Halictine 1

Antimicrobial peptides are innate host defense molecules with the ability to kill pathogens. They have been widely studied for their membrane lytic activity and their potential to overcome the ever-increasing threat of antimicrobial resistance against conventional antibiotics. Here, we focus on two halictines, antimicrobial peptides first obtained from the venom of the eusocial bee Halictus sexcinctus. The peptides, HAL-1 and HAL-2, are cationic (with +3 and +4 charges, respectively) and amphipathic, have 12 amino acid residues, and exhibit high biological activity. For this study, the mechanism of action of HAL-1 and HAL-2 was studied in detail using large and giant unilamellar vesicles composed of pure palmitoyl oleoyl phosphatidyl choline (POPC) and a mixture of POPC and the anionic lipid palmitoyl oleoyl phosphatidyl glycerol (POPG) as biomimetic models of the membranes of eukaryotes and microorganisms, respectively. A set of complementary techniques was put forward: carboxyfluorescein leakage assay, phase contrast optical microscopy, ζ-potential, static and dynamic light scattering, fluorescence and circular dichroism spectroscopies, and isothermal titration calorimetry. The results show that both halictines are able to interact strongly with anionic membranes: The interaction is exothermic and accompanied by structuring of the peptides as an α-helix and deep insertion into the membrane causing substantial membrane permeabilization at very low peptide/lipid molar ratios. Extensive vesicle aggregation was detected only at a high peptide concentration. On the other hand, the interaction of the halictines with POPC is significantly milder. Yet, the peptides were able to permeabilize the POPC membranes to some extent. Comparing both peptides, HAL-1 showed a somewhat stronger effect on model membranes. Fits to the data revealed apparent binding constants on the order of 103-104 M-1 for anionic membranes and 1 order of magnitude lower for zwitterionic bilayers. When lytic activity results were compared at the same bound peptide/lipid ratio, the halictines exhibited a higher activity toward zwitterionic membranes. As novel peptides, small and with powerful activity, these halictines are potential candidates for becoming antimicrobial agents.

The halictid bees are excellent models for the study of social evolution because greater social diversity and plasticity are observed in the tribe Halictini than in any other comparable taxonomic group. We examine the evolutionary relationships within the subfamily Halictinae ("sweat bees") to investigate the origins of social behaviour within the tribe Halictini. We present a new phylogeny of the subfamily Halictinae based on three nuclear genes (elongation factor-1 alpha, wingless, and long-wavelength rhodopsin) and one mitochondrial gene (cytochrome c oxidase 1) sequenced for 206 halictine bees. We use model-based character reconstruction to infer the probability of a shared eusocial ancestor for the genera Halictus and Lasioglossum, the two genera of Halictini which display eusociality. Our results suggest a high probability for a single origin of eusociality for these two genera, contradicting earlier views of separate origins within each taxon. Fossil-calibrated divergence estimates place this ancestor at approximately 35 million years ago, about 14 million years earlier than previous estimates of eusocial origins in the halictid bees.

We have investigated structural changes of peptides related to antimicrobial peptide Halictine-1 (HAL-1) induced by interaction with various membrane-mimicking models with the aim to identify a mechanism of the peptide mode of action and to find a correlation between changes of primary/secondary structure and biological activity. Modifications in the HAL-1 amino acid sequence at particular positions, causing an increase of amphipathicity (Arg/Lys exchange), restricted mobility (insertion of Pro) and consequent changes in antimicrobial and hemolytic activity, led to different behavior towards model membranes. Secondary structure changes induced by peptide-membrane interaction were studied by circular dichroism, infrared spectroscopy, and fluorescence spectroscopy. The experimental results were complemented by molecular dynamics calculations. An α-helical structure has been found to be necessary but not completely sufficient for the HAL-1 peptides antimicrobial action. The role of alternative conformations (such as β-sheet, PPII or 310-helix) also seems to be important. A mechanism of the peptide mode of action probably involves formation of peptide assemblies (possibly membrane pores), which disrupt bacterial membrane and, consequently, allow membrane penetration.