Mouse Muscle Creatine Kinase Gene Research Articles

An Adeno-Associated Virus Vector Efficiently and Specifically Transduces Mouse Skeletal Muscle

Expression of a therapeutic gene in the skeletal muscle is a practical strategy to compensate a patients' insufficient circulating factor. Its clinical application requires a muscle-targeting vector capable of inducing a continuous high-level transgene expression. We modified an adeno-associated virus serotype 2 (AAV2) vector expressing luciferase from the mouse muscle creatine kinase gene promoter-enhancer (Ckm). First, AAVS1 insulator was inserted into the vector genome for transcriptional enhancement. This increased transduction of mouse quadriceps muscle by 11-fold at 4weeks after intramuscular injection. Second, two capsid modifications were combined (21F capsid): incorporation of a segment of AAV1 capsid to produce a hybrid capsid and substitution of a tyrosine with a phenylalanine. Use of 21F capsid increased muscle transduction further by 18-fold, resulting in 200-fold higher efficacy than that of the unmodified vector. Compared with a vector having human elongation factor 1α promoter which showed similar efficacy in the muscle, this vector having Ckm transduced non-muscle organs less efficiently after intravenous administration. The AAV2 vector composed of the modified genome and capsid provides a backbone to develop a clinical vector expressing a therapeutic gene in the muscle.

Expression of muscle creatine kinase gene of mice and interaction of nuclear proteins with MEF-2, E boxes and A/T-rich elements during aging.

The changes in the expression of muscle creatine kinase (MCK) gene in the heart and skeletal muscle of mice during aging were studied. Its expression declines as a function of age in the heart, however, no age-related change is observed in the skeletal muscle. The cis-acting elements, MEF-2, E boxes and A/T rich elements present in the enhancer region of the mouse MCK gene are known to regulate the expression of the gene. Hence, these elements were subcloned and electrophoretic mobility shift assay was carried out to investigate the changes in the binding of the nuclear trans-acting protein factors of the heart with these elements as a function of age. These factors showed specificity for the respective cis-acting elements. Furthermore, the binding of these factors was found to decrease during aging which may contribute to the age-related decline in the expression of the MCK gene and activity of the heart.

Differences in the Function of Three Conserved E-boxes of the Muscle Creatine Kinase Gene in Cultured Myocytes and in Transgenic Mouse Skeletal and Cardiac Muscle

The 1256-base pair enhancer-promoter of the mouse muscle creatine kinase gene includes three CAnnTG E-boxes that are conserved among mammals and have flanking and middle sequences conforming to consensus muscle regulatory factor binding sites. This study seeks to determine whether these E-boxes are critical for muscle creatine kinase expression in physiologically distinct muscles. Mutations of the "right" and "left" E-boxes in the enhancer decreased expression in cultured skeletal myocytes approximately 10- and 2-fold, respectively, whereas a "promoter" E-box mutation had little effect. In neonatal myocardiocytes, the left E-box mutation decreased expression approximately 3-fold, whereas right or promoter E-box mutations had no effect. Very different effects were seen in transgenic mice, where the promoter E-box mutation decreased expression in quadriceps, extensor digitorum longus, and soleus approximately 10-fold, and approximately 100-fold in distal tongue, diaphragm, and ventricle. The right E-box mutation, tested in the presence of the other two mutations, caused a significant decrease in distal tongue, but not in quadriceps, extensor digitorum longus, soleus, or ventricle. Mutation of the left E-box actually raised expression in soleus, suggesting a possible repressor role for this control element. The discrepancies between mutation effects in differentiating skeletal muscle cultures, neonatal myocardiocytes, and adult mice suggested that the E-boxes might play different roles during muscle development and adult steady-state function. However, transgenic analysis of embryonic and early postnatal mice indicated no positive role for these three E-boxes in early development, implying that differences in E-box function between adult muscle and cultured cells are the result of physiological signals.

Interaction of Nuclear Proteins with Repeat Sequences in the 5′ Flanking Region of Mouse Muscle Creatine Kinase Gene during Aging

The 5′ flanking region of the mouse muscle creatine kinase (MCK) gene contains two repeat sequences—a mononucleotide repeat, (A)22 (−2694 to −2673), and a tetranucleotide repeat, (GTTT)8 (−2962 to −2931). We show here that these repeats in the mouse MCK gene bind to specific nuclear protein factors. Some of the factors interacting with these sequences are tissue-specific and show age-related decrease in the binding activity. Nonspecific competitor and heterologous DNA probes failed to compete out the complexes showing that the interaction is specific to the repeat sequences. These proteins may have a role in the expression of the gene during aging.

Multiple muscle-specific regulatory elements are associated with a DNase I hypersensitive site of the cardiac beta-myosin heavy-chain gene.

Using nuclei isolated from neonatal cardiomyocytes, we have mapped the DNase I hypersensitive sites (DHSs) residing within the 5'-upstream regions of the hamster cardiac myosin heavy-chain (MyHC) gene. Two cardiac-specific DHSs within the 5 kb upstream region of the cardiac MyHC gene were identified. One of the DHSs was mapped to the -2.3 kb (beta-2.3 kb) region and the other to the proximal promoter region. We further localized the beta-2.3 kb site to a range of 250 bp. Multiple, conserved, muscle regulatory motifs were found within the beta-2.3 kb site, consisting of three E-boxes, one AP-2 site, one CArG motif, one CT/ACCC box and one myocyte-specific enhancer factor-2 site. This cluster of regulatory elements is strikingly similar to a cluster found in the enhancer of the mouse muscle creatine kinase gene (-1256 to -1050). The specific interaction of the motifs within the beta-2.3 kb site and the cardiac nuclear proteins was demonstrated using gel mobility-shift assays and footprinting analysis. In addition, transfection analysis revealed a significant increase in chloramphenicol acetyltransferase activity when the beta-2.3 kb site was linked to a heterologous promoter. These results suggest that previously undefined regulatory elements of the beta-MyHC gene may be associated with the beta-2.3 kb site.

Increased glycogen accumulation in transgenic mice overexpressing glycogen synthase in skeletal muscle.

To investigate the role of glycogen synthase in controlling glycogen accumulation, we generated three lines of transgenic mice in which the enzyme was overexpressed in skeletal muscle by using promoter-enhancer elements derived from the mouse muscle creatine kinase gene. In all three lines, expression was highest in muscles composed primarily of fast-twitch fibers, such as the gastrocnemius and anterior tibialis. In these muscles, glycogen synthase activity was increased by as much as 10-fold, with concomitant increases (up to 5-fold) in the glycogen content. The uridine diphosphoglucose concentrations were markedly decreased, consistent with the increase in glycogen synthase activity. Levels of glycogen phosphorylase in these muscles increased (up to 3-fold), whereas the amount of the insulin-sensitive glucose transporter 4 either remained unchanged or decreased. The observation that increasing glycogen synthase enhances glycogen accumulation supports the conclusion that the activation of glycogen synthase, as well as glucose transport, contributes to the accumulation of glycogen in response to insulin in skeletal muscle.

Analysis of muscle creatine kinase gene regulatory elements in skeletal and cardiac muscles of transgenic mice.

Regulatory regions of the mouse muscle creatine kinase (MCK) gene, previously discovered by analysis in cultured muscle cells, were analyzed in transgenic mice. The 206-bp MCK enhancer at nt-1256 was required for high-level expression of MCK-chloramphenicol acetyltransferase fusion genes in skeletal and cardiac muscle; however, unlike its behavior in cell culture, inclusion of the 1-kb region of DNA between the enhancer and the basal promoter produced a 100-fold increase in skeletal muscle activity. Analysis of enhancer control elements also indicated major differences between their properties in transgenic muscles and in cultured muscle cells. Transgenes in which the enhancer right E box or CArG element were mutated exhibited expression levels that were indistinguishable from the wild-type transgene. Mutation of three conserved E boxes in the MCK 1,256-bp 5' region also had no effect on transgene expression in thigh skeletal muscle expression. All these mutations significantly reduced activity in cultured skeletal myocytes. However, the enhancer AT-rich element at nt - 1195 was critical for expression in transgenic skeletal muscle. Mutation of this site reduced skeletal muscle expression to the same level as transgenes lacking the 206-bp enhancer, although mutation of the AT-rich site did not affect cardiac muscle expression. These results demonstrate clear differences between the activity of MCK regulatory regions in cultured muscles cells and in whole adult transgenic muscle. This suggests that there are alternative mechanism of regulating the MCK gene in skeletal and cardiac muscle under different physiological states.

M-creatine kinase gene expression in mechanically overloaded skeletal muscle of transgenic mice.

The molecular pathways and regulatory molecules that underlie changes in gene transcription during mechanical overload of skeletal muscle remain obscure. To better understand this process, we have examined mouse muscle creatine kinase (MCK) gene expression in mechanically overloaded plantaris (OP) muscle of transgenic and nontransgenic mice. Northern blot analysis revealed that endogenous MCK-specific mRNA transcripts were decreased 150% in the OP muscles after 6 wk. To identify the MCK gene regions involved in the response to mechanical overload, three different mouse MCKCAT transgenes were studied by measuring chloramphenicol acetyltransferase (CAT assays) activity in OP and sham-operated (control plantaris) muscles. Mouse lines carrying (+enh206)117MCKCAT and -1256MCKCAT transgenes exhibited 30 and 40% lower CAT levels, whereas two mouse lines carrying -3300MCKCAT transgenes exhibited average decreases of 430%. Nearly identical results, including measurements of exogenous CAT mRNA, were obtained 2 days postoverload. Six weeks or 2 days of mechanical overload led to an average decrease in MM-CK isoprotein of 140%. These data provide evidence that mechanical overload induces changes in MCK gene expression that appear to be regulated by at least two portions of the MCK gene: the 206 base pair 5' enhancer and the -3,300 to -1,257 region.

Rabbit muscle creatine kinase: genomic cloning, sequencing, and analysis of upstream sequences important for expression in myocytes

Muscle creatine kinase (MCK) is a major enzyme of cellular energy metabolism that is expressed upon differentiation of myoblasts into myotubes. Previously we cloned and sequenced the entire rabbit enzyme cDNA which was used as a probe in these studies to obtain a genomic clone from a rabbit library. The transcription start site was identified by primer extension analysis and over 800 bp of 5' flanking DNA was sequenced. Comparison of this sequence with the published sequences from the upstream regions of the mouse MCK gene and the human MCK gene showed two conserved regions and a large intervening block of non-conserved sequence. The conserved regions are separated by about 800 bp in the mouse and by about 400 bp in the human, but are much closer (200 bp) in the rabbit. The upstream conserved region of the mouse gene encompasses a region possessing the properties of an enhancer and containing two MyoD binding sites; the downstream element is adjacent to the start of transcription. A set of of overlapping deletions of the 5' upstream DNA was fused to the CAT gene and transfected into mouse C2 myocytes, chick primary myocytes, and chick primary liver cells. Constructs which contained both conserved 5' regions were strongly expressed in C2 and chick myocytes, but were not expressed (above background) in primary liver cells. Surprisingly, while the upstream enhancer element was required for strong expression in C2 myocytes, it was less important for expression in chick myocytes. This suggests that there are important muscle-specific transcriptional signals in the proximal promoter region of mammalian MCK genes.

In vivo footprinting of a muscle specific enhancer by ligation mediated PCR.

In vivo protein-DNA interactions at the developmentally regulated enhancer of the mouse muscle creatine kinase (MCK) gene were examined by a newly developed polymerase chain reaction (PCR) footprinting procedure. This ligation mediated, single-sided PCR technique permits the exponential amplification of an entire sequence ladder. Several footprints were detected in terminally differentiated muscle cells where the MCK gene is actively transcribed. None were observed in myogenic cells prior to differentiation or in nonmuscle cells. Two footprints appear to correspond to sites that can bind the myogenic regulator MyoD1 in vitro, whereas two others represent muscle specific use of apparently general factors. Because MyoD1 is synthesized by undifferentiated myoblasts, these data imply that additional regulatory mechanisms must restrict the interaction between this protein and its target site prior to differentiation.

MyoD is a sequence-specific DNA binding protein requiring a region of myc homology to bind to the muscle creatine kinase enhancer

MyoD is a skeletal muscle-specific protein that is able to induce myogenesis in a wide variety of cell types. In this report, we show that MyoD is a DNA binding protein capable of specific interaction with two regions of the mouse muscle creatine kinase gene upstream enhancer, both of which are required for full muscle-specific enhancer activity. MyoD shares antigenicity and DNA binding specificity with MEF1, a myocyte-specific DNA binding factor. The contiguous basic and myc homology regions of MyoD that are necessary and sufficient for specific DNA interaction are the same regions of the protein required to convert 10 T1 2 fibroblasts into muscle. These findings suggest that the biological activity of MyoD is mediated via its capacity for specific DNA interaction.

Muscle Creatine Kinase Sequence Elements Regulating Skeletal and Cardiac Muscle Expression in Transgenic Mice

Muscle creatine kinase (MCK) is expressed at high levels only in skeletal and cardiac muscle tissues. Previous in vitro transfection studies of skeletal muscle myoblasts and fibroblasts had identified two MCK enhancer elements and one proximal promoter element, each of which exhibited expression only in differentiated skeletal muscle. In this study, we have identified several regions of the mouse MCK gene that are responsible for tissue-specific expression in transgenic mice. A fusion gene containing 3,300 nucleotides of MCK 5' sequence exhibited chloramphenicol acetyltransferase activity levels that were more than 10(4)-fold higher in skeletal muscle than in other, nonmuscle tissues such as kidney, liver, and spleen. Expression in cardiac muscle was also greater than in these nonmuscle tissues by 2 to 3 orders of magnitude. Progressive 5' deletions from nucleotide -3300 resulted in reduced expression of the transgene, and one of these resulted in a preferential decrease in expression in cardiac tissue relative to that in skeletal muscle. Of the two enhancer sequences analyzed, only one directed high-level expression in both skeletal and cardiac muscle. The other enhancer activated expression only in skeletal muscle. These data reveal a complex set of cis-acting sequences that have differential effects on MCK expression in skeletal and cardiac muscle.

Muscle creatine kinase sequence elements regulating skeletal and cardiac muscle expression in transgenic mice.

Muscle creatine kinase (MCK) is expressed at high levels only in skeletal and cardiac muscle tissues. Previous in vitro transfection studies of skeletal muscle myoblasts and fibroblasts had identified two MCK enhancer elements and one proximal promoter element, each of which exhibited expression only in differentiated skeletal muscle. In this study, we have identified several regions of the mouse MCK gene that are responsible for tissue-specific expression in transgenic mice. A fusion gene containing 3,300 nucleotides of MCK 5' sequence exhibited chloramphenicol acetyltransferase activity levels that were more than 10(4)-fold higher in skeletal muscle than in other, nonmuscle tissues such as kidney, liver, and spleen. Expression in cardiac muscle was also greater than in these nonmuscle tissues by 2 to 3 orders of magnitude. Progressive 5' deletions from nucleotide -3300 resulted in reduced expression of the transgene, and one of these resulted in a preferential decrease in expression in cardiac tissue relative to that in skeletal muscle. Of the two enhancer sequences analyzed, only one directed high-level expression in both skeletal and cardiac muscle. The other enhancer activated expression only in skeletal muscle. These data reveal a complex set of cis-acting sequences that have differential effects on MCK expression in skeletal and cardiac muscle.

Identification of a myocyte nuclear factor that binds to the muscle-specific enhancer of the mouse muscle creatine kinase gene.

The muscle creatine kinase (MCK) gene is transcriptionally induced when skeletal muscle myoblasts differentiate into myocytes. The gene contains two muscle-specific enhancer elements, one located 1,100 nucleotides (nt)5' of the transcriptional start site and one located in the first intron. We have used gel mobility shift assays to characterize the trans-acting factors that interact with a region of the MCK gene containing the 5' enhancer. MM14 and C2C12 myocyte nuclear extracts contain a sequence-specific DNA-binding factor which recognizes a site within a 110-nt fragment of the MCK enhancer region shown to be sufficient for enhancer function. Preparative mobility shift gels were combined with DNase I footprinting to determine the site of binding within the 110-nt fragment. Site-directed mutagenesis within the footprinted region produced a 110-nt fragment which did not bind the myocyte factor in vitro. The mutant fragment had about 25-fold-less activity as a transcriptional enhancer in myocytes than did the wild-type fragment. Complementary oligomers containing 21 base pairs spanning the region protected from DNase degradation were also specifically bound by MM14 and C2C12 myocyte nuclear factors. The oligomer-binding activity was not found in nuclear extracts from the corresponding myoblasts, in nuclear extracts from a variety of nonmuscle cell types (including differentiation-defective MM14-DD1 cells and 10T1/2 mesodermal stem cells), or in cytoplasmic extracts. Both the 5' and intron 1 enhancer-containing fragments competed for factors that bind the oligomer probe, while total mouse genomic DNA and several DNA fragments containing viral and cellular enhancers did not. Interestingly, a 5' MCK proximal promoter fragment that also contains muscle-specific positive regulatory elements did not compete for factor binding to the oligomer. We have designated the factor which interacts with the two MCK enhancers myocyte-specific enhancer-binding nuclear factor 1 (MEF 1). A consensus for binding sites in muscle-specific regulatory regions is proposed.

Identification of a myocyte nuclear factor that binds to the muscle-specific enhancer of the mouse muscle creatine kinase gene.

The muscle creatine kinase (MCK) gene is transcriptionally induced when skeletal muscle myoblasts differentiate into myocytes. The gene contains two muscle-specific enhancer elements, one located 1,100 nucleotides (nt)5' of the transcriptional start site and one located in the first intron. We have used gel mobility shift assays to characterize the trans-acting factors that interact with a region of the MCK gene containing the 5' enhancer. MM14 and C2C12 myocyte nuclear extracts contain a sequence-specific DNA-binding factor which recognizes a site within a 110-nt fragment of the MCK enhancer region shown to be sufficient for enhancer function. Preparative mobility shift gels were combined with DNase I footprinting to determine the site of binding within the 110-nt fragment. Site-directed mutagenesis within the footprinted region produced a 110-nt fragment which did not bind the myocyte factor in vitro. The mutant fragment had about 25-fold-less activity as a transcriptional enhancer in myocytes than did the wild-type fragment. Complementary oligomers containing 21 base pairs spanning the region protected from DNase degradation were also specifically bound by MM14 and C2C12 myocyte nuclear factors. The oligomer-binding activity was not found in nuclear extracts from the corresponding myoblasts, in nuclear extracts from a variety of nonmuscle cell types (including differentiation-defective MM14-DD1 cells and 10T1/2 mesodermal stem cells), or in cytoplasmic extracts. Both the 5' and intron 1 enhancer-containing fragments competed for factors that bind the oligomer probe, while total mouse genomic DNA and several DNA fragments containing viral and cellular enhancers did not. Interestingly, a 5' MCK proximal promoter fragment that also contains muscle-specific positive regulatory elements did not compete for factor binding to the oligomer. We have designated the factor which interacts with the two MCK enhancers myocyte-specific enhancer-binding nuclear factor 1 (MEF 1). A consensus for binding sites in muscle-specific regulatory regions is proposed.

The muscle creatine kinase gene is regulated by multiple upstream elements, including a muscle-specific enhancer.

Muscle creatine kinase (MCK) is induced to high levels during skeletal muscle differentiation. We have examined the upstream regulatory elements of the mouse MCK gene which specify its activation during myogenesis in culture. Fusion genes containing up to 3,300 nucleotides (nt) of MCK 5' flanking DNA in various positions and orientations relative to the bacterial chloramphenicol acetyltransferase (CAT) structural gene were transfected into cultured cells. Transient expression of CAT was compared between proliferating and differentiated MM14 mouse myoblasts and with nonmyogenic mouse L cells. The major effector of high-level expression was found to have the properties of a transcriptional enhancer. This element, located between 1,050 and 1,256 nt upstream of the transcription start site, was also found to have a major influence on the tissue and differentiation specificity of MCK expression; it activated either the MCK promoter or heterologous promoters only in differentiated muscle cells. Comparisons of viral and cellular enhancer sequences with the MCK enhancer revealed some similarities to essential regions of the simian virus 40 enhancer as well as to a region of the immunoglobulin heavy-chain enhancer, which has been implicated in tissue-specific protein binding. Even in the absence of the enhancer, low-level expression from a 776-nt MCK promoter retained differentiation specificity. In addition to positive regulatory elements, our data provide some evidence for negative regulatory elements with activity in myoblasts. These may contribute to the cell type and differentiation specificity of MCK expression.

The muscle creatine kinase gene is regulated by multiple upstream elements, including a muscle-specific enhancer.

Muscle creatine kinase (MCK) is induced to high levels during skeletal muscle differentiation. We have examined the upstream regulatory elements of the mouse MCK gene which specify its activation during myogenesis in culture. Fusion genes containing up to 3,300 nucleotides (nt) of MCK 5' flanking DNA in various positions and orientations relative to the bacterial chloramphenicol acetyltransferase (CAT) structural gene were transfected into cultured cells. Transient expression of CAT was compared between proliferating and differentiated MM14 mouse myoblasts and with nonmyogenic mouse L cells. The major effector of high-level expression was found to have the properties of a transcriptional enhancer. This element, located between 1,050 and 1,256 nt upstream of the transcription start site, was also found to have a major influence on the tissue and differentiation specificity of MCK expression; it activated either the MCK promoter or heterologous promoters only in differentiated muscle cells. Comparisons of viral and cellular enhancer sequences with the MCK enhancer revealed some similarities to essential regions of the simian virus 40 enhancer as well as to a region of the immunoglobulin heavy-chain enhancer, which has been implicated in tissue-specific protein binding. Even in the absence of the enhancer, low-level expression from a 776-nt MCK promoter retained differentiation specificity. In addition to positive regulatory elements, our data provide some evidence for negative regulatory elements with activity in myoblasts. These may contribute to the cell type and differentiation specificity of MCK expression.