The transmembrane and flanking sequences of beta 1,2-N-acetylglucosaminyltransferase I specify medial-Golgi localization.

UDP-GlcNAc:alpha 3-D-mannoside beta 1,2-N-acetylglucosaminyltransferase I (GnTI) is an N(in)/C(out) (type II) membrane protein, localized in the medial-Golgi, that initiates the conversion of high mannose N-glycans to complex N-glycans. Anti-rabbit GnTI antibodies were generated using a purified, enzymatically active, bacterial recombinant fusion protein as immunogen. Rabbit GnTI was effectively retained in the Golgi complex of transfected COS-1 cells and murine L cells, as assessed by indirect immunofluorescence using the species-specific anti-GnTI antibodies; no surface expression of rabbit GnTI could be detected in the transfected cells. Rabbit GnTI, stably expressed in murine L cells, was localized by immunoperoxidase electron microscopy to the medial-cisternae of the Golgi stack. The role of the transmembrane domain of GnTI in Golgi localization was examined by generation of a hybrid construct containing the amino-terminal 31 amino acids of GnTI, corresponding to the 25-residue transmembrane (signal/anchor) domain and flanking hydrophilic sequences, fused with ovalbumin; this ovalbumin/GnTI hybrid molecule was retained in the Golgi complex of transfected COS cells and stably transfected murine L cells. No surface expression of ovalbumin/GnTI was detected. In contrast, ovalbumin fused to the equivalent domains of the human transferrin receptor, a type II cell-surface protein, was efficiently expressed on the cell surface of transfected cells. The ovalbumin/GnTI hybrid molecules in the transfected L cells were N-glycosylated, indicating an N(in)/C(out) membrane orientation, and were localized by immunoperoxidase electron microscopy to one or two cisternae of the medial-Golgi (90% of stained Golgi profiles showed medial-cisternae staining). These results show that a signal contained within the transmembrane domain and flanking residues of GnTI specifies medial-Golgi localization.     

Medial Golgi but not late Golgi glycosyltransferases exist as high molecular weight complexes. Role of luminal domain in complex formation and localization

To investigate the organization of Golgi glycosyltransferases and their mechanism of localization, we have compared the properties of a number of medial and late acting Golgi enzymes. The medial Golgi enzymes, N-acetylglucosaminyltransferase I and II (GnTI and GnTII) required high salt for solubilization and migrated as high molecular weight complexes on sucrose density gradients. In contrast, the late acting Golgi enzymes, beta1,4-galactosyltransferase and alpha1, 2-fucosyltransferase, were readily solubilized in low salt and migrated as monomers/dimers by sucrose density gradient centrifugation. Analysis of membrane-bound GnTI chimeras indicates that the formation of high molecular weight complexes does not require the transmembrane domain and cytoplasmic tail sequences of GnTI. Furthermore, a soluble form of GnTI, containing the stem region and catalytic domain, accumulated in the Golgi prior to secretion, in contrast to beta1,4-galactosyltransferase. Soluble GnTI, which also associated with high molecular weight complexes, was comparable with membrane-bound GnTI in its ability to glycosylate newly synthesized glycoproteins in vivo. Mutation of charged residues within the stem region of GnTI, known to be important for "kin recognition", had no effect on the efficiency of Golgi localization, the inclusion into high molecular weight complexes, nor functional activity in vivo. The differences in behavior between the medial and late acting Golgi enzymes may contribute to their differential localization and their ability to glycosylate efficiently in the correct Golgi subcompartment.     

Enolase isoenzymes in adult and developing Xenopus laevis and characterization of a cloned enolase sequence.

As part of a study of glycolysis during early development we have examined the pattern of expression of enolase isoenzymes in Xenopus laevis. In addition, the nucleotide sequence of a cDNA clone coding for the complete amino acid sequence of one enolase gene (ENO1) in X. laevis was determined. X. laevis ENO1 shows highest homology to mammalian non-neuronal enolase. Analysis of enolase isoenzymes in X. laevis by non-denaturing electrophoresis on cellulose acetate strips revealed five isoenzymes. One form was present in all tissues tested, two additional forms were expressed in oocytes, embryos, adult liver and adult brain, and two further forms were restricted to larval and adult muscle. Since enolase is a dimer, three different monomers (gene products) could account for the observed number of isoenzymes. This pattern of enolase isoenzyme expression in X. laevis differs from that of birds and mammals. In birds and mammals the most acidic form is neuron-specific and there is only one major isoenzyme expressed in the liver. RNAase protection experiments showed the presence of ENO1 mRNA in oocytes, liver and muscle, suggesting that it codes for a non-tissue-restricted isoenzyme. ENO1 mRNA concentrations are high in early oocytes, decrease during oogenesis and decrease further after fertilization. Enolase protein, however, is maintained at high concentrations throughout this period.     

Removal of 106 amino acids from the N-terminus of UDP-GlcNAc :alpha-3-D-mannoside beta-1,2-N-acetylglucosaminyltransferase I does not inactivate the enzyme

UDP-GlcNAc : -3-D-mannoside -1,2-N-acetylglucosaminyltransferase I (GnT I, EC 2.4.1.101) plays an essential role in the conversion of oligomannose to complex and hybrid N-glycans. Rabbit GnTI is 447 residues long and has a short four-residue N-terminal cytoplasmic tail, a 25-residue putative signal–anchor hydrophobic domain, a stem region of undetermined length and a large C-terminal catalytic domain, a structure typical of all glycosyltransferases cloned to date. Comparison of the amino acid sequences for human, rabbit, mouse, rat, chicken, frog and Caenorhabditis elegans GnT I was used to obtain a secondary structure prediction for the enzyme which suggested that the location of the junction between the stem and the catalytic domain was at about residue 106. To test this hypothesis, several hybrid constructs containing GnT I with N- and C-terminal truncations fused to a mellitin signal sequence were inserted into the genome of Autographa californica nuclear polyhedrosis virus (AcMNPV), Sf 9 insect cells were infected with the recombinant baculovirus and supernatants were assayed for GnT I activity. Removal of 29, 84 and 106 N-terminal amino acids had no effect on GnT I activity; however, removal of a further 14 amino acids resulted in complete loss of activity. Western blot analysis showed strong protein bands for all truncated enzymes except for the construct lacking 120 N-terminal residues indicating proteolysis or defective expression or secretion of this protein. The data indicate that the stem is at least 77 residues long.     

Isolation of two novel metalloproteinase-disintegrin (ADAM) cDNAs that show testis-specific gene expression.

Metalloproteinase-disintegrins (ADAMs) are type 1 transmembrane proteins that contain a unique domain structure including a zinc-binding metalloproteinase domain. We have isolated cDNAs encoding two novel members of this family, ADAM29 and ADAM30 which show testis-specific expression. Three forms of ADAM29 were found that encode proteins of 820, 786 and 767 amino acids. All of the amino acid differences are located in the cytoplasmic domain. Two forms of ADAM30 were isolated that encode proteins of 790 and 781 amino acids, with the difference in the coding region occurring in the cytoplasmic domain. ADAM29 and ADAM30 map to human chromosome 4q34 and 1p11-13, respectively. An ancestral analysis of all known mammalian ADAMs indicates that the zinc-binding motif in the catalytic domain arose once in a common ancestor and was subsequently lost by those members lacking this motif.     

Amino acid sequence and molecular characterization of murine lamin B as deduced from cDNA clones

The nuclear lamina is the karyoskeletal structure, intimately associated with the nuclear envelope, that is widespread among the diverse types of eukaryotic cells. A family of proteins, termed lamins, has been shown to be a prominent component of this lamina, and various members of this family are differentially expressed in different cell types. In mammals, three major lamins (A, B, C) have been identified, and in all cells so far examined lamin B is constitutively expressed while lamins A and C are not, suggesting that lamin B is sufficient to form a functional lamina. Because of this key importance of lamin B, cDNA clones encoding mammalian lamin B were isolated by screening murine cDNA libraries, representing F9 teratocarcinoma cells and fetal liver, with the corresponding cDNA probe of lamin LI of Xenopus laevis. The nucleotide sequence of the murine lamin B mRNA (approximately 2.9 kb) was determined. The deduced amino acid sequence of the encoded polypeptide (587 amino acids; mol. wt. 66760) is highly homologous to X. laevis lamin LI (72.9% identical residues) but displays lower similarity to A-type lamins (53.8% identical amino acid residues with human lamin A). Lamin B also conforms to the general molecular organization principle of the members of the intermediate filament (IF) protein family, i.e., an extended alpha-helical rod domain that is interrupted by two non alpha-helical linkers and flanked by non-alpha-helical head (amino-terminal) and tail (carboxy-terminal) domains. The tail domain, which does not reveal a hydrophobic region of considerable length, contains a typical karyophilic signal sequence and an uninterrupted stretch of eight negatively charged amino acids.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characterization of the cDNA and amino acid sequences of Xenopus Metaxin 3, and relationship to Xenopus Metaxins 1 and 2.

The cDNA and protein structures of Xenopus metaxin 3, along with those of Xenopus metaxins 1 and 2, have been characterized. A protein of 309 amino acid residues is encoded by X. laevis metaxin 3 (XMTX3) cDNA. In comparison, the cDNA of X. laevis metaxin 1 (XMTX1) specifies a protein of 320 residues, while the metaxin 2 cDNAs of X. laevis (XMTX2) and X. tropicalis (SMTX2) both specify proteins of 274 amino acids. Aligning the amino acid sequences of XMTX3 and XMTX1 showed 39% identities; 22% identities were found for XMTX3 and XMTX2. However, 55% amino acid identities were revealed in aligning the XMTX3 and zebrafish metaxin 3 sequences. The construction of a phylogenetic tree gave further evidence for the existence of three distinct groups of metaxin genes and their common ancestry. Two conserved protein domains are present in each of the Xenopus metaxins: a glutathione S-transferase (GST) domain and a thioredoxin-like domain. The protein secondary structure predicted for the Xenopus metaxins is dominated by regions of alpha helix which alternate with regions that are neither alpha helix nor beta strand.     

Proton nuclear magnetic resonance spectroscopy of horseradish peroxidase isoenzymes: correlation of distinctive spectra with isoenzyme specific activities

High-resolution proton NMR spectra are reported for the paramagnetic ferric native and cyano complexes of the five major horseradish root peroxidase (HRP) isoenzymes (A1, A2, A3, B, and C). Axial imidazole resonances are observed in the native and cyano-complex spectra of all the isoenzymes, thus indicating the presence of a common axial histidine ligand. Proton NMR spectra outside the usual diamagnetic region are identical for sets of A1 and A2 isoenzymes and for the B and C isoenzyme set. Variation in heme residue chemical shift positions may be controlled in part by porphyrin vinyl side chain-protein interactions. Diverse upfield spectra among the isoenzymes reflect amino acid substitutions and/or conformational differences near the prosthetic group, as signals in this region must result from amino acid residues in proximity to the heme center. Acid-base dependence studies reveal an "alkaline" transition that converts the native high-spin iron (III) porphyrin to the low-spin state. The transition occurs at pH 9.3, 9.4, 9.8, and 10.9 for respective HRP A1, A2, A3, and C isoenzymes, respectively. Significantly, this ordering also reflects specific activities for the isoenzymes in the order A1 = A2 greater than A3 greater than B = C. Identical proton NMR spectra for A1/A2 and B/C isoenzyme sets parallel equivalent specific activities for members of a particular set. Proton NMR spectra thus appear to be highly sensitive to protein modifications that affect catalytic activity.     

Construction and characterization of an active factor VIII variant lacking the central one-third of the molecule

The primary structure of factor VIII consists of 2332 amino acids that exhibit 3 distinct structural domains, including a triplicated region (A domains), a unique region of 909 amino acids (B domain), and a carboxy-terminal duplicated region (C domains), that are arranged in the order A1-A2-B-A3-C1-C2. The B domain (residues 741-1648) of factor VIII is lost when factor VIII is activated by thrombin, which proteolytically processes factor VIII to active subunits of Mr 50,000 (domain A1), 43,000 (domain A2), and 73,000 (domains A3-C1-C2). To determine if the B domain is required for factor VIII coagulant activity, a variant was constructed by using recombinant DNA techniques in which residues 797-1562 were eliminated. This shortened the B domain from 909 to 142 amino acids. This variant factor VIIIdes-797-1652 was expressed in mammalian cells and was found to be functional. The factor VIIIdes-797-1562 protein was purified and shown to be processed by thrombin in the same manner as full-length factor VIII. The factor VIIIdes-797-1562 variant also bound to von Willebrand factor (vWF) immobilized on Sepharose. These results indicate that most of the highly glycosylated B domain of factor VIII is not required for the expression of factor VIII coagulant activity and its interaction with vWF.     

The transmembrane domain of N –acetylglucosaminyltransferase I is the key determinant for its Golgi subcompartmentation

Golgi‐resident type–II membrane proteins are asymmetrically distributed across the Golgi stack. The intrinsic features of the protein that determine its subcompartment‐specific concentration are still largely unknown. Here, we used a series of chimeric proteins to investigate the contribution of the cytoplasmic, transmembrane and stem region of Nicotiana benthamiana N–acetylglucosaminyltransferase I (GnTI) for its cis/medial‐Golgi localization and for protein–protein interaction in the Golgi. The individual GnTI protein domains were replaced with those from the well‐known trans‐Golgi enzyme α2,6–sialyltransferase (ST) and transiently expressed in Nicotiana benthamiana. Using co‐localization analysis and N–glycan profiling, we show that the transmembrane domain of GnTI is the major determinant for its cis/medial‐Golgi localization. By contrast, the stem region of GnTI contributes predominately to homomeric and heteromeric protein complex formation. Importantly, in transgenic Arabidopsis thaliana, a chimeric GnTI variant with altered sub‐Golgi localization was not able to complement the GnTI‐dependent glycosylation defect. Our results suggest that sequence‐specific features in the transmembrane domain of GnTI account for its steady‐state distribution in the cis/medial‐Golgi in plants, which is a prerequisite for efficient N–glycan processing in vivo.     

Expression cloning of a receptor for murine granulocyte colony-stimulating factor

Two cDNAs encoding the receptor for murine granulocyte colony-stimulating factor (G-CSF) were isolated from a CDM8 expression library of mouse myeloid leukemia NFS-60 cells, and their nucleotide sequences were determined. Murine G-CSF receptor expressed in COS cells could bind G-CSF with an affinity and specificity similar to that of the native receptor expressed by mouse NFS-60 cells. The amino acid sequence encoded by the cDNAs has demonstrated that murine G-CSF receptor is an 812 amino acid polypeptide (Mr, 90,814) with a single transmembrane domain. The extracellular domain consists of 601 amino acids with a region of 220 amino acids that shows a remarkable similarity to rat prolactin receptor. The cytoplasmic domain of the G-CSF receptor shows a significant similarity with parts of the cytoplasmic domain of murine interleukin-4 receptor. A 3.7 kb mRNA coding for the G-CSF receptor could be detected in mouse myeloid leukemia NFS-60 and WEHI-3B D+ cells as well as in bone marrow cells.     

The transmembrane domain of murine alpha-mannosidase IB is a major determinant of Golgi localization

Murine alpha1,2-mannosidase IB is a type II transmembrane protein localized to the Golgi apparatus where it is involved in the biogenesis of complex and hybrid N-glycans. This enzyme consists of a cytoplasmic tail, a transmembrane domain followed by a "stem" region and a large C-terminal catalytic domain. To analyze the determinants of targeting, we constructed various deletion mutants of murine alpha1,2-mannosidase IB as well as alpha1,2-mannosidase IB/yeast alpha1,2-mannosidase and alpha1,2-mannosidase IB/GFP chimeras and localized these proteins by fluorescence microscopy, when expressed transiently in COS7 cells. Replacing the catalytic domain of alpha1,2-mannosidase IB with that of the homologous yeast alpha1,2-mannosidase and deleting the "stem" region in this chimera had no effect on Golgi targeting, but caused increased cell surface localization. The N-terminal tagged protein lacking a catalytic domain was also localized to the Golgi. In the latter case, when the stem region was partially or completely removed, the protein was found in both the ER and the Golgi. A chimera consisting of the alpha1,2-mannosidase IB N-terminal region (cytoplasmic and transmembrane domains plus 10 amino acids of the "stem" region) and GFP was localized mainly to the Golgi. Deletion of 30 out of 35 amino acids in the cytoplasmic tail had no effect on Golgi localization. A GFP chimera lacking the entire cytoplasmic tail was found in both the ER and the Golgi. These results indicate that the transmembrane domain of alpha1,2-mannosidase IB is a major determinant of Golgi localization.     

How nature tunes isoenzyme activity in the multifunctional catalytic globin dehaloperoxidase from Amphitrite ornata

The coelomic hemoglobin of Amphitrite ornata, termed dehaloperoxidase (DHP), is the first known multifunctional catalytic globin to possess biologically-relevant peroxidase and peroxygenase activities. Although the two isoenzymes of DHP, A and B, differ in sequence by only 5 amino acids out of 137 residues, DHP B consistently exhibits a greater activity than isoenzyme A. To delineate the contributions of each amino acid substitution to the activity of either isoenzyme, the substitutions of the five amino acids were systematically investigated, individually and in combination, using 22 mutants. Biochemical assays and mechanistic studies demonstrated that the mutants that only contained the I9L substitution showed increased i) k_cat values (peroxidase activity), ii) 5-Br-indole conversion and binding affinity (peroxygenase activity), and iii) rate of Compound ES formation (enzyme activation). Whereas the X-ray structures of the oxyferrous forms of DHP B (L9I) (1.96 Å), DHP A (I9L) (1.20 Å), and WT DHP B (1.81 Å) showed no significant differences, UV–visible spectroscopy (A_Soret/A₃₈₀ ratio) revealed that the I9L substitution increased the 5-coordinate high-spin heme population characterized by the “open” conformation (i.e., distal histidine swung out of the pocket), which likely favors substrate binding. The positioning of the distal histidine closer to the heme cofactor in the solution state also appears to facilitate activation of DHP via the Compound ES intermediate. Taken together, the studies undertaken here shed light on the structure-function relationship in dehaloperoxidase, but also help to establish the foundation for understanding how enzymatic activity can be tuned in isoenzymes of a multifunctional catalytic globin.     

Mammalian hexokinase 1: Evolutionary conservation and structure to function analysis

We have amplified and sequenced the complete coding region of bovine hexokinase isoenzyme 1 (HK1) from brain RNA with PCR primers selected for sequence conservation. The sequence information was analyzed to evaluate the evolutionary and structure-function relationships among the mammalian and yeast HK isoenzymes. Structure to function analysis identified an unduplicated, invariant N-terminal domain involved in HK1 outer mitochondrial membrane targeting, as well as putative carbohydrate and nucleotide-binding sites in the regulatory and catalytic halves of HK1 essential to enzyme function. The ATP-binding site in the catalytic half of the HK1 protein resembles nucleotide-binding regions from protein kinases, with the single amino acid replacement (lysine to glutamate) in the ATP-binding site of the amino half explaining the loss of HK1 catalytic function in the regulatory domain. Sequence comparisons suggest that the 50-kDa mammalian and yeast glucokinases arose separately in evolution. In addition to providing valuable phylogenetic and structure-function insights, this work provides an efficient strategy for rapid cloning and sequencing of the coding regions for other HKs and related proteins.     

Purification procedure and N-terminal amino acid sequence of yeast malate dehydrogenase isoenzymes

A method has been devised for the rapid isolation of malate dehydrogenase isoenzymes. First, anionic proteins were precipitated with polyethyleneimine, whilst hydrophobic malate dehydrogenase remained in the supernatant fluid. Secondly, the supernatant was 30% saturated with ammonium sulfate and the two isoenzymes were separated by hydrophobic phenyl-Sepharose CL-4B chromatography. For further purification the enzymes were chromatofocused, and polybuffer was removed by hydrophobic chromatography. Affinity chromatography with blue Sepharose CL-6B [1] was used as final purification step. The purified isoenzymes were homogeneous as shown by isoelectric focusing and could be used for N-terminal sequencing. 34 amino acid residues could be identified for the cytoplasmic isoenzyme and 56 amino acid residues for the mitochondrial isoenzyme. Although there are regions of strong homology between both isoenzymes, the sequence differences clearly showed support that both isoenzymes are coded by different genes. Sequence comparison clearly indicated that the N-terminus of the cytoplasmic enzyme extended that of the mitochondrial enzyme by 12 amino acid residues. The amino acid sequence of the extending sequence resembled that of leading sequences known for enzymes which are transported into the mitochondria. The assumed leading sequence is discussed with respect to its possible role in glucose inactivation.     

Computational studies on a new cationic peroxidase isoenzyme from artichoke leaves

Previously we presented the purification, biochemical characterization, and cloning of a cationic peroxidase isoenzyme (CysPrx) from artichoke (Cynara cardunculus subsp scolymus (L.) Hegi) leaves. The protein was shown to have some interesting properties, suggesting that CysPrx could be a considered as a potential candidate for industrial application. In addition, from the CysPrx sequence, two full-lengh cDNAs: CysPrx1 and CysPrx2, differing for three amino acids, were isolated. A three-dimensional model was predicted from CysPrx1 by homology modeling, using two different computational tools. Herein we discuss the roles of particular amino acid residues and structural motifs or regions of both deduced sequences with the aim to find new understandings between the new plant peroxidase isoenzymes and their physiological substrates. Additionally, the obtained information may lead to new methods for improving the stability of the enzyme in several processes of biotechnological interest for peroxidase applications.     

Isoenzymes of horse liver alcohol dehydrogenase active on ethanol and steroids. cDNA cloning, expression, and comparison of active sites.

Horse liver alcohol dehydrogenase occurs as isoenzymes: E is active on ethanol but not steroids; S is active on ethanol and steroids. The cDNAs for these isoenzymes were cloned; both were 1.8-kilobase long and contained complete coding sequences. Both enzymes were expressed in Escherichia coli, and the purified proteins had properties similar to those of the natural enzymes. The amino acid sequence deduced from the open reading frame of the E-type cDNA agreed with the amino acid sequence of the E isoenzyme determined by protein sequencing and x-ray crystallography. When compared with the E-type cDNA, the coding region of the S-type cDNA contains 24 substitutions and 3 deletions, giving rise to an amino acid sequence for the S. isoenzyme that differs from that of the E isoenzyme at 10 positions: nine conservative substitutions and one deletion, of Asp-115. These changes can be accommodated in the three-dimensional structure of the E isoenzyme, and models of the E and S isoenzymes complexed with a 3 beta-hydroxy-5 beta-steroid were built. The modeling shows that Leu-116 apparently sterically hinders binding of steroids in the E isoenzyme, and deletion in the S isoenzyme of Asp-115 moves Leu-116 and relieves the hindrance. The human gamma and rat liver enzymes are also active on steroids, but they have a different constellation of amino acid residues in the substrate pocket. Thus, there are multiple bases for the activity on steroids.