A re-evaluation of the molecular size of duck ε-crystallin and its comparison with avian lactate dehydrogenases

A biochemical comparison of ε-crystallin isolated from the duck lens and lactate dehydrogenase of chicken heart has been made in order to establish the structural and functional identities of these two proteins. The native molecular weight of ε-crystallin was re-examined by combining sedimentation and gel-filtration data. It was found that ε-crystallin is 150 kDa in contrast to the 120 kDa reported previously for this crystallin. Subunit cross-linking experiments corroborated that lactate dehydrogenase and ε-crystallin both exist as tetramers of four identical subunits in their native quaternary structures. Amino acid compositions plus N-terminal analyses revealed no differences between the two proteins. Duck ε-crystallin exhibited high enzymatic activity of lactate dehydrogenases even after a long period of storage, and showed characteristic thermostability at 50°C for several hours. Comparison of the enzyme activity of duck lens homogenate with those of heart, liver and muscle tissues revealed that duck lens is a much richer source than other tissues for the isolation and characterization of this important enzyme which appears also as a structural protein in the lens.     

Characterization and comparison of epsilon-crystallin and lactate dehydrogenases in the lenses of vertebrates and invertebrates

Screening of lens homogenates for the identification of lactate dehydrogenases was undertaken for the representative species from five major classes of vertebrates plus the cephalopod of invertebrates. The duck and caiman lenses appeared to contain the highest enzymatic activity of this glycolytic enzyme among all species examined. Biochemical isolation and characterization of epsilon-crystallins from the duck and caiman lenses revealed differences between these structural crystallins and the authentic lactate dehydrogenase of the avian heart regarding some of the kinetic properties. This is in contrast with the claim that duck epsilon-crystallin is identical to heart-type lactate dehydrogenase.     

epsilon-crystallin from duck eye lens comparison of its quaternary structure and stability with other lactate dehydrogenases and complex formation with alpha-crystallin.

Taxon-specific epsilon-crystallin (epsilonC) from duck eye lens is identical to duck heart muscle lactate dehydrogenase. It forms a dimer of dimers with a dissociation constant of 2.2 x 10-7 M, far beyond the value observed for other vertebrate lactate dehydrogenases. Comparing the characteristics of wild-type epsilon-crystallin with those of three mutants, G115N, G119F and 115N/119F, representing the only significant peripheral sequence variations between duck epsilonC and chicken or pig heart muscle lactate dehydrogenase, no significant conformational differences are detectable. Regarding the catalytic properties, the Michaelis constant of the double mutant 115N/119F for pyruvate is found to be decreased; for wild-type enzyme, the effect is overcompensated by the high expression level of epsilonC in the eye lens. As taken from spectral analysis of the guanidine-induced and temperature-induced denaturation transitions, epsilonC in its dimeric state is relatively unstable, whereas the native tetramer exhibits the high intrinsic stability characteristic of common vertebrate heart and muscle lactate dehydrogenases. The denaturation mechanism of epsilonC is complex and only partially reversible. In the case of thermal unfolding, the predominant side reaction competing with the reconstitution of the native state is the kinetic partitioning between proper folding and aggregation. alpha-Crystallin, the major molecular chaperone in the eye lens, inhibits the aggregation of epsilonC by trapping the misfolded protein.     

Kinetic analysis of duck epsilon-crystallin, a lens structural protein with lactate dehydrogenase activity.

Biochemical characterization and kinetic analysis of epsilon-crystallin from the lenses of common ducks were undertaken to elucidate the enzyme mechanism of this unique crystallin with lactate dehydrogenase (LDH) activity. Despite the structural similarities between epsilon-crystallin and chicken heart LDH, differences in charge and kinetic properties were revealed by isoenzyme electrophoresis and kinetic studies. Bi-substrate kinetic analysis examined by initial-velocity and product-inhibition studies suggested a compulsory ordered Bi Bi sequential mechanism with NADH as the leading substrate followed by pyruvate. The products were released in the order L-lactate and NAD+. The catalysed reaction is shown to have a higher rate in the formation of L-lactate and NAD+. Substrate inhibition was observed at high concentrations of pyruvate and L-lactate for the forward and reverse reactions respectively. The substrate inhibition was presumably due to the formation of epsilon-crystallin-NAD(+)-pyruvate or epsilon-crystallin-NADH-L-lactate abortive ternary complexes, as suggested by the product-inhibition studies. The significance and the interrelationship of duck epsilon-crystallin with other well-known LDHs are discussed with special regard to its role as a structural protein with some enzymic function in lens metabolism.     

Kinetic analysis of duck epsilon-crystallin with L-lactate dehydrogenase activity: determination of kinetic constants and comparison of substrate specificity.

A systematic analysis of the kinetic properties of duck lens epsilon-crystallin with lactate dehydrogenase [LDH, (E.C. 1.1.1.27)] activity was carried out by employing some 19 different alpha-keto acids as substrates for this NADH-dependent LDH-catalyzed reaction. The steady-state Michaelis and catalytic constants (Km, kcat) were determined for a broad range of organic compounds. The results provide important insights regarding the binding and affinity of substrates to active sites of this enzyme crystallin and indicate a great potential for the application of the stable epsilon-crystallin as a catalyst to the synthesis of some important chiral alpha-hydroxyacids in a convenient and efficient way. It is also demonstrated for the first time that in addition to the enzymatic activity of lactate dehydrogenase, duck epsilon-crystallin also possesses the enzymatic activity of malate dehydrogenase.     

Kinetic mechanism of the endogenous lactate dehydrogenase activity of duck epsilon-crystallin

Initial velocity, product inhibition, and substrate inhibition studies suggest that the endogenous lactate dehydrogenase activity of duck epsilon-crystallin follows an order Bi-Bi sequential mechanism. In the forward reaction (pyruvate reduction), substrate inhibition by pyruvate was uncompetitive with inhibition constant of 6.7 +/- 1.7 mM. In the reverse reaction (lactate oxidation), substrate inhibition by L-lactate was uncompetitive with inhibition constant of 158 +/- 25 mM. The cause of these inhibitions may be due to epsilon-crystallin-NAD(+)-pyruvate and epsilon-crystallin-NADH-L-lactate abortive ternary complex formation as suggested by the multiple inhibition studies. Pyruvate binds to free enzyme very poorly, with a very large dissociation constant. Bromopyruvate, fluoropyruvate, pyruvate methyl ester, and pyruvate ethyl ester are alternative substrates for pyruvate. 3-Acetylpyridine adenine dinucleotide, nicotinamide 1,N6-ethenoadenine dinucleotide, and nicotinamide hypoxanthine dinucleotide serve as alternative coenzymes for epsilon-crystallin. All the above alternative substrates or coenzymes showed an intersecting initial-velocity pattern conforming to the order Bi--Bi kinetic mechanism. Nicotinic acid adenine dinucleotide, thionicotinamide adenine dinucleotide, and 3-aminopyridine adenine dinucleotide acted as inhibitors for this enzymatic crystallin. The inhibitors were competitive versus NAD+ and noncompetitive versus L-lactate. alpha-NAD+ was a noncompetitive inhibitor with respect to the usual beta-NAD+. D-Lactate, tartronate, and oxamate were strong dead-end inhibitors for the lactate dehydrogenase activity of epsilon-crystallin. Both D-lactate and tartronate were competitive inhibitors versus L-lactate while oxamate was a competitive inhibitor versus pyruvate. We conclude that the structural requirements for the substrate and coenzyme of epsilon-crystallin are similar to those of other dehydrogenases and that the carboxamide carbonyl group of the nicotinamide moiety is important for the coenzyme activity.     

Screening and kinetic analysis of delta-crystallins with endogenous argininosuccinate lyase activity in the lenses of vertebrates.

Screening of lens homogenates from the representative species of five major classes of vertebrates was undertaken to search for delta-crystallin with argininosuccinate lyase activity. Purification and biochemical characterization of delta-crystallins from the avian and reptilian species revealed differences in their electrophoretic and kinetic properties in spite of their similar tetrameric structure of about 200 kDa in the native forms. Chicken delta-crystallin, in contrast to those obtained from duck, goose and caiman, is almost devoid of the enzymatic activity. Two-dimensional gel electrophoresis of lens homogenates indicated that in the chicken lens delta-crystallin is composed of a subunit with an isoelectric point of 5.9 and a subunit mass of 50 kDa whereas that of goose lenses possesses heterogeneous subunits with isoelectric points spreading in a range of 5.9 to 6.8. Immunological comparison of inactive and active delta-crystallins from the chicken, duck and caiman lenses established the apparent structural similarity of all delta-crystallins to the authentic enzyme regarding some of common surface epitopes, yet they are not completely identical. Kinetic constants for two of the active delta-crystallins, i.e. those from the duck and goose of the Anatidae family, were also determined and their catalyzed reaction was shown to conform to a random Uni-Bi kinetic mechanism similar to that of the argininosuccinate lyase from the bovine liver.     

epsilon-Crystallin, a novel avian and reptilian eye lens protein

Gel filtration of Peking duck eye lens proteins reveals a component eluting just behind delta-crystallin and comprising approximately 10% of the total soluble protein. The native Mr of this additional component is estimated to be 120000; it appears to be composed of three identical chains of Mr 38000 and pI 7.5. Circular dichroic spectroscopy showed a relatively high alpha-helical content. No immunological cross-reactivity is found with alpha-, beta-, gamma- or delta-crystallins, and partial amino acid sequence determinations likewise failed to reveal any similarity with other known crystallins. We conclude that this protein represents another and novel family of eye lens proteins, for which we propose the designation epsilon-crystallin. epsilon-Crystallin is translated from a 1450-base mRNA, which has been partially purified. epsilon-Crystallin is found scattered among avian and reptilian taxa, but not in other vertebrates. Its rate of evolutionary change seems to be as slow as that of alpha- and beta-crystallins.     

Tau-crystallin/alpha-enolase: one gene encodes both an enzyme and a lens structural protein

tau-Crystallin has been a major component of the cellular lenses of species throughout vertebrate evolution, from lamprey to birds. Immunofluorescence analysis of the embryonic turtle lens, using antiserum to lamprey tau-crystallin showed that the protein is expressed throughout embryogenesis and is present at high concentrations in all parts of the lens. Partial peptide sequence for the isolated turtle protein and deduced sequences for several lamprey peptides all revealed a close similarity to the glycolytic enzyme enolase (E.C. 4.2.1.11). A full-sized cDNA for putative duck tau- crystallin was obtained and sequenced, confirming the close relationship with alpha-enolase. Southern blot analysis showed that the duck genome contains a single alpha-enolase gene, while Northern blot analysis showed that the message for tau-crystallin/alpha-enolase is present in embryonic duck lens at 25 times the abundance found in liver. tau-Crystallin possesses enolase activity, but the activity is greatly reduced, probably because of age-related posttranslational modification. It thus appears that a highly conserved, important glycolytic enzyme has been used as a structural component of lens since the start of vertebrate evolution. Apparently the enzyme has not been recruited for its catalytic activity but for some distinct structural property. tau-Crystallin/alpha-enolase is an example of a multifunctional protein playing two very different roles in evolution but encoded by a single gene.     

Covalent fixation of NAD+ to dehydrogenases and properties of the modified enzymes

Starting from 6-chloropurine riboside and NAD+, different reactive analogues of NAD+ have been obtained by introducing diazoniumaryl or aromatic imidoester groups via flexible spacers into the nonfunctional adenine moiety of the coenzyme. The analogues react with different amino-acid residues of dehydrogenases and form stable amidine or azobridges, respectively. After the formation of a ternary complex by the coenzyme, the enzyme and a pseudosubstrate, the reactive spacer is anchored in the vicinity of the active site. Thus, the coenzyme remains covalently attached to the protein even after decomposition of the complex. On addition of substrates the covalently bound coenzyme is converted to the dihydro-form. In enzymatic tests the modified dehydrogenases show 80-90% of the specific activity of the native enzymes, but they need remarkably higher concentrations of free NAD+ to achieve these values. The dihydro-coenzymes can be reoxidized by oxidizing agents like phenazine methosulfate or by a second enzyme system. Various systems for coenzyme regeneration were investigated; the modified enzymes were lactate dehydrogenase from pig heart and alcohol dehydrogenase from horse liver; the auxiliary enzymes were alcohol dehydrogenase from yeast and liver, lactate dehydrogenase from pig heart, glutamate dehydrogenase and alanine dehydrogenase. Lactate dehydrogenase from heart muscle is inhibited by pyruvate. With alanine dehydrogenase as the auxiliary enzyme, the coenzyme is regenerated and the reaction product, pyruvate, is removed. This system succeeds to convert lactate quantitatively to L-alanine. The thermostability of the binary enzyme systems indicates an interaction of covalently bound coenzymes with both dehydrogenases; both binding sites seem to compete for the coenzyme. The comparison of dehydrogenases with different degrees of modifications shows that product formation mainly depends on the amount of incorporated coenzyme.     

Biochemical characterization of crystallins from pigeon lenses: structural and sequence analysis of pigeon delta-crystallin.

Crystallins from pigeon eye lenses were isolated and purified by gel-permeation chromatography and characterized by gel electrophoresis, amino-acid composition and sequence analysis. Alpha- and beta-crystallins could be obtained in relatively pure forms by single-step size-exclusion chromatography whereas an extra step of ion-exchange chromatography was needed for the separation of delta-crystallin from the beta-crystallin fraction. In contrast to most characterized vertebrate species, a large amount of glycogen is eluted as a high molecular form in the first peak of the gel filtration column. Pigeon delta-crystallin, similar to duck and reptilian delta-crystallins, exists as a tetrameric structure of about 200 kDa in the native form and is composed of one major subunit of 50 kDa with heterogeneous isoelectric points spreading in a range of 4.7 to 6.8. In contrast to those obtained from duck, goose and caiman, delta-crystallin isolated from the pigeon lens possessed very little argininosuccinate lyase activity. However, pigeon delta-crystallin can still cross-react with the antibody against enzymically active duck delta-crystallin as revealed by the sensitive immunoblotting technique. It was also shown that the delta-crystallin content of the total pigeon soluble proteins decreased with the age of the animal. Structural analysis of purified delta-crystallin fraction was made with respect to its amino-acid composition and protein primary sequence. N-terminal sequence analysis indicated the presence of blocked amino-termini in all crystallin fractions of pigeon lenses. Therefore, a sequence analysis of PCR (polymerase chain reaction) amplified delta-crystallin cDNA was employed to deduce the protein sequence of this crystallin. Structural comparison of delta-crystallin sequences from pigeon, chicken and duck lenses casts some doubts on the recent claim that His-89-->Gln mutation in the chicken delta-crystallin may account for the loss of argininosuccinate lyase activity in this avian species, as compared to high enzymic activity in the duck crystallin (Barbosa et al. (1991) J. Biol. Chem. 266, 5286-5290).     

Lactate dehydrogenase A as a highly abundant eye lens protein in platypus (Ornithorhynchus anatinus): upsilon (upsilon)-crystallin

Vertebrate eye lenses mostly contain two abundant types of proteins, the alpha-crystallins and the beta/gamma-crystallins. In addition, certain housekeeping enzymes are highly expressed as crystallins in various taxa. We now observed an unusual approximately 41-kd protein that makes up 16% to 18% of the total protein in the platypus eye lens. Its cDNA sequence was determined, which identified the protein as muscle-type lactate dehydrogenase A (LDH-A). It is the first observation of LDH-A as a crystallin, and we designate it upsilon (upsilon)-crystallin. Interestingly, the related heart-type LDH-B occurs as an abundant lens protein, known as epsilon-crystallin, in many birds and crocodiles. Thus, two members of the ldh gene family have independently been recruited as crystallins in different higher vertebrate lineages, suggesting that they are particularly suited for this purpose in terms of gene regulatory or protein structural properties. To establish whether platypus LDH-A/upsilon-crystallin has been under different selective constraints as compared with other vertebrate LDH-A sequences, we reconstructed the vertebrate ldh-a gene phylogeny. No conspicuous rate deviations or amino acid replacements were observed.     

Gene conversion and splice-site slippage in the argininosuccinate lyases/delta-crystallins of the duck lens: members of an enzyme superfamily

Argininosuccinate lyase(ASL)/delta-crystallin is a prominent example of an enzyme-crystallin with roles as both a catalyst and a major structural component of the eye lens in birds and reptiles. In chicken it appears that gene duplication and separation of function may have occurred with one gene product acting primarily as a crystallin and one primarily as an enzyme. However, two delta-crystallin-encoding genes are abundantly expressed in the lens of the embryonic duck (Anas platyrhynchos) which has extremely high ASL activity. Here the isolation and sequence analysis of full length cDNA clones for both duck delta-crystallins are described. The two delta-crystallins are highly similar (94% identical in predicted aa sequence), probably as a result of gene conversion. However, the cDNA for duck delta 2-crystallin contains an in-frame insertion of two codons, probably the result of a recent intron boundary slippage. ASL/delta-crystallin belongs to a superfamily of lyases, including fumarases, aspartases and adenylosuccinate lyase which possess some highly conserved blocks of aa sequence. There may be some clues to the tertiary structures of these conserved motifs in otherwise unrelated proteins for which three-dimensional structures are known.     

Kinetic comparison of caiman ε-crystallin and authentic lactate dehydrogenases of vertebrates

Kinetic comparison of -crystallins isolated from the avian and reptilian species and the authentic lactate dehydrogenases (LDHs) was undertaken in order to clarify the identities of these structural lens proteins in relation to their enzymatic activity. Caiman -crystallin similar to the previously characterized duck -crystallin appeared to possess a genuine and stable LDH activity as detected by nitro blue tetrazolium staining on polyacrylamide gels and conventional kinetic assays. Kinetic parameters for pyruvate,l-lactate, NAD⁺, and three structural analogues of the coenzyme in this -crystallin catalyzed reaction were also determined and compared. Despite the structural similarities between -crystallins and chicken heart LDH, differences in charge and kinetic properties have been revealed by native isozyme electrophoresis and kinetic analysis as examined by initial velocity and substrate inhibition studies. It is found that the kinetic data analyzed for caiman -crystallin were more fitted with a compulsory ordered Bi-Bi sequential mechanism similar to those for the authentic LDHs and duck -crystallin. Caiman -crystallin has for the first time been established as a heart-type LDH based on the kinetic analysis and comparison with the authentic heart- and muscle-type LDHs from pig and chicken.     

Substrate inhibition of the mitochondrial and cytoplasmic malate dehydrogenases.

The mechanism that leads to an inhibition of enzyme activity in the presence of high concentrations of substrate was investigated with the two malate dehydrogenase isoenzymes obtained from pig heart. The inhibition is promoted by an abortive binary complex formed by the enzymes and the enol form of of oxalacelate. Neither the oxidized coenzyme nor the reduced coenzyme appears to be involved in the formation of this complex. These results suggest that the mechanism of substrate inhibition that occurs with the pig heart malate dehydrogenases is different from that observed with the lactate dehydrogenases from chicken hearts. The inhibition constants for oxalacetate are 2.0 mM with the mitochondrial enzyme and 4.5 mM with the cytoplasmic enzyme. Since the in vivo concentration of oxalacetate is reported to be about 10 micrometer, these data suggest that the substrate inhibition that is exhibited by the malate dehydrogenases may not be of any significance in vivo.     

Occurrence of immunoreactive 80 kDa and non-immunoreactive diacylglycerol kinases in different pig tissues.

We surveyed diacylglycerol kinase in different pig tissues by using rabbit antibody immunospecific to the brain 80 kDa enzyme [Kanoh, Iwata, Ono & Suzuki (1986) J. Biol. Chem. 261, 5597-5602]. Among the other tissues examined, the immunoreactive 80 kDa enzyme was found only in the thymus and, to a much lesser extent, in the spleen, although this enzyme species was widely distributed in a variety of brain regions. Other tissues such as platelets, kidney, heart and liver contained little, if any, immunoreactive enzymes. Gel filtration of cytosolic enzymes from several tissues revealed the presence of three major activity peaks, apparently corresponding to 280, 120 and 80 kDa. Thymus and spleen contained the immunoreactive 80 kDa species together with non-immunoreactive 280 kDa enzyme. In the case of platelets, the kinase consisted almost exclusively of non-immunoreactive 120 kDa species with some 280 kDa enzyme. In an attempt to characterize the different kinase forms, the thymus enzyme was chosen for further studies because of its high activity. No immunoreactive proteins were detected in Western-blot analysis when the 280 kDa enzyme was solvent-extracted, proteinase-treated or preincubated in the presence of Ca2+. In comparison with the 80 kDa species, the 280 kDa enzyme was much more heat-stable and less dependent on deoxycholate in the assay mixture. Although the purification of different forms of the kinase is required to confirm the presence of isoenzymes, the results show that there exist several immunologically distinct diacylglycerol kinase species.     

Purification and characterization of a thermostable glutamate dehydrogenase from a thermophilic bacterium isolated from a sterilization drying oven

Glutamate dehydrogenase from axenic bacterial cultures of a new microorganism, called GWE1, isolated from the interior of a sterilization drying oven, was purified by anion-exchange and molecular-exclusion liquid chromatography. The apparent molecular mass of the native enzyme was 250.5 kDa and was shown to be an hexamer with similar subunits of molecular mass 40.5 kDa. For glutamate oxidation, the enzyme showed an optimal pH and temperature of 8.0 and 70 degrees C, respectively. In contrast to other glutamate dehydrogenases isolated from bacteria, the enzyme isolated in this study can use both NAD(+) and NADP(+) as electron acceptors, displaying more affinity for NADP(+) than for NAD(+). No activity was detected with NADH or NADPH, 2-oxoglutarate and ammonia. The enzyme was exceptionally thermostable, maintaining more than 70% of activity after incubating at 100(o)C for more than five hours suggesting being one of the most thermoestable enzymes reported in the family of dehydrogenases.     

Expression level of adenosine kinase in rat tissues. Lack of phosphate effect on the enzyme activity

In this report we describe cloning and expression of rat adenosine kinase (AK) in Esccherichaia coli cells as a fusion protein with 6xHis. The recombinant protein was purified and polyclonal antibodies to AK were generated in rabbits. Immunoblot analysis of extracts obtained from various rat tissues revealed two protein bands reactive with anti-AK IgG. The apparent molecular mass of these bands was 48 and 38 kDa in rat kidney, liver, spleen, brain, and lung. In heart and muscle the proteins that react with AK antibodies have the molecular masses of 48 and 40.5 kDa. In order to assess the relative AK mRNA level in rat tissues we used the multiplex PCR technique with beta-actin mRNA as a reference. We found the highest level of AK mRNA in the liver, which decreased in the order kidney > spleen > lung > heart > brain > muscle. Measurement of AK activity in cytosolic fractions of rat tissues showed the highest activity in the liver (0.58 U/g), which decreased in the order kidney > spleen > lung > brain > heart > skeletal muscle. Kinetic studies on recombinant AK as well as on AK in the cytosolic fraction of various rat tissues showed that this enzyme is not affected by phosphate ions. The data presented indicate that in the rat tissues investigated at least two isoforms of adenosine kinase are expressed, and that the expression of the AK gene appears to have some degree of tissue specificity.     

Evidence of aerobic and anaerobic format dehydrogenase and aldehyde dehydrogenase immunological similarities shown by polyclonal antibodies raised against molybdoproteins

Antisera against metal(Mo)-containing dye-linked dehydrogenases from sulphate-reducing bacteria were used to screen for immunological similarities with NAD⁺-linked dehydrogenases detected in aerobic methanol-utilizing bacterial isolates. Out of eleven strains tested, the strains #5, 8, 9 and 11 were shown to have specific formate and aldehyde dehydrogenases displaying antibody cross-reaction against highly purified Mo-containing dye-linked dehydrogenases. The apparent molecular mass of the identified proteins observed during the antibody reaction correlated with the molecular mass of the dehydrogenases obtained after native PAGE electrophoresis. The strains #8 and 11 exhibited one formate dehydrogenase apparently of identical molecular mass 140–145 kDa, whereas strains #5, 9 and 11 synthesized aldehyde dehydrogenases with apparent molecular masses of about 110, 120 and 155 kDa (two forms) and 120 kDa, respectively. All these aerobic enzymes shared antigenic properties with the anaerobic metalloproteins, indicating the existence of structural similarities between those enzymes in spite of having different cofactor moieties.