Comparative study of catalase-peroxidases (KatGs)

Catalase-peroxidases or KatGs from seven different organisms, including Archaeoglobus fulgidus,Bacillus stearothermophilus, Burkholderia pseudomallei, Escherichia coli, Mycobacterium tuberculosis, Rhodobacter capsulatus and Synechocystis PCC 6803, have been characterized to provide a comparative picture of their respective properties. Collectively, the enzymes exhibit similar turnover rates with the catalase and peroxidase reactions varying between 4900 and 15,900 s⁻¹ and 8-25 s⁻¹, respectively. The seven enzymes also exhibited similar pH optima for the peroxidase (4.25-5.0) and catalase reactions (5.75), and high sensitivity to azide and cyanide with IC₅₀ values of 0.2-20 μM and 50-170 μM, respectively. The K_Ms of the enzymes for H₂O₂ in the catalase reaction were relatively invariant between 3 and 5 mM at pH 7.0, but increased to values ranging from 20 to 225 mM at pH 5, consistent with protonation of the distal histidine (pKa approximately 6.2) interfering with H₂O₂ binding to Cpd I. The catalatic k_cat was 2- to 3-fold higher at pH 5 compared to pH 7, consistent with the uptake of a proton being involved in the reduction of Cpd I. The turnover rates for the INH lyase and isonicotinoyl-NAD synthase reactions, responsible for the activation of isoniazid as an anti-tubercular drug, were also similar across the seven enzymes, but considerably slower, at 0.5 and 0.002 s⁻¹, respectively. Only the NADH oxidase reaction varied more widely between 10⁻⁴ and 10⁻² s⁻¹ with the fastest rate being exhibited by the enzyme from B. pseudomallei.     

Purification and characterization of Mycobacterium tuberculosis KatG, KatG(S315T), and Mycobacterium bovis KatG(R463L)

Isoniazid, a first-line antibiotic used for the treatment of tuberculosis, is a prodrug that requires activation by the Mycobacterium tuberculosis enzyme KatG. The KatG(S315T) mutation causes isoniazid resistance while the KatG(R463L) variation is thought to be a polymorphism. Much of the work to date focused on isoniazid activation by KatG has utilized recombinant enzyme overexpressed in Escherichia coli. In this work, native KatG and KatG(S315T) were purified from M. tuberculosis, and KatG(R463L) was purified from Mycobacterium bovis. The native molecular weight, enzymatic activity, optical, resonance Raman, and EPR spectra, K(D) for isoniazid binding, and isoniazid oxidation rates were measured and compared for each native enzyme. Further, the properties of the native enzymes were compared and contrasted with those reported for recombinant KatG, KatG(S315T), and KatG(R463L) in order to assess the ability of the recombinant enzymes to act as good models for the native enzymes.     

Role of the Met-Tyr-Trp cross-link in Mycobacterium tuberculosis catalase-peroxidase (KatG) as revealed by KatG(M255I)

Catalase-peroxidases (KatGs) are bifunctional enzymes possessing both catalase and peroxidase activities. Four crystal structures of different KatGs revealed the presence of a novel Met-Tyr-Trp cross-link which has been suggested to impart catalatic activity to the KatGs. To decipher the individual roles of the two cross-links in the Met-Tyr-Trp adduct, we have focused on recombinant Mycobacterium tuberculosis KatG(M255I). UV-visible spectroscopic and mass spectrometric studies of the peptide fragments resulting from tryptic digestion of KatG(M255I) confirmed the presence of the single Tyr-Trp cross-link, as well as a 2e- oxidized form which is postulated to be an intermediate generated during Met-Tyr-Trp cross-link formation. KatG(M255I) lacking the Tyr-Trp cross-link was also prepared, and incubation with peroxyacetic acid, but not 2-methyl-1-phenyl-2-propyl hydroperoxide, resulted in complete formation of the Tyr-Trp cross-link. A mechanism for Tyr-Trp autocatalytic formation by KatG compound I is proposed from these studies. Optical stopped-flow studies with KatG(M255I) were performed, allowing characterization of compounds I, II, and III. Interestingly, two compound II intermediates were identified: (KatG*)(Por)Fe(III)-OH, where KatG* represents a protein-based radical, and oxoferryl (KatG)(Por)Fe(IV)=O. Insight into the contributions of the individual Tyr-Trp and Met-Tyr cross-links to catalase activity is presented, as is the overall contribution of the Met-Tyr-Trp cross-link to the structure-function-spectroscopy relationship and catalase-peroxidase mechanism in KatG.     

Catalase-peroxidases (KatG) exhibit NADH oxidase activity

Catalase-peroxidases (KatG) produced by Burkholderia pseudomallei, Escherichia coli, and Mycobacterium tuberculosis catalyze the oxidation of NADH to form NAD+ and either H2O2 or superoxide radical depending on pH. The NADH oxidase reaction requires molecular oxygen, does not require hydrogen peroxide, is not inhibited by superoxide dismutase or catalase, and has a pH optimum of 8.75, clearly differentiating it from the peroxidase and catalase reactions with pH optima of 5.5 and 6.5, respectively, and from the NADH peroxidase-oxidase reaction of horseradish peroxidase. B. pseudomallei KatG has a relatively high affinity for NADH (Km=12 microm), but the oxidase reaction is slow (kcat=0.54 min(-1)) compared with the peroxidase and catalase reactions. The catalase-peroxidases also catalyze the hydrazinolysis of isonicotinic acid hydrazide (INH) in an oxygen- and H2O2-independent reaction, and KatG-dependent radical generation from a mixture of NADH and INH is two to three times faster than the combined rates of separate reactions with NADH and INH alone. The major products from the coupled reaction, identified by high pressure liquid chromatography fractionation and mass spectrometry, are NAD+ and isonicotinoyl-NAD, the activated form of isoniazid that inhibits mycolic acid synthesis in M. tuberculosis. Isonicotinoyl-NAD synthesis from a mixture of NAD+ and INH is KatG-dependent and is activated by manganese ion. M. tuberculosis KatG catalyzes isonicotinoyl-NAD formation from NAD+ and INH more efficiently than B. pseudomallei KatG.     

Redox thermodynamics of the ferric-ferrous couple of wild-type synechocystis KatG and KatG(Y249F)

Crystal structures and mass spectrometric analyses of catalase-peroxidases (KatGs) from different organisms revealed the existence of a peculiar distal Met-Tyr-Trp cross-link. The adduct appears to be important for the catalase but not the peroxidase activity of bifunctional KatG. To examine the effect of the adduct on enzyme redox properties and functions, we have determined the thermodynamics of ferric reduction for wild-type KatG and KatG(Y249F), whose tyrosine-to-phenylalanine mutation prevents cross-link formation. At 25 degrees C and pH 7.0, the reduction potential of wild-type KatG is found to be -226 +/- 10 mV, remarkably lower than the published literature values. The reduction potential of KatG(Y249F) is very similar (-222 +/- 10 mV), but variable temperature experiments revealed compensatory differences in reduction enthalpies and entropies. In both proteins, the oxidized state is enthalpically stabilized over the reduced state, but entropy is lost on reduction, which is in strong contrast to horseradish peroxidase, which also features a much more pronounced enthalpic stabilization of the ferriheme. With both proteins, the midpoint potential increased linearly with decreasing pH. We discuss whether the observed redox thermodynamics reflects the differences in structure and function between bifunctional KatG and monofunctional peroxidases.     

Intracellular targeting of the proteasome

Proteasomes are soluble, but can also be found in association with subcellular organelles. Adaptors capable of mediating interactions between proteasomes and intracellular organelles have not yet been identified, although they might exist. Although most proteasomal substrates are soluble, some membrane-bound proteins are also degraded by the proteasome. Processing of such insoluble substrates might cause proteasomes to be organelle-bound by tethering the degradative apparatus to the organelle.     

Probing the structure and bifunctionality of catalase-peroxidase (KatG)

Catalase-peroxidases (KatGs) exhibit peroxidase and substantial catalase activities similar to monofunctional catalases. Crystal structures of four different KatGs reveal the presence of a peroxidase-conserved proximal and distal heme pocket together with features unique to KatG. To gain insight into their structure-function properties, many variants were produced and very similar results were obtained irrespective of the origin of the KatG mutated. This review focuses mainly on the electronic absorption and resonance Raman results together with the combined analysis of pre-steady and steady-state kinetics of various mutants involving both the peroxidase-conserved and the KatG-specific residues of recombinant KatG from the cyanobacterium Synechocystis. Marked differences in the structural role of conserved amino acids and hydrogen-bond networks in KatG with respect to the other plant peroxidases were found. Typically, the catalatic but not the peroxidatic activity was very sensitive to mutations that disrupted the KatG-typical extensive hydrogen-bonding network. Moreover, the integrity of this network is crucial for the formation of distinct protein radicals formed upon incubation of KatG with peroxides in the absence of one-electron donors. The correlation between the structural architecture and the bifunctional activity is discussed and compared with data obtained for KatGs from other organisms.     

Cell biology of the human thiamine transporter-1 (hTHTR1). Intracellular trafficking and membrane targeting mechanisms

The human thiamine transporter hTHTR1 is involved in the cellular accumulation of thiamine (vitamin B1) in many tissues. Thiamine deficiency disorders, such as thiamine-responsive megaloblastic anemia (TRMA), which is associated with specific mutations within hTHTR1, likely impairs the functionality and/or intracellular targeting of hTHTR1. Unfortunately, nothing is known about the mechanisms that control the intracellular trafficking or membrane targeting of hTHTR1. To identify molecular determinants involved in hTHTR1 targeting, we generated a series of hTHTR1 truncations fused with the green fluorescent protein and imaged the targeting and trafficking dynamics of each construct in living duodenal epithelial cells. Whereas the full-length fusion protein was functionally expressed at the plasma membrane, analysis of the truncated mutants demonstrated an essential role for both NH(2)-terminal sequence and the integrity of the backbone polypeptide for cell surface expression. Most notably, truncation of hTHTR1 within a region where several TRMA truncations are clustered resulted in intracellular retention of the mutant protein. Finally, confocal imaging of the dynamics of intracellular hTHTR1 vesicles revealed a critical role for microtubules, but not microfilaments, in hTHTR1 trafficking. Taken together, these results correlate hTHTR1 structure with cellular expression profile and reveal a critical dependence on hTHTR1 backbone integrity and microtubule-based trafficking processes for functional expression of hTHTR1.     

Catalase-peroxidase (Mycobacterium tuberculosis KatG) catalysis and isoniazid activation

Resonance Raman spectra of native, overexpressed M. tuberculosis catalase-peroxidase (KatG), the enzyme responsible for activation of the antituberculosis antibiotic isoniazid (isonicotinic acid hydrazide), have confirmed that the heme iron in the resting (ferric) enzyme is high-spin five-coordinate. Difference Raman spectra did not reveal a change in coordination number upon binding of isoniazid to KatG. Stopped-flow spectrophotometric studies of the reaction of KatG with stoichiometric equivalents or small excesses of hydrogen peroxide revealed only the optical spectrum of the ferric enzyme with no hypervalent iron intermediates detected. Large excesses of hydrogen peroxide generated oxyferrous KatG, which was unstable and rapidly decayed to the ferric enzyme. Formation of a pseudo-stable intermediate sharing optical characteristics with the porphyrin pi-cation radical-ferryl iron species (Compound I) of horseradish peroxidase was observed upon reaction of KatG with excess 3-chloroperoxybenzoic acid, peroxyacetic acid, or tert-butylhydroperoxide (apparent second-order rate constants of 3.1 x 10(4), 1.2 x 10(4), and 25 M(-1) s(-1), respectively). Identification of the intermediate as KatG Compound I was confirmed using low-temperature electron paramagnetic resonance spectroscopy. Isoniazid, as well as ascorbate and potassium ferrocyanide, reduced KatG Compound I to the ferric enzyme without detectable formation of Compound II in stopped-flow measurements. This result differed from the reaction of horseradish peroxidase Compound I with isoniazid, during which Compound II was stably generated. These results demonstrate important mechanistic differences between a bacterial catalase-peroxidase and the homologous plant peroxidases and yeast cytochrome c peroxidase, in its reactions with peroxides as well as substrates.     

Carbon monoxide adducts of KatG and KatG(S315T) as probes of the heme site and isoniazid binding

KatG, the catalase peroxidase from Mycobacterium tuberculosis, is important in the activation of the antitubercular drug, isoniazid. About 50% of isoniazid-resistant clinical isolates contain a mutation in KatG wherein the serine at position 315 is substituted with threonine, KatG(S315T). The heme pockets of KatG and KatG(S315T) and their interactions with isoniazid are probed using resonance Raman (rR) spectroscopy to characterize their ferrous CO complexes. Three vibrational modes, C-O and Fe-C stretching and Fe-CO bending, are assigned using 12CO and 13CO isotope shifts. Two conformers are observed for KatG-CO and KatG(S315T)-CO. Resonance Raman features assigned to form I are consistent with it having a neutral proximal histidine ligand and the Fe-C-O moiety hydrogen bonded to a distal residue. The nu(C-O) band for form I is sharp, consistent with a conformationally homogeneous Fe-CO unit. Form II also has a neutral proximal histidine ligand but is not hydrogen bonded. This appears to result in a conformationally disordered Fe-CO unit, as evidenced by a comparatively broad C-O stretching band. The 13CO-sensitive bands assigned to form II are predominant in the KatG(S315T)-CO rR spectrum. Isoniazid binding is apparent from the resonance Raman signatures of both WT KatG-CO and KatG(S315T)-CO. Moreover, isoniazid binding elicits an increase in the form I population of wild-type KatG-CO while having little, if any, effect on the already low population of form I of KatG(S315T)-CO. Since oxyKatG (compound III) also contains a low-spin diatomic ligand-heme adduct (heme-O2), it is reasonable to suggest that it too would exist as a mixture of conformers. Because the small form I population of KatG(S315T)-CO correlates with its inability to activate INH, we hypothesize that form I plays a role in INH activation.     

Analysis of heme structural heterogeneity in Mycobacterium tuberculosis catalase-peroxidase (KatG)

Mycobacterium tuberculosis catalase-peroxidase (KatG) is a heme enzyme considered important for virulence, which is also responsible for activation of the anti-tuberculosis pro-drug isoniazid. Here, we present an analysis of heterogeneity in KatG heme structure using optical, resonance Raman, and EPR spectroscopy. Examination of ferric KatG under a variety of conditions, including enzyme in the presence of fluoride, chloride, or isoniazid, and at different stages during purification in different buffers allowed for assignment of spectral features to both five- and six-coordinate heme. Five-coordinate heme is suggested to be representative of "native" enzyme, since this species was predominant in the enzyme examined immediately after one chromatographic protocol. Quantum mechanically mixed spin heme is the most abundant form in such partially purified enzyme. Reduction and reoxidation of six-coordinate KatG or the addition of glycerol or isoniazid restored five-coordinate heme iron, consistent with displacement of a weakly bound distal water molecule. The rate of formation of KatG Compound I is not retarded by the presence of six-coordinate heme either in wild-type KatG or in a mutant (KatG[Y155S]) associated with isoniazid resistance, which contains abundant six-coordinate heme. These results reveal a number of similarities and differences between KatG and other Class I peroxidases.     

Intracellular targeting of isoproteins in muscle cytoarchitecture

Part of the muscle creatine kinase (MM-CK) in skeletal muscle of chicken is localized in the M-band of myofibrils, while chicken heart cells containing myofibrils and BB-CK, but not expressing MM-CK, do not show this association. The specificity of the MM-CK interaction was tested using cultured chicken heart cells as "living test tubes" by microinjection of in vitro generated MM-CK and hybrid M-CK/B-CK mRNA with SP6 RNA polymerase. The resulting translation products were detected in injected cells with isoprotein-specific antibodies. M-CK molecules and translation products of chimeric cDNA molecules containing the head half of the B-CK and the tail half of the M-CK coding regions were localized in the M-band of the myofibrils. The tail, but not the head portion of M-CK is essential for the association of M-CK with the M-band of myofibrils. We conclude that gross biochemical properties do not always coincide with a molecule's specific functions like the participation in cell cytoarchitecture which may depend on molecular targeting even within the same cellular compartment.     

Evidence for isoniazid-dependent free radical generation catalyzed by Mycobacterium tuberculosis KatG and the isoniazid-resistant mutant KatG(S315T)

The antitubercular agent isoniazid can be activated by Mycobacterium tuberculosis KatG using either a peroxidase compound I/II or a superoxide-dependent oxyferrous pathway. The identity of activated isoniazid is unknown, but it has been suggested that it may be a free radical intermediate. In this work, EPR spin trapping experiments detected isoniazid-derived radicals generated during KatG-mediated oxidation via the peroxidase compound I/II pathway. On the basis of hyperfine splitting patterns and oxygen dependence, these radicals were identified as the acyl, acyl peroxo, and pyridyl radicals of isoniazid. Isoniazid-resistant KatG(S315T) produced the same radicals found with KatG, while the less potent antitubercular agent nicotinic acid hydrazide produced the corresponding nicotinyl radicals. The time course of radical production was similar for KatG and KatG(S315T), while a lower steady-state level of radicals was produced from nicotinic acid hydrazide. These results support an earlier finding that the peroxidase pathway does not correlate with isoniazid resistance conferred by KatG(S315T). Trace amounts of radicals were detected via the superoxide-dependent pathway. The low level of isoniazid-derived radicals found in the superoxide-dependent pathway may be due to scavenging by superoxide.     

Intracellular targeting of proteins by sumoylation.

A novel host cell posttranslational modification system, termed sumoylation, has recently been characterized. Sumoylation is an enzymatic process that is biochemically analogous to, but functionally distinct from, ubiquitinylation. As in ubiquitinylation, sumoylation involves the covalent attachment of a small protein moiety, SUMO, to substrate proteins. However, conjugation of SUMO does not typically lead to degradation of the substrate and instead has a more diverse array of effects on substrate function. As the list of sumoylation substrates has expanded, a common theme is that many substrates exhibit sumoylation-dependent subcellular distribution. While the molecular mechanisms by which sumoylation targets protein localization are still poorly understood, it is clear that this modification system is an important regulator of intracellular protein localization, particularly involving nuclear uptake and punctate intranuclear accumulation.     

Intracellular and oligomeric forms of surfactant-associated apolipoproteins(s) A in the rat

Sulfhydryl-dependent oligomeric forms of the surfactant-associated apolipoprotein(s) A, obtained from particulate preparations of adult rat lung lavage, were characterized by immunoblot analysis and by silver staining of proteins separated by one- and two-dimensional SDS-polyacrylamide gel electrophoresis. Under non-reducing conditions, these proteins migrated as oligomers, Mr approx. 50-70, 115, 160 kDa and greater. The large oligomers were reduced to the apolipoprotein(s) A subunits by treatment with beta-mercaptoethanol; Mr 38 (A3), 32 (A2) and 26 kDa (A1), pI 4.2-4.8. Mr 50 kDa protein was composed of sulfhydryl-dependent homo-dimers of protein(s) A1 (Mr 26 kDa). 55 kDa protein was a hetero-dimer composed primarily of A1 and A2 (Mr 26 and 32 kDa). 62 kDa protein was composed of hetero-dimers of A3 and apolipoprotein A2 (Mr 38 and 32 kDa). 70 kDa protein was a homodimer composed of apolipoprotein A3 A3 (38 kDa). Larger molecular forms were composed primarily of 38 and 32 kDa and lesser amounts of 26 kDa. Treatment with endoglycosidase F reduced A2 and A3 to 26 kDa. Apolipoprotein A1 co-migrated with a protein of Mr 26 kDa immunoprecipitated from [35S]methionine-labelled Type II epithelial cells. Chymotryptic-tryptic peptide maps of apolipoproteins A1, A2 and A3 were identical, suggesting that apolipoproteins A3 and A2 arise through extensive glycosylation of apolipoprotein A1.     

Developmental Changes in Rat Liver Xanthine Oxidase(s) and Its Intracellular Distribution

Developmental change and subcellular distribution of xanthine oxidase in the rat liver were examined.

The specific activity of the fetal liver xanthine oxidase increased sharply to the levels of the adult liver on the day of the birth. After birth, the activity dropped rapidly and on the 14th day after birth it was about 1/4 of adult level. Then the activity was regained and around 28th day after birth it was about the same as in adult level.

In the livers from 80 days old rats, about 60% of total xanthine oxidase activity was found in soluble fraction and the rest was distributed among particulate fractions including microsomal, lysosomal, mitochondrial and nuclear fractions.

In contrast to the adult livers 80% of total xanthine oxidase activity in fetal liver was found to be in particulate fractions.

From kinetic studies of xanthine oxidases in particulate and soluble fractions it was suggested that xanthine oxidase in soluble fraction and xanthine oxidase in particulate fraction might be different in their natures of protein molecule.     

Intracellular cannabinoid type 1 (CB1) receptors are activated by anandamide

Recent studies have demonstrated that the majority of endogenous cannabinoid type 1 (CB(1)) receptors do not reach the cell surface but are instead associated with endosomal and lysosomal compartments. Using calcium imaging and intracellular microinjection in CB(1) receptor-transfected HEK293 cells and NG108-15 neuroblastoma × glioma cells, we provide evidence that anandamide acting on CB(1) receptors increases intracellular calcium concentration when administered intracellularly but not extracellularly. The calcium-mobilizing effect of intracellular anandamide was dose-dependent and abolished by pretreatment with SR141716A, a CB(1) receptor antagonist. The anandamide-induced calcium increase was reduced by blocking nicotinic acid-adenine dinucleotide phosphate- or inositol 1,4,5-trisphosphate-dependent calcium release and abolished when both lysosomal and endoplasmic reticulum calcium release pathways were blocked. Taken together, our results indicate that, in CB(1) receptor-transfected HEK293 cells, intracellular CB(1) receptors are functional; they are located in acid-filled calcium stores (endolysosomes). Activation of intracellular CB(1) receptors releases calcium from endoplasmic reticulum and lysosomal calcium stores. In addition, our results support a novel role for nicotinic acid-adenine dinucleotide phosphate in cannabinoid-induced calcium signaling.     

Intracellular fate and nuclear targeting of plasmid DNA

One of the major steps limiting nonviral gene transfer efficiency is the entry of plasmid DNA from the cytoplasm into the nucleus of the transfected cells. The nuclear localization signal (NLS) of the SV40 large T antigen is known to efficiently induce nuclear targeting of proteins. We have developed two chemical strategies for covalent coupling of NLS peptides to plasmid DNA. One method involves a site-specific labeling of plasmid DNA by formation of a triple helix with an oligonucleotide–NLS peptide conjugate. After such modification with one NLS peptide per plasmid molecule, plasmid DNA remained fully active in cationic lipid-mediated transfection. In the other method, we randomly coupled 5–115 p-azidotetrafluorobenzyllissamine–NLS peptide molecules per plasmid DNA by photoactivation. Oligonucleotide–NLS and plasmid–lissamine–NLS conjugates interacted specifically with the NLS-receptor importin . Plasmid–lissamine–NLS conjugates were not detected in the nucleus, after cytoplasmic microinjection. Plasmids did not diffuse from the site of injection and plasmid–lissamine–NLS conjugates appeared to be progressively degraded in the cytoplasm. The process of plasmid DNA sequestration/degradation stressed in this study might be as important in limiting the efficiency of nonviral gene transfer as the generally recognized entry step of plasmid DNA from the cytoplasm into the nucleus     

Redox potential measurements of the Mycobacterium tuberculosis heme protein KatG and the isoniazid-resistant enzyme KatG(S315T): insights into isoniazid activation

Mycobacterium tuberculosis KatG is a multifunctional heme enzyme responsible for activation of the antibiotic isoniazid. A KatG(S315T) point mutation is found in >50% of isoniazid-resistant clinical isolates. Since isoniazid activation is thought to involve an oxidation reaction, the redox potential of KatG was determined using cyclic voltammetry, square wave voltammetry, and spectroelectrochemical titrations. Isoniazid activation may proceed via a cytochrome P450-like mechanism. Therefore, the possibility that substrate binding by KatG leads to an increase in the heme redox potential and the possibility that KatG(S315T) confers isoniazid resistance by altering the redox potential were examined. Effects of the heme spin state on the reduction potentials of KatG and KatG(S315T) were also determined. Assessment of the Fe(3+)/Fe(2+) couple gave a midpoint potential of ca. -50 mV for both KatG and KatG(S315T). In contrast to cytochrome P450s, addition of substrate had no significant effect on either the KatG or KatG(S315T) redox potential. Conversion of the heme to a low-spin configuration resulted in a -150 to -200 mV shift of the KatG and KatG(S315T) redox potentials. These results suggest that isoniazid resistance conferred by KatG(S315T) is not mediated through changes in the heme redox potential. The redox potentials of isoniazid were also determined using cyclic and square wave voltammetry, and the results provide evidence that the ferric KatG and KatG(S315T) midpoint potentials are too low to promote isoniazid oxidation without formation of a high-valent enzyme intermediate such as compounds I and II or oxyferrous KatG.     

Intracellular targeting of the insulin-regulatable glucose transporter (GLUT4) is isoform specific and independent of cell type

Insulin stimulates glucose transport in adipocytes via the rapid redistribution of the GLUT1 and GLUT4 glucose transporters from intracellular membrane compartments to the cell surface. Insulin sensitivity is dependent on the proper intracellular trafficking of the glucose transporters in the basal state. The bulk of insulin-sensitive transport in adipocytes appears to be due to the translocation of GLUT4, which is more efficiently sequestered inside the cell and is present in much greater abundance than GLUT1. The cell type and isoform specificity of GLUT4 intracellular targeting were investigated by examining the subcellular distribution of GLUT1 and GLUT4 in cell types that are refractory to the effect of insulin on glucose transport. Rat GLUT4 was expressed in 3T3-L1 fibroblasts and HepG2 hepatoma cells by DNA-mediated transfection. Transfected 3T3-L1 fibroblasts over-expressing human GLUT1 exhibited increased glucose transport, and laser confocal immunofluorescent imaging of GLUT1 in these cells indicated that the protein was concentrated in the plasma membrane. In contrast, 3T3-L1 fibroblasts expressing GLUT4 exhibited no increase in transport activity, and confocal imaging demonstrated that this protein was targeted almost exclusively to cytoplasmic compartments. 3T3-L1 fibroblasts expressing GLUT4 were unresponsive to insulin with respect to transport activity, and no change was observed in the subcellular distribution of the protein after insulin administration. Immunogold labeling of frozen ultrathin sections revealed that GLUT4 was concentrated in tubulo-vesicular elements of the trans-Golgi reticulum in these cells. Sucrose density gradient analysis of 3T3-L1 homogenates was consistent with the presence of GLUT1 and GLUT4 in discrete cytoplasmic compartments. Immunogold labeling of frozen thin sections of HepG2 cells indicated that endogenous GLUT1 was heavily concentrated in the plasma membrane. Sucrose density gradient analysis of homogenates of HepG2 cells expressing rat GLUT4 suggested that GLUT4 is targeted to an intracellular location in these cells. The density of the putative GLUT4-containing cytoplasmic membrane vesicles was very similar in HepG2 cells, 3T3-L1 fibroblasts, 3T3-L1 adipocytes, and rat adipocytes. These data indicate that the intracellular trafficking of GLUT4 is isoform specific. Additionally, these observations support the notion that GLUT4 is targeted to its proper intracellular locale even in cell types that do not exhibit insulin-responsive glucose transport, and suggest that the machinery that regulates the intracellular targeting of GLUT4 is distinct from the factors that regulate insulin-dependent recruitment to the cell surface.