Document Type : Research article
Authors
Parasitology Department in Animal Health Research Institute, Assiut Governorate, Egypt
Abstract
Keywords
AssiutUniversity web-site: www.aun.edu.eg
MICROSCOPICAL AND SEROLOGICAL STUDIES WITH ULTRASTRUCTURE DESCRIPTION OF SARCOCYSTIS SPECIES IN SHEEP IN ASSIUT
BASEM R. NAGEIB1 andHUDA M. KURAA2
1, 2 Parasitology Department in Animal Health Research Institute, Assiut Governorate, Egypt
Received: 7 March 2018; Accepted: 22 March 2018
ABSTRACT
This study was conducted to determine theinfection rate of Sarcocystis species in sheep in Assiut. A total of 100 slaughtered sheep examined for Sarcocystis, no macroscopic cysts were observed, 93% (93/100) were positive by microscopical examination and 28% (28/100) were positive by using Agar gel diffusion test.Theinfection rate of Sarcocystis had very high significant differences between microscopic examination and Agar gel diffusion test. High statistical significant effect was found on the infection rate of Sarcocystis in different examined muscles of sheep. The highest infection rate was recorded in oesophagus (71%), followed by diaphragm (65%), tongue (58%), skeletal muscles (53%) and heart muscles (43%). The infection rate of Sarcocystis in males was 95.2% (40/42) while in females were 91.4% (53/58) by microscopical examination. Higher infection rate of Sarcocystis were detected in sheep 6 months - 2 years age 95% (38/40) than that of sheep between 2-4 years old 92.7% (38/41) and those equal or older than 4 years 89.5% (17/19). No significant difference between infection and age groups or sex of animals was observed. The use of transmission electron microscope (TEM) allowed the identification of S. tenella and S. arieticanis in sheep in Assiut. Examination of S. tenella cyst wall with TEM showed palisade-like villar protrusions while, examination of S. arieticanis cyst wall showed hair-like villar protrusions parallel to cyst wall.
Key words: Microscopical - serological -ultrastructure - Sarcocystis species - sheep – Assiut.
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INTRODUCTION
Sarcocystis is one of the most prevalent obligate intracellular protozoan parasites belong to Apicomplexan phylum infecting food livestock such as cattle, sheep and goat (Kia et al., 2011). Sarcocystis spp. require two hosts to complete its life cycle; with the sexual cycle in the intestine of a carnivore as a definitive host and asexual cycle in the tissues of an herbivore as an intermediate hosts (Dubey, 1976 and Fayer, 2004). After ingestion of oocysts by the intermediate host, Sarcocystis spp. undergoes asexual generations in the vascular endothelial cells in all parts of the body with eventual formation of mature sarcocysts in the host's muscles. The definitive host is infected due to ingestion of the Sarcocystis infected muscular tissue, which results in the intestinal generation of oocysts (Fayer et al., 2015).
Sarcocystis are common parasites of a broad range of vertebrates. 189 different species can infect
Corresponding author: Dr. BASEM R. NAGEIB
E-mail address: Basemnageib@gmail.com;
Present address: Parasitology Department in Animal Health Research Institute, Assiut Governorate, Egypt
mammals, birds, reptiles, and fish even human (Odening, 1998). Infections are recognized to occur in all parts of the world and farm animals are intermediate hosts for a number of species (Dubey et al., 1989a and Hettiarachchi and Rajapakse, 2008). Sarcocystisspecies infect skeletal muscle, cardiac muscle, and smooth muscle and are rarely found in other tissues(Fayer, 2004).
Sheep are the intermediate host for four species: S. tenella (S. ovicanis) and S. arieticanis thatare known as pathogenic parasites, which form muscular microcysts transferred by dogs. S. gigantea (S. ovifelis) and S. medusiformis are non-pathogenic and form macrocysts transferred by cats (Tenter, 1995; Heckeroth and Tenter, 1998 and Dubey et al., 2015). Sheep become infected with the parasite via ingesting sporocysts or sometimes sporulated oocysts existed in the food or water (Dubey and Lindsay, 2006).Natural infections by Sarcocystis in domestic sheep have been investigated in various countries throughout the world, with prevalence ranging from 9 to 100% depending on the detection methodology (Dubey et al., 2015).
The severity of clinical signs in domesticated animals depends on the species of parasite and number of digested oocysts. S. tenella is the most pathogenic Sarcocystis species in sheep. It can cause anorexia, fever, decreased weight gain, anemia and has been associated with abortions in ewes. Neurologic signs including encephalomyelitis, muscle weakness, hind limb paresis and ataxia have been seen in naturally infected sheep. After recovery from the acute illness, some sheep may lose their wool. Sudden deaths can also occur without other symptoms. Experimentally, S. arieticanis is also pathogenic but somewhat less so than S. tenella. In the other hand S. medusiformis and S. gigantea are nonpathogenic or cause only mild disease (Charleston, 1994 and OIE, 2005).
S. tenella causes significant losses in the life stock industry due to death of the animal or abortion of pregnant ewes during acute sarcocystosis, and reduced weight gain, milk and wool production during chronic sarcocystosis (Kia et al., 2011 and Dubey et al., 2015). S. gigantea and S. medusiformis develop macroscopic cysts in striated muscles of sheep which are considered as causes of economic losses in the sheep industry. The heavily infected sheep meat by macroscopic cysts may be condemned as unfit for human consumption during meat inspection in abattoirs. Economic losses in Spain due to Sarcocystis infection to the Spanish sheep industry have been estimated 20 million Euros annually and an average 4 million sheep culled every year (Martínez-Navalon et al., 2012 and Farhang-Pajuh et al., 2014)
Identification of different species of Sarcocystis is based on the structure study of the cyst wall by using light or transmission electron microscope of tissue samples from infected hosts, primarily from the skeletal muscle, tongue, heart, diaphragm, and esophagus (Jehle et al., 2009 and Latif et al., 2015).
Several Serological tests such as enzyme-linked immunosorbent assay (ELISA), indirect fluorescent antibody test (IFAT), complement fixation tests and an agar gel diffusion test has also been used to detect sarcocystosis in animals and humans (Hay and Westwood, 2002; Kalita et al., 2015 and Latif et al., 2015).
The aim of the present studywas to determine the microscopical and serological prevalence of natural infection with Sarcocystis in the muscles of different organs (tongue, oesophagus, heart, diaphragm and skeletal muscles) of sheep slaughtered in Assuit Gov., Egypt, with identification of the parasite species by light and electron microscope. In addition studying the influence of age, gender of sheep on the infection rate.
MATERIALS AND METHODS
Collection of samples: In this study, Blood and muscle samples were collected from 100 sheep (42 male and 58 female) with age ranged from 6 momths to 5 years slaughtered at abattoirs from different locations in Assuit Governorate. Fresh tissue samples of tongue, oesophagus, heart, diaphragm and neck skeletal muscle were collected from each animal in clean separate labeled plastic bags. Samples were labeled separately, kept in icebox and rapidly transported to the lab where refrigerated at 4°C for further investigation. Moreover, blood sample were collected from each animal during slaughtering in clean, labeled centrifuge tube and their sera were separated by centrifugation and stored at -20°C until tested.
Macroscopic examination: Each fresh sample was thoroughly examined by naked eye for the presence of macroscopic Sarcocystis sp. cysts (Mahran, 2009).
Microscopic examination: According to (Mahran, 2009 and Latif et al., 2015), using Squash method “the compress method” where small pieces of fresh muscle measuring 2-3 mm3 were cut from each tissue sample and squeezed firmly between two glass slides and examined microscopically at 10 x magnifications.
Transmission electron microscopy (TEM): Specimens of muscles were prefixed in 2.5% glutaraldehyde solution, diced into 1 mm3, then rinsed three times for15 min each with 0.1 M phosphate buffer (pH 7.4). Post-fixation samples were placed in a cold 1% aqueous osmium tetroxide for 2 h. After rinsing with phosphate buffer again, the specimens were dehydrated in a graded ethanol series of 50–100% and then embedded in Epon 812. Semithin sections were sliced with glass knives on ultramicrotome for orientation and selection of representative tissue specimens and stained with 0.5% Toulidine blue according to Bancroft and stevens (1993). Ultrathin sections of (500-800 A°) were done using ultramicrotome then contrasted in uranyl acetate and lead citrate, and examined under a (Jeol, CX11) electron microscope in Electron Microscope unit, Assiut University.
Serological examination:
Preparation of antigen According to Hettiarachchi and Rajapakse (2008): antigen prepared from macroscopically visible Sarcocystis fusiformis cysts were obtained from the oesophagus of heavily infected buffaloes carcasses at Assuit city Abattoir. They were teased out of the muscle with fine forceps, collected into phosphate buffered saline (PBS) PH 7 and stored at –20 °C. Twinty sarcocysts were collected into tube and washed with saline to remove attached bovine tissue. Using fine forceps the cysts were macerated in 1 mL of PBS at room temperature until a cream coloured suspension formed. A drop of the suspension was examined under the light microscope (x40) to confirm presence of banana-shaped cystozoites. These cystozoites were centrifuged at 3000 r.p.m for 10 min, resuspended in PBS (PH 7), recentrifuged at 3000 r.p.m for 10 min and the supernatant discarded. The pellet of cystozoites was mixed with about 10 mL of 50% isotonic Percoll solution (Percoll® P1644-25ML, Sigma-Aldrich Co, St. Louis, MO 63103 USA) in a conical tube and centrifuged at 2500 rpm for 10 min. Extraction buffer consisting of 200μL 1% Triton diluted by PBS (PH 7) (TritonX-100, Sigma-Aldrich Co, St. Louis, MO 63103 USA) in PBS was then added to the eppendorf. The sample was mixed well by a whirly mixer for 5 min, while alternatively placing it in ice to avoid heating. The sample was then centrifuged for 10 min at 14000 rpm in 4°C. The resulting supernatant (antigen) was collected into eppendorfs then estimated of protein quantity in the antigen using BioTek® Instruments, Inc. (Center of Medical research in AssiutUniversity) and stored at –20°C.
Agar gel diffusion test: According to Hay and Westwood (2002) and Al-Taee et al. (2009), Fifteen mL of 1% agarose solution (Bioshop ® Canada Inc., Burlington, ON. L7L 6A4) in 8% saline was poured into a Petri dish 9 cm in diameter. Several wells were prepared in the agarose gel at a distance of 3 mm between the wells. Undiluted and untreated serum was used in this study. Each well in the gel was filled with the antigen or serum to be tested. The dish was kept in a moist chamber at room temperature for 4 days and the reaction was observed daily. When a distinct precipitin line was found in the gel, the serum was considered to have the antibody against Sarcocystis.
Statistical analysis: Statistical analysis was performed by SPSS (ver. 16, IBM, New York, USA) using χ2 test with 95% confidence interval, with considering P value (P <0.05) as significant difference (Mirzaei and Rezaei , 2016).
RESULTS
One hundred sheep muscle samples were examined for Sarcocystis spp., no macroscopic cysts were observed in the tissues sample of sheep by macroscopic examination. The infection rate of Sarcocystis spp. was 93% (93/100) by microscopic examination (Figure 1) and 28% (28/100) by Agar gel diffusion test (Table 1, Figure 2). The infection rate of Sarcocystis had very high significant differences between microscopic examination and Agar gel diffusion test. The infection rate of Sarcocystis spp. in different muscular tissues of sheep (Table 2), showed very high statistical significant effect on the infection rate (χ2=19.212, p>0.001). The highest infection rate was recorded in the oesophagus (71%) followed by the diaphragm (65%), tongue (58%) and skeletal muscles (53%); the lower rate was recorded in the heart muscles (43%). Concerning the sex, the infection rate of Sarcocystis spp. in male sheep was 95.2% (40/42), while in female was 91.4% (53/58) by microscopic examination (Table 3). Infection with Sarcocystis associated with age is shown in table 4, higher infection rate among sheep 6 months - 2 years 95% (38/40) than that of sheep between 2-4 years old 92.7% (38/41) and those equal or older than 4 years 89.5% (17/19). No significant differences between infection and age groups or sex of animals were observed.
The ultrastructural evaluation of Sarcocystis spp. in sheep was mainly targeted to the cyst walls. The use of TEM allowed the identification of S. tenella and S. arieticanis in sheep. Examination of S. tenella cyst in semithin section showed cyst wall with villar protrusions. Metrocytes were adhered the inner surface of the cyst wall followed by bradyzoites in groups separated from each other’s with fine septa (Figure 3). Examination of S. tenella cyst with TEM showed that the cyst wall consisted of palisade-like villar protrusions. The ground substance is located directly under the primary cyst wall. Bradyzoites found in inner side of ground substance. Host mitochondria and host cells found near cyst surface (Figure 3, 4). Examination of S. arieticanis cyst with TEM showed that the cyst wall consisted of hair-like villar protrusions parallel to cyst wall. The ground substance is located directly under the primary cyst wall. Sections of bradyzoites found in inner side of ground substance contain ampylopectin granules. Host mitochondria found near cyst surface (Figure 5).
Table 1: Comparative efficiency of techniques used for detection of Sarcocystis spp. in sheep.
Technique |
No. of examined sheep |
No. of positive*** |
% |
ᵡ2 |
P |
Light microscopy |
100 |
93 |
93 |
88.4 |
<0.0001 |
Agar gel diffusion test |
100 |
28 |
28 |
*** Very high significant differences (P<0.0001)
Table 2: Infection rate of Sarcocystis spp. in different organs of sheep using light microscope.
Organ |
No. of examined |
No. of positive*** |
% |
ᵡ2 |
P |
Oesphagus |
100 |
71 |
71 |
19.212 |
<0.001 |
Tongue |
100 |
58 |
58 |
||
Heart |
100 |
43 |
43 |
||
Diaphragum |
100 |
65 |
65 |
||
Skeletal muscle |
100 |
53 |
53 |
*** Very high significant differences (P<0.001)
Table 3: Effect of sex on the infection rate of Sarcocystis spp. in sheep using light microscope.
Sex of sheep |
No. of examined sheep |
No. of positive |
% |
ᵡ2 |
P |
Female |
58 |
53 |
91.4 |
0.557 |
>0.05 |
Male |
42 |
40 |
95.2 |
||
Total |
100 |
93 |
93 |
Insignificant differences (P>0.05)
Table 4: Effect of age on the infection rate of Sarcocystis spp. in sheep using light microscope.
Age of sheep |
No. of examined sheep |
No. of positive |
% |
ᵡ2 |
P |
6 m - 2 y |
40 |
38 |
95 |
0.615 |
>0.05 |
2 to <4 year |
41 |
38 |
92.7 |
||
≥4 year |
19 |
17 |
89.5 |
||
Total |
100 |
93 |
93 |
Insignificant differences (P>0.05)
Figure 1: Fresh Sarcocystis spp. cysts in the muscles of sheep compressed between two slides, showing cyst parallel to muscle fibers; Note spindle shaped cyst (arrow head) and septa (arrow) dividing the internal compartments are seen as dark structures (X 10).
Figure 2: Agar gel diffusion test for diagnosis of Sarcocystis spp. in sheep. A. Agarose gel with Sarcocystis antigen (Ag) in central well and sheep tested sera (S) in peripheral wells in petri dish. B. showing precipitin line (arrow) between positive serum sample and antigen.
Figure 3: Morphological characteristics of Sarcocystis tenella cysts from sheep muscle. (A) Semithin section of Sarcocystis tenella in muscle of sheep, showing cross section of cyst inside muscle fiber showing villar protrusions (arrows). Metrocytes (Me) found in the inner side of wall followed by bradyzoites (Bz) in chambers. Toluidine blue stain (X100). (B) Transmission electron micrograph (TEM) showing cross-section of a sarcocyst with cross sections of villar protrusions (VP), ground substance (Gs) and bradyzoites (Bz) in inner side of ground substance. Note host mitochondria (Hm) and host cells (Hc) near cyst surface (14000X).
Figure 4: TEM of Sarcocystis tenella from muscle of sheep. (A) TEM showing longitudinal sections showing palisade-like villar protrusions (VP). Sections of bradyzoites (Bz) found inner side of ground substance (Gs) separated by septa (S) (19000X). (B) TEM showing Palisade-like villar protrusions (VP). Sections of bradyzoites (Bz) found in inner side of ground substance (Gs) contain micronemes (m) separated by septa (S) Note host cell (Hc) near cyst surface (19000X).
Figure 5: TEM of Sarcocystis arieticanis sarcocysts from sheep muscle. (A) Showing hair-like villar protrusions (VP) parallel to cyst wall. Sections of bradyzoites (Bz) found in inner side of ground substance (Gs) contain several ampylopectin granules (A). Note host cell (Hc) near cyst surface (29000X). (B) Showing sections in villar protrusions (VP). Different sections of bradyzoites (Bz) found inside cyst separated by septa (s). Bradyzoites in inner side of ground substance (Gs) contain micronemes (m). Note host mitochondria (Hm) near cyst surface (14000X).
DISCUSSION
Sarcocystis spp. are the most common parasites in domestic ruminants and some of them can generate significant economic losses due to decreased production rates or death of the most severely infected animals (Martínez-Navalón et al., 2012 and Hu et al., 2017).
No macroscopic cysts were observed in the tissues sample of the 100 sheep by macroscopic examination in our study. This result is in line with those recorded before in Dakahlia Governorate, Egypt (Abd El-Kader, 2008); Iran (Hajimohammadi et al., 2014); Brazil (Bittencourt et al., 2016) and Iraq (Zangana and Hussein, 2017), whereas Mahran (2009) and El-Mishmishy (2017) reported an infection rate of 9.9% and 0.74% in sheep in Red Sea and Cairo Governorates, respectively. Moreover, Martínez-Navalon et al. (2012) reported an infection rate of 12% in Spain and (Bahari et al., 2014) 5% in Iran. The absence of macroscopic sarcocysts in the present study, in comparison with high infection rate of microscopic sarcocysts may be due to the fact that such cysts are of feline origin which characterized by production of low number of sporocysts. The results were in agreement with, Dubey et al. (1989b)who mentioned that Sarcocystis species transmitted by felides have been found less frequent than those transmitted by canids because of low oocyst production in those hosts. Also, Fouly (1997) reported that no sporocysts of Sarcocystis are found in all collected faecal samples of cats in Assiut.
In the present study, the infection rate ofSarcocystis in sheep was 93% (93/100) by microscopic examination. This result agreed with those recorded by El-Mishmishy (2017) who mentioned that the prevalence of Sarcocystis spp. cysts at 3 Egyptian Provinces (Dakahlia, Damietta and Cairo) was 95.37%. Moreover studies carried out from different countries have reported similar prevalence of infection in sheep, in Ethiopia (Woldemeskel and Gebreab, 1996) reported an infection rate of 93.6%, also (Bittencourt et al., 2016) and (Hu et al., 2017) reported an infection rates of 95.8% and 91.9% in sheep in Brazil and china, respectively. The high infection rate of infection by Sarcocystis in the present work might be due to presence of the examined sheep in rural areas in close association with dogs which contaminate the animal’s food with large number of Sarcocystis sporocysts. In addition to that the sporocysts are mostly infective already when passed in the faeces. The result were in agreement with Nourollahi Fard et al. (2009) and Latif et al. (1999) who recorded that carnivorous such as canine, infect environment via faeces by passing 200 million oocyst of Sarcocystis during infection period.
Whereas our result was lower than those previously reported by Whaeeb and Faraj (2016) 100%, Zangana and Hussein (2017) 97.5% in Iraq and Hajimohammadi et al. (2014) 97.14%, Mirzaei and Rezaei (2016) 100% in Iran. On the contrary, lower values were recorded by various authors (61.41%) in Assiut Governorate (Taher, 1985); 81.8% at Shalatin abattoir Red Sea Governorate (Mahran, 2009); 65.15% in New-Valley Governorate (Elbadre et al., 2014) and from different countries 47.32% in Turkey (Ozkayhan et al., 2007), 81.5-90% in K.S.A. (Al Quraishy et al., 2014), 86% in Malaysia (Latif et al., 2015) and 72.2% in India (Gopal et al., 2016). The variation in these results may be attributed to the difference in the diagnostic technique used, study locality, management conditions and number of samples (Mahran, 2009; Farhang-Pajuh et al., 2014; Latif et al., 2015 and Gopal et al., 2016).
Theinfection rate of Sarcocystis spp. in sheep was 28% (28/100) by Agar gel diffusion test. So, using antigen prepared from macroscopically visible Sarcocystis fusiformis cysts could be used in serological diagnosis of sheep Sarcocystis. This finding agrees withthat observedby Dubey and Fayer (1983)who recorded that antigen prepared from Sarcocystis of one host generally cross reaction with antibodies against homologous and heterologous species of Sarcocystis. Similar results reported byAl-Taee et al. (2009) who revealed that the rate of Sarcocystis sp. infection in 100 sheep was 82% by Modified Enzyme linked Immunosorbent Assay (ELISA) and 25% by Agar gel precipitation test in Iraq. Significant differences were detected in sensitivity of these serological tests.
Our results revealed that theinfection rate of Sarcocystis in sheep was 93% by microscopical examination while was 28% by Agar gel diffusion test.These differences may be due to variation in the intensity of infection in these animals which in turn effect of the amount of the released antibodies that can be detected by Agar gel diffusion test. This finding agree with Gasbarre et al. (1984) who detected that IgG antibody levels of sheep inoculated with Sarcocystis ovicanis was slightly delayed increase (6 to 8 weeks after inoculation was done). Also, measurable IgM antibody response was not seen in sheep.
Concerning the infection rate of Sarcocystis spp. in different muscular tissues of sheep, this study showed variable rates of distribution of sarcocysts in the tissues with very high statistical significant effect on the infection rate (χ2=19.212, p>0.001). The highest infection rate was recorded in the oesophagus (71%) followed by the diaphragm (65%), tongue (58%) and skeletal muscles (53%); the lower rate was recorded in the heart muscles (43%). In Red Sea Governorate, Mahran (2009) made similar observation he revealed that maximum sarcocysts were found in the muscles of oesophagus in sheep (71.1%) followed the diaphragm, tongue, skeletal muscles and the heart muscles (54.9%, 48.6%, 40.7% and 36.9%), respectively. Likewise, Hu et al. (2017) in Chinamentioned that the distribution of the sarcocysts was 84.9% in esophagus, 32.6% in tongue, 57% in diaphragm, 20.9% in heart and 79.1% in skeletal muscles. These differences in the infection rate of the organs of sheep might be due to various external factors, such as Sarcocystis spp. responsible for infection, or differences in the study locality and nutritional status of the hosts that may lead to variations in the immunity of the host against infection (Latif et al., 2015).
Observation on the variation due to the sex of sheep on infection rate of sarcocysts infection, showed that males were more infected 95.2% than females 91.4%, but there was no significant difference between different sexes. This result correlated with the observation of Farhang-Pajuh et al. (2014) that found that the prevalence was 55.17% and 15.20% among male and female sheep, respectively. Likewise, Hajimohammadi et al. (2014); Mirzaei and Rezaei (2016) and Zangana and Hussein (2017) found no significant difference between males and females. However, in a study by El-Mishmishy, (2017) he reported that ewes had a higher prevalence of infection (99%) than males (94.55%). These differences may be due to difference in the management conditions in such localities.
In relation to age;the infection rate of Sarcocystis spp. in sheep showed higher infection rate among sheep 6 monthes- 2 years (95%) than that of sheep between 2-4 years old (92.7%) and those equal or older than 4 year (89.5%), no significant difference was observed. This result agreed with Hajimohammadi et al. (2014) and Mirzaei and Rezaei (2016) that found no significant difference in infection of younger and older animals. While disagreed with Mahran (2009); Elbadre et al. (2014) and El-Mishmishy (2017) that reported higher infection rate among older sheep than that younger one. These differences may be due to difference in location, number of samples and management conditions.
Although light microscopic examination is commonly used for identification of sarcocysts, electron microscopy has been used to identify Sarcocystis spp. according to their wall structure (Haziroglu et al., 2002 and Heckeroth and Tenter, 2007).
In the present study, the use of TEM of Sarcocystis wall showed palisade-like villar protrusions which allowed the identification of Sarcocystis tenella. While, the cyst wall of Sarcocystis thatshowed hair-like villar protrusions parallel to cyst wall wereidentified as Sarcocystis arieticanis. These results were in agreement with Dubey et al. (1989b) and Heckeroth and Tenter (2007) who described S. arieticanis with hair-like projections in the walls of their cysts. Similar results reported by Bittencourt et al. (2016) and Hu et al. (2017) who identified the ultrastructural of Sarcocystis tenella and S. arieticanis in tissues from sheep in Brazil and China, respectively.
Our results revealed that S. arieticanis cysts were septated, similarly as observed by Heydorn and Mehlhorn (1987) and Bittencourt et al. (2016) who noted that the septa inside some cysts are sometimes not easily visualized, especially in large cysts with large compartments. In contrary, Dubey et al. (1988) described S. arieticanis cysts lack of septa in from sheep in the USA which probably due to the low number of analyzed cysts.
In the present work, TEM revealed the mitochondria were seen to be concentrated near the villar protrusions of Sarcocystis in some host cells of muscle. This finding was similar to that mentioned by Abdel Mawla (1990) who suggested the presence of mitochondria with Sarcocystis infection due to disappearance of myofibrillar pattern in the precystic zone, then loss of the typical linear distribution of the muscle mitochondria and causes their crowding in the ultrastructure study.
Our results revealed a high infection rate of Sarcocystis in sheep. Therefore, we recommend that feed supplies of sheep must be protected from faecal contamination by carnivores. Also, it has of great importance the farmers to be trained not to feed their dogs and cats with uncooked meat in order to be effectively broken of infection cycle between sheep and carnivores.
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دراسات مجهرية ومصلية مع توصيف الترکيب الدقيق لأنواع السارکوسيست في الأغنام في أسيوط
باسم رفعت نجيب ،هدى محمد محمد قراعه
E-mail: Basemnageib@gmail.com; Huda5380@yahoo.com Assiut University web-site: www.aun.edu.eg
أجريت هذه الدراسة لتحديد مدى انتشار طفيل السارکوسيست في الأغنام في أسيوط. وقد تم فحص عدد 100 من الأغنام لطفيل السارکوسيست وقد وجد ان معدل الاصابة 93٪ (93/100) بإستخدام الفحص المجھرى و 28٪ (28/100) بإستخدام اختبار الانتشار خلال جل الأجار. أظھرت ھذه الدراسة أن هناک فروق معنوية کبيرة جدا لمدى انتشار طفيل السارکوسيست باستخدام الفحص المجهري واختبار الانتشار خلال جل الأجار. لم يتم ملاحظة أي مـن السارکوسيست العينى بالفحص الظاهرى. وقد وجد تأثير معنوي إحصائي کبير على انتشار طفيل السارکوسيست في مختلف عينات عضلات الأغنام. وقد سجلت أعلى نسبة إصابة في المريء (71٪) تليها الحجاب الحاجز (65٪) واللسان (58٪) والعضلات الهيکلية (53٪) وعضلات القلب (43٪). وکانت نسبة الإصـابة بطفيل السارکوسيست في الذکور 95,2٪ (40/42) بينما في الإناث کانت 91,4٪ (53/58) عن طريق الفحص المجهري. وقد تم الکشف عن ارتفاع معدل الإصابة بطفيل السارکوسيست في الأغنام فى عمر أقل من سنتين 95٪ (38/40) عن الأغنام بين عمر 2-4 سنوات 92,7٪ (38/41) وأولئک الذين اعمارها تساوي أو أکبر من 4 سنوات 89,5٪ (17/19) . لم يلاحظ أي فرق معنوى بين العدوى فى الفئات العمرية المختلفة أو جنس الحيوانات. وقد ساعد استخدام المجهر الإلکتروني على تحديد نوع السارکوسيست تينيلا والسارکوسيست أريتيکانيس في الأغنام. حيث تبين وجود إمتـدادات زغبيـه مثل الحواجز بفحص جدار السارکوسيست تينيلا في حين أظهر فحص جدار السارکوسيست أريتيکانيس وجود إمتـدادات زغبيـه تشبـه الشعيـرات على سطح الجـدار وتکـون تقريبا مـوازيه للسطح.