Study on spatio-temporal prevalence and hematological attributes of bovine Babesiosis in cattle population of Layyah, Southern Punjab, Pakistan

Ahmad, A.; Ali, Z.; Lashari, M.H.

doi:10.1590/1678-4162-13002

ABSTRACT

The present study was conducted to investigate the spatiotemporal prevalence of bovine babesiosis in cattle population (n=376) of Layyah, Pakistan as affected by location, age, breed, gender, and seasons. Blood samples were collected aseptically and assessed for babesiosis through microscopy and PCR, and through automated analyzer for hematological attributes. Overall results of prevalence through PCR in cattle population showed significantly (P≤0.05) lower prevalence of 19.4% (n=72/376) as compared to 37.2% (n=140/276) through microscopy. None of the studied cattle from Cholistani breed were Babesia-positive. However, significantly (P≤0.05) higher prevalence was noticed for crossbred cattle (46.7%, n= 50/107) followed by that in Friesian (16.1%, n= 10/62), Jersey (7%, n= 5/71) and Sahiwal (6.9%, n= 7/101) cattle breeds. Female cattle (19.5%, n= 55/281) and age group 1 (Up to 2 years) (40%, n= 42/105) had higher prevalence of Babesia as ascertained through PCR in comparison to their counterpart groups. Significantly (P≤0.05) higher prevalence of 35.9% (n=60/167) was shown in summer as compared to that in winter season (5.7%, n= 12/209). All the positive samples produced the 490bp amplicons specific and typical for Babesia bigemina. Hemoglobin concentration, erythrocytic count, hematocrit and mean corpuscular volume were significantly (P≤0.05) lower in babesia-positive cattle as compared to healthy ones.

Keywords:
Babesiosis; spatiotemporal prevalence; PCR

RESUMO

O presente estudo foi realizado para investigar a prevalência espaço-temporal da babesiose bovina na população bovina (n=376) de Layyah, Paquistão, conforme afetada por localização, idade, raça, gênero e estações. As amostras de sangue foram coletadas assepticamente e avaliadas quanto à babesiose por meio de microscopia e PCR, e por meio de um analisador automatizado para atributos hematológicos. Os resultados gerais da prevalência por PCR na população bovina mostraram uma prevalência significativamente (P≤0,05) menor de 19,4% (n=72/376) em comparação com 37,2% (n=140/276) por microscopia. Nenhum dos bovinos estudados da raça Cholistani foi positivo para Babesia. No entanto, uma prevalência significativamente maior (P≤0,05) foi observada em bovinos mestiços (46,7%, n= 50/107), seguida por bovinos das raças Friesian (16,1%, n= 10/62), Jersey (7%, n= 5/71) e Sahiwal (6,9%, n= 7/101). O gado fêmea (19,5%, n= 55/281) e a faixa etária 1 (até 2 anos) (40%, n= 42/105) apresentaram maior prevalência de Babesia, conforme verificado por PCR, em comparação com seus grupos homólogos. Uma prevalência significativamente maior (P≤0,05) de 35,9% (n=60/167) foi mostrada no verão em comparação com a do inverno (5,7%, n=12/209). Todas as amostras positivas produziram os amplicons de 490 pb específicos e típicos de Babesia bigemina. A concentração de hemoglobina, a contagem de eritrócitos, o hematócrito e o volume corpuscular médio foram significativamente (P≤0,05) menores nos bovinos positivos para babesia em comparação com os saudáveis.

Palavras-chave:
Babesiose; prevalência espaço-temporal; PCR

INTRODUCTION

Bovine babesiosis is highly pathogenic and the signs and symptoms of its infection are varied depending upon the infected species, age, climatic conditions of the area, tick population, and immune system of the host. However, the general indications include fever, anemia, jaundice and hemoglobinurea. Though the signs and symptoms of its infection are varied depending upon the infected species, age, climatic conditions of the area, tick population, and immune system of the host as mentioned above, however, various techniques (both conventional and molecular) are in vogue. Traditionally, its diagnosis is attained through direct identification of the parasite in infected RBCs of the host, using appropriately stained blood smears. Infected RBCs are hard to find in acute infections owing to sequestration of RBCs to the walls of the capillaries, hence serological (Immunoblotting and immunofluorescent testing) and molecular diagnostic tests (standard PCR, nested PCR, rtPCR, reverse line blot, loop-mediated isothermal amplification) have made a stronger footing being highly specific, sensitive, and precise (Ozubek et al., 2020OZUBEK, S.; BASTOS, R.G.; ALZAN, H.F.; INCI, A. et al. Bovine babesiosis in Turkey: impact, current gaps, and opportunities for intervention. Pathogens, v.9, p.1041, 2020.; Sivakumar et al., 2020SIVAKUMAR, T.; TUVSHINTULGA, B.; KOTHALAWALA, H.; SILVA, S.S. et al. Host range and geographical distribution of Babesia sp. Mymensingh. Transbound. Emerg. Dis., v.67, p.2233-2239, 2020.).

Over the years, livestock has emerged as a main sub-sector of agriculture in Pakistan with its share of 60.09% to agriculture value addition and 11.5% to the GDP during the financial year 2021 (Finance Division, 2021). A growth of 3.06% in this sub-sector has been reported by the Government of Pakistan. Livestock engages more than 8 million rural families providing them with 35-40% of their income. Hence, it can be dubbed as the most vital sector for the socio-economic uplift of rural communities in specific and whole country in general.

The geographical location of Pakistan being in the Warm Climate Zones (WCZs) of the world as per UNO is endemic to high prevalence of tick-borne diseases especially babesiosis. Lowered productivity and high mortality as a feature of this infection imply a grave economic burden especially on rural livestock farmers of the country. Extensive studies have been conducted regarding tick prevalence in Pakistan with highest prevalence reported for cattle (28.2%) by that in sheep (18.8%), buffaloes (14.7%) and goats (12.3%) (Ghosh et al., 2007GHOSH, S.; BANSAL, G.C.; GUPTA, S.C.; RAY, D. et al. Status of tick distribution in Bangladesh, India and Pakistan. Parasitol. Res., v.101, p.207-216, 2007.; Jabbar et al., 2015JABBAR, A.; ABBAS, T.; SANDHU, Z.U.D.; SADDIQI, H.A. et al. Tick-borne diseases of bovines in Pakistan: major scope for future research and improved control. Parasites Vectors, v.8, p.1-13, 2015.). These varying levels of tick prevalence in Pakistan have been attributed to varying geo-climatic conditions, lifestyles of livestock keepers, livestock production systems, farmer awareness, management practices and governmental interventions (Karim et al., 2017KARIM, S.; BUDACHETRI, K.; MUKHERJEE, N.; WILLIAMS, J. et al. A study of ticks and tick-borne livestock pathogens in Pakistan. PLoS Negl. Trop. Dis.., v.11, p.e0005681, 2017.; Muhammad et al., 2008MUHAMMAD, G.; NAUREEN, A.; FIRYAL, S.; SAQIB, M. Tick control strategies in dairy production medicine. Pak. Vet. J., v.28, p.43, 2008.). The warm climate of the country allied with higher tick prevalence makes it vulnerable to bovine babesiosis. Extensive research work has been reported on prevalence of bovine babesiosis from various cities and provinces of Pakistan. From Punjab, Pakistan, the research work on its prevalence has mostly emanated from cities of upper Punjab. However, not much work has yet been carried out in cities of Lower/Southern Punjab (a newly proposed province of Pakistan) which includes 13 major cities. The present research work has thus been devised with an aim to assess situation analysis/spatiotemporal prevalence of bovine babesiosis using both traditional diagnostic technique and PCR in various cattle breeds (Sahiwal, Cholistani, Crossbred, Friesian, Jersey) being reared in district Layyah of Southern Punjab, Pakistan. Furthermore, it also aims to compare hematological attributes between Babesia-infected and non-infected animals.

MATERIALS AND METHODS

The study was conducted at the District Layyah, Southern Punjab, Pakistan. Layyah is 72^nd biggest city of Pakistan lying within the Dera-Ghazi-Khan Division (Figure 1). Covering an area of 6291 km², it lays at latitude of 30° N and longitude of 70° E. Its geographic characteristic is sandy land as it is entrapped between River Indus and River Chenab. It has a dry climate with scanty rainfall with a wide temperature variation of 7-41°C with an average temperature of 25.2°C (Ashraf et al., 2021ASHRAF, S.; PARVEEN, A.; MUHAMMAD AWAIS, M.; GILLANI, Q. et al. A report on molecular detection and phylogenetic evaluation of Anaplasma marginale in ticks and blood samples collected from cattle in District Layyah in Punjab (Pakistan). Curr. Microb., v.78, p.274-281, 2021.). In summer the temperature may reach 48°C. The recorded annual precipitation for Layyah is 236.3mm.

District Layyah has three Tehsils namely Layyah, Karor and Choubara and 44 Union Councils (Figure 2). Private livestock farms were identified and registered under the study from each of the three Tehsils. Qualitative/quantitative data regarding the traits of growth, performance, nutritional plain, housing, production systems, health status, veterinary services provision, and identification of constraints for the bovine rearing were acquired through structural interviews with owners, predefined questionnaires, focus group discussions, and participatory rural appraisal.

Figure 1
Geo-location of Layyah District, Southern Punjab, Pakistan

Figure 2
Map of Layyah indicating its three Tehsils and 44 Union Councils.

The cattle population (n=376) of both genders and belonging to different age and breed groups was randomly selected and sampled throughout the year of 2021 to ascertain the effect of location, age, breed, gender, and seasons. The tehsil-wise study population of bovines is presented in Table 1 whereas the age, gender, breed, and season-wise study population of cattle is given in Table 2.

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Table 1
The tehsil-wise cattle population (n=376) incorporated in the study

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Table 2
The age, gender, and breed-wise grouping of cattle (n=376) population incorporated in the study

Prior to blood collection, a thorough on-site clinical examination was carried out on each animal and deductions were made on the basis of anamnesis, clinical examination, and signs and symptoms. The prevalence of ticks on animal body was confirmed through visual and manual inspection. Blood was collected aseptically in three aliquots from the coccygeal vein of the animal after a thorough restraint and was placed in EDTA containing vacutainers (BD Vacutainers®, Becton Dickinson, USA). Timing, personnel, and method of restraint for blood collection were maintained same throughout the study period to minimize stress in animals (Figure 3). The three aliquots of each blood sample from an animal were transported in ice packs to: a) Paraveterinary Institute, Karor Lal Easan, Layyah, South Punjab, (sub-campus of University of Veterinary and Veterinary Animal Sciences, Lahore, Pakistan) for slide preparation, microscopy and hematological analysis, b) College of Veterinary and Animal Sciences (UVAS), Jhang (sub-campus of University of Veterinary and Veterinary Animal Sciences, Lahore, Pakistan) for conventional PCR.

A thin blood smear was prepared on clean, grease-free glass slides, air dried, fixed through methanol and stained using Field’s stain (Chunge et al., 1989CHUNGE, C.N.; NGIGE, S.; BWIBO, C.R.A; MULEGA, P.C. et al. A rapid staining technique for Leishmania parasites in splenic aspirate smears. Ann. Trop. Med. Parasitol. v. 4, p.361-364, 1989.). This blood film was examined under the oil immersion lens of a trinocular microscope (100X) fitted with a 16 MP camera (LaboMed Inc. LB 243, USA) for presence of babesia species and morphological alterations of blood cells. Various hematological attributes viz. Hemoglobin concentration (Hb), Total Erythrocyte Count (TEC), Packed Cell Volume (PCV), Total Leukocyte Count (TLC), Neutrophils, Eosinophils, Basophils, Monocytes and Lymphocytes were analyzed through a veterinary hematology analyzer (Vet Exigo, H400, Boule Diagnostics AB, Sweden).

DNA extraction was carried out using a commercial kit (Gene Jet Whole Blood DNA Purification Kit, Thermo-fisher Scientific, USA; catalogue no. K0782) following the procedure described by the manufacturer. Briefly, 200µL of whole blood sample was added in a 1.5mL Eppendorf tube along with 400µL of lysis solution and 20µL of Proteinase-K. This was incubated at 56°C for 10 minutes in shaking water-bath after vortexing the mixture. After addition of 200 µL of 96-100% ethanol, the mixture was transferred in Gene JET Genomic DNA purification column inserted in a collection tube. The column was centrifuged after addition of ethanol, wash buffer 1 and wash buffer 2 at different speed and time intervals for removal of debris. An elution buffer was added to elute the DNA from silicon sieve of spin column. Finally, the DNA was collected in 1.5mL Eppendorf tubes after centrifugation and stored in -20°C freezer for further processing.

For conventional PCR, BJ1 (5’-GTC-TTG-TAA-TTG-GAATGA-TGG-3’) and BN2 (5’-TAG-TTT-ATG-GTT-AGG-ACT-ACG-3’) primers were used along with PCR Master Mix (2 × Ace-Taq Master Mix (Dye Plus) P412). The PCR mixture of 20µL was comprised of (PCR master mix 10µL, Primer BJ1 1µL, Primer BN2 1µL, Template DNA 5µL, and nuclease free water 3µL). A total of 35 cycles (Initial heating and denaturation at 95°C for 3 minutes, denaturation at 95°C for 30sec, annealing at 52°C for 30sec, extension at 72°C for 30sec and final extension at 72°C for 5minutes) were conducted in Thermocycler (Bio-Rad, USA). Positive control samples were taken from Molecular Parasitology Laboratory, Veterinary Faculty, UAF, Pakistan, whereas sterile distilled water was used as a negative control.

Figure 3
Representative gel of the samples showing specificity of 490amplicon for Babesia bigemina in infected animals

The PCR products along with positive and negative controls were analyzed using 50 bp and 100bp DNA ladder on 2% agarose gel containing ethidium bromide at the rate of 0.5µg/µL of gel in 1X TAE buffer. About 10µL of PCR product was loaded in agarose gel for visualization. The gel electrophoresis was performed in gel documentation system (Bio-Rad, USA) at 110V, and 400 amp (maximum) for 35 minutes or until the dye migrated into two third of gel. Finally, the gel was visualized, and image was taken with the help of UV illuminator (Biostep, Germany).

All the collected data was sorted based on location, age, breed, gender, and seasons. Regarding age, the animals were grouped as G1= Up to 02 Years, G2= 03-04 Years, and G3= 05-06 Years. The cattle breeds included Sahiwal (n=101), Cholistani (n=35), Crossbred (n=107), Friesian (n=62) and Jersey (n=71). The seasons were designated as summer (April to September), and winter (October to March). Descriptive statistics were implied to attain frequencies, percentages, and measures of central tendency. Regarding prevalence, percentages were deduced, and results were presented as odds ratio with their 95% confidence intervals. Difference of prevalence between location, age, breed, gender, and seasons was deducted through Chi-square test keeping P≤0.05 as statistically significant. All the hematological attributes were expressed as means (±SE). The difference of hematological attributes between Babesia-positive and Babesia-negative animals was deducted through unpaired t-test. Predictive values were determined through sensitivity and specificity of blood smear examination and PCR test. All the above statistical analyses were carries out through Statistical Package for Social Sciences (V19, IBM, USA).

RESULTS

The on-site diagnosis/field survey revealed that regarding cattle breeds, the crossbred, Friesian and Jersey cattle showed severe and typical clinical signs of pyrexia, anorexia, nervous signs, elevated pulse rate, anemia, hyperpnea, jaundice, pale conjunctiva/vaginal membrane and hemoglobinuria. Generalized poor demeanor of the body was also observed in some animals. The Sahiwal cattle, on the other hand, revealed milder symptoms of pyrexia and anorexia only. On the contrary, it was noticed that none of the Cholistani breed of cattle showed any of the typical signs and symptoms related to babesiosis.

An overall prevalence of 37.2% (n=140/376) was observed in cattle population of the present study using stained blood smear microscopy. Breed-wise results for cattle indicated an overall higher (P≤0.05) prevalence of 64.5% (n=44/62) for Friesian followed by 51.4% (n=55/107), 43.6% (n=31/71) and 7.9% (n=8/101) for crossbred, Jersey and Sahiwal breeds of cattle, respectively. The lowest prevalence was noticed for Cholistani cattle breed bring 5.7% (n=2/35). Regarding age, Group 1 (Up to 02 Years) had significantly (P≤0.05) higher prevalence of 57.1% (n=60/105) followed by 39.4% (n=60/152) and 16.8% (n=20/119) for Group 2 and 3, respectively. Females had significantly (P≤0.05) higher prevalence (42.7%, n=120/281) as compared to that in males (21.0%, n=20/95). A significantly (P≤0.05) higher prevalence of bovine babesiosis in cattle was noticed during summer season being 47.9% (n=80/167) as compared to 28.7% (n=60/209) in winter season.

Overall results of prevalence as attained through PCR in cattle population (n=376) showed a significantly (P≤0.05) higher prevalence of 19.4% (n=72/376) through PCR as compared to 37.2% (n=140/276) through microscopy. Breed, tehsils, gender, seasons, and age-wise results have been tabulated in Table 3. None of the studied cattle from Cholistani breed were Babesia-positive. However, significantly (P≤0.05) higher prevalence was noticed for crossbred cattle (46.7%, n= 50/107) followed by that in Friesian (16.1%, n= 10/62), Jersey (7%, n= 5/71) and Sahiwal (6.9%, n= 7/101) cattle breeds. Regarding tehsils, Layyah had highest prevalence of 30.7% (n=43/140) followed by the other two tehsils of Karor (14.4%, n= 18/125) and Choubara (9.9%, n= 11/111). Female cattle (19.5%, n= 55/281) and age group 1 (Up to 2 years) (40%, n= 42/105) had higher prevalence of Babesia as ascertained through PCR in comparison to their counterpart groups. Similarly, a significantly (P≤0.05) higher prevalence of 35.9% (n=60/167) was shown in summer as compared to that in winter season (5.7%, n= 12/209).

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Table 3
Overall prevalence of bovine babesiosis in cattle population (n=376) for Layyah District, Southern Punjab, Pakistan as ascertained through PCR

The results of prevalence attained through stained slide microscopy and PCR were significantly different (P≤0.05) from each other being higher for microscopy. All the positive samples produced the 490bp amplicons specific and typical for Babesia bigemina (Figure 3).

The sensitivity, specificity, positive predictive and negative predictive values for blood smear examination were 8.9, 45.1, 1.8 and 80.6%, respectively. Similar values for PCR were 91.0, 54.8, 19.3 and 98.1%, respectively.

The overall mean (±SE) values of various hematological attributes in Babesia-positive and negative cattle are given in Table 4. All the values of healthy non-infected cattle were within the reference ranges described previously in different studies.

Results revealed that Hb concentration, TEC, PCV and MCV were significantly (P±0.05) lower in babesia-positive cattle as compared to healthy ones. However, the TLC and lymphocytes were higher (P≤0.05) for infected cattle as compared to healthy, negative ones.

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Table 4
Overall mean (±SE) values of hematological attributes between Babesia-positive and negative cattle (n=376) of Layyah District, Southern Punjab, Pakistan

DISCUSSION

Results regarding clinical examination of cattle during the on-site/field survey revealed that the crossbred, Friesian and Jersey cattle showed severe and typical clinical signs of pyrexia, anorexia, nervous disturbance, elevated pulse rate, anemia, hyperpnea, jaundice, pale conjunctiva/vaginal membrane and hemoglobinurea. Signs and symptoms shown in Babesia-infected-animals have been studied extensively and two main factors are associated with their severity being virulence of species/strain, and host vulnerability (depending upon its age, gender, season, physiological status, and immunological condition) (Chaudhry et al., 2010CHAUDHRY, Z.I.; SULEMAN, M.; YOUNUS, M.; ASLIM, A. Molecular detection of Babesia bigemina and Babesia bovis in crossbred carrier cattle through PCR. Pak. J. Zool., v.42, p.201-204, 2010.). B. bovis is highly pathogenic and virulent as compared to B. bigemina as provided by earlier studies. Similarly, African, Asian, and Israeli strains have been reported to be highly virulent as compared to Australian strains (Friedhoff, 2018FRIEDHOFF, K.T. Transmission of babesia: Babesiosis of domestic animals and man. [Boca Raton]: CRC Press, 2018. p.23-52.). The signs and symptoms noticed in infected cattle of the present study coincide with earlier studies. It has also been reported that anemia allied with hemoglobinuria may cause abortions in female pregnant cattle (Iseki et al., 2010ISEKI, H.; ZHOU, L.; KIM, C.; INPANKAEW, T. et al. Seroprevalence of Babesia infections of dairy cows in northern Thailand. Vet. Parasitol., v.170, p.193-196, 2010.). The higher severity of signs and symptoms noticed in infected crossbred and exotic breeds (Friesian and Jersey) of the present study are also in line with previous studies. While studying exotic cattle in Australia similar signs for babesiosis have been reported (Aziz et al., 2014AZIZ, K.A.; KHALIL, W.; MAHMOUD, M.; HASSAN, N. et al. Molecular characterization of babesiosis infected cattle: Improvement of diagnosis and profiling of the immune response genes expression. Globo Vet., v.12, p.197-206, 2014.). In another study it has been reported that vaccinated cattle are highly unlikely to show any symptoms of babesiosis (Schlögl et al., 2020SCHLÖGL, K.S.; HIESEL, J.A.; WOLF, R.; KOPACKA, I. et al. Spatiotemporal cluster and incidence analysis of cattle mortality caused by bovine babesiosis in Styria, Austria, between 1998 and 2016. Parasitol. Res., v.119, p.1117-1123, 2020.), however it was still endorsed that all animals may thoroughly be inspected for clinical signs at the beginning of and in middle of summer season (Holzheu et al., 2016HOLZHEU, E.M.; DELBECC, S.; BAUMGARTNER, W.; HOFER, J. In cattle in a field trial-investigations on effectivity and compatibility. Berl. Munch. Tierarztl. Wochenschr., v.129, p.495-499, 2016.). A study from Pakistan, though conducted on theileriosis has also reported similar signs and symptoms for crossbred and exotic cattle breeds (Saeed et al., 2016SAEED, Z.; IQBAL, F.; HUSSAIN, M.; SHAIKH, R.S. et al. Molecular prevalence and haematology of tropical theileriosis in Cholistani cattle from nomadic herds of the Cholistan desert, Pakistan. Kafkas Üniv. Vet. Fak. Derg., v.22. p.281-286, 2016.). Similar study conducted on prevalence of babesiosis in Friesian and Jersey cattle breeds of Livestock Experimental Station, Bhunike, Punjab, Pakistan has also reported severe signs and symptoms of babesiosis in these exotic cattle breeds (Zahid et al., 2005ZAHID, I.; LATIF, M.; BALOCH, K. Incidence and treatment of theileriasis and babesiasis. Pak. Vet. J., v.25, p.137, 2005.). The severity of signs and symptoms in cross bred and exotic cattle breeds seems to be an innate genetic characteristic of these breeds. The comparative hematological profile assessed between Bos indicus and Bos taurus (exotic) cattle breeds in various studies clearly indicate substantially lower hematological attributes (especially TEC and PCV) as compared to indigenous native cattle breeds which may be a plausible cause of the severity in signs and symptoms for infected exotic cattle breeds (Saeed et al., 2016). This aspect of hematological differences will be discussed in detail ahead.

In the present study, the Sahiwal cattle showed milder symptoms of pyrexia and anorexia only, whereas Cholistani breed of cattle showed none of the typical signs and symptoms for babesiosis. Sahiwal and Cholistani breed of cattle are amongst the 15 indigenous, humped, zebu breeds of cattle in Pakistan (Khan et al., 2008KHAN, M.S.; REHMAN, Z.; KHAN, M.A.; AHMAD, S. Genetic resources and diversity in Pakistani cattle. Pak. Vet. J., v.28, p.95-102, 2008.). Cholistani breed of cattle is an indigenous, tick-resistant breed of cattle being reared under pastoralism in the Cholistan desert of Pakistan. A study on theileriosis conducted on this Cholistani breed of cattle (n= 264) has clearly reported that this breed is a tick-resistant and hence Babesia-resistant breed of Pakistan (Saeed et al., 2016SAEED, Z.; IQBAL, F.; HUSSAIN, M.; SHAIKH, R.S. et al. Molecular prevalence and haematology of tropical theileriosis in Cholistani cattle from nomadic herds of the Cholistan desert, Pakistan. Kafkas Üniv. Vet. Fak. Derg., v.22. p.281-286, 2016.). This study envisaged that a prevalence of 19.3% for noticed for theileriosis, yet none of the Cholistani cattle showed any clinical signs of the ileria apart from the fact that they were tick-ridden. This character was plausibly justified with an innate ability of this breed to be tick resistant as reported for other zebu cattle breeds throughout the world (Godfrey and Hansen, 1994GODFREY, R.; HANSEN, P. Effects of coat color on production and reproduction of dairy cattle on St. Croix. In: CARIBBEAN FOOD CROPS SOCIETY / ANNUAL MEETING, 30., 1994. Proceedings… 1994, St. Thomas: [FAO], 1994. 7p.; Farooq et al., 2017FAROOQ, U.; NAZIR, A.; AHMAD, I.; MAHMOOD, S.A. et al. Effect of seasonal variations on hematochemical profile of Cholistani service bulls. J. Appl. Anim. Res., v.45, p.85-89, 2017.).

The percentage prevalence attained through PCR in the present study was 19.4% (n=72/376) which was lower than that of 37.2% (n=140/376) attained through microscopy. Furthermore, in the present study, the sensitivity, specificity, positive predictive, and negative predictive values for blood smear examination were lower than that for PCR. The traditional and conventional diagnostic test being utilized globally for diagnosis of various intra-erythrocytic diseases in bovines is blood smear microscopy. It is a routine test which needs less expertise, is cheap, and can be conducted as an infield/cow-side test. However, the Babesia (and other intra-erythrocytic parasites) parasite is difficult to be viewed through microscopy if a chronic condition occurs as reported in previous studies (Chaudhry et al., 2010CHAUDHRY, Z.I.; SULEMAN, M.; YOUNUS, M.; ASLIM, A. Molecular detection of Babesia bigemina and Babesia bovis in crossbred carrier cattle through PCR. Pak. J. Zool., v.42, p.201-204, 2010.). Owing to a vast expansion and validation of various molecular diagnostic techniques, various types of PCRs such as nested PCR, real-time PCR, quantitative PCR, and reverse-transcriptase PCR are now being used for confirmed diagnosis. Various research studies have reported higher sensitivity, specificity and repeatability for these molecular techniques as compared to blood slide microscopy (Bal et al., 2016BAL, M.S.; MAHAJAN, V.; FILIA G.; KAUR, P. et al. Diagnosis and management of bovine babesiosis outbreaks in cattle in Punjab state. Vet. World, v.9, p.1370, 2016.; Singh et al., 2013SINGH, H.; HAQUE, M.; SINGH, N.; RATH, S. PCR based detection of subclinical bovine babesiosis in Punjab. Indian J. Anim. Res., v.47, p.543-546, 2013.; Terkawi et al., 2011TERKAWI, M.A.; HUYEN, N.X.; SHINUO, C.; INPANKAEW, T. et al. Molecular and serological prevalence of Babesia bovis and Babesia bigemina in water buffaloes in the northeast region of Thailand. Vet. Parasitol., v.178, p.201-207, 2011.).

In our results, prevalence attained for babesiosis through blood smear microscopy was lower as compared to that attained through PCR. This contrasts with a research work reported from Pakistan on buffaloes which reports a higher prevalence of 29% through PCR as compared to 18% for blood smear microscopy (Chaudhry et al., 2010CHAUDHRY, Z.I.; SULEMAN, M.; YOUNUS, M.; ASLIM, A. Molecular detection of Babesia bigemina and Babesia bovis in crossbred carrier cattle through PCR. Pak. J. Zool., v.42, p.201-204, 2010.). However, the results of sensitivity and specificity of both tests are same as those seen in our present study. Results similar to ours have also been reported in another work reported from KP province of Pakistan on cattle blood which revealed a higher sensitivity and specificity of PCR as compared to light microscopy of the blood (Ayaz et al., 2013AYAZ, S.; SUMERA, S.; MOHAMMAD A.T.; RAHEEM, A. et al. Epidemiology and Molecular Detection of Babesiosis in Household Dairies in Districts Kohat and Karak. Life Sci. J., v.10, p.188-193, 2013.). While studying theileriosis in Cholistani breed of cattle in an earlier study, sensitivity, specificity, positive predictive, and negative predictive values for blood smear examination have been reported as 8.9, 45.1, 1.8, and 80.6%, respectively. Coinciding values for PCR were 91.0, 54.8, 19.3, and 98.1%, respectively in this work. These results are also in line with our results. A study conducted in Mexico to assess comparative efficacy of IFAT, ELISA, and ICT as diagnostic techniques for babesiosis has reported highest sensitivity and specificity for ICT (Lira-Amaya et al., 2021). Apart from being cheapest and fastest method of diagnosis, blood smear microscopy has lower sensitivity and hence increased chances of false positives (Mosqueda et al., 2012MOSQUEDA, J.; OLVERA-RAMIREZ, A.; AGUILAR-TIPACAMU, G.; CANTO, G. Current advances in detection and treatment of babesiosis. Curr. Med. Chem., v.19, p.1504-1518, 2012.). From Pakistan, mostly the diagnosis of intra-erythrocytic infections such as babesiosis is mostly being carried out through blood smear microscopy with gradual incorporation of PCR (Rafique et al., 2015RAFIQUE, N.; KAKAR, A.; IQBAL, A.; KAMRAN, K. et al. Pervasiveness of tick borne disease, babesiosis in Quetta City of province Balochistan, Pakistan. Int. J., v.7, p.792-794, 2015.).

Considering the molecular diagnostics of Babesia of the present study, it was revealed that all the positive samples produced the 490bp amplicons specific and typical for Babesia bigemina. The present results are not in line with studies conducted in other regions/provinces of Pakistan which during molecular detection of Babesia have reported a higher incidence of Babesia bovis with 907bp amplicons specific to B. bovis (Farooqi et al., 2017FAROOQI, S.H.; IJAZ, M.; RASHID, M.I.; AQIB, A.I. et al. Molecular epidemiology of Babesia bovis in bovine of Khyber Pakhtunkhwa, Pakistan. Pak. Vet. J., v.37, p.275-280, 2017.; Zulfiqar et al., 2012ZULFIQAR, S.; SHAHNAWAZ, S.; ALI, M.; BHUTTA, A.M. et al. Detection of Babesia bovis in blood samples and its effect on the hematological and serum biochemical profile in large ruminants from Southern Punjab. Asian Pacific J. Trop. Biomed., v.2, p.104-108, 2012.).

The overall prevalence of bovine babesiosis attained through blood smear microscopy (37.2%) was higher than that ascertained through PCR (19.4%) in the present study for cattle population (n=376) of Layyah District, South Punjab, Pakistan. A lot of work has been conducted on prevalence of babesiosis in Pakistan using both blood smear microscopy and PCR. However, none of it has emanated from Southern Punjab region of Pakistan. Comparing these results with research work conducted earlier in Pakistan, it was noticed that in contrast to our results, past research has reported higher values of prevalence through PCR as compared to those attained through blood smear microscopy (Chaudhry et al., 2010CHAUDHRY, Z.I.; SULEMAN, M.; YOUNUS, M.; ASLIM, A. Molecular detection of Babesia bigemina and Babesia bovis in crossbred carrier cattle through PCR. Pak. J. Zool., v.42, p.201-204, 2010.; Siddique et al., 2020SIDDIQUE, R.M.; SAJID, M.S.; IQBAL, Z.; SAQIB, M. Association of different risk factors with the prevalence of babesiosis in cattle and buffalos. Pak. J. Agric. Sci., v.57. p.517-524, 2020.). A study conducted on three agro-pastoral regions of Central Punjab, Pakistan has reported a higher prevalence of 26.86% through PCR in bovines (n=2176) (Siddique et al., 2020). Yet another study conducted on crossbred cattle (n=100) of Sahiwal, Punjab has reported 29.0% prevalence through small subunit ribosomal RNA gene-based PCR (Chaudhry et al., 2010). A study from KP conducted on cattle (n=2,400) has reported a yet higher prevalence of 27.5% through qPCR (Ayaz et al., 2013AYAZ, S.; SUMERA, S.; MOHAMMAD A.T.; RAHEEM, A. et al. Epidemiology and Molecular Detection of Babesiosis in Household Dairies in Districts Kohat and Karak. Life Sci. J., v.10, p.188-193, 2013.). A higher percentage prevalence of 27.5% has been reported for cattle in KPK through PCR (Ayaz et al., 2013). A yet higher incidence of 54.8% for cattle has been reported from Baluchistan province of Pakistan (Rafique et al., 2015RAFIQUE, N.; KAKAR, A.; IQBAL, A.; KAMRAN, K. et al. Pervasiveness of tick borne disease, babesiosis in Quetta City of province Balochistan, Pakistan. Int. J., v.7, p.792-794, 2015.). Comparing our results with the work conducted in other parts of the world, it was revealed that globally higher values of prevalence have been noticed. An Iraqi study conducted on buffaloes (n=194) has reported an overall prevalence of 45.2% for babesiosis through conventional PCR (Ateaa and Alkhaled, 2019ATEAA, R.; ALKHALED, M. Microscopic identification, molecular and phylogenetic analysis of Babesia species in buffalo from slaughter house in Al-Najaf city of Iraq. Iraq. J. Vet. Sci., v.33, p.251-258, 2019.). Lower prevalence in our study attained through PCR (15.0%) as compared to previous studies could be attributed to difference in sample number, breeds, climate, and types of PCR. In addition, the area under investigation (Southern Punjab) could be lesser prone to TBDs as compared to other parts of Pakistan. Lower prevalence in our study could also plausibly be attributed to better management of animals owing to better awareness of livestock farmers.

Regarding our results of prevalence for the studied cattle breeds, it was noticed that one of the animals from Cholistani breed was Babesia-positive. However, higher prevalence was noticed for crossbred cattle (46.7%) followed by that in Friesian (16.1%), Jersey (7%) and Sahiwal (6.9%) cattle breeds. Our results are in line with almost all research work published earlier. It has already been well elucidated that crossbred cattle and exotic breeds of cattle are more vulnerable to all the TBDs including babesiosis. On the other hand, the indigenous humped zebu cattle in any part of the world (Sahiwal, Cholistani etc.) are hardy and tick-tolerant breeds hence being less prone to them (Dikmen et al., 2017DIKMEN, S.; DAHL, G.E.; COLE, J.B.; NULL, D.J. et al. The Larson Blue coat color phenotype in Holsteins: Characteristics and effects on body temperature regulation and production in lactating cows in a hot climate. J. Anim. Sci., v.95, p1164-1169, 2017.; Farooq et al., 2010FAROOQ, U.; SAMAD, H.; SHER, F.; ASIM, M. et al. Cholistan and cholistani breed of cattle. Pak. Vet. J., v.30, p.2074-7764, 2010.). A work from Cholistan desert of Pakistan though conducted on theileriosis, has reported similar results (Saeed et al., 2016SAEED, Z.; IQBAL, F.; HUSSAIN, M.; SHAIKH, R.S. et al. Molecular prevalence and haematology of tropical theileriosis in Cholistani cattle from nomadic herds of the Cholistan desert, Pakistan. Kafkas Üniv. Vet. Fak. Derg., v.22. p.281-286, 2016.). Furthermore, the zebu cattle breeds have a potential to maintain most of their physiological (haematochemical) parameters at a harmonious pattern in all seasons, without showing much variation during stress free or stressful times (Farooq et al., 2012). This stress-bearing property probably renders them free from any clinical signs of TBDs as shown in our results. The exotic Taurine cattle breeds are extremely susceptible and show severe signs of parasitism, whereas the indicus breeds develop a strong immunity after an infection due to their innate immunity as reviewed earlier. This immunity might be another cause for absence of clinical signs in zebu cattle as seen in our results. A plausible justification based upon the principles of “Endemic Stability” to tick-borne diseases in tropics is also being presented globally. Endemic stability is an epidemiological state of equilibrium that is characterized by absence of a clinical disease instead of high incidence of infection within of set of population (Jonsson et al., 2012JONSSON, N.N.; BOCK, R.E.; JORGENSEN, W.K.; MORTON, J.M. Is endemic stability of tick-borne disease in cattle a useful concept? Trends Parasitol., v.28, p.85-89, 2012.). However, a prerequisite for the achievement of this state is presence of substantial functional/innate immunity at a young age. Though no work has yet been reported on endemic stability of tick-borne diseases from Pakistan, the lack of clinical symptoms and low prevalence of babesiosis in our study could be attributed to this phenomenon.

Our gender-wise results indicated that females (both of cattle and buffaloes) had a higher overall prevalence of 19.5% as compared to 17.8% for males. Relationship of Babesia with gender has been studied extensively and it has been elucidated that females are more prone to babesiosis as compared to their male counterparts. Similar results have been reported from KPK with higher prevalence of babesiosis in females (41.0%) as compared to males (23.2%) (Khan et al., 2020KHAN, A.; NOUSHIN, R.; ATTAULLAH, M.; KHAN, S.N. et al. Prevalence of tick born Babesia infection in domestic cattle of Khyber Pakhtunkhwa, Pakistan. Pak. J. Zool., v.52, p.2401-2403, 2020.). Research works from other provinces of Pakistan have also presented similar results with higher prevalence for females (Ahmad et al., 2014AHMAD, I.; KHAWJA, A.; SHAMS, S.; AYAZ, S. et al. Detection of babesiosis and identification of associated ticks in cattle. Int. J. Bioassays, v.3, p.3195-3199, 2014.; Rafique et al., 2015RAFIQUE, N.; KAKAR, A.; IQBAL, A.; KAMRAN, K. et al. Pervasiveness of tick borne disease, babesiosis in Quetta City of province Balochistan, Pakistan. Int. J., v.7, p.792-794, 2015.). Gender-associated resistance or susceptibility to babesiosis has extensively been studied in lab animal models which have revealed that female Wistar rats are more susceptible as compared to males (Aguilar-Delfin et al., 2001). Conclusions have hence been put forth that innate immunity plays a substantial role in the resistance to Babesia infection and that genetic and gender-related factors influence the efficiency of the protective response (Romero-Salas et al., 2016).

In the present study, prevalence percentage for babesiosis was ascertained as per three age groups viz. G1= Up to 02 Years, G2= 03-04 Years, G3= 05-06 Years. Results revealed that G1 (Up to 02 Years) showed a higher prevalence of 40.0% as compared to G2 (13.1%) and G3 (8.4%), respectively. Our results are in line with most of the studies conducted on bovine population of Pakistan as well as with those conducted globally (Ahmad et al., 2014AHMAD, I.; KHAWJA, A.; SHAMS, S.; AYAZ, S. et al. Detection of babesiosis and identification of associated ticks in cattle. Int. J. Bioassays, v.3, p.3195-3199, 2014.; Farooqi et al., 2017FAROOQI, S.H.; IJAZ, M.; RASHID, M.I.; AQIB, A.I. et al. Molecular epidemiology of Babesia bovis in bovine of Khyber Pakhtunkhwa, Pakistan. Pak. Vet. J., v.37, p.275-280, 2017.; Khattak et al., 2017KHATTAK, B.; KHAN, M.J.; KHAN, T.A.; HUSSAIN, M. et al. Study the incidence of babesiosis in cattle of afghan refugees in Mohmand agency, Pakistan. J. Entomol. Zool. Study, v.5, p.1422-1424, 2017.). A positive correlation (r= 0.99) has been reported between TBDs and age (Lew and Jorgensen, 2005LEW, A.; JORGENSEN, W. Molecular approaches to detect and study the organisms causing bovine tick borne diseases: babesiosis and anaplasmosis. Afr. J. Biotech., v.4, p.292-302, 2005.). A study conducted on bovine population of KPK and South Punjab simultaneously reported 42.0% prevalence of TBDs in animals less than 1 year old as compared to 33.1% for those above 1 year of age (Ashraf et al., 2013ASHRAF, Q.U.; KHAN, A.U.; KHATTAK, R.M.; ALI, M. et al. A report on the high prevalence of Anaplasma sp. in buffaloes from two provinces in Pakistan. Ticks Tick Borne Dis., v.4, p.395-398, 2013.). Similarly, from KPK, a higher prevalence of babesiosis (75.3%) has been reported for young cattle elsewhere (Khan et al., 2020KHAN, A.; NOUSHIN, R.; ATTAULLAH, M.; KHAN, S.N. et al. Prevalence of tick born Babesia infection in domestic cattle of Khyber Pakhtunkhwa, Pakistan. Pak. J. Zool., v.52, p.2401-2403, 2020.). Yet another study which incorporates three agro-ecological zones of Pakistan has reported higher prevalence in young cattle (23.1%) as compared to older cattle (11.9%) (Siddique et al., 2020SIDDIQUE, R.M.; SAJID, M.S.; IQBAL, Z.; SAQIB, M. Association of different risk factors with the prevalence of babesiosis in cattle and buffalos. Pak. J. Agric. Sci., v.57. p.517-524, 2020.). Various scientific and medical reasons have been put forth by researchers regarding this age-associate vulnerability to babesiosis and other TBDs. As per one reasoning, the young animals have thin and soft skin, which is easier for ticks to infest, resulting in higher tick infestation and resultantly higher susceptibility towards TBDs including babesiosis (Khan et al., 2020; Zahid et al., 2005ZAHID, I.; LATIF, M.; BALOCH, K. Incidence and treatment of theileriasis and babesiasis. Pak. Vet. J., v.25, p.137, 2005.). Apart from this, failure in passive transfer (FPT) due to decreased intake of colostral antibodies by young ones may result in lesser immunity and hence a reason of susceptibility towards babesiosis. In Pakistan, the pattern of colostrum feeding is quite flawed which makes it vital to streamline efforts towards appropriate colostrum feeding and hence enhanced immunity (Lashari et al., 2020LASHARI, M.; FAROOQ, U.; IDRIS, M.; REHMAN, Z. et al. Physiological serum chemistry variables and brix% for assessing status of passive transfer in goat kids. J. Anim. Plant Sci., v.30, p.1331-1335, 2020.).

Summer season had the highest prevalence (35.9%) of babesiosis in our study as compared to the winter season (5.7%). These results are also in concordance to earlier published work both from Pakistan and other countries of the world (Ahmad et al., 2014AHMAD, I.; KHAWJA, A.; SHAMS, S.; AYAZ, S. et al. Detection of babesiosis and identification of associated ticks in cattle. Int. J. Bioassays, v.3, p.3195-3199, 2014.; Farooqi et al., 2017FAROOQI, S.H.; IJAZ, M.; RASHID, M.I.; AQIB, A.I. et al. Molecular epidemiology of Babesia bovis in bovine of Khyber Pakhtunkhwa, Pakistan. Pak. Vet. J., v.37, p.275-280, 2017.; Ayaz et al., 2013AYAZ, S.; SUMERA, S.; MOHAMMAD A.T.; RAHEEM, A. et al. Epidemiology and Molecular Detection of Babesiosis in Household Dairies in Districts Kohat and Karak. Life Sci. J., v.10, p.188-193, 2013.; Siddique et al., 2020SIDDIQUE, R.M.; SAJID, M.S.; IQBAL, Z.; SAQIB, M. Association of different risk factors with the prevalence of babesiosis in cattle and buffalos. Pak. J. Agric. Sci., v.57. p.517-524, 2020.). Similar to age, seasons have also been highly associated with level of prevalence of babesiosis and all other TBDs (Ahmad et al., 2014; Ayaz et al., 2013; Siddique et al., 2020; Zahid et al., 2005ZAHID, I.; LATIF, M.; BALOCH, K. Incidence and treatment of theileriasis and babesiasis. Pak. Vet. J., v.25, p.137, 2005.). A study from Layyah conducted on prevalence of anaplasmosis (a TBD) has reported highest prevalence during autumn (18.3%), followed by that in summer (9.7%) and winter season (7.1%) (Ashraf et al., 2021ASHRAF, S.; PARVEEN, A.; MUHAMMAD AWAIS, M.; GILLANI, Q. et al. A report on molecular detection and phylogenetic evaluation of Anaplasma marginale in ticks and blood samples collected from cattle in District Layyah in Punjab (Pakistan). Curr. Microb., v.78, p.274-281, 2021.). Summer season allied with humidity has emerged in two summer seasons in Pakistan i.e., dry summer (May, June) and wet summer (July, August). In general, the whole summer season is a conducive environment for the growth of ticks, and results in a high tick population which ultimately results in higher infestation of livestock and higher susceptibility to TBDs including babesiosis. This has been reported from all south Asian nations such as India (Ghosh et al., 2007GHOSH, S.; BANSAL, G.C.; GUPTA, S.C.; RAY, D. et al. Status of tick distribution in Bangladesh, India and Pakistan. Parasitol. Res., v.101, p.207-216, 2007.; Minjauw and McLeod, 2003MINJAUW, B.; MCLEOD, A. Tick-borne diseases and poverty: the impact of ticks and tickborne diseases on the livelihood of small-scale and marginal livestock owners in India and eastern and southern Africa. Edinburgh: DFID, 2003. 124p.; Singh et al., 2013SINGH, H.; HAQUE, M.; SINGH, N.; RATH, S. PCR based detection of subclinical bovine babesiosis in Punjab. Indian J. Anim. Res., v.47, p.543-546, 2013.). Pakistan, lying in the WCZs of the world, makes it highly susceptible to babesiosis and other TBDs.

Amongst the studied hematological attributes, Hb concentration, TEC, PCV and MCV were lower in babesia-positive animals as compared to healthy ones. However, the TLC and lymphocytes were higher for infected animals as compared to healthy, negative ones. Our results are completely in accordance with the previously published international literature that the TBDs including babesiosis hamper significantly the blood profile of infected animals (Fadly, 2012FADLY, R.S. Prevalence of blood parasites of some farm animals at behera province. Assiut. Vet. Med. J., v.58, p.134, 2012.; Javed et al., 2014JAVED, K.; IJAZ, M.; ALI, M.M.; KHAN, I. et al. Prevalence and hematology of tick borne hemoparasitic diseases in equines in and around Lahore. Pak. J. Zool., v.46. p.401-408, 2014.; Mahmoud et al., 2015MAHMOUD, M.S.; KANDIL, O.M.; NASR, S.M.; HENDAWY, S.H. et al. Serological and molecular diagnostic surveys combined with examining hematological profiles suggests increased levels of infection and hematological response of cattle to babesiosis infections compared to native buffaloes in Egypt. Parasites Vectors, v.8, p.1-15, 2015.). From Pakistan however, mostly the research work conducted on TBDs is related to their prevalence and molecular identification rather than hematological assessment. A study conducted on cattle and buffalo of South Punjab regarding hematological alterations in Babesia, results similar to ours have been presented (Zulfiqar et al., 2012ZULFIQAR, S.; SHAHNAWAZ, S.; ALI, M.; BHUTTA, A.M. et al. Detection of Babesia bovis in blood samples and its effect on the hematological and serum biochemical profile in large ruminants from Southern Punjab. Asian Pacific J. Trop. Biomed., v.2, p.104-108, 2012.). Previous international reports have also clearly documented a significant decrease in RBC count, Hb and PCV values in livestock with TBDs (Col and Uslu, 2007COL, R.; USLU, U. Changes in selected serum components in cattle naturally infected with Theileria annulata. Bull. Vet. Inst. Pulawy, v.51, p.15, 2007.; Khan et al., 2011KHAN, I.A.; KHAN, A.; HUSSAIN, A.; RIAZ, A. et al. Hemato-biochemical alterations in cross bred cattle affected with bovine theileriosis in semi arid zone. Pak. Vet. J., v.31, p.137-140, 2011.). The plausible justification for these hematological alterations in infected bovines is release of certain toxins/metabolites Babesia species., blood loss due to tick infestation, parasitemia-induced-anemia, immune-mediated erythrophagocytosis and Tumour-Necrosis Factor-α (Boulter and Hall, 1999BOULTER, N.; HALL, R. Immunity and vaccine development in the bovine theilerioses. Adv. Parasitol., v.44, p.41-97, 1999.; Geerts et al., 2001GEERTS, S.; HOLMES, P.H.; EISLER, M.C.; DIALL, O. African bovine trypanosomiasis: the problem of drug resistance. Trends Parasitol., v.17, p.25-28, 2001.). It has also been postulated that the Babesia species causes macrocytic hypochromic anemia, indicative of severe intravascular hemolysis of RBCs in bovines affected with persistent babesiosis (Ibrahim et al., 2009IBRAHIM, A.; EL BEHAIRY, A.; MAHRAN, K.; AWAD, W. Clinical and laboratory diagnosis of piroplasmids in naturally infected cattle in Egypt. J. Egypt Vet. Med. Assoc., v.69, p.105-203, 2009.; Mahmoud et al., 2015; Zulfiqar et al., 2012). These may be because although Babesia sp. may cause direct damage on some erythrocytes, immune-mediated injury of parasite may be more important in the pathogenesis of anemia (Messick, 2004MESSICK, J. B. Hemotrophic mycoplasmas (hemoplasmas): a review and new insights into pathogenic potential. Vet. Clin. Path., v.33, p.2-13, 2004.). Yet, the increase in erythrophagocytosis by activated macrophages (Court et al., 2001COURT, R.; JACKSON, L.; LEE, R. Elevated anti-parasitic activity in peripheral blood monocytes and neutrophils of cattle infected with Babesia bovis. Int. J. Parasitol., v.31, p.29-37, 2001.) and the production of anti-erythrocyte antibodies (Góes et al., 2007GÓES, T.; GÓES, V.; RIBEIRO, M.; GONTIJO, C. Bovine babesiosis: anti-erythrocyte antibodies purification from the sera of naturally infected cattle. Vet. Immun. Immunopathol., v.116, p.215-218. 2007.) may also contribute to the development of anemia.

CONCLUSION

In a nutshell, the overall prevalence of babesiosis in cattle population of Southern Punjab (19.4% by PCR) is lower than other parts of Pakistan. Furthermore, this region has Babesia bigemina as the prevalent species. Microscopy is a less sensitive and specific test which needs to be replaced with novel molecular diagnostic tests such as IFAT, ICT and ELISA. Development of an appropriate vaccine from the field strain of Babesia using proteomics and DNA technology is a need of time.

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JONSSON, N.N.; BOCK, R.E.; JORGENSEN, W.K.; MORTON, J.M. Is endemic stability of tick-borne disease in cattle a useful concept? Trends Parasitol., v.28, p.85-89, 2012.
KARIM, S.; BUDACHETRI, K.; MUKHERJEE, N.; WILLIAMS, J. et al. A study of ticks and tick-borne livestock pathogens in Pakistan. PLoS Negl. Trop. Dis.., v.11, p.e0005681, 2017.
KHAN, A.; NOUSHIN, R.; ATTAULLAH, M.; KHAN, S.N. et al. Prevalence of tick born Babesia infection in domestic cattle of Khyber Pakhtunkhwa, Pakistan. Pak. J. Zool., v.52, p.2401-2403, 2020.
KHAN, I.A.; KHAN, A.; HUSSAIN, A.; RIAZ, A. et al. Hemato-biochemical alterations in cross bred cattle affected with bovine theileriosis in semi arid zone. Pak. Vet. J., v.31, p.137-140, 2011.
KHAN, M.S.; REHMAN, Z.; KHAN, M.A.; AHMAD, S. Genetic resources and diversity in Pakistani cattle. Pak. Vet. J., v.28, p.95-102, 2008.
KHATTAK, B.; KHAN, M.J.; KHAN, T.A.; HUSSAIN, M. et al. Study the incidence of babesiosis in cattle of afghan refugees in Mohmand agency, Pakistan. J. Entomol. Zool. Study, v.5, p.1422-1424, 2017.
LASHARI, M.; FAROOQ, U.; IDRIS, M.; REHMAN, Z. et al. Physiological serum chemistry variables and brix% for assessing status of passive transfer in goat kids. J. Anim. Plant Sci., v.30, p.1331-1335, 2020.
LEW, A.; JORGENSEN, W. Molecular approaches to detect and study the organisms causing bovine tick borne diseases: babesiosis and anaplasmosis. Afr. J. Biotech., v.4, p.292-302, 2005.
LIRA-AMAYA, J.J.; MARTÍNEZ-GARCÍA, G.; SANTAMARIA-ESPINOSA, R.M.; CASTAÑEDA-ARRIOLA, R.O. et al. Comparative study of indirect fluorescent antibody, elisa, and immunochromatography tests for serological diagnosis of bovine babesiosis caused by babesia bovis. Animals, v.11, p.3358, 2021.
MAHMOUD, M.S.; KANDIL, O.M.; NASR, S.M.; HENDAWY, S.H. et al. Serological and molecular diagnostic surveys combined with examining hematological profiles suggests increased levels of infection and hematological response of cattle to babesiosis infections compared to native buffaloes in Egypt. Parasites Vectors, v.8, p.1-15, 2015.
MESSICK, J. B. Hemotrophic mycoplasmas (hemoplasmas): a review and new insights into pathogenic potential. Vet. Clin. Path., v.33, p.2-13, 2004.
MINJAUW, B.; MCLEOD, A. Tick-borne diseases and poverty: the impact of ticks and tickborne diseases on the livelihood of small-scale and marginal livestock owners in India and eastern and southern Africa. Edinburgh: DFID, 2003. 124p.
MOSQUEDA, J.; OLVERA-RAMIREZ, A.; AGUILAR-TIPACAMU, G.; CANTO, G. Current advances in detection and treatment of babesiosis. Curr. Med. Chem., v.19, p.1504-1518, 2012.
MUHAMMAD, G.; NAUREEN, A.; FIRYAL, S.; SAQIB, M. Tick control strategies in dairy production medicine. Pak. Vet. J., v.28, p.43, 2008.
OZUBEK, S.; BASTOS, R.G.; ALZAN, H.F.; INCI, A. et al. Bovine babesiosis in Turkey: impact, current gaps, and opportunities for intervention. Pathogens, v.9, p.1041, 2020.
RAFIQUE, N.; KAKAR, A.; IQBAL, A.; KAMRAN, K. et al. Pervasiveness of tick borne disease, babesiosis in Quetta City of province Balochistan, Pakistan. Int. J., v.7, p.792-794, 2015.
ROMERO-SALAS, D.; MIRA, A.; MOSQUEDA, J.; GARCÍA-VÁZQUEZ, Z. et al. Molecular and serological detection of Babesia bovis-and Babesia bigemina-infection in bovines and water buffaloes raised jointly in an endemic field. Vet. Parasitol., v.217, p.101-107, 2016.
SAEED, Z.; IQBAL, F.; HUSSAIN, M.; SHAIKH, R.S. et al. Molecular prevalence and haematology of tropical theileriosis in Cholistani cattle from nomadic herds of the Cholistan desert, Pakistan. Kafkas Üniv. Vet. Fak. Derg., v.22. p.281-286, 2016.
SCHLÖGL, K.S.; HIESEL, J.A.; WOLF, R.; KOPACKA, I. et al. Spatiotemporal cluster and incidence analysis of cattle mortality caused by bovine babesiosis in Styria, Austria, between 1998 and 2016. Parasitol. Res., v.119, p.1117-1123, 2020.
SIDDIQUE, R.M.; SAJID, M.S.; IQBAL, Z.; SAQIB, M. Association of different risk factors with the prevalence of babesiosis in cattle and buffalos. Pak. J. Agric. Sci., v.57. p.517-524, 2020.
SINGH, H.; HAQUE, M.; SINGH, N.; RATH, S. PCR based detection of subclinical bovine babesiosis in Punjab. Indian J. Anim. Res., v.47, p.543-546, 2013.
SIVAKUMAR, T.; TUVSHINTULGA, B.; KOTHALAWALA, H.; SILVA, S.S. et al. Host range and geographical distribution of Babesia sp. Mymensingh. Transbound. Emerg. Dis., v.67, p.2233-2239, 2020.
TERKAWI, M.A.; HUYEN, N.X.; SHINUO, C.; INPANKAEW, T. et al. Molecular and serological prevalence of Babesia bovis and Babesia bigemina in water buffaloes in the northeast region of Thailand. Vet. Parasitol., v.178, p.201-207, 2011.
ZAHID, I.; LATIF, M.; BALOCH, K. Incidence and treatment of theileriasis and babesiasis. Pak. Vet. J., v.25, p.137, 2005.
ZULFIQAR, S.; SHAHNAWAZ, S.; ALI, M.; BHUTTA, A.M. et al. Detection of Babesia bovis in blood samples and its effect on the hematological and serum biochemical profile in large ruminants from Southern Punjab. Asian Pacific J. Trop. Biomed., v.2, p.104-108, 2012.

Publication Dates

Publication in this collection
18 Sept 2023
Date of issue
Sep-Oct 2023

History

Received
23 Feb 2023
Accepted
11 May 2023

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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[29] JABBAR, A.; ABBAS, T.; SANDHU, Z.U.D.; SADDIQI, H.A. et al. Tick-borne diseases of bovines in Pakistan: major scope for future research and improved control. Parasites Vectors, v.8, p.1-13, 2015.

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[31] JONSSON, N.N.; BOCK, R.E.; JORGENSEN, W.K.; MORTON, J.M. Is endemic stability of tick-borne disease in cattle a useful concept? Trends Parasitol., v.28, p.85-89, 2012.

[32] KARIM, S.; BUDACHETRI, K.; MUKHERJEE, N.; WILLIAMS, J. et al. A study of ticks and tick-borne livestock pathogens in Pakistan. PLoS Negl. Trop. Dis.., v.11, p.e0005681, 2017.

[33] KHAN, A.; NOUSHIN, R.; ATTAULLAH, M.; KHAN, S.N. et al. Prevalence of tick born Babesia infection in domestic cattle of Khyber Pakhtunkhwa, Pakistan. Pak. J. Zool., v.52, p.2401-2403, 2020.

[34] KHAN, I.A.; KHAN, A.; HUSSAIN, A.; RIAZ, A. et al. Hemato-biochemical alterations in cross bred cattle affected with bovine theileriosis in semi arid zone. Pak. Vet. J., v.31, p.137-140, 2011.

[35] KHAN, M.S.; REHMAN, Z.; KHAN, M.A.; AHMAD, S. Genetic resources and diversity in Pakistani cattle. Pak. Vet. J., v.28, p.95-102, 2008.

[36] KHATTAK, B.; KHAN, M.J.; KHAN, T.A.; HUSSAIN, M. et al. Study the incidence of babesiosis in cattle of afghan refugees in Mohmand agency, Pakistan. J. Entomol. Zool. Study, v.5, p.1422-1424, 2017.

[37] LASHARI, M.; FAROOQ, U.; IDRIS, M.; REHMAN, Z. et al. Physiological serum chemistry variables and brix% for assessing status of passive transfer in goat kids. J. Anim. Plant Sci., v.30, p.1331-1335, 2020.

[38] LEW, A.; JORGENSEN, W. Molecular approaches to detect and study the organisms causing bovine tick borne diseases: babesiosis and anaplasmosis. Afr. J. Biotech., v.4, p.292-302, 2005.

[39] LIRA-AMAYA, J.J.; MARTÍNEZ-GARCÍA, G.; SANTAMARIA-ESPINOSA, R.M.; CASTAÑEDA-ARRIOLA, R.O. et al. Comparative study of indirect fluorescent antibody, elisa, and immunochromatography tests for serological diagnosis of bovine babesiosis caused by babesia bovis. Animals, v.11, p.3358, 2021.

[40] MAHMOUD, M.S.; KANDIL, O.M.; NASR, S.M.; HENDAWY, S.H. et al. Serological and molecular diagnostic surveys combined with examining hematological profiles suggests increased levels of infection and hematological response of cattle to babesiosis infections compared to native buffaloes in Egypt. Parasites Vectors, v.8, p.1-15, 2015.

[41] MESSICK, J. B. Hemotrophic mycoplasmas (hemoplasmas): a review and new insights into pathogenic potential. Vet. Clin. Path., v.33, p.2-13, 2004.

[42] MINJAUW, B.; MCLEOD, A. Tick-borne diseases and poverty: the impact of ticks and tickborne diseases on the livelihood of small-scale and marginal livestock owners in India and eastern and southern Africa. Edinburgh: DFID, 2003. 124p.

[43] MOSQUEDA, J.; OLVERA-RAMIREZ, A.; AGUILAR-TIPACAMU, G.; CANTO, G. Current advances in detection and treatment of babesiosis. Curr. Med. Chem., v.19, p.1504-1518, 2012.

[44] MUHAMMAD, G.; NAUREEN, A.; FIRYAL, S.; SAQIB, M. Tick control strategies in dairy production medicine. Pak. Vet. J., v.28, p.43, 2008.

[45] OZUBEK, S.; BASTOS, R.G.; ALZAN, H.F.; INCI, A. et al. Bovine babesiosis in Turkey: impact, current gaps, and opportunities for intervention. Pathogens, v.9, p.1041, 2020.

[46] RAFIQUE, N.; KAKAR, A.; IQBAL, A.; KAMRAN, K. et al. Pervasiveness of tick borne disease, babesiosis in Quetta City of province Balochistan, Pakistan. Int. J., v.7, p.792-794, 2015.

[47] ROMERO-SALAS, D.; MIRA, A.; MOSQUEDA, J.; GARCÍA-VÁZQUEZ, Z. et al. Molecular and serological detection of Babesia bovis-and Babesia bigemina-infection in bovines and water buffaloes raised jointly in an endemic field. Vet. Parasitol., v.217, p.101-107, 2016.

[48] SAEED, Z.; IQBAL, F.; HUSSAIN, M.; SHAIKH, R.S. et al. Molecular prevalence and haematology of tropical theileriosis in Cholistani cattle from nomadic herds of the Cholistan desert, Pakistan. Kafkas Üniv. Vet. Fak. Derg., v.22. p.281-286, 2016.

[49] SCHLÖGL, K.S.; HIESEL, J.A.; WOLF, R.; KOPACKA, I. et al. Spatiotemporal cluster and incidence analysis of cattle mortality caused by bovine babesiosis in Styria, Austria, between 1998 and 2016. Parasitol. Res., v.119, p.1117-1123, 2020.

[50] SIDDIQUE, R.M.; SAJID, M.S.; IQBAL, Z.; SAQIB, M. Association of different risk factors with the prevalence of babesiosis in cattle and buffalos. Pak. J. Agric. Sci., v.57. p.517-524, 2020.

[51] SINGH, H.; HAQUE, M.; SINGH, N.; RATH, S. PCR based detection of subclinical bovine babesiosis in Punjab. Indian J. Anim. Res., v.47, p.543-546, 2013.

[52] SIVAKUMAR, T.; TUVSHINTULGA, B.; KOTHALAWALA, H.; SILVA, S.S. et al. Host range and geographical distribution of Babesia sp. Mymensingh. Transbound. Emerg. Dis., v.67, p.2233-2239, 2020.

[53] TERKAWI, M.A.; HUYEN, N.X.; SHINUO, C.; INPANKAEW, T. et al. Molecular and serological prevalence of Babesia bovis and Babesia bigemina in water buffaloes in the northeast region of Thailand. Vet. Parasitol., v.178, p.201-207, 2011.

[54] ZAHID, I.; LATIF, M.; BALOCH, K. Incidence and treatment of theileriasis and babesiasis. Pak. Vet. J., v.25, p.137, 2005.

[55] ZULFIQAR, S.; SHAHNAWAZ, S.; ALI, M.; BHUTTA, A.M. et al. Detection of Babesia bovis in blood samples and its effect on the hematological and serum biochemical profile in large ruminants from Southern Punjab. Asian Pacific J. Trop. Biomed., v.2, p.104-108, 2012.

Studied Parameters	No. of Animals	Positive		Negative		95% CI	Odd Ratio/ P value
Studied Parameters	No. of Animals	N	%	N	%
Total	376	72	19.4	304	80.8	18.1 to 31.0	-
Breed
Sahiwal Cholistani Crossbred Friesian Jersey	101 35 107 62 71	7 0 50 10 5	6.9 0 46.7 16.1 7.0	94 35 57 52 66	93.0 100.0 53.2 83.8 63.9	8.1 to 11.0 7.2 to 10.5 11.1 to 13.1 6.2 to 9.5 7.2 to 9.5	OR=1.71 [reciprocal = 0.042]
Tehsils
Layyah Karor Choubara	140 125 111	43 18 11	30.7 14.4 9.9	97 107 100	69.2 85.6 90.0	10.2 to 35.5 8.8 to 18.5 9.3 to 14.2	Mantel-Haenszel chi-sq. P = 0.029
Gender
Females Males	281 95	55 17	19.5 17.8	226 78	80.4 82.1	17.7 to 25.3 11.2 to 19.6	OR=1.53 [reciprocal = 0.036]
Seasons
Summer Winter	167 209	60 12	35.9 5.7	107 197	64.0 94.2	18.2 to 21.2 11.5 to 18.5	Mantel-Haenszel chi-sq. P = 0.061
Age
G1 G2 G3	105 152 119	42 20 10	40.0 13.1 8.4	63 132 109	60.0 86.8 91.6	11.8 to 19.4 9.4 to 14.1 6.4 to 9.2	Mantel-Haenszel chi-sq. P = 0.071

Attributes	Positive (n= 72)	Negative (n= 304)	Overall (n= 376)
Hemoglobin (g/dL)	9.6±0.7	12.8±0.9*	13.2±0.4
Total erythrocyte count (10¹²/L)	6.9±0.4	8.8±0.4*	7.2±0.7
Packed cell volume (%)	32.0±1.1	39.9±1.8*	37.2±1.7
Mean corpuscular volume (fL)	48±2.1	55±1.2*	48.2±1.4
Mean corpuscular hemoglobin (pg)	21.2±0.8	20.8±0.5	21.2±0.7
Mean corpuscular hemoglobin concentration (g/L)	330.7±10.2	329.1±11.5	320.7±10.2
Total leukocyte count (10⁹/L)	11.4±0.4	9.2±0.4*	11.2±0.9
Neutrophils (%)	44.5±0.9	42.2±1.1	43.2±1.7
Lymphocytes (%)	58.7±1.9	41.8±0.9*	52.7±2.7
Eosinophils (%)	2.3±0.7	1.5±0.4	1.9±0.01
Basophils (%)	2.9±0.7	2.7±0.4	1.9±0.07
Monocytes (%)	1.4±0.1	1.1±0.1	1.1±0.04

Brasil

Brasil

Study on spatio-temporal prevalence and hematological attributes of bovine Babesiosis in cattle population of Layyah, Southern Punjab, Pakistan

[Estudo da prevalência espaço-temporal e dos atributos hematológicos da babesiose bovina na população bovina de Layyah, sul de Punjab, Paquistão]

ABSTRACT

RESUMO

INTRODUCTION

MATERIALS AND METHODS

RESULTS

DISCUSSION

CONCLUSION

REFERENCES

Publication Dates

History

Age			Gender		Breed					Seasons
G1	G2	G3	Males	Females	Sahiwal	Cholistani	Crossbred	Friesian	Jersey	S	W
105	152	119	95	281	101	35	107	62	71	167	209