Changes in chromatin folding in solution

The formation of higher order structures by nucleosome oligomers of graded sizes with increasing ionic strength has been studied in solution, by measuring sedimentation coefficients. Nucleosome monomers and dimers show no effect of ionic strength at the concentrations used, while trimers to pentamers show a linear dependence of the logarithm of sedimentation coefficient upon the logarithm of ionic strength between 5 and 25 mm, but no dependence above 25 mm. Between pentamer and hexamer a change occurs and the linear relationship is observed up to ionic strength 125 mm with hexamer and above.The simple power-law dependence of the sedimentation coefficient upon the ionic strength (s ∝ Iⁿ) is observed up to nucleosome 30mers, but by 60mer a jump in the sedimentation coefficient occurs between ionic strengths 45 and 55 mm, with the power-law applying both above and below the jump. Removal of histone H1 and non-histone proteins lowers the overall sedimentation rate and abolishes the jump.Cross-linking large oligomers at ionic strength 65 mm stabilizes the structure in the conformation found above the jump, leading to a simple power-law dependence throughout the range of ionic strength for cross-linked material. Cleavage of the cross-links restores the jump, presumably by allowing the conformational transition that causes it. Large oligomers are indistinguishable in sedimentation behaviour whether extracted from nuclei at low ionic strength or at 65 mm and maintained in the presence of salt.We interpret these results, together with the detailed electron microscopic studies reported by Thoma et al. (1979) under similar salt conditions, as showing the histone H1-dependent formation of superstructures of nucleosomes in solution induced by increasing ionic strength. The unit of higher order structure probably contains five or six nucleosomes, leading to the change in stability with hexamer. Although this size corresponds to the lower limit of size suggested for “superbeads” (Renz et al., 1977), we see no evidence that multiples of six nucleosomes have any special significance as might be predicted if superbeads had any structural importance. Rather, our results are compatible with a continuous pattern of condensation, such as a helix of nucleosomes (see e.g. Finch & Klug, 1976). The jump in sedimentation observed between ionic strengths 45 and 55 mm, together with the effect of cross-linking, suggests the co-operative stabilization of this structure at higher ionic strengths. A plausible hypothesis is that the turns of the solenoid are not tightly bonded in the axial direction below 45 mm, but come apart due to the hydrodynamic shearing forces in the larger particles leading to less compact structures with slower sedimentation rates. Above 55 mm the axial bonding is strong enough to give a stable structure of dimensions compatible with the 30 nm structures observed in the cell nucleus.     

Magnesium-induced linear self-association of the FtsZ bacterial cell division protein monomer. The primary steps for FtsZ assembly

The bacterial cell division protein FtsZ from Escherichia coli has been purified with a new calcium precipitation method. The protein contains one GDP and one Mg(2+) bound, it shows GTPase activity, and requires GTP and Mg(2+) to polymerize into long thin filaments at pH 6.5. FtsZ, with moderate ionic strength and low Mg(2+) concentrations, at pH 7.5, is a compact and globular monomer. Mg(2+) induces FtsZ self-association into oligomers, which has been studied by sedimentation equilibrium over a wide range of Mg(2+) and FtsZ concentrations. The oligomer formation mechanism is best described as an indefinite self-association, with binding of an additional Mg(2+) for each FtsZ monomer added to the growing oligomer, and a slight gradual decrease of the affinity of addition of a protomer with increasing oligomer size. The sedimentation velocity of FtsZ oligomer populations is compatible with a linear single-stranded arrangement of FtsZ monomers and a spacing of 4 nm. It is proposed that these FtsZ oligomers and the polymers formed under assembly conditions share a similar axial interaction between monomers (like in the case of tubulin, the eukaryotic homolog of FtsZ). Similar mechanisms may apply to FtsZ assembly in vivo, but additional factors, such as macromolecular crowding, nucleoid occlusion, or specific interactions with other cellular components active in septation have to be invoked to explain FtsZ assembly into a division ring.     

The action of chymotrypsin on nucleosome cores. Histone products and conformational effects of limited digestion

alpha-Chymotrypsin was used to probe accessible hydrophobic amino acid residues in nucleosome cores. Small amounts of chymotrypsin rapidly and selectively cleaved at leucine 20 of histone H3. Cleavage at this site caused partial unfolding of the nucleosome core at low ionic strengths indicated by a small decrease in sedimentation coefficient and increase in circular dichroism in the 265-285-nm range. Unfolding did not occur at moderate ionic strengths, probably because of more effective electrolyte screening of residual negative charge on the nucleosome core. More extensive treatment with chymotrypsin partially degraded other core histones in nucleosome cores at similar rates. The primary sites of cleavage were assigned to Leu115 of H2a, Val18 or Gln22 of H2b, and Leu10 plus Leu22 of H4. We conclude that these primary sites of chymotrypsin cleavage of the four core histones lie on or near the nucleosome core surface, while the large number of other hydrophobic histone residues located in more central sequences must be inaccessible. Extensive chymotrypsin treatment yielded a set of "limit" products approximately 80-100 residues long that were similar to the limit products of trypsin digestion. Sedimentation coefficients and circular dichroism spectra of nucleosome cores treated to near limits with chymotrypsin or chymotrypsin followed by trypsin were not consistent with significant unfolding of the proteolyzed cores at moderate ionic strength. These results indicate that the amino-terminal 20-30 residues of H2b, H3, and H4 and the amino- and carboxyl-terminal approximately 12 residues of H2a, in toto, interact weakly if at all with DNA of isolated nucleosome cores. These histone termini stabilize less than two turns and perhaps only one turn on each DNA terminus.     

Self-association of the yeast nucleosome assembly protein 1

The self-association properties of the yeast nucleosome assembly protein 1 (yNAP1) have been investigated using biochemical and biophysical methods. Protein cross-linking and calibrated gel filtration chromatography of yNAP1 indicate the protein exists as a complex mixture of species at physiologic ionic strength (75-150 mM). Sedimentation velocity reveals a distribution of species of 4.5-12 Svedbergs (S) over a 50-fold range of concentrations. The solution-state complexity is reduced at higher ionic strength, allowing for examination of the fundamental oligomer. Sedimentation equilibrium of a homogeneous 4.5 S population at 500 mM sodium chloride reveals these species to be yNAP1 dimers. These dimers self-associate to form higher order oligomers at more moderate ionic strength. Titration of guanidine hydrochloride converts the higher order oligomers to the homogeneous 4.5 S dimer and then converts the 4.5 S dimers to 2.5 S monomers. Circular dichroism shows that guanidine-mediated dissociation of higher order oligomers into yNAP1 dimers is accompanied by only slight changes in secondary structure. Dissociation of the dimer requires a nearly complete denaturation event.     

The Changes of “Myosin B” during Storage of Rabbit Muscle

The process of the denaturation of “myosin B” solution was studied by the measurement of ATPase activity, SH groups, sedimentation behaviour and flow birefringence. When “myosin B” solution was stored at lower temperature, lower pH or higher ionic strength, the interaction between myosin A and actin became less strong, and further storage brought about an irreversible dissociation.

The condition for measuring Mg-modified ATPase activity of “myosin B” at low ionic strength was explained in the relation with superprecipitation.     

Early stages of fibrinogen to fibrin conversion studied by static and dynamic light scattering

The early steps of fibrin aggregation induced by low Reptilase concentrations were studied by means of static and dynamic light scattering. In order to obtain information on the size and shape of the first oligomers, the angular dependence of the scattered intensity and the mean Rayleigh line width were measured. Under physiological pH and ionic strength, oligomer formation was detectable immediately after enzymatic activation. Comparison of the calculated data for different models with experimental results shows that the early fibrin polymerization proceeds as an end-to-end aggregation of elongated and possibly flexible molecules approximately 75 nm long.     

A Raman spectroscopic study on the sequence dependent conformations of DNA oligomers

Eighteen kinds of oligodeoxyribonucleic acids have been examined to reveal their structures in aqueous solutions at different ionic strengths by Raman spectroscopy. The structures in solutions were found to be very polymorphic depending on their sequences as well as on the salt concentrations. At a low salt condition a DNA oligomer assumes a unique B form within a B family, for examples Ba, Bh, B', or Bn form. Amongst these DNA oligomers, d(CGCG)2 showed a salt induced Ba-Z transition, while d(GGGGCCCC)2 showed a salt induced Bh-A transition. DNA oligomers with AA/TT sequences were found to prefer B' form even at high salt condition. From comparing the structures of DNA oligomers in solutions with their crystal structures, it is safe to say that the crystal structure of a DNA oligomer is very similar to the structure in the high salt solution.     

Histone H5 promotes the association of condensed chromatin fragments to give pseudo-higher-order structures

We describe two distinct situations in which chicken erythrocyte chromatin fragments associate in solution. The erythrocyte-specific histone H5 is implicated since chromatins that do not contain H5 do not show this behaviour. Well-defined oligomers of between approximately 6 and approximately 18 nucleosomes prepared at low ionic strength condense and associate when the ionic strength is raised to 75 mM, forming pseudo-higher-order structures. The associated forms, probably predominantly dimers, are stabilized by migration of about 10% of the H5, and of the minor lysine-rich histone H1, from the non-associated forms, probably reflecting the preference of H5 for higher-order structures observed previously [Thomas, J. O. and Rees, C. (1983) Eur. J. Biochem. 134, 109-115]. Since the final (H1 + H5) content of the aggregate at 75 mM is never higher than that of the fragment prepared at low ionic strength, migration is probably to a small proportion of sites that have inevitably become vacant due to handling losses at the higher (but not at low) ionic strength. H5 thus maximizes its interactions in the condensed state of chromatin and even maintains the association of two or more fragments without continuity of the DNA. Aggregates of oligomers larger than about 18 nucleosomes may be too long to withstand hydrodynamic shear forces in the absence of such continuity. During nuclease digestion of nuclear chromatin, H5 and, to a lesser extent, H1, are released from the ends of very short fragments and bind to larger oligomers of various sizes leading to heterogeneous aggregates that survive exposure to low ionic strength. These aggregates, in contrast to those described above, have up to 60% more H5 and 20% more H1 than chromatin prepared at low ionic strength. Whether the excess H5 and H1 bind non-specifically or to a second low-affinity binding site on each nucleosome is not known. The associated forms described above (1) are well defined and potentially useful for structural studies, whereas the other aggregates (2) seem less likely to be directly relevant to the native structure of chromatin.     

Involvement of histone H1 in the organization of the nucleosome and of the salt-dependent superstructures of chromatin

We describe the results of a systematic study, using electron microscopy, of the effects of ionic strength on the morphology of chromatin and of H1-depleted chromatin. With increasing ionic strength, chromatin folds up progressively from a filament of nucleosomes at approximately 1 mM monovalent salt through some intermediate higher- order helical structures (Thoma, F., and T. Koller, 1977, Cell 12:101- 107) with a fairly constant pitch but increasing numbers of nucleosomes per turn, until finally at 60 mM (or else in approximately 0.3 mM Mg++) a thick fiber of 250 A diameter is formed, corresponding to a structurally well-organized but not perfectly regular superhelix or solenoid of pitch approximately 110 A as described by Finch and Klug (1976, Proc. Natl. Acad. Sci. U.S.A. 73:1897-1901). The numbers of nucleosomes per turn of the helical structures agree well with those which can be calculated from the light-scattering data of Campbell et al. (1978, Nucleic Acids Res. 5:1571-1580). H1-depleted chromatin also condenses with increasing ionic strength but not so densely as chromatin and not into a definite structure with a well-defined fiber direction. At very low ionic strengths, nucleosomes are present in chromatin but not in H1-depleted chromatin which has the form of an unravelled filament. At somewhat higher ionic strengths (greater than 5 mM triethanolamine chloride), nucleosomes are visible in both types of specimen but the fine details are different. In chromatin containing H1, the DNA enters and leaves the nucleosome on the same side but in chromatin depleted of H1 the entrance and exit points are much more random and more or less on opposite sides of the nucleosome. We conclude that H1 stabilizes the nucleosome and is located in the region of the exit and entry points of the DNA. This result is correlated with biochemical and x-ray crystallographic results on the internal structure of the nucleosome core to give a picture of a nucleosome in which H1 is bound to the unique region on a complete two-turn, 166 base pair particle (Fig. 15). In the formation of higher-order structures, these regions on neighboring nucleosomes come closer together so that an H1 polymer may be formed in the center of the superhelical structures.     

Isolation and characterization of chromatin subfractions from rat liver

Rat-liver chromatin was digested with micrococcal nuclease at low ionic strength in the presence of a low concentration of CaCl2. The nuclease digest was successfully separated into three fractions, P1, P2, and P3, by gel filtration on a column of Sepharose 2B. P1 fraction was shown to be a mixture of long fragments of partially digested chromatin by the sedimentation profile or by electrophoresis of DNA. P2 fraction contained four histones H2A, H2B, H3, and H4 in almost equal amounts, together with nonhistone protein of low molecular weight. The DNA was composed of three or four fragments less than 300 base pairs long. From the Kav value of the P2 fraction, the average size was estimated to be about 240 base pairs. On analytical ultracentrifugation, this fraction exhibited a monophasic boundary and a sedimentation value of 13.7S. P3 fraction contained nonhistone proteins which showed a molecular weight larger than that of H1 histone. The size of DNA was estimated to be less than 50 base pairs from the Kav value. Based on these results, the P2 fraction was concluded to consist of nucleosome monomer enriched in nonhistone proteins. The P3 fraction is presumably the nuclease-sensitive or internucleosome portion, which contains small amounts of nonhistone proteins.     

Salt-dependent interconversion of inner histone oligomers.

The inner histone complex, extracted from chicken erythrocyte chromatin in 2 M NaCL AT pH 7.4, has been characterized by sedimentation equilibrium and sedimentation velocity. High speed sedimentation equilibrium studies indicate that in 2 M NaCl the inner histones are a weakly associating system with contributions from species ranging in molecular weight from dimer to octamer. The appearance of a single boundary (3.8S at 2 M NaCl) in sedimentation velocity studies conducted over a wide range of protein concentrations and ionic conditions indicates that the various histone oligomers present are in rapid equilibrium with one another. At higher salts the equilibrium is shifted to favor higher molecular weight species; in 4 M NaCl essentially all of the histone is octameric at protein concentrations above 0.2 mg/ml. The facile interconversion of histone oligomers suggests that small alterations in histone-histone interactions may be responsible for changes in nucleosome conformations during various biological processes.     

The effects of ionic strength on the self-association of human spectrin.

The self-association of human spectrin has been studied by means of sedimentation equilibrium in the analytical ultracentrifuge at pH 7.5 and over a range of ionic strength from 0.009 to 1.0 M. Increasing ionic strength above 0.1 M reduces the equilibrium constants for all of the measurable steps in the self-association reaction. These results support the concept of charge-charge interactions stabilizing the tetramer and higher oligomers with respect to the heterodimer. In addition, increasing ionic strength brought about a dissociation of the heterodimer to component polypeptide chains. Dissociation to the heterodimers is also enhanced with a decrease in ionic strength below 0.05 M. This low ionic strength-dependent dissociation is consistent with generalised electrostatic repulsion; however, this effect also correlates with some loss of alpha-helical content as revealed by circular dichroism. The secondary, tertiary and quaternary structures may all be partially disrupted by electrostatic free energy at low ionic strength.     

Characterization of the molybdate-stabilized glucocorticoid receptor from rat thymus.

The untransformed glucocorticoid receptor of rat thymus cytosol was characterized in the form of its complex with [1,2,4-3H]triamcinolone acetonide by ion-exchange chromatography and by gel filtration and sucrose-density-gradient ultracentrifugation at different ionic strengths. Molybdate (10 mM) was present throughout all experimental procedures and prevented receptor inactivation and degradation as well as transformation. At low ionic strength the molybdate-stabilized steroid-receptor complex was detected as a single highly asymmetric entity with a Stokes radius of 5.85 nm, a sedimentation coefficient of 9.6 S and an apparent molecular weight of 236 000. This form was converted into a smaller, even more asymmetric, form in increasing proportion as the ionic strength was increased. In the presence of 0.4 M-KCl, the smaller form had a Stokes radius of 4.95 nm, a sedimentation coefficient of 4.6 S and an apparent molecular weight of 95 500. It is concluded that the glucocorticoid-receptor complex exists at low ionic strengths as a homodimer or as a heterodimer in which only one subunit possesses a steroid-binding site, and that the process of dissociation into subunits brought about by increasing the ionic strength is a process distinct from, but possibly preceding, the transformation phenomenon responsible for conferring DNA-binding properties on the complex.     

Studies on the assembly of a spherical plant virus. I. States of aggregation of the isolated protein

The aggregates formed at equilibrium by purified protein from cowpea chlorotic mottle virus have been characterized on the basis of their sedimentation behaviour and appearance in the electron microscope. Between pH 3.5 and 7.5, at ionic strengths greater than 0.2, most of the protein is found in aggregates sedimenting at either 3 S or 50 S. The 50 S aggregate is identified as the reassembled capsid of cowpea ehlorotic mottle virus. Decreasing the ionic strength favours the formation of multi-shelled particles. Below pH 5.5 single- and multishelled particles predominate, while above this pH most of the protein sediments at 3 S.Varying the temperature from 5 °C to 20 °C has little effect on the equilibrium proportions of aggregates although some real differences can be detected. Ionic strength is not as important a variable as pH in determining which protein forms are present (but increasing ionic strength does result in a steady decrease in the proportion of protein in the multi-layer aggregates). The dependence of the equilibrium upon protein concentration shows that capsid formation is a quasi-crystallization: beyond a certain total protein concentration the concentration of 3 S aggregate remains at this “critical” concentration and all further protein goes into 50 S capsid. In addition to shells and variations upon shells, tubes and hexagonal nets of protein subunits have occasionally been seen with the electron microscope.     

Specific histone-histone contacts are ruptured when nucleosomes unfold at low ionic strength.

The ordered unfolding of the nucleosome core within chromatin at low ionic strengths has been studied. The results show that, when nuclei are lysed gently in solutions of very low ionic strength, their constituent nucleosomes rupture at a major H2B-H4 binding site but remain unperturbed at the site of the H2A-H2B interaction. These conclusions are based on data which show that at least four separate but closely spaced H2B-H4 contacts, identifiable by contact-site cross-linking in intact nuclei, are broken when nuclei are suspended in very dilute buffers. Appropriate controls on purified nucleosomes monomers demonstrate that the H2B-H4 contacts being broken are indeed intranucleosomal. Sedimentation of nucleosomes in the ultracentrifuge at various salt concentrations reveals that a significant conformational transition occurs in the range of ionic strength over which the H2B-H4 binding site ruptures.     

Self-association and chaperone activity of Hsp27 are thermally activated

The small heat shock protein 27 (Hsp27) is an oligomeric, molecular chaperone in vitro. This chaperone activity and other physiological roles attributed to Hsp27 have been reported to depend on the state of self-association. In the present work, we have used sedimentation velocity experiments to demonstrate that the self-association of Hsp27 is independent of pH and ionic strength but increases significantly as the temperature is increased from 10 to 40 degrees C. The largest oligomers formed at 10 degrees C are approximately 8-12 mer, whereas at 40 degrees C oligomers as large as 22-30 mer are observed. Similarly, the chaperone activity of Hsp27 as indicated by its ability to inhibit dithiothreitol-induced insulin aggregation also increases with increased temperature, with a particularly sharp increase in activity as temperature is increased from 34 to 43 degrees C. Similar studies of an Hsp27 triple variant that mimics the behavior of the phosphorylated protein establish that this protein has greatly diminished chaperone activity that responds minimally to increased temperature. We conclude that Hsp27 can exploit a large number of oligomerization states and that the range of oligomer size and the magnitude of chaperone activity increase significantly as temperature is increased over the range that is relevant to the physiological heat shock response.