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Subunit Interactions in the Inducible Arginine Decarboxylase from Escherichia Coli BDepusoy, Catalina N. 01 May 1983 (has links)
The nature of the subunit interactions in the inducible arginine decarboxylase from Escherichia coli B is of considerable interest because of the observed differences in the catalytic activities of the dimer and the decamer; the decamer is active and the dimer is inactive. To study these interactions, inactive dimers were prepared by sodium borohydride reduction of the E-amino--pyridoxal-P Schiff base. Hybrid decamers were then prepared from varying molar ratios of native and reduced dimers. The hybrid decamers were indistinguishable from native decamers as observed in the analytical ultracentrifuge and on acrylamide gel electrophoresis. Kinetic studies indicated that true hybrids were formed rather than mixtures of all-native and all-reduced decamers. Results obtained with the decamers containing 1, 2, 3, or 4 parts in 5 of reduced enzyme showed no significant changes in Km values from the native decamer. However, the Vm values for these hybrids are greater than predicted from the mole fraction of active dimers. For example, the hybrid containing 20% reduced enzyme approaches the Vm of the native decamer. These observations suggest that, in the intact molecule, two active sites cooperate catalytically but only one is catalytically active.
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Structure and function of AMPK: subunit interactions of the AMPK heterotrimeric complexIseli, Tristan J. Unknown Date (has links) (PDF)
AMP-activated protein kinase (AMPK) is an important metabolic stress-sensing protein kinase responsible for regulating metabolism in response to changing energy demand and nutrient supply. Mammalian AMPK is a stable aß? heterotrimer comprising a catalytic a subunit and two non-catalytic subunits, ß and ?. The ß subunit targets AMPK to membranes via an N-terminal myristoyl group and to glycogen via a mid-molecule glycogen-binding domain. Here I show that the conserved C-terminal 85-residue sequence of the ß subunit, ß1(186-270), is sufficient to form an active AMP-dependent heterotrimer a1ß1(186-270)?1, whereas the 25-residue ß1 C-terminal (246-270) sequence is sufficient to bind ?1, ?2, or ?3 but not the a subunit. Within this sequence (246-270), two residues were essential for ß? association based on Ala scanning mutagenesis. / Substitution of ß1 Tyr-267 for Ala precludes ß? but not aß association suggesting independent binding requirements. Substitution of Tyr-267 for Phe or His but not Ala or Ser can rescue ß? binding. Substitution of Thr-263 for Ala also resulted in decreased ß? but not aß association. Truncation of the a subunit reveals that ß1 binding requires the a1(313-473) sequence while the remainder of the a C-terminus is required for ? binding. The conserved C-terminal 85-residue sequence of the ß subunit (90% between ß1 and ß2) is the primary a? binding sequence responsible for the formation of the AMPK aß? heterotrimer. The ? subunits contain four repeat CBS sequences with variable N-terminal extensions and the ?1 isoform is N-terminally acetylated. The ?2 subunit can be multiply phosphorylated by protein kinase C (PKC) in vitro, with Ser-32 identified as a minor site. A detailed understanding of the structure and regulation of AMPK will enable rational drug design for treatment of such linked diseases as obesity, insulin resistance and type 2 diabetes.
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Structure and function of AMPK: subunit interactions of the AMPK heterotrimeric complexIseli, Tristan J. Unknown Date (has links) (PDF)
AMP-activated protein kinase (AMPK) is an important metabolic stress-sensing protein kinase responsible for regulating metabolism in response to changing energy demand and nutrient supply. Mammalian AMPK is a stable aß? heterotrimer comprising a catalytic a subunit and two non-catalytic subunits, ß and ?. The ß subunit targets AMPK to membranes via an N-terminal myristoyl group and to glycogen via a mid-molecule glycogen-binding domain. Here I show that the conserved C-terminal 85-residue sequence of the ß subunit, ß1(186-270), is sufficient to form an active AMP-dependent heterotrimer a1ß1(186-270)?1, whereas the 25-residue ß1 C-terminal (246-270) sequence is sufficient to bind ?1, ?2, or ?3 but not the a subunit. Within this sequence (246-270), two residues were essential for ß? association based on Ala scanning mutagenesis. / Substitution of ß1 Tyr-267 for Ala precludes ß? but not aß association suggesting independent binding requirements. Substitution of Tyr-267 for Phe or His but not Ala or Ser can rescue ß? binding. Substitution of Thr-263 for Ala also resulted in decreased ß? but not aß association. Truncation of the a subunit reveals that ß1 binding requires the a1(313-473) sequence while the remainder of the a C-terminus is required for ? binding. The conserved C-terminal 85-residue sequence of the ß subunit (90% between ß1 and ß2) is the primary a? binding sequence responsible for the formation of the AMPK aß? heterotrimer. The ? subunits contain four repeat CBS sequences with variable N-terminal extensions and the ?1 isoform is N-terminally acetylated. The ?2 subunit can be multiply phosphorylated by protein kinase C (PKC) in vitro, with Ser-32 identified as a minor site. A detailed understanding of the structure and regulation of AMPK will enable rational drug design for treatment of such linked diseases as obesity, insulin resistance and type 2 diabetes.
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