Limited proteolysis of liver and muscle aldolases: Effects of subtilisin,cathepsin B,and Staphylococcus aureus protease

Limited proteolysis of rabbit liver and muscle aldolases by subtilisin and cathepsin B results in decreased catalytic activity, associated with the release of acid-soluble peptides from the COOH terminus. Analysis of the sequence of these peptides confirms the COOH-terminal sequence of the muscle enzyme and provides new information on the COOH-terminal sequence of the liver enzyme. As previously reported for muscle aldolase, cathepsin B releases mainly dipeptides from the COOH terminus of liver aldolase. The COOH-terminal sequence of rabbit liver aldolase is SerThrGlnSerLeuPheThrAla SerTyrThrTyr. The Gln-Ser bond is resistant to Staphylococcus aureus protease, which hydrolyzes a GluSer bond at the corresponding positions in the muscle enzyme.     

A comparative study of aldolase from human muscle and liver

Aldolase was purified from human skeletal muscle and human liver by techniques capable of processing large quantities (10-20kg) of tissue. The methods used also proved convenient for isolating aldolase on a large scale from other mammalian and avian sources. Aldolase from both human liver and muscle was crystallized; each gave two crystalline forms, depending on the conditions of crystallization. X-ray studies on the muscle aldolase crystals suggest a close structural similarity between human and rabbit muscle aldolase. Aldolases from human muscle and liver have similar pH optima and pH stability but their stability to heat treatment differs. The effect of heat on the enzymes may therefore provide an easy means of distinguishing them. The kinetic constants K(m) and k(cat.) for these aldolases are similar to other mammalian aldolases. Amino acid analyses and tryptic peptide ;mapping' show that the primary structures of the two aldolases differ greatly.     

Fructose 1,6-bisphosphate aldolase of Drosophila melanogaster: comparative sequence analyses around the substrate-binding lysyl residue

The amino acid sequence of a 103 residue segment encompassing the substrate-binding active site lysyl residue of fructose 1,6-bisphosphate aldolase from Drosophila melanogaster is determined. The sequence is identical to more than 70% with the structure of rabbit muscle aldolase and with the known partial sequences of the sturgeon muscle, trout muscle, and ox liver enzymes. The homology of the insect enzyme with the vertebrate aldolases strongly implies a similar tertiary structure folding.     

A selective reaction of fructose bisphosphate aldolase with fluorescein isothiocyanate in chicken muscle extracts

The present work describes the selective covalent modification of fructose bisphosphate aldolase in crude extracts of chicken breast muscle by fluorescein 5'-isothiocyanate (5'-FITC) at pH 7.0 and 35 degrees C. The modification was observed after 1 min while no other major soluble protein was labeled even after 30 min. We calculated that ca. one 5'-FITC molecule was incorporated into each aldolase tetramer after a 30 min reaction which resulted in a minimal loss of enzyme activity. The "native" structure of aldolase was required for the selective modification by 5'-FITC since high pH, high temperature, and ionic detergents either inhibited or prevented the reaction of 5'-FITC with aldolase. Certain metabolites (ATP, ADP, CTP, GTP, FBP) and erythrosin B also inhibited the 5'-FITC modification of aldolase. In contrast, F-6-P, AMP, NADH, and NAD(+) as well as free lysine and most importantly, the 6'-isomer of FITC exhibited no competition with 5'-FITC for the labeling of aldolase. Alone, the 6'-isomer of FITC did not exhibit preferential reaction when combined with aldolase. 5'-FITC-labeled and -unlabeled aldolases were not distinguished by their ability to bind to muscle myofibrils (MFs) or by their abilities to refold following reversible denaturation in urea. Structural analysis revealed that 5'-FITC-labeled a tryptic peptide corresponding to residues 112-134 in the primary structure of aldolase, a peptide that does not contain lysine, the amino acid believed to be the primary target of this reagent. Unlike chicken and rabbit muscle aldolases, chicken brain and liver aldolase isoforms along with several other aldolases derived from diverse biological sources did not exhibit this highly selective modification by 5'-FITC.     

Carboxyl terminus region modulates catalytic activity of recombinant maize aldolase

Site-directed mutagenesis was utilized to study the functional role of the COOH-terminal region in recombinant maize aldolase. A single mutation was created in each of the last nine amino acids of the COOH terminus and characterized kinetically. Point mutations in the COOH-terminal region were found to influence both the rate of fructose 1,6-bisphosphate and fructose 1-phosphate cleavage. Catalytic efficiency, kcat/Km, was not affected by the mutations within experimental error consistent with this region of the COOH terminus modulating product release. Concentrations of the carbanion-enamine enzyme intermediate complex produced upon substrate cleavage increased with the severity of the point mutation. A condensation assay was developed to directly measure fructose 1,6-bisphosphate synthesized by aldolases in the presence of high triose phosphate concentrations. The maximal rate of aldol condensation of triose phosphates, D-glyceralehyde-3-P and dihydroxyacetone-P, was affected by the point mutations to the same extent as the maximal rate of substrate cleavage. Interpretation of the data is consistent with point mutations in the COOH terminus predominantly affecting the proton exchange with the dihydroxyacetone-P enzymatic complex at the carbanion-enamine step and that this step is probably rate-limiting in the catalytic mechanism of recombinant maize aldolase. The role of the COOH-terminal region in aldolases is thus consistent with a sequence dependent modulation of catalytic activity.     

Novel ATP-binding and autophosphorylation activity associated with Arabidopsis and human cryptochrome-1.

Cryptochromes are blue-light photoreceptors sharing sequence similarity to photolyases, a class of flavoenzymes catalyzing repair of UV-damaged DNA via electron transfer mechanisms. Despite significant amino acid sequence similarity in both catalytic and cofactor-binding domains, cryptochromes lack DNA repair functions associated with photolyases, and the molecular mechanism involved in cryptochrome signaling remains obscure. Here, we report a novel ATP binding and autophosphorylation activity associated with Arabidopsis cry1 protein purified from a baculovirus expression system. Autophosphorylation occurs on serine residue(s) and is absent in preparations of cryptochrome depleted in flavin and/or misfolded. Autophosphorylation is stimulated by light in vitro and oxidizing agents that act as flavin antagonists prevent this stimulation. Human cry1 expressed in baculovirus likewise shows ATP binding and autophosphorylation activity, suggesting this novel enzymatic activity may be important to the mechanism of action of both plant and animal cryptochromes.     

Chloroplast and cytoplasmic enzymes 1, 2, 3. Subunit structure of pea leaf aldolases.

The pea leaf chloroplastic and cytoplasmic forms of aldolase are very similar in structure. The subunit molecular weights determined by polyacrylamide gel electrophoresis in sodium dodecyl sulfate are approximately 37.000. Both aldolases appear to terminate in the same sequence, SerAlaTyrCOOH, and the amino-terminal sequence H₂NGlySerTyrAla was obtained for each. The previously reported differences in kinetic properties and in isoelectric points of the two pea leaf enzymes probably are the consequence of minor differences in amino acid composition or conformation.     

Recombinant anaerobic maize aldolase: overexpression, characterization, and metabolic implications

Complementary DNA sequence of anaerobically induced cytoplasmic maize aldolase was expressed under control of the tac promoter sequence in Escherichia coli using the pKK223-3 plasmid as a vehicle. Levels of recombinant protein expressed exceeded 20 mg of soluble aldolase per liter of culture. The purified recombinant enzyme displayed the expected molecular weight and tetrameric subunit assembly on the basis of mobilities on denaturing electrophoretic gels and gel filtration, respectively. Sequencing of the NH2 terminus and amino acid composition analysis of the recombinant protein including COOH-terminal peptides agreed with the cDNA sequence. Partial kinetic characterization based on product inhibition studies was consistent with the ordered uni-bi reaction mechanism expected of aldolases. Turnover with respect to substrates Fru-1,6-P2 and Fru-1-P by the recombinant enzyme is the highest reported to date for class I aldolases. Fru-1,6-P2 cleavage rate by recombinant cytoplasmic maize enzyme is three times greater than that of the chloroplast enzyme. Fru-1-P cleavage is 8-fold greater than that of the rabbit liver isozyme and 20-fold greater than that of the rabbit muscle isozyme to which maize aldolase exhibits the greatest homology. The implications of such a high Fru-1-P turnover on carbohydrate utilization under anaerobiosis is discussed.     

Structure of human brain fructose 1,6-(bis)phosphate aldolase: linking isozyme structure with function

Fructose-1,6-(bis)phosphate aldolase is a ubiquitous enzyme that catalyzes the reversible aldol cleavage of fructose-1,6-(bis)phosphate and fructose 1-phosphate to dihydroxyacetone phosphate and either glyceral-dehyde-3-phosphate or glyceraldehyde, respectively. Vertebrate aldolases exist as three isozymes with different tissue distributions and kinetics: aldolase A (muscle and red blood cell), aldolase B (liver, kidney, and small intestine), and aldolase C (brain and neuronal tissue). The structures of human aldolases A and B are known and herein we report the first structure of the human aldolase C, solved by X-ray crystallography at 3.0 A resolution. Structural differences between the isozymes were expected to account for isozyme-specific activity. However, the structures of isozymes A, B, and C are the same in their overall fold and active site structure. The subtle changes observed in active site residues Arg42, Lys146, and Arg303 are insufficient to completely account for the tissue-specific isozymic differences. Consequently, the structural analysis has been extended to the isozyme-specific residues (ISRs), those residues conserved among paralogs. A complete analysis of the ISRs in the context of this structure demonstrates that in several cases an amino acid residue that is conserved among aldolase C orthologs prevents an interaction that occurs in paralogs. In addition, the structure confirms the clustering of ISRs into discrete patches on the surface and reveals the existence in aldolase C of a patch of electronegative residues localized near the C terminus. Together, these structural changes highlight the differences required for the tissue and kinetic specificity among aldolase isozymes.     

Rat aldolase isozyme gene

Rat aldolase B mRNA was partially purified from liver polysomes by an immunochemical technique followed by oligo(dT)-cellulose column chromatography. Double-stranded cDNA, synthesized from this mRNA, was inserted into the PstI site of plasmid pBR322 employing the oligo(dC)-oligo(dG) tailing method. Clones containing aldolase B cDNA inserts were selected by colony hybridization using 32P-labeled purified mRNA as a specific probe. Several recombinant plasmids containing 600 to 1000 base pair inserts were isolated. Hybrid selection-translation experiments showed that they hybridize specifically with aldolase B mRNA. By overlapping restriction maps of several individual cDNA inserts, it was found that they spanned 1200 base pairs, which represented about 70% of the aldolase B mRNA sequence. The nucleotide sequence of the cDNA was then determined and the sequence of 180 amino acids from the COOH terminus and the entire 3' untranslatable nucleotide sequence were clarified. Although the complete amino acid sequence of rat aldolase B has not yet been reported, it was found that several amino acids neighboring the COOH-terminal tyrosine obtained by carboxypeptidase digestion completely coincided with those determined from the cDNA sequence; i.e. -Ser-Leu-Phe-Thr-Ala-Ser-Tyr-Thr-Tyr. Furthermore, a putative active site peptide appeared and is extensively homologous to those of rabbit aldolases A and B.     

Site-directed mutagenesis of human aldolase isozymes: the role of Cys-72 and Cys-338 residues of aldolase A and of the carboxy-terminal Tyr residues of aldolases A and B

In order to elucidate the role of particular amino acid residues in the catalytic activity and conformational stability of human aldolases A and B [EC 4.1.2.13], the cDNAs encoding these isoenzyme were modified using oligonucleotide-directed, site-specific mutagenesis. The Cys-72 and/or Cys-338 of aldolase A were replaced by Ala and the COOH-terminal Tyr of aldolases A and B was replaced by Ser. The three mutant aldolases A thus prepared, A-C72A, A-C338A, and A-C72,338A, were indistinguishable from the wild-type enzyme with respect to general catalytic properties, while the replacement of Tyr-363 by Ser in aldolase A (A-Y363S) resulted in decreases of the Vmax of the fructose-1, 6-bisphosphate (FDP) cleavage reaction, activity ratio of FDP/fructose-1-phosphate (F1P), and the Km values for FDP and F1P. The wild-type and all the mutant aldolase A proteins exhibited similar thermal stabilities. In contrast, the mutant aldolase A proteins were more stable than the wild-type enzyme against tryptic and alpha-chymotryptic digestions. Based upon these results it is concluded that the strictly conserved Tyr-363 of human aldolase A is required for the catalytic function with FDP as the substrate, while neither Cys-72 nor Cys-338 directly takes part in the catalytic function although the two Cys residues may be involved in maintaining the correct spatial conformation of aldolase A. Replacement of Tyr-363 by Ser in human aldolase B lowered the Km value for FDP appreciably and also diminished the stability against elevated temperatures and tryptic digestion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Extended amino acid sequences around the active-site lysine residue of class-I fructose 1,6-bisphosphate aldolases from rabbit muscle, sturgeon muscle, trout muscle and ox liver.

1. Amino acid sequences covering the region between residues 173 and 248 [adopting the numbering system proposed by Lai, Nakai & Chang (1974) Science 183, 1204-1206] were derived for trout (Salmo trutta) muscle aldolase and for ox liver aldolase. A comparable sequence was derived for residues 180-248 of sturgeon (Acipenser transmontanus) muscle aldolase. The close homology with the rabbit muscle enzyme was used to align the peptides of the other aldolases from which the sequences were derived. The results also allowed a partial sequence for the N-terminal 39 residues for the ox liver enzyme to be deduced. 2. In the light of the strong homology evinced for these enzymes, a re-investigation of the amino acid sequence of rabbit muscle aldolase between residues 181 and 185 was undertaken. This indicated the presence of a hitherto unsuspected -Ile-Val-sequence between residues 181 and 182 and the need to invert the sequence -Glu-Val- to -Val-Glx- at positions 184 and 185. 3. Comparison of the available amino acid sequences of these enzymes suggested an early evolutionary divergence of the genes for muscle and liver aldolases. It was also consistent with other evidence that the central region of the primary structure of these enzymes (which includes the active-site lysine-227) forms part of a conserved folding domain in the protein subunit. 4. Detailed evidence for the amino acid sequences proposed has been deposited as Suy Lending Division, Boston Spa, Wetherby, West Yorkshire LS23 7BQ, U.K., from whom copies can be obtained on the terms indicated in Biochem. J. (1978) 169, 5.     

Characterization of an autophosphorylation-dependent multifunctional protein kinase from liver

A cyclic nucleotide- and Ca2+-independent protein kinase has been identified and purified from pig liver to apparent homogeneity. This independent protein kinase is basically inactive but can be activated by a 4-min incubation with 0.25 mM ATP and 2 mM Mg2+. This ATP X Mg-mediated activation appears to involve an intramolecular autophosphorylation as it is independent of kinase concentration. Phosphoamino acid analysis further indicates that this intramolecular autophosphorylation/activation process is predominantly on a serine residue. The nonphosphorylated, inactive form of the kinase is extremely trypsin-labile, whereas the phosphorylated, active kinase is more resistant to trypsin, suggesting a conformational change during the activation process. Autophosphorylation/activation of the kinase is enhanced 2-fold by heparin (0.4 unit/ml) and blocked by phosphatidylserine (0.4 mg/ml). Partial dephosphorylation of the phosphorylated kinase is associated with a time-dependent decrease in the enzyme activity. This autophosphorylation-dependent protein kinase phosphorylates glycogen synthase (Km = 8 microM) at sites 2 and 3, resulting in inactivation of glycogen synthase. The results indicate that this independent kinase may represent a previously undiscovered liver multifunctional protein kinase which can be regulated by reversible phosphorylation.     

New superfamily members identified for Schiff-base enzymes based on verification of catalytically essential residues

Enzymes that utilize a Schiff-base intermediate formed with their substrates and that share the same alpha/beta barrel fold comprise a mechanistically diverse superfamily defined in the SCOPS database as the class I aldolase family. The family includes the "classical" aldolases fructose-1,6-(bis)phosphate (FBP) aldolase, transaldolase, and 2-keto-3-deoxy-6-phosphogluconate aldolase. Moreover, the N-acetylneuraminate lyase family has been included in the class I aldolase family on the basis of similar Schiff-base chemistry and fold. Herein, we generate primary sequence identities based on structural alignment that support the homology and reveal additional mechanistic similarities beyond the common use of a lysine for Schiff-base formation. The structural and mechanistic correspondence comprises the use of a catalytic dyad, wherein a general acid/base residue (Glu, Tyr, or His) involved in Schiff-base chemistry is stationed on beta-strand 5 of the alpha/beta barrel. The role of the acid/base residue was probed by site-directed mutagenesis and steady-state and pre-steady-state kinetics on a representative member of this family, FBP aldolase. The kinetic results are consistent with the participation of this conserved residue or position in the protonation of the carbinolamine intermediate and dehydration of the Schiff base in FBP aldolase and, by analogy, the class I aldolase family.     

Phosphorylation of the insulin receptor kinase by phosphocreatine in combination with hydrogen peroxide: the structural basis of redox priming.

Signaling by insulin requires autophosphorylation of the insulin receptor kinase (IRK) at Tyr1158, Tyr1162, and Tyr1163. Earlier experiments with (32)P-gamma-ATP indicated that the nonphosphorylated IRK (IRK-0P) is relatively inactive, and crystallographic data indicated that the ATP binding site of IRK-0P is blocked by its activation loop. We now show that phosphocreatine (PCr) in combination with hydrogen peroxide serves as an alternative phosphate donor and that ATP and PCr use distinct binding sites. Whereas phosphorylation of the IRK by ATP is inhibited by the nonhydrolyzable competitor adenylyl-imidodiphosphate, phosphorylation by PCr is enhanced. The IRK mutant Tyr1158Phe showed no phosphorylation with PCr but almost normal phosphorylation with ATP, whereas Tyr1162Phe was phosphorylated well with PCr but less then normal with ATP. 3-Dimensional models of IRK-0P revealed that the conversion of any of the four cysteine residues 1056, 1138, 1234, and 1245 into sulfenic acid produces structural changes that bring Tyr1158 into close contact with Asp1083 and render the well-known catalytic site at Asp1132 and Tyr1162 accessible from a direction that differs from the known ATP binding site. The mutant Cys1138Ala, in contrast, showed relatively inaccessible catalytic sites and weak catalytic activity in functional experiments. Taken together, these findings indicate that 'redox priming' of the IRK facilitates its autophosphorylation by PCr in the activation loop.     

Tyrosine nitration impairs mammalian aldolase A activity

Protein tyrosine nitration increases in vivo as a result of oxidative stress and is elevated in numerous inflammatory-associated diseases. Mammalian fructose-1,6-bisphosphate aldolases are tyrosine nitrated in lung epithelial cells and liver, as well as in retina under different inflammatory conditions. Using two-dimensional gel electrophoresis and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry, we now show that aldolase A is nitrated in human skin fibroblasts. To reveal the consequences of tyrosine nitration, we studied the impact of peroxynitrite on the glycolytic functions of aldolase A. A peroxynitrite concentration-dependent decrease in fructose-1,6-bisphosphate cleavage activity was observed with a concomitant increase in nitrotyrosine immunoreactivity. Both V(max) and the K(m) for fructose-1,6-bisphosphate decreased after incubation with peroxynitrite. Aldolase nitrotyrosine immunoreactivity diminished following carboxypeptidase Y digestion, demonstrating that tyrosine residues in the carboxyl-terminal region of aldolase are major targets of nitration. Aldolase A contains a carboxyl-terminal tyrosine residue, Tyr(363), that is critical for its catalytic activity. Indeed, tandem mass spectrometric analysis of trypsin-digested aldolase showed that Tyr(363) is the most susceptible to nitration, with a modification of Tyr(342) occurring only after nitration of Tyr(363). These tyrosine nitrations likely result in altered interactions between the carboxyl-terminal region and enzyme substrate or reaction intermediates causing the decline in activity. The results suggest that tyrosine nitration of aldolase A can contribute to an impaired cellular glycolytic activity.     

The carboxyl terminus of protein kinase c provides a switch to regulate its interaction with the phosphoinositide-dependent kinase, PDK-1

The function of protein kinase C family members depends on two tightly coupled phosphorylation mechanisms: phosphorylation of the activation loop by the phosphoinositide-dependent kinase, PDK-1, followed by autophosphorylation at two positions in the COOH terminus, the turn motif, and the hydrophobic motif. Here we address the molecular mechanisms underlying the regulation of protein kinase C betaII by PDK-1. Co-immunoprecipitation studies reveal that PDK-1 associates preferentially with its substrate, unphosphorylated protein kinase C, by a direct mechanism. The exposed COOH terminus of protein kinase C provides the primary interaction site for PDK-1, with co-expression of constructs of the carboxyl terminus effectively disrupting the interaction in vivo. Disruption of this interaction promotes the autophosphorylation of protein kinase C, suggesting that the binding of PDK-1 to the carboxyl terminus protects it from autophosphorylation. Studies with constructs of the COOH terminus reveal that the intrinsic affinity of PDK-1 for phosphorylated COOH terminus is over an order of magnitude greater than that for unphosphorylated COOH terminus, contrasting with the finding that PDK-1 does not bind phosphorylated protein kinase C effectively. However, effective binding of the phosphorylated species can be induced by the activated conformation of protein kinase C. This suggests that the carboxyl terminus becomes masked following autophosphorylation, a process that can be reversed by the conformational changes accompanying activation. Our data suggest a model in which PDK-1 provides two points of regulation of protein kinase C: 1) phosphorylation of the activation loop, which is regulated by the intrinsic activity of PDK-1, and 2) phosphorylation of the carboxyl terminus, which is regulated by the release of PDK-1 to allow autophosphorylation.     

Kinetic parameters of the protein tyrosine kinase activity of EGF-receptor mutants with individually altered autophosphorylation sites.

Epidermal growth factor (EGF)-receptor mutants in which individual autophosphorylation sites (Tyr1068, Tyr1148 or Tyr1173) have been replaced by phenylalanine residues were expressed in NIH-3T3 cells lacking endogenous EGF-receptors. Kinetic parameters of the kinase of wild-type and mutant receptors were compared. Both wild-type and mutant EGF-receptors had a Km(ATP) 1-3 microM for the autophosphorylation reaction, and a Km(ATP) of 3-7 microM for the phosphorylation of a peptide substrate. These are similar to the Km(ATP) values reported for EGF-receptor of A431 cells. A synthetic peptide representing the major in vitro autophosphorylation site Tyr1173 of the EGF-receptor (KGSTAENAEYLRV) was phosphorylated by wild-type receptor with a Km of 110-130 microM, and the peptide inhibited autophosphorylation with a Ki of 150 microM. Mutant EGF-receptors phosphorylated the peptide substrate with a Km of 70-100 microM. A similar decrease of Km (substrate) was obtained when the phosphorylation experiments were performed with the commonly applied substrates angiotensin II and a peptide derived from c-src. The Km of angiotensin II phosphorylation was reduced from 1100 microM for wild-type receptor to 890 microM for mutant receptor and for c-src peptide from 1010 microM to 770 microM respectively. The Vmax of the kinase was dependent on receptor concentration, but was not significantly affected by the mutation. Analogs of the Tyr1173 peptide in which the tyrosine residue was replaced by either a phenylalanine or an alanine residue also inhibited autophosphorylation with Ki of 650-750 microM. These analyses show that alterations of individual autophosphorylation sites do not have a major effect on kinase activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structural Similarities between Spinach Chloroplast and Cytosolic Class I Fructose 1,6-Bisphosphate Aldolases : Immunochemical and Amino-Terminal Amino Acid Sequence Analysis

Immunochemical studies using polyclonal antisera prepared individually against highly purified cytosolic and chloroplast spinach leaf (Spinacia oleracea) fructose bisphosphate aldolases showed significant cross reaction between both forms of spinach aldolase and their heterologous antisera. The individual cross reactions were estimated to be approximately 50% in both cases under conditions of antibody saturation using a highly sensitive enzyme-linked immunosorbent assay. In contrast, the class I procaryotic aldolase from Mycobacterium smegmatis and the class II aldolase from yeast (Saccharomyces cerevisiae) did not cross-react with either type of antiserum. The 29 residue long amino-terminal amino acid sequences of the procaryotic M. smegmatis and the spinach chloroplast aldolases were determined. Comparisons of these sequences with those of other aldolases showed that the amino-terminal primary structure of the chloroplast aldolase is much more similar to the amino-terminal structures of class I cytosolic eucaryotic aldolases than it is to the corresponding region of the M. smegmatis enzyme, especially in that region which forms the first “beta sheet” in the secondary structure of the eucaryotic aldolases. Moreover, results of a systematic comparison of the amino acid compositions of a number of diverse eucaryotic and procaryotic fructose bisphosphate aldolases further suggest that the chloroplast aldolase belongs to the eucaryotic rather than the procaryotic “family” of class I aldolases.