Atomic force microscope imaging of phospholipid bilayer degradation by phospholipase A2.

We have investigated the time course of the degradation of a supported dipalmitoylphosphatidylcholine bilayer by phospholipase A2 in aqueous buffer with an atomic force microscope. Contact mode imaging allows visualization of enzyme activity on the substrate with a lateral resolution of less than 10 nm. Detailed analysis of the micrographs reveals a dependence of enzyme activity on the phospholipid organization and orientation in the bilayer. These experiments suggest that it is possible to observe single enzymes at work in small channels, which are created by the hydrolysis of membrane phospholipids. Indeed, the measured rate of hydrolysis of phospholipids corresponds very well with the enzyme activity found in kinetic studies. It was also possible to correlate the number of enzymes at the surface, as calculated from the binding constant to the number of starting points of the hydrolysis. In addition, the width of the channels was found to be comparable to the diameter of a single phospholipase A2 and thus further supports the single-enzyme hypothesis.     

Ketone Body Utilization for Lipid Synthesis in the Murine Sciatic Nerve: Alterations in the Dysmyelinating Trembler Mutant

This work demonstrates that in vitro sciatic nerves of normal and trembler adult mice can use ketone bodies (beta-hydroxybutyrate and acetoacetate) and butyrate for lipid synthesis. In normal sciatic nerves, beta-hydroxybutyrate is incorporated in total lipids to a larger extent than acetoacetate (141% and 33%, respectively, of acetate incorporation), whereas for trembler sciatic nerves, these percentages are only 69% and 27%. Incorporation of ketone bodies is greater into sterols than into other lipids. Lipid metabolism of ketone bodies in trembler nerves is altered and could reflect a process similar to Wallerian degeneration: a dramatic decrease of sterol and free fatty acid synthesis and an increased synthesis of triglycerides. Moreover, differences seen in precursor incorporation into lipids between normal and trembler sciatic nerves suggest that their lipid metabolism is not the same.     

Granula motion and membrane spreading during activation of human platelets imaged by atomic force microscopy.

The redistribution of platelet constituents during activation is essential for their physiological function of maintaining hemostasis. We report here about real time investigations of the activation of native human platelets under physiological conditions from the initial formation of filopodia to the fully spread form by atomic force microscopy. We followed the trafficking of granules and their interaction with the plasma membrane within single cells. Our results show movement of certain granula towards the lamellipodia. Analysis of this rearrangement and the subsequent enlargement of the platelet surface reveals details of the membrane spreading process. Images of living cells are presented that show the distribution of cytoskeletal components and membrane-bound filaments at a resolution of better than 50 nm. The local minimum forces between the tip and the platelets were estimated to be smaller than 60 pN. A model for the elastic contributions of the glycocalix to the tip/membrane interaction was developed using the theory of grafted polymers.     

Kinetics of induction of error-prone repair of bacteriophage lambda by temperature shift in an Escherichia coli dnaB mutant.

Summary Preincubation at 42^o, before infection at permissive temperature by phage , of an Escherichia coli dnaB mutant, provokes a significant increase in survival and mutagenesis of ultraviolet irradiated phage as well as mutagenesis of untreated phage. Similarly to UV irradiation and many chemical mutagens, the inhibition of DNA synthesis by temperature shift of this dnaB mutant induces SOS repair. This work shows that replication blockage in bacterial DNA is not only mutagenic for bacterial DNA itself (Witkin, 1975) but also for normally replicating DNA, probably due to induction of diffusible products.     

Two-dimensional recognition pattern of lipid-anchored Fab'' fragments.

A two-dimensional pattern of oriented antibody fragments was formed at the air-water interface and transferred onto a solid support. The Fab'-fragments of a monoclonal antibody against the hapten dinitrophenyl (DNP) were covalently linked via a hydrophilic spacer to phospholipid vesicles. A monomolecular lipid-protein layer at equilibrium with these vesicles was allowed to form at the air-water interface. The monolayer was separated from the vesicle phase and transferred to a Langmuir-Blodgett trough. By cooling and compressing, the previously homogeneous lipid-protein film was driven into a two-dimensional phase separation resulting in protein-rich domains and a second phase consisting mainly of lipid. This film was transferred onto a solid support in a way that preserved the protein-lipid pattern. The specificity as well as the contrast in the binding activity of the two different separated phases were then quantified using microfluorometry. DNP conjugated to fluorescein-labeled bovine serum albumin (BSA) showed virtually no binding to the lipid regions, but gave a ratio of bound DNP-BSA to Fab'-lipid of greater than 50% in the protein-rich domains proving that the Fab'-moiety retained its biological activity. This demonstrates that the technique presented here is well suited to modify different solid surfaces with a pattern of a given biological function. The optional control of lateral packing and orientation of the components in the monolayer makes it a general tool for the reconstitution of supported lipid-protein membranes and might also open new ways for the two-dimensional crystallization of proteins at membranes.     

Influence of Vectors’ Risk-Spreading Strategies and Environmental Stochasticity on the Epidemiology and Evolution of Vector-Borne Diseases: The Example of Chagas’ Disease

Insects are known to display strategies that spread the risk of encountering unfavorable conditions, thereby decreasing the extinction probability of genetic lineages in unpredictable environments. To what extent these strategies influence the epidemiology and evolution of vector-borne diseases in stochastic environments is largely unknown. In triatomines, the vectors of the parasite Trypanosoma cruzi, the etiological agent of Chagas’ disease, juvenile development time varies between individuals and such variation most likely decreases the extinction risk of vector populations in stochastic environments. We developed a simplified multi-stage vector-borne SI epidemiological model to investigate how vector risk-spreading strategies and environmental stochasticity influence the prevalence and evolution of a parasite. This model is based on available knowledge on triatomine biodemography, but its conceptual outcomes apply, to a certain extent, to other vector-borne diseases. Model comparisons between deterministic and stochastic settings led to the conclusion that environmental stochasticity, vector risk-spreading strategies (in particular an increase in the length and variability of development time) and their interaction have drastic consequences on vector population dynamics, disease prevalence, and the relative short-term evolution of parasite virulence. Our work shows that stochastic environments and associated risk-spreading strategies can increase the prevalence of vector-borne diseases and favor the invasion of more virulent parasite strains on relatively short evolutionary timescales. This study raises new questions and challenges in a context of increasingly unpredictable environmental variations as a result of global climate change and human interventions such as habitat destruction or vector control.