Identification of cis-acting regulatory elements in the promoter region of the rat brain creatine kinase gene

Creatine kinase in ischemic and inflammatory disorders

The creatine/phosphocreatine pathway plays a conserved and central role in energy metabolism. Compartmentalization of specific creatine kinase enzymes permits buffering of local high energy phosphates in a thermodynamically favorable manner, enabling both rapid energy storage and energy transfer within the cell. Augmentation of this metabolic pathway by nutritional creatine supplementation has been shown to elicit beneficial effects in a number of diverse pathologies, particularly those that incur tissue ischemia, hypoxia or oxidative stress. In these settings, creatine and phosphocreatine prevent depletion of intracellular ATP and internal acidification, enhance post-ischemic recovery of protein synthesis and promote free radical scavenging and stabilization of cellular membranes. The creatine kinase energy system is itself further regulated by hypoxic signaling, highlighting the existence of endogenous mechanisms in mammals that can enhance creatine metabolism during oxygen deprivation to promote tissue resolution and homeostasis. Here, we review recent insights into the creatine kinase pathway, and provide rationale for dietary creatine supplementation in human ischemic and inflammatory pathologies.

Towards resolving the transcription factor network controlling myelin gene expression

In the central nervous system (CNS), myelin is produced from spirally-wrapped oligodendrocyte plasma membrane and, as exemplified by the debilitating effects of inherited or acquired myelin abnormalities in diseases such as multiple sclerosis, it plays a critical role in nervous system function. Myelin sheath production coincides with rapid up-regulation of numerous genes. The complexity of their subsequent expression patterns, along with recently recognized heterogeneity within the oligodendrocyte lineage, suggest that the regulatory networks controlling such genes drive multiple context-specific transcriptional programs. Conferring this nuanced level of control likely involves a large repertoire of interacting transcription factors (TFs). Here, we combined novel strategies of computational sequence analyses with in vivo functional analysis to establish a TF network model of coordinate myelin-associated gene transcription. Notably, the network model captures regulatory DNA elements and TFs known to regulate oligodendrocyte myelin gene transcription and/or oligodendrocyte development, thereby validating our approach. Further, it links to numerous TFs with previously unsuspected roles in CNS myelination and suggests collaborative relationships amongst both known and novel TFs, thus providing deeper insight into the myelin gene transcriptional network.

Expression of creatine kinase isoenzyme genes during postnatal development of rat brain cerebellum: evidence for transcriptional regulation

Transcription and accumulation of brain-type creatine kinase (CKB) mRNA and its protein was examined during postnatal development of rat brain cerebellum, the brain region containing highest CKB mRNA in the adult. CKB protein was extremely low at day 1, increased about 10-fold until week 4 and remained constant until week 10. This time course was paralleled by cerebellar CKB mRNA, which was also extremely low at day 1 and increased 5-fold during the first 3 weeks and then remained constant. High levels of CKB protein were also detected in cultured primary cerebellar granular neurons. Nuclear run-on assays directly showed that CKB mRNA accumulation during postnatal cerebellar development was due to increased transcription. When compared with cerebrum and whole brain, cerebellar CKB mRNA accumulation during postnatal development was temporally delayed. Analysis of myocyte enhancer factor (MEF)-2 and Sp1, factors known to initiate or sustain CKB transcription in tissues other than brain, revealed that MEF-2 in cerebellum was low at week 1 but increased 3.5-fold by week 7, while Sp1 remained unchanged. The increase in CKB protein during cerebellar postnatal development was coincident with that of the ubiquitous mitochondrial CK protein and mRNA, indicating that a functional phosphocreatine energy shuttle probably exists for efficient ATP regeneration in the cerebellum. This should be beneficial for the many energy-demanding requirements during cerebellar development, as indicated by the observed temporal co-expression of CKB with myelin basic protein, which is involved in axon myelination by oligodendrocytes.

MEF2 proteins, including MEF2A, are expressed in both muscle and non-muscle cells

The MEF2 proteins are involved in regulation of many muscle specific genes. Although MEF2 RNAs encoding the MEF2A and MEF2D isoforms are ubiquitously expressed, the presence of MEF2 proteins in non-muscle cell types has been controversial. Here we use a well-characterised antibody in conjunction with DNA binding studies to provide evidence that members of the MEF2 family are widely expressed in the nuclei of cultured cells and are competent to bind DNA. The data show that non-muscle MEF2 complexes contain MEF2A, and that another MEF2 protein, probably MEF2D, is also present. These results suggest that MEF2 proteins fulfil functions in addition to muscle-specific gene expression.

Mouse p53 represses the rat brain creatine kinase gene but activates the rat muscle creatine kinase gene

The creatine kinases (CK) regenerate ATP for cellular reactions with a high energy expenditure. While muscle CK (CKM) is expressed almost exclusively in adult skeletal and cardiac muscle, brain CK (CKB) expression is more widespread and is highest in brain glial cells. CKB expression is also high in human lung tumor cells, many of which contain mutations in p53 alleles. We have recently detected high levels of CKB mRNA in HeLa cells and, in this study, have tested whether this may be due to the extremely low amounts of p53 protein present in HeLa cells. Transient transfection experiments showed that wild-type mouse p53 severely repressed the rat CKB promoter in HeLa but not CV-1 monkey kidney cells, suggesting that, in HeLa but not CV-1 cells, p53 either associates with a required corepressor or undergoes a posttranslational modification necessary for CKB repression. Conversely, mouse wild-type p53 strongly activated the rat CKM promoter in CV-1 cells but not in HeLa cells, suggesting that, in CV-1 cells, p53 may associate with a required coactivator or is modified in a manner necessary for CKM activation. The DNA sequences required for p53-mediated modulations were found to be within bp -195 to +5 of the CKB promoter and within bp -168 to -97 of the CKM promoter. Moreover, a 112-bp fragment from the proximal rat CKM promoter (bp -168 to -57), which contained five degenerate p53-binding elements, was capable of conferring p53-mediated activation on a heterologous promoter in CV-1 cells. Also, this novel p53 sequence, when situated in the native 168-bp rat CKM promoter, conferred p53-mediated activation equal to or greater than that of the originally characterized far-upstream (bp -3160) mouse CKM p53 element. Therefore, CKB and CKM may be among the few cellular genes which could be targets of p53 in vivo. In addition, we analyzed a series of missense mutants with alterations in conserved region II of p53. Mutations affected p53 transrepression and transactivation activities differently, indicating that these activities in p53 are separable. The ability of p53 mutants to transactivate correlated well with their ability to inhibit transformation of rat embryonic fibroblasts by adenovirus E1a and activated Ras.

Mouse p53 represses the rat brain creatine kinase gene but activates the rat muscle creatine kinase gene

The creatine kinases (CK) regenerate ATP for cellular reactions with a high energy expenditure. While muscle CK (CKM) is expressed almost exclusively in adult skeletal and cardiac muscle, brain CK (CKB) expression is more widespread and is highest in brain glial cells. CKB expression is also high in human lung tumor cells, many of which contain mutations in p53 alleles. We have recently detected high levels of CKB mRNA in HeLa cells and, in this study, have tested whether this may be due to the extremely low amounts of p53 protein present in HeLa cells. Transient transfection experiments showed that wild-type mouse p53 severely repressed the rat CKB promoter in HeLa but not CV-1 monkey kidney cells, suggesting that, in HeLa but not CV-1 cells, p53 either associates with a required corepressor or undergoes a posttranslational modification necessary for CKB repression. Conversely, mouse wild-type p53 strongly activated the rat CKM promoter in CV-1 cells but not in HeLa cells, suggesting that, in CV-1 cells, p53 may associate with a required coactivator or is modified in a manner necessary for CKM activation. The DNA sequences required for p53-mediated modulations were found to be within bp -195 to +5 of the CKB promoter and within bp -168 to -97 of the CKM promoter. Moreover, a 112-bp fragment from the proximal rat CKM promoter (bp -168 to -57), which contained five degenerate p53-binding elements, was capable of conferring p53-mediated activation on a heterologous promoter in CV-1 cells. Also, this novel p53 sequence, when situated in the native 168-bp rat CKM promoter, conferred p53-mediated activation equal to or greater than that of the originally characterized far-upstream (bp -3160) mouse CKM p53 element. Therefore, CKB and CKM may be among the few cellular genes which could be targets of p53 in vivo. In addition, we analyzed a series of missense mutants with alterations in conserved region II of p53. Mutations affected p53 transrepression and transactivation activities differently, indicating that these activities in p53 are separable. The ability of p53 mutants to transactivate correlated well with their ability to inhibit transformation of rat embryonic fibroblasts by adenovirus E1a and activated Ras.

A novel, cell-type-specific mechanism for estrogen receptor-mediated gene activation in the absence of an estrogen-responsive element

The estrogen receptor (ER) typically activates gene transcription by binding to estrogen-responsive elements (EREs). The brain creatine kinase (BCK) promoter is responsive to estrogen but contains no ERE-related sequence. To investigate the mechanism of estrogen induction, we have introduced the estrogen receptor into HeLa cells and primary rat cardiomyocytes and fibroblasts along with 195 bp of BCK promoter linked to a chloramphenicol acetyltransferase (CAT) reporter gene. A 10-fold stimulation of CAT activity was observed in the presence of beta-estradiol in both HeLa and rat primary fibroblasts, but no induction was observed in primary rat cardiomyocytes. In contrast, a control vitellogenin gene construct which contains a typical ERE was induced in an ER-dependent manner in all cell types studied. Estrogen induction in HeLa was not sensitive to cycloheximide and was blocked by the ER antagonists tamoxifen and ICI 164,384. Analysis of 5' deletion and linker-scanning mutations indicates sequences between bp -45 and -75 including a TA-rich sequence and a CCAAT sequence to be crucial for stimulation of the BCK promoter by the ER. BCK estrogen induction is dependent on the DNA-binding domain and transactivation domain TAF2 of the ER. However, direct DNA binding is probably not required. Taken together, these results suggest a novel mechanism for ER-mediated gene activation. This mechanism is consensus ERE independent and cell type specific and requires interactions between the ER and molecules capable of interacting with the BCK promoter TA-rich region.

A novel, cell-type-specific mechanism for estrogen receptor-mediated gene activation in the absence of an estrogen-responsive element

The estrogen receptor (ER) typically activates gene transcription by binding to estrogen-responsive elements (EREs). The brain creatine kinase (BCK) promoter is responsive to estrogen but contains no ERE-related sequence. To investigate the mechanism of estrogen induction, we have introduced the estrogen receptor into HeLa cells and primary rat cardiomyocytes and fibroblasts along with 195 bp of BCK promoter linked to a chloramphenicol acetyltransferase (CAT) reporter gene. A 10-fold stimulation of CAT activity was observed in the presence of beta-estradiol in both HeLa and rat primary fibroblasts, but no induction was observed in primary rat cardiomyocytes. In contrast, a control vitellogenin gene construct which contains a typical ERE was induced in an ER-dependent manner in all cell types studied. Estrogen induction in HeLa was not sensitive to cycloheximide and was blocked by the ER antagonists tamoxifen and ICI 164,384. Analysis of 5' deletion and linker-scanning mutations indicates sequences between bp -45 and -75 including a TA-rich sequence and a CCAAT sequence to be crucial for stimulation of the BCK promoter by the ER. BCK estrogen induction is dependent on the DNA-binding domain and transactivation domain TAF2 of the ER. However, direct DNA binding is probably not required. Taken together, these results suggest a novel mechanism for ER-mediated gene activation. This mechanism is consensus ERE independent and cell type specific and requires interactions between the ER and molecules capable of interacting with the BCK promoter TA-rich region.

Human cytomegalovirus US3 and UL36-38 immediate-early proteins regulate gene expression

We have established the ability of the human cytomegalovirus (HCMV) UL36-38 and US3 immediate-early (IE) gene products to alter gene expression in human cells by using transient transfection assays. The cellular heat shock protein 70 (hsp70) promoter was transactivated following cotransfection with the HCMV IE regions in nonpermissive HeLa cells by UL36-38, US3, or IE1 and in permissive human diploid fibroblasts (HFF) by IE1 or IE2. Moreover, hsp70 expression was synergistically increased in HeLa cells cotransfected with US3 and UL36, with US3 and UL37, or with US3 and UL37x1. The synergistic transactivation of hsp70 expression by US3 and UL36-38 was not observed in HFF cells. Synergy was also not observed in HeLa cells between US3 and UL38, an early gene product encoded by the UL36-38 IE locus. Synergistic transactivation of hsp70 expression in HeLa cells required the syntheses of UL36-38 and US3 IE proteins, since nonsense mutants were not functional. hsp70 expression increased with increasing amounts of transfected US3 and UL37 DNA and occurred at the level of stable hsp70-promoted RNA. In contrast to the broad hsp70 response, promoters from the HCMV UL112 early gene and another cellular gene, brain creatine kinase, both responded strongly only to singly transfected IE2 in HeLa cells. Nevertheless, IE2 transactivation of the UL112 promoter was further stimulated by cotransfection of IE1 or of UL36-38 in both HeLa and HFF cells. Thus, different patterns of promoter transactivation and interactions between HCMV IE gene products in transactivation were found in HFF cells and in HeLa cells. These results establish the ability of the HCMV US3 and UL36-38 proteins to alter cellular and viral gene expression and are consistent with involvement of cellular transcription factors in HCMV IE regulation of gene expression.