCR positive. But two samples with low level of oocyst have different results of microscopy and PCR, one was determined to be weakly positive by PCR (Ct> 40) although microscopy was negative, and conversely, the second one was weakly positive by microscopy (“+”), but determined as negative by PCR. Additionally commercially kit for DNA extraction and PCR detection DNA Cryptosporidium spp. FBioNucleo (Fractal Bio, Russia) was tested. Cryptosporidium spp. was detected in 9 of 20 samples, all weakly positive and two medium positive samples were determined as negative. Thus, the FBioNukleo kit showed lower sensitivity than the assay proposed. Finally, an effective assay has been designed including bead-beating and purification on spin columns, which provides the sensitivity of PCR similar to the microscopy with Ziehl-Neelsen staining.  

Keywords: Cryptosporidium spp., feces, cattle, DNA extraction protocol, PCR, molecular diagnostics.

 

REFERENCES

  1. Pudovkin D.N., Shchepetkina S.V., Karpenko L.Yu., Rishko O.A. Bolezni molodnyaka krupnogo rogatogo skota: prakticheskie rekomendatsii [Diseases of young cattle: practical recommendations]. St. Petersburg, 2019 (in Russ.).
  2. Jessop E., Li L., Renaud D.L., Verbrugghe A., Macnicol J., Gamsjäger L., Gomez D.E. Neonatal calf diarrhea and gastrointestinal microbiota: etiologic agents and microbiota manipulation for treatment and prevention of diarrhea. Veterinary Sciences, 2024, 11(3): 108 CrossRef
  3. Muktar Y., Mamo G., Tesfaye B., Belina D. A review on major bacterial causes of calf diarrhea and its diagnostic method. Journal of Veterinary Medicine and Animal Health, 2015, 7(5): 173-185 CrossRef
  4. Safiullin R.T., Shibitov S.K. V sbornike: Teoriya i praktika bor’bi s parazitarnimi boleznyami [In: Theory and practice of combating parasitic diseases]. Moscow, 2019: 564-569 CrossRef (in Russ.).
  5. Louro M., Bexiga R., da Fonseca I.P., Gomes J. Detection and molecular characterization of Cryptosporidium spp. in dairy calves in Lisbon and Tagus Valley, Portugal. Veterinary Parasitology: Regional Studies and Reports, 2024, 47: 100964 CrossRef
  6. Certad G., Gantois N., Merlin S., Martel S., Even G., Viscogliosi E., Audebert C., Chabé M. Frequency and molecular identification of Cryptosporidium in adult prim'holstein dairy cattle farms in the North of France. Microorganisms, 2024, 12(2): 335 CrossRef
  7. Rzeżutka A., Kaupke A. Cryptosporidium infections in asymptomatic calves up to 4 months in Poland: a cross-sectional population study. Scientific Reports, 2023, 13(1): 20997 CrossRef
  8. Ouakli N., Belkhiri A., de Lucio A., Köster P.C., Djoudi M., Dadda A., Khelef D., Kaidi R., Carmena D. Cryptosporidium-associated diarrhoea in neonatal calves in Algeria. Veterinary Parasitology: Regional Studies and Reports, 2018, 12: 78-84 CrossRef
  9. de Alba P., Garro C., Florin-Christensen M., Schnittger L. Prevalence, risk factors and molecular epidemiology of neonatal cryptosporidiosis in calves: the Argentine perspective. Current Research in Parasitology & Vector-Borne Diseases, 2023, 4: 100147 CrossRef
  10. Chetvertnov V.I., Kits E.A. Sel’skokhozyaystvenniy zhurnal, 2022, 4(15): 121-127 (in Russ.).
  11. Safiullin R.T., Shibitov S.K., Safiullin R.R. V sbornike: Teoriya i praktika bor’bi s parazitarnimi boleznyami [In: Theory and practice of combating parasitic diseases]. Moscow, 2023: 420-425 CrossRef (in Russ.).
  12. Klimova E.S., Mkrtchyan M.E., Babintseva T.V. V sbornike: Teoriya i praktika bor’bi s parazitarnimi boleznyami [In: Theory and practice of combating parasitic diseases]. Moscow, 2019: 273-277 CrossRef (in Russ.).
  13. Reshetnikova A.D., Klimova E.S. Rossiyskiy parazitologicheskiy zhurnal, 2023, 17(1): 99-104 CrossRef (in Russ.).
  14. Shaw H.J., Innes E.A., Morrison L.J., Katzer F., Wells B. Long-term production effects of clinical cryptosporidiosis in neonatal calves. International Journal for Parasitology, 2020, 50(5): 371-376 CrossRef
  15. Nikitin V.F. Rossiyskiy parazitologicheskiy zhurnal, 2007, 1: 87-97 (in Russ.).
  16. Schinwald M., Creutzinger K., Keunen A., Winder C.B., Haley D., Renaud D.L. Predictors of diarrhea, mortality, and weight gain in male dairy calves. Journal of Dairy Science, 2022, 105(6): 5296-5309 CrossRef
  17. Santin M. Cryptosporidium and Giardia in Ruminants. Veterinary Clinics of North America: Food Animal Practice, 2020, 36(1): 223-238 CrossRef
  18. Mahmoudi M., Hazrati Tapeh K., Abasi E., Sayyadi H., Aminpour A. Prevalence and genetic characterization of Cryptosporidium in pre-weaned cattle in Urmia (Northwestern Iran). Journal of Infection in Developing Countries, 2021, 15(3): 422-427 CrossRef
  19. Kirillov E.G. Uchenie zapiski Kazanskoy gosudarstvennoy akademii veterinarnoy meditsini im. N.E. Baumana, 2014, 218(2): 128-131 (in Russ.).
  20. Caffarena R.D., Casaux M.L., Schild C.O., Fraga M., Castells M., Colina R., Maya L., Corbellini L.G., Riet-Correa F., Giannitti F. Causes of neonatal calf diarrhea and mortality in pasture-based dairy herds in Uruguay: a farm-matched case-control study. Brazilian Journal of Microbiology, 2021, 52(2): 977-988 CrossRef
  21. Brar A.P.S., Sood N.K., Kaur P., Singla L.D., Sandhu B.S., Gupta K., Narang D., Singh C.K., Chandra M. Periurban outbreaks of bovine calf scours in Northern India caused by Cryptosporidium in association with other enteropathogens. Epidemiology and Infection, 2017, 145(13): 2717-2726 CrossRef
  22. Aslanova M. Zdorov’e naseleniya i sreda obitaniya, 2015, 7(268): 49-52 (in Russ.).
  23. Jaiswal V., Brar A.P.S., Sandhu B.S., Singla L.D., Narang D., Leishangthem G.D., Kaur P. Comparative evaluation of various diagnostic techniques for detection of Cryptosporidium infection from the faecal samples of diarrhoeic bovine calves. Iranian Journal of Veterinary Research, 2022, 23(3): 247-254.
  24. Gerace E., Lo Presti V.D.M., Biondo C. Cryptosporidium infection: epidemiology, pathogenesis, and differential diagnosis. European Journal of Microbiology & Immunology, 2019, 9(4): 119-123 CrossRef
  25. Novikova T.V., Ribakova N.A., Lemekhov P.A., Kryazhev A.L., Mashava E.M. Kriptosporidioz telyat (ekologiya, etiologiya, epizootologiya, klinika, diagnostika, lechenie, profilaktika): metodicheskie ukazaniya [Cryptosporidiosis of calves (ecology, etiology, epizootology, clinical signs, diagnostics, treatment, prevention): guidelines]. Vologda-Molochnoe, 2003 (in Russ.).
  26. Brar A.P.S., Sood N.K., Singla L.D., Kaur P., Gupta K., Sandhu B.S. Validation of Romanowsky staining as a novel screening test for the detection of faecal cryptosporidial oocysts. Journal of Parasitic Diseases: Official Organ of the Indian Society for Parasitology, 2017, 41(1): 260-262 CrossRef
  27. Vejdani M., Mansour R., Hamzavi Y., Vejdani S., Nazeri N., Michaeli A. Immunofluorescence assay and PCR analysis of cryptosporidium oocysts and species from human feacal specimens. Jundishapur Journal of Microbiology, 2014, 7(6): e10284 CrossRef
  28. Weinreich F., Hahn A., Eberhardt K.A., Feldt T., Sarfo F.S., Di Cristanziano V., Frickmann H., Loderstädt U. Comparison of three real-time PCR assays targeting the SSU rRNA gene, the COWP gene and the DnaJ-like protein gene for the diagnosis of Cryptosporidium spp. in stool samples. Pathogens, 2021, 10(9): 1131 CrossRef
  29. Papaiakovou M., Pilotte N., Baumer B., Grant J., Asbjornsdottir K., Schaer F., Hu Y., Aroian R., Walson J., Williams S.A. A comparative analysis of preservation techniques for the optimal molecular detection of hookworm DNA in a human fecal specimen. PLoS Neglected Tropical Diseases, 2018, 12(1): e0006130 CrossRef
  30. Ayana M., Cools P., Mekonnen Z., Biruksew A., Dana D., Rashwan N., Prichard R., Vlaminck J., Verweij J.J., Levecke B. Comparison of four DNA extraction and three preservation protocols for the molecular detection and quantification of soil-transmitted helminths in stool. PLoS Neglected Tropical Diseases, 2019, 13(10): e0007778 CrossRef
  31. Lombardelli J.A., Tomazic M.L., Schnittger L., Tirant K.I. Prevalence of Cryptosporidium parvum in dairy calves and GP60 subtyping of diarrheic calves in central Argentina. Parasitology Research, 2019, 118(7): 2079-2086 CrossRef
  32. Devyatov A.A., Davydova E.E., Luparev A.R., Karseka S.A., Shuryaeva A.K., Zagainova A.V., Shipulin G.A. Design of a protocol for soil-transmitted helminths (in light of the Nematode Toxocara canis) DNA extraction from feces by combining commercially available solutions. Diagnostics, 2023, 13(13): 2156 CrossRef
  33. Leutenegger C.M., Lozoya C.E., Tereski J., Andrews J., Mitchell K.D., Meeks C., Willcox J.L., Freeman G., Richmond H.L., Savard C., Evason M.D. Comparative study of a broad qPCR panel and centrifugal flotation for detection of gastrointestinal parasites in fecal samples from dogs and cats in the United States. Parasites & Vectors, 2023, 16(1): 288 CrossRef
  34. Masalkova Yu.Yu. Rossiyskiy parazitologicheskiy zhurnal, 2014, 1: 52-56 (in Russ.).
  35. Izadi S., Mohaghegh M.A., Ghayour-Najafabadi Z., Azami M., Mirzaei F., Namdar F., Mohebali M., Leshan Wannigama D., Hejazi S.H. Frequency and molecular identification of Cryptosporidium species among immunocompromised patients referred to hospitals, Central Iran, 2015-16. Iranian Journal of Parasitology, 2020, 15(1): 31-39.
  36. Mammeri M., Chevillot A., Chenafi I., Thomas M., Julien C., Vallée I., Polack B., Follet J., Adjou K.T. Molecular characterization of Cryptosporidium isolates from diarrheal dairy calves in France. Veterinary Parasitology, Regional Studies and Reports, 2019, 18: 100323 CrossRef
  37. Enbom T., Suominen K., Laitinen S., Ollgren J., Autio T., Rimhanen-Finne R. Cryptosporidium parvum: an emerging occupational zoonosis in Finland. ActaVeterinaria Scandinavica, 2023, 65(1): 25 CrossRef
  38. Knox M.A., Garcia-R J.C., Ogbuigwe P., Pita A., Velathanthiri N., Hayman D.T.S. Absence of Cryptosporidium hominis and dominance of zoonotic Cryptosporidium species in patients after Covid-19 restrictions in Auckland, New Zealand. Parasitology, 2021, 148(11): 1288-1292 CrossRef

 

back

 


CONTENTS

 

Full article PDF (Rus)