Phenotypic and functional characterisation of follicle-associated epithelium of rectal lymphoid tissue.

Lymphoid follicles cluster in the terminal rectum of various animal species and of man and hence this site may be important in the development of immune responses to pathogens. For the induction of immune responses at mucosal sites, interplay is required between various cell types performing functions ranging from antigen-sampling cells via antigen-presenting cells to antigen-specific lymphocytes. Therefore, we have characterised the cell populations and relevant functioning of follicle-associated epithelium (FAE) and associated follicles in the terminal portion of rectum in cattle as a representative mammal. Immunohistochemical studies of this region identified immune cell subsets (CD4+, CD8+, WC 1+gammadelta, CD2+, CD 21+ and CD 40+ cells) characteristic of an immune-inductive site. Examination of FAE identified a subset of cells with structural and functional features of antigen-sampling M-cells. Cells of the FAE and adjacent follicle-associated crypts expressed vimentin and a subset of these cells internalised microparticles, a further attribute of M-cells. The FAE cells were phenotypically heterogeneous and therefore the function and phenotype of these cell subsets requires further characterisation, particularly with respect to their potentially important role in the interaction of hosts with pathogens and the development of immune responses.

Regulation, secretion and activity of type III-secreted proteins of enterohaemorrhagic Escherichia coli O157.

Enterohaemorrhagic Escherichia coli (EHEC) O157:H7 causes gastrointestinal disease with the potential for life-threatening sequelae. Although Shiga-like toxins are responsible for much of the serious pathology in humans, the bacterium also possesses a type III protein secretion system that is responsible for intimate attachment to host intestinal mucosa. This sophisticated interaction requires co-ordination that is governed by environmental and genetic factors. Ongoing research supports the following model for how EHEC enables and controls this process: (i) specific environmental cues that are present in the host result in the expression of a number of adhesins, including fimbriae, which allow the initial binding to the mucosal surface. The same conditions support the expression of the basal type III secretion apparatus; (ii) targeting and assembly of the translocon requires both an mRNA signal and chaperones, with coupled translation and secretion of translocon proteins, EspA, B and D; (iii) opening up of a conduit between the bacterium and host cell releases a cytoplasmic pool of effector proteins. A consequence of this is increased expression of particular effector proteins. Potentially, different proteins could be released into the cell at different times or have activities modulated with time; (iv) intimate contact between the translocated intimin receptor (Tir) and the bacterial surface factor intimin requires translocon expression to be down-regulated and translocon filaments to be lost. Fluorescent protein fusions allow contact-mediated regulation and protein targeting through the type III secretion system to be studied in detail.