Thyroid hormone inhibits slow skeletal TnI expression in cardiac TnI-null myocardial cells

A cardiac troponin I (cTnI) gene knockout mouse model has been created and the phenotype of the cTnI null mice is an acute heart failure resulting from the deficiency of TnI and a diastolic dysfunction. Two isoforms of TnI (the fetal form ssTnI and the adult form cTnI) are mainly expressed in the heart under a developmentally regulated program. In our previous studies, we demonstrated that thyroid hormone could alter the time course of ssTnI gene expression in the heart. In the present study, we have successfully cultured neonatal cardiac myocytes from wild type and cTnI null mouse hearts. The ssTnI gene expression pattern has been investigated in these cells. By using Western blotting assays, a TnI isoform switching has been observed in the wild type cardiac myocytes. The pattern of TnI isoform switching is very similar to that of in vivo study we reported previously. In cTnI null cardiac myocytes cultured from day 1 to day 7, there is a continuous decline in ssTnI concentration in the cells. The time course of ssTnI decline in cTnI null cells is similar to that of wild type cardiac myocytes, suggesting that there is no significant compensation of ssTnI gene expression for the absence of the cTnI. This observation is different from what we found previously at a whole heart level. In addition, when thyroid hormone T3 (20 ng/ml) is added to cultured cTnI null cardiac myocytes, the decline of ssTnI concentration occurs earlier. This is inconsistent with our observations from previous in vivo studies. The data demonstrate that thyroid hormone can alter the time course of ssTnI gene expression in cultured cardiac myocytes and TnI gene regulation is also controlled by some unknown programmed events inside of cardiac myocytes.     

A pH-sensitive interaction of troponin I with troponin C coupled with strongly binding cross-bridges in cardiac myofilament activation

Slow skeletal muscle troponin I (ssTnI) expressed predominantly in perinatal heart confers a marked resistance to acidic pH on Ca(2+) regulation of cardiac muscle contraction. To explore the molecular mechanism underlying this phenomenon, we investigated the roles of TnI isoforms (ssTnI and cardiac TnI (cTnI)) in the thin filament activation by strongly binding cross-bridges, by exchanging troponin subunits in cardiac permeabilized muscle fibers. Fetal cardiac muscle showed a marked resistance to acidic pH in activation of the thin filament by strongly binding cross-bridges compared to adult muscle. Exchanging ssTnI into adult fibers altered the pH sensitivity from adult to fetal type, indicating that ssTnI also confers a marked resistance to acidic pH on the cross-bridge-induced thin filament activation. However, the adult fibers containing ssTnI or cTnI but lacking TnC showed no pH sensitivity. These findings provide the first evidence for the coupling between strongly binding cross-bridges and a pH-sensitive interaction of TnI with TnC in cardiac muscle contraction, as a molecular basis of the mechanism conferring the differential pH sensitivity on Ca(2+) regulation.     

Molecular Determinants of Cardiac Myocyte Performance as Conferred by Isoform-Specific TnI Residues

Troponin I (TnI) is the molecular switch of the sarcomere. Cardiac myocytes express two isoforms of TnI during development. The fetal heart expresses the slow skeletal TnI (ssTnI) isoform and shortly after birth ssTnI is completely and irreversibly replaced by the adult cardiac TnI (cTnI) isoform. These two isoforms have important functional differences; broadly, ssTnI is a positive inotrope, especially under acidic/hypoxic conditions, whereas cTnI facilitates faster relaxation performance. Evolutionary directed changes in cTnI sequence suggest cTnI evolved to favor relaxation performance in the mammalian heart. To investigate the mechanism, we focused on several notable TnI isoform and trans-species-specific residues located in TnI’s helix 4 using structure/function and molecular dynamics analyses. Gene transduction of adult cardiac myocytes by cTnIs with specific helix 4 ssTnI substitutions, Q157R/A164H/E166V/H173N (QAEH), and A164H/H173N (AH), were investigated. cTnI QAEH is similar in these four residues to ssTnI and nonmammalian chordate cTnIs, whereas cTnI AH is similar to fish cTnI in these four residues. In comparison to mammalian cTnI, cTnI QAEH and cTnI AH showed increased contractility and slowed relaxation, which functionally mimicked ssTnI expressing myocytes. cTnI QAEH molecular dynamics simulations demonstrated altered intermolecular interactions between TnI helix 4 and cTnC helix A, specifically revealing a new, to our knowledge, electrostatic interaction between R171of cTnI and E15 of cTnC, which structurally phenocopied the ssTnI conformation. Free energy perturbation calculation of cTnC Ca²⁺ binding for these conformations showed relative increased calcium binding for cTnI QAEH compared to cTnI. Taken together, to our knowledge, these new findings provide evidence that the evolutionary-directed coordinated acquisition of residues Q157, A164, E166, H173 facilitate enhanced relaxation performance in mammalian adult cardiac myocytes.     

Molecular Determinants of Cardiac Myocyte Performance as Conferred by Isoform-Specific TnI Residues

Troponin I (TnI) is the molecular switch of the sarcomere. Cardiac myocytes express two isoforms of TnI during development. The fetal heart expresses the slow skeletal TnI (ssTnI) isoform and shortly after birth ssTnI is completely and irreversibly replaced by the adult cardiac TnI (cTnI) isoform. These two isoforms have important functional differences; broadly, ssTnI is a positive inotrope, especially under acidic/hypoxic conditions, whereas cTnI facilitates faster relaxation performance. Evolutionary directed changes in cTnI sequence suggest cTnI evolved to favor relaxation performance in the mammalian heart. To investigate the mechanism, we focused on several notable TnI isoform and trans-species-specific residues located in TnI’s helix 4 using structure/function and molecular dynamics analyses. Gene transduction of adult cardiac myocytes by cTnIs with specific helix 4 ssTnI substitutions, Q157R/A164H/E166V/H173N (QAEH), and A164H/H173N (AH), were investigated. cTnI QAEH is similar in these four residues to ssTnI and nonmammalian chordate cTnIs, whereas cTnI AH is similar to fish cTnI in these four residues. In comparison to mammalian cTnI, cTnI QAEH and cTnI AH showed increased contractility and slowed relaxation, which functionally mimicked ssTnI expressing myocytes. cTnI QAEH molecular dynamics simulations demonstrated altered intermolecular interactions between TnI helix 4 and cTnC helix A, specifically revealing a new, to our knowledge, electrostatic interaction between R171of cTnI and E15 of cTnC, which structurally phenocopied the ssTnI conformation. Free energy perturbation calculation of cTnC Ca²⁺ binding for these conformations showed relative increased calcium binding for cTnI QAEH compared to cTnI. Taken together, to our knowledge, these new findings provide evidence that the evolutionary-directed coordinated acquisition of residues Q157, A164, E166, H173 facilitate enhanced relaxation performance in mammalian adult cardiac myocytes.     

Cardiac troponin T isoforms affect the Ca(2+) sensitivity of force development in the presence of slow skeletal troponin I: insights into the role of troponin T isoforms in the fetal heart

In this study we investigated the physiological role of the cardiac troponin T (cTnT) isoforms in the presence of human slow skeletal troponin I (ssTnI). ssTnI is the main troponin I isoform in the fetal human heart. In reconstituted fibers containing the cTnT isoforms in the presence of ssTnI, cTnT1-containing fibers showed increased Ca(2+) sensitivity of force development compared with cTnT3- and cTnT4-containing fibers. The maximal force in reconstituted skinned fibers was significantly greater for the cTnT1 (predominant fetal cTnT isoform) when compared with cTnT3 (adult TnT isoform) in the presence of ssTnI. Troponin (Tn) complexes containing ssTnI and reconstituted with cTnT isoforms all yielded different maximal actomyosin ATPase activities. Tn complexes containing cTnT1 and cTnT4 (both fetal isoforms) had a reduced ability to inhibit actomyosin ATPase activity when compared with cTnT3 (adult isoform) in the presence of ssTnI. The rate at which Ca(2+) was released from site II of cTnC in the cTnI.cTnC complex (122/s) was 12.5-fold faster than for the ssTnI.cTnC complex (9.8/s). Addition of cTnT3 to the cTnI.cTnC complex resulted in a 3.6-fold decrease in the Ca(2+) dissociation rate from site II of cTnC. Addition of cTnT3 to the ssTnI.cTnC complex resulted in a 1.9-fold increase in the Ca(2+) dissociation rate from site II of cTnC. The rate at which Ca(2+) dissociated from site II of cTnC in Tn complexes also depended on the cTnT isoform present. However, the TnI isoforms had greater effects on the Ca(2+) dissociation rate of site II than the cTnT isoforms. These results suggest that the different N-terminal TnT isoforms would produce distinct functional properties in the presence of ssTnI when compared with cTnI and that each isoform would have a specific physiological role in cardiac muscle.     

A comparative study of the interactions of synthetic peptides of the skeletal and cardiac troponin I inhibitory region with skeletal and cardiac troponin C

The cardiac and skeletal TnI inhibitory regions have identical sequences except at position 110 which contains Pro in the skeletal sequence and Thr in the cardiac sequence. The effect of the synthetic TnI inhibitory peptides [skeletal TnI peptide (104-115), cardiac TnI peptide (137-148), and a single Gly-substituted analogue at position 110] on the secondary structure of skeletal and cardiac TnC was investigated. The biphasic increases in ellipticity and tyrosine fluorescence were analyzed to determine the Ca2+ binding constants for the high- and low-affinity Ca2+ binding sites of TnC. Importantly, the skeletal and cardiac TnI peptides altered Ca2+ binding at the low-affinity sites of TnC, but the magnitude and direction of the pCa shifts depended on whether the peptides were bound to skeletal or cardiac TnC. For example, binding of skeletal TnI peptide to skeletal TnC (monitored by CD) caused a pCa shift of +0.30 unit such that a lower Ca2+ concentration was required to fill sites I and II, while binding of this peptide to cardiac TnC caused a pCa shift of -0.35 unit such that a higher Ca2+ concentration was required to fill site II. This is the first report of the alteration at the low-affinity regulatory sites (located in the N-terminal domain) by the skeletal TnI inhibitory peptide, even though the primary peptide binding site is located in the C-terminal domain of TnC, a finding which strongly indicates that there is communication between the two halves of the TnC molecule.(ABSTRACT TRUNCATED AT 250 WORDS)     

Transcriptional regulation of the gene for prothoracicotropic hormone in the silkworm, <Emphasis Type="Italic">Bombyx mori</Emphasis>

Prothoracicotropic hormone (PTTH) is one of key players in regulation of insect growth, molting, metamorphosis, diapause, and is expressed specifically in the two pairs of lateral PTTH-producing neurosecretory cells in the brain. Analysis of cis-regulatory elements of the PTTH promoter might elucidate the regulatory mechanism controlling PTTH expression. In this study, the PTTH gene promoter of Bombyx mori (Bom-PTTH) was cloned and sequenced. The cis-regulatory elements in Bom-PTTH gene promoter were predicted using Matinspector software, including myocyte-specific enhancer factor 2, pre-B-cell leukemia homeobox 1, TATA box, etc. Transient transfection assays using a series of fragments linked to the luciferase reporter gene indicated that the fragment spanning −110 to +33 bp of the Bom-PTTH promoter showed high ability to support reporter gene expression, but the region of +34 to +192 bp and −512 to −111 bp repressed the promoter activity in the BmN and Bm5 cell lines. Electrophoretic mobility shift assays demonstrated that the nuclear protein could specifically bind to the region spanning −124 to −6 bp of the Bom-PTTH promoter. Furthermore, we observed that the nuclear protein could specifically bind to the −59 to −30 bp region of the Bom-PTTH promoter. A classical TATA box, TATATAA, localized at positions −47 to −41 bp, which is a potential site for interaction with TATA box binding protein (TBP). Mutation of this TATA box resulted in no distinct binding band. Taken together, TATA box was involved in regulation of PTTH gene expression in B. mori.     

The −14010*C variant associated with lactase persistence is located between an Oct-1 and HNF1α binding site and increases lactase promoter activity

In most people worldwide intestinal lactase expression declines in childhood. In many others, particularly in Europeans, lactase expression persists into adult life. The lactase persistence phenotype is in Europe associated with the −13910*T single nucleotide variant located 13,910 bp upstream the lactase gene in an enhancer region that affects lactase promoter activity. This variant falls in an Oct-1 binding site and shows greater Oct-1 binding than the ancestral variant and increases enhancer activity. Several other variants have been identified very close to the −13910 position, which are associated with lactase persistence in the Middle East and Africa. One of them, the −14010*C, is associated with lactase persistence in Africa. Here we show by deletion analysis that the −14010 position is located in a 144 bp region that reduces the enhancer activity. In transfections the −14010*C allele shows a stronger enhancer effect than the ancestral −14010*G allele. Binding sites for Oct-1 and HNF1α surrounding the −14010 position were identified by gel shift assays, which indicated that −14010*C has greater binding affinity to Oct-1 than −14010*G.     

Characterization of troponin T dilated cardiomyopathy mutations in the fetal troponin isoform

The major goal of this study was to elucidate how troponin T (TnT) dilated cardiomyopathy (DCM) mutations in fetal TnT and fetal troponin affect the functional properties of the fetal heart that lead to infantile cardiomyopathy. The DCM mutations R141W and DeltaK210 were created in the TnT1 isoform, the primary isoform of cardiac TnT in the embryonic heart. In addition to a different TnT isoform, a different troponin I (TnI) isoform, slow skeletal TnI (ssTnI), is the dominant isoform in the embryonic heart. In skinned fiber studies, TnT1-wild-type (WT)-treated fibers reconstituted with cardiac TnI.troponin C (TnC) or ssTnI.TnC significantly increased Ca(2+) sensitivity of force development when compared with TnT3-WT-treated fibers at both pH 7.0 and pH 6.5. Porcine cardiac fibers treated with TnT1 that contained the DCM mutations (R141W and DeltaK210), when reconstituted with either cardiac TnI.TnC or ssTnI.TnC, significantly decreased Ca(2+) sensitivity of force development compared with TnT1-WT at both pH values. The R141W mutation, which showed no significant change in the Ca(2+) sensitivity of force development in the TnT3 isoform, caused a significant decrease in the TnT1 isoform. The DeltaK210 mutation caused a greater decrease in Ca(2+) sensitivity and maximal isometric force development compared with the R141W mutation in both the fetal and adult TnT isoforms. When complexed with cardiac TnI.TnC or ssTnI.TnC, both TnT1 DCM mutations strongly decreased maximal actomyosin ATPase activity as compared with TnT1-WT. Our results suggest that a decrease in maximal actomyosin ATPase activity in conjunction with decreased Ca(2+) sensitivity of force development may cause a severe DCM phenotype in infants with the mutations.     

Role of the structural domain of troponin C in muscle regulation: NMR studies of Ca2+ binding and subsequent interactions with regions 1-40 and 96-115 of troponin I

The interaction between the calcium binding and inhibitory components of troponin is central to the regulation of muscle contraction. In this work, two-dimensional heteronuclear single-quantum coherence nuclear magnetic resonance (2D-?1H,15N?-HSQC NMR) spectroscopy was used to determine the stoichiometry, affinity, and mechanisms for binding of Ca2+ and two synthetic TnI peptides [TnI1-40 (or Rp40) and TnI96-115] to the isolated C-domain of skeletal troponin C (CTnC). The Ca2+ titration revealed that 2 equiv of Ca2+ binds to sites III and IV of CTnC with strong positive cooperativity and high affinity [dissociation constant (KD) 相似文献   

A 1H NMR study of a ternary peptide complex that mimics the interaction between troponin C and troponin I.

The troponin I peptide N alpha-acetyl TnI (104-115) amide (TnIp) represents the minimum sequence necessary for inhibition of actomyosin ATPase activity of skeletal muscle (Talbot, J.A. & Hodges, R.S. 1981, J. Biol. Chem. 256, 2798-3802; Van Eyk, J.E. & Hodges, R.S., 1988, J. Biol. Chem. 263, 1726-1732; Van Eyk, J.E., Kay, C.M., & Hodges, R.S., 1991, Biochemistry 30, 9974-9981). In this study, we have used 1H NMR spectroscopy to compare the binding of this inhibitory TnI peptide to a synthetic peptide heterodimer representing site III and site IV of the C-terminal domain of troponin C (TnC) and to calcium-saturated skeletal TnC. The residues whose 1H NMR chemical shifts are perturbed upon TnIp binding are the same in both the site III/site IV heterodimer and TnC. These residues include F102, I104, F112, I113, I121, I149, D150, F151, and F154, which are all found in the C-terminal domain hydrophobic pocket and antiparallel beta-sheet region of the synthetic site III/site IV heterodimer and of TnC. Further, the affinity of TnIp binding to the heterodimer (Kd = 192 +/- 37 microM) was found to be similar to TnIp binding to TnC (48 +/- 18 microM [Campbell, A.P., Cachia, P.J., & Sykes, B.D., 1991, Biochem. Cell Biol. 69, 674-681]). The results indicate that binding of the inhibitory region of TnI is primarily to the C-terminal domain of TnC. The results also indicate how well the synthetic peptide heterodimer mimics the C-terminal domain of TnC in structure and functional interactions.     

A novel nuclear factor, SREB, binds to a cis-acting element, SRE, required for inducible expression of the Aspergillus oryzae Taka-amylase A gene in A. nidulans

The Taka-amylase A gene (taaG2) of Aspergillus oryzae is inducibly expressed in A. nidulans upon exposure to inducing carbon sources, such as starch and maltose. In order to identify nuclear factor(s) possibly involved in the induction of the taaG2 gene, gel mobility shift assays and DNase I footprinting analyses were carried out, and revealed a novel nuclear factor in A. nidulans extracts, which specifically bound to two sites in the taaG2 promoter region, −204 to −189 and −182 to −168, which share the common sequence GGAAATT. The nuclear factor was detected in nuclei from both induced and uninduced mycelia. Mutational analysis within and around the binding sequences demonstrated that only the upstream binding sequence, designated SRE (starch responsive element), was required for the inducible expression of the taaG2 gene, and thus we designated the nuclear factor SREB (SRE binding factor). The downstream binding site contained an inverted SRE (ISRE) and played no role in the induction of taaG2 expression. SREB was shown by gel retardation assays to have higher affinity for SRE than for ISRE. Received: 26 January 1999 / Accepted: 10 November 1999