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1. Sampling a pika's pantry: Temporal shifts in nutritional quality and winter preservation of American pika food caches

   https://doi.org/10.1002/ecs2.4494  

   Varner, Johanna; Carnes‐Douglas, Zoe J.; Monk, Emily; Benedict, Lauren M.; Whipple, Ashley; Dearing, M. Denise; Bhattacharyya, Sabuj; Griswold, Loren; Ray, Chris (May 2023, Ecosphere)

   Abstract Climate change is increasing temperature, decreasing precipitation, and increasing atmospheric CO₂concentrations in many ecosystems. As atmospheric carbon rises, plants may increase carbon‐based defenses, such as phenolics, thereby potentially affecting food quality, foraging habits, and habitat suitability for mammalian herbivores. In alpine habitats, the American pika (Ochotona princeps) is a model species for studying effects of changing plant chemistry on mammals. To survive between growing seasons, pikas cache “haypiles” of plants rich in phenolics. Although they are toxic to pikas, phenolic compounds facilitate retention of plant biomass and nutrition during storage, and they degrade over time. Alpine avens (Geum rossii, Rosales: Rosaceae) is a high‐phenolic plant species that comprises up to 75% of pika haypiles in Colorado. Here, we tested the hypothesis that contemporary climate change has affected the nutritional value of alpine avens to pikas in the last 30 years. Specifically, we compared phenolic activity, nutritional quality, and overwinter preservation of plants collected at Niwot Ridge, Colorado (USA), in 1992 to those collected between 2010 and 2018, spanning nearly three decades of climate change. Phenolic activity increased in alpine avens since 1992, while fiber and nitrogen content decreased. Importantly, overwinter preservation of plant biomass also increased, particularly on windblown slopes without long‐lasting snow cover. Previous studies indicate that pikas at this site still depend on alpine avens for their winter food caches. Higher phenolic content in alpine avens could therefore enhance the preservation of haypiles over winter; however, if pikas must further delay consuming these plants to avoid toxicity or invest extra energy in detoxification, then the nutritional gains from enhanced preservation may not be beneficial. This study provides important insights into how climate‐driven changes in plant chemistry will affect mammalian herbivores in the future. 

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2. Are You a HAB Warrior?

   https://doi.org/10.3389/frym.2021.611282  

   Lehman, Peggy W.; Kurobe, Tomofumi; Otten, Timothy G.; Peacock, Melissa B. (August 2021, Frontiers for Young Minds)

   Microalgae and cyanobacteria are tiny, microscopic plant-like organisms that float in the water and grow using nutrients from the water, energy from the sun and carbon dioxide gas from the air. Most microalgae and cyanobacteria are helpful because, like grass for cows on land, they provide food for aquatic animals. However, some microalgae and cyanobacteria are poisonous and when large numbers of them occur, they are called harmful algal blooms, or HABs for short. HABs can poison both humans and animals through the food they eat, the water they drink, and even the air they breathe. HABs are increasing within lakes, rivers, oceans, and estuaries worldwide because of pollution and climate change. This article will tell you about HABs in San Francisco Estuary, USA: who they are, what they look like, why they occur, how they affect plants, animals and people, and things you can do as a HAB warrior to stay safe and prevent their spread. 

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3. Creating New Types of Plants—The Art of Plant Breeding

   https://doi.org/10.3389/frym.2024.1307600  

   Stewart, Victoria; Nganga, Mwaura Livingstone; Henry, Isabelle M; Comai, Luca (September 2024, Frontiers for Young Minds)

   We eat or interact with crops every day for food (tomatoes, lettuce, apples, rice, etc.), for feeding animals (hay, corn), or for a wide variety of other uses (wood, cotton). All crops come from wild plants that do not look anything like the ones we buy at the store. That is because they have been selected to look and behave in very specific ways that fit the needs of farmers, sellers, and us—the consumers. The process of developing new varieties is called breeding. Plant breeding is a complicated and lengthy process. Why do we need to breed plants? Because climate and environmental conditions are changing quickly and breeding new varieties that can survive in these new conditions or meet new needs is even more critical than before. In this article, we explain why breeding takes so long, and we discuss recent scientific findings that might help speed up the process. 

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4. The Weird and Wonderful World of Worms

   https://doi.org/10.3389/frym.2022.902248  

   Gadeken, Kara J.; Kiskaddon, Erin; Moore, Jenna M.; Dorgan, Kelly M. (November 2022, Frontiers for Young Minds)

   Animals with long, skinny bodies are often called “worms,” but there are many kinds of worms—even in the ocean. Annelids (segmented worms) include garden earthworms, but their ocean relatives come in many colors, shapes, and sizes. Some are so small that they live between grains of sand, while others can be longer than a human and eat fish! Marine worms are essential to the ocean food web, as both predators and prey. They help create homes for plants and animals by burrowing and building tubes in ocean sediments. Scientists are still discovering new worm species, and there are still many mysteries about how worms eat, why they live in the places they do, and what roles they play in ocean ecosystems. Worms are a fascinating and important part of ocean communities. 

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5. Examining the performance of an insect generalist reared on unused host plants in Colorado

   Meyer, MJ; Dam, K; Hicks, KG; Sellers, EJ; Tanino_Springsteen, MM; Reigrut, JD; Vyas, DK; Murphy, SM (July 2025, University of Denver Undergraduate Research Journal)

   Doris, Nicole; Vahl, Cate; Kruger, Elijah (Ed.)

   Dietary generalist insects are important to ecological communities because they are commonly found in many environments and play important roles in ecosystem services like pollination and decomposition. Although dietary generalist herbivores eat a broad range of plant species, regional populations of these species may have significantly narrower or specialized diet breadths. Fall webworm (Hyphantria cunea, hereafter FW) is a dietary generalist at the species level, but we do not know if there is dietary generalism at the population level or how generalism varies across populations. In Colorado, FW larvae feed on only a few plant species, but many plant species are available that are used by FW elsewhere and not locally. We investigated if FW may be an example of a species that is a dietary generalist when considered over a large geographic range but is composed of populations with narrower diets regionally.We reared FW larvae from fifteen maternal lines in Colorado on a local high-quality host plant and compared their performance (survival, development time, and pupal mass) with larvae reared on plants that are not used locally. We found that FW performance was significantly reduced on plant species that Colorado FW does not use. Our findings demonstrate that Colorado FW cannot eat the same plants as FW in the eastern United States and thus lack the physiological ability to feed on these plants. Our research also suggests that FW are a generalist species with narrower diets that vary regionally at the population level. 

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