Your search keyword '"Saiardi, Adolfo"' showing total 12 results

1. Inositol phosphate kinases in the eukaryote landscape.

Author

Laha D, Portela-Torres P, Desfougères Y, and Saiardi A

Subjects

Animals, Eukaryotic Cells classification, Eukaryotic Cells metabolism, Humans, Inositol Phosphates chemistry, Inositol Phosphates metabolism, Multigene Family, Phosphotransferases genetics, Phylogeny, Plants enzymology, Plants metabolism, Signal Transduction, Eukaryotic Cells enzymology, Phosphotransferases metabolism

Abstract

Inositol phosphate encompasses a large multifaceted family of signalling molecules that originate from the combinatorial attachment of phosphate groups to the inositol ring. To date, four distinct inositol kinases have been identified, namely, IPK, ITPK, IPPK (IP5-2K), and PPIP5K. Although, ITPKs have recently been identified in archaea, eukaryotes have taken advantage of these enzymes to create a sophisticated signalling network based on inositol phosphates. However, it remains largely elusive what fundamental biochemical principles control the signalling cascade. Here, we present an evolutionary approach to understand the development of the 'inositol phosphate code' in eukaryotes. Distribution analyses of these four inositol kinase groups throughout the eukaryotic landscape reveal the loss of either ITPK, or of PPIP5K proteins in several species. Surprisingly, the loss of IPPK, an enzyme thought to catalyse the rate limiting step of IP 6 (phytic acid) synthesis, was also recorded. Furthermore, this study highlights a noteworthy difference between animal (metazoan) and plant (archaeplastida) lineages. While metazoan appears to have a substantial amplification of IPK enzymes, archaeplastida genomes show a considerable increase in ITPK members. Differential evolution of IPK and ITPK between plant and animal lineage is likely reflective of converging functional adaptation of these two types of inositol kinases. Since, the IPK family comprises three sub-types IPMK, IP6K, and IP3-3K each with dedicated enzymatic specificity in metazoan, we propose that the amplified ITPK group in plant could be classified in sub-types with distinct enzymology., (Copyright © 2020. Published by Elsevier Ltd.)

Published

2021

2. Eukaryotic Phosphate Homeostasis: The Inositol Pyrophosphate Perspective.

Author

Azevedo C and Saiardi A

Subjects

Humans, Eukaryotic Cells metabolism, Homeostasis, Inositol Phosphates metabolism

Abstract

Phosphate, as a cellular energy currency, essentially drives most biochemical reactions defining living organisms, and thus its homeostasis must be tightly regulated. Investigation into the role of inositol pyrophosphates (PP-IPs) has provided a novel perspective on the regulation of phosphate homeostasis. Recent data suggest that metabolic and signaling interplay between PP-IPs, ATP, and inorganic polyphosphate (polyP) influences and is influenced by cellular phosphate homeostasis. Different studies have demonstrated that the SPX protein domain is a key component of proteins involved in phosphate metabolism. How PP-IPs control some aspects of phosphate homeostasis has become clearer with the recently acquired crystal structures of SPX domains. We review here recent studies on eukaryote phosphate homeostasis and provide insights into future research., (Copyright © 2016 Elsevier Ltd. All rights reserved.)

Published

2017

3. Functions of inorganic polyphosphates in eukaryotic cells: a coat of many colours.

Author

Azevedo C and Saiardi A

Subjects

Animals, Cell Membrane metabolism, Energy Metabolism, Gene Expression Regulation, Fungal, Humans, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Eukaryotic Cells metabolism, Polyphosphates metabolism

Abstract

PolyP (inorganic polyphosphate) is a linear polymer of tens to hundreds of orthophosphate residues linked by high-energy phosphoanhydride bonds. This polymer is present in all living organisms from bacteria to mammals. Until recently, most of the studies on polyP have focused on its function in prokaryotes. In prokaryotes, polyP has been implicated in many unrelated processes ranging from basic metabolism to structural functions. However, polyP analysis and function in higher eukaryotes has been gaining momentum recently. In the present review, we mainly aim to discuss the proposed intracellular functions of polyP in higher eukaryotes and its detection methods.

Published

2014

4. Cell signalling by inositol pyrophosphates.

Author

Saiardi A

Subjects

Animals, Apoptosis, Biological Transport, Chemotaxis, Eukaryotic Cells cytology, Humans, Inositol chemistry, Inositol metabolism, Inositol Phosphates chemistry, Insulin metabolism, Insulin Secretion, Protein Biosynthesis, Ribosomes genetics, Ribosomes metabolism, Stress, Physiological, Telomere Homeostasis, Eukaryotic Cells metabolism, Inositol Phosphates metabolism, Signal Transduction

Abstract

Inositol serves as a module for the generation of a high level of molecular diversity through the combinatorial attachment and removal of phosphate groups. The array of potential inositol-containing molecules is further expanded by the generation of diphospho inositol polyphosphates, commonly referred as inositol pyrophosphates. All eukaryotic cells possess inositol pyrophosphates containing one or more diphospho- moieties. The metabolism of this class of molecules is highly dynamic, and the enzymes responsible for their metabolism are evolutionary conserved. This new, exciting class of molecules are uniquely chracterized by a high energetic diphospho- bound that is able to participate in phosphotrasfer reactions thereby generating pyrophosphorylation of protein. However, allosteric mechanisms of action have been also proposed. In the past decade several disparate nuclear and cytoplasmic functions have been attributed to inositol pyrophosphates, ranging from intracellular trafficking to telomere length control and from regulating apoptotic process to stimulating insulin secretion. The extraordinary range of cellular function controlled by inositol pyrophosphate underline their great importance.

Published

2012

5. Biochemical and structural characterization of an inositol pyrophosphate kinase from a giant virus.

Author

Zong, Guangning, Desfougères, Yann, Portela-Torres, Paloma, Kwon, Yong-Uk, Saiardi, Adolfo, Shears, Stephen B., and Wang, Huanchen

Subjects

INOSITOL phosphates, INOSITOL, SITE-specific mutagenesis, EUKARYOTIC cells, LIGAND binding (Biochemistry), CELL communication

Abstract

Kinases that synthesize inositol phosphates (IPs) and pyrophosphates (PP-IPs) control numerous biological processes in eukaryotic cells. Herein, we extend this cellular signaling repertoire to viruses. We have biochemically and structurally characterized a minimalist inositol phosphate kinase (i.e., TvIPK) encoded by Terrestrivirus, a nucleocytoplasmic large ("giant") DNA virus (NCLDV). We show that TvIPK can synthesize inositol pyrophosphates from a range of scyllo- and myo-IPs, both in vitro and when expressed in yeast cells. We present multiple crystal structures of enzyme/substrate/nucleotide complexes with individual resolutions from 1.95 to 2.6 Å. We find a heart-shaped ligand binding pocket comprising an array of positively charged and flexible side chains, underlying the observed substrate diversity. A crucial arginine residue in a conserved "G-loop" orients the γ-phosphate of ATP to allow substrate pyrophosphorylation. We highlight additional conserved catalytic and architectural features in TvIPK, and support their importance through site-directed mutagenesis. We propose that NCLDV inositol phosphate kinases may have assisted evolution of inositol pyrophosphate signaling, and we discuss the potential biogeochemical significance of TvIPK in soil niches. Synopsis: Inositol phosphate kinases regulate many biological processes in eukaryotes, but recent discoveries of archaeal homologs suggest an ancient evolutionary origin. Here, characterization of a primordial ATP-dependent inositol pyrophosphate kinase encoded by the giant virus genome of Terrestrivirus provides insights into the evolution of inositol phosphate kinases. Terrestrivirus TvIPK specifically pyrophosphorylates a range of myo- and scyllo-based inositol polyphosphates both in vitro and when ectopically expressed in yeast. X-ray crystallographic analysis of TvIPK in complex with its substrates or products reveals conserved catalytic and architectural features. Positively charged and flexible side chains allow recognition of the diverse range of substrates. Pyrophosphorylation depends on ATP γ-phosphate orientation via an Arg residues in a conserved "G-loop." TvIPK, an ATP-dependent inositol pyrophosphate kinase from Terrestrivirus, a putative member of the Mimiviridae family of giant viruses, offers insights into the evolution of inositol phosphate signaling. [ABSTRACT FROM AUTHOR]

Published

2024

6. Fungal Kinases With a Sweet Tooth: Pleiotropic Roles of Their Phosphorylated Inositol Sugar Products in the Pathogenicity of Cryptococcus neoformans Present Novel Drug Targeting Opportunities.

Author

Lev, Sophie, Li, Cecilia, Desmarini, Desmarini, Sorrell, Tania C., Saiardi, Adolfo, and Djordjevic, Julianne T.

Subjects

CRYPTOCOCCUS neoformans, INOSITOL, PATHOGENIC fungi, KINASES, DRUG target, EUKARYOTIC cells

Abstract

Invasive fungal pathogens cause more than 300 million serious human infections and 1.6 million deaths per year. A clearer understanding of the mechanisms by which these fungi cause disease is needed to identify novel targets for urgently needed therapies. Kinases are key components of the signaling and metabolic circuitry of eukaryotic cells, which include fungi, and kinase inhibition is currently being exploited for the treatment of human diseases. Inhibiting evolutionarily divergent kinases in fungal pathogens is a promising avenue for antifungal drug development. One such group of kinases is the phospholipase C1-dependent inositol polyphosphate kinases (IPKs), which act sequentially to transfer a phosphoryl group to a pre-phosphorylated inositol sugar (IP). This review focuses on the roles of fungal IPKs and their IP products in fungal pathogenicity, as determined predominantly from studies performed in the model fungal pathogen Cryptococcus neoformans , and compares them to what is known in non-pathogenic model fungi and mammalian cells to highlight potential drug targeting opportunities. [ABSTRACT FROM AUTHOR]

Published

2019

7. Microbial inositol polyphosphate metabolic pathway as drug development target.

Author

Saiardi, Adolfo, Azevedo, Cristina, Desfougères, Yann, Portela-Torres, Paloma, and Wilson, Miranda S.C.

Subjects

*INOSITOL polyphosphate phosphatase, *DRUG development, *EUKARYOTIC cells, *CELL physiology, *KINASES

Abstract

Inositol polyphosphates are a diverse and multifaceted class of intracellular messengers omnipresent in eukaryotic cells. These water-soluble molecules regulate many aspects of fundamental cell physiology. Removing this metabolic pathway is deleterious: inositol phosphate kinase null mutations can result in lethality or substantial growth phenotypes. Inositol polyphosphate synthesis occurs through the actions of a set of kinases that phosphorylate phospholipase-generated IP 3 to higher phosphorylated forms, such as the fully phosphorylated IP 6 and the inositol pyrophosphates IP 7 and IP 8 . Unicellular organisms have a reduced array of the kinases for synthesis of higher phosphorylated inositol polyphosphates, while human cells possess two metabolic routes to IP 6 . The enzymes responsible for inositol polyphosphate synthesis have been identified in all eukaryote genomes, although their amino acid sequence homology is often barely detectable by common search algorithms. Homology between human and microbial inositol phosphate kinases is restricted to a few catalytically important residues. Recent studies of the inositol phosphate metabolic pathways in pathogenic fungi ( Cryptococcus neoformans ) and protozoa ( Trypanosome brucei ) have revealed the importance of the highly phosphorylated inositol polyphosphates to the fitness and thus virulence of these pathogens. Given this, identification of inositol kinase inhibitors specifically targeting the kinases of pathogenic microorganisms is desirable and achievable. [ABSTRACT FROM AUTHOR]

Published

2018

8. Protein pyrophosphorylation: moving forward.

Author

Saiardi, Adolfo

Subjects

*PHOSPHORYLATION, *PROTEINS, *EUKARYOTIC cells, *CYTOLOGY, *BIOCHEMISTRY, *INOSITOL pyrophosphates

Abstract

Genetic ablation of inositol pyrophosphate synthesis has established the fundamental importance of this class of molecules to the eukaryote cell. These studies, however, must be complemented by cell biology and biochemical approaches to appreciate the signalling involved in the processes regulated by inositol pyrophosphates. A recent study by Chanduri et al. published in the Biochemical Journal, by integrating multiple experimental approaches, demonstrated that inositol pyrophosphates regulate intracellular vesicular movement. In particular, the vesicular transport along the microtubule that is driven by the motor protein complex dynein. Importantly, one subunit of this cellular motor, dynein 1 intermediate chain 2, undergoes serine pyrophosphorylation, a post-translational modification driven by inositol pyrophosphates. The pyrophosphorylation status of this dynein intermediate chain regulates its interaction with dynactin, which recruits the motor to vesicles. This mechanistically might explain how inositol pyrophosphates control intracellular membrane trafficking. By dissecting the serine pyrophosphorylation process, this work increases our awareness of this modification, underappreciated by the scientific literature but probably not by the eukaryotic cell. [ABSTRACT FROM AUTHOR]

Published

2016

9. Phosphate, inositol and polyphosphates.

Author

Livermore, Thomas M., Azevedo, Cristina, Kolozsvari, Bernadett, Wilson, Miranda S. C., and Saiardi, Adolfo

Subjects

INOSITOL, POLYPHOSPHATES, EUKARYOTIC cells, DIGLYCERIDES, MOLECULAR shapes

Abstract

Eukaryotic cells have ubiquitously utilized the myo-inositol backbone to generate a diverse array of signalling molecules. This is achieved by arranging phosphate groups around the six-carbon inositol ring. There is virtually no biological process that does not take advantage of the uniquely variable architecture of phosphorylated inositol. In inositol biology, phosphates are able to form three distinct covalent bonds: phosphoester, phosphodiester and phosphoanhydride bonds, with each providing different properties. The phosphoester bond links phosphate groups to the inositol ring, the variable arrangement of which forms the basis of the signalling capacity of the inositol phosphates. Phosphate groups can also form the structural bridge between myo-inositol and diacylglycerol through the phosphodiester bond. The resulting lipid-bound inositol phosphates, or phosphoinositides, further expand the signalling potential of this family of molecules. Finally, inositol is also notable for its ability to host more phosphates than it has carbons. These unusual organic molecules are commonly referred to as the inositol pyrophosphates (PP-IPs), due to the presence of high-energy phosphoanhydride bonds (pyro- or diphospho-). PP-IPs themselves constitute a varied family of molecules with one or more pyrophosphate moiety/ies located around the inositol. Considering the relationship between phosphate and inositol, it is no surprise that members of the inositol phosphate family also regulate cellular phosphate homoeostasis. Notably, the PP-IPs play a fundamental role in controlling the metabolism of the ancient polymeric form of phosphate, inorganic polyphosphate (polyP). Here we explore the intimate links between phosphate, inositol phosphates and polyP, speculating on the evolution of these relationships. [ABSTRACT FROM AUTHOR]

Published

2016

10. Inositol pyrophosphates: between signalling and metabolism.

Author

WILSON, Miranda S. C., LIVERMORE, Thomas M., and SAIARDI, Adolfo

Subjects

INOSITOL pyrophosphates, CELLULAR signal transduction, METABOLISM, EUKARYOTIC cells, ENZYMES, SACCHAROMYCES cerevisiae

Abstract

The present review will explore the insights gained into inositol pyrophosphates in the 20 years since their discovery in 1993. These molecules are defined by the presence of the characteristic 'high energy' pyrophosphate moiety and can be found ubiquitously in eukaryotic cells. The enzymes that synthesize them are similarly well distributed and can be found encoded in any eukaryote genome. Rapid progress has been made in characterizing inositol pyrophosphate metabolism and they have been linked to a surprisingly diverse range of cellular functions. Two decades of work is now beginning to present a view of inositol pyrophosphates as fundamental, conserved and highly important agents in the regulation of cellular homoeostasis. In particular it is emerging that energy metabolism, and thus ATP production, is closely regulated by these molecules. Much of the early work on these molecules was performed in the yeast Saccharomyces cerevisiae and the social amoeba Dictyostelium discoideum, but the development of mouse knockouts for IP6K1 and IP6K2 [IP6K is IP6 (inositol hexakisphosphate) kinase] in the last 5 years has provided very welcome tools to better understand the physiological roles of inositol pyrophosphates. Another recent innovation has been the use of gel electrophoresis to detect and purify inositol pyrophosphates. Despite the advances that have been made, many aspects of inositol pyrophosphate biology remain far from clear. By evaluating the literature, the present review hopes to promote further research in this absorbing area of biology. [ABSTRACT FROM AUTHOR]

Published

2013

11. Inositol Hexakisphosphate Kinase Products Contain Diphosphate and Triphosphate Groups

Author

Draškovič, Petra, Saiardi, Adolfo, Bhandari, Rashna, Burton, Adam, Ilc, Gregor, Kovačevič, Miroslav, Snyder, Solomon H., and Podobnik, Marjetka

Subjects

*POLYPHOSPHATES, *VITAMIN B complex, *ALCOHOLS (Chemical class), *EUKARYOTIC cells

Abstract

Summary: Eukaryotic cells produce a family of diverse inositol polyphosphates (IPs) containing pyrophosphate bonds. Inositol pyrophosphates have been linked to a wide range of cellular functions, and there is growing evidence that they act as second messengers. Inositol hexakisphosphate kinase (IP6K) is able to convert the natural substrates inositol pentakisphosphate (IP5) and inositol hexakisphosphate (IP6) to several products with an increasing number of phospho-anhydride bonds. In this study, we structurally analyzed IPs synthesized by three mammalian isoforms of IP6K from IP5 and IP6. The NMR and mass analyses showed a number of products with diverse, yet specific, stereochemistry, defined by the architecture of IP6K''s active site. We now report that IP6K synthesizes both pyrophosphate (diphospho) as well as triphospho groups on the inositol ring. All three IP6K isoforms share the same activities both in vitro and in vivo. [Copyright &y& Elsevier]

Published

2008

12. Identification of an Evolutionarily Conserved Family of Inorganic Polyphosphate Endopolyphosphatases.

Author

Lonetti, Annalisa, Szijgyarto, Zsolt, Bosch, Daniel, Loss, Omar, Azevedo, Cristina, and Saiardi, Adolfo

Subjects

*POLYPHOSPHATES, *PHOSPHATES, *EUKARYOTIC cells, *BLOOD coagulation, *ANTICOAGULANTS, *BIOCHEMISTRY, *PHYSIOLOGY, *THERAPEUTICS

Abstract

Inorganic polyphosphate (poly-P) consists of just a chain of phosphate groups linked by high energy bonds. It is found in every organism and is implicated in a wide variety of cellular processes (e.g. phosphate storage, blood coagulation, and pathogenicity). Its metabolism has been studied mainly in bacteria while remaining largely uncharacterized in eukaryotes. It has recently been suggested that poly-P metabolism is connected to that of highly phosphorylated inositol species (inositol pyrophosphates). Inositol pyrophosphates are molecules in which phosphate groups outnumber carbon atoms. Like poly-P they contain high energy bonds and play important roles in cell signaling. Here, we show that budding yeast mutants unable to produce inositol pyrophosphates have undetectable levels of poly-P. Our results suggest a prominent metabolic parallel between these two highly phosphorylated molecules. More importantly, we demonstrate that DDP1, encoding diadenosine and diphosphoinositol phosphohydrolase, possesses a robust poly-P endopolyphosphohydrolase activity. In addition, we prove that this is an evolutionarily conserved feature because mammalian Nudix hydrolase family members, the three Ddp1 homologues in human cells (DIPP1, DIPP2, and DIPP3), are also capable of degrading poly-P. [ABSTRACT FROM AUTHOR]

Published

2011