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1. Sugar-Phosphate Metabolism Regulates Stationary-Phase Entry and Stalk Elongation in Caulobacter crescentus

   https://doi.org/10.1128/JB.00468-19  

   de Young, Kevin D. ; Stankeviciute, Gabriele ; Klein, Eric A. ( January 2020 , Journal of Bacteriology)

   Brun, Yves V. (Ed.)

   ABSTRACT Bacteria have a variety of mechanisms for adapting to environmental perturbations. Changes in oxygen availability result in a switch between aerobic and anaerobic respiration, whereas iron limitation may lead to siderophore secretion. In addition to metabolic adaptations, many organisms respond by altering their cell shape. Caulobacter crescentus , when grown under phosphate-limiting conditions, dramatically elongates its polar stalk appendage. The stalk is hypothesized to facilitate phosphate uptake; however, the mechanistic details of stalk synthesis are not well characterized. We used a chemical mutagenesis approach to isolate and characterize stalk-deficient mutants, one of which had two mutations in the phosphomannose isomerase gene ( manA ) that were necessary and sufficient to inhibit stalk elongation. Transcription of the pho regulon was unaffected in the manA mutant; therefore, ManA plays a unique regulatory role in stalk synthesis. The mutant ManA had reduced enzymatic activity, resulting in a 5-fold increase in the intracellular fructose 6-phosphate/mannose 6-phosphate ratio. This metabolic imbalance impaired the synthesis of cellular envelope components derived from mannose 6-phosphate, namely, lipopolysaccharide O-antigen and exopolysaccharide. Furthermore, the manA mutations prevented C. crescentus cells from efficiently entering stationary phase. Deletion of the stationary-phase response regulator gene spdR inhibited stalk elongation in wild-type cells, while overproduction of the alarmone ppGpp, which triggers growth arrest and stationary-phase entry, increased stalk length in the manA mutant strain. These results demonstrate that sugar-phosphate metabolism regulates stalk elongation independently of phosphate starvation. IMPORTANCE Metabolic control of bacterial cell shape is an important mechanism for adapting to environmental perturbations. Caulobacter crescentus dramatically elongates its polar stalk appendage in response to phosphate starvation. To investigate the mechanism of this morphological adaptation, we isolated stalk-deficient mutants, one of which had mutations in the phosphomannose isomerase gene ( manA ) that blocked stalk elongation, despite normal activation of the phosphate starvation response. The mutant ManA resulted in an imbalance in sugar-phosphate concentrations, which had effects on the synthesis of cellular envelope components and entry into stationary phase. Due to the interconnectivity of metabolic pathways, our findings may suggest more generally that the modulation of bacterial cell shape involves the regulation of growth phase and the synthesis of cellular building blocks. 

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2. GCAF(TMEM251) regulates lysosome biogenesis by activating the mannose-6-phosphate pathway

   https://doi.org/10.1038/s41467-022-33025-1  

   Zhang, Weichao ; Yang, Xi ; Li, Yingxiang ; Yu, Linchen ; Zhang, Bokai ; Zhang, Jianchao ; Cho, Woo Jung ; Venkatarangan, Varsha ; Chen, Liang ; Burugula, Bala Bharathi ; et al ( September 2022 , Nature Communications)

   The mannose-6-phosphate (M6P) biosynthetic pathway for lysosome biogenesis has been studied for decades and is considered a well-understood topic. However, whether this pathway is regulated remains an open question. In a genome-wide CRISPR/Cas9 knockout screen, we discover TMEM251 as the first regulator of the M6P modification. Deleting TMEM251 causes mistargeting of most lysosomal enzymes due to their loss of M6P modification and accumulation of numerous undigested materials. We further demonstrate that TMEM251 localizes to the Golgi and is required for the cleavage and activity of GNPT, the enzyme that catalyzes M6P modification. In zebrafish, TMEM251 deletion leads to severe developmental defects including heart edema and skeletal dysplasia, which phenocopies Mucolipidosis Type II. Our discovery provides a mechanism for the newly discovered human disease caused by TMEM251 mutations. We name TMEM251 asGNPTABcleavage andactivityfactor (GCAF) and its related disease as Mucolipidosis Type V.

    

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3. Structural and biochemical characterization of Arabidopsis alcohol dehydrogenases reveals distinct functional properties but similar redox sensitivity

   https://doi.org/10.1111/tpj.16651  

   Meloni, Maria ; Rossi, Jacopo ; Fanti, Silvia ; Carloni, Giacomo ; Tedesco, Daniele ; Treffon, Patrick ; Piccinini, Luca ; Falini, Giuseppe ; Trost, Paolo ; Vierling, Elizabeth ; et al ( February 2024 , The Plant Journal)

   Alcohol dehydrogenases (ADHs) are a group of zinc‐binding enzymes belonging to the medium‐length dehydrogenase/reductase (MDR) protein superfamily. In plants, these enzymes fulfill important functions involving the reduction of toxic aldehydes to the corresponding alcohols (as well as catalyzing the reverse reaction, i.e., alcohol oxidation; ADH1) and the reduction of nitrosoglutathione (GSNO; ADH2/GSNOR). We investigated and compared the structural and biochemical properties of ADH1 and GSNOR fromArabidopsis thaliana. We expressed and purified ADH1 and GSNOR and determined two new structures, NADH‐ADH1 and apo‐GSNOR, thus completing the structural landscape of Arabidopsis ADHs in both apo‐ and holo‐forms. A structural comparison of these Arabidopsis ADHs revealed a high sequence conservation (59% identity) and a similar fold. In contrast, a striking dissimilarity was observed in the catalytic cavity supporting substrate specificity and accommodation. Consistently, ADH1 and GSNOR showed strict specificity for their substrates (ethanol and GSNO, respectively), although both enzymes had the ability to oxidize long‐chain alcohols, with ADH1 performing better than GSNOR. Both enzymes contain a high number of cysteines (12 and 15 out of 379 residues for ADH1 and GSNOR, respectively) and showed a significant and similar responsivity to thiol‐oxidizing agents, indicating that redox modifications may constitute a mechanism for controlling enzyme activity under both optimal growth and stress conditions.

    

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4. A multidomain enzyme, with glycerol‐3‐phosphate dehydrogenase and phosphatase activities, is involved in a chloroplastic pathway for glycerol synthesis in Chlamydomonas reinhardtii

   https://doi.org/10.1111/tpj.13530  

   Morales‐Sánchez, Daniela ; Kim, Yeongho ; Terng, Ee Leng ; Peterson, Laura ; Cerutti, Heriberto ( April 2017 , The Plant Journal)

   Understanding the unique features of algal metabolism may be necessary to realize the full potential of algae as feedstock for the production of biofuels and biomaterials. Under nitrogen deprivation, the green algaC. reinhardtiishowed substantial triacylglycerol (TAG) accumulation and up‐regulation of a gene,GPD2, encoding a multidomain enzyme with a putative phosphoserine phosphatase (PSP) motif fused to glycerol‐3‐phosphate dehydrogenase (GPD) domains. CanonicalGPDenzymes catalyze the synthesis of glycerol‐3‐phosphate (G3P) by reduction of dihydroxyacetone phosphate (DHAP). G3P forms the backbone ofTAGs and membrane glycerolipids and it can be dephosphorylated to yield glycerol, an osmotic stabilizer and compatible solute under hypertonic stress. RecombinantChlamydomonasGPD2 showed both reductase and phosphatase activitiesin vitroand it can work as a bifunctional enzyme capable of synthesizing glycerol directly fromDHAP. In addition,GPD2and a gene encoding glycerol kinase were up‐regulated inChlamydomonascells exposed to high salinity.RNA‐mediated silencing ofGPD2revealed that the multidomain enzyme was required forTAGaccumulation under nitrogen deprivation and for glycerol synthesis under high salinity. Moreover, aGPD2‐mCherry fusion protein was found to localize to the chloroplast, supporting the existence of aGPD2‐dependent plastid pathway for the rapid synthesis of glycerol in response to hyperosmotic stress. We hypothesize that the reductase and phosphatase activities ofPSP–GPDmultidomain enzymes may be modulated by post‐translational modifications/mechanisms, allowing them to synthesize primarily G3P or glycerol depending on environmental conditions and/or metabolic demands in algal species of the core Chlorophytes.

    

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5. Structural basis for divergent and convergent evolution of catalytic machineries in plant aromatic amino acid decarboxylase proteins

   https://doi.org/10.1073/pnas.1920097117  

   Torrens-Spence, Michael P. ; Chiang, Ying-Chih ; Smith, Tyler ; Vicent, Maria A. ; Wang, Yi ; Weng, Jing-Ke ( May 2020 , Proceedings of the National Academy of Sciences)

   Radiation of the plant pyridoxal 5′-phosphate (PLP)-dependent aromaticl-amino acid decarboxylase (AAAD) family has yielded an array of paralogous enzymes exhibiting divergent substrate preferences and catalytic mechanisms. Plant AAADs catalyze either the decarboxylation or decarboxylation-dependent oxidative deamination of aromaticl-amino acids to produce aromatic monoamines or aromatic acetaldehydes, respectively. These compounds serve as key precursors for the biosynthesis of several important classes of plant natural products, including indole alkaloids, benzylisoquinoline alkaloids, hydroxycinnamic acid amides, phenylacetaldehyde-derived floral volatiles, and tyrosol derivatives. Here, we present the crystal structures of four functionally distinct plant AAAD paralogs. Through structural and functional analyses, we identify variable structural features of the substrate-binding pocket that underlie the divergent evolution of substrate selectivity toward indole, phenyl, or hydroxyphenyl amino acids in plant AAADs. Moreover, we describe two mechanistic classes of independently arising mutations in AAAD paralogs leading to the convergent evolution of the derived aldehyde synthase activity. Applying knowledge learned from this study, we successfully engineered a shortened benzylisoquinoline alkaloid pathway to produce (S)-norcoclaurine in yeast. This work highlights the pliability of the AAAD fold that allows change of substrate selectivity and access to alternative catalytic mechanisms with only a few mutations.

    

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