Gut microbiome dysbiosis and honeybee health

Since a few decades, apiculture is facing important economic losses worldwide with general major consequences in many areas of agriculture. A strong attention has been paid towards the phenomenon named Colony Collapse Disorder in which colonies suddenly disappear with no clear explanations. Honeybee colonies can be affected by abiotic factors, such as environmental pollution or insecticide applications for agricultural purposes. Also biotic stresses cause colony losses, including bacterial (e.g. Paenibacillus larvae) and fungal (e.g. Ascosphaera apis) pathogens, microsporidia (e.g. Nosema apis), parasites (i.e. Varroa destructor) and several viruses. In the light of recent research, intestinal dysbiosis, considered as the relative disproportion of the species within the native microbiota, has shown to affect human and animal health. In arthropods, alteration of the gut microbial climax community has been shown to be linked to health and fitness disequilibrium, like in the medfly Ceratitis capitata for which low mate competitiveness is determined by a gut microbial community imbalance. According to these observations, it is possible to hypothesize that dysbiosis may have a role in disease occurrence also in honeybees. Here we aim to discuss the current knowledge on dysbiosis in the honeybee and its relation with honeybee health by reviewing the investigations of the microbial diversity associated to honeybees and the recent experiments performed to control bee diseases by microbial symbionts. We conclude that, despite the importance of a good functionality of the associated microbiota in preserving insect health has been proved, the mechanisms involved in honeybee gut dysbiosis are still unknown. Accurate in vitro, in vivo and in field investigations are required under healthy, diseased and stressed conditions for the host.     

Analysis of Conserved Glutamate and Aspartate Residues in Drosophila Rhodopsin 1 and Their Influence on Spectral Tuning

The molecular mechanisms that regulate invertebrate visual pigment absorption are poorly understood. Studies of amphioxus G_o-opsin have demonstrated that Glu-181 functions as the counterion in this pigment. This finding has led to the proposal that Glu-181 may function as the counterion in other invertebrate visual pigments as well. Here we describe a series of mutagenesis experiments to test this hypothesis and to also test whether other conserved acidic amino acids in Drosophila Rhodopsin 1 (Rh1) may serve as the counterion of this visual pigment. Of the 5 Glu and Asp residues replaced by Gln or Asn in our experiments, none of the mutant pigments shift the absorption of Rh1 by more than 6 nm. In combination with prior studies, these results suggest that the counterion in Drosophila Rh1 may not be located at Glu-181 as in amphioxus, or at Glu-113 as in bovine rhodopsin. Conversely, the extremely low steady state levels of the E194Q mutant pigment (bovine opsin site Glu-181), and the rhabdomere degeneration observed in flies expressing this mutant demonstrate that a negatively charged residueat this position is essential for normal rhodopsin function in vivo. This work also raises the possibility that another residue or physiologic anion may compensate for the missing counterion in the E194Q mutant.     

The Green-absorbing Drosophila Rh6 Visual Pigment Contains a Blue-shifting Amino Acid Substitution That Is Conserved in Vertebrates

The molecular mechanisms that regulate invertebrate visual pigment absorption are poorly understood. Through sequence analysis and functional investigation of vertebrate visual pigments, numerous amino acid substitutions important for this adaptive process have been identified. Here we describe a serine/alanine (S/A) substitution in long wavelength-absorbing Drosophila visual pigments that occurs at a site corresponding to Ala-292 in bovine rhodopsin. This S/A substitution accounts for a 10–17-nm absorption shift in visual pigments of this class. Additionally, we demonstrate that substitution of a cysteine at the same site, as occurs in the blue-absorbing Rh5 pigment, accounts for a 4-nm shift. Substitutions at this site are the first spectrally significant amino acid changes to be identified for invertebrate pigments sensitive to visible light and are the first evidence of a conserved tuning mechanism in vertebrate and invertebrate pigments of this class.Organisms use color vision for survival behaviors such as foraging, mating, and predator avoidance (1–3). Color vision in invertebrates ranges from trichromatic systems capable of detecting UV, blue, and green (e.g. bees and flies) to the highly complex mantis shrimps (stomatopods) having 12 spectrally distinct classes of photoreceptor cells (4). Despite the diversity of invertebrate color vision systems and the large collection of naturally occurring visual pigments, important questions remain concerning the molecular mechanisms that regulate color sensitivity.In both vertebrates and invertebrates, the visual pigment rhodopsin consists of a chromophore (e.g. 11-cis retinal) covalently bound to an opsin apoprotein via a protonated Schiff base. Upon light absorption, the chromophore isomerizes from cis to all-trans, inducing conformational changes in the opsin that produce activated metarhodopsin. Specific interactions between the retinal chromophore and residues in the opsin tune the λ_max of the chromophore. Studies have shown that Glu-113 (bovine position) serves as the retinylidene Schiff base counter-ion in vertebrate visual pigments (5–7). Removing the negative charge of the counter-ion from the binding pocket deprotonates the chromophore and yields a UV-absorbing pigment (5–7). Using sequence alignments, phylogenetic analysis, analysis of the bovine rhodopsin crystal structure (PDB² entry 1U19), and functional experiments, a large number of amino acids involved in the spectral tuning of vertebrate visual pigments have been identified (8).In contrast, the counter-ion for invertebrate rhodopsin remains unknown, and only one spectrally relevant residue has been identified: an amino acid substitution in Drosophila pigments responsible for UV versus visible sensitivity (9). Interestingly, this amino acid substitution (Gly-90 in bovine rhodopsin) coincides with a substitution that mediates UV versus blue sensitivity in several bird species (10, 11). This discovery highlights the value of a cross-phyla comparison of visual pigments as a means to identify structural differences that may regulate color vision in invertebrates.In the present study, we identify an amino acid substitution in Drosophila visual pigments that regulates the color sensitivity of blue- and green-absorbing rhodopsins. For these studies, we employed sequence analysis of invertebrate and vertebrate visual pigments and a functional examination of mutant invertebrate opsins. This amino acid substitution red-shifts the λ_max of the Drosophila Rh1 pigment and reciprocally blue-shifts the λ_max of Rh6 pigment. Interestingly, this site also affects the spectral tuning of vertebrate pigments and corresponds to Ala-292 in bovine rhodopsin (8, 12–16).     

Population structure and Mdh-1 locus variation in Apis mellifera ligustica

In a wide area of the Piedmont of Italy the apiaries of Apis mellifera ligustica Spin., (the Italian bee) show homogeneous allelic frequency distributions at the Mdh-1 locus, the only one known to be polymorphic in worker bees. This can be explained by considering that an apiary is not a closed genetic system and that among apiaries gene flow is sufficient to overcome the different forces of inbreeding and random genetic drift. Nevertheless there is some evidence for partial subdivision because the pooled samples show a weak Wahlund effect. Moreover, the M allele at the same locus can be used as a diagnostic marker to distinguish A. m. ligustica populations (M absent or at very low frequencies) from A. m. mellifera French populations (monomorphic for M). The two honey-bee varieties, almost entirely separated by the Alps, hybridize with each other in very limited alpine areas. Hybrid populations show intermediate M frequencies.