Your search keyword '"Sasaki, Atsuo T"' showing total 4 results

1. Functional molecular evolution of a GTP sensing kinase: PI5P4Kβ.

Author

Takeuchi, Koh, Senda, Miki, Ikeda, Yoshiki, Okuwaki, Koji, Fukuzawa, Kaori, Nakagawa, So, Sasaki, Mika, Sasaki, Atsuo T., and Senda, Toshiya

Subjects

MOLECULAR evolution, CELL physiology, CHROMOSOME duplication, GUANOSINE triphosphate, MULTICELLULAR organisms, GUANINE

Abstract

Over 4 billion years of evolution, multiple mutations, including nucleotide substitutions, gene and genome duplications and recombination, have established de novo genes that translate into proteins with novel properties essential for high‐order cellular functions. However, molecular processes through which a protein evolutionarily acquires a novel function are mostly speculative. Recently, we have provided evidence for a potential evolutionary mechanism underlying how, in mammalian cells, phosphatidylinositol 5‐phosphate 4‐kinase β (PI5P4Kβ) evolved into a GTP sensor from ATP‐utilizing kinase. Mechanistically, PI5P4Kβ has acquired the guanine efficient association (GEA) motif by mutating its nucleotide base recognition sequence, enabling the evolutionary transition from an ATP‐dependent kinase to a distinct GTP/ATP dual kinase with its KM for GTP falling into physiological GTP concentrations—the genesis of GTP sensing activity. Importantly, the GTP sensing activity of PI5P4Kβ is critical for the manifestation of cellular metabolism and tumourigenic activity in the multicellular organism. The combination of structural, biochemical and biophysical analyses used in our study provides a novel framework for analysing how a protein can evolutionarily acquire a novel activity, which potentially introduces a critical function to the cell. [ABSTRACT FROM AUTHOR]

Published

2023

2. GTP metabolic reprogramming by IMPDH2: unlocking cancer cells' fuelling mechanism.

Author

Kofuji, Satoshi and Sasaki, Atsuo T

Subjects

*CANCER cells, *GUANOSINE triphosphate, *RNA polymerases, *GLIOBLASTOMA multiforme, *FUEL cells

Abstract

Growing cells increase multiple biosynthetic processes in response to the high metabolic demands needed to sustain proliferation. The even higher metabolic requirements in the setting of cancer provoke proportionately greater biosynthesis. Underappreciated key aspects of this increased metabolic demand are guanine nucleotides and adaptive mechanisms to regulate their concentration. Using the malignant brain tumour, glioblastoma, as a model, we have demonstrated that one of the rate-limiting enzymes for guanosine triphosphate (GTP) synthesis, inosine monophosphate dehydrogenase-2 (IMPDH2), is increased and IMPDH2 expression is necessary for the activation of de novo GTP biosynthesis. Moreover, increased IMPDH2 enhances RNA polymerase I and III transcription directly linking GTP metabolism to both anabolic capacity as well as nucleolar enlargement historically observed as associated with cancer. In this review, we will review in detail the basis of these new discoveries and, more generally, summarize the current knowledge on the role of GTP metabolism in cancer. [ABSTRACT FROM AUTHOR]

Published

2020

3. Anti-Tumor Potential of IMP Dehydrogenase Inhibitors: A Century-Long Story.

Author

Naffouje, Rand, Grover, Punita, Yu, Hongyang, Sendilnathan, Arun, Wolfe, Kara, Majd, Nazanin, Smith, Eric P., Takeuchi, Koh, Senda, Toshiya, Kofuji, Satoshi, and Sasaki, Atsuo T.

Subjects

PURINE metabolism, ANTINEOPLASTIC agents, MOLECULAR structure, OXIDOREDUCTASES, MYCOPHENOLIC acid, CHEMICAL inhibitors

Abstract

The purine nucleotides ATP and GTP are essential precursors to DNA and RNA synthesis and fundamental for energy metabolism. Although de novo purine nucleotide biosynthesis is increased in highly proliferating cells, such as malignant tumors, it is not clear if this is merely a secondary manifestation of increased cell proliferation. Suggestive of a direct causative effect includes evidence that, in some cancer types, the rate-limiting enzyme in de novo GTP biosynthesis, inosine monophosphate dehydrogenase (IMPDH), is upregulated and that the IMPDH inhibitor, mycophenolic acid (MPA), possesses anti-tumor activity. However, historically, enthusiasm for employing IMPDH inhibitors in cancer treatment has been mitigated by their adverse effects at high treatment doses and variable response. Recent advances in our understanding of the mechanistic role of IMPDH in tumorigenesis and cancer progression, as well as the development of IMPDH inhibitors with selective actions on GTP synthesis, have prompted a reappraisal of targeting this enzyme for anti-cancer treatment. In this review, we summarize the history of IMPDH inhibitors, the development of new inhibitors as anti-cancer drugs, and future directions and strategies to overcome existing challenges. [ABSTRACT FROM AUTHOR]

Published

2019

4. The GTP responsiveness of PI5P4Kβ evolved from a compromised trade-off between activity and specificity.

Author

Takeuchi, Koh, Ikeda, Yoshiki, Senda, Miki, Harada, Ayaka, Okuwaki, Koji, Fukuzawa, Kaori, Nakagawa, So, Yu, Hong Yang, Nagase, Lisa, Imai, Misaki, Sasaki, Mika, Lo, Yu-Hua, Ito, Doshun, Osaka, Natsuki, Fujii, Yuki, Sasaki, Atsuo T., and Senda, Toshiya

Subjects

*G proteins, *G protein coupled receptors, *GUANINE, *KINASES, *CELL growth, *ADENINE, *DATA analysis

Abstract

Unlike most kinases, phosphatidylinositol 5-phosphate 4-kinase β (PI5P4Kβ) utilizes GTP as a physiological phosphate donor and regulates cell growth under stress (i.e., GTP-dependent stress resilience). However, the genesis and evolution of its GTP responsiveness remain unknown. Here, we reveal that PI5P4Kβ has acquired GTP preference by generating a short dual-nucleotide-recognizing motif called the guanine efficient association (GEA) motif. Comparison of nucleobase recognition with 660 kinases and 128 G proteins has uncovered that most kinases and PI5P4Kβ use their main-chain atoms for adenine recognition, while the side-chain atoms are required for guanine recognition. Mutational analysis of the GEA motif revealed that the acquisition of GTP reactivity is accompanied by an extended activity toward inosine triphosphate (ITP) and xanthosine triphosphate (XTP). Along with the evolutionary analysis data that point to strong negative selection of the GEA motif, these results suggest that the GTP responsiveness of PI5P4Kβ has evolved from a compromised trade-off between activity and specificity, underpinning the development of the GTP-dependent stress resilience. [Display omitted] • GTP sensing of PI5P4Kβ is enabled by the dual ATP/GTP-recognizing GEA motif • As in kinases, the main-chain atoms of the GEA motif contribute to adenine binding • Similar to G proteins, the side-chain atoms are required for guanine recognition • We propose an evolutionary path for how PI5P4Kβ became a GTP-sensing kinase PI5P4Kβ is a unique GTP-utilizing kinase that functions as an intracellular GTP sensor. Takeuchi et al. show that GTP binding requires the GTP/ATP dual recognition motif, named GEA, which emerged in a vertebrate. Further analyses reveal that limited substitutions in the GEA motif turned PI5P4Kβ into an unusual GTP-utilizing kinase. [ABSTRACT FROM AUTHOR]

Published

2022