Cryptosporidium sp. is a protozoan parasite that can cause gastrointestinal infection known as cryptosporidiosis. This parasite is responsible for veterinary problems particularly enteric illness outbreaks in livestock animals [
1]. In farm animals, cattle are recognized as the most common mammalian species that can be infected by
Cryptosporidium [
2-
4]. It is known since 1980s that calves and cattle have been identified as an important reservoir for zoonotic
Cryptosporidium spp. [
5]. The major
Cryptosporidium sp. that infects calves is
Cryptosporidium parvum which can cause severe watery, yellowish, and foulsmelling acute diarrhea that may lead to morbidity and mortality [
6].
In Malaysia, little is known about
Cryptosporidium spp. infection in cattle especially in Kuantan, Pahang. The first report of the incidence of C. parvum among calves in Malaysia was reported by Lee et al. [
7] who found 4 out of 11 diarrheic calves in Johor had the infection. For more than a decade, there was no study done on
Cryptosporidium in cattle in Malaysia until 2005. Farizawati et al. [
8] reported that
Cryptosporidium oocysts from cattle had contaminated rivers in Sungai Langat Basin, and Halim et al. [
9] reported the first data on
Cryptosporidium deer-like genotype from cattle in Selangor.
Since there are few studies on Cryptosporidium infection in cattle in Kuantan area, the present study attempted to identify the occurrence of Cryptosporidium in cattle and to find out the association of the occurrence with age groups of cattle and the presence of diarrhea.
This cross-sectional study was conducted at a dairy cattle farm (3°43'01.7"N 103°00'41.6"E) located in Ulu Lepar, Kuantan Pahang, Malaysia (
Fig. 1). Kuantan is located at east coast of Peninsular Malaysia, and the climate is tropical rainforest climate. The average maximum temperature is 31˚C, and the average minimum temperature is 23˚C [
10].
Ethical clearance was obtained from the Institutional Animal Care and Use Committee (IACUC), International Islamic University of Malaysia (IIUM). A total of 151 fecal samples were collected between May 2015 and August 2015. The fecal samples were collected according to the age group; 55 samples from calves (less than 12 months), 45 samples from yearlings (12-24 months), and 51 samples from adults (more than 24 months). The fecal samples were collected directly from the rectum of the animals by using sterile plastic gloves. The samples were transferred into stool containers and preserved in 10% formalin. For each animal, the sampling date, age, identification tag, gender, and consistency of feces (score 0-1, 0: absence of diarrhea, 1: presence of diarrhea) were recorded. The samples were immediately transported to the laboratory and stored at 4˚C before analysis.
The fecal samples were processed by using formol-ether concentration technique based on the method of Allen and Ridley [
11] with slight modifications. Approximately 1 g of stool sample was emulsified in 4 ml of 10% formal saline by using an applicator stick. The suspension was filtered through a sieve or gauze into a beaker. A 3-4 ml formal saline was added followed by an addition of 2.5 ml diethyl ether to the formalized solution. The samples were centrifuged at 500 g for 30 sec and continued with 500 g for another 20 sec. Finally, the supernatant was removed, and 1 or 2 drops of the resuspended pellet were smeared onto a microscope slide and stained with modified Ziehl Neelsen for
Cryptosporidium examination. Later, the slides were air-dried and viewed under the x 1,000 objective lens of a light microscope.
Statistical analysis were performed by using Statistical Package for Social Sciences for windows SPSS (version 16). Chi-square test was used to compare the occurrence of infection between the age group of cattle, and Fisher’s exact test was used to find the association between the occurrence of infection and the presence of diarrhea. A P-value of <0.05 was considered as the level of significance.
Referring to
Table 1, the results showed that the prevalence of
Cryptosporidium infection in calves less than 1 year was the highest compared to those in yearling and adult cattle. However, there was no significance difference (
P>0.05) between the age group and occurrence of
Cryptosporidium. Analysis indicated that the occurrence of
Cryptosporidium in calves less than 1 year was the highest with the percentage of 20.0% while in yearling and adult cattle, the percentage of occurrence was 15.6 % and 11.8%, respectively.
Of the total 151 samples collected, 23 were diarrheic samples, and 128 were non-diarrheic ones. As shown in
Table 2, from 23 diarrheic samples, 4 (17.4%) were positive for infection while out of 128 non-diarrheic samples, 20 (15.6%) were positive for
Cryptosporidium oocysts. However, the results showed that there is no significant difference between the presence of diarrhea and occurrence of infection.
Microscopic analysis of 151 fecal samples showed that 24 cattle (15.9%) were positive for
Cryptosporidium infection. Studies on
Cryptosporidium infection in cattle population have been conducted from other researchers. The results were almost similar with former studies in Egypt, Poland, and China with the overall prevalence of 13.6%, 17.0%, and 16.0%, respectively [
12-
14]. So far, there were only 2 data collected from Pahang area which was done in Kuantan and Jerantut, Pahang. Yap et al. [
15] reported a lower prevalence of
Cryptosporidium infection in Kuantan and Jerantut areas, Pahang as compared to the present study which was 2.7% and 2.9%, respectively. Another study conducted in Johor by Muhid et al. [
16] reported that the overall prevalence of
Cryptosporidium infection in pre-weaned and post-weaned calves was 27.1% (65/240) indicating a higher prevalence of infection compared to the present study. The dissimilarity in the prevalence among countries may be due to a different amount of stocking rate and different management system in the farm [
17].
In summary, calves less than 1 year recorded the highest occurrence of
Cryptosporidium sp. followed by yearlings and adult cattle. Similar high prevalences of
Cryptosporidium in young calves compared to adult cattle have been reported by other studies [
18-
20]. This finding is most likely due to the low immune system function of young neonates as suggested by Maurya et al. [
21]. Young animals have become more vulnerable to infection and disease, while infections in adults usually show no symptoms [
22]. This result is in agreement with other studies which found no statistically significant association between infection and diarrhea [
23-
26]. On the other hand, other previous studies have reported that
Cryptosporidium sp. infection is associated with the occurrence of diarrhea [
27].
The present study has succeeded to achieve the objective of the research. This research has indicated that there is Cryptosporidium infection in cattle in Kuantan, Pahang. The findings suggested that control and prevention measures must be taken in order to reduce the infection among cattle. It is highly important to control the infection since cattle infected with parasites may serve as potential reservoirs of the infection to other animals and humans especially animal handlers. Good management practices and proper hygiene managements are the most effective weapons to combat Cryptosporidium spp. infections.
ACKNOWLEDGEMENTS
This study was funded by RAGS grant no. 13-010-0073. The authors are highly grateful to the management and technical staff of Department of Veterinary Services, Kuantan Malaysia for their kind cooperation during the study period. The technical assistance from laboratory assistance of Kulliyyah of Allied Health Science and Integrated Centre for Research Animal Care and Use (ICRACU) are highly appreciated. We would also express our gratitude to the respective farmers for the cooperation during this study.
Conflict of interest
We declare that we have no conflict of interest.
REFERENCES
2. Zhang W, Wang R, Yang F, Zhang L, Cao J. Distribution and genetic characterizations of Cryptosporidium spp. in pre-weaned dairy calves in northeastern China’s Heilongjiang Province. PLoS One 2013;8:e54857.
3. Cui Z, Wang R, Huang J, Wang H, Zhao J, Luo N, Li J, Zhang Z, Zhang L. Cryptosporidiosis caused by
Cryptosporidium parvum subtype IIdA15G1 at a dairy farm in northwestern China. Parasit Vectors 2014;7:529.
4. Huang J, Yue D, Qi M, Wang R, Zhao J, Li J, Shi K, Wang M, Zhang L. Prevalence and molecular characterization of Cryptosporidium spp. and Giardia duodenalis in dairy cattle in Ningxia, northwestern China. Vet Res 2014;10:292.
5. Izadi M, Jonaidi-Jafari N, Saburi A, Eyni H, Rezaiemanesh MR, Ranjbar R. Cryptosporidiosis in Iranian farm workers and their household members: a hypothesis about possible zoonotic transmission. J Trop Med 2014;Article ID 405875.
6. Lendner M, Daugschies A.
Cryptosporidium infections: molecular advances. Parasitology 2014;141:1511-1532.
7. Lee CC, Sheik-Omar AR, Rasool N. Finding of Cryptosporidium parvum oocysts in diarrhoeic calves in Malaysia. Trop Biomed 1989;6:145-146.
8. Farizawati S, Lim YA, Ahmad RA, Fatimah CT NI, Siti-Nor Y. Contribution of cattle farms towards river contamination with
Giardia cysts and
Cryptosporidium oocysts in Sungai Langat Basin. Trop Biomed 2005;22:89-98.
9. Halim NA, Plutzer J, Bakheit MA, Karanis P. First report of
Cryptosporidium deer-like genotype in Malaysian cattle. Vet Parasitol 2008;152:325-329.
10. Malaysian Meteorological Department. General Climate of Malaysia. Retrieved on 12 May 2014 (from
http://www.met.gov.my)
12. Amer S, Zidan S, Adamu H, Ye J, Roellig D, Xiao L, Feng Y. Prevalence and characterization of
Cryptosporidium spp. in dairy cattle in Nile River delta provinces, Egypt. Exp Parasitol 2013;135:518-523.
13. Rzeżutka A, Kaupke A. Occurrence and molecular identification of
Cryptosporidium species isolated from cattle in Poland. Vet Parasitol 2013;196:301-306.
14. Qi M, Wang H, Jing B, Wang D, Wang R, Zhang L. Occurrence and molecular identification of
Cryptosporidium spp. in dairy calves in Xinjiang, northwestern China. Vet Parasitol 2015;212:404-407.
15. Yap NJ, Koehler AV, Ebner J, Tan TK, Lim YAL, Gasser RB. Molecular analysis of
Cryptosporidium from cattle from five states of Peninsular Malaysia. Mol Cell Probes 2016;30:39-43.
16. Muhid A, Robertson I, Ng J, Ryan U. Prevalence of and management factors contributing to
Cryptosporidium sp. infection in preweaned and post-weaned calves in Johor, Malaysia. Exp Parasitol 2011;127:534-538.
17. Regassa A, Gizaw O, Abunna F, Abebe R, Beyene D, Megersa B, Debela E, Asmare K, Skierve E.
Cryptosporidium in calves, lambs and kids at Haramaya, eastern Ethiopia. Ethiop Vet J 2013;17:81-94.
18. Santín M, Trout JM, Fayer R. A longitudinal study of cryptosporidiosis in dairy cattle from birth to 2 years of age. Vet Parasitol 2008;155:15-23.
19. Al-Zubaidi ; MTHS. Prevalence of some Cryptosporidium species in cattle in Baghdad, Iraq. AL-Qadisiya J Vet Med Sci 2012;11:(qu.edu.iq).
20. Ouchene N, Ouchene-Khelifi NA, Zeroual F, Benakhla A, Adjou K. Study of Giardia spp., Cryptosporidium spp. and Eimeria spp. infections in dairy cattle in Algeria. J Parasitol Vector Biol 2014;6:61-65.
21. Maurya PS, Rakesh RL, Pradeep B, Kumar S, Kundu K, Garg R, Ram H, Kumar A, Banerjee PS. Prevalence and risk factors associated with
Cryptosporidium spp. infection in young domestic livestock in India. Trop Anim Health Prod 2013;45:941-946.
22. O'Donoghue PJ.
Cryptosporidium and cryptosporidiosis in man and animals. Int J Parasitol 1995;25:139-195.
23. Silverlås C, Emanuelson U, de Verdier K, Björkman C. Prevalence and associated management factors of
Cryptosporidium shedding in 50 Swedish dairy herds. Prev Vet Med 2009;90:242-253.
24. Maikai BV, Umoh JU, Kwaga JK, Lawal IA, Maikai VA, Cama V, Xiao L. Molecular characterization of
Cryptosporidium spp. in native breeds of cattle in Kaduna State, Nigeria. Vet Parasitol 2011;178:241-245.
25. Faleke OO, Yabo YA, Olaleye AO, Dabai YU, Ibitoye EB. Point prevalence of
Cryptosporidium oocyst in calves grazing along River Rima Bank in Sokoto Nigeria. Pak J Biol Sci 2014;17:443-446.
26. Azami M. Prevalence of
Cryptosporidium infection in cattle in Isfahan, Iran. J Eukaryot Microbiol 2007;54:100-102.
27. Jafari R, Maghsood AH, Fallah M. Prevalence of Cryptosporidium infection among livestock and humans in contact with livestock in Hamadan District, Iran, 2012. J Res Health Sci 2013;13:86-89.
Fig. 1.
The sampling site in Kuantan, Pahang, Malaysia.
Table 1.
The occurrence of Cryptosporidium in cattle in different age groups of cattle
Age |
Total sample |
Positive |
Occurrence (%) |
P-value |
Calves |
55 |
11 |
20 |
|
Yearling |
45 |
7 |
15.6 |
0.51 |
Adult |
51 |
6 |
11.8 |
|
Table 2.
The association between the presence of diarrhea and the occurrence of infection
Age |
Total sample |
Positive |
Occurrence (%) |
P-value |
Diarrheic |
23 |
4 |
17.4 |
0.764 |
Non-diarrheic |
128 |
20 |
15.6 |
|