Organization of the gene for an invertebrate mitochondrial creatine kinase: comparisons with genes of higher forms and correlation of exon boundaries with functional domains

Two major gene duplication events are thought to have taken place in the evolution of creatine kinases (CK) in the vertebrates - (1) the formation of distinct mitochondrial (MiCK) and cytoplasmic forms from the primordial gene and (2) subsequent formation of the sarcomeric (sar-) and ubiquitous (ubi-) isoforms of octameric MiCK and muscle (M) and brain (B) isoforms of dimeric, cytoplasmic CK. The genes of these two CK clades reflect a distant divergence as sar- and ubiMiCK genes consistently have nine protein-coding exons while M- and B-CK genes have seven protein-coding exons; these genes share only one common exon. CKs are also widely distributed in the invertebrates and it has recently been shown that MiCKs evolved well before the divergence of the major metazoan groups. In the present communication, we report the structure and topology of the gene for MiCK from the protostome marine worm Chaetopterus variopedatus. The protein-coding region of the gene for this primitive MiCK spans over 10 kb and consists of eight exons, the last five (E4-E8) have identical boundaries to the corresponding exons of sar- and ubiMiCK genes. Exon-3 of the C. variopedatus MiCK gene consists of the corresponding E3 and E4 of the vertebrate MiCKs with no intervening intron. E1 is longer and E2 is shorter in the polychaete MiCK gene than the counterpart sarcomeric and ubiquitous genes. The insertion of the intron in C. variopedatus E3 creating the two exons as well as the rearrangement of the intron between E1 and E2 must have occurred prior to or coincident with the duplication event creating the two vertebrate mitochondrial isoforms. Sarcomeric and ubiMiCKs display substantial differences from their invertebrate MiCK counterparts in properties relating to octamer stability and membrane binding. The evolutionary changes in gene topology may be a component of this functional progression.     

Multiple isoforms and an unusual cathodic isoform of creatine kinase from channel catfish (Ictalurus punctatus)

In vertebrates, the creatine kinase (CK) family consists of two cytosolic and two mitochondrial isoforms. The two cytosolic isoforms are the muscle type (M-CK) and the brain type (B-CK). Here we report multiple CK isoenzymes in the diploid channel catfish (Ictalurus punctatus) with one unusual cathodic isoform that was previously found only in pathological situations in human. The cathodic CK isoform existed only in the channel catfish stomach, ovary, and spleen, but not in any other species analyzed such as tilapia, smallmouth bass, chicken, or rat. Two genes encode the multiple forms of the channel catfish M-CK cDNAs. M-CK1 has three alleles, M-CK1.1, M-CK1.2, and M-CK1.3, while M-CK2 has just one allele as determined by analysis of 17 cDNA clones and by allele-specific PCR. M-CK1 encodes a protein of 381 amino acids and the M-CK2 cDNA encodes a protein of 380 amino acids. The two cDNAs shared an 86% identity and both have the nine diagnostic boxes for cytosolic CKs and thus are of cytosolic origin. The M-CK1 gene was isolated, sequenced, and characterized and its promoter should be useful for transgenic research for muscle-specific expression.     

Comparison of kinetic constants of creatine kinase isoforms

The purpose of this study was to elucidate the functional differences between the CK isoforms by cloning the cDNAs of 12 CK isoforms: the M and B cytoplasmic forms and uMiCK from mouse, the M1, M2 and B cytoplasmic forms from Danio rerio, M1 and M2 cytoplasmic forms from the lower vertebrate Lampetra japonica, a cytoplasmic CK and a MiCK from the marine worm Neanthes diversicolor, and a cytoplasmic CK and a MiCK from the soft coral Dendronephthya gigantea. These were expressed in Escherichia coli as a fusion protein with maltose-binding protein, and kinetic constants (K(m), K(d) and k(cat)) of all the recombinant enzymes, except for the unstable Dendronephthya cytoplasmic CK, were determined for the forward reaction. The kinetic constants of the M- and B-forms of the mouse and Danio cytoplasmic CKs differed significantly, with the K(m) for creatine (K(m)Cr) of M-CK being three- to nine-fold higher than that of B-CK, possibly reflecting differences in the concentration of creatine in muscle and brain cells. The mouse uMiCK had the lowest K(m)Cr value among the CK isoforms. In addition, it also exhibited a strong synergism for substrate binding (K(d)/K(m)=11.8). These results indicate that uMiCK has unique characteristics compared with other CK isoforms. Two subisoforms of M-CK were found in the lower vertebrate L. japonica, and the kinetic constants of recombinant M1- and M2-CKs differed significantly. The M1- and M2-CKs were expressed in skeletal muscle with a ratio of 7:3, while M1-CK was the predominant subisoform in the testis. The kinetic constants of cytoplasmic CK from the marine worm Neanthes were significantly different from those of Neanthes MiCK, possibly indicating that functional differences among CK isoforms occurred at least before the divergence of annelids from other protostome invertebrates.     

Elements of the major myofibrillar binding peptide motif are present in the earliest of true muscle type creatine kinases

Most vertebrates possess two genes for cytoplasmic creatine kinase (CK) coding for muscle (M-CK) and brain (B-CK) isoforms which assemble into homo-dimeric (MM, BB) and hetero-dimeric (MB) active enzymes. In mammals and birds, a significant fraction of MM-CK is bound to the myofibrillar M-line where it is thought to facilitate energy buffering and transport. Myofibrillar binding is mediated by major and minor lysine charge clamp motifs (K104/K115 [major] and K8/K24 [minor] in chicken M-CK) located in the N-terminal region [J. Cell Biol. 149 (2000) 1225]. We have obtained the cDNA and deduced amino acid sequences for cytoplasmic CKs from two hagfish, Myxine glutinosa and Eptatretus stoutii, non-vertebrate craniates, and the sequences for two cytoplasmic CKs from the lamprey Lampetra japonica, a jawless true vertebrate. All four cDNAs code for CKs consisting of approximately 380 residues. Phylogenetic analyses showed that the hagfish and lamprey CKs are coded for by genes which are clearly muscle type (M) creatine kinases. Two of these four M-CKs have the K104/K115-equivalent residues of the major myofibrillar binding region while the other two have the K115 equivalent but lack the corresponding K104 residue. All four M-CKs lack the K8/K24 equivalent elements of the minor myofibrillar binding region. Comparison of these sequences to corresponding sequences of cytoplasmic CKs from two protochordates (tunicate, amphioxus) and M- and B-CKs from true fish and above reveal a pattern of acquisition (and loss) of key lysine residues consistent with the physiological context in which these enzymes operate.     

银鲫肌酸激酶M3-CK cDNA的克隆及其表达特征

用抑制性差减杂交结合SMART cDNA合成和RACE—PCR技术克隆到雌核发育银鲫(Carassius auratus gibelio)肌酸激酶M3-CK基因的全长cDNA。银鲫M3-CK cDNA全长1551bp，编码380个氨基酸，与普通鲤鱼(cyprinus carpio)M3-CK的氨基酸序列同源性高达95％。种系分析表明，银鲫M3-CK与其它脊椎动物的肌肉型肌酸激酶聚为较近的一支，与鲤鱼的M3-CK聚在一起，与脑特异型肌酸激酶及线粒体型肌酸激酶分歧较大。虚拟Northern杂交显示银鲫M3-CK基因在胚胎发育中差异表达。RT—PCR表明，银鲫M3-CK基因在成熟卵母细胞和胚胎发育早期可检测到少量的转录产物，在胚胎发育期间从肌肉效应期开始转录，并一直持续表达。组织RT—PCR表明，银鲫M3-CK基因只在心脏和肌肉表达。     

鳜肌酸激酶M-CK cDNA的克隆与组织表达分析

利用RT–PCR和cDNA末端快速扩增法（RACE）克隆了鳜（Siniperca chuatsi）肌酸激酶（creatine kinase,CK）cDNA序列,并分析了该基因的结构特征和系统关系。鳜CK cDNA序列全长1586 bp,包括5′端非翻译区92 bp,3′端非翻译区348 bp和开放阅读框（ORF）1 146 bp,共编码381个氨基酸。鳜CK具有脊椎动物CK共有的保守结构域和肌型肌酸激酶（M-CK）同工酶的特异识别位点;氨基酸序列与M-CK型的相似度最高,而与脑型肌酸激酶（B-CK）和线粒体型肌酸激酶（Mi-CKs）的相似度较低;在CK系统关系树中鳜CK与M-CK群聚类。这些均表明,鳜CK属脊椎动物M-CK型。RT-PCR分析表明,鳜M-CK在成体不同组织中的表达量不同,其中,在皮肤、卵巢、肾脏、胃、肌肉和心脏中表达较强;而在眼和脑、肝胰脏中表达较弱。     

Spermatogenesis-related change in the synthesis of the creatine kinase B-type and M-type isoforms in human spermatozoa

We have demonstrated earlier that the per sperm creatine-N-phosphotransferase (CK) activity was increased in oligospermic vs. normospermic men. The increased sperm CK activity is related to higher concentrations of cellular CK, which may indicate a defect of cytoplasmic extrusion during spermatogenesis. In the present work, we examined whether in spermatozoa, similar to muscle, there is a change in the synthesis of B-CK and M-CK isoforms during cellular differentiation. In 109 normospermic and 50 oligospermic specimens (sperm concentrations 60.6 +/- 3.7 vs. 8.8 +/- 1.3 million sperm/ml; all values expressed as mean +/- SEM), the relative concentrations of the M-CK isoform (M-CK/M-CK + B-CK) were 27.2% +/- 2.1% vs. 6.7% +/- 0.9% (P less than 0.001). The per sperm CK activities showed comparable differences (0.21 +/- 0.02 vs. 0.89 +/- 0.1 CK IU/100 million sperm; P less than 0.001) in the two groups, and there was a close correlation between per sperm CK activities and M-CK concentrations (R = 0.69, P less than 0.001, N = 159). This indicates that the loss of cytoplasm and the commencement of M-CK isoform synthesis are related events during the last phase of spermatogenesis, also that the incidence of spermatozoa with incomplete cellular maturation is higher in oligospermic specimens. In characterizing the M-CK, we found that sperm (unlike muscle tissue) lack the MB hybrid of CK dimers. However, in the presence of muscle M-CK, the muscle-sperm MB-CK hybrid has formed. Thus in sperm and muscle the M-CK isoforms are structurally different, whereas the B-CKs are apparently homologous.(ABSTRACT TRUNCATED AT 250 WORDS)     

Lactate dehydrogenase (LDH) gene duplication during chordate evolution: the cDNA sequence of the LDH of the tunicate Styela plicata

L-Lactate dehydrogenase (L-LDH, E.C. 1.1.1.27) is encoded by two or three loci in all vertebrates examined, with the exception of lampreys, which have a single LDH locus. Biochemical characterizations of LDH proteins have suggested that a gene duplication early in vertebrate evolution gave rise to Ldh-A and Ldh-B and that an additional locus, Ldh-C arose in a number of lineages more recently. Although some phylogenetic studies of LDH protein sequences have supported this pattern of gene duplication, others have contradicted it. In particular, a number of studies have suggested that Ldh-C represents the earliest divergence among vertebrate LDHs and that it may have diverged from the other loci well before the origin of vertebrates. Such hypotheses make explicit statements about the relationship of vertebrate and invertebrate LDHs, but to date, no closely related invertebrate LDH sequences have been available for comparison. We have attempted to provide further data on the timing of gene duplications leading to multiple vertebrate LDHs by determining the cDNA sequence of the LDH of the tunicate Styela plicata. Phylogenetic analyses of this and other LDH sequences provide strong support for the duplications giving rise to multiple vertebrate LDHs having occurred after vertebrates diverged from tunicates. The timing of these LDH duplications is consistent with data from a number of other gene families suggesting widespread gene duplication near the origin of vertebrates. With respect to the relationships among vertebrate LDHs, our data are not consistent with previous claims that Ldh-C represented the earliest divergence. However, the precise relationships among some of the main lineages of vertebrate LDHs were not resolved in our analyses.      

Origin of the genes for the isoforms of creatine kinase

Creatine kinase (CK) is a member of a family of phosphoryl transfer enzymes called phosphagen (guanidino) kinases which play a central role in cellular energy homeostasis. There are three CK isoform gene groups, each coding for proteins targeted to different intracellular compartments--cytoplasmic (CytCK), mitochondrial (MtCK) and flagellar (FlgCK). The former two CKs are either dimeric or octameric while FlgCKs are contiguous trimers consisting of three fused, complete CK domains. Conventional wisdom supports the view that CKs evolved from a cytoplasmic, monomeric ancestral protein closely related to a phosphagen kinase homologue, arginine kinase (AK). Recently, it has been shown that a demosponge (Phylum Porifera) expresses a true MtCK and two dimeric, protoflagellar CKs (protoflgCK) with great similarity to FlgCKs. To further probe the early evolution of CK, we have obtained additional sequences for Mt- and protoflgCKs from two more demosponges and from three hexactinellid (glass) sponges as well as an MtCK sequence from a basal metazoan cnidarian. Phylogenetic analyses using Maximum Likelihood (ML) of these new CK sequences with other CKs and phosphagen kinases yielded a consensus tree containing an assemblage of MtCKs and a supercluster consisting of protoflg-, Flg- and CytCKs. The MtCKs appear basal in the tree topology consistent with prior results. Within the protoflg-, Flg- and CytCK supercluster, the protoflgCKs appear to be allied to the domains of the FlgCKs, although the support is not robust. PCR amplification of genomic DNA and sequencing of the genes for Mt- and protoflgCK from the demosponge Suberites fuscus showed that the sponge MtCK shares four-five common intron:exon boundaries with invertebrate, protochordate and vertebrate MtCKs supporting a common ancestry and the extreme conservation of intron:exon organization in MtCK genes. The protoflgCK gene organization was highly divergent in relation to other CK genes but shares a common intron:exon boundary with domain 2 of the gene for the FlgCK from the tunicate Ciona intestinalis, providing support for the linkage of the protoflgCKs with the FlgCKs. Our results show that the two, major CK gene lineages are present in arguably the oldest, extant metazoan group, the hexactinellid sponges, indicating that these two genes are ancient and confirming prior work that the MtCK gene is likely basal and ancestral.     

Molecular evolution of nitric oxide synthases in metazoans

Nitric oxide synthases (NOS), the enzymes responsible for the NO synthesis, are present in all eukaryotes. Three isoforms (neuronal, inducible and endothelial), encoded by different loci, have been described in vertebrates, although the endothelial isoform seems to be restricted to tetrapods. In invertebrates, a variety of NOS isoforms have been variably annotated as "inducible" or "neuronal", while others lack precise annotation. We have performed an exhaustive collection of the available NOS amino-acid sequences in order to perform a phylogenetic analysis. We hypothesized that the NOS isoforms reported in vertebrates derive from 1) different invertebrate NOS, 2) a single invertebrate ancestral gene, through an event related to the double whole genomic duplication that occurred at the origin of vertebrates, and 3) the endothelial form of NOS appeared late in the evolution of vertebrates, after the split of tetrapods and fishes. Our molecular evolution analysis strongly supports the second scenario, the three vertebrate NOS isoforms derived from a single ancestral invertebrate gene. Thus, the diverse NOS isoforms in invertebrates can be explained by events of gene duplication, but their characterization as "inducible" or "neuronal" should only be justified by physiological features, since they are evolutionarily unrelated to the homonym isoforms of vertebrates.     

Accumulation of creatine kinase mRNA during myogenesis: molecular cloning of a B-creatine kinase cDNA

Cytosolic creatine kinase isoenzymes MM, MB, and BB are assembled from M or B subunits which occur in different relative amounts in specific tissues. The accumulation of mRNAs encoding the M and B subunits was measured during myogenesis in culture. The relative concentration of the two mRNAs was determined by hybridization with a M-CK cDNA probe isolated previously and a B-CK cDNA probe, the cloning and characterization of which is reported here. The B-CK cDNA hybridizes specifically to a 1.6-kb mRNA found in brain and gizzard but not in adult skeletal muscle tissue. The M-CK cDNA hybridizes to a smaller mRNA 1.4-kb long which is specific to skeletal muscle. In culture, the B-CK mRNA is transiently induced and then declines to a low but detectable level.     

Heterogeneous cellular expression of creatine kinase isoenzyme during normal rat heart development

The degree to which developmentally related alterations in cardiac creatine kinase (CK) activity reflect modification of CK isoenzyme gene expression remains uncertain. The present studies addressed this question by assessing multiple aspects of CK in rat heart during the perinatal to adult transition. In addition to whole tissue, isolated and purified muscle and nonmuscle cells were studied, as well as myofibrillar, mitochondrial, and cytosolic subcellular fractions. Whole homogenate CK enzyme specific activity nearly doubled during the weanling to adult developmental period. Muscle cell CK activity increased by a similar magnitude. Nonmuscle cell activity decreased. In the adult heart, both myofibrillar and mitochondrial CK activities were augmented versus the weanling heart. The cytoplasmic fraction activity held constant during development. Electrophoretic isoenzyme analyses of both weanling and adult cardiac muscle cells indicated the presence of mitochondrial CK and MM-CK isoforms. Weanling heart nonmuscle cells contained mitochondrial, MM, MB, and BB isoforms; however, BB isoform was not detected in the adult heart nonmuscle cells. Arrhenius plots provided information regarding heart muscle and nonmuscle cell alterations during development. CK activation energies were also determined for whole tissue, muscle/nonmuscle cells, myofibrils, mitochondria, and cytosol. Results demonstrate that heterogeneous muscle/nonmuscle cellular composition and differential myofibrillar/mitochondrial subcellular composition account for normal, developmentally related changes in heart CK enzyme activity. CK isoenzyme gene expression changes were not detected in cardiac muscle cells, and transition of CK-B to CK-M gene expression is limited to nonmuscle cells during normal, weanling to adult development in the rat heart.     

Regulation of creatine kinase induction in differentiating mouse myoblasts.

The regulation of creatine kinase (CK) induction during muscle differentiation was analyzed with MM14 mouse myoblasts. These cells withdraw from the cell cycle and commit to terminal differentiation when fed with mitogen-depleted medium. Myoblasts contained trace amounts of an isozyme of brain CK (designated BB-CK), but differentiation was accompanied by the induction of two other isozymes of muscle and brain CKs (designated MM-CK and MB-CK). Increased CK activity was detectable within 6 h of mitogen removal, 3 h after the first cells committed to differentiation and 6 h before fusion began. By 48 h, MM-CK activity increased more than 400-fold, MB-CK activity increased more than 150-fold, and BB-CK activity increased more than 10-fold. Antibodies prepared against purified mouse MM-CK cross-reacted with muscle and brain CKs (designated M-CK and B-CK, respectively) from a variety of species and were used to demonstrate that the increase in enzymatic activity was paralleled by an increase in the protein itself. CK antibodies were also used to aid in identifying cDNA clones to M-CK. cDNA sequences which corresponded to protein-coding regions cross-hybridized with B-CK mRNA; however, a subclone containing the 3'-nontranslated region was unique and was used to quantitate M-CK mRNA levels during myoblast differentiation. M-CK mRNA was not detectable in myoblasts, but within 5 to 6 h of mitogen withdrawal (6 to 7 h before fusion begins) it accumulated to about 30 molecules per cell. By 24 h, myotubes contained approximately 1,100 molecules per nucleus of M-CK mRNA.     

A genomewide survey of developmentally relevant genes in Ciona intestinalis. IX. Genes for muscle structural proteins

Ascidians are simple chordates that are related to, and may resemble, vertebrate ancestors. Comparison of ascidian and vertebrate genomes is expected to provide insight into the molecular genetic basis of chordate/vertebrate evolution. We annotated muscle structural (contractile protein) genes in the completely determined genome sequence of the ascidian Ciona intestinalis, and examined gene expression patterns through extensive EST analysis. Ascidian muscle protein isoform families are generally of similar, or lesser, complexity in comparison with the corresponding vertebrate isoform families, and are based on gene duplication histories and alternative splicing mechanisms that are largely or entirely distinct from those responsible for generating the vertebrate isoforms. Although each of the three ascidian muscle types - larval tail muscle, adult body-wall muscle and heart - expresses a distinct profile of contractile protein isoforms, none of these isoforms are strictly orthologous to the smooth-muscle-specific, fast or slow skeletal muscle-specific, or heart-specific isoforms of vertebrates. Many isoform families showed larval-versus-adult differential expression and in several cases numerous very similar genes were expressed specifically in larval muscle. This may reflect different functional requirements of the locomotor larval muscle as opposed to the non-locomotor muscles of the sessile adult, and/or the biosynthetic demands of extremely rapid larval development.     

Evolution and Divergence of the Genes for Cytoplasmic,Mitochondrial, and Flagellar Creatine Kinases

Creatine kinase (CK) plays a central role in energy homeostasis in cells that display high and variable rates of energy turnover. A number of CK genes exist, each being targeted to particular intracellular compartments. In the vertebrates, two genes code for proteins which form homo- and heterodimers targeted to the cytoplasm, while two additional genes code for primarily octameric proteins targeted to the mitochondrial intermembrane space. Yet another gene is present in certain groups which codes for three fused, complete CK domains and is typically targeted to the flagellar membrane of primitive-type spermatozoa. CK is widely distributed in protochordates and both protostome and deuterostome invertebrate groups. The evolutionary relationships of these CK genes have not been fully elucidated. The present communication reports new cDNA-derived deduced amino acid sequences for four cytoplasmic and three mitochondrial CKs and one flagellar CK from lophotrochozoan, protostome invertebrates as well as a new cytoplasmic CK sequence from a protochordate tunicate. These new sequences, coupled with available sequences in the databases and sequences extracted from genome sequencing projects, provide revealing insights into the evolution and divergence of CK genes. Phylogenetic analyses showed that single cytoplasmic, mitochondrial, and flagellar CK genes were present prior to the divergence of the protostomes and deuterostomes. The flagellar CK gene may have evolved within the cytoplasmic gene clade, although the evidence is somewhat equivocal. The two cytoplasmic genes in the vertebrates, and most likely the two mitochondrial genes, evolved after the divergence of the craniates from the protochordates. Comparison of the structure of the genes for selected cytoplasmic, mitochondrial, and flagellar CKs revealed two identical intron boundaries, further reinforcing the notion of a common evolutionary origin, but also showed patterns of changes in structure consistent with each gene type. These studies show that the cytoplasmic, mitochondrial, and flagellar CK genes are rather ancient and that there has been a systematic pattern of duplication and divergence consistent with changing nature of energy demands and physicochemical environment in the cells where they are expressed.[Reviewing Editor: Martin Kreitman]     

Three Drosophila beta-tubulin sequences: a developmentally regulated isoform (beta 3), the testis-specific isoform (beta 2), and an assembly-defective mutation of the testis-specific isoform (B2t8) reveal both an ancient divergence in metazoan isotypes and structural constraints for beta-tubulin function.

The genomic DNA sequence and deduced amino acid sequence are presented for three Drosophila melanogaster beta-tubulins: a developmentally regulated isoform beta 3-tubulin, the wild-type testis-specific isoform beta 2-tubulin, and an ethyl methanesulfonate-induced assembly-defective mutation of the testis isoform, B2t8. The testis-specific beta 2-tubulin is highly homologous to the major vertebrate beta-tubulins, but beta 3-tubulin is considerably diverged. Comparison of the amino acid sequences of the two Drosophila isoforms to those of other beta-tubulins indicates that these two proteins are representative of an ancient sequence divergence event which at least preceded the split between lines leading to vertebrates and invertebrates. The intron/exon structures of the genes for beta 2- and beta 3-tubulin are not the same. The structure of the gene for the variant beta 3-tubulin isoform, but not that of the testis-specific beta 2-tubulin gene, is similar to that of vertebrate beta-tubulins. The mutation B2t8 in the gene for the testis-specific beta 2-tubulin defines a single amino acid residue required for normal assembly function of beta-tubulin. The sequence of the B2t8 gene is identical to that of the wild-type gene except for a single nucleotide change resulting in the substitution of lysine for glutamic acid at residue 288. This position falls at the junction between two major structural domains of the beta-tubulin molecule. Although this hinge region is relatively variable in sequence among different beta-tubulins, the residue corresponding to glu 288 of Drosophila beta 2-tubulin is highly conserved as an acidic amino acid not only in all other beta-tubulins but in alpha-tubulins as well.     

Malate dehydrogenase (sMDH) in Amazon cichlid fishes: evolutionary features

• 1.1. The sMDH isozyme system was studied in five species of cichlid fishes found in the Amazon hydrographic basin (Astronotus ocellatus, Cichla monoculus, Geophagus cff harreri, Cichlassoma severum and Mesonauta insignis). All studied specimens presented a six-banded electrophoretic pattern, suggesting the existence of three gene loci (sMDH-A1, sMDH-B11 and sMDH-B21).
• 2.2. Klebe's serial dilutions, thermostability tests and tissue specificity performed on the sMDH of studied species indicated no divergence between B11 and B21 loci products, suggesting that these genes probably undergo the same regulatory gene action and that the duplication event occurred recently, after A1 and B1 divergence.
• 3.3. The appearance of the same characteristics in all specimens, and the chromosomic picture of the family, suggest the occurrence of an event of duplication “in tandem” in the ancestors of Amazon cichlids.

     

Isoenzyme-specific interaction of muscle-type creatine kinase with the sarcomeric M-line is mediated by NH(2)-terminal lysine charge-clamps

Creatine kinase (CK) is located in an isoenzyme-specific manner at subcellular sites of energy production and consumption. In muscle cells, the muscle-type CK isoform (MM-CK) specifically interacts with the sarcomeric M-line, while the highly homologous brain-type CK isoform (BB-CK) does not share this property. Sequence comparison revealed two pairs of lysine residues that are highly conserved in M-CK but are not present in B-CK. The role of these lysines in mediating M-line interaction was tested with a set of M-CK and B-CK point mutants and chimeras. We found that all four lysine residues are involved in the isoenzyme-specific M-line interaction, acting pair-wise as strong (K104/K115) and weak interaction sites (K8/K24). An exchange of these lysines in MM-CK led to a loss of M-line binding, whereas the introduction of the very same lysines into BB-CK led to a gain of function by transforming BB-CK into a fully competent M-line-binding protein. The role of the four lysines in MM-CK is discussed within the context of the recently solved x-ray structures of MM-CK and BB-CK.     

Kinetic, thermodynamic, and developmental consequences of deleting creatine kinase isoenzymes from the heart. Reaction kinetics of the creatine kinase isoenzymes in the intact heart

Creatine kinase (CK) exists as a family of isoenzymes in excitable tissue. We studied isolated perfused hearts from mice lacking genes for either the main muscle isoform of CK (M-CK) or both M-CK and the main mitochondrial isoform (Mt-CK) to determine 1) the biological significance of CK isoenzyme shifts, 2) the necessity of maintaining a high CK reaction rate, and 3) the role of CK isoenzymes in establishing the thermodynamics of ATP hydrolysis. (31)P NMR was used to measure [ATP], [PCr], [P(i)], [ADP], pH, as well as the unidirectional reaction rate of PCr--> [gamma-P]ATP. Developmental changes in the main fetal isoform of CK (BB-CK) were unaffected by loss of other CK isoenzymes. In hearts lacking both M- and Mt-CK, the rate of ATP synthesis from PCr was only 9% of the rate of ATP synthesis from oxidative phosphorylation demonstrating a lack of any high energy phosphate shuttle. We also found that the intrinsic activities of the BB-CK and the MM-CK isoenzymes were equivalent. Finally, combined loss of M- and Mt-CK (but not loss of only M-CK) prevented the amount of free energy released from ATP hydrolysis from increasing when pyruvate was provided as a substrate for oxidative phosphorylation.