Functional Role of the Intracellular Loop Linking Transmembrane Domains 6 and 7 of the Human Dipeptide Transporter hPEPT1

The human intestinal di-/tripeptide transporter (hPEPT1) is a 12-transmembrane protein that facilitates transport of peptides from the intestine into the circulation. hPEPT1 is also an important target in oral delivery of drugs, but mechanistic and structural data for the protein are limited. In particular, there is little information on the function of the loops of the transporter. In this study, we show that mutation of several charged residues in the largest intracellular loop of hPEPT1 (loop 6-7, amino acids 224-278) significantly reduces hPEPT1 function. This loop has an asymmetric distribution of charged residues, with only positive charges in the N-terminal half and all five negative charges in the loop located in a small part of the C-terminal half. Point mutagenesis to alanine of three positive residues in the N-terminal half of loop 6-7 and four negative residues in the C-terminal half of the loop significantly reduced glycylsarcosine uptake. E267 was particularly sensitive to mutation, and kinetic analyses of E267A- and E267K-hPEPT1 gave V (max) values 10-fold lower than that for the wild-type protein. Secondary structure prediction suggested that loop 6-7 includes two amphipathic α-helices, with net positive and negative charges, respectively. We interpret the mutagenesis data in terms of interactions of the charged residues in loop 6-7 that may influence conformational changes of hPEPT1 during and after substrate transport.     

Role of terminal dipole charges in aggregation of α-helix pair in the voltage gated K+ channel

The voltage sensor domain (VSD) of the potassium ion channel KvAP is comprised of four (S1–S4) α-helix proteins, which are encompassed by several charged residues. Apart from these charges, each peptide α-helix having two inherent equal and opposite terminal dipolar charges behave like a macrodipole. The activity of voltage gated ion channel is electrostatic, where all the charges (charged residues and dipolar terminal charges) interact with each other and with the transmembrane potential. There are evidences that the role of the charged residues dominate the stabilization of the conformation and the gating process of the ion channel, but the role of the terminal dipolar charges are never considered in such analysis. Here, using electrostatic theory, we have studied the role of the dipolar terminal charges in aggregation of the S3b–S4 helix pair of KvAP in the absence of any external field (V = 0). A system attains stability, when its potential energy reaches minimum values. We have shown that the presence of terminal dipole charges (1) change the total potential energy of the charges on S3b–S4, affecting the stabilization of the α-helix pair within the bilayer lipid membrane and (2) the C- and the N-termini of the α-helices favor a different dielectric medium for enhanced stability. Thus, the dipolar terminal charges play a significant role in the aggregation of the two neighboring α-helices.     

Buried charged surface in proteins

BACKGROUND: The traditional picture of charged amino acids in globular proteins is that they are almost exclusively on the outside exposed to the solvent. Buried charges, when they do occur, are assumed to play an essential role in catalysis and ligand binding, or in stabilizing structure as, for instance, helix caps. RESULTS: By analyzing the amount and distribution of buried charged surface and charges in proteins over a broad range of protein sizes, we show that buried charge is much more common than is generally believed. We also show that the amount of buried charge rises with protein size in a manner which differs from other types of surfaces, especially aromatic and polar uncharged surfaces. In large proteins such as hemocyanin, 35% of all charges are greater than 75% buried. Furthermore, at all sizes few charged groups are fully exposed. As an experimental test, we show that replacement of the buried D178 of muconate lactonizing enzyme by N stabilizes the enzyme by 4.2 degrees C without any change in crystallographic structure. In addition, free energy calculations of stability support the experimental results. CONCLUSIONS: Nature may use charge burial to reduce protein stability; not all buried charges are fully stabilized by a prearranged protein environment. Consistent with this view, thermophilic proteins often have less buried charge. Modifying the amount of buried charge at carefully chosen sites may thus provide a general route for changing the thermophilicity or psychrophilicity of proteins.     

A quantitative model for partition in aqueous multiphase systems.

A model for the partition of charged molecules in aqueous multiphase systems has been developed. The partition coefficient of one component, or the overall partition coefficient of a number of components, between two arbitrary phases is expressed in terms of the difference in electrical potential between the phases (due to electrolytes present in the system), the net charges of the partitioned components and their partition coefficients in a (sometimes hypothetical) uncharged state. The fraction of material in one phase has also been described as a function of the net charges of the partitioned components. The model fits well to experimental data for partition of chromate, pyridine, ribonuclease A, two types of CO-hemoglobin and an enzyme mixture (yeast lysate) in three-phase systems consisting of poly(ethylene glycol), dextran, Ficoll and water. Minor deviations from the model are construed to be a pH-dependent uptake of ions. The data have also been used to detect differences in solvation of similar proteins, as well as the presence of several forms of some glycolytic enzymes present in yeast lysate.     

Exploring the DNA mimicry of the Ocr protein of phage T7

DNA mimic proteins have evolved to control DNA-binding proteins by competing with the target DNA for binding to the protein. The Ocr protein of bacteriophage T7 is the most studied DNA mimic and functions to block the DNA-binding groove of Type I DNA restriction/modification enzymes. This binding prevents the enzyme from cleaving invading phage DNA. Each 116 amino acid monomer of the Ocr dimer has an unusual amino acid composition with 34 negatively charged side chains but only 6 positively charged side chains. Extensive mutagenesis of the charges of Ocr revealed a regression of Ocr activity from wild-type activity to partial activity then to variants inactive in antirestriction but deleterious for cell viability and lastly to totally inactive variants with no deleterious effect on cell viability. Throughout the mutagenesis the Ocr mutant proteins retained their folding. Our results show that the extreme bias in charged amino acids is not necessary for antirestriction activity but that less charged variants can affect cell viability by leading to restriction proficient but modification deficient cell phenotypes.     

Conservation of local electric fields in the evolution of Cu,Zn superoxide dismutase

The trend of the electric field and the value of the electric field flux, sensed by the superoxide substrate in the proximity of the active site, were found to be constant in three highly homologous Cu,Zn superoxide dismutases from ox, pig and sheep, which display large differences in net protein charge and distribution of electrically charged surface residues but very similar catalytic rate constants. The spatial relationship of charges on the protein surface apparently has been conserved during the evolution of this enzyme to create electrostatic facilitation of catalysis.     

Sensitive enzyme assays based on the production of chemiluminescent leaving groups

A new type of synthetic peptide substrate for amidase assay has been devised. The substrates are luminogenic, with potential for extremely high sensitivity, and are here exemplified by Boc- and Z-Ala-Ala-Phe-isoluminol amide. The synthetic substrates were designed to release isoluminol when hydrolyzed by enzyme; isoluminol production was determined by measuring its chemiluminescence. Kinetic constants of the luminogenic substrates were measured with α-chymotrypsin; and levels of the enzyme as low as 50 ng were determined conveniently. A comparison of similar luminogenic, chromogenic, and fluorogenic substrates is presented.     

Spatial order as a source of kinetic cooperativity in organized bound enzyme systems.

When enzyme molecules are distributed within a negatively charged matrix, the kinetics of the conversion of a negatively charged substrate into a product depends on the organization of fixed charges and bound enzyme molecules. Organization is taken to mean the existence of macroscopic heterogeneity in the distribution of fixed charge density, or of bound enzyme density, or of both. The degree of organization is quantitatively expressed by the monovariate moments of charge and enzyme distributions as well as by the bivariate moments of these two distributions. The overall reaction rate of the bound enzyme system may be expressed in terms of the monovariate moments of the charge density and of the bivariate moments of charge and enzyme densities. The monovariate moments of enzyme density do not affect the reaction rate. With respect to the situation where the fixed charges and enzyme molecules are randomly distributed in the matrix, the molecular organization, as expressed by these two types of moments, generates an increase or decrease of the overall reaction rate as well as a cooperativity of the kinetic response of the system. Thus both the alteration of the rate and the modulation of cooperativity are the consequence of a spatial organization of charges with respect to the enzyme molecules. The rate equations have been derived for different types of organization of fixed charges and enzyme molecules, namely, clustered charges and homogeneously distributed enzyme molecules, clustered enzyme molecules and homogeneously distributed charges, clusters of charges and clusters of enzymes that partly overlap, and clusters of enzymes and clusters of charges that are exactly superimposed. Computer simulations of these equations show how spatial molecular organization may modulate the overall reaction rate.     

Solution structure and dynamics of mouse ARMET

ARMET is an endoplasmic reticulum (ER) stress-inducible protein that is required for maintaining cell viability under ER stress conditions. However, the exact molecular mechanisms by which ARMET protects cells are unknown. Here, we have analyzed the solution structure of ARMET. ARMET has an entirely α-helical structure, which is composed of two distinct domains. Positive charges are dispersed on the surfaces of both domains and across a linker structure. Trypsin digestion and ¹⁵N relaxation experiments indicate that the tumbling of the N-terminal and C-terminal domains is effectively independent. These results suggest that ARMET may hold a negatively charged molecule using the two positively charged domains.     

Enantioselectivity of alcohol dehydrogenase-catalyzed oxidation of 1,2-diols and aminoalcohols

The alcohol dehydrogenase from horse liver is able to catalyze the oxidation of a number of 1,2-diols and α-aminoalcohols enantioselectively to l-α-hydroxyaldehydes and l-α-amino aldehydes. A decrease of enantioselectivity was found in reactions with 1,3-diols and substrates with hydrophobic substituent at position 3. α-Aminoalcohols are not substrates for yeast alcohol dehydrogenase, but the enzyme can catalyze the oxidation of most of the diols to l-hydroxyaldehydes. New methods for determination of the optical purity of α-hydroxy-and α-aminoaldehydes via converting them in situ to the corresponding acids, catalyzed by the aldehyde dehydrogenase from yeast, have been developed. The coupled alcohol dehydrogenase/aldehyde dehydrogenase has been extended to preparatory scale synthesis of optically pure l-α-hydroxyacids in the presence of a cofactor regeneration system. The active-site cubic-space section model has been shown not to be applicable to all substrates.     

The electrostatic potential of Escherichia coli dihydrofolate reductase

Escherichia coli dihydrofolate reductase (DHFR) carries a net charge of -10 electrons yet it binds ligands with net charges of -4 (NADPH) and -2 (folate or dihydrofolate). Evaluation and analysis of the electrostatic potential of the enzyme give insight as to how this is accomplished. The results show that the enzyme is covered by an overall negative potential (as expected) except for the ligand binding sites, which are located inside "pockets" of positive potential that enable the enzyme to bind the negatively charged ligands. The electrostatic potential can be related to the asymmetric distribution of charged residues in the enzyme. The asymmetric charge distribution, along with the dielectric boundary that occurs at the solvent-protein interface, is analogous to the situation occurring in superoxide dismutase. Thus DHFR is another case where the shape of the active site focuses electric fields out into solution. The positive electrostatic potential at the entrance of the ligand binding site in E. coli DHFR is shown to be a direct consequence of the presence of three positively charged residues at positions 32, 52, and 57--residues which have also been shown recently to contribute significantly to electronic polarization of the ligand folate. The latter has been postulated to be involved in the catalytic process. A similar structural motif of three positively charged amino acids that gives rise to a positive potential at the entrance to the active site is also found in DHFR from chicken liver, and is suggested to be a common feature in DHFRs from many species. It is noted that, although the net charges of DHFRs from different species vary from +3 to -10, the enzymes are able to bind the same negatively charged ligands, and perform the same catalytic function.     

A Novel Synthesis of (±)-Munduserone via Acetylenic Intermediates

A riboflavin α-glucoside-synthesizing enzyme from the acetone powder of pig liver was purified by a procedure including fractionation with ammonium sulfate, heat treatment, fractionation with acetone, gel filtration on a Sephadex G-150 column, calcium phosphate gel treatment, and isoelectric focusing. A final enzyme preparation was homogeneous on polyacrylamide disc gel electrophoresis and in the ultracentrifuge. The enzyme had a sedimentation coefficient of 9.90 S and an isoelectric point of pH 3.7. The enzyme had a pH optimum at 6.0 with maltose as substrate. The enzyme catalyzed the hydrolysis of diverse kinds of α-glucosidic substrates, and the transfer of α-glucosyl residue from these substrates to riboflavin. The Km value for maltose was 1.20×10^?3m. The enzyme hydrolyzed phenyl α-maltoside to glucose and phenyl α-glucoside. Amylose was almost completely hydrolyzed to glucose by the enzyme. Maltotriose was obtained as the main transfer product after the treatment of maltose with the enzyme. The enzyme also catalyzed the transfer of α-glucosyl residue from maltose to pyridoxine, esculin, rutin, and adenosine. It was recognized that a single enzyme catalyzed not only the hydrolysis of maltose and α-glucosidic substrates but also the transfer of the α-glucosyl residue of these substrates to suitable acceptors.     

The influence of a surface charge on the electronic and steric structure of a high potential iron-sulfur protein

The recombinant high-potential iron-sulfur protein (HiPIP) iso-I from Ectothiorhodospira halophila has been mutated at position 68. The αC of Val 68 is within a 0.6-nm sphere from the closest iron ion of the cluster. The valine residue has been replaced by a negatively charged glutamate residue (V68E) and by a positively charged lysine residue (V68K). With respect to the recombinant wild-type protein the reduction potentials of the V68E and V68K variants are –21±2 and +29±2?mV respectively (200?mM NaCl, pH?7, 25??°C). The solution structure of the V68E mutant was solved up to a pairwise RMSD of 66?pm for backbone atoms and 138?pm for all heavy atoms. The structure of the variant is very similar to that of recombinant wild type, indicating that the observed changes in reduction potentials are largely due to the effect of the introduced charges. It is proposed that the valence distribution within the oxidized iron-sulfur cluster is affected only slightly by the change in charge at position 68, but consistently with a simple electrostatic model.     

Electrostatic interactions of charged groups in an aqueous medium and their effect on the formation of the secondary structures of polypeptide chains

Analysis of experimental data shows that interaction of charges in an aqueous medium is satisfactorily evaluated by macroscopic dielectric water permeability even at small (approximately 3--4 A) distances. It has been shown that a non-polar molecule located between the charges weakens their interaction. At the same time interaction between charges situated on the non-polar molecules somewhat increases. An estimate is made of the free energy loss of alpha- and beta-structures of polypeptides, resulting from the insertion of charged groups as well as of the free energy of interactions involving charged groups in different secondary structures.     

Topology of eukaryotic type II membrane proteins: importance of N-terminal positively charged residues flanking the hydrophobic domain

We have tested the role of different charged residues flanking the sides of the signal/anchor (S/A) domain of a eukaryotic type II (N(cyt)C(exo)) integral membrane protein in determining its topology. The removal of positively charged residues on the N-terminal side of the S/A yields proteins with an inverted topology, while the addition of positively charged residues to only the C-terminal side has very little effect on orientation. Expression of chimeric proteins composed of domains from a type II protein (HN) and the oppositely oriented membrane protein M2 indicates that the HN N-terminal domain is sufficient to confer a type II topology and that the M2 N-terminal ectodomain can direct a type II topology when modified by adding positively charged residues. These data suggest that eukaryotic membrane protein topology is governed by the presence or absence of an N-terminal signal for retention in the cytoplasm that is composed in part of positive charges.     

Unusual secondary specificity of prolyl oligopeptidase and the different reactivities of its two forms toward charged substrates.

Prolyl oligopeptidase belongs to a new family of serine proteases which contains both exo- and endopeptidases, and this suggests that the enzyme binds its substrate in a special manner. Its secondary specificity, i.e., its interaction with the other residues linked to the proline that accounts for the primary specificity, has been investigated by using peptide substrates of various length and charge. Elongation of the classic dipeptide substrate Z-Gly-Pro-2-naphthylamide with 1-3 residues (Gln, Ala-Gln, Ala-Ala-Gln, and Ala-Lys-Gln) resulted in decreased specificity rate constants. This indicated a limited binding site for prolyl oligopeptidase, a major difference from the finding with other serine endopeptidases. Insertion of charged residues into the substrates, such as lysine or aspartic acid, considerably affected the rates and the pH-rate profiles. The rate constants were higher with the positively charged peptides and lower with the substrates bearing a negative charge. These electrostatic effects were reduced at high ionic strength. The results can be interpreted in terms of a negatively charged active site, which exists at high pH and exerts electrostatic attraction or repulsion toward charged substrates. The pH dependencies of the rate constants with neutral substrates exhibited roughly bell-shaped curves, whereas with charged substrates the existence of two active enzyme forms was clearly demonstrated. The physiologically competent high pH form preferred positively charged substrates (Z-Lys-Pro-2-(4-methoxy)naphthylamide, Z-Ala-Lys-Gln-Gly-Pro-2-naphthylamide), whereas the low pH form reacted faster with the negatively charged substrate (Z-Asp-Gly-Pro-2-naphthylamide).(ABSTRACT TRUNCATED AT 250 WORDS)     

Cleavage-site specificity of prolyl endopeptidase FAP investigated with a full-length protein substrate

Fibroblast activation protein (FAP) is a prolyl-cleaving endopeptidase proposed as an anti-cancer drug target. It is necessary to define its cleavage-site specificity to facilitate the identification of its in vivo substrates and to understand its biological functions. We found that the previously identified substrate of FAP, α(2)-anti-plasmin, is not a robust substrate in vitro. Instead, an intracellular protein, SPRY2, is cleavable by FAP and more suitable for investigation of its substrate specificity in the context of the full-length globular protein. FAP prefers uncharged residues, including small or bulky hydrophobic amino acids, but not charged amino acids, especially acidic residue at P1', P3 and P4 sites. Molecular modelling analysis shows that the substrate-binding site of FAP is surrounded by multiple tyrosine residues and some negatively charged residues, which may exert least preference for substrates with acidic residues. This provides an explanation why FAP cannot cleave interleukins, which have a glutamate at either P4 or P2', despite their P3-P2-P1 sites being identical to SPRY2 or α-AP. Our study provided new information on FAP cleavage-site specificity, which differs from the data obtained by profiling with a peptide library or with the denatured protein, gelatin, as the substrate. Furthermore, our study suggests that negatively charged residues should be avoided when designing FAP inhibitors.     

Modelling the three-dimensional structure and electrostatic potential field of the two Cu,Zn superoxide dismutase variants from Xenopus laevis

The crystallographic structure of bovine superoxide dismutase has been used as a template for the graphic reconstruction of the three-dimensional structures of the two Xenopus laevis variants (Schininà, M.E. et al. Arch. Biochem. Biophys. 272:507-515, 1989). In these models the structure-essential residues maintain their position and their structural role, and the interactions between the subunits and the close packing within the beta-barrel are maintained with conservative substitutions and even increased with "aromatic pairs." Because of the same topological motif and surface location of charges, arising from the model building of the two variants with respect to the bovine enzyme, we have calculated the electrostatic potential fields around the models of the two Xenopus laevis variants by numerically solving the Poisson-Boltzmann equation. We show that conservation of a specific space-relationship of charges maintains the potential field pattern already observed in the bovine enzyme, where a negative potential field surrounds the protein surface and specific positive regions wrap up the copper center active site. This electrostatic potential field distribution supports the idea that electrostatic interactions control, like in the bovine enzyme, the mechanism of enzyme-substrate recognition in the Xenopus laevis Cu,Zn superoxide dismutases, suggesting that coordinated mutation of charged residues has occurred in the evolution of this enzyme.     

The influence of charge and the distribution of charge in the polar region of phospholipids on the activity of UDP-glucuronosyltransferase.

Studies of the mechanism of lipid-induced regulation of the microsomal enzyme UDP-glucuronosyltransferase have been extended by examining the influence of charge within the polar region on the ability of lipids to activate delipidated pure enzyme. The effects of net negative charge, of charge separation in phosphocholine, and of the distribution of charge in the polar region of lipids were studied using the GT2p isoform isolated from pig liver. Prior experiments have shown that lipids with net negative charge inhibit the enzyme (Zakim, D., Cantor, M., and Eibl, H. (1988) J. Biol. Chem. 263, 5164-5169). The current experiments show that the extent of inhibition on a molar basis increases as the net negative charge increases from -1 to -2. The inhibitory effect of negatively charged lipids is on the functional state of the enzyme and is not due to electrostatic repulsion of negatively charged substrates of the enzyme. Although the inhibitory effect of net negative charge is removed when negative charge is balanced by a positive charge due to a quaternary nitrogen, neutrality of the polar region is not a sufficient condition for activation of the enzyme. In addition to a balance of charge between Pi and the quaternary nitrogen, the distance between the negative and positive charges and the orientation of the dipole created by them are critical for activation of GT2p. The negative and positive charges must be separated by the equivalent of three -CH2- groups for optimal activation by a lipid. Shortening this distance by one -CH2- unit leads to a lipid that is ineffective in activating the enzyme. Reversal of the orientation of the dipole in which the negative charge is on the polymethylene side of the lipid-water interface and the positive charge extends into water also produces a lipid that is not effective for activating GT2p. On the other hand, lipids with phosphoserine as the polar region, which has the "normal" P-N distance but carries a net negative charge, do not inhibit GT2p. This result again illustrates the importance of the dipole of phosphocholine for modulating the functional state of GT2p.     

Rat mast cell carboxypeptidase: amino acid sequence and evidence of enzyme activity within mast cell granules

The amino acid sequence of rat mast cell carboxypeptidase has been determined. The major form has 308 residues; a minor form has an additional (glutamyl) residue at the amino terminus that may indicate an alternate cleavage site during zymogen activation. The enzyme is homologous to pancreatic carboxypeptidases A and B, with conservation of the functional amino acid residues of the active site. The putative substrate binding site resembles that of carboxypeptidase A, although other structural features bear more similarity to carboxypeptidase B. Mast cell carboxypeptidase retains enzymatic activity toward a peptide substrate (angiotensin I) while bound within the granular matrix of the rat connective tissue mast cells. Evidence is presented to suggest that a cluster of positively charged lysyl and arginyl residues binds the enzyme to the negatively charged heparin of the granular matrix but leaves the active site exposed to bind and cleave peptide substrates.