Beta-catenin-histone deacetylase interactions regulate the transition of LEF1 from a transcriptional repressor to an activator.

Recent evidence suggests that certain LEF/TCF family members act as repressors in the absence of Wnt signaling. We show here that repression by LEF1 requires histone deacetylase (HDAC) activity. Further, LEF1 associates in vivo with HDAC1, and transcription of a model LEF1-dependent target gene is modulated by the ratio of HDAC1 to beta-catenin, implying that repression by LEF1 is mediated by promoter-targeted HDAC. Consistent with this hypothesis, under repression conditions the promoter region of a LEF1 target gene is hypoacetylated. By contrast, when the reporter is activated, its promoter becomes hyperacetylated. Coexpression of beta-catenin with LEF1 and HDAC1 results in the formation of a beta-catenin/HDAC1 complex. Surprisingly, the enzymatic activity of HDAC1 associated with beta-catenin is attenuated. Together, these findings imply that activation of LEF1-dependent genes by beta-catenin involves a two-step mechanism. First, HDAC1 is dissociated from LEF1 and its enzymatic activity is attenuated. This first step yields a promoter that is inactive but poised for activation. Second, once HDAC1-dependent repression has been overridden, beta-catenin binds LEF1 and the beta-catenin-LEF1 complex is competent to activate the expression of downstream target genes.

Inhibition of Tcf3 binding by I-mfa domain proteins.

We have determined that I-mfa, an inhibitor of several basic helix-loop-helix (bHLH) proteins, and XIC, a Xenopus ortholog of human I-mf domain-containing protein that shares a highly conserved cysteine-rich C-terminal domain with I-mfa, inhibit the activity and DNA binding of the HMG box transcription factor XTcf3. Ectopic expression of I-mfa or XIC in early Xenopus embryos inhibited dorsal axis specification, the expression of the Tcf3/beta-catenin-regulated genes siamois and Xnr3, and the ability of beta-catenin to activate reporter constructs driven by Lef/Tcf binding sites. I-mfa domain proteins can regulate both the Wnt signaling pathway and a subset of bHLH proteins, possibly coordinating the activities of these two critical developmental pathways.

Inhibition of unloaded shortening velocity in permeabilized muscle fibres by caged ATP compounds.

The effects of both the P3-1-(2-nitrophenyl)ethyl ester of adenosine 5'-triphosphate (NPE-caged ATP) and its separate diastereoisomers, and the P3-3',5'-dimethoxybenzoin ester of ATP (DMB-caged ATP) were studied on the unloaded shortening velocity of glycerinated rabbit psoas muscle fibres. The unloaded shortening velocities of the active fibres were measured as a function of ATP concentration (0.1-5 mM) using the 'slack-test' with and without 2 mM caged ATP. Shortening velocity followed a Michaelis-Menten relationship with ATP concentration, the Km for ATP being 170 microM. The caged ATP compounds inhibited shortening velocity, in a manner consistent with competitive inhibition, with a Ki of 1-2 mM. The R- and S-diastereoisomers of NPE-caged ATP showed the same degree of competitive inhibition of the shortening velocity, as did DMB-caged ATP. These observations suggest that caged ATP compounds bind to the ATPase site of the actomyosin where they compete with the substrate, Mg2+ ATP.

Elastic distortion of myosin heads and repriming of the working stroke in muscle.

Muscle contraction is driven by a cyclical interaction between the globular head domain of myosin and the actin filaments. We used quick stretches of 5 nm per half sarcomere to synchronize the movements of myosin heads in active single muscle fibres. The intensity of the 14.5 nm X-ray reflection decreased during the stretch, showing that the instantaneous elasticity of muscle involves distortion of myosin heads. Head movement continued at about 1,500 s-1 after the stretch, accompanied by partial force recovery. This indicates a reversal of the force-generating 'working stroke' in the myosin heads that is smaller and faster than assumed previously. By 50 ms after the stretch, myosin heads have regained both their original conformation and the ability to execute a normal working stroke. This 'repriming' process is slower than that following shortening but much faster than the ATP turnover rate per myosin head.

Kinetics of relaxation from rigor of permeabilized fast-twitch skeletal fibers from the rabbit using a novel caged ATP and apyrase.

The complex time course of tension decay was investigated in fast-twitch permeabilized rabbit muscle fibers when they were relaxed from the rigor state using photochemical generation of ATP. A novel caged ATP compound, the P3-3',5'-dimethoxybenzoin ester of ATP (DMB-caged ATP), as well as the P3-1-(2-nitrophenyl)ethyl ester of ATP (NPE-caged ATP), have been used. DMB-caged ATP photolyzes at least three orders of magnitude more rapidly than NPE-caged ATP. The role of ADP on relaxation kinetics from rigor was examined by using apyrase to remove ADP from the rigor muscle solutions. The presence of Pi-sensitive states was investigated from the effect of Pi on relaxation. Rigor tension was varied enabling the influence of tension on the relaxation to be examined. The time course of relaxation was faster with DMB-caged ATP compared with NPE-caged ATP for concentrations of ATP released by photolysis greater than 0.7 mM. Most of the complexity in the relaxation tension records was caused by ADP. In the absence of ADP, tension decayed monotonically after photochemical release of ATP in a process whose rate was unaffected by Pi. In the presence of ADP, relaxation was more complex and tension passed through a maximum. A model invoking cooperative interactions involving ADP-containing myosin heads provides a reasonable description of the data.

Changes in the x-ray diffraction pattern from single, intact muscle fibers produced by rapid shortening and stretch.

Changes in the x-ray diffraction patterns produced by 100-microseconds-length steps imposed during tetanic stimulation were recorded from single intact fibers of frog tibialis anterior muscle. For shortening steps, a staircase length change was applied, with a 20-ms interval between steps. For stretches, each 20-ms cycle started with a stretch, followed after 4 ms by shortening to the original length. Each shortening step in the staircase and each stretch in the stretch/shortening protocol produced a response similar to that of a single step from the isometric steady state. The intensity of the 14.5-nm x-ray reflection arising from the axial repeat of the myosin heads along their filaments decreased after both shortening and stretch; this decrease was not accompanied by broadening along or across the meridian. The relationship between the intensity after the length step and step amplitude was approximately linear for both stretches and shortening steps, extrapolating to zero intensity for 11-nm stretches and 13-nm shortening steps, but there was no significant intensity change for the first approximately 2 nm of shortening. These results are broadly consistent with conventional models of muscle contraction in which myosin heads move through about 10 nm during the working stroke in the shortening direction, but an additional distortion of the myosin heads may be produced by a stretch.

Characterization of the regulatory regions in the human desmoglein genes encoding the pemphigus foliaceous and pemphigus vulgaris antigens.

The adhesive proteins in the desmosome type of cell junction consist of two members of the cadherin superfamily, the desmogleins and desmocollins. Both desmogleins and desmocollins occur as at least three different isoforms with various patterns of expression. The molecular mechanisms controlling the differential expression of the desmosomal cadherin isoforms are not yet known. We have begun an investigation of desmoglein gene expression by cloning and analysing the promoters of the human genes coding for the type 1 and type 3 desmogleins (DSG1 and DSG3). The type 1 isoform is restricted to the suprabasal layers of the epidermis and is the autoantigen in the autoimmune blistering skin disease pemphigus foliaceous. The type 3 desmoglein isoform is also expressed in the epidermis, but in lower layers than the type 1 isoform, and is the autoantigen in pemphigus vulgaris. Phage lambda genomic clones were obtained containing 4.2 kb upstream of the translation start site of DSG1 and 517 bp upstream of the DSG3 start site. Sequencing of 660 bp upstream of DSG1 and 517 bp upstream of DSG3 revealed that there was no obvious TATA box, but a possible CAAT box was present at -238 in DSG1 and at -193 in DSG3 relative to the translation start site. Primer extension analysis and RNase protection experiments revealed four putative transcription initiation sites for DSG1 at positions -163, -151, -148 and -141, and seven closely linked sites for DSG3, the longest being at -140 relative to the translation start site. The sequences at these possible sites at -166 to -159 in DSG1 (TTCAGTCC) and at -124 to -117 in DSG3 (CTTAGACT) have some similarity to the initiator sequence (CTCANTCT) described for a TATA-less promoter often from -3 to +5, and the true transcription initiator site might therefore be the A residue in these sequences. There were two regions of similarity between the DSG1 and DSG3 promoters just upstream of the transcription initiation sites, of 20 and 13 bp, separated by 41 bp in DSG1 and 36 bp in DSG3. The significance of these regions of similarity remains to be elucidated, but the results suggest that they represent a point at which these two desmoglein genes are co-ordinately regulated. Analysis of the upstream sequences revealed GC-rich regions and consensus binding sites for transcription factors including AP-1 and AP-2. Exon boundaries were conserved compared with the classical cadherin E-cadherin, but the equivalent of the second cadherin intron was lacking. A 4.2 kb region of the human DSG1 promoter sequence was linked to the lacZ gene reporter gene in such a way that there was only one translation start site, and this construct was used to generate transgenic mice. We present the first transgenic analysis of a promoter region taken from a desmosomal cadherin gene. Our results suggest that the 4.2 kb upstream region of DSG1 does not contain all the regulatory elements necessary for correct expression of this gene but might have elements that regulate activity during hair growth.