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1. Microbiome analysis of monarch butterflies reveals effects of development and diet

   https://doi.org/10.1093/femsec/fiae143  

   Sanaei, Ehsan; Chavez, Joselyne; Harris, Erica_V; Alcaide, Tiffanie_Y; Baffour-Addo, Keisha; Bugay, Mahal_J; Adams, Kandis L.; Zelaya, Anna; de Roode, Jacobus_C; Gerardo, Nicole_M (November 2024, FEMS Microbiology Ecology)

   Abstract Diet profoundly influences the composition of an animal’s microbiome, especially in holometabolous insects, offering a valuable model to explore the impact of diet on gut microbiome dynamics throughout metamorphosis. Here, we use monarch butterflies (Danaus plexippus), specialist herbivores that feed as larvae on many species of chemically well-defined milkweed plants (Asclepias sp.), to investigate the impacts of development and diet on the composition of the gut microbial community. While a few microbial taxa are conserved across life stages of monarchs, the microbiome appears to be highly dynamic throughout the life cycle. Microbial diversity gradually diminishes throughout the larval instars, ultimately reaching its lowest point during the pupal stage and then recovering again in the adult stage. The microbial composition then undergoes a substantial shift upon the transition from pupa to adult, with female adults having significantly different microbial communities than the eggs that they lay, indicating limited evidence for vertical transmission of gut microbiota. While diet did not significantly impact overall microbial composition, our results suggest that fourth instar larvae exhibit higher microbial diversity when consuming milkweed with high concentrations of toxic cardenolide phytochemicals. This study underscores how diet and developmental stage collectively shape the monarch’s gut microbiota. 

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2. Environmentally acquired gut-associated bacteria are not critical for growth and survival in a solitary bee, Megachile rotundata

   https://doi.org/10.1128/aem.02076-23  

   Brar, Gagandeep; Floden, Madison; McFrederick, Quinn; Rajamohan, Arun; Yocum, George; Bowsher, Julia (September 2024, Applied and Environmental Microbiology)

   Tortosa, Pablo (Ed.)

   ABSTRACT Social bees have been extensively studied for their gut microbial functions, but the significance of the gut microbiota in solitary bees remains less explored. Solitary bee,Megachile rotundatafemales provision their offspring with pollen from various plant species, harboring a diverse microbial community that colonizes larvae guts. TheApilactobacillusis the most abundant microbe, but evidence concerning the effects ofApilactobacillusand other provision microbes on growth and survival are lacking. We hypothesized that the presence ofApilactobacillusin abundance would enhance larval and prepupal development, weight, and survival, while the absence of intact microbial communities was expected to have a negative impact on bee fitness. We reared larvae on pollen provisions with naturally collected microbial communities (Natural pollen) or devoid of microbial communities (Sterile pollen). We also assessed the impact of introducingApilactobacillus micheneriby adding it to both types of pollen provisions. Feeding larvae with sterile pollen +A. micheneriled to the highest mortality rate, followed by natural pollen +A. micheneri, and sterile pollen. Larval development was significantly delayed in groups fed with sterile pollen. Interestingly, larval and prepupal weights did not significantly differ across treatments compared to natural pollen-fed larvae. 16S rRNA gene sequencing found a dominance ofSodalis, whenA. micheneriwas introduced to natural pollen. The presence ofSodaliswith abundantA. micheneri suggests potential crosstalk between both, shaping bee nutrition and health. Hence, this study highlights that the reliance on nonhost-specific environmental bacteria may not impact fitness ofM. rotundata.IMPORTANCEThis study investigates the impact of environmentally acquired gut microbes of solitary bee fitness with insights into the microbial ecology of bee and their health. While the symbiotic microbiome is well-studied in social bees, the role of environmental acquired microbiota in solitary bees remains unclear. Assessing this relationship in a solitary pollinator, the leaf-cutting bee,Megachile rotundata, we discovered that this bee species does not depend on the diverse environmental bacteria found in pollen for either its larval growth or survival. Surprisingly, high concentrations of the most abundant pollen bacteria, Apilactobacillus micheneridid not consistently benefit bee fitness, but caused larval mortality. Our findings also suggest an interaction betweenApilactobacillusand theSodalisand perhaps their role in bee nutrition. Hence, this study provides significant insights that contribute to understanding the fitness, conservation, and pollination ecology of other solitary bee species in the future. 

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3. Embryo, larval, and juvenile staging of Lytechinus pictus from fertilization through sexual maturation

   https://doi.org/10.1002/dvdy.223  

   Nesbit, Katherine_T; Hamdoun, Amro (August 2020, Developmental Dynamics)

   Abstract BackgroundSea urchin embryos have been used for more than a century in the study of fertilization and early development. However, several of the species used, such asStrongylocentrotus purpuratus, have long generation times making them suboptimal for transgenerational studies. ResultsHere, we present an overview of the development of a rapidly developing echinoderm species,Lytechinus pictus, from fertilization through sexual maturation. When grown at room temperature (20°C) embryos complete the first cell cycle in 90 minutes, followed by subsequent cleavages every 45 minutes, leading to hatching at 9 hours postfertilization (hpf). The swimming embryos gastrulate from 12 to 36 hpf and produce the cells which subsequently give rise to the larval skeleton and immunocytes. Larvae begin to feed at 2 days and metamorphose by 3 weeks. Juveniles reach sexual maturity at 4 to 6 months of age, depending on individual growth rate. ConclusionsThis staging scheme lays a foundation for future studies inL. pictus, which share many of the attractive features of other urchins but have the key advantage of rapid development to sexual maturation. This is significant for multigenerational and genetic studies newly enabled by CRISPR‐CAS mediated gene editing. 

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4. Drosophila Late Embryonic through Late Larval Stage Body Wall Dissection: Dissection Tools and Techniques

   https://doi.org/10.1101/pdb.prot108499  

   Ashley, James; Carrillo, Robert A (June 2024, Cold Spring Harbor Protocols)

   One of the challenges of studying synaptic structure and function is accessibility. Some of the earliest readily identifiable and accessible synapses were from the frog and various arthropods. To address questions regarding mechanisms that underlie synaptic development and function, genetically tractable systems were required, and researchers turned to theDrosophila melanogasterembryonic/larval neuromuscular preparation.Drosophilaembryos are transparent and can be labeled with antibodies or probes and imaged in whole-mount preparation for structural analysis. Embryos can also be dissected to visualize the entire body wall musculature as well as finer details including live protein trafficking and protein–protein interactions. Whereas younger dissected embryos can be mounted directly onto charged slides, more mature embryos and larvae develop a cuticle that impedes this adherence, so different techniques must be applied. In this protocol, we detail how to manufacture dissection tools and collect embryos, and discuss the individual steps of dissecting late-stage embryos, early first-instar larvae, and late-stage third-instar larvae. 

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5. Gut microbiota variation of a tropical oil-collecting bee species far exceeds that of the honeybee

   https://doi.org/10.3389/fmicb.2023.1122489  

   Kardas, Elif; González-Rosario, Angie M.; Giray, Tugrul; Ackerman, James D.; Godoy-Vitorino, Filipa (May 2023, Frontiers in Microbiology)

   Introduction Interest for bee microbiota has recently been rising, alleviating the gap in knowledge in regard to drivers of solitary bee gut microbiota. However, no study has addressed the microbial acquisition routes of tropical solitary bees. For both social and solitary bees, the gut microbiota has several essential roles such as food processing and immune responses. While social bees such as honeybees maintain a constant gut microbiota by direct transmission from individuals of the same hive, solitary bees do not have direct contact between generations. They thus acquire their gut microbiota from the environment and/or the provision of their brood cell. To establish the role of life history in structuring the gut microbiota of solitary bees, we characterized the gut microbiota of Centris decolorata from a beach population in Mayagüez, Puerto Rico. Females provide the initial brood cell provision for the larvae, while males patrol the nest without any contact with it. We hypothesized that this behavior influences their gut microbiota, and that the origin of larval microbiota is from brood cell provisions. Methods We collected samples from adult females and males of C. decolorata ( n  = 10 each, n  = 20), larvae ( n  = 4), and brood cell provisions ( n  = 10). For comparison purposes, we also sampled co-occurring female foragers of social Apis mellifera ( n  = 6). The samples were dissected, their DNA extracted, and gut microbiota sequenced using 16S rRNA genes. Pollen loads of A. mellifera and C. decolorata were analyzed and interactions between bee species and their plant resources were visualized using a pollination network. Results While we found the gut of A. mellifera contained the same phylotypes previously reported in the literature, we noted that the variability in the gut microbiota of solitary C. decolorata was significantly higher than that of social A. mellifera . Furthermore, the microbiota of adult C. decolorata mostly consisted of acetic acid bacteria whereas that of A. mellifera mostly had lactic acid bacteria. Among C. decolorata , we found significant differences in alpha and beta diversity between adults and their brood cell provisions (Shannon and Chao1 p  < 0.05), due to the higher abundance of families such as Rhizobiaceae and Chitinophagaceae in the brood cells, and of Acetobacteraceae in adults. In addition, the pollination network analysis indicated that A. mellifera had a stronger interaction with Byrsonima sp. and a weaker interaction with Combretaceae while interactions between C. decolorata and its plant resources were constant with the null model. Conclusion Our data are consistent with the hypothesis that behavioral differences in brood provisioning between solitary and social bees is a factor leading to relatively high variation in the microbiota of the solitary bee. 

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