Browning of white fat: agents and implications for beige adipose tissue to type 2 diabetes.

Mammalian adipose tissue is traditionally categorized into white and brown relating to their function and morphology: while white serves as an energy storage, brown adipose tissue acts as the heat generator maintaining the core body temperature. The most recently identified type of fat, beige adipocyte tissue, resembles brown fat by morphology and function but is developmentally more related to white. The synthesis of beige fat, so-called browning of white fat, has developed into a topical issue in diabetes and metabolism research. This is due to its favorable effect on whole-body energy metabolism and the fact that it can be recruited during adult life. Indeed, brown and beige adipose tissues have been demonstrated to play a role in glucose homeostasis, insulin sensitivity, and lipid metabolism-all factors related to pathogenesis of type 2 diabetes. Many agents capable of initiating browning have been identified so far and tested widely in humans and animal models including in vitro and in vivo experiments. Interestingly, several agents demonstrated to have browning activity are in fact secreted as adipokines from brown and beige fat tissue, suggesting a physiological relevance both in beige adipocyte recruitment processes and in maintenance of metabolic homeostasis. The newest findings on agents driving beige fat recruitment, their mechanisms, and implications on type 2 diabetes are discussed in this review.

Response of SCP-2L domain of human MFE-2 to ligand removal: binding site closure and burial of peroxisomal targeting signal.

In the study of the structure and function relationship of human MFE-2, we have investigated the dynamics of human MFE-2SCP-2L (hSCP-2L) and its response to ligand removal. A comparison was made with homologous rabbit SCP-2. Breathing and a closing motion are found, identifiable with an adjustment in size and a closing off of the binding pocket. Crucial residues for structural integrity have been identified. Particularly mobile areas of the protein are loop 1 that is connecting helices A and C in space, and helix D, next to the entrance of the pocket. In hSCP-2L, the binding pocket gets occupied by Phe93, which is making a tight hydrophobic contact with Trp36. In addition, it is found that the C-terminal peroxisomal targeting signal (PTS1) that is solvent exposed in the complexed structure becomes buried when no ligand is present. Moreover, an anti-correlation exists between burial of PTS1 and the size of the binding pocket. The results are in accordance with plant nsLTPs, where a similar accommodation of binding pocket size was found after ligand binding/removal. Furthermore, the calculations support the suggestion of a ligand-assisted targeting mechanism.

Crystal structure of the liganded SCP-2-like domain of human peroxisomal multifunctional enzyme type 2 at 1.75 A resolution.

beta-Oxidation of amino acyl coenzyme A (acyl-CoA) species in mammalian peroxisomes can occur via either multifunctional enzyme type 1 (MFE-1) or type 2 (MFE-2), both of which catalyze the hydration of trans-2-enoyl-CoA and the dehydrogenation of 3-hydroxyacyl-CoA, but with opposite chiral specificity. MFE-2 has a modular organization of three domains. The function of the C-terminal domain of the mammalian MFE-2, which shows similarity with sterol carrier protein type 2 (SCP-2), is unclear. Here, the structure of the SCP-2-like domain comprising amino acid residues 618-736 of human MFE-2 (d Delta h Delta SCP-2L) was solved at 1.75 A resolution in complex with Triton X-100, an analog of a lipid molecule. This is the first reported structure of an MFE-2 domain. The d Delta h Delta SCP-2L has an alpha/beta-fold consisting of five beta-strands and five alpha-helices; the overall architecture resembles the rabbit and human SCP-2 structures. However, the structure of d Delta h Delta SCP-2L shows a hydrophobic tunnel that traverses the protein, which is occupied by an ordered Triton X-100 molecule. The tunnel is large enough to accommodate molecules such as straight-chain and branched-chain fatty acyl-CoAs and bile acid intermediates. Large empty apolar cavities are observed near the exit of the tunnel and between the helices C and D. In addition, the C-terminal peroxisomal targeting signal is ordered in the structure and solvent-exposed, which is not the case with unliganded rabbit SCP-2, supporting the hypothesis of a ligand-assisted targeting mechanism.

Immunoaffinity purification and reconstitution of human alpha(2)-adrenergic receptor subtype C2 into phospholipid vesicles.

Large quantities of correctly folded, pure alpha(2)-adrenergic receptor protein are needed for structural analysis. We report here the first efficient method to purify human alpha(2)-adrenergic receptor subtype C2 to homogeneity from recombinant yeast Saccharomyces cerevisiae by one-step purification using a monoclonal antibody column (specific for alpha(2)C2). We show that the adrenoceptor antagonist phentolamine stabilized the receptor during purification. We used a very effective chaotropic agent, NaSCN, to elute the receptor from the immunoaffinity column with an overall yield of 34% before reconstitution. Ligand binding of detergent-solubilized, immunoaffinity-purified receptors could not be demonstrated, but partial recovery of ligand binding activity was achieved when purified receptors were reconstituted into phospholipid vesicles. The reconstituted receptors still bound radioligand after storage on ice for 4 weeks. This purification procedure can be easily scaled-up and thus demonstrates the utility of a monoclonal antibody column and NaSCN elution to purify large quantities of G-protein-coupled receptors.

Production and purification of recombinant human alpha 2C2 adrenergic receptor using Saccharomyces cerevisiae.

The objective is to generate milligram quantities of recombinant human alpha 2C2 adrenergic receptor for X-ray crystallographic studies. It has been cloned in Saccharomyces cerevisiae, and the production level is at best about 13 pmol/mg of membrane protein, as estimated by radio-ligand binding assay. The receptor is solubilized with sucrose monolaurate followed by immunoaffinity purification and reconstitution into phospholipid vesicles. The efficiency of solubilization and immuno-purification are 60% and 91%, respectively.

Human peroxisomal multifunctional enzyme type 2. Site-directed mutagenesis studies show the importance of two protic residues for 2-enoyl-CoA hydratase 2 activity.

Beta-oxidation of acyl-CoAs in mammalian peroxisomes can occur via either multifunctional enzyme type 1 (MFE-1) or type 2 (MFE-2), both of which catalyze the hydration of trans-2-enoyl-CoA and the dehydrogenation of 3-hydroxyacyl-CoA, but with opposite chiral specificity. Amino acid sequence alignment of the 2-enoyl-CoA hydratase 2 domain in human MFE-2 with other MFE-2s reveals conserved protic residues: Tyr-347, Glu-366, Asp-370, His-406, Glu-408, Tyr-410, Asp-490, Tyr-505, Asp-510, His-515, Asp-517, and His-532. To investigate their potential roles in catalysis, each residue was replaced by alanine in site-directed mutagenesis, and the resulting constructs were tested for complementation in a yeast. After additional screening, the wild type and noncomplementing E366A and D510A variants were expressed and characterized. The purified proteins have similar secondary structural elements, with the same subunit composition. The E366A variant had a k(cat)/K(m) value 100 times lower than that of the wild type MFE-2 at pH 5, whereas the D510A variant was inactive. Asp-510 was imbedded in a novel hydratase 2 motif found in the hydratase 2 proteins. The data show that the hydratase 2 reaction catalyzed by MFE-2 requires two protic residues, Glu-366 and Asp-510, suggesting that their catalytic role may be equivalent to that of the two catalytic residues of hydratase 1.

Yeast peroxisomal multifunctional enzyme: (3R)-hydroxyacyl-CoA dehydrogenase domains A and B are required for optimal growth on oleic acid.

The yeast peroxisomal (3R)-hydroxyacyl-CoA dehydrogenase/2-enoyl-CoA hydratase 2 (multifunctional enzyme type 2; MFE-2) has two N-terminal domains belonging to the short chain alcohol dehydrogenase/reductase superfamily. To investigate the physiological roles of these domains, here called A and B, Saccharomyces cerevisiae fox-2 cells (devoid of Sc MFE-2) were taken as a model system. Gly(16) and Gly(329) of the S. cerevisiae A and B domains, corresponding to Gly(16), which is mutated in the human MFE-2 deficiency, were mutated to serine and cloned into the yeast expression plasmid pYE352. In oleic acid medium, fox-2 cells transformed with pYE352:: ScMFE-2(aDelta) and pYE352::ScMFE-2(bDelta) grew slower than cells transformed with pYE352::ScMFE-2, whereas cells transformed with pYE352::ScMFE-2(aDeltabDelta) failed to grow. Candida tropicalis MFE-2 with a deleted hydratase 2 domain (Ct MFE- 2(h2Delta)) and mutational variants of the A and B domains (Ct MFE- 2(h2DeltaaDelta), Ct MFE- 2(h2DeltabDelta), and Ct MFE- 2(h2DeltaaDeltabDelta)) were overexpressed and characterized. All proteins were dimers with similar secondary structure elements. Both wild type domains were enzymatically active, with the B domain showing the highest activity with short chain and the A domain with medium and long chain (3R)-hydroxyacyl-CoA substrates. The data show that the dehydrogenase domains of yeast MFE-2 have different substrate specificities required to allow the yeast to propagate optimally on fatty acids as the carbon source.

Crystallization and preliminary crystallographic analysis of 3-carboxy-cis,cis-muconate lactonizing enzyme from Neurospora crassa.

Crystals of 3-carboxy-cis,cis-muconate lactonizing enzyme (CMLE; E.C. 5.5.1.5) from Neurospora crassa that diffract to high resolution have been obtained. The crystals belong to the orthorhombic space group P2(1)2(1)2(1) with unit-cell dimensions a = 92.1, b = 159.7, c = 236.6 A (at 103 K) and diffract at most to 2 A resolution. The asymmetric unit of the crystals appears to contain two tetrameric CMLE molecules making up a total of 328 kDa per asymmetric unit. Both cross-linking with glutaraldehyde and cryo-cooling to 103 K have been used to facilitate data collection because the crystals are unstable in the X-ray beam; both techniques extend the crystal lifetime but cryo-cooling, unlike glutaraldehyde cross-linking, does not lower the quality of the diffraction pattern.

Effects of signal peptide mutations on processing of Bacillus stearothermophilus alpha-amylase in Escherichia coli.

Bacillus stearothermophilus alpha-amylase has a signal peptide typical for proteins exported by Gram-positive bacteria. There is only one signal peptidase processing site when the protein is exported from the original host, but when it is exported by Escherichia coli, two alternative sites are utilized. Site-directed mutagenesis was used to study the processing in E. coli. Processing sites for 13 B. stearothermophilus alpha-amylases carrying mutations in their signal peptide were determined. Processing of the signal peptide was remarkably tolerant to mutations, because switching between the alternative sites was possible. The length and the sequence of the region between the hydrophobic core and the cleavage site was crucial for determining the choice of the processing site. Some mutations more distal to the cleavage site also affected the site preference.

The structure of E.coli soluble inorganic pyrophosphatase at 2.7 A resolution.

The structure of E.coli soluble inorganic pyrophosphatase has been refined at 2.7 A resolution to an R-factor of 20.9%. The overall fold of the molecule is essentially the same as yeast pyrophosphatase, except that yeast pyrophosphatase is longer at both the N- and C-termini. Escherichia coli pyrophosphatase is a mixed alpha + beta protein with a complicated topology. The active site cavity, which is also very similar to the yeast enzyme, is formed by seven beta-strands and an alpha-helix and has a rather asymmetric distribution of charged residues. Our structure-based alignment extends and improves upon earlier sequence alignment studies; it shows that probably no more than 14, not 15-17 charged and polar residues are part of the conserved enzyme mechanism of pyrophosphatases. Six of these conserved residues, at the bottom of the active site cavity, form a tight group centred on Asp70 and probably bind the two essential Mg2+ ions. The others, more spreadout and more positively charged, presumably bind substrate. Escherichia coli pyrophosphatase has an extra aspartate residue in the active site cavity, which may explain why the two enzymes bind divalent cation differently. Based on the structure, we have identified a sequence motif that seems to occur only in soluble inorganic pyrophosphatases.

Do carbohydrates play a role in the lignin peroxidase cycle? Redox catalysis in the endergonic region of the driving force.

The redox cycle of lignin peroxidase (LiP) is discussed in terms of the Marcus theory of electron transfer. The difference in kinetic behaviour of the two redox couples LiP-Compound I/LiP-Compound II (LiPI/LiPII), respectively LiPII/LiP, in the oxidation of veratryl alcohol is attributed to an estimated increase in reorganization energy of about 0.5 eV for the conversion of LiPII to native enzyme compared to the reduction of LiPI to LiPII. Whereas LiPI/LiPII involves a transition from a low-spin oxyferryl prophyrin radical cation to a low-spin oxyferryl porphyrin system, the conversion of LiPII to native enzyme involves a change in spin-state to high-spin ferric, accompanied by a conformational change of the protein. In addition, a molecule of water is formed after protonation of the oxyferryl porphyrin system by the distal His-47 and Arg-43. Furthermore, the reduction of LiPI to LiPII is observed as an irreversible process. Since the oxidation of veratryl alcohol by oxidized LiP will occur in the endergonic region of the driving force, it is postulated that the thermodynamic unfavourable formation of veratryl alcohol radical cation is facilitated by reaction of a nucleophile with the incipient radical cation. It is further postulated that the ordered carbohydrate residues found near the entrance to the active site channel in the LiP crystal structure play a role in this process.

Decolorization of Azo, Triphenyl Methane, Heterocyclic, and Polymeric Dyes by Lignin Peroxidase Isoenzymes from Phanerochaete chrysosporium.

The ligninolytic enzyme system of Phanerochaete chrysosporium decolorizes several recalcitrant dyes. Three isolated lignin peroxidase isoenzymes (LiP 4.65, LiP 4.15, and LiP 3.85) were compared as decolorizers with the crude enzyme system from the culture medium. LiP 4.65 (H2), LiP 4.15 (H7), and LiP 3.85 (H8) were purified by chromatofocusing, and their kinetic parameters were found to be similar. Ten different types of dyes, including azo, triphenyl methane, heterocyclic, and polymeric dyes, were treated by the crude enzyme preparation. Most of the dyes lost over 75% of their color; only Congo red, Poly R-478, and Poly T-128 were decolorized less than the others, 54, 46, and 48%, respectively. Five different dyes were tested for decolorization by the three purified isoenzymes. The ability of the isoenzymes to decolorize the dyes in the presence of veratryl alcohol was generally comparable to that of the crude enzyme preparation, suggesting that lignin peroxidase plays a major role in the decolorization and that manganese peroxidase is not required to start the degradation of these dyes. In the absence of veratryl alcohol, the decolorization activity of the isoenzymes was in most cases dramatically reduced. However, LiP 3.85 was still able to decolorize 20% of methylene blue and methyl orange and as much as 60% of toluidine blue O, suggesting that at least some dyes can function as substrates for isoenzyme LiP 3.85 but not to the same extent for LiP 4.15 or LiP 4.65. Thus, the isoenzymes have different specificities towards dyes as substrates.

Low pH crystal structure of glycosylated lignin peroxidase from Phanerochaete chrysosporium at 2.5 A resolution.

The heme-containing glycoprotein lignin peroxidase (pI 4.15) has been crystallized at pH 4.0. The structure of the peroxidase from the orthorhombic crystals has been determined by multiple isomorphous replacement. The model comprises all 343 amino acids, one heme molecule, and three sugar residues. It has been refined to an R-factor of 20.3%. The chain fold of residues 15 to 275 is in general similar to those of cytochrome c peroxidase. Despite binding of the heme to the same region and a similar arrangement of the proximal and distal histidine as in cytochrome c peroxidase a significantly larger distance of the iron ion to the proximal histidine is observed. Distinct electron density extending from Asn-257 and at the distal side of the heme indicates ordered sugar residues in the crystal.

Lignin peroxidase from Phanerochaete chrysosporium. Molecular and kinetic characterization of isozymes.

Five isozymes of lignin peroxidase from Phanerochaete chrysosporium were purified and their physical, molecular and kinetic properties determined. The isozymes differ from each other in terms of their isoelectric point, molecular mass, sugar content, spectral characteristics, substrate specificity and stability. The N-terminal sequence of amino acids was different for each isozyme suggesting they are different gene products. The isozyme with the highest carbohydrate level was most sensitive to changes in environmental factors. The kinetic behaviour of the isozymes varied clearly when tert-butyl hydroperoxide instead of hydrogen peroxide was used as the oxidant. Two out of five isozymes had very similar substrate specificity. The results are discussed in relation to the role which lignin peroxidase isozymes may play in lignin biodegradation.

Extracellular production of cloned alpha-amylase by Escherichia coli.

Overexpression of Bacillus stearothermophilus gene coding for thermostable alpha-amylase in Escherichia coli was shown to cause outer-membrane damage leading to extracellular location of periplasmic proteins. Prolonged high expression of the alpha-amylase gene under lacZpo control eventually also lysed cells. Surprisingly, expression controlled by the pL promoter of phage lambda allowed specific release of periplasmic proteins into the growth medium without total cell lysis. Accumulation of alpha-amylase in the growth medium continued for at least 24 h under lambda pL control, whereas beta-lactamase activity ceased to increase beyond the exponential growth phase. The extent of outer membrane damage caused by alpha-amylase expression was monitored by following growth kinetics in the presence of lysozyme and by electron microscopy of the cells. Supplementing growth medium with Mg2+ restored the normal growth kinetics. It is suggested that periplasmic protein release caused by alpha-amylase overexpression is a stress response of the cell. A role for induced autolytic activity of the cell as a final effector of protein release is also proposed.