Identification of Cj1051c as a major determinant for the restriction barrier of Campylobacter jejuni strain NCTC11168.

Campylobacter jejuni is a leading cause of human diarrheal illness in the world, and research on it has benefitted greatly by the completion of several genome sequences and the development of molecular biology tools. However, many hurdles remain for a full understanding of this unique bacterial pathogen. One of the most commonly used strains for genetic work with C. jejuni is NCTC11168. While this strain is readily transformable with DNA for genomic recombination, transformation with plasmids is problematic. In this study, we have identified a determinant of this to be cj1051c, predicted to encode a restriction-modification type IIG enzyme. Knockout mutagenesis of this gene resulted in a strain with a 1,000-fold-enhanced transformation efficiency with a plasmid purified from a C. jejuni host. Additionally, this mutation conferred the ability to be transformed by plasmids isolated from an Escherichia coli host. Sequence analysis suggested a high level of variability of the specificity domain between strains and that this gene may be subject to phase variation. We provide evidence that cj1051c is active in NCTC11168 and behaves as expected for a type IIG enzyme. The identification of this determinant provides a greater understanding of the molecular biology of C. jejuni as well as a tool for plasmid work with strain NCTC11168.

Assessment of myosin II, Va, VI and VIIa loss of function on endocytosis and endocytic vesicle motility in bone marrow-derived dendritic cells.

An essential feature of dendritic cell immune surveillance is endocytic sampling of the environment for non-self antigens primarily via macropinocytosis and phagocytosis. The role of several members of the myosin family of actin based molecular motors in dendritic cell endocytosis and endocytic vesicle movement was assessed through analysis of dendritic cells derived from mice with functionally null myosin mutations. These include the dilute (myosin Va), Snell's waltzer (myosin VI) and shaker-1 (myosin VIIa) mouse lines. Non muscle myosin II function was assessed by treatment with the inhibitor, blebbistatin. Flow cytometric analysis of dextran uptake by dendritic cells revealed that macropinocytosis was enhanced in Snell's waltzer dendritic cells while shaker-1 and blebbistatin-treated cells were comparable to controls. Comparison of fluid phase uptake using pH insensitive versus pH sensitive fluorescent dextrans revealed that in dilute cells rates of uptake were normal but endosomal acidification was accelerated. Phagocytosis, as quantified by uptake of E. coli, was normal in dilute while dendritic cells from Snell's waltzer, shaker-1 and blebbistatin treated cells exhibited decreased uptake. Microtubule mediated movements of dextran-or transferrin-tagged endocytic vesicles were significantly faster in dendritic cells lacking myosin Va. Loss of myosin II, VI or VIIa function had no significant effects on rates of endocytic vesicle movement.