Specific heterodimerization plays a crucial role in the regulation of the biology of the cell. For example, the specific heterodimerization between the b-HLH-LZ transcription factors c-Myc and Max is a prerequisite for c-Myc transcriptional activity that leads to cell growth, proliferation and tumorigenesis. On the other hand, the Mad proteins can compete with c-Myc for Max. The Mad/Max heterodimer antagonizes the effect of the c-Myc/Max heterodimer. In this contribution, we have focused on the specific heterodimerization between the b-HLH-LZ domains of c-Myc and Max using CD and NMR. While the c-Myc and Max b-HLH-LZ domains are found to preferentially form a heterodimer; we demonstrate for the first time that a significant population of the Max homodimeric b-HLH-LZ can also form and hence interferes significantly with the specific heterodimerization. This indicates that the Max/Max homodimer can also interfere with c-Myc/Max functions, therefore adding to the complexity of the regulation of transcription by the Myc/Max/Mad network. The demonstration of the existence of the homodimeric population was made possible by the application of numerical routines that enable the simulation of composite spectroscopic signal (e.g. CD) as a function of temperature and total concentration of proteins. From a systems biology perspective, our routines may be of general interest as they offer the opportunity to treat many competing equilibriums in order to predict the probability of existence of protein complexes.
Matriptase is a member of the novel family of type II transmembrane serine proteases. It was recently shown that a rare genetic disorder, autosomal recessive ichthyosis with hypotrichosis, is caused by a mutation in the coding region of matriptase. However, the biochemical and functional consequences of the G827R mutation in the catalytic domain of the enzyme have not been reported. Here we expressed the G827R-matriptase mutant in bacterial cells and found that it did not undergo autocatalytic cleavage from its zymogen to its active form as did the wild-type matriptase. Enzymatic activity measurements showed that the G827R mutant was catalytically inactive. When expressed in HEK293 cells, G827R-matriptase remained inactive but was shed as a soluble form, suggesting that another protease cleaved the full-length mature form of matriptase. Molecular modeling based on the crystal structure of matriptase showed that replacing Gly 827 by Arg blocks access to the binding/catalytic cleft of the enzyme thereby preventing autocatalysis of the zymogen form. Our study, thus, provides direct evidence that the G827R mutation in patients with autosomal recessive ichthyosis with hypotrichosis leads to the expression of an inactive protease.Type II transmembrane serine proteases (TTSPs) 2 belong to a novel family of proteolytic enzymes anchored to cell membranes with extracellular catalytic domains (1, 2). There are currently upwards of 20 known members of this family that are involved in the maintenance of normal homeostasis but that cause disease when deregulated or mutated (1). TTSPs are mosaic proteins containing multiple domains involved in cellular targeting, protein-protein interactions, and enzymatic catalysis. Like many other proteolytic enzymes, they undergo posttranslational processing events to generate active proteases from inactive zymogens.The most studied TTSP at both the physiological and biochemical levels is matriptase (3). Although matriptase deficient-mice develop to term, they die within 48 h due to the lack of epidermal barrier function and thymic homeostasis (4). Matriptase expressed in keratinocytes is a key regulator of epidermal differentiation, which is an essential component of the pro-fillagrin processing pathway (5). Fillagrin is an important protein that is involved in epidermal barrier function (6) and late stratum corneum differentiation (7). It has also been suggested that matriptase is a proteolytic activator of prostasin (8), a serine protease that is crucial for epidermal permeability and postnatal survival (9), and that it may play important roles in tumor cell metastasis and invasiveness (10 -15). Indeed, matriptase causes malignant transformations when orthotopically overexpressed in the skin of mice, suggesting a causal role in human carcinogenesis (15). Moreover, it is overexpressed in many cancer tissues, including primary breast carcinomas, ovarian tumors of epithelial origin, and colon tumors (10), and has potential as a prognostic marker in ovarian cancer (16).Matriptase has a compl...
The b-HLH-LZ family of transcription factors contains numerous proteins including the Myc and Mad families of proteins. Max heterodimerizes with other members to bind the E-Box DNA sequence in target gene promoters. Max is the only protein in this network that recognizes and binds E-Box DNA sequences as a homodimer in vitro and represses transcription of Myc target genes in vivo. Key information such as the structure of p21 Max, the complete gene product, and its KD in the absence of DNA are still unknown. Here, we report the characterization of the secondary and quaternary structures, the dimerization and DNA binding of p21 Max and a thermodynamically stable mutant. The helical content of p21 Max indicates that its N-terminal and C-terminal regions are unstructured in the absence of DNA. NMR experiments further support the location of folded and unfolded domains. We also show that p21 Max has an apparent KD (37 degrees C) of 7 x 10(-6), a value 10-100 times smaller than the b-HLH-LZ itself. We demonstrate that electrostatic repulsions are responsible for the higher KD of the b-HLH-LZ. Finally, we show that a p21 Max double mutant forms a very stable dimer with a KD (37 degrees C) of 3 x 10(-10) and that the protein/DNA complex depicts a higher temperature of denaturation than p21 Max/DNA complex. Our results indicate that Max could homodimerize, bind DNA, and repress transcription in vivo and that its mutant could be more efficient at repressing the expression of c-Myc target genes.
Myc and Max belong to the b-HLH-LZ family of transcription factors. Heterodimerization between Myc and Max or homodimerization of Max allows these proteins to bind their cognate DNA sequence known as the E-box (CACGTG). Recent evidence has suggested that the c-Myc/Max heterodimeric b-HLH-LZ could interact to form a head-to-tail dimer of dimers and induce complex topologies such as loops in promoters containing more than one E-box sequence. In an attempt to shed light on this hypothesis, the interaction between the heterodimeric b-HLH-LZ of c-Myc/Max and a fragment of the hTERT promoter containing two E-box sequences was studied by atomic force microscopy. Specific binding events were observed at both E-box sites with equal probabilities. In accordance with previous results obtained by EMSA, we observed that the specific binding of the c-Myc/Max b-HLH-LZ bends the promoter. However no looping could be observed in a wide range of concentration encompassing the Ka (association constant) of the putative tetramer and the Ka for the specific binding of the heterodimer. In contrast, experiments performed with a mandatory c-Myc/Max b-HLH-LZ tetramer incubated with the hTERT promoter fragment allowed for the visualization of loops and cross-linked DNA strands originating from specific binding. Altogether, our results indicate that the c-Myc/Max b-HLH-LZ dimer binds specifically and equally to both E-box sites of the hTERT promoter and induces a significant bending of the promoter and that the suggested oligomerization of the c-Myc/Max heterodimeric b-HLH-LZ, if existing, is most likely too weak to induce the formation of a loop in a promoter.
c-Myc must heterodimerize with Max to accomplish its functions as a transcription factor. This specific heterodimerization occurs through the b-HLH-LZ (basic region, helix 1-loop-helix 2-leucine zipper) domains. In fact, many studies have shown that the c-Myc b-HLH-LZ (c-Myc'SH) preferentially forms a heterodimer with the Max b-HLH-LZ (Max'SH). The primary mechanism underlying the specific heterodimerization lies on the destabilization of both homodimers and the formation of a more stable heterodimer. In this regard, it has been widely reported that c-Myc'SH has low solubility and homodimerizes poorly and that repulsions within the LZ domain account for the homodimer instability. Here, we show that replacing one residue in the basic region and one residue in Helix 1 (H(1)) of c-Myc'SH with corresponding residues conserved in b-HLH proteins confers to c-Myc'SH a higher propensity to form a stable homodimer in solution. In stark contrast to the wild-type protein, this double mutant (L362R, R367L) of the c-Myc b-HLH-LZ (c-Myc'RL) shows limited heterodimerization with Max'SH in vitro. In addition, c-Myc'RL forms highly stable and soluble complexes with canonical as well as non-canonical E-box probes. Altogether, our results demonstrate for the first time that structural determinants driving the specific heterodimerization of c-Myc and Max are embedded in the basic region and H(1) of c-Myc and that these can be exploited to engineer a novel homodimeric c-Myc b-HLH-LZ with the ability of binding the E-box sequence autonomously and with high affinity.
Mad1 is a member of the Mad family. This family is part of the larger Myc/Max/Mad b-HLH-LZ eukaryotic transcription-factor network. Mad1 forms a specific heterodimer with Max and acts as a transcriptional repressor when bound to an E-box sequence (CACGTG) found in the promoter of c-Myc target genes. Mad1 cannot form a complex with DNA by itself under physiological conditions. A global model for the molecular recognition has emerged in which the Mad1 b-HLH-LZ homodimer is destabilized and the Mad/Max b-HLH-LZ heterodimer is favored. The detailed structural determinants responsible for the molecular recognition remain largely unknown. In this study, we focus on the elucidation of the structural determinants responsible for the destabilization of the Mad1 b-HLH-LZ homodimer. Conserved acidic residues at the dimerization interface (position a) of the LZ of all Max-interacting proteins have been hypothesized to be involved in the destabilization of the homodimeric states. In Mad1, this position corresponds to residue Asp 112. As reported for the complete gene product of Mad1, we show that wild-type b-HLH-LZ does not homodimerize or bind DNA under physiological conditions. On the other hand, the single mutation of Asp 112 to an Asn enables the b-HLH-LZ to dimerize and bind DNA. Our results suggest that Asp 112 is implicated in the destabilization of Mad1 b-HLH-LZ homodimer. Interestingly, this side chain is observed to form a salt bridge at the interface of the LZ domain in the crystal structure of Mad1/Max heterodimeric b-HLH-LZ bound to DNA [Nair, S. K., and Burley, S. K. (2003) Cell 112, 193-205]. This clearly suggests that Asp 112 plays a crucial role in the molecular recognition between Max and Mad1.
Canavalia ensiformis (jack bean) alpha-urease is a hexameric protein characterized by a complex denaturation mechanism. In previous papers, we have shown that a hydrophobic 8-anilino-1-naphthalenesulfonic acid (ANSA) binding conformer could be populated in a moderate concentration of denaturant. This state was obtained under conditions that had no detectable impact on its tertiary structure, as indicated by fluorescence measurements. In the present study, we further characterized this ANSA-binding state in an attempt to understand urease behavior. Evidence presented here shows that the presence of ANSA was not required for the generation of the conformer and that its affinity for ANSA came from an increase in hydrophobicity leading to aggregation. Circular dichroism investigation of urease revealed that it had periodical secondary structure content similar to Klebsiella aerogenes urease (secondary structures calculated on the basis of crystallographic data). The impact of 0.9 M guanidine hydrochloride (GuHCl) on soluble urease secondary structures was minimal but is compatible with a slight increase in beta-sheet structures. Such modification may indicates that aggregation involves amyloid-like fibril formation. Electron microscopy analysis of urease in the absence of GuHCl revealed the presence of urease hexamers (round shape 13 nm in diameter). These particles disappeared in the presence of moderate denaturant concentration owing to the formation of aggregates and fibril-like structures. The fibrils obtained in 1.5 M GuHCl had an average diameter of 6.5 nm, suggesting that urease hexamers dissociated into smaller oligomeric forms when forming such fibrils.
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