Light and electron microscopic observations confirmed that Eimeria necatrix sporozoites first enter villous epithelial cells of the chicken small intestine and are transported to the crypts by mononuclear cells. Ultrastructurally, these cells resemble granulated intraepithelial lymphocytes (IEL) rather than macrophages, as suggested previously. The injection of chickens intraperitoneally (i.p.) with a variety of irritants, including proteose peptone, at the time of oocyst inoculation or up to 12 hr postinoculation (PI) resulted in a delay in the arrival of sporozoites at the crypt. Significantly fewer sporozoites had arrived at the crypt by 24 hr PI in i.p.-injected birds as compared to controls. This delay in the arrival of sporozoites at the crypts was reflected by a delay in the development of intestinal lesions and in peak oocyst production. However, there was no significant decrease in the total numbers of oocysts produced by these birds as compared to controls, indicating that no significant loss of sporozoites occurs during the possible rerouting of the parasites. The presence of infective stages in extraintestinal sites was detected by transferring various tissues to coccidia-free recipients. Infection was transferable by gut, liver, and spleen from irritant-injected and control birds at all time intervals studied (12, 24, 36, and 48 hr PI). Infection was also transferable with blood and kidney, but not consistently. A small number of oocysts was passed by the recipients of peritoneal wash from irritant-injected birds at 12 hr PI. In all transfers, the prepatent period was normal, suggesting that the migrant stages are sporozoites.
The development of second generation schizonts of Eimeria necatrix and E. tenella was studied with the electron microscope. Invasion of the crypt epithelial cells by merozoites of the first generation schizonts caused changes in the morphology of the infected cells and stimulated their migration into the lamina propria through breaks which appeared in the basement membrane of the crypts. Second generation schizonts developed in the lamina propria within these crypt cells whose epithelial origin was confirmed by their interconnection by desmosomes and tight junctions and by their possession of characteristic microvilli. A comparison is made between this invasion of the lamina propria by parasitized cells and invasion of connective tissue by malignant epithelial cells; the possible mechanisms involved are discussed.
Chickens were dosed orally with sporulated oocysts of Eimeria acervulina, E. brunetti, E. maxima, or E. praecox and the subsequent presence, in various tissues, of parasites capable of inducing patent infections was detected by transferring the tissues to coccidia-free recipients. Similar results were obtained with each of the 4 species studied, irrespective of whether initial development occurs in the superficial (E. praecox, E. brunetti) or crypt (E. acervulina, E. maxima) epithelium. Infection was transferable by gut scrapings and liver homogenates at all time intervals (3, 6, 12, 18, 24, and 36 hr postinoculation) studied. Infection was also transferable with blood and with splenic homogenates but not consistently. Transfers made within a short time of the inoculation of donors were more successful in producing patent infections in the recipients. In all transfers the prepatent period was normal for the species. These findings suggest that sporozoites enter the mucosa very shortly after inoculation, and some of them pass to the liver and spleen and then leave these tissues at a somewhat slower rate, possibly to reenter the mucosa. Sporozoites in the lamina propria of the gut were found within host mononuclear cells in all 4 species studied. Most of the cells harbouring E. maxima and some of those with E. praecox were identified as intraepithelial lymphocytes while all others could only be identified as agranular mononuclear cells that were not characteristically macrophages.
Pelecitus galli n.sp. is described from the Malayan jungle fowl Gallus gallus spadiceus. It differs from other species of the genus in the size of the spicules, number and arrangement of caudal papillae in the male, and the relative position of the vulva. It is also the first species of Pelecitus described from the genus Gallus.Three types of microfilariae were seen in blood and lung smears of two jungle fowls trapped in Tasek Bera in Pahang State. One of these microfilariae is indisguishable from that described by Dissanaike (1963) from the Ceylon jungle fowl. One of the other two resembles the microfilaria of Pelecitus ceylonensis described from Ceylon (Dissanaike, 1967) and adults were found between the tendons at the bases of the legs of one of the jungle fowls examined.
A cDNA library was constructed with poly(A)+ RNA from unsporulated oocysts of Eimeria tenella in pUC18. After screening, 4 cDNA clones that hybridized to RNA of unsporulated and sporulating oocysts but not to RNA of either sporulated oocysts or second generation merozoites were isolated and characterized. Each of the cDNA clones is unique. The loci for 2 of the clones are on E. tenella chromosome 7, the site of the third is located on chromosome 6 and the last clone hybridizes, for the most part, to chromosome 5 but also to other E. tenella chromosomes. The cognate RNAs for each of the cDNA clones show differential patterns of hybridization during oocyst sporulation with the levels of RNA being low at the start of sporulation (0 hr), increasing to peak levels between 6.5 and 23 hr after the onset of sporulation and, in each case, decreasing to low hybridization levels at 48 hr after initiation of sporulation. These results establish that specific mRNA levels are differentially regulated during sporulation.
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