More Like this

1. KREH2 helicase represses ND7 mRNA editing in procyclic-stage Trypanosoma brucei by opposite modulation of canonical and ‘moonlighting’ gRNA utilization creating a proposed mRNA structure

   https://doi.org/10.1093/nar/gkae699  

   Meehan, Joshua; Ivens, Alasdair; Grote, Scott; Rodshagen, Tyler; Chen, Zihao; Goode, Cody; Sharma, Sunil K.; Kumar, Vikas; Frese, Addison; Goodall, Zachary; et al (August 2024, Nucleic Acids Research)

   Abstract Unknown factors regulate mitochondrial U-insertion/deletion (U-indel) RNA editing in procyclic-form (PCF) and bloodstream-form (BSF) T. brucei. This editing, directed by anti-sense gRNAs, creates canonical protein-encoding mRNAs and may developmentally control respiration. Canonical editing by gRNAs that specify protein-encoding mRNA sequences occurs amid massive non-canonical editing of unclear sources and biological significance. We found PCF-specific repression at a major early checkpoint in mRNA ND7, involving helicase KREH2-dependent opposite modulation of canonical and non-canonical ‘terminator’ gRNA utilization. Terminator-programmed editing derails canonical editing and installs proposed repressive structure in 30% of the ND7 transcriptome. BSF-to-PCF differentiation in vitro recreated this negative control. Remarkably, KREH2-RNAi knockdown relieved repression and increased editing progression by reverting canonical/terminator gRNA utilization. ND7 transcripts lacking early terminator-directed editing in PCF exhibited similar negative editing control along the mRNA sequence, suggesting global modulation of gRNA utilization fidelity. The terminator is a ‘moonlighting’ gRNA also associated with mRNA COX3 canonical editing, so the gRNA transcriptome seems multifunctional. Thus, KREH2 is the first identified repressor in developmental editing control. This and our prior work support a model whereby KREH2 activates or represses editing in a stage and substrate-specific manner. KREH2’s novel dual role tunes mitochondrial gene expression in either direction during development. 

   more » « less
2. The localization of PHRAGMOPLAST ORIENTING KINESIN1 at the division site depends on the microtubule-binding proteins TANGLED1 and AUXIN-INDUCED IN ROOT CULTURES9 in Arabidopsis

   https://doi.org/10.1093/plcell/koac266  

   Mills, Alison M.; Morris, Victoria H.; Rasmussen, Carolyn G. (August 2022, The Plant Cell)

   Abstract Proper plant growth and development require spatial coordination of cell divisions. Two unrelated microtubule-binding proteins, TANGLED1 (TAN1) and AUXIN-INDUCED IN ROOT CULTURES9 (AIR9), are together required for normal growth and division plane orientation in Arabidopsis (Arabidopsis thaliana). The tan1 air9 double mutant has synthetic growth and division plane orientation defects, while single mutants lack obvious defects. Here we show that the division site-localized protein, PHRAGMOPLAST ORIENTING KINESIN1 (POK1), was aberrantly lost from the division site during metaphase and telophase in the tan1 air9 mutant. Since TAN1 and POK1 interact via the first 132 amino acids of TAN1 (TAN11–132), we assessed the localization and function of TAN11–132 in the tan1 air9 double mutant. TAN11–132 rescued tan1 air9 mutant phenotypes and localized to the division site during telophase. However, replacing six amino-acid residues within TAN11–132, which disrupted the POK1–TAN1 interaction in the yeast-two-hybrid system, caused loss of both rescue and division site localization of TAN11–132 in the tan1 air9 mutant. Full-length TAN1 with the same alanine substitutions had defects in phragmoplast guidance and reduced TAN1 and POK1 localization at the division site but rescued most tan1 air9 mutant phenotypes. Together, these data suggest that TAN1 and AIR9 are required for POK1 localization, and yet unknown proteins may stabilize TAN1–POK1 interactions. 

   more » « less
3. A phenotypic screen with Trypanosoma brucei for discovering small molecules that target the SLiM‐binding pocket of proliferating cell nuclear antigen orthologs

   https://doi.org/10.1111/cbdd.14361  

   Actis, Marisa; Fujii, Naoaki; Mackey, Zachary B. (September 2023, Chemical Biology & Drug Design)

   Abstract Proliferating cell nuclear antigen (PCNA) is a homo‐trimeric protein complex that clamps around DNA to tether DNA polymerases to the template during replication and serves as a hub for many other interacting proteins. It regulates DNA metabolic processes and other vital cellar functions through the binding of proteins having short linear motifs (SLiMs) like the PIP‐box (PCNA‐interacting protein‐box) or the APIM (AlkB homolog 2 PCNA‐interacting motif) in the hydrophobic pocket where SLiMs bind. However, overproducing TbPCNA or human PCNA (hPCNA) in the pathogenic protistTrypanosoma bruceitriggers a dominant‐negative phenotype of arrested proliferation. The mechanism for arrestingT. bruceiproliferation requires the overproduced PCNA orthologs to have functional intact SLiM‐binding pocket. Sight‐directed mutagenesis studies showed thatT. bruceioverproducing PCNA variants with disrupted SLiM‐binding pockets grew normally. We hypothesized that chemically disrupting the SLiM‐binding pocket would restore proliferation inT. brucei, overproducing PCNA orthologs. Testing this hypothesis is the proof‐of‐concept for aT. brucei‐based PCNA screening assay. The assay design is to discover bioactive small molecules that restore proliferation inT. bruceistrains that overproduce PCNA orthologs, likely by disrupting interactions in the SLiM‐binding pocket. The pilot screen for this assay discovered two hit compounds that linked to predetermined PCNA targets. Compound#1, a known hPCNA inhibitor, had selective bioactivity to hPCNA overproduced inT. brucei, validating the assay. Compound#6had promiscuous bioactivity for hPCNA and TbPCNA but is the first compound discovered with bioactivity for inhibiting TbPCNA. 

   more » « less
4. Glucose Signaling Is Important for Nutrient Adaptation during Differentiation of Pleomorphic African Trypanosomes

   https://doi.org/10.1128/mSphere.00366-18  

   Qiu, Yijian; Milanes, Jillian E.; Jones, Jessica A.; Noorai, Rooksana E.; Shankar, Vijay; Morris, James C.; Moreno, Silvia N. (October 2018, mSphere)

   ABSTRACT The African trypanosome has evolved mechanisms to adapt to changes in nutrient availability that occur during its life cycle. During transition from mammalian blood to insect vector gut, parasites experience a rapid reduction in environmental glucose. Here we describe how pleomorphic parasites respond to glucose depletion with a focus on parasite changes in energy metabolism and growth. Long slender bloodstream form parasites were rapidly killed as glucose concentrations fell, while short stumpy bloodstream form parasites persisted to differentiate into the insect-stage procyclic form parasite. The rate of differentiation was lower than that triggered by other cues but reached physiological rates when combined with cold shock. Both differentiation and growth of resulting procyclic form parasites were inhibited by glucose and nonmetabolizable glucose analogs, and these parasites were found to have upregulated amino acid metabolic pathway component gene expression. In summary, glucose transitions from the primary metabolite of the blood-stage infection to a negative regulator of cell development and growth in the insect vector, suggesting that the hexose is not only a key metabolic agent but also an important signaling molecule. IMPORTANCE As the African trypanosome Trypanosoma brucei completes its life cycle, it encounters many different environments. Adaptation to these environments includes modulation of metabolic pathways to parallel the availability of nutrients. Here, we describe how the blood-dwelling life cycle stages of the African trypanosome, which consume glucose to meet their nutritional needs, respond differently to culture in the near absence of glucose. The proliferative long slender parasites rapidly die, while the nondividing short stumpy parasite remains viable and undergoes differentiation to the next life cycle stage, the procyclic form parasite. Interestingly, a sugar analog that cannot be used as an energy source inhibited the process. Furthermore, the growth of procyclic form parasite that resulted from the event was inhibited by glucose, a behavior that is similar to that of parasites isolated from tsetse flies. Our findings suggest that glucose sensing serves as an important modulator of nutrient adaptation in the parasite. 

   more » « less
5. Elucidating the Structural Impacts of Protein InDels

   https://doi.org/10.3390/biom12101435  

   Jilani, Muneeba; Turcan, Alistair; Haspel, Nurit; Jagodzinski, Filip (October 2022, Biomolecules)

   The effects of amino acid insertions and deletions (InDels) remain a rather under-explored area of structural biology. These variations oftentimes are the cause of numerous disease phenotypes. In spite of this, research to study InDels and their structural significance remains limited, primarily due to a lack of experimental information and computational methods. In this work, we fill this gap by modeling InDels computationally; we investigate the rigidity differences between the wildtype and a mutant variant with one or more InDels. Further, we compare how structural effects due to InDels differ from the effects of amino acid substitutions, which are another type of amino acid mutation. We finish by performing a correlation analysis between our rigidity-based metrics and wet lab data for their ability to infer the effects of InDels on protein fitness. 

   more » « less