An intact hydrophobic N-terminal sequence is critical for binding of rat brain hexokinase to mitochondria

The N-terminal sequence of rat brain hexokinase (ATP: D-hexose-6-phosphotransferase, EC 2.7.1.1) has been determined to be X-NH-Met-Ile-(Ala, Gln)-Ala-Leu-Leu-Ala-Tyr-, where X is a blocking group on the N-terminal methionine, probably an N-acetyl group. Modification of this hydrophobic N-terminal segment by endogenous proteases in crude brain extracts resulted in loss of the ability to bind to mitochondria, but had no effect on catalytic activity, resulting in the appearance of nonbindable enzyme reported by several previous investigators to be present in purified hexokinase preparations. Similar results can be obtained by deliberate limited digestion with chymotrypsin (cleavage points marked by arrows in sequence above). Both bindable and nonbindable enzyme, the latter generated either by endogenous proteases or with chymotrypsin, have an identical C-terminal dipeptide sequence, Ile-Ala. The great susceptibility of the N-terminus to proteolysis plus the marked effect that its proteolytic modification has on binding of hexokinase to anion exchange or hydrophobic (phenyl-Sepharose) matrices suggest that this N-terminal segment is prominently displayed at the enzyme surface. Epitopes recognized by two monoclonal antibodies which block binding of hexokinase to mitochondria (but have no effect on catalytic activity) have been mapped to a 10K fragment cleaved from the N-terminus by limited tryptic digestion. Thus the binding of hexokinase to mitochondria appears to occur via a "binding domain" constituting the N-terminal region of the molecule, with maintenance of an intact hydrophobic sequence at the extreme N-terminus being critical to this interaction. A resulting specific orientation of the molecule on the mitochondrial surface is considered to be a prerequisite for the observed coupling of hexokinase activity and mitochondrial oxidative phosphorylation.     

Difference in hydrophobicity between mitochondria-bindable and non-bindable forms of hexokinase purified from rat brain

Hexokinase able to bind to mitochondria was purified to homogeneity from rat brain by two successive DEAE-cellulose chromatographic steps. The enzyme lost only the binding ability with almost undetectable change in molecular weight on mild chymotrypsin digestion. The bindable hexokinase was adsorbed to a Phenyl-Sepharose column and eluted with a Lubrol PX gradient, whereas non-bindable hexokinase and yeast hexokinase were not adsorbed under the similar conditions. These results suggest that mitochondria-bindable hexokinase has a hydrophobic region on its surface, which is responsible for the specific interaction with mitochondria.     

Neisseria gonorrhoeae prepilin export studied in Escherichia coli.

The pilE gene of Neisseria gonorrhoeae MS11 and a series of pilE-phoA gene fusions were expressed in Escherichia coli. The PhoA hybrid proteins were shown to be located in the membrane fraction of the cells, and the prepilin product of the pilE gene was shown to be located exclusively in the cytoplasmic membrane. Analysis of the prepilin-PhoA hybrids showed that the first 20 residues of prepilin can function as an efficient export (signal) sequence. This segment of prepilin includes an unbroken sequence of 8 hydrophobic or neutral residues that form the N-terminal half of a 16-residue hydrophobic region of prepilin. Neither prepilin nor the prepilin-PhoA hybrids were processed by E. coli leader peptidase despite the presence of two consensus cleavage sites for this enzyme just after this hydrophobic region. Comparisons of the specific molecular activities of the four prepilin-PhoA hybrids and analysis of their susceptibility to proteolysis by trypsin and proteinase K in spheroplasts allow us to propose two models for the topology of prepilin in the E. coli cytoplasmic membrane. The bulk of the evidence supports the simplest of the two models, in which prepilin is anchored in the membrane solely by the N-terminal hydrophobic domain, with the extreme N terminus facing the cytoplasm and the longer C terminus facing the periplasm.     

Photochemical labeling of membrane hydrophobic core of human erythrocytes using a new photoactivable reagent 2-[3H]diazofluorene

Photoactivable reagents have been useful for studying the structural aspects of membrane hydrophobic core. We have reported earlier (Anjaneyulu, P.S.R., and Lala, A. K. (1982) FEBS Lett. 146, 165-167) the use of diazofluorene as a probe for fluorescent photochemical labeling of hydrophobic core in artificial membranes. To quantitate and enhance the monitoring ability of this probe, we have synthesized 2-[3H]diazofluorene of high specific activity. This reagent rapidly partitions into phosphatidylcholine vesicles and selectively labels the fatty acyl chains of phosphatidylcholine. The insertion yield (13%) is not affected by the presence of scavengers like reduced glutathione. 2-[3H]Diazofluorene also readily partitions into erythrocyte membranes and on photolysis labels the membrane. The overall insertion was 48% with 9.7% in protein fraction and the rest in lipids. The distribution of radioactivity in labeled protein fraction was restricted to integral membrane proteins with Band 3 being the major protein labeled. There is little or no labeling associated with extrinsic proteins like spectrin. Further analysis of labeled Band 3 by treatment with chymotrypsin indicated that the labeling was restricted to the membrane spanning CH-17 and CH-35 fragments. No labeling of the cytoplasmic fragment of Band 3 could be observed. 2-[3H]Diazofluorene should prove useful for studying integral membrane proteins and their membrane-spanning regions.     

Glucose phosphorylation in tumor cells. Cloning, sequencing, and overexpression in active form of a full-length cDNA encoding a mitochondrial bindable form of hexokinase

In rapidly growing tumor cells exhibiting high glucose catabolic rates, the enzyme hexokinase is markedly elevated and bound in large amounts (50-80% of the total cell activity) to the outer mitochondrial membrane (Arora, K.K., and Pedersen, P.L. (1988) J. Biol. Chem. 263, 17422-17428; Parry, D.M., and Pedersen, P.L. (1983) J. Biol. Chem. 258, 10904-10912). In extending these studies, we have isolated a cDNA clone of hexokinase from a lambda gt11 library of the highly glycolytic, c37 mouse hepatoma cell line. This clone, comprising 4,198 base pairs, contains a single open reading frame of 2,754 nucleotides which encode a 918-amino acid hexokinase with a mass of 102,272 daltons. This enzyme exhibits, respectively, 68 and 32 amino acid differences, including several charge differences, from the recently sequenced human kidney and rat brain enzymes. The putative glucose and ATP binding domains present in the latter two enzymes and in rat liver glucokinase are conserved in the tumor enzyme. At its N-terminal region, tumor hexokinase has a 12-amino acid hydrophobic stretch which is present in the rat brain enzyme but absent in the rat liver glucokinase, a cytoplasmic enzyme. The mature tumor hexokinase protein has been overexpressed in active form in Escherichia coli and purified 9-fold. The overexpressed enzyme binds to rat liver mitochondria in the presence of MgCl2. This is the first report describing the cloning and sequencing of a tumor hexokinase, and the first report documenting the overexpression of any hexokinase type in E. coli. Questions pertinent to the enzyme's mechanism, regulation, binding to mitochondria, and its marked elevation in tumor cells can now be addressed.     

Rat brain hexokinase: location of the substrate nucleotide binding site in a structural domain at the C-terminus of the enzyme

8-Azido-ATP serves as a substrate for rat brain hexokinase (ATP:D-hexose 6-phosphotransferase, EC 2.7.1.1). Irradiation of hexokinase in the presence of this photoactivatable ATP analog results in inactivation of the enzyme. ATP and hexose 6-phosphates (Glc-6-P, 1,5-anhydroglucitol-6-P) previously shown to competitively inhibit nucleotide binding protect the enzyme from photoinactivation; other hexose 6-phosphates do not. Hexoses (Glc, Man) previously shown to enhance nucleotide binding also protect against photoinactivation; other hexoses do not. These effects of hexoses and hexose 6-phosphates can be interpreted in terms of the conformational changes previously shown to result from the binding of these ligands and to influence the characteristics of the nucleotide binding site (M. Baijal and J. E. Wilson (1982) Arch. Biochem. Biophys. 218, 513-524). Limited tryptic cleavage of the enzyme produces three major fragments having molecular weights of about 10K, 40K, and 50K, and thought to represent major structural domains within the enzyme (P. G. Polakis and J. E. Wilson (1984) Arch. Biochem. Biophys. 234, 341-352). Tryptic cleavage of the enzyme, photoinactivated in the presence of 14C-labeled azido-ATP, discloses prominent labeling of the 10K and 40K domains, which are known to originate from the N- and C-terminal regions, respectively. Labeling of the 40K domain is influenced by ligands in a manner that corresponds to the effectiveness of these ligands in protecting against photoinactivation whereas labeling of the 10K domain is not affected by these same ligands. It is concluded that the 40K domain includes the binding site for nucleotide substrates. More refined two-dimensional peptide mapping techniques demonstrate that the predominant site of labeling is a peptide segment, molecular weight approximately 20K, that is located in the central and/or C-terminal region of the 40K domain. Labeling of the 10K domain is attributed to nonspecific interaction of azido-ATP with the hydrophobic sequence shown to be located at the N-terminus of brain hexokinase (P. G. Polakis and J. E. Wilson (1985) Arch. Biochem. Biophys. 236, 328-337).     

Amino acid residues before the hydrophobic region which are critical for membrane translocation of the N-terminal domain of synaptotagmin II.

We examined the fine structure of the type I signal-anchor sequence of synaptotagmin II, which has a 60-residue N-terminal domain followed by a hydrophobic region (H-region), focusing on the hinge region between the N-terminal and the H-regions. It was found that the charged or highly polar residues support the translocation of the N-terminal domain through the endoplasmic reticulum membrane at specific positions in the hinge. The residue requirement correlated with the turn propensity scale for transmembranes. It is suggested that a certain conformation, likely helical hairpin, in the hinge is critical for N-terminal domain translocation.     

Molecular cloning and sequence analysis of the cDNA for small proteoglycan II of bovine bone.

The cDNA for the full-length core protein of the small chondroitin sulphate proteoglycan II of bovine bone was cloned and sequenced. A 1.3 kb clone (lambda Pg28) was identified by plaque hybridization with a previously isolated 1.0 kb proteoglycan cDNA clone (lambda Pg20), positively identified previously by polyclonal and monoclonal antibody reactivity and by hybrid-selected translation in vitro [Day, Ramis, Fisher, Gehron Robey, Termine & Young (1986) Nucleic Acids Res. 14, 9861-9876]. The cDNA sequences of both clones were identical in areas of overlap. The 360-amino-acid-residue protein contains a 30-residue propeptide of which the first 15 residues are highly hydrophobic. The mature protein consists of 330 amino acid residues corresponding to an Mr of 36,383. The core protein contains three potential glycosaminoglycan-attachment sites (Ser-Gly), only one of which is within a ten-amino-acid-residue homologous sequence seen at the known attachment sites of related small proteoglycans. Comparisons of the published 24-residue N-terminal protein sequence of bovine skin proteoglycan II core protein with the corresponding region in the deduced sequence of the bovine core protein reveals complete homology. Comparison of the cDNA-derived sequences of bovine bone and human embryonic fibroblast proteoglycans shows a hypervariable region near the N-terminus. Nucleotide homology between bone and fibroblast core proteins was 87% and amino acid homology was 90%.     

Control of the transmembrane orientation and interhelical interactions within membranes by hydrophobic helix length

We examined the effect of the length of the hydrophobic core of Lys-flanked poly(Leu) peptides on their behavior when inserted into model membranes. Peptide structure and membrane location were assessed by the fluorescence emission lambdamax of a Trp residue in the center of the peptide sequence, the quenching of Trp fluorescence by nitroxide-labeled lipids (parallax analysis), and circular dichroism. Peptides in which the hydrophobic core varied in length from 11 to 23 residues were found to be largely alpha-helical when inserted into the bilayer. In dioleoylphosphatidylcholine (diC18:1PC) bilayers, a peptide with a 19-residue hydrophobic core exhibited highly blue-shifted fluorescence, an indication of Trp location in a nonpolar environment, and quenching localized the Trp to the bilayer center, an indication of transmembrane structure. A peptide with an 11-residue hydrophobic core exhibited emission that was red-shifted, suggesting a more polar Trp environment, and quenching showed the Trp was significantly displaced from the bilayer center, indicating that this peptide formed a nontransmembranous structure. A peptide with a 23-residue hydrophobic core gave somewhat red-shifted fluorescence, but quenching demonstrated the Trp was still close to the bilayer center, consistent with a transmembrane structure. Analogous behavior was observed when the behavior of individual peptides was examined in model membranes with various bilayer widths. Other experiments demonstrated that in diC18:1PC bilayers the dilution of the membrane concentration of the peptide with a 23-residue hydrophobic core resulted in a blue shift of fluorescence, suggesting the red-shifted fluorescence at higher peptide concentrations was due to helix oligomerization. The intermolecular self-quenching of rhodamine observed when the peptide was rhodamine-labeled, and the concentration dependence of self-quenching, supported this conclusion. These studies indicate that the mismatch between helix length and bilayer width can control membrane location, orientation, and helix-helix interactions, and thus may mismatch control both membrane protein folding and the interactions between membrane proteins.     

Isolation of the hydrophobic membrane binding domain of rat renal gamma-glutamyl transpeptidase selectively labeled with 3-trifluoromethyl-3-(m-[125I]iodophenyl)diazirine

The membrane-permeable photoactivatable reagent 3-trifluoromethyl-3-(m-[125I]iodophenyl)diazirine was used to selectively label the hydrophobic domain of the amphipathic form of gamma-glutamyl transpeptidase reconstituted into phosphatidylcholine vesicles. The reagent labels only a limited segment of the large subunit of the heterodimeric transpeptidase. Treatment of labeled and reconstituted enzyme with papain causes the release of the unlabeled catalytic domain and the cleavage of the membrane binding domain into two discrete 125I-labeled peptides. The hydrophobic peptides which remain associated with the vesicles were isolated by chromatography on Sephadex LH-60. They exhibit apparent molecular weights of 8700 and 3400. Amino acid analysis indicates that they contain 68 and 58% hydrophobic residues, respectively. The procedures developed in this study should make possible the large scale isolation of the unlabeled membrane binding domain of gamma-glutamyl transpeptidase.     

Disposition of mitochondrially bound hexokinase at the membrane surface, deduced from reactivity with monoclonal antibodies recognizing epitopes of defined location.

A panel of monoclonal antibodies against rat brain hexokinase (ATP: D-hexose 6-phosphotransferase, EC 2.7.1.1) has been employed to investigate the orientation of the mitochondrially bound enzyme on the mitochondrial surface. Based on their ability to immunoprecipitate truncated forms of the protein, obtained by in vitro translation of truncated versions of the mRNA, the epitopes for seven monoclonal antibodies were mapped to regions consisting of 20-50 amino acid residues within the sequence of the N-terminal half of the enzyme. There is extensive sequence similarity between the N- and C-terminal halves of this enzyme, which is thought to have evolved by a process of gene duplication and fusion. However, these antibodies react selectively with epitopes in the N-terminal half, and thus epitopic regions for several of these antibodies could be further defined by eliminating from consideration regions showing substantial sequence similarity with the C-terminal half. The epitope for one of the monoclonal antibodies, designated 4D4, was shown to involve the extreme N-terminus of the enzyme; selective proteolytic modification of this region resulted in loss of immunoreactivity. Relative location of epitopes for three other antibodies, designated 2B, 1C5, and 4C5, within a 20-residue segment was deduced from effects of modifying sulfhydryl residues within this segment on immunoreactivity. Thus, by a combination of sequence analysis and experimental methods, the epitopes for these seven antibodies could be localized to defined regions within the overall sequence. The ability of these antibodies to prevent binding of hexokinase to mitochondria, and their ability to recognize the mitochondrially bound enzyme, provided a basis for assessing the relative proximity of the corresponding epitopes to the mitochondrial surface when the enzyme was bound. The disposition of the bound enzyme on the mitochondrial surface was deduced by relating these results to the proposed structure for brain hexokinase.     

The N-terminal hydrophobic segment of Streptomyces coelicolor FtsY forms a transmembrane structure to stabilize its membrane localization

FtsY is the receptor of the signal recognition particle that mediates the targeting of integral membrane proteins in bacteria. It was shown that in Escherichia coli, the N-terminal region of FtsY contributes to its interaction with the membrane, but it is not inserted into the membrane. However, this study presents evidence that in Streptomyces coelicolor, FtsY has a hydrophobic region at its N-terminus, which forms a membrane insertion structure and contributes significantly to the binding between FtsY and membrane. Through membrane protein extraction followed by immunoblotting, we demonstrated that deletion of the N-terminal residues 11-39 from the S. coelicolor FtsY (ScFtsY) drastically reduced its membrane-binding capability and that the N-terminus of ScFtsY alone was capable of targeting the soluble EGFP protein onto the membrane with high efficiency. Furthermore, in a labeling experiment with the membrane-impermeable probe Mal-PEG, the ScFtsY N-terminal region was protected by the membrane and was not labeled. This observation indicates that this region was inserted into the membrane.     

Rabbit intestinal aminopeptidase N. Purification and molecular properties

The detergent and protease forms of rabbit intestinal aminopeptidase N were purfied for chemical investigations and future specific immunological labeling of the enzyme in situ. The purification of the detergent form required a special technique called 'reverse immunoabsorbant chromatography'. The specific activity of the detergent form finally obtained was identical to that of the protease form. A significant charge micro heterogeneity persisted in the most purified preparations, due probably to a certain level of variability in the sugar moiety. The major proteolytic cleavage which occurred at the hydrophilic-hydrophobic junction of the detergent form during its conversion into the protease form was well defined. But additional splittings probably in C-terminal region of the molecules led to several protease forms differing by their size. The molecular weight assigned to the peptide liberated during the above conversion was overestimated due to preferential detergent binding to hydrophobic structures. The correct value, estimated by a new isotopic dilution method, was 3800 (36-38 residues) for the peptide originating from the rabbit enzyme. The real anchor plunging into the membrane core is possibly still shorter. Comparative N-terminal residue determinations in the detergent form, the protease form and the peptide difinitely confirmed that the enzyme is anchored to the bursh border membrane by its N-terminal region.     

Identification of the pH-dependent membrane anchor of carboxypeptidase E (EC 3.4.17.10)

Carboxypeptidase E (CPE), a peptide hormone-processing enzyme, is present within secretory granules in both a soluble form and a form which is membrane-bound at pH 5.5 but soluble at neutral pH. Antisera raised against a peptide corresponding to the predicted COOH-terminus of CPE bind to the membrane-associated form of CPE but not to the soluble form. This COOH-terminal region is predicted to form an amphiphilic alpha-helix, containing several pairs of hydrophobic residues separated by hydrophilic residues. Synthetic COOH-terminal peptides 11-24 residues in length are able to bind to bovine pituitary membranes and can be extracted by conditions that extract the membrane-bound form of CPE. The influence of pH on the membrane binding of a 21-residue COOH-terminal peptide is similar to the membrane binding of CPE: at pH values less than 6 the majority of the peptide is membrane-bound, while at pH values above 8 less than 20% is membrane-bound. Both the 21-residue COOH-terminal peptide and the purified membrane form of CPE, but not the soluble form, partition into Triton X-114 only at low pH (pH less than 6). Combined polar and hydrophobic interactions of the COOH-terminal peptide appear to be responsible for the reversible, pH-dependent association of CPE with membranes.     

Genetic analyses of processing involving C-terminal cleavage in penicillin-binding protein 3 of Escherichia coli.

The processing of Escherichia coli penicillin-binding protein 3 (PBP 3) was investigated by gene manipulation for producing hybrid and truncated PBP 3 molecules. The hybrid PBP 3 was processed when the N-terminal 40 residues of PBP 3 were replaced by the murein lipoprotein signal peptide which lacked the cysteine residue for processing and followed by seven extra linker residues. In contrast, the PBP 3 molecules truncated at Thr-560 (28-residue deletion) or at Thr-497 (91-residue deletion) were not processed, and those truncated at Phe-576 (12-residue deletion) were processed at a greatly reduced rate. The results indicate that the C-terminal part, rather than the N-terminal part, is involved in the processing. This was supported by the result that the purified mature PBP 3 retained the complete N-terminal sequence with Met for translation initiation. The cleavage at the C-terminal region was shown by the loss of [35S]cysteine label when the cysteine-free hybrid PBP 3 joined to a cysteine-rich extra peptide tail was processed into the mature form. Confirmative assays for processing of PBP 3 were aided by a newly found prc mutant, defective in the processing involving the C-terminal region. A plasmid that directs PBP 3 truncated at Thr-560 complemented a thermosensitive PBP 3 mutation, but the truncated product was unstable in vivo. This suggests the importance of C-terminal hydrophobic regions that terminate at Leu-558 to PBP 3 functioning and the requirement of further-distal peptides for the stability of PBP 3.     

A structural motif of acetylcholinesterase that promotes amyloid beta-peptide fibril formation

Acetylcholinesterase (AChE) has been found to be associated with the core of senile plaques. We have shown that AChE interacts with the amyloid beta-peptide (Abeta) and promotes amyloid fibril formation by a hydrophobic environment close to the peripheral anionic binding site (PAS) of the enzyme. Here we present evidence for the structural motif of AChE involved in this interaction. First, we modeled the docking of Abeta onto the structure of Torpedo californica AChE, and identified four potential sites for AChE-Abeta complex formation. One of these, Site I, spans a major hydrophobic sequence exposed on the surface of AChE, which had been previously shown to interact with liposomes [Shin et al. (1996) Protein Sci. 5, 42-51]. Second, we examined several AChE-derived peptides and found that a synthetic 35-residue peptide corresponding to the above hydrophobic sequence was able to promote amyloid formation. We also studied the ability to promote amyloid formation of two synthetic 24-residue peptides derived from the sequence of a Omega-loop, which has been suggested as an AChE-Abeta interacting motif. Kinetic analyses indicate that only the 35-residue hydrophobic peptide mimics the effect of intact AChE on amyloid formation. Moreover, RP-HPLC analysis revealed that the 35-residue peptide was incorporated into the growing Abeta-fibrils. Finally, fluorescence binding studies showed that this peptide binds Abeta with a K(d) = 184 microM, independent of salt concentration, indicating that the interaction is primarily hydrophobic. Our results indicate that the homologous human AChE motif is capable of accelerating Abeta fibrillogenesis.     

The effect of insulin on the catalytic efficacy of rat skeletal muscle hexokinase isoenzyme II]

The effect of insulin on the intracellular localization of rat skeletal muscle hexokinase isozyme II (hexokinase II) was studied in vivo. It was found that after injection of the hormone the glucose concentration in the muscle gradually increases in parallel with the hexokinase II redistribution between the cytosol and the mitochondrial fraction in the direction of the bound form of the enzyme. This effect of insulin is due to glucose, an indispensable participant of the complex formation between the enzyme and the mitochondrial membrane. It was shown that the effect of glucose as a hexokinase II adsorbing reagent is a highly specific one. The hexokinase II binding to mitochondria in the presence of glucose is accompanied by changes in some kinetic properties of the enzyme. A kinetic analysis of catalytic efficiency of the free and bound hexokinase II forms revealed that the catalytic efficiency of hexokinase II within the composition of the enzyme-membrane complex exceeds by two orders of magnitude that of the free enzyme. The data obtained are discussed in the framework of an adsorption mechanism of hexokinase activity regulation in the cell.     

In vitro synthesis of rat brain hexokinase

Hexokinase (ATP:D-hexose 6-phosphotransferase, EC 2.7.1.1) has been synthesized in the rabbit reticulocyte lysate system directed by poly(A)+ mRNA isolated from rat brain. Identification of the in vitro synthesis product as hexokinase was based on its immunoprecipitation with anti-hexokinase serum as well as the generation of identical peptide maps after partial cleavage of the in vitro product and authentic hexokinase with Staphylococcus aureus V8 proteinase or chymotrypsin. The in vitro product and authentic hexokinase were indistinguishable in molecular weight (SDS-gel electrophoresis); thus, despite the fact that, in situ, much of the hexokinase in brain is found in association with mitochondria, it is not synthesized in the form of a higher molecular weight precursor as is characteristic of other mitochondrial proteins. This is in accord with the view that hexokinase is best considered as a classical 'soluble' enzyme which is capable of exhibiting reversible association with mitochondria. The in vitro product cochromatographs (during anion-exchange HPLC) with authentic hexokinase previously shown to have a blocked (presumably acetylated) N-terminus; this procedure is capable of resolving the N-terminally blocked form of the enzyme from a partially proteolyzed form having a free N-terminal amino group. Thus the in vitro product is apparently N-acetylated by an enzyme system previously shown to be present in reticulocyte lysates. A significant fraction of the in vitro synthesized hexokinase attained a conformation characteristic of the native enzyme as judged by the observations that it could be immunoprecipitated by monoclonal antibodies recognizing the native enzyme but not by antibodies recognizing denatured hexokinase, and limited tryptic cleavage of the in vitro product gave fragments identical to those seen with the native enzyme and thought to reflect the organization of structural domains in that enzyme. However, based on these same criteria, the majority of the hexokinase synthesized in vitro appears to exist in a folding state that is not identical to that of either the fully denatured or native enzyme.     

Determinants of the enzymatic activity and the subcellular localization of aspartate N-acetyltransferase

Aspartate N-acetyltransferase (NAT8L, N-acetyltransferase 8-like), the enzyme that synthesizes N-acetylaspartate, is membrane-bound and is at least partially associated with the ER (endoplasmic reticulum). The aim of the present study was to determine which regions of the protein are important for its catalytic activity and its subcellular localization. Transfection of truncated forms of NAT8L into HEK (human embryonic kidney)-293T cells indicated that the 68 N-terminal residues (regions 1 and 2) have no importance for the catalytic activity and the subcellular localization of this enzyme, which was exclusively associated with the ER. Mutation of conserved residues that precede (Arg81 and Glu101, in region 3) or follow (Asp168 and Arg220, in region 5) the putative membrane region (region 4) markedly affected the kinetic properties, suggesting that regions 3 and 5 form the catalytic domain and that the membrane region has a loop structure. Evidence is provided for the membrane region comprising α-helices and the catalytic site being cytosolic. Transfection of chimaeric proteins in which GFP (green fluorescent protein) was fused to different regions of NAT8L indicated that the membrane region (region 4) is necessary and sufficient to target NAT8L to the ER. Thus NAT8L is targeted to the ER membrane by a hydrophobic loop that connects two regions of the catalytic domain.     

The HIV-1 gp41 N-terminal heptad repeat plays an essential role in membrane fusion

For many different enveloped viruses the crystal structure of the fusion protein core has been established. A striking conservation in the tertiary and quaternary arrangement of these core structures is repeatedly revealed among members of diverse families. It has been proposed that the primary role of the core involves structural rearrangements which facilitate apposition between viral and target cell membranes. Forming the internal trimeric coiled coil of the core, the N-terminal heptad repeat (NHR) of HIV-1 gp41 was suggested to have additional roles, due to its ability to bind biological membranes. The NHR is adjacent to the N-terminal hydrophobic fusion peptide (FP), which alone can fuse biological membranes. To investigate the role of the NHR in membrane fusion, we synthesized and functionally characterized HIV-1 gp41 peptides corresponding to the FP and NHR alone, as well as continuous peptides made of both FP and NHR (wild type and mutant). We show here that a consecutive, 70-residue peptide consisting of both the FP and NHR (gp41/1-70) has dramatic fusogenic properties. The effect of including the complete NHR, as compared to shorter 23-, 33-, or 52-residue N-terminal peptides, is illustrated by a leap in lipid mixing of phosphatidylcholine (PC) large unilamellar vesicles (LUV) and clearly delineates the synergistic role of the NHR in the fusion event. Furthermore, a mutation in the NHR that renders the virus noninfectious is reflected by a significant reduction in in vitro lipid mixing induced by the mutant, gp41/1-70 (I62D). Additional spectroscopic studies, characterizing membrane binding and apposition induced by the peptides, help to clarify the role of the NHR in membrane fusion.