Structure–function analysis of <i>Plasmodium</i> RNA triphosphatase and description of a triphosphate tunnel metalloenzyme superfamily that includes Cet1-like RNA triphosphatases and CYTH proteins

Gong, Chunling; Smith, Paul; Shuman, Stewart

doi:10.1261/rna.119806

RNA

2006

DOI: 10.1261/rna.119806

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Structure–function analysis of Plasmodium RNA triphosphatase and description of a triphosphate tunnel metalloenzyme superfamily that includes Cet1-like RNA triphosphatases and CYTH proteins

Chunling Gong¹,

Paul Smith²,

Stewart Shuman³

Abstract: RNA triphosphatase catalyzes the first step in mRNA capping. The RNA triphosphatases of fungi and protozoa are structurally and mechanistically unrelated to the analogous mammalian enzyme, a situation that recommends RNA triphosphatase as an anti-infective target. Fungal and protozoan RNA triphosphatases belong to a family of metal-dependent phosphohydrolases exemplified by yeast Cet1. The Cet1 active site is unusually complex and located within a topologically closed hydrophilic b-barrel (the triphosphate tun… Show more

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Cited by 36 publications

(59 citation statements)

References 27 publications

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“…The triphosphate tunnel metalloenzyme (TTM) superfamily comprises two groups of enzymes, RNA triphosphatases and CYTH phosphatases (CyaB adenylate cyclase, thiamine triphosphatase) that possess common characteristics in their catalytic sites (Iyer and Aravind, 2002;Gong et al, 2006). Members of this superfamily are able to hydrolyze a variety of triphosphate substrates, giving them important roles in cAMP formation, mRNA capping, and secondary metabolism (Iyer and Aravind, 2002;Gallagher et al, 2006;Gong et al, 2006;Song et al, 2008).…”

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confidence: 99%

“…Members of this superfamily are able to hydrolyze a variety of triphosphate substrates, giving them important roles in cAMP formation, mRNA capping, and secondary metabolism (Iyer and Aravind, 2002;Gallagher et al, 2006;Gong et al, 2006;Song et al, 2008). Most TTMs possess a unique tunnel structure composed of eight antiparallel beta strands forming a beta barrel and a characteristic EXEXK motif (where X is any amino acid), which is important for catalytic activity (Lima et al, 1999;Iyer and Aravind, 2002;Gallagher et al, 2006).…”

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confidence: 99%

“…However, it appears they have acquired the ability to act on a diverse range of nucleotide and organophosphate substrates (Iyer and Aravind, 2002;Bettendorff and Wins, 2013). Known functions of TTMs include fungal and protozoan RNA triphosphatases (Cet1; Lima et al, 1999;Gong et al, 2006), bacterial adenylate cyclases (CyaB from Aeromonas hydrophila and YpAC-IV from Yersinia pestis; Sismeiro et al, 1998;Gallagher et al, 2006), and mammalian thiamine triphosphatases (Lakaye et al, 2004;Song et al, 2008). More recently, tripolyphosphatase activity was discovered for CthTTM from Clostridium thermocellum and NeuTTM from Nitrosomonas europaea, highlighting the functional diversity of this superfamily (Keppetipola et al, 2007;Delvaux et al, 2011).…”

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Triphosphate Tunnel Metalloenzyme Function in Senescence Highlights a Biological Diversification of This Protein Superfamily

et al. 2017

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ORCID IDs: 0000-0003-3889-6183 (W.M.); 0000-0002-3797-4277 (K.Y.).The triphosphate tunnel metalloenzyme (TTM) superfamily comprises a group of enzymes that hydrolyze organophosphate substrates. They exist in all domains of life, yet the biological role of most family members is unclear. Arabidopsis (Arabidopsis thaliana) encodes three TTM genes. We have previously reported that AtTTM2 displays pyrophosphatase activity and is involved in pathogen resistance. Here, we report the biochemical activity and biological function of AtTTM1 and diversification of the biological roles between AtTTM1 and 2. Biochemical analyses revealed that AtTTM1 displays pyrophosphatase activity similar to AtTTM2, making them the only TTMs characterized so far to act on a diphosphate substrate. However, knockout mutant analysis showed that AtTTM1 is not involved in pathogen resistance but rather in leaf senescence. AtTTM1 is transcriptionally up-regulated during leaf senescence, and knockout mutants of AtTTM1 exhibit delayed dark-induced and natural senescence. The double mutant of AtTTM1 and AtTTM2 did not show synergistic effects, further indicating the diversification of their biological function. However, promoter swap analyses revealed that they functionally can complement each other, and confocal microscopy revealed that both proteins are tail-anchored proteins that localize to the mitochondrial outer membrane. Additionally, transient overexpression of either gene in Nicotiana benthamiana induced senescence-like cell death upon dark treatment. Taken together, we show that two TTMs display the same biochemical properties but distinct biological functions that are governed by their transcriptional regulation. Moreover, this work reveals a possible connection of immunity-related programmed cell death and senescence through novel mitochondrial tail-anchored proteins.

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Triphosphate Tunnel Metalloenzyme Function in Senescence Highlights a Biological Diversification of This Protein Superfamily

et al. 2017

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“…RNA triphosphatases of fungi, protozoa, and several DNA viruses are the founding members of the triphosphate tunnel metalloenzyme (TTM) 2 superfamily of phosphohydrolases (1). Members of this family that have been characterized biochemically include the triphosphatase components of the cellular mRNA capping systems of Saccharomyces cerevisiae (2,3), Schizosaccharomyces pombe (4), Candida albicans (5), Plasmodium falciparum (1,6,7), Trypanosoma brucei (8,9), Encephalitozoon cuniculi (10), and Giardia lamblia (11) plus the triphosphatases of the Chlorella virus, poxvirus, and baculovirus mRNA capping systems (12)(13)(14)(15)(16)(17).…”

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confidence: 99%

“…It was thought initially that the Cet1-like RNA triphosphatases arose de novo in unicellular eukarya in tandem with the emergence of caps as the defining feature of eukaryal mRNA. This notion has been eclipsed by the finding that the heretofore unique tertiary structure and active site of yeast RNA triphosphatase are recapitulated in the crystal structures of archaeal and bacterial proteins of unknown biochemical function, including proteins from Pyrococcus (Protein Data Bank (PDB) accession codes 1YEM and 2DC4), Vibrio (2ACA), and Nitrosomonas (2FBL) (1). The Cet1-like archaeal/bacterial proteins are usually annotated as belonging to the so-called CYTH family (19), which is defined by its two biochemically characterized founding members, an Aeromonas hydrophila adenylate cyclase CyaB and a mammalian thiamine triphosphatase (20,21).…”

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Novel Triphosphate Phosphohydrolase Activity of Clostridium thermocellum TTM, a Member of the Triphosphate Tunnel Metalloenzyme Superfamily

Keppetipola

Jain

Shuman

2007

Journal of Biological Chemistry

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Triphosphate tunnel metalloenzymes (TTMs) are a newly recognized superfamily of phosphotransferases defined by a unique active site residing within an eight-stranded ␤ barrel. The prototypical members are the eukaryal metal-dependent RNA triphosphatases, which catalyze the initial step in mRNA capping. Little is known about the activities and substrate specificities of the scores of TTM homologs present in bacterial and archaeal proteomes, nearly all of which are annotated as adenylate cyclases. Here we have conducted a biochemical and structure-function analysis of a TTM protein (CthTTM) from the bacterium Clostridium thermocellum. CthTTM is a metal-dependent tripolyphosphatase and nucleoside triphosphatase; it is not an adenylate cyclase. We have identified 11 conserved amino acids in the tunnel that are critical for tripolyphosphatase and ATPase activity. The most salient findings are that (i) CthTTM is 150-fold more active in cleaving tripolyphosphate than ATP and (ii) the substrate specificity of CthTTM can be transformed by a single mutation (K8A) that abolishes tripolyphosphatase activity while strongly stimulating ATP hydrolysis. Our results underscore the plasticity of CthTTM substrate choice and suggest how novel specificities within the TTM superfamily might evolve through changes in the residues that line the tunnel walls.

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Brachypodium distachyon triphosphate tunnel metalloenzyme 3 is both a triphosphatase and an adenylyl cyclase upregulated by mechanical wounding

et al. 2019

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Proteins with a CyaB, thiamine triphosphatase domain (CYTH domain) may play a central role at the interface between nucleotide and polyphosphate metabolism. One of the plant CYTH domain‐containing proteins from Brachypodium distachyon, BdTTM3, is annotated in NCBI databases as an ‘adenylyl cyclase (AC)’ or a ‘triphosphate tunnel metalloenzyme’. The divergent nomenclature and the search for plant ACs induced us to experimentally confirm the enzymatic activity of BdTTM3. Based on in vitro analysis, we have shown that the recombinant form of BdTTM3 is a protein with high triphosphatase activity (binding both tripolyphosphate and ATP) and low AC activity. Furthermore, the analysis of BdTTM3 transcriptional activity indicates its involvement in the mechanism underlying responses to wounding stress in B. distachyon leaves.

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Structure–function analysis of Plasmodium RNA triphosphatase and description of a triphosphate tunnel metalloenzyme superfamily that includes Cet1-like RNA triphosphatases and CYTH proteins

Cited by 36 publications

References 27 publications

Triphosphate Tunnel Metalloenzyme Function in Senescence Highlights a Biological Diversification of This Protein Superfamily

Triphosphate Tunnel Metalloenzyme Function in Senescence Highlights a Biological Diversification of This Protein Superfamily

Novel Triphosphate Phosphohydrolase Activity of Clostridium thermocellum TTM, a Member of the Triphosphate Tunnel Metalloenzyme Superfamily

Brachypodium distachyon triphosphate tunnel metalloenzyme 3 is both a triphosphatase and an adenylyl cyclase upregulated by mechanical wounding

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