Amino acid sequences of two high-potential iron-sulfur proteins (HiPIPs) from the moderately halophilic purple phototrophic bacterium, Rhodospirillum salinarum.

The amino acid sequences of two very different high-potential iron-sulfur protein (HiPIP) isozymes have been determined from the moderately halophilic purple phototrophic bacterium, Rhodospirillum salinarum. Iso-1 HiPIP, which is monomeric and contains 57 amino acid residues, is most similar to the Thiobacillus ferrooxidans iron-oxidizing enzyme (45% identity and a 6-residue deletion). On the other hand, iso-2 HiPIP, which is isolated as an oligomer, contains a peptide chain with 54 amino acid residues. It is the smallest reported to date and is only 31% identical to iso-1 HiPIP. A massive deletion of 17 residues is found at the N-terminus, such that only 2 residues remain prior to the first cysteine. Iso-2 HiPIP also has a 12-residue insertion and a 5-residue deletion. Prior to this study, there were only 2 absolutely conserved residues (Tyr 19 and Gly 75, Chromatium numbering) in addition to the 4 iron-sulfur cluster binding cysteine residues among the 13 HiPIPs sequenced to date. We found that Tyr 19 is absent in iso-2 HiPIP along with the entire N-terminal loop. Moreover, Gly 75 is substituted in both R. salinarum HiPIPs. These characteristics make the R. salinarum HiPIPs, and especially iso-2, the most divergent yet characterized.     

Three-dimensional structure of the high-potential iron-sulfur protein isolated from the purple phototrophic bacterium Rhodocyclus tenuis determined and refined at 1.5 A resolution.

The molecular structure of the high-potential iron-sulfur protein (HiPIP) isolated from the phototrophic bacterium, Rhodocyclus tenuis, has been solved and refined to a nominal resolution of 1.5 A with a crystallographic R-factor of 17.3% for all measured X-ray data from 30 A to 1.5 A. It is the smallest of the HiPIP structures studied thus far with 62 amino acid residues. Crystals used in the investigation belonged to the space group P2(1) with unit cell dimensions of a = 36.7 A, b = 52.6 A, c = 27.6 A and beta = 90.8 degrees and contained two molecules per asymmetric unit. The structure was solved by a combination of multiple isomorphous replacement with two heavy-atom derivatives, anomalous scattering from the iron-sulfur cluster, symmetry averaging and solvent flattening. The folding motif for this HiPIP is characterized by one small alpha-helix, six Type I turns, an approximate Type II turn and one Type I' turn. As in other HiPIPs, the iron-sulfur cluster is co-ordinated by four cysteinyl ligands and exhibits a cubane-like motif. These cysteinyl ligands are all located in Type I turns. The hydrogen bonding around the metal cluster in the R. tenuis protein is similar to the patterns observed in the Chromatium vinosum and Ectothiorhodospira halophila HiPIPs. Several of the amino acid residues invariant in the previously determined C. vinosum and E. halophila structures are not retained in the R. tenuis molecule. There are 13 solvent molecules structurally conserved between the two R. tenuis HiPIP molecules in the asymmetric unit, some of which are important for stabilizing surface loops. Interestingly, while it is assumed that this HiPIP functions as a monomer in solution, the two molecules in the asymmetric unit pack as a dimer and are related to each other by an approximate twofold rotation axis.     

1H-NMR studies of high-potential iron-sulfur protein from the purple phototrophic bacterium, Rhodospirillum tenue

The high-potential iron-sulfur protein (HiPIP) from Rhodospirillum tenue (strain 3761) shows only a weak (20-25%) sequence similarity to HiPIPs from Chromatium vinosum, Ectothiorhodospira halophila and Ectothiorhodospira vacuolata, including the strict conservation of only two of the twelve residues assumed to be in the 4Fe-4S cluster packing region [Tedro, S. M., Meyer, T. E. and Kamen, M. D. (1979) J. Biol. Chem. 254, 1495-1500]. In spite of these differences, the general range and distribution of hyperfine-shifted 1H-NMR peaks of oxidized and reduced R. tenue HiPIP resemble those of E. halophila HiPIP I [Krishnamoorthi, R., Markley, J. L., Cusanovich, M. A., Pryzycieki, C. T. and Meyer, T. E. (1986) Biochemistry 25, 60-67]. Temperature- and pH-dependence and longitudinal relaxation behavior were determined for hyperfine-shifted peaks of the oxidized protein. Tentative assignments of peaks to ligands and aromatic residues suggest the presence of common apoprotein-active-site interactions in these proteins. Differences occur in the pattern of paramagnetically shifted peaks attributed to hydrogens bonded to the 4Fe-4S cluster. Hyperfine-shifted peaks of R. tenue HiPIP are not perturbed by pH changes in the range 5-9. In contrast, those of the C. vinosum protein exhibit a pH-dependence of chemical shifts that has been attributed to the titration of His42 [Nettesheim, D. G., Meyer, T. E., Feinberg, B. A. and Otvos, J. D. (1983) J. Biol. Chem. 258, 8235-8239]. Since R. tenue HiPIP contains no histidine, the present observation confirms the above hypothesis.     

Circular dichroism and redox properties of high redox potential ferredoxins

The circular dichroism (CD) spectra of 13 examples of high-potential iron-sulfur proteins (HiPIPs), a class of [4Fe-4S] ferredoxins, have been determined. In contrast to the proposal of Carter [Carter, C. W., Jr. (1977) J. Biol. Chem. 252, 7802-7811], no strict correlation between visible CD features and utilization of the [4Fe-4S]2+/[4Fe-4S]3+ oxidation levels was found. Although most HiPIPs have these features, the model requires their presence in all species. There is also no simple relationship between CD spectral features and the presence of conserved tyrosine-19. In addition, no apparent correlation between CD properties and oxidation-reduction potential could be detected. However, amino acid side chains in close contact to the iron-sulfur cluster appear to be important in modulating spectral and oxidation-reduction properties. In particular, the negative shoulder at 290 nm and negative maximum at 230 nm correlate with the presence of Trp-80 (Chromatium vinosum numbering). Two HiPIPs that do not have Trp at this position have positive bands at 290 and 230 nm. These bands in the Ectothiorhodospira halophila HiPIPs are apparently associated with Trp-49, which is located on the opposite side of the effective mirror plane of the cluster from Trp-80. The effect of pH on circular dichroism and redox potential in Thiocapsa roseopersicina HiPIP, which has a histidine at position 49, is consistent with the interaction of the side chain with the cluster. Despite specific differences in their CD spectra, the various HiPIPs studied show general similarity consistent with structural homology within this class of iron-sulfur proteins.     

Amino Acid Sequences and Distribution of High-Potential Iron–Sulfur Proteins That Donate Electrons to the Photosynthetic Reaction Center in Phototropic Proteobacteria

High-potential iron-sulfur protein (HiPIP) has recently been shown to function as a soluble mediator in photosynthetic electron transfer between the cytochrome bc1 complex and the reaction-center bacteriochlorophyll in some species of phototrophic proteobacteria, a role traditionally assigned to cytochrome c2. For those species that produce more than one high-potential electron carrier, it is unclear which protein functions in cyclic electron transfer and what characteristics determine reactivity. To establish how widespread the phenomenon of multiple electron donors might be, we have studied the electron transfer protein composition of a number of phototrophic proteobacterial species. Based upon the distribution of electron transfer proteins alone, we found that HiPIP is likely to be the electron carrier of choice in the purple sulfur bacteria in the families Chromatiaceae and Ectothiorhodospiraceae, but the majority of purple nonsulfur bacteria are likely to utilize cytochrome c2. We have identified several new species of phototrophic proteobacteria that may use HiPIP as electron donor and a few that may use cytochromes c other than c2. We have determined the amino acid sequences of 14 new HiPIPs and have compared their structures. There is a minimum of three sequence categories of HiPIP based upon major insertions and deletions which approximate the three families of phototrophic proteobacteria and each of them can be further subdivided prior to construction of a phylogenetic tree. The comparison of relationships based upon HiPIP and RNA revealed several discrepancies.     

Dynamics of wild-type HiPIPs: a Cys77Ser mutant and a partially unfolded HiPIP

The temperature dependence of the mean square displacement of the (57)Fe nuclei due to motion faster than 100 ns are measured by temperature-dependent M?ssbauer spectroscopy for oxidized and reduced HiPIPs from Ectothiorhodospira halophila, Chromatium vinosum WT and a Cys77Ser mutant. The behaviour is interpretable in the frame of the general model of protein dynamics distinguishing two temperature intervals. The character of harmonic and quasi-diffusional modes in HiPIPs is discussed. Dynamic information obtained from M?ssbauer spectroscopy and Fe K-edge EXAFS are compared. Structure dynamics of the iron-sulfur cluster in the partially unfolded reduced HiPIP from C. vinosum was investigated by M?ssbauer spectroscopy and EXAFS, indicating an intact metal centre and a protein backbone with a largely collapsed secondary structure. The role of the cofactor during protein folding is discussed. Differences in the dynamics between the native protein and the molten globule are found at physiological temperatures only. The structure and dynamic behaviour of the [Fe(4)S(4)]Cys(3)Ser cluster in the Cys77Ser mutant of the HiPIP from C. vinosum are analysed. The temperature dependence of electron relaxation in oxidized HiPIPs is investigated by M?ssbauer spectroscopy and analysed theoretically, considering spin-spin and spin-lattice relaxation. The latter consists of contributions from direct phonon bottleneck and Orbach mechanisms. The data agree with former pulsed EPR results. Orbach relaxation is interpreted as due to transitions between electronic isomers of oxidized HiPIPs. With this interpretation, the energetic difference between both isomers equals the energy gap estimated from the temperature dependence of the Orbach relaxation.     

Hydrogen-1 nuclear magnetic resonance investigation of high-potential iron-sulfur proteins from Ectothiorhodospira halophila and Ectothiorhodospira vacuolata: a comparative study of hyperfine-shifted resonances

Proton NMR spectra of the oxidized and reduced forms of high-potential iron-sulfur proteins (HiPIPs) were recorded at 200 MHz. The proteins studied were the HiPIPs I and II from Ectothiorhodospira halophila and Ectothiorhodospira vacuolata. Hyperfine-shifted peaks in spectra of the oxidized proteins were assigned to some of the protons of the cysteinyl ligands and aromatic residues at the active site on the basis of their chemical shifts, longitudinal relaxation times, and temperature-dependent behavior. The cysteinyl C beta-H protons were found to resonate downfield (about 100 ppm) and the C alpha-H protons upfield (about-25 ppm). This hyperfine shift pattern is consistent with the observed isotropic shift being contact in origin; it probably results from a pi-spin-transfer mechanism. The large magnitudes of the chemical shifts of peaks assigned to aromatic residues suggest that these residues interact with the iron-sulfur cluster via pi-pi overlap. Some of the hyperfine-shifted peaks observed in water were found to disappear in 2H2O solution. Such resonances probably arise from exchange-labile hydrogens of amino acid residues directly hydrogen bonded to the iron-sulfur cluster. In the case of HiPIPs I and II from E. vacuolata, whose spectra are similar except for the number of such peaks, the relative number of hydrogen bonds inferred to be present in the oxidized and reduced proteins qualitatively explains the difference between their midpoint redox potentials. On the other hand, for E. halophila HiPIPs I and II, consideration of the inferred number of hydrogen bonds alone fails to predict the sign of the difference between their midpoint redox potentials.(ABSTRACT TRUNCATED AT 250 WORDS)     

Complete amino acid sequence of the type II isozyme of rat hexokinase, deduced from the cloned cDNA: comparison with a hexokinase from novikoff ascites tumor

The 917-residue amino acid sequence of the Type II isozyme of rat hexokinase has been deduced from the nucleotide sequence of cloned cDNA. The sequences of 197 nucleotides in the 5' untranslated region and 687 bases of the 3' untranslated region have also been determined. A region of overlap between two discrete cDNA clones was confirmed by isolation and sequencing of a genomic DNA clone that spanned the region. Within this region, the 634-nucleotide coding sequence was divided into three exons, each of 150-250 nucleotides; these results suggest that the gene encoding Type II hexokinase is likely to be quite complex. There is extensive similarity between the sequences of the N- and C-terminal halves of the Type II isozyme, as previously seen with the Type I and III isozymes; this is consistent with the view that these enzymes evolved by a process of gene duplication and fusion. A cDNA encoding the entire C-terminal half of a hexokinase from Novikoff ascites tumor cells was also isolated and found to be identical to a cDNA encoding the corresponding region of the Type II isozyme of skeletal muscle. Northern analysis indicated that a single mRNA, approx 5200 nucleotides in length, encoded both the skeletal muscle and the tumor enzymes. These results do not support previous speculation that the hexokinase isozymes of normal tissue are distinct from those of tumors, and suggest the possibility that post-translational modifications of a single protein species might account for apparent differences between the isozymes of normal and tumor tissues.     

The nucleotide sequence of the ilvBN operon of Escherichia coli: sequence homologies of the acetohydroxy acid synthase isozymes.

Three acetohydroxy acid synthase isozymes, AHAS I (ilvBN), AHAS II (ilvGM) and AHAS III (ilvIH) catalyze the first step of the parallel isoleucine-valine biosynthetic pathway in Escherichia coli. Previous DNA sequence and protein purification data have shown that AHAS II and AHAS III are composed of large and small subunits encoded in the ilvGMEDA and ilvIH operons, respectively. Recent protein purification and characterization data have demonstrated that the AHAS I isozyme is also composed of large and small subunits (L. Eoyang, L. and P. M. Silverman [1984] J. Bacteriol. 157:184-189). Now the complete DNA sequence of the operon encoding the AHAS I isozyme has been determined. These data show that both AHAS I subunits (Mr 60,400 and Mr 11,100) are encoded in this operon. The coordinant regulation of both genes of the ilvBN operon has also been demonstrated. Comparisons of the DNA sequences of the genes encoding all three AHAS isozymes have been performed. Conserved homologies were observed between both the large and small subunits of all three isozymes. The closest homology was seen between the AHAS I and AHAS II isozymes. On the basis of these comparisons a rationale for the evolution of the AHAS isozymes in E. coli has been proposed.     

The molecular structure of the high potential iron-sulfur protein isolated from Ectothiorhodospira halophila determined at 2.5-A resolution

The molecular structure of a high potential iron-sulfur protein (HiPIP) isolated from the purple photosynthetic bacterium, Ectothiorhodospira halophila strain BN9626, has been solved by x-ray diffraction analysis to a nominal resolution of 2.5 A and refined to a crystallographic R value of 18.4% including all measured x-ray data from 30.0- to 2.5-A resolution. Crystals used in the investigation contained two molecules/asymmetric unit and belonged to the space group P21 with unit cell dimensions of a = 60.00 A, b = 31.94 A, c = 40.27 A, and beta = 100.5 degrees. An interpretable electron density map, obtained by combining x-ray data from one isomorphous heavy atom derivative with non-crystallographic symmetry averaging and solvent flattening, clearly showed that this high potential iron-sulfur protein contains 71 amino acid residues, rather than 70 as originally reported. As in other bacterial ferredoxins, the [4Fe-4S] cluster adopts a cubane-like conformation and is ligated to the protein via four cysteinyl sulfur ligands. The overall secondary structure of the E. halophila HiPIP is characterized by a series of Type I and Type II turns allowing the polypeptide chain to wrap around the [4Fe-4S] prosthetic group. The hydrogen bonding pattern around the cluster is nearly identical to that originally observed in the 85-amino acid residue Chromatium vinosum HiPIP and consequently, the 240 mV difference in redox potentials between these two proteins cannot be simply attributed to hydrogen bonding patterns alone.     

Soluble cytochromes and ferredoxins from the marine purple phototrophic bacterium, Rhodopseudomonas marina

Four soluble c-type cytochromes, the high redox potential 4-Fe-S ferredoxin known as HiPIP, a large molecular weight 2-Fe-S ferredoxin and a 4-Fe-S 'bacterial' ferredoxin, were isolated from extracts of two strains of Rps. marina. Cytochrome c-550, cytochrome c' and cytochrome c-549 were previously described, and we have extended their characterization. Cytochrome c-558, which has not previously been observed in Rps. marina, appears to be a low-spin isozyme of the more commonly observed high-spin cytochrome c'. HiPIP, which was not observed in previous work, was found to be abundant in Rps. marina. The 2-Fe-S ferredoxin, which has previously been observed only in Rps. palustris, has a native size greater than 100 kDa and a subunit size of 17 kDa. The 'bacterial' ferredoxin appears to have only a single four-iron-sulfur cluster. We examined photosynthetic membranes by difference spectroscopy and found abundant c-type cytochromes. Approximately one-quarter of the heme can be reduced by ascorbate and the remainder by dithionite. There is 2 nm difference between the high-potential heme (554 nm) and the low (552 nm). These characteristics resemble those of the tetraheme reaction center cytochrome of Rps. viridis. In addition to the electron transfer components, we found small amounts of a fluorescent yellow protein which has spectral resemblance to a photoactive yellow protein from Ec. halophila.     

Cathepsin D isozymes from porcine spleens. Large scale purification and polypeptide chain arrangements.

Six cathepsin D isozymes have been purified from porcine spleen using a large scale purification procedure. Five isozymes, I to V, have an identical molecular weight of 50,000 and are similar in specific activity. Isozymes I to IV contained two polypeptide chains each. The light and heavy chains have Mr = 15,000 and 35,000, respectively. Isozyme V is a single polypeptide. The molecular weight of the sixth isozyme is about 100,000 and it has only 5% of the specific activity of the other isozymes. On Ouchterlony immunodiffusion, an antiserum formed precipitin lines against the urea-denatured isozyme with Mr = 100,000. This immunoreactivity showed immunoidentity with those formed against other isozymes. The NH2-terminal sequence of light chains was identical for the isozymes. This sequence is homologous to the NH2-terminal sequence of other acid proteases, especially near the region of the active center aspartate-32. The NH2-terminal sequence of the single chain, isozyme V, Is apparently the same as the light chain sequence. The NH2-terminal sequence analysis of the heavy chain from isozyme I produced two sets of related sequences, suggesting the prescene of structural microheterogeneity. The carbohydrate analysis of the isozymes, the light chain, and the heavy chain revealed the presence of possibly four attachment sites, with one in the light chain and three in the heavy chain. Each carbohydrate unit contains 2 residues of mannose and 1 residue of glucosamine. The results suggest that the high molecular weight cathepsin D (Mr = 100,000) is the probable precursor of the single chain (Mr = 50,000), which in turn produces the two-chain isozymes. These are likely in vivo processes.     

AMP deaminase isozymes in human tissues

In human, there are four AMP deaminase (AMP aminohydrolase, EC 3.5.4.6) isozymes: E1, E2, M and L. Chromatographic, electrophoretic and immunological studies showed the existence of isozymes E1 and E2 in erythrocytes, isozyme M in muscle and isozyme L in liver and brain. The tissues such as heart, kidney and spleen contained isozymes E1, E2 and L. Isozymes E1, M and L were isolated as apparently homogeneous preparations. The three isozymes were all tetramers composed of identical subunits, but differing slightly in molecular weight; isozyme E1 showed a subunit molecular weight of 80 000, isozyme M 72 000 and isozyme L 68 000. They were immunologically different from one another. The antisera precipitated only the corresponding enzyme and did not precipitate any other isozyme. The three isozymes were also different in kinetic and regulatory properties. Isozyme E2 was very similar to isozyme E1 in immunological and kinetic properties, although isozyme E2 could be separated from isozyme E1 by phosphocellulose chromatography, and zonal electrophoresis.     

Purification and characterization of aldehyde dehydrogenase from human brain

Aldehyde dehydrogenase (EC 1.2.1.3) has been purified from human brain; this constitutes the first purification to homogeneity from the brain of any mammalian species. Of the three isozymes purified two are mitochondrial in origin (Peak I and Peak II) and one is cytoplasmic (Peak III). By comparison of properties, the cytoplasmic Peak III enzyme could be identified as the same as the liver cytoplasmic E1 isozyme (N.J. Greenfield and R. Pietruszko (1977) Biochim. Biophys. Acta 483, 35-45). The Peak I and Peak II enzymes resemble the liver mitochondrial E2 isozyme, but both have properties that differ from those of the liver enzyme. The Peak I enzyme is extremely sensitive to disulfiram while the Peak II enzyme is totally insensitive; liver mitochondrial E2 isozyme is partially sensitive to disulfiram. The specific activity is 0.3 mumol/mg/min for the Peak I and 3.0 mumol/mg/min for the Peak II enzyme; the specific activity of the liver mitochondrial E2 isozyme is 1.6 mumol/min/mg under the same conditions. The Peak I enzyme is also inhibited by acetaldehyde at low concentrations, while the Peak II enzyme and the liver mitochondrial E2 isozyme are not inhibited under the same conditions. The precise relationship of brain Peak I and II enzymes to the liver E2 isozyme is not clear but it cannot be excluded at the present time that the two brain mitochondrial enzymes are brain specific.     

Crystal structure and stability studies of C77S HiPIP: a serine ligated [4Fe-4S] cluster.

The crystal structure of Chromatium vinosum C77S HiPIP has been determined and is compared with that of wild type. This is the first reported crystal structure of a Ser ligated [4Fe-4S] cluster and reveals a 0.11 A shortening of the Fe-O bond (relative to Fe-S), but only minor structural alterations of the overall tertiary structure. Coordination changes are corroborated by resonance Raman spectroscopy. Comparison of the crystal and solution structures for HiPIPs identifies Phe48 as the main controller of solvent access to the Fe-S cluster; however, there is no significant change in cluster solvation of the C77S mutant relative to WT HiPIP. Ser ligation ultimately results in decreased cluster stability due to increased sensitivity to proton mediated degradation.     

Distinct C-terminal sequences of isozymes I and II of the human erythrocyte L-isoaspartyl/D-aspartyl protein methyltransferase

We have purified the more acidic major isozyme (II) of the human erythrocyte L-isoaspartyl/D-aspartyl methyltransferase and compared its structure to that of the previously sequenced isozyme I. These isozymes are both monomers of 25,000 molecular weight polypeptides and have similar enzymatic properties, but have isoelectric points that differ by one pH unit. Analysis of 16 tryptic peptides of isozyme II accounting for 89% of the sequence of isozyme I revealed no differences between these enzyme forms. However, analysis of a Staphylococcal V8 protease C-terminal fragment revealed that the last two residues of these proteins differed. The Trp-Lys-COOH terminus of isozyme I is replaced by a Asp-Asp-COOH terminus in isozyme II. Southern blot analysis of genomic DNA suggests that the human genome [corrected] may contain only a single gene encoding the enzyme. We propose that the distinct C-termini of isozymes I and II can arise from the generation of multiple mRNA's by alternative splicing.     

Molecular cloning of complementary DNA encoding one of the human pancreatic protease E isozymes

We have cloned a DNA from a human pancreatic cDNA library using a cloned rat pancreatic elastase 1 cDNA as a probe, and determined its nucleotide sequence. This cDNA contains a coding region of 810 nucleotides which encodes a 270-amino-acid protein. The deduced amino acid sequence shows less than 60% homologies with rat and porcine pancreatic elastase 1, although its substrate binding region is homologous with those of the above elastases 1. When this deduced amino acid sequence was compared with known amino acid sequences of pancreatic proteases other than elastases, it was found to contain an amino acid sequence which was highly homologous with the N-terminal amino acid sequence of porcine pancreatic protease E. We also purified human pancreatic protease E isozymes from human pancreatic juice, and determined their N-terminal amino acid sequences. One of the isozymes does not hydrolyze elastin but does hydrolyze a synthetic substrate. Endoglycosidase F digests glycoside bonds of the isozyme. These results suggest that the cDNA cloned by us corresponded to one of the human protease E isozymes.     

Partial purification and characterization of L-lactate dehydrogenase isozymes from sweet potato roots.

Lactate dehydrogenase [L-lactate: NAD oxidoreductase, EC 1.1.1.27] was isolated from sweet potato root tissues. Two species of the enzyme (isozymes I and II) were separated by DE-52 cellulose column chromatography from healthy, cut, and black-rot diseased tissues. Isozymes I and II were purified from healthy and diseased tissues, respectively. Reduction of pyruvate by NADH with either isozyme I or II was inhibited by pyruvate at high concentrations, by NAD+ and by several mononucleotides. Isozyme I was inhibited by a lower concentration of adenine nucleotide than isozyme II, and Km for pyruvate was increased markedly at acidic pH in the case of isozyme I, but only slightly in the case of isozyme II. The molecular weights of both isozymes were determined to be 150,000 and they were found to be charge isomers by polyacrylamide gel electrophoresis. The enzyme activity increased in response to infection by black-rot fungus but decreased in response to cutting.     

The nucleotide sequence and derived amino acid sequence of cDNA coding for mouse carbonic anhydrase II

The nucleotide sequence of a clone containing mouse carbonic anhydrase (CA) cDNA in pBR322 has been determined. The cloned cDNA contains all of the coding region except for nucleotides specifying the first eight amino acids, and all of the 3' noncoding region, which consists of 700 nucleotides. A cDNA clone was identified which contains an additional 54 bp at the 5' end, so that the complete amino acid sequence of mouse CA could be deduced. This sequence showed a 73-81% homology with other mammalian CA form II isozymes, 56-63% with form I isozymes, and 52-56% with form III isozymes. By examination of the amino acids which are unique and invariant for each isozyme, the mouse amino acid sequence was found to contain 16 of the 23 residues that are unique and invariant to mammalian CA form II isozymes, but only one or no residue for forms I and III, respectively.     

Pyruvate kinase isozymes in adult tissues and eggs of Rana pipiens. Comparative studies on the properties of the different isozymes

The properties of the isozymes of pyruvate kinase (ATP: pyruvate phosphotransferase, EC 2.7.1.40) found in unfertilized frog egg have been compared to those found in adult tissues of Rana pipiens. Chromatographic, kinetic, and electrophoretic data indicate that, of the five electrophoretic forms found in egg, the isozyme with the least anodic mobility (isozyme I) is the same molecular species as the only isozyme found in heart, and the egg isozyme with the greatest anodic mobility (isozyme V) is identical to the major isozyme found in liver.The activity of egg isozyme I was markedly inhibited by the antibody to the skeletal muscle enzyme, which has been shown previously to cross-react with the cardiac enzyme, but was unaffected by the antibody to liver isozyme V; the opposite effects were observed with egg isozyme V. The antibody to the skeletal muscle enzyme inhibited egg isozymes II > III > IV whereas the antibody to the liver enzyme gave the reverse inhibitory pattern, e.g., isozyme IV > III > II.In vitro dissociation-reassociation of mixtures of isozyme I and V led to the formation of the other three isozymes. Similar experiments performed individually with either egg isozyme III or IV resulted in the production of predominantly isozymes III, II, and I due to the instability of isozyme V during the hybridization procedure.The above results indicate that isozymes I and V are tetramers of the respective parental subunits and that isozymes II, III, and IV are hybrid molecules with subunit assignments of (I₃V₁), I₂V₂), and (I₁V₃), respectively.