α6 integrin subunit regulates cerebellar development

Mutations in genes encoding several basal lamina components as well as their cellular receptors disrupt normal deposition and remodeling of the cortical basement membrane resulting in a disorganized cerebral and cerebellar cortex. The α6 integrin was the first α subunit associated with cortical lamination defects and formation of neural ectopias. In order to understand the precise role of α6 integrin in the central nervous system (CNS), we have generated mutant mice carrying specific deletion of α6 integrin in neuronal and glia precursors by crossing α6 conditional knockout mice with Nestin-Cre line. Cerebral cortex development occurred properly in the resulting α6^{fl/fl;nestin-Cre} mutant animals. Interestingly, however, cerebellum displayed foliation pattern defects although granule cell (GC) proliferation and migration were not affected. Intriguingly, analysis of Bergmann glial (BG) scaffold revealed abnormalities in fibers morphology associated with reduced processes outgrowth and altered actin cytoskeleton. Overall, these data show that α6 integrin receptors are required in BG cells to provide a proper fissure formation during cerebellum morphogenesis.     

Stiffness of γ subunit of F1-ATPase

F₁-ATPase is a molecular motor in which the γ subunit rotates inside the α₃β₃ ring upon adenosine triphosphate (ATP) hydrolysis. Recent works on single-molecule manipulation of F₁-ATPase have shown that kinetic parameters such as the on-rate of ATP and the off-rate of adenosine diphosphate (ADP) strongly depend on the rotary angle of the γ subunit (Hirono-Hara et al. 2005; Iko et al. 2009). These findings provide important insight into how individual reaction steps release energy to power F₁ and also have implications regarding ATP synthesis and how reaction steps are reversed upon reverse rotation. An important issue regarding the angular dependence of kinetic parameters is that the angular position of a magnetic bead rotation probe could be larger than the actual position of the γ subunit due to the torsional elasticity of the system. In the present study, we assessed the stiffness of two different portions of F₁ from thermophilic Bacillus PS3: the internal part of the γ subunit embedded in the α₃β₃ ring, and the complex of the external part of the γ subunit and the α₃β₃ ring (and streptavidin and magnetic bead), by comparing rotational fluctuations before and after crosslinkage between the rotor and stator. The torsional stiffnesses of the internal and remaining parts were determined to be around 223 and 73 pNnm/radian, respectively. Based on these values, it was estimated that the actual angular position of the internal part of the γ subunit is one-fourth of the magnetic bead position upon stalling using an external magnetic field. The estimated elasticity also partially explains the accommodation of the intrinsic step size mismatch between F_o and F₁-ATPase.     

Quantitative subunit hybridization of drosophilaα-Glycerophosphate dehydrogenase

Summary The dimeric enzyme,-Glycerophosphate dehydrogenase, was purified from eight Drosophila species by the method of Collier et al. (1976). The enzymes were inactivated at high pH and the conditions sufficient for reactivation were established. Electrophoretic patterns of reactivated-glycerophosphate dehydrogenases which were mixed following inactivation of two species' enzymes, demonstrate that high pH dissociates the enzyme into its constituent subunits and reactivation involves subunit reassociation. Twenty interspecific combinations of dissociated enzymes were allowed to reassociate, and the amounts of both heterospecific and homospecific enzyme activity and protein were determined by densitometry. In all 20 tests there were no differences between observed and expected heterospecific:homospecific enzyme ratios. These results are consistent with the very slow rate of evolution of this enzyme in the family Drosophilidae (Collier and MacIntyre, 1977).     

Regulation of ATP hydrolysis by the ε subunit, ζ subunit and Mg-ADP in the ATP synthase of Paracoccus denitrificans

F₁F_O-ATP synthase is a crucial metabolic enzyme that uses the proton motive force from respiration to regenerate ATP. For maximum thermodynamic efficiency ATP synthesis should be fully reversible, but the enzyme from Paracoccus denitrificans catalyzes ATP hydrolysis at far lower rates than it catalyzes ATP synthesis, an effect often attributed to its unique ζ subunit. Recently, we showed that deleting ζ increases hydrolysis only marginally, indicating that other common inhibitory mechanisms such as inhibition by the C-terminal domain of the ε subunit (ε-CTD) or Mg-ADP may be more important. Here, we created mutants lacking the ε-CTD, and double mutants lacking both the ε-CTD and ζ subunit. No substantial activation of ATP hydrolysis was observed in any of these strains. Instead, hydrolysis in even the double mutant strains could only be activated by oxyanions, the detergent lauryldimethylamine oxide, or a proton motive force, which are all considered to release Mg-ADP inhibition. Our results establish that P. denitrificans ATP synthase is regulated by a combination of the ε and ζ subunits and Mg-ADP inhibition.     

Calcineurin B subunit interacts with proteasome subunit alpha type 7 and represses hypoxia-inducible factor-1α activity via the proteasome pathway

The calcineurin (CN) B subunit (CNB) is the regulatory subunit of CN, which is the only serine/threonine-specific protein phosphatase regulated by Ca²⁺/CaM. It has been shown to have potential as an anticancer agent, and has a positive effect on the phagocytic index and coefficient. We report here that CNB binds to proteasome subunit alpha type 7 (PSMA7) and inhibits the transactivation activity of hypoxia-inducible factor-1α (HIF-1α) via the proteasome pathway. In addition, we show that CNB represses the expression of vascular endothelial growth factor (VEGF), which is regulated by HIF-1α. These results indicate that CNB modulates cellular proteasome activity via a specific interaction with PSMA7. This may provide a molecular basis for its anticancer and antiviral activities.     

Tamm–Horsfall urinary glycoprotein. The subunit structure

1. Subunit molecular weights of 76000-82000 were obtained for native and alkylated Tamm-Horsfall glycoprotein by gel filtration on Sephadex G-200 in the presence of sodium dodecyl sulphate. 2. A further estimate of the subunit molecular weight of 79000+/-4000 was obtained by disc gel electrophoresis in sodium dodecyl sulphate. 3. A minimum value of the chemical molecular weight of 79000+/-6000 was obtained from the number of N-terminal amino acids released by cyanogen bromide cleavage of the glycoprotein. 4. Similar values were obtained for the subunit molecular weight of Tamm-Horsfall glycoprotein from patients with cystic fibrosis. 5. On ultracentrifugation both in 1.0% sodium dodecyl sulphate and in 70% formic acid, Tamm-Horsfall glycoprotein sedimented as a single component, slightly faster than serum albumin. 6. On reduction of the disulphide bonds the same subunit molecular weight was obtained, which suggested that these bonds are intrachain.     

Conformational change of the α subunit of Escherichia coli F1 ATPase: ATP changes the trypsin sensitivity of the subunit

Conformational change in the α subunit of Escherichia coli proton-translocating ATPase was studied using trypsin. The subunit was cleaved with a small amount of trypsin (1 μg/mg subunit) to peptides of less than 8000 daltons. On the other hand, the subunit was cleaved to two main polypeptides (30,000 and 25,000 daltons) in the presence of sufficient ATP (1 mm-0.5 μm) to saturate the high-affinity site of the subunit. Analysis of digests of the subunit combined with fluorescent maleimide suggested that the subunit was digested in the middle of the polypeptide chain in the presence of the nucleotide. ADP and adenylyl imidodiphosphate had the same effect as ATP. These results suggest that the conformation of the subunit changed to form two trypsin-resistant domains upon binding of ATP to the high-affinity site.     

Metformin interacts with AMPK through binding to γ subunit

Metformin acts as an energy regulator by activating 5'-adenosine monophosphate-activated protein kinase (AMPK), which is a key player in the regulation of energy homeostasis, but it is uncertain whether AMPK is its direct target. This study aims to investigate the possible interaction between metformin and AMPK. First, we verified that metformin can promote AMPK activation and induce ACC inactivation in human HepG2 cells using western blot. Then we predicted that metformin may interact with the γ subunit of AMPK by molecular docking analysis. The fluorescence spectrum and ForteBio assays indicated that metformin has a stronger binding ability to the γ subunit of AMPK than to α subunit. In addition, interaction of metformin with γ-AMPK resulted in a decrease in the α-helicity determined by CD spectra, but relatively little change was seen with α-AMPK. These results demonstrate that metformin may interact with AMPK through binding to the γ subunit.     

Is Kir6.1 a subunit of mitoK(ATP)?

The subunit composition of the mitochondrial ATP-sensitive K⁺-channel (mitoK_ATP) is unknown, though some suspect a role for the inward rectifier, Kir6.1, based largely on antibody studies of heart mitochondria. To ascertain the molecular identity of mitoK_ATP we therefore sought to purify this putative mitochondrial Kir6.1, and conclusively identify the subunits by mass spectrometry. Immunoblots, conducted with two commercially available antibodies, revealed two distinct signals in isolated heart mitochondria, of 51 and 48 kDa, respectively. Localization was confirmed by either immuno-gold electron microscopy or by immunofluorescence. Each putative Kir6.1 species was extracted, purified, and identified by LC-MS/MS. The 51 kDa band was identified as NADH-dehydrogenase flavoprotein 1, while the preponderant protein in the 48-kDa band was mitochondrial isocitrate dehydrogenase (NADP form). 1D-, 2D-, and native gel analyses were consistent with these assignments. The data suggest it is premature to assign Kir6.1 a role in mitoK_ATP on the basis of immunoreactivity alone.     

A novel role of proteasomal β1 subunit in tumorigenesis

p27^Kip1 is a key cell-cycle regulator whose level is primarily regulated by the ubiquitin–proteasome degradation pathway. Its β1 subunit is one of seven β subunits that form the β-ring of the 20S proteasome, which is responsible for degradation of ubiquitinated proteins. We report here that the β1 subunit is up-regulated in oesophageal cancer tissues and some ovarian cancer cell lines. It promotes cell growth and migration, as well as colony formation. β1 binds and degrades p27^Kip1directly. Interestingly, the lack of phosphorylation at Ser¹⁵⁸ of the β1 subunit promotes degradation of p27^Kip1. We therefore propose that the β1 subunit plays a novel role in tumorigenesis by degrading p27^Kip1.     

Phylogeny and evolutionary rates of G protein α subunit genes

Summary Rooted phylogenetic trees for a total of 34 genes encoding the stimulatory (s), inhibitory (i), transducin (t), G_x (x), G_z (z), G₁₁ (11), G₁₂ (12), G₁₃ (13), G₁₆ (16), G_q (q), and other (o) G protein a subunits have been constructed. The analysis shows that the G₁₂ (12 and 13), G_q (11, 16, and q), and G_s (s genes) groups form one cluster, and the G_x (x and z genes), G_i (i genes), G_t (t1 and t2), and G_o (o genes) groups form another cluster. During mammalian evolution, the rates of synonymous substitutions for these genes were estimated to be between 1.77 × 10^–9/site/year and 5.63 × 10^–9/site/year, whereas those of nonsynonymous substitutions were between 0.008 × 10^–9/site/year and 0.067 × 10^–9/site/year. These evolutionary rates are similar to those for histone genes, suggesting equally important biological functions of the G protein a subunits. Offprint requests to: S. Yokoyama     

Identification and expression of the medaka inhibin βE subunit

Activin E, a member of the TGF-β super family, is a protein dimer of mature inhibin βE subunits. Recently, it is reported that hepatic activin E may act as a hepatokine that alter whole body energy/glucose metabolism in human. However, orthologues of the activin E gene have yet to be identified in lower vertebrates, including fish. Here, we cloned the medaka (Oryzias latipes) activin E cDNA from liver. Among all the mammalian inhibin β subunits, the mature medaka activin E amino acid sequence shares the highest homology with mammalian activin E. Recombinant expression studies suggest that medaka activin E, the disulfide–bound mature form of mature inhibin βE subunits, may exert its effects in a way similar to that in mammals. Although activin E mRNA is predominantly expressed in liver in mammals, it is ubiquitously expressed in medaka tissues. Since expression in the liver was enhanced after a high fat diet, medaka activin E may be associated with energy/glucose metabolism, as shown in mice and human.

     

Stabilization of the Escherichia coli DNA polymerase III ε subunit by the θ subunit favors in vivo assembly of the Pol III catalytic core

Escherichia coli DNA polymerase III holoenzyme (HE) contains a core polymerase consisting of three subunits: α (polymerase), ε (3'-5' exonuclease), and θ. Genetic experiments suggested that θ subunit stabilizes the intrinsically labile ε subunit and, furthermore, that θ might affect the cellular amounts of Pol III core and HE. Here, we provide biochemical evidence supporting this model by analyzing the amounts of the relevant proteins. First, we show that a ΔholE strain (lacking θ subunit) displays reduced amounts of free ε. We also demonstrate the existence of a dimer of ε, which may be involved in the stabilization of the protein. Second, θ, when overexpressed, dissociates the ε dimer and significantly increases the amount of Pol III core. The stability of ε also depends on cellular chaperones, including DnaK. Here, we report that: (i) temperature shift-up of ΔdnaK strains leads to rapid depletion of ε, and (ii) overproduction of θ overcomes both the depletion of ε and the temperature sensitivity of the strain. Overall, our data suggest that ε is a critical factor in the assembly of Pol III core, and that this is role is strongly influenced by the θ subunit through its prevention of ε degradation.     

Structure of the human protein kinase CK2 catalytic subunit CK2α' and interaction thermodynamics with the regulatory subunit CK2β

Protein kinase CK2 (formerly “casein kinase 2”) is composed of a central dimer of noncatalytic subunits (CK2β) binding two catalytic subunits. In humans, there are two isoforms of the catalytic subunit (and an additional splicing variant), one of which (CK2α) is well characterized. To supplement the limited biochemical knowledge about the second paralog (CK2α′), we developed a well-soluble catalytically active full-length mutant of human CK2α′, characterized it by Michaelis-Menten kinetics and isothermal titration calorimetry, and determined its crystal structure to a resolution of 2 Å. The affinity of CK2α′ for CK2β is about 12 times lower than that of CK2α and is less driven by enthalpy. This result fits the observation that the β4/β5 loop, a key element of the CK2α/CK2β interface, adopts an open conformation in CK2α′, while in CK2α, it opens only after assembly with CK2β. The open β4/β5 loop in CK2α′ is stabilized by two elements that are absent in CK2α: (1) the extension of the N-terminal β-sheet by an additional β-strand, and (2) the filling of a conserved hydrophobic cavity between the β4/β5 loop and helix αC by a tryptophan residue. Moreover, the interdomain hinge region of CK2α′ adopts a fully functional conformation, while unbound CK2α is often found with a nonproductive hinge conformation that is overcome only by CK2β binding. Taken together, CK2α′ exhibits a significantly lower affinity for CK2β than CK2α; moreover, in functionally critical regions, it is less dependent on CK2β to obtain a fully functional conformation.     

Expression,purification, characterization,and deletion mutations of phosphorylase kinase γ subunit: identification of an inhibitory domain in the γ subunit

A catalytic fragment, _1-298, derived from limited chymotryptic digestion of phosphorylaseb kinase (Harris, W.R.et al., J. Biol. Chem., 265: 11740–11745, 1990), is reported to have about six-fold greater specific activity than does the subunit-calmodulin complex. To test whether there is an inhibitory domain located outside the catalytic core of the subunit, full-length wild-type and seven truncated forms of were expressed inE. coli. Recombinant proteins accumulate in the inclusion bodies and can be isolated, solubilized, renatured, and purified further by ammonium sulfate precipitation and Q-Sepharose column. Four out of seven truncated mutants show similar ( _1-353 and _1-341) or less ( _1-331 and _1-276) specific activity than does the full-length wild-type , _1-386. Three truncated forms, _1-316, _1-300, and _1-290 have molar specific activities approximately twice as great as those of the full-length wild-type and the nonactivated holoenzyme. All recombinant s exhibit similarK _m values for both substrates, i.e., about 18M for phosphorylaseb and about 75 M for MgATP. Three truncated s, _1-316, _1-300, and _1-290, have a 1.9- to 2.5-fold greater catalytic efficiency (V _max/K _m) than that of the full-length wild-type and a 3.5- to 4.5-fold greater efficiency than that of the truncated _1-331. This evidence suggests that there is at least one inhibitory domain in the C-terminal region of , which is located at _301-331· _1-290, but not _1-276, which contains the highly conserved kinase domain, is the minimum sequence required for the subunit to exhibit phosphotransferase activity. Both _1-290 and _1-300 have several properties similar to full-length wild-type , including metal ion responses (activation by free Mg²⁺ and inhibition by free Mn²⁺) pH dependency, and substrate specificities.     

The regulatory subunit ε in Escherichia coli FOF1-ATP synthase

F-type ATP synthases are extraordinary multisubunit proteins that operate as nanomotors. The Escherichia coli (E. coli) enzyme uses the proton motive force (pmf) across the bacterial plasma membrane to drive rotation of the central rotor subunits within a stator subunit complex. Through this mechanical rotation, the rotor coordinates three nucleotide binding sites that sequentially catalyze the synthesis of ATP. Moreover, the enzyme can hydrolyze ATP to turn the rotor in the opposite direction and generate pmf. The direction of net catalysis, i.e. synthesis or hydrolysis of ATP, depends on the cell's bioenergetic conditions. Different control mechanisms have been found for ATP synthases in mitochondria, chloroplasts and bacteria. This review discusses the auto-inhibitory behavior of subunit ε found in F_OF₁-ATP synthases of many bacteria. We focus on E. coli F_OF₁-ATP synthase, with insights into the regulatory mechanism of subunit ε arising from structural and biochemical studies complemented by single-molecule microscopy experiments.     

Catalytic properties of β subunit isolated from chloroplast coupling factor 1

The chloroplast coupling factor (CF₁) was dissociated into subunits by the freezing-thawing procedure in the presence of 0.5 M NaBr and the subunit was purified by ion-exchange chromatography on a DEAE-cellulose column. The subunit did not catalyze ATP hydrolysis either in the presence or in the absence of reagents known to activate Mg²⁺-dependent ATPase activity of CF₁. However, it manifested appreciable adenylate kinase-like and ATP-ADP -phosphate exchange activities. The adenylate kinase-like activity only slightly depended on Mg²⁺ ions. Ethanol, and especially diadenosine pentaphosphate, inhibited the reaction effectively. In contrast, the ATP-ADP exchange activity was Mg²⁺-dependent. Ethanol and diadenosine pentaphosphate were poor inhibitors. Sulfite, the CF₁-ATPase activator, and quercetin, its inhibitor, had a minor effect on catalytic activity of the subunit.Abbreviations CF chloroplast coupling factor 1 - RBP carboxylase-ribulose-1,5-bisphosphate carboxylase - TLC thin layer chromatography - MES morpholinoethane sulfonic acid - PMSF phenylmethylsulfonyl fluoride - AP₅A diadenosine pentaphosphate, P¹, P⁵-bis(5-adenosyl)pentaphosphate - DCCD N₁N-dicyclohexylcarbodiimide - SDS sodium dodecylsulfate - PAAG polyacrylamide gel