Agriculture, together with aquaculture, supplies most of the foodstuffs required by the world human population to survive. Hence, bacterial diseases affecting either agricultural crops, fish, or shellfish not only cause large economic losses to producers but can even create food shortages, resulting in malnutrition, or even famine, in vulnerable populations. Years of antibiotic use in the prevention and the treatment of these infections have greatly contributed to the emergence and the proliferation of multidrug-resistant bacteria. This review addresses the urgent need for alternative strategies for the use of antibiotics, focusing on the use of bacteriophages (phages) as biocontrol agents. Phages are viruses that specifically infect bacteria; they are highly host-specific and represent an environmentally-friendly alternative to antibiotics to control and kill pathogenic bacteria. The information evaluated here highlights the effectiveness of phages in the control of numerous major pathogens that affect both agriculture and aquaculture, with special emphasis on scientific and technological aspects still requiring further development to establish phagotherapy as a real universal alternative to antibiotic treatment.
The identification and characterization of meningococcal outer membrane vesicle complexes can be important for gaining an in-depth understaining of their structure and functionality. Analysis of the vesicle complexome by 'traditional' 2-D analysis, in which isoelectrofocusing is used for separation in the first dimension, is hampered by the high hydrophobicity and extreme isoelectric points of many relevant proteins. Analysis of the meningococcal outer membrane vesicle complexome using Blue Native (nondenaturing) electrophoresis instead of isoelectrofocusing in the first dimension showed several porin complexes, but their composition could not be clearly resolved after separation by SDS-PAGE in the second dimension. In this work, using a recently described native separation technique -high resolution Clear Native Electrophoresis-and different bidimensional approaches, we were able to demonstrate the presence of relevant outer membrane complexes which could be resolved with a higher resolution than in previous analysis. The most relevant were nine porin complexes formed by different combinations of the meningococcal PorA, PorB and RmpM proteins, and comparison with the complexes formed in specific knockout mutants allowed us to infer the relevance of each porin in the formation of each complex.
The structure of the porin complexes of Neisseria meningitidis was assessed in the vaccine strain H44/76 and its homologous mutants lacking the main porins (PorA and PorB) and other outer membrane (OM) components (RmpM and FetA). The analysis using 1-D blue native (BN) electrophoresis, 2-D BN/SDS-PAGE and 2-D diagonal electrophoresis, followed by LC/MS-MS (for 1-D gels) or MALDI-TOF (for 2-D gels) revealed at least six porin complexes in the wild-type strain with molecular masses (MW) ranging from 145 to 195 kDa and variable composition: The two higher MW complexes are formed by PorA, PorB and RmpM, the following three are formed by PorA and PorB, and the lower MW one is formed by only PorB. Complexes in the mutants lacking either PorA, PorB or RmpM, but not those in the mutant lacking FetA, were alterered respect to those in the wild-type strain. The most evident alteration was seen in the mutant lacking PorB, in which PorA formed only a high MW complex (approximately 800 kDa). Our results suggest that PorA and PorB could form a 'basic' template for the transportation systems in the OM of the meningococci. Other proteins (such as RmpM) could be transiently associated to the porin complexes, depending on the specific tranport needs at different stages of the meningococcal life cycle, resulting in a dynamic net of pores of variable composition.
Bacterial swimming in confined two-dimensional environments is ubiquitous in nature and in clinical settings. Characterizing individual interactions between swimming bacteria in 2D confinement will help to understand diverse microbial processes, such as bacterial swarming and biofilm formation. Here we report a novel form of biophysical interaction between flagellated bacteria in 2D confinement: When two nearby cells align their moving directions, they tend to engage in cohesive swimming without direct cell body contact, as a result of hydrodynamic interaction but not flagellar intertwining. We further found that cells in cohesive swimming move with higher directional persistence, which can increase the effective diffusivity of cells by ~3 times as predicted by computational modeling. As a conserved behavior for peritrichously flagellated bacteria, cohesive swimming in 2D confinement may be key to collective motion and self-organization in bacterial swarms; it may also promote bacterial dispersal in unsaturated soils and in interstitial space during infections.
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