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1. Distribution and the evolutionary history of G-protein components in plant and algal lineages

   https://doi.org/10.1093/plphys/kiac153  

   Mohanasundaram, Boominathan; Dodds, Audrey; Kukshal, Vandna; Jez, Joseph M.; Pandey, Sona (April 2022, Plant Physiology)

   Abstract Heterotrimeric G-protein complexes comprising Gα-, Gβ-, and Gγ-subunits and the regulator of G-protein signaling (RGS) are conserved across most eukaryotic lineages. Signaling pathways mediated by these proteins influence overall growth, development, and physiology. In plants, this protein complex has been characterized primarily from angiosperms with the exception of spreading-leaved earth moss (Physcomitrium patens) and Chara braunii (charophytic algae). Even within angiosperms, specific G-protein components are missing in certain species, whereas unique plant-specific variants—the extra-large Gα (XLGα) and the cysteine-rich Gγ proteins—also exist. The distribution and evolutionary history of G-proteins and their function in nonangiosperm lineages remain mostly unknown. We explored this using the wealth of available sequence data spanning algae to angiosperms representing extant species that diverged approximately 1,500 million years ago, using BLAST, synteny analysis, and custom-built Hidden Markov Model profile searches. We show that a minimal set of components forming the XLGαβγ trimer exists in the entire land plant lineage, but their presence is sporadic in algae. Additionally, individual components have distinct evolutionary histories. The XLGα exhibits many lineage-specific gene duplications, whereas Gα and RGS show several instances of gene loss. Similarly, Gβ remained constant in both number and structure, but Gγ diverged before the emergence of land plants and underwent changes in protein domains, which led to three distinct subtypes. These results highlight the evolutionary oddities and summarize the phyletic patterns of this conserved signaling pathway in plants. They also provide a framework to formulate pertinent questions on plant G-protein signaling within an evolutionary context. 

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2. The nuclear lamina is required for proper development and nuclear shape distortion in tomato

   https://doi.org/10.1093/jxb/erad294  

   Blunt, Endia L.; Choi, Junsik; Sussman, Hayley; Christopherson, Rachel C.; Keen, Patricia; Rahmati Ishka, Maryam; Li, Linda Y.; Idrovo, Joanna M.; Julkowska, Magdalena M.; Van Eck, Joyce; et al (July 2023, Journal of Experimental Botany)

   Abstract The nuclear lamina in plant cells is composed of plant-specific proteins, including nuclear matrix constituent proteins (NMCPs), which have been postulated to be functional analogs of lamin proteins that provide structural integrity to the organelle and help stabilize the three-dimensional organization of the genome. Using genomic editing, we generated alleles for the three genes encoding NMCPs in cultivated tomato (Solanum lycopersicum) to determine if the consequences of perturbing the nuclear lamina in this crop species were similar to or distinct from those observed in the model Arabidopsis thaliana. Loss of the sole NMCP2-class protein was lethal in tomato but is tolerated in Arabidopsis. Moreover, depletion of NMCP1-type nuclear lamina proteins leads to distinct developmental phenotypes in tomato, including leaf morphology defects and reduced root growth rate (in nmcp1b mutants), compared with cognate mutants in Arabidopsis. These findings suggest that the nuclear lamina interfaces with different developmental and signaling pathways in tomato compared with Arabidopsis. At the subcellular level, however, tomato nmcp mutants resembled their Arabidopsis counterparts in displaying smaller and more spherical nuclei in differentiated cells. This result argues that the plant nuclear lamina facilitates nuclear shape distortion in response to forces exerted on the organelle within the cell. 

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3. Long non-coding RNA hsr-omega provides scaffolding for the nuclear domain B-body

   An, SooBin; Haque, Sharar; Adams, Miranda; Torres, Luis E; Kiani, Kaveh; Bryantsev, Anton L (May 2025, bioRxiv)

   Nuclear domains (NDs)—such as nucleoli or nuclear speckles—are membraneless, organelle-like compartments that concentrate and retain nuclear proteins. Despite their ubiquitous presence in the cell, the organization, regulation, and functions of many NDs remain poorly understood. The B-body is a prominent nuclear domain observed in developing flight muscles of Drosophila. In this study, we expand the understanding of B-body composition and function. We identify several additional RNA-binding proteins (RBPs) as B-body components and show that some proteins can dynamically disappear from this ND. We further demonstrate that the B-body contains an RNA component, which was identified as the long non-coding RNA hsrω. Genetic analyses reveal that hsrω acts as a structural scaffold for the B-body, and its depletion leads to B-body disassembly. In contrast, loss of the resident protein Bruno (Bru), a splicing factor, does not compromise B-body integrity. Finally, we show that imbalance in the hsrω/Bru ratio promotes Bru aggregation, suggesting that the B-body plays a role in maintaining nuclear protein homeostasis. 

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4. Deep mutational scanning of the RNase III-like domain in Trypanosoma brucei RNA editing protein KREPB4

   https://doi.org/10.3389/fcimb.2024.1381155  

   McDermott, Suzanne M; Pham, Vy; Oliver, Brian; Carnes, Jason; Sather, D Noah; Stuart, Kenneth D (April 2024, Frontiers in Cellular and Infection Microbiology)

   Kinetoplastid pathogens includingTrypanosoma brucei,T. cruzi, andLeishmaniaspecies, are early diverged, eukaryotic, unicellular parasites. Functional understanding of many proteins from these pathogens has been hampered by limited sequence homology to proteins from other model organisms. Here we describe the development of a high-throughput deep mutational scanning approach inT. bruceithat facilitates rapid and unbiased assessment of the impacts of many possible amino acid substitutions within a protein on cell fitness, as measured by relative cell growth. The approach leverages several molecular technologies: cells with conditional expression of a wild-type gene of interest and constitutive expression of a library of mutant variants, degron-controlled stabilization of I-SceI meganuclease to mediate highly efficient transfection of a mutant allele library, and a high-throughput sequencing readout for cell growth upon conditional knockdown of wild-type gene expression and exclusive expression of mutant variants. Using this method, we queried the effects of amino acid substitutions in the apparently non-catalytic RNase III-like domain of KREPB4 (B4), which is an essential component of the RNA Editing Catalytic Complexes (RECCs) that carry out mitochondrial RNA editing inT. brucei. We measured the impacts of thousands of B4 variants on bloodstream form cell growth and validated the most deleterious variants containing single amino acid substitutions. Crucially, there was no correlation between phenotypes and amino acid conservation, demonstrating the greater power of this method over traditional sequence homology searching to identify functional residues. The bloodstream form cell growth phenotypes were combined with structural modeling, RECC protein proximity data, and analysis of selected substitutions in procyclic formT. brucei. These analyses revealed that the B4 RNaseIII-like domain is essential for maintenance of RECC integrity and RECC protein abundances and is also involved in changes in RECCs that occur between bloodstream and procyclic form life cycle stages. 

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5. ATAD3 Proteins: Unique Mitochondrial Proteins Essential for Life in Diverse Eukaryotic Lineages

   https://doi.org/10.1093/pcp/pcad122  

   Waters, Elizabeth R.; Bezanilla, Magdalena; Vierling, Elizabeth (October 2023, Plant And Cell Physiology)

   Abstract ATPase family AAA domain–containing 3 (ATAD3) proteins are unique mitochondrial proteins that arose deep in the eukaryotic lineage but that are surprisingly absent in Fungi and Amoebozoa. These ∼600-amino acid proteins are anchored in the inner mitochondrial membrane and are essential in metazoans and Arabidopsis thaliana. ATAD3s comprise a C-terminal ATPases Associated with a variety of cellular Activities (AAA+) matrix domain and an ATAD3_N domain, which is located primarily in the inner membrane space but potentially extends to the cytosol to interact with the ER. Sequence and structural alignments indicate that ATAD3 proteins are most similar to classic chaperone unfoldases in the AAA+ family, suggesting that they operate in mitochondrial protein quality control. A. thaliana has four ATAD3 genes in two distinct clades that appear first in the seed plants, and both clades are essential for viability. The four genes are generally coordinately expressed, and transcripts are highest in growing apices and imbibed seeds. Plants with disrupted ATAD3 have reduced growth, aberrant mitochondrial morphology, diffuse nucleoids and reduced oxidative phosphorylation complex I. These and other pleiotropic phenotypes are also observed in ATAD3 mutants in metazoans. Here, we discuss the distribution of ATAD3 proteins as they have evolved in the plant kingdom, their unique structure, what we know about their function in plants and the challenges in determining their essential roles in mitochondria. 

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