SRY-directed DNA bending and human sex reversal: reassessment of a clinical mutation uncovers a global coupling between the HMG box and its tail.

Sex-reversal mutations in human SRY cluster within its high-mobility group box, a conserved motif of DNA bending. A classical substitution at the crux of this angular domain (M64I) has been reported to impair DNA bending but not DNA binding, implying that sharp bending is required for transcriptional activation and testis determination. Surprisingly, we report that this defect was an inadvertent consequence of protein truncation: in the intact protein, sharp DNA bending is restored by the basic tail of the high-mobility group box. Structural coupling between box and tail is tuned to the native DNA bend angle, damping conformational fluctuations and enabling bidirectional induced fit within the bent complex. M64I-associated sex reversal is instead caused by the impaired function of a flanking non-classical nuclear localization signal (NLS). Similar impairment is caused by M64A, suggesting that mislocalization is due to loss of an M64-specific function and not gain of a non-native I64-specific function. Transcriptional activity, attenuated by mislocalization, is rescued by fusion of a heterologous NLS. In a male embryonic gonadal cell line, M64I and M64A SRY-NLS fusion proteins exhibit native transcriptional activation of Sox9, a key step in testicular differentiation. Our results suggest that male development is robust to subtle alterations in SRY-DNA architecture but depends critically on nuclear localization. The previously unsuspected role of M64 within a non-classical NLS may contribute to its invariance among SOX-related and LEF-1-related transcription factors.

SRY and human sex determination: the basic tail of the HMG box functions as a kinetic clamp to augment DNA bending.

Human testis-determining factor SRY contains a high-mobility-group (HMG) box, an alpha-helical DNA-binding domain that binds within an expanded minor groove to induce DNA bending. This motif is flanked on the C-terminal end by a basic tail, which functions both as a nuclear localization signal and accessory DNA-binding element. Whereas the HMG box is broadly conserved among otherwise unrelated transcription factors, tails differ in sequence and mode of DNA binding. Contrasting examples are provided by SRY and lymphoid enhancer factor 1 (LEF-1): whereas the SRY tail remains in the minor groove distal to the HMG box, the LEF-1 tail binds back across the center of the bent DNA site. The LEF-1 tail relieves electrostatic repulsion that would otherwise be incurred within the compressed major groove to enable sharp DNA bending with high affinity. Here, we demonstrate that the analogous SRY tail functions as a "kinetic clamp" to regulate the lifetime of the bent DNA complex. As in LEF-1, partial truncation of the distal SRY tail reduces specific DNA affinity and DNA bending, but these perturbations are modest: binding is reduced by only 1.8-fold, and bending by only 7-10 degrees . "Tailed" and truncated SRY complexes exhibit similar structures (as probed by NMR) and distributions of long-range conformational substates (as probed by time-resolved fluorescence resonance energy transfer). Surprisingly, however, the SRY tail retards dissociation of the protein-DNA complex by 20-fold. The marked and compensating changes in rates of association and dissociation observed on tail truncation, disproportionate to perturbations in affinity or structure, suggest that this accessory element functions as a kinetic clamp to regulate the lifetime of the SRY-DNA complex. We speculate that the kinetic stability of a bent DNA complex is critical to the assembly and maintenance of a sex-specific transcriptional pre-initiation complex.

Formation and characterization of stable human serum albumin-tris-malonic acid [C60]fullerene complex.

The preparation and characterization of the stable human serum albumin (HSA)-C3 isomer of tris-malonic acid [C60]fullerene complex is reported. Other than the anti-fullerene antibody, a stable protein-fullerene complex with a native protein has never been observed. This study may provide valuable answers to the growing concern regarding the effects of carbonaceous nanomaterials on human health on one hand and, on the other, may lead to the development of novel antioxidant therapeutic agents, radiopharmaceuticals, and components for bioelectronic devices.

Applications of time-resolved resonance energy transfer measurements in studies of the molecular crowding effect.

The native structures of many globular proteins are only weakly stabilized and form in solution ensembles of multiple conformers. The energy differences between the conformers are assumed to be small. This is the case of flexible multidomain proteins where domain motions were observed. High concentrations of inert macrosolute, which create a crowded or confined environment, can cause shifts of the distribution of the conformers of such proteins towards the more compact structures. This effect may also promote compact structures in partially folded proteins. Time-resolved dynamic non-radiative excitation energy transfer (tr-RET) is suitable for detection of either subtle or major changes in distributions of intramolecular distances in protein molecules in solutions. Two experiments were performed which demonstrated the applicability of tr-RET for detection of the effect of macrosolutes on the conformational ensembles of flexible states of protein molecules. The distribution of distances between residues 203 and 169 in the CORE domain of E. coli adenylate kinase (AK) in the denatured state was determined in the presence of high concentrations of dextran 40. A significant shift of the mean of the distribution was observed without reduction of its width. This was interpreted as a shift to compact structure without change of the degree of disorder of the chain. In a second experiment the distribution of the distance between residues 55 and 169 in AK, which spans the cleft between the CORE and the AMPbind domains, was monitored. No clear effect of high concentrations of dextran 40 was found. These experiments show the strength of the application of tr-RET in investigation of changes in the sub-states of flexible conformations of globular protein. Networks of pairs of labeled sites can be prepared and tr-RET experiments can be performed in order to search for the segments of the protein molecules, which respond to the presence of inert macromolecules in their environment.

Sry-directed sex reversal in transgenic mice is robust with respect to enhanced DNA bending: comparison of human and murine HMG boxes.

The testis-determining factor SRY contains an HMG box DNA-bending domain. Human and murine factors (hSRY and mSRY, respectively) exhibit marked sequence divergence and are reported to differ markedly in DNA bending properties. Surprisingly, the combined application of time-resolved fluorescence resonance energy transfer (tr-FRET) and permutation gel electrophoresis demonstrates that the hSRY-DNA complex is more sharply bent than the murine complex and not less bent as previously reported. tr-FRET-based analyses of the distribution of end-to-end distances in the bent DNA-protein complexes further suggest that a broader range of DNA bend angles is populated in the murine ensemble than in the human ensemble. The two domains and their respective DNA complexes nevertheless exhibit similar thermodynamic stabilities. (1)H NMR spectra indicate analogous intercalation of distinct "cantilever" side chains (isoleucine or methionine) with subtle differences in induced DNA structure. Interchange of cantilevers does not affect DNA bending. That transgenic expression of either human or murine Sry in XX mice can confer a male somatic phenotype suggests that SRY-directed transcriptional regulation is robust to enhanced DNA bending and to changes in the precision of DNA bending. We propose that male-specific gene regulation requires DNA bending above a critical threshold set by architectural requirements of enhanceosome assembly.

Formation of the hydrophobic core of ribonuclease A through sequential coordinated conformational transitions.

With steady-state and time-resolved fluorescence energy-transfer measurements, we determined the distributions of intramolecular distances in nine mutants to study the conformations of wild-type ribonuclease A in the reduced state under folding conditions. Although far-UV-CD measurements show no evidence for a secondary-structure transition, temperature- and GdnHCl-induced changes in intramolecular distance distributions in the reduced state revealed evidence for long-range subdomain structures in the denatured protein. These poorly defined structures, reflected here by wide distributions corresponding to a wide range of energies, form during refolding in a complex sequence of multiple subdomain transitions. A more well-defined structure emerges only when this structural framework, which directs the successive steps in the folding process, matures and is reinforced by stronger interactions such as disulfide bonds.