Vitamin E: inhibition of retinol-induced hemolysis and membrane-stabilizing behavior.

For the elucidation of the mechanism of membrane stabilization by vitamin E, the effects of alpha-tocopherol and its model compounds on either retinol-induced hemolysis of rabbit erythrocytes or the permeability and fluidity of liposomal membranes have been studied. Retinol-induced rabbit erythrocyte hemolysis has been found not to be caused by the oxidative disruption of erythrocyte membrane lipids initiated by retinol oxidation, but rather to arise from physical damage of the membrane micelle induced by penetration of retinol molecules. In suppressing hemolysis, alpha-tocopherol was more effective than other naturally occurring tocopherols. alpha-Tocopheryl acetate, nicotinate, and 6-deoxy-alpha-tocopherol were more effective than alpha-tocopherol itself. The inhibitory effects of alpha-tocopherol model compounds having side chains with at least two isoprene units or a long straight chain instead of the isoprenoid side chain were similar to those of alpha-tocopherol. These data suggest that for protection of membranes against retinol-induced damage, the hydroxyl group of alpha-tocopherol is not critical, but rather the chroman ring, three methyl groups on the aromatic ring, and the long side chain are necessary. To verify the mechanism of the inhibitory effect on hemolysis, not only the effect of vitamin E and its model compounds on the membrane permeability and fluidity, but also the mobility of alpha-tocopherol molecule in membranes has been investigated using bilayer liposomes as the model membranes. Addition of alpha-tocopherol to membranes produced a greater decrease in the permeability and fluidity of rat liver phosphatidylcholine liposomes compared with egg yolk phosphatidylcholine liposomes. In dipalmitoylphosphatidylcholine liposomes, however, alpha-tocopherol was less effective, that is, the more unsaturated the lipids, the more they interact with alpha-tocopherol. 2,2,5,7,8-Pentamethyl-6-chromanol with no isoprenoid side chain and phytol without the chromanol moiety had no effect. The measurement of 13C NMR relaxation times revealed that the mobility of methyl groups on the aromatic ring of alpha-tocopherol in membranes is significantly restricted. In contrast, the methyl groups at positions 4'a and 8'a on the isoprenoid side chain have high degrees of motional freedom in the lipid core of membranes. Furthermore, it was found that alpha-tocopherol in membranes interacts with chromate ions added as potassium chromate outside the membranes, resulting in an increase in membrane fluidity. These results are compatible with those of the inhibitory effect on retinol-induced erythrocyte hemolysis. On the basis of the results obtained here, a possible mechanism for membrane stabilization by vitamin E is proposed.     

Membrane-stabilizing effect of vitamin E: effect of alpha-tocopherol and its model compounds on fluidity of lecithin liposomes

The effects of vitamin E (alpha-tocopherol) and its model compounds on the fluidity of liposomes composed of dipalmitoylphosphatidylcholin (DPPC) and fatty acids were investigated by the measurement of the fluorescent polarization (P) using 1,6-diphenyl-1,3,5-hexatriene (DPH) as a plobe. Although all tocopherols decreased the fluidity of liposomes which was perturbed by the inclusion of an unsaturated fatty acid having more than one double bond, alpha-tocopherol was more effective than the others. The fluidity in arachidonic acid-containing liposomes was decreased most in the presence of alpha-tocopherol and was decreased considerably by the inclusion of model compounds having a side chain at least one isoprene unit or a long straight chain instead of isoprenoid side chain. However, the chromanol with methyl group instead of the above side chain, and phytol, having no chromanol moiety, had no effect. These results show that a structural requirement for a membrane stabilization is to be either the chromanol moiety with methyl groups born on its aromatic ring or a side chain of appropriate length; an isoprenoid side chain of full length or one containing 4'a- and 8'a-methyl groups is not necessarily needed.     

Synthesis and antioxidative activity of structural analogs of vitamin E

Analogues of alpha-tocopherol with modified structure of side isoprenoid chain and chroman nucleus have been synthesised. The influence of chromanol structure on the dynamic of oxidation products formation have been investigated on models of induced and noninduced bulk-phase peroxidation of ethyl linoleate in presence of 2.3.10(-3)-1.2.10(-2) M alpha-tocopherol and the synthesised compounds.     

An increase in side chain entropy facilitates effector binding: NMR characterization of the side chain methyl group dynamics in Cdc42Hs

Cdc42Hs is a signal transduction protein that is involved in cytoskeletal growth and organization. We describe here the methyl side chain dynamics of three forms of (2)H,(13)C,(15)N-Cdc42Hs [GDP-bound (inactive), GMPPCP-bound (active), and GMPPCP/PBD46-bound (effector-bound)] from (13)C-(1)H NMR measurements of deuterium T(1) and T(1 rho) relaxation times. A wide variation in flexibility was observed throughout the protein, with methyl axis order parameters (S(2)(axis)) ranging from 0.2 to 0.4 (highly disordered) in regions near the PBD46 binding site to 0.8--1.0 (highly ordered) in some helices. The side chain dynamics of the GDP and GMPPCP forms are similar, with methyl groups on the PBD46 binding surface experiencing significantly greater mobility (lower S(2)(axis)) than those not on the binding surface. Binding of PBD46 results in a significant increase in the disorder and a corresponding increase in entropy for the majority of methyl groups. Many of the methyl groups that experience an increase in mobility are found in residues that are not part of the PBD46 binding interface. This entropy gain represents a favorable contribution to the overall entropy of effector binding and partially offsets unfavorable entropy losses such as those that occur in the backbone.     

The role of isoprenoid chain of alpha-tocopherol in the protection of synaptosomes against lipid peroxidation and phospholipase A2-induced damage

The role of the alpha-tocopherol molecule isoprenoid chain in synaptosomal membrane protection from lipid peroxidation activation and phospholipase A2 damage was investigated. A comparative study of alpha-tocopherol analogs differing in the length of the isoprenoid chain revealed that the increase in the chain length results in a decrease of the efficiency of inhibition in the course of synaptosomal lipid peroxidation activation. This effect is due to the diminution of mobility of chromanols in the lipid bilayer which is associated with an increase in the length of the isoprenoid fragment. The decreased efficiency of lipid peroxidation inhibition resulting from the lengthening of the chromanol nucleus phytol chain is concomitant with the appearance of new stabilizing properties, e. g., the ability to protect synaptosomal membranes from the damaging action of phospholipase A2. This effect is lost with a decrease in the length of the chromanol isoprenoid chain.     

Arabinogalactan from Western larch, Part III: alkaline degradation revisited, with novel conclusions on molecular structure

Alkaline degradation of larch arabinogalactan (AG) involves rapid peeling of the (1→3)-galactan main chain from the reducing end. The products are the original side chains attached to galactometasaccharinic (GalMS) acids derived from main-chain residues. These products have been separated by GPC and studied by compositional, methylation and NMR analyses. Results confirm that in a typical AG molecule most main-chain residues carry a side chain on C-6. About half of these side chains are β-(1→6)-linked Galp dimers, and about a quarter are single Galp residues. The rest contain three or more residues and include most of the Ara (arabinose) found in the polysaccharide. About one-fifth of the original Ara is consumed by the peeling reaction, and Ara groups at the non-reducing end of the main chain are proposed, predominantly as arabinobiosyl groups [β-l-Arap-(1→3)-L-Araf-(1→.. In general for the larger side chains abundance decreases with size, while branching and Ara content increase with size. Most terminal Araf residues occur in three- and four-residue side chains, while most arabinobiosyl groups are found in side chains of more than three residues. The Ara probably occurs only as these monomeric or dimeric groups, and since no Ara is found in side chains smaller than three residues, this implies that there are no Ara branches attached directly to the main chain.     

Comparative study of the effect of alpha-tocopherol, its synthetic metabolite and ionol on dexamethasone-induced apoptosis in rat thymocytes

alpha-Tocopherol was found to decrease the level of rat thymocytes DNA fragmentation and to increase the viability of these cells under apoptosis induction by dexamethazone. So the antiapoptotic role of this vitamin is suggested. In contrast to alpha-tocopherol synthetic antioxidant ionol and alpha-tocopherylacetate, contained only 6 carbon atoms in its isoprenoid side chain caused the cell death from necrosis. This process preceded the apoptosis stimulated by dexamethazone.     

Ubiquinones have surface-active properties suited to transport electrons and protons across membranes

Surface-active properties of ubiquinones and ubiquinols have been investigated by monomolecular-film techniques. Stable monolayers are formed at an air/water interface by the fully oxidized and reduced forms of the coenzyme; collapse pressures and hence stability of the films tend to increase with decreasing length of the isoprenoid side chain and films of the reduced coenzymes are more stable than those of their oxidized counterparts. Ubiquinone with a side chain of two isoprenoid units does not form stable monolayers at the air/water interface. Mixed monolayers of ubiquinol-10 or ubiquinone-10 with 1,2-dimyristoyl phosphatidylcholine, soya phosphatidylcholine and diphosphatidylglycerol do not exhibit ideal mixing characteristics. At surface pressures less than the collapse pressure of pure ubiquinone-10 monolayers (approx. 12mN.m(-1)) the isoprenoid chain is located substantially within the region occupied by the fatty acyl residues of the phospholipids. With increasing surface pressure the ubiquinones and their fully reduced equivalents are progressively squeezed out from between the phospholipid molecules until, at a pressure of about 35mN.m(-1), the film has surface properties consistent with that of the pure phospholipid monolayer. This suggests that the ubiquinone(ol) forms a separate phase overlying the phospholipid monolayer. The implications of this energetically poised situation, where the quinone(ol) is just able to penetrate the phospholipid film, are considered in terms of the function of ubiquinone(ol) as electron and proton carriers of energy-transducing membranes.     

The relationship between the structure of plastoquinone derivatives and their biological activity in Photosystem II of spinach chloroplasts

The relationship between the structure of reconstituted plastoquinone derivatives and their ability to recover the Hill reaction was investigated by extraction and reconstitution of lyophilized chloroplasts from spinach, followed by monitoring DCIP photoreduction at 600 nm. The results show that: It is not essential that the plastoquinone side chain be an isoprenoid or a phytol; the activity increases with increasing length of the side chain up to 13–15 carbon atoms; for chains longer than 15 carbon atoms, the activity is practically constant. Lipophilic groups (such as -Br) in the side chain increased the activity, hydrophilic groups (such as -OH) decreased the activity. Conjugated double bonds in the side chain decreased the activity greatly, but non-conjugated double bonds had almost no effect on the activity, indicating a requirement of flexibility of the side chain. The activity is decreased in the order of PQ, UbiQ and MQ, showing a large effect of the ring structure.Abbreviations DCIP 2,6-dichlorophenolindophenol - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - Q_A primary electron acceptor in PS II reaction centers - Q_B secondary electron acceptor in PS II reaction centers - PQ _n plastoquinones with an isoprenoid side chain (n, number of the isoprenoid units in the side chain) - PQ-n synthetic plastoquinones with alkyl side chain (n, number of the carbon atoms in the alkyl side chain) - PQ-n synthetic plastoquinones with a double bond in the alkyl side chain - UQ _n ubiquinones with an isoprenoid side chain (n, number of the isoprenoid units in the side chain) - UQ-n synthetic ubiquinones with alkyl side chain (n, number of the carbon atoms in the akyl side chain) - MQ-n 2-alkyl-1,4-naphthoquinone (n, number of the carbon atoms in the alkyl side chain)     

The influence of structure and redox state of prenylquinones on thermotropic phase behaviour of phospholipids in model membranes

Our study was aimed to investigate the significance of the isoprenoid side chain size as well as redox state of the quinone ring for interaction of two main classes of prenylquinones: plastoquinones (PQ) and ubiquinones (UQ) with lipid bilayers. By use of differential scanning calorimetry (DSC) we have followed the thermotropic behaviour of multilamellar vesicles prepared from dipalmitoylphosphatidylcholine (DPPC) upon incorporation of increasing amount (1.3-12 mol%) of quinone (quinol) molecules. Our studies reveal that as the side chain is shorter (from 9 to 2 isoprenoid units) the height of the calorimetric profiles is reduced and the temperature of the main transition of DPPC (T(m)) decreases (T(m)=39.4 degrees C for a sample with 12 mol% of PQ-2), and then increases up to 39.8 degrees C for PQ-1. For the samples containing quinols the effect is more pronounced even at lower concentration. The greater influence of the added prenylquinones on the pretransition demonstrates a stronger distortion of the DPPC packing in the gel state. It seems that this is the isoprenoid side chain length rather than the redox state of prenylquinones that determines their effectiveness in perturbation of thermotropic properties of lipid bilayer.     

Vectorial redox reactions of physiological quinones. I. Requirement of a minimum length of the isoprenoid side chain.

Physiological quinones carrying isoprenoid side chains have been compared with homologues lacking the side chain, for their ability to carry electrons and protons from dithionite to ferricyanide, trapped in liposomes. Six differential observations were made: (1) Plastoquinone and ubiquinones, with a side chain of more than two isoprene units, are by far better mediators than their short-chain homologues. Also other benzoquinones lacking a long side chain are poor catalysts, except dimethyl-methylenedioxy-p-benzoquinone, a highly autooxidizable compound. Tocopherol is a good catalyst. (2) Vitamin K-1 and K-2 are poor mediators compared to vitamin K-3. (3) The reaction catalyzed by quinones carrying long isoprenoid side chains has an about three-fold higher activation energy, irrespective of the catalytic efficiency. (4) The reaction catalyzed by quinones lacking a long side chain follows pseudo first-order kinetics, while the reaction with quinones carrying a long side chain is of apparently higher order. (5) The rate with ubiquinone-1 is increasing pH, while with ubiquinone-9 it is decreasing. (6) The reaction mediated by short-chain quinones seems to be satuarated at lower dithionite concentration. We conclude that isoprenoid quinones are able to translocate electrons and protons in lipid membranes, and that the side chain has a strong impact on the mechanism. This and the relevance of the model reaction for electron and proton transport in photosynthesis and respiration is discussed.     

Membranotropic and pro-oxidative effects of alpha-tocopherol short-chain derivatives

The development of hemolysis and methemoglobin formation under influence of vitamin E derivatives was investigated on the in vitro model of rat red blood cells. It is established, that the shortening of lateral chains of alpha-tocopherol (T), alpha-tocopheryl acetate (TAc) and alpha-tocopheryl quinone (TQ) to 6 atoms of carbon (accordingly C6-T, C6-TAc, C6-TQ) results in occurrence of hemolysis and prooxidative properties, which are not characteristic of derivatives with native length of isoprenoid side chains. Modifications of chroman ring of short-chain derivatives, in turn, bring the contribution to mechanisms of their action. So, the effect of C6-TAc is caused, basically, physical destabilization of a plasmatic membrane, in C6-TQ effect prevails prooxidative mechanism, while C6-T equally shows membrane-destabilizing and prooxidative properties. Thus the derivatives T with the modified structure chroman nucleus and variability of isoprenoid side chains length show absolutely various properties and in each concrete case should be considered as independent biologically active substances irrespective of T properties.     

Comparison of structure of quinone redox site in the mitochondrial cytochrome-bc1 complex and photosystem II (QB site).

A series of nitrophenolic electron-transport inhibitors (2-substituted 4,6-dinitrophenols) of rat liver mitochondrial cytochrome-bc1 complex and of photosystem II (QB site) of spinach thylakoids was synthesized. The structure/inhibitory-activity relationship was examined to elucidate differences in the three-dimensional structure of the quinone redox site in the two systems. These inhibitors occupy the ubiquinone redox site of cytochrome-bc1 complex competitively with natural ubiquinol, probably at a Qo reaction center. The inhibitory activity tended to increase with the length of the 2-substituent, which may correspond to the isoprenoid side chain of ubiquinone and plastoquinone, increased in both experimental systems. However, the strict structural requirements of the 2-substituent for binding to the ubiquinone or plastoquinone redox site were not identical. The alkyl substituents with a branching structure at the alpha-position to the benzene ring were favorable for inhibition of the cytochrome-bc1 complex, but not of photosystem II. Molecular-orbital calculations indicated that the main chain of 2-substituents with an alpha-branching structure was almost perpendicular to the benzene-ring plane because of steric congestion between the alpha-methyl and phenolic OH groups. The main chain of 2-substituents without an alpha-branching structure was flexible. Molecular-orbital studies indicated that ubiquinol was most stable when the portion of the isoprenoid side chain adjacent to the quinol ring was perpendicular to the quinol-ring plane, because of steric congestion by the vicinal OH and methyl groups. The side chain of plastoquinol was flexible because of the lack of a vicinal methyl group. Thus, the difference in the inhibitory activities between the two systems seemed to reflect the difference in the configuration of the isoprenoid side chain of ubiquinone and plastoquinone. These results suggested that the quinone redox site of the cytochrome-bc1 complex may recognize the configuration of the side chain near the quinone ring in the strict sense, whereas that of photosystem II (QB site) may recognize it in a loose sense.     

Ionization properties of titratable groups in ribonuclease T1. I. pKa values in the native state determined by two-dimensional heteronuclear NMR spectroscopy

pKa values of amino acid side chains of ribonuclease T1 have been determined from the pH dependence of 13C and 15N resonances. It was possible to derive pKa values of single protonation or deprotonation sites of carboxylate and imidazole groups. Deviations from pKa values of free amino acids could be interpreted with electrostatic interactions of corresponding side chains with the protein environment. In particular, the interaction between H27 and E82 led to an increase of the H27 pKa and a decrease of the E82 pKa. The pKa of E28 at the C-terminal end of the alpha-helix was increased because of the dipolar character of the alpha-helix. D76 did not titrate in the investigated pH range of about 2-9. From the chemical shift value this buried side chain seems to be protonated. The pKa values of side chains in the active site deviate from a normal behaviour. The lower pKa value of E58 may be interpreted with the close proximity of this side chain with positively charged H40 and R77. A novel two-dimensional 1H(13Cdelta)13Cgamma correlation experiment was developed to observe the pH dependence of the chemical shifts of the Cgamma resonances of histidine residues. From the inspection of the Cgamma chemical shift-pH profiles it was possible to determine the predominant tautomeric form for the histidine residues at higher pH values.     

Structure of the O-polysaccharide of Pseudomonas syringae pv. delphinii NCPPB 1879(T) having side chains of 3-acetamido-3,6-dideoxy-D-galactose residues

The O-polysaccharide (OPS) was obtained from the lipopolysaccharide of Pseudomonas syringae pv. delphinii NCPPB 1879(T) and studied by sugar and methylation analyses, Smith degradation, and (1)H- and (13)C-NMR spectroscopy. The OPS was found to contain residues of L-rhamnose (L-Rha) and 3-acetamido-3,6-dideoxy-D-galactose (D-Fuc3NAc), and the following structure of the major (n = 2) and minor (n = 3) heptasaccharide repeating units of the OPS was established: [carbohydrate structure: see text]. The OPS is distinguished by the presence of oligosaccharide side chains consisting of three D-Fuc3NAc residues that are connected to each other by the (alpha 1-->2)-linkage. The OPS is characterized by a structural heterogeneity due to a different position of substitution of one of the four L-rhamnose residues in the main chain of the repeating unit as well as to the presence of oligosaccharide units with an incomplete side chain.     

Effect of alpha-tocopherol incorporation of glucose permeability and phase transition of lecithin liposomes.

Liposomes were prepared from dipalmitoyllecithin, dimyristoyllecithin, dioleoyllecithin, egg lecithin, and soybean lecithin, and the effects of incorporation of various quantities of alpha-tocopherol or its analogs on permeability of the liposomes to glucose were studied at various temperatures (4--40 degrees C). Results showed that increase in the quantity of alpha-tocopherol incorporated into dipalmitoyllecithin and dimyristoyllecithin liposomes lowered the transition temperature for marked release of glucose and also decreased the maximum rate of temperature-dependent permeability, alpha-Tocopherol also had similar but less marked effects on the permeability of dioleoyllecithin and egg lecithin liposomes, but little effect on those of soybean lecithin, which has a higher degree of unsaturation. In dipalmitoyllecithin liposomes phytol showed a similar effect of permeability to that of alpha-tocopherol, but phytanic acid caused a different pattern of temperature-dependent permeability. With analogs of alpha-tocopherol, the regulatory effect on permeability decreased with shortening and disappearance of the isoprenoid side chain. The significance of these observations is discussed in relation to the physiological functions of tocopherols in natural membranes.     

Hemoglobin oxidation and erythrocyte hemolysis induced by a synthetic analog of alpha-tocopherol not containing an isoprenoid chain

The effect of alpha-tocopherol and its synthetic analogue which does not contain an isoprenoid chain, 2,2,5,7,8-pentamethyl-6-hydroxychroman (chromanol), on rat erythrocyte and hemoglobin has been studied. Chromanol, unlike alpha-tocopherol, induces oxidation of hemoglobin into aquomethemoglobin and causes erythrocyte hemolysis. A mechanism of the reaction has been established. It consists of two-electron reduction of haem-associated oxygen molecule. The products formed can cause oxidative membrane damage and subsequent hemolysis. The absence of similar activity of alpha-tocopherol seems to be connected with the inaccessibility of ligand sphere of hemin iron because of the presence of the isoprenoid chain. The oxidative activity of chromanol can explain the absence of E-vitamin activity in this compound.     

The three-dimensional structure of bovine calcium ion-bound osteocalcin using 1H NMR spectroscopy

Structural information on osteocalcin or other noncollagenous bone proteins is very limited. We have solved the three-dimensional structure of calcium bound osteocalcin using (1)H 2D NMR techniques and proposed a mechanism for mineral binding. The protons in the 49 amino acid sequence were assigned using standard two-dimensional homonuclear NMR experiments. Distance constraints, dihedral angle constraints, hydrogen bonds, and (1)H and (13)C chemical shifts were all used to calculate a family of 13 structures. The tertiary structure of the protein consisted of an unstructured N terminus and a C-terminal loop (residues 16-49) formed by long-range hydrophobic interactions. Elements of secondary structure within residues 16-49 include type III turns (residues 20-25) and two alpha-helical regions (residues 27-35 and 41-44). The three Gla residues project from the same face of the helical turns and are surface exposed. The genetic algorithm-molecular dynamics simulation approach was used to place three calcium atoms on the NMR-derived structure. One calcium atom was coordinated by three side chain oxygen atoms, two from Asp30, and one from Gla24. The second calcium atom was coordinated to four oxygen atoms, two from the side chain in Gla 24, and two from the side chain of Gla 21. The third calcium atom was coordinated to two oxygen atoms of the side chain of Gla17. The best correlation of the distances between the uncoordinated Gla oxygen atoms is with the intercalcium distance of 9.43 A in hydroxyapatite. The structure may provide further insight into the function of osteocalcin.     

Insight into the binding of antifreeze proteins to ice surfaces via 13C spin lattice relaxation solid-state NMR

The primary sequences of type I antifreeze proteins (AFPs) are Ala rich and contain three 11-residue repeat units beginning with threonine residues. Their secondary structures consist of alpha-helices. Previous activity study of side-chain mutated AFPs suggests that the ice-binding side of type I AFPs comprises the Thr side chains and the conserved i + 4 and i + 8 Ala residues, where i indicates the positions of the Thrs. To find structural evidence for the AFP's ice-binding side, a variable-temperature dependent (13)C spin lattice relaxation solid-state NMR experiment was carried out for two Ala side chain (13)C labeled HPLC6 isoforms of the type I AFPs each frozen in H(2)O and D(2)O, respectively. The first one was labeled on the equivalent 17th and 21st Ala side chains (i + 4, 8), and the second one on the equivalent 8th, 19th, and 30th Ala side chains (i + 6). The two kinds of labels are on the opposite sides of the alpha-helical AFP. A model of Ala methyl group rotation/three-site rotational jump combined with water molecular reorientation was tested to probe the interactions of the methyl groups with the proximate water molecules. Analysis of the T(1) data shows that there could be 10 water molecules closely capping an i + 4 or an i + 8 methyl group within the range of van der Waals interaction, whereas the surrounding water molecules to the i + 6 methyl groups could be looser. This study suggests that the side of the alpha-helical AFP comprising the i + 4 and i + 8 Ala methyl groups could interact with the ice surface in the ice/water interface.     

Dimer formation of octaprenyl-diphosphate synthase (IspB) is essential for chain length determination of ubiquinone

Ubiquinone (Q), composed of a quinone core and an isoprenoid side chain, is a key component of the respiratory chain and is an important antioxidant. In Escherichia coli, the side chain of Q-8 is synthesized by octaprenyl-diphosphate synthase, which is encoded by an essential gene, ispB. To determine how IspB regulates the length of the isoprenoid, we constructed 15 ispB mutants and expressed them in E. coli and Saccharomyces cerevisiae. The Y38A and R321V mutants produced Q-6 and Q-7, and the Y38A/R321V double mutant produced Q-5 and Q-6, indicating that these residues are involved in the determination of chain length. E. coli cells (ispB::cat) harboring an Arg-321 mutant were temperature-sensitive for growth, which indicates that Arg-321 is important for thermostability of IspB. Intriguingly, E. coli cells harboring wild-type ispB and the A79Y mutant produced mainly Q-6, although the activity of the enzyme with the A79Y mutation was completely abolished. When a heterodimer of His-tagged wild-type IspB and glutathione S-transferase-tagged IspB(A79Y) was formed, the enzyme produced a shorter length isoprenoid. These results indicate that although the A79Y mutant is functionally inactive, it can regulate activity upon forming a heterodimer with wild-type IspB, and this dimer formation is important for the determination of the isoprenoid chain length.