Schistosoma mansoni: cellular reactions to challenge infections in the cheek pouch skin of chronically infected Chinese hamsters

A secondary wave of neutrophil infiltration causes necrosis and ulceration in lesions of experimental American cutaneous leishmaniasis

We evaluated the importance of neutrophils in the development of chronic lesions caused by L. Viannia spp. using the hamster as experimental model of American Cutaneous Leishmaniasis (ACL). Neutrophils infiltrated the lesion within the first six hours post-infection. Inhibition of this early infiltration using a polyclonal antibody or cyclophosphamide was associated with transient parasite control but the protective effect vanished when lesions became clinically apparent. At lesion onset (approximately 10 days p.i.), there was an increased proportion of both uninfected and infected macrophages, and subsequently a second wave of neutrophils infiltrated the lesion (after 19 days p.i.) This second neutrophil infiltration was associated with lesion necrosis and ulceration (R² = 0.75) and maximum parasite burden. Intradermal delivery of N-formylmethionyl-leucyl-phenylalanine (fMLP), aimed to increase neutrophil infiltration, resulted in larger lesions with marked necrosis and higher parasite burden than in mock treated groups (p<0.001 each). In contrast, reduced neutrophil infiltration via cyclophosphamide-mediated depletion led to more benign lesions and lower parasite loads compared to controls (p<0.001 each). Neutrophils of the second wave expressed significantly lower GM-CSF, reactive oxygen species and nitric oxide than those of the first wave, suggesting that they had less efficient anti-leishmania activity. However, there was increased inflammatory cytokines and expression of neutrophil proteases (myeloperoxidase, cathepsin G and elastase) in lesions during the second wave of neutrophil infiltration compared with the levels reached during the first wave (6h p.i.). This suggests that augmented neutrophil proteases and inflammatory cytokines during the secondary wave of neutrophils could contribute to skin inflammation, ulceration and necrosis in ACL. The overall results indicate that neutrophils were unable to clear the infection in this model, and that the second wave of neutrophils played an important role in the severity of ACL.

Waterborne zinc alters temporal dynamics of guppy Poecilia reticulata epidermal response to Gyrodactylus turnbulli (Monogenea)

The present study assessed the histological changes in the epidermis of Poecilia reticulata induced by the combined effects of an ectoparasite Gyrodactylus turnbulli and differing concentrations of waterborne zinc (Zn). Infected guppies were exposed to 0, 15, 30, 60, or 120 µg Zn l-1 and monitored over 3 wk during the exponential increase in parasite numbers on the fish. The fish epidermis responded within 3 d to G. turnbulli infection with a rapid increase in epidermal thickness and a modest increase in number, but not size or composition, of mucous cells. In contrast, in the presence of combined waterborne Zn and infection, mucous cell numbers declined rapidly. As the parasite numbers increased, the epidermis remained thicker than normal, and the number and size of mucous cells decreased. The addition of Zn led to a dramatic thickening of the epidermis during the exponential growth of the parasite population. Mucous cell numbers remained depressed. Temporal changes in mucous cell size were Zn concentration dependent. At 60 µg Zn l-1, cells returned to normal size as infection progressed, whereas they remained extremely small at 120 µg Zn l-1. Changes in mucin composition previously reported in response to Zn alone were subdued in the presence of the parasite except at 60 µg Zn l-1, where all cells contained only acidic mucins. Together these results demonstrate that, on exposure to both Zn and G. turnbulli infection, the epidermal response is initially a protective response to both stressors, and then mainly driven by the increased parasite burden.

The Chinese or Striped-Back Hamster

Chinese hamsters are small rodents with a grayish black coat and a black dorsal stripe. Adult animals weigh approximately 39–46 gm, and measure approximately 9 cm in length. This species has been shown to be susceptible to a number of experimentally induced viral, bacterial, and parasitic infections. In recent years, the Chinese hamster's contributions as a laboratory animal have been largely overshadowed by the focus on its cell lines and the role it plays in scientific research and biotechnology. The Chinese hamster used in biomedical research is traditionally classified as Cricetulus griseus. It has several biological features that have helped promote its use in biomedical research and these attributes include its small size, polyestrous cycle, short gestation period, and low chromosome number. The Chinese hamster has a low incidence of spontaneous and endogenous viral infections. This species has been shown to be susceptible to a number of experimentally induced viral, bacterial, and parasitic infections. Chinese hamster-derived cells have played a major role in cytogenetic toxicity assays and the production of glycosylated therapeutic proteins. The behavior, research uses, and general toxicology of the Chinese hamster are summarized in this chapter.

Susceptibility of Chinese hamsters (Cricetulus griseus) to the infection of Babesia microti

Chinese hamsters were examined for the susceptibility to the infection with Babesia microti based on the hematological parameters during the course of infection. A marked decrease in the RBC count, Ht value, Hb concentration, and an increase in WBC count due to the development of neutrophils or monocytes were recognized with the progress of parasitemia. Remarkable clinical findings were anemia and persistent infection with a low level of parasite burden in the chronic and convalescent stages. From these findings, it was concluded that Chinese hamsters were susceptible to infection with B. microti and would be useful for infection examination with the parasite.

Immunocytochemistry of cytoskeletal proteins in adult Schistosoma mansoni

Antisera to vertebrate actin and actin-binding proteins were used to characterize the cytoskeleton of adult Schistosoma mansoni. Actin, alpha-actinin and tropomyosin immunoreactivities were detected in the cytoplasm of the apical tegument. Antiserum to alpha-actinin bound to the tegumental spines and this protein may be involved in cross-linking of spine actin filaments. Actin, alpha-actinin and tropomyosin antisera bound to the musculature. Strongest immunoreactivity was seen in the parenchyma. Antisera to actin, alpha-actinin, tropomyosin and spectrin bound to parenchyma cells including those of the tubercles, suggesting that these proteins are located in muscle cell bodies. The distribution of cytoskeletal proteins is discussed in relation to tegumental repair processes.

A histological study of skin reactions of baboons to Schistosoma mansoni schistosomula

A histological study was undertaken of the cellular reaction in the skin of baboons challenged with cercariae of Schistosoma mansoni. Control animals with no previous schistosome infection were compared with baboons that had infections of varying duration. In animals infected for 10 weeks no striking inflammatory reaction was seen, the histological picture being very similar to that of the control animals. After 8 months of infection the hosts developed a strong cellular response to the invading schistosomula. The predominant cells in these reactions were eosinophil leucocytes which sometimes closely adhered to degenerating schistosomula. However, some unaffected schistosomula were found close to these intense cellular reactions, suggesting that schistosomula possess varying ability to resist the host's immunological attack.

The role of pulmonary cellular reactions in the resistance of vaccinated mice to Schistosoma mansoni

A histopathological and ultrastructural study was made of schistosomula and associated inflammatory reactions in the lungs of normal mice, and mice previously vaccinated with irradiated cercariae. In normal mice at day 7 post-infection all schistosomula were located in blood vessels. From day 11 onwards an increasing proportion of schistosomula were intra-alveolar (80% from day 20). No cellular reactions were evident around intravascular parasites in normal mice but at later sampling times large compact foci were associated with alveolar parasites. Initial reactions, probably in response to non-specific tissue damage, were approximately 50% polymorphonuclear, and 50% mononuclear. Mononuclear cells predominated at later times. In spite of inflammation, no damage to the schistosomula was observed. There was no evidence for re-entry of schistosomula into blood vessels, and it was assumed entry into alveoli occurred accidentally as parasites attempted to traverse pulmonary blood vessels. The pattern of localization of schistosomula in vaccinated mice was similar to that in normal mice, the proportion in alveoli increasing with time (64% from day 20). The most significant difference was that intravascular schistosomula attracted foci of host leucocytes which were always 85% or more mononuclear, containing both lymphocytes and macrophages. The infiltrating cells enlarged the intersititium, separating the vascular endothelium from the alveolar epithelium. Fibrous protein was also deposited in the interstitial region. In some instances the complete blood-air barrier was destroyed by the infiltrates. Unusual paracrystalline inclusions were observed in alveolar macrophages and giant cells. The differences in cellular responses in vaccinated and normal mice suggest that challenge schistosomula stimulated an anamnestic immune response. The resulting inflammation, by impeding movement through the vasculature, terminated migration in the lungs, and accounted for the observed resistance to reinfection. The reactions in vaccinated mice have many of the features of a delayed hypersensitivity response implying that lung phase resistance in vaccinated mice may be T-cell rather than antibody-mediated.

Techniques for locating isotopically labelled schistosomula of Schistosoma mansoni in host tissues for ultrastructural investigations

The use of 75 Selenomethionine labelled cercariae of Schistosoma mansoni for ultrastructural localization of parasites in host tissues has been evaluated. Both gamma counting of tissue, and autoradiography of resin-embedded tissue were successful. The autoradiographic technique was more sensitive and schistosomula were readily located in pulmonary tissue up to 24 days post-infection.

Schistosoma mansoni: an ultrastructural examination of skin migration in the hamster cheek pouch

The hamster cheek pouch has been used to investigate the skin migration of schistosomula at the ultrastructural level. Parasites have been observed up to 72 h post-infection. Despite rapidly reaching the epidermal basement membrane schistosomula remain in an epidermal location for at least 40 h post-infection, by which time the acetabular glands and their ducts have been lost and the transformation from cercaria to schistosomulum completed. Entry into the dermis and exit from the skin via the blood vessels is therefore by mechanical means or by lytic secretions emanating from a source other than the acetabular glands. The head gland which persists in the dermal schistosomula is a probable source of such secretions. The observations suggest that the apical area and musculature of the head capsule are important in gaining access to the lumen of blood vessels.