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1. Gene family rearrangements and transcriptional priming drive the evolution of vegetative desiccation tolerance in Selaginella

   https://doi.org/10.1111/tpj.17169  

   Alejo‐Jacuinde, Gerardo; Chávez_Montes, Ricardo_A; Gutierrez_Reyes, Cristian_D; Yong‐Villalobos, Lenin; Simpson, June; Herrera‐Estrella, Luis (December 2024, The Plant Journal)

   SUMMARY Extreme dryness is lethal for nearly all plants, excluding the so‐called resurrection plants, which evolved vegetative desiccation tolerance (VDT) by recruiting genes common in most plants. To better understand the evolution of VDT, we generated chromosome‐level assemblies and improved genome annotations of twoSelaginellaspecies with contrasting abilities to survive desiccation. We identified genomic features and critical mechanisms associated with VDT through sister‐group comparative genomics integrating multi‐omics data. Our findings indicate thatSelaginellaevolved VDT through the expansion of some stress protection‐related gene families and the contraction of senescence‐related genes. Comparative analyses revealed that desiccation‐tolerantSelaginellaspecies employ a combination of constitutive and inducible protection mechanisms to survive desiccation. We show that transcriptional priming of stress tolerance‐related genes and accumulation of flavonoids in unstressed plants are hallmarks of VDT inSelaginella. During water loss, the resurrectionSelaginellainduces phospholipids and glutathione metabolism, responses that are missing in the desiccation‐sensitive species. Additionally, gene regulatory network analyses indicate the suppression of growth processes as a major component of VDT. This study presents novel perspectives on how gene dosage impacts crucial protective mechanisms and the regulation of central processes to survive extreme dehydration. 

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2. Natural and engineered mediators of desiccation tolerance stabilize Human Blood Clotting Factor VIII in a dry state

   https://doi.org/10.1038/s41598-023-31586-9  

   Packebush, Maxwell H.; Sanchez-Martinez, Silvia; Biswas, Sourav; KC, Shraddha; Nguyen, Kenny H.; Ramirez, John F.; Nicholson, Vincent; Boothby, Thomas C. (December 2023, Scientific Reports)

   Abstract Biologics, pharmaceuticals containing or derived from living organisms, such as vaccines, antibodies, stem cells, blood, and blood products are a cornerstone of modern medicine. However, nearly all biologics have a major deficiency: they are inherently unstable, requiring storage under constant cold conditions. The so-called ‘cold-chain’, while effective, represents a serious economic and logistical hurdle for deploying biologics in remote, underdeveloped, or austere settings where access to cold-chain infrastructure ranging from refrigerators and freezers to stable electricity is limited. To address this issue, we explore the possibility of using anhydrobiosis, the ability of organisms such as tardigrades to enter a reversible state of suspended animation brought on by extreme drying, as a jumping off point in the development of dry storage technology that would allow biologics to be kept in a desiccated state under not only ambient but elevated temperatures. Here we examine the ability of different protein and sugar-based mediators of anhydrobiosis derived from tardigrades and other anhydrobiotic organisms to stabilize Human Blood Clotting Factor VIII under repeated dehydration/rehydration cycles, thermal stress, and long-term dry storage conditions. We find that while both protein and sugar-based protectants can stabilize the biologic pharmaceutical Human Blood Clotting Factor VIII under all these conditions, protein-based mediators offer more accessible avenues for engineering and thus tuning of protective function. Using classic protein engineering approaches, we fine tune the biophysical properties of a protein-based mediator of anhydrobiosis derived from a tardigrade, CAHS D. Modulating the ability of CAHS D to form hydrogels make the protein better or worse at providing protection to Human Blood Clotting Factor VIII under different conditions. This study demonstrates the effectiveness of tardigrade CAHS proteins and other mediators of desiccation tolerance at preserving the function of a biologic without the need for the cold-chain. In addition, our study demonstrates that engineering approaches can tune natural products to serve specific protective functions, such as coping with desiccation cycling versus thermal stress. Ultimately, these findings provide a proof of principle that our reliance on the cold-chain to stabilize life-saving pharmaceuticals can be broken using natural and engineered mediators of desiccation tolerance. 

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3. Regulatory dynamics distinguishing desiccation tolerance strategies within resurrection grasses

   https://doi.org/10.1002/pld3.457  

   St. Aubin, Brian; Wai, Ching Man; Kenchanmane Raju, Sunil K.; Niederhuth, Chad E.; VanBuren, Robert (December 2022, Plant Direct)

   Abstract Desiccation tolerance has evolved recurrently in grasses using two unique strategies of either protecting or dismantling the photosynthetic apparatus to minimize photooxidative damage under life without water (anhydrobiosis). Here, we surveyed chromatin architecture and gene expression during desiccation in two closely related grasses with distinguishing desiccation tolerance strategies to identify regulatory dynamics underlying these unique adaptations. In both grasses, we observed a strong association between nearby chromatin accessibility and gene expression in desiccated tissues compared to well‐watered, reflecting an unusual chromatin stability under anhydrobiosis. Integration of chromatin accessibility (ATACseq) and expression data (RNAseq) revealed a core desiccation response across these two grasses. This includes many genes with binding sites for the core seed development transcription factor ABI5, supporting the long‐standing hypothesis that vegetative desiccation tolerance evolved from rewiring seed pathways.Oropetium thomaeumhas a unique set of desiccation induced genes and regulatory elements associated with photoprotection, pigment biosynthesis, and response to high light, reflecting its adaptation of protecting the photosynthetic apparatus under desiccation (homoiochlorophyly). By contrast,Eragrostis nindensishas unique accessible and expressed genes related to chlorophyll catabolism, scavenging of amino acids, and hypoxia, highlighting its poikilochlorophyllous adaptations of dismantling the photosynthetic apparatus and degrading chlorophyll under desiccation. Together, our results highlight the complex regulatory and expression dynamics underlying desiccation tolerance in grasses. 

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4. Helicity of a tardigrade disordered protein contributes to its protective function during desiccation

   https://doi.org/10.1002/pro.4872  

   Biswas, Sourav; Gollub, Edith; Yu, Feng; Ginell, Garrett; Holehouse, Alex; Sukenik, Shahar; Boothby, Thomas C. (January 2024, Protein Science)

   Abstract To survive extreme drying (anhydrobiosis), many organisms, spanning every kingdom of life, accumulate intrinsically disordered proteins (IDPs). For decades, the ability of anhydrobiosis‐related IDPs to form transient amphipathic helices has been suggested to be important for promoting desiccation tolerance. However, evidence empirically supporting the necessity and/or sufficiency of helicity in mediating anhydrobiosis is lacking. Here, we demonstrate that the linker region of CAHS D, a desiccation‐related IDP from the tardigradeHypsibius exemplaris, that contains significant helical structure, is the protective portion of this protein. Perturbing the sequence composition and grammar of the linker region of CAHS D, through the insertion of helix‐breaking prolines, modulating the identity of charged residues, or replacement of hydrophobic amino acids with serine or glycine residues results in variants with different degrees of helical structure. Importantly, correlation of protective capacity and helical content in variants generated through different helix perturbing modalities does not show as strong a trend, suggesting that while helicity is important, it is not the only property that makes a protein protective during desiccation. These results provide direct evidence for the decades‐old theory that helicity of desiccation‐related IDPs is linked to their anhydrobiotic capacity. 

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5. Tardigrade small heat shock proteins can limit desiccation-induced protein aggregation

   https://doi.org/10.1038/s42003-023-04512-y  

   Hibshman, Jonathan D.; Carra, Serena; Goldstein, Bob (January 2023, Communications Biology)

   Abstract Small heat shock proteins (sHSPs) are chaperones with well-characterized roles in heat stress, but potential roles for sHSPs in desiccation tolerance have not been as thoroughly explored. We identified nine sHSPs from the tardigradeHypsibius exemplaris, each containing a conserved alpha-crystallin domain flanked by disordered regions. Many of these sHSPs are highly expressed. Multiple tardigrade and human sHSPs could improve desiccation tolerance ofE. coli, suggesting that the capacity to contribute to desicco-protection is a conserved property of some sHSPs. Purification and subsequent analysis of two tardigrade sHSPs, HSP21 and HSP24.6, revealed that these proteins can oligomerize in vitro. These proteins limited heat-induced aggregation of the model enzyme citrate synthase. Heterologous expression of HSP24.6 improved bacterial heat shock survival, and the protein significantly reduced heat-induced aggregation of soluble bacterial protein. Thus, HSP24.6 likely chaperones against protein aggregation to promote heat tolerance. Furthermore, HSP21 and HSP24.6 limited desiccation-induced aggregation and loss of function of citrate synthase. This suggests a mechanism by which tardigrade sHSPs promote desiccation tolerance, by limiting desiccation-induced protein aggregation, thereby maintaining proteostasis and supporting survival. These results suggest that sHSPs provide a mechanism of general stress resistance that can also be deployed to support survival during anhydrobiosis. 

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