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1. Host switching by an ambrosia beetle fungal mutualist: Mycangial colonization of indigenous beetles by the invasive laurel wilt fungal pathogen

   https://doi.org/10.1111/1462-2920.16401  

   Joseph, Ross; Bansal, Kamaldeep; Keyhani, Nemat_O (May 2023, Environmental Microbiology)

   Abstract Ambrosia beetles require their fungal symbiotic partner as their cultivated (farmed) food source in tree galleries. While most fungal‐beetle partners do not kill the host trees they inhabit, since their introduction (invasion) into the United states around ~2002, the invasive beetleXyleborus glabratushas vectored its mutualist partner (but plant pathogenic) fungus,Harringtonia lauricola, resulting in the deaths of over 300 million trees. Concerningly, indigenous beetles have been caught bearingH. lauricola. Here, we show colonization of the mycangia of the indigenousX. affinisambrosia beetle byH. lauricola. Mycangial colonization occurred within 1 h of feeding, with similar levels seen forH. lauricolaas found for the nativeX. affinis‐R. arxiifungal partner. Fungal mycangial occupancy was stable over time and after removal of the fungal source, but showed rapid turnover when additional fungal cells were available. Microscopic visualization revealed two pre‐oral mycangial pouches of ~100–200 × 25–50 μm/each, with narrow entry channels of 25–50 × 3–10 μm. Fungi within the mycangia underwent a dimorphic transition from filamentous/blastospore growth to yeast‐like budding with alterations to membrane structures. These data identify the characteristics of ambrosia beetle mycangial colonization, implicating turnover as a mechanism for host switching ofH. lauricolato other ambrosia beetle species. 

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2. The influence of lightning on insect and fungal dynamics in a lowland tropical forest

   https://doi.org/10.1002/ecy.4521  

   Lawhorn, Kane_A; Richards, Jeannine_H; Gora, Evan_M; Burchfield, Jeffrey_C; Bitzer, Phillip_M; Gutierrez, Cesar; Yanoviak, Stephen_P (January 2025, Ecology)

   Abstract Lightning strikes are a common source of disturbance in tropical forests, and a typical strike generates large quantities of dead wood. Lightning‐damaged trees are a consistent resource for tropical saproxylic (i.e., dead wood‐dependent) organisms, but patterns of consumer colonization and succession following lightning strikes are not known. Here, we documented the occurrence of four common consumer taxa spanning multiple trophic levels—beetles,Aztecaants, termites, and fungi—in lightning strike sites and nearby undamaged control sites over time in a lowland forest of Panama. Beetle abundance was 10 times higher in lightning strike sites than in paired control sites, and beetle assemblages were compositionally distinct. Those in strike sites were initially dominated by bark and ambrosia beetles (Curculionidae: Platypodinae, Scolytinae); bark and ambrosia beetles, and predaceous taxa increased in abundance relatively synchronously. Beetle activity and fungal fruiting bodies, respectively, were 3.8 and 12.2 times more likely to be observed in lightning‐damaged trees in strike sites versus undamaged trees in paired control sites, whereas the occurrence probabilities ofAztecaants and termites were similar between damaged trees in lightning strike sites and undamaged trees in control sites. Tree size also was important; larger dead trees in strike sites were more likely to support beetles, termites, and fungal fruiting bodies, and larger trees—regardless of mortality status—were more likely to hostAzteca. Beetle presence was associated with higher rates of subsequent fungal presence, providing some evidence of beetle‐associated priority effects on colonization patterns. These results suggest that lightning plays a key role in supporting tropical insect and fungal consumers by providing localized patches of suitable habitat. Any climate‐driven changes in lightning frequency in tropical forests will likely affect a broad suite of consumer organisms, potentially altering ecosystem‐level processes. 

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3. Laboratory Maintenance of the Chytrid Fungus Batrachochytrium dendrobatidis

   https://doi.org/10.1002/cpz1.309  

   Prostak, Sarah M.; Fritz‐Laylin, Lillian K. (December 2021, Current Protocols)

   Abstract The chytrid fungusBatrachochytrium dendrobatidis(Bd) is a causative agent of chytridiomycosis, a skin disease associated with amphibian population declines around the world. Despite the major impactBdis having on global ecosystems, much ofBd’s basic biology remains unstudied. In addition to revealing mechanisms driving the spread of chytridiomycosis, studyingBdcan shed light on the evolution of key fungal traits because chytrid fungi, includingBd, diverged before the radiation of the Dikaryotic fungi (multicellular fungi and yeast). StudyingBdin the laboratory is, therefore, of growing interest to a wide range of scientists, ranging from herpetologists and disease ecologists to molecular, cell, and evolutionary biologists. This protocol describes how to maintain developmentally synchronized liquid cultures ofBdfor use in the laboratory, how to growBdon solid media, as well as cryopreservation and revival of frozen stocks. © 2021 The Authors. Current Protocols published by Wiley Periodicals LLC. Basic Protocol 1: Reviving cryopreservedBdcultures Basic Protocol 2: Establishing synchronized liquid cultures ofBd Basic Protocol 3: Regular maintenance of synchronousBdin liquid culture Alternate Protocol 1: Regular maintenance of asynchronousBdin liquid culture Basic Protocol 4: Regular maintenance of synchronousBdon solid medium Alternate Protocol 2: Starting a culture on solid medium from a liquid culture Basic Protocol 5: Cryopreservation ofBd 

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4. Alcohol mediated degenerate chain transfer controlled cationic polymerisation of para -alkoxystyrene

   https://doi.org/10.1039/c9py00480g  

   Prasher, Alka; Hu, Huamin; Tanaka, Joji; Nicewicz, David A.; You, Wei (July 2019, Polymer Chemistry)

   In this report we demonstrate methanol as an effective degenerative chain transfer agent to control the cationic polymerisation (initiated by triflic acid) of electron rich p -alkoxy-styrenes, such as p -methoxystyrene ( p -MOS). Kinetic analysis revealed that an induction period occurs initially during which free cationic polymerisation occurs at low monomer conversion before proceeding through the pseudo first order rate, analogous to the RAFT mechanism. Ethanol and isopropanol also demonstrated excellent control ( Đ > 1.30), however, with an apparent increase in experimental molecular weight. Furthermore, methanol controlled polymers were successfully chain extended upon sequential monomer addition, demonstrating the ‘livingness’ of the alcohol mediated cationic polymerisation. 

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5. Ethanol exposure can inhibit red spruce ( Picea rubens ) seed germination

   https://doi.org/10.15258/sst.2018.46.2.07  

   Butnor, John R.; Verrico, Brittany M.; Vankus, Victor; Keller, Stephen R. (June 2018, Seed Science and Technology)

   Flotation of seeds in solvents is a common means of separating unfilled and filled seeds. While a few protocols for processing red spruce (Picea rubens) seeds recommend ethanol flotation, delayed and reduced germination have been reported. We conducted an ethanol bioassay on seeds previously stored at -20°C to quantify the concentration required to separate red spruce seeds and the effects on germination. We used seeds from Canada (CAN) that had been exposed to ethanol during processing, and seeds from the United States (USA) that had not been exposed to ethanol during processing. Seeds were exposed to 10 ethanol concentrations (10-100%) and deionised water was used as a control. The effective concentration of ethanol for 50% (EC50) of the seeds to sink ranged by source from 70.9 to 90.7%, with all seeds sinking in 100% ethanol. The use of less than 100% ethanol is not adequate for seed separation, as some filled seeds could float and be mistakenly categorised as unfilled. The mean EC50 of ethanol that inhibits germination was significantly higher for USA sources (52.7%), than for CAN sources (40.8%; P < 0.05). Ethanol concentrations that inhibited germination coincided with delays in germination. The mechanism of phytotoxity was not determined; however, damage during extraction, desiccation and storage at -20°C are potential sources. We recommend separating red spruce seeds by physical means rather than ethanol flotation to avoid potential negative impacts on germination. 

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