Electric and flow linear dichroism of unfolded and condensed chromatin: a comparative study at low and intermediate ionic strength

Identical samples containing polynucleosomal chains of chicken erythrocyte (CE) and Ehrlich ascites tumour (EA) chromatin were studied under various ionic conditions with regard to electric linear dichroism (ELD) and flow linear dichroism (FLD). Both orientation techniques consistently confirmed that, in the limit of very low ionic strength and in the absence of multivalent cations, the reduced linear dichroism of chromatin is negative in the DNA-base absorption band, as expected for an extended zig-zag polynucleosomal conformation. With increasing electrolyte content, both ELD and FLD decreased drastically in amplitude, but in contrast to the ELD which remains negative in an intermediate range of low ionic strength (0.1-0.5 mM Mg2+) the FLD changes sign and becomes positive. The ELD and FLD amplitudes decrease with higher Mg2+ concentrations and FLD even vanishes in the region of 0.2-0.4 mM; both signals are positive above 0.4-0.5 mM Mg2+. The origin of the dissimilarities between ELD and FLD observations is still not fully understood. Several possibilities are considered: ELD signals are more influenced than FLD by the presence of short chromatin chains, nucleosomes and small pieces of naked DNA, while FLD is more susceptible to the presence of large, easily orientable, scattering aggregates. Different preferred orientation directions of the chromatin fibre with respect to electric and hydrodynamic fields may also be involved. Finally, FLD and ELD probably "see" different features of the chromatin structure.     

Reinterpretation of Linear Dichroism of Chromatin Supports a Perpendicular Linker Orientation in the Folded State

Abstract

We present a reinterpretation of linear dichroism data for the salt induced condensation of chromatin. A conflict between electric and flow linear dichroism data for identical chromatin samples, studied at varying degrees of Mg²⁺ induced folding, can be solved if the orientation in electric fields is mainly determined through the polarization of counter ions along the linker parts, whereas the orientation in flow is governed by the hydrodynamical response of the entire chromatin fiber. The orientation of a chromatin fiber in an electric field would then depend on the linker tilt angle so that at an angle larger than 55° the fiber would tend to orient perpendicular to the applied field. The different orientation distributions obtained with the two methods of alignment may in this way provide extra information about the structure and folding of chromatin.     

Optical Anisotropy of Chromatin. Flow Linear Dichroism and Electric Dichroism Studies

Abstract

The optical anisotropy of chromatin with different length of the linker DNA isolated from a variety of sources (Frend erythroleukemia cells, calf thymus, hen erythrocytes and sea urchin sperm) has been studied in a large range of mono- and bivalent cations concentraitons by the use of flow linear dichroism (LD) and electric dichroism.

We have found that all chromatins studied displayed negative LD values in the range of 0.25 mM EDTA—2 mM NaCl and close positive values in the range of 2–100 mM NaCl. Mg²⁺ cations, in contrast to Na⁺ cations, induce optically isotropic chromatin fibers. All chromatin samples exhibit positive form effect amounting to 5–10% of LD amplitude observed at 260 nm. This form effect is determined by the anisotropic scattering of polarized light by single chromatin fibers.

The conformational transition at 2 mM NaCl leads to the distortion of chromatin filament structure. The reversibility of this distortion depends on the length of the linker DNA—for chromatins with the linker DNA of 10–30 b.p. it is parially reversible, while for preparations with longer linker DNA it is irreversible.

Relatively low electric field does not affect chromatin structure, while higher electric field (more than 7 kV/cm) distorts the structure of chromatin.

Presented resutls explain the contradictory data obtained by electrooptical and hydrooptical methods.     

Comparative Study of the Condensation of Chicken Erythrocyte and Calf Thymus Chromatins by Di- and Multivalent Cations

Abstract

The condensation of chicken erythrocyte (CE) and calf thymus (CT) chromatins upon addition of di- and multivalent cations has been studied using turbidityJulprecipitation and electric dichroism measurements. For all the cations investigated (Mg²⁺, Tb³⁺, Co(NH₃)₆ ³⁺, spermidine Spd²⁺ and spermine Sp⁴⁺) condensation of CE chromatin occurred before the onset of aggregation, while aggregation of CT chromatin started before condensation with all cations except Mg²⁺ and Tb³⁺. Precipitation of CE chromatin required lower di- and multivalent cations concentrations than CT chromatin. The electric dichroism data for both chromatins, at low ionic strength in the absence of di- or multivalent cations, indicated that the nucleoprotein molecules were not totally decondensed but that a “precondensed” state was already present. A positive electric dichroism was observed for the most condensed chromatin fibers, in agreement with the “cross-linker” models. Tb³⁺ led to less compact condensed particles as judged from the electric dichroism observations, but electron microscopy revealed that “30 nm fibers” were formed. Very little aggregation was produced by Tb³⁺. On the contrary, spermine produced very large networks of condensed molecules, but large spheroidal particles were also observed. The condensation of CE chromatin happened without changes of solution conductivity upon cation salt addition, regardless of the condensing cation, indicating a cooperative uptake of the ions during this process.     

Erratum

Abstract

The condensation and the precipitation of rat liver chromatin upon addition of spermine⁴⁺, spermidine³⁺, hexamminecobalt(III)³⁺ and Mg²⁺ cations have been studied using solubility, fluorescence, circular dichroism, melting curves, electric dichroism and spermidine binding measurements, made on both soluble and precipitated complexes. The soluble complexes obtained with tetra- and trivalent cations were depleted from all histones and enriched in other proteins, particularly high mobility group proteins 1 and 2, which brings about an important enhancement of tryptophan fluorescence without modification of its two lifetimes 5.1 and 1.2 ns. In the precipitates the non-histone proteins are eliminated. Under precipitation by Mg²⁺ ions, the distribution of proteins remains practically unchanged. The electric dichroism and the melting curves indicate that the soluble complexes between polyamines and chromatin undergo important condensation and, at high ratios of cation over phosphate, are constituted by heterogeneous assemblies of non-histone proteins and DNA. On the contrary, the insoluble complexes seem to retain the main features of original chromatin. Precipitation by Mg²⁺ ions reveal much less drastic changes than those produced by polyamines. Precipitation by spermidine occurs when one cation is bound per eight nucleotides, which in addition to the histone positive charges brings about a complete neutralization of chromatin phosphates.     

Direct measurement of intracellular free magnesium in frog skeletal muscle using magnesium-selective microelectrodes

Mg²⁺-selective microelectrodes have been used to measure the intracellular free Mg²⁺ concentration in frog skeletal muscle fibers. Glass capillaries with a tip diameter of less than 0.4 μm were backfilled with the Mg²⁺ sensor, ETH 1117. In the absence of interfering ions, they gave Nernstian responses between 1 and 10 mM free Mg²⁺. In the presence of an ionic environment resembling the myoplasm, the microelectrode response was sub Nernstian (18–24 mV) but still useful. The electrodes were calibrated before and after muscle-fiber impalements. In quiescent fibers from sartorius muscle (Rana pipiens), with resting membrane potentials not less than ?82 mV, the intracellular free Mg²⁺ concentration was 3.8±0.41 (S.E.) mM (n=58) at 22°C. No significant change in the intracellular free Mg²⁺ was observed following extensive (approx. 6 h) incubation in Mg²⁺-free media. Increasing the external concentration of magnesium from 4 to 20 mM (approx. 15 min) produced a slow and small enhancement (1.8 mM) of [Mg²⁺]_i, which was fully reverted when the divalent cation was removed from the bathing solution. No change in ionic magnesium resting concentration was observed when the muscle fibers were treated either with caffeine 3 mM or with Na⁺-free solutions. In depolarized muscle fibers (?23±2.7 mV) treated with 100 mM K⁺, the myoplasmic [Mg²⁺] was 3.7±0.45 (S.E.) mM, n=6, immediately after the spontaneous relaxation of the contracture. Similar determinations in muscle fibers during stimulation at low frequency (5 Hz), and after fatigue development, showed no changes in the concentration of free cytosolic Mg²⁺. These results point out that [Mg²⁺]_i is not modified under these three different experimental conditions.     

Ionic requirements of impaled bull spermatozoa driven by external ADP and ATP

The flagellar motion of impaled bull spermatozoa can be maintained by external ADP or ATP. The post-impalement flagellar frequency depends sharply on the external Mg²⁺ concentration. 0.3 mM Mg²⁺ is required for half-optimal activity with ADP, 0.05 mM Mg²⁺ with ATP as external power source. Mn²⁺ can substitute partially for Mg²⁺ as ionic co-factor. Ca²⁺ cannot substitute for Mg²⁺, and at concentrations above 0.5 mM it inhibits motility slightly. Zn²⁺ acts only as inhibitor of post-impalement flagellar activity, reducing it to zero at concentrations above 1 mM.     

The mode of action of divalent cations on the RNase catalyzed hydrolysis of RNA and uridylyl (3'-5') uridine

Pseudo first order rate constants (k′) have been measured for the RNase A catalyzed hydrolysis of uridylyl (3′–5′) uridine at several ionic strengths and compositions. The k′ values are independent of Mg²⁺ concentration between 0 and 10 mM. This shows that for hydrolysis of RNA, in which Mg²⁺ concentration does change k′, the perturbation must be through binding of Mg²⁺ to the substrate RNA rather than to the enzyme RNase.     

Chromatin structure studied by linear dichroism at different salt concentrations

We have studied the linear dichroism (LD) of rat liver chromatin oriented by flow. Soluble chromatin, prepared by brief nuclease digestion, is found to exhibit a positive LD at low ionic strength (1 mM NaCl), with a constant LD/A over the absorption band centered at 260 nm (A, isotropic absorbance). Several previous dichroism studies on soluble chromatin have been performed on sonicated materials and have given negative LD, probably due to the presence of uncoiled DNA. The positive dichroism can be interpreted in terms of a supercoil of DNA in chromatin with a pitch angle larger than 55°, and is, for example, consistent with a model where the cylindrical nucleosome core particles are stacked face to face in the chromatin filament. In contrast to the nuclease-digested chromatin, sonicated chromatin was confirmed to exhibit negative LD. This difference can be attributed to a partial uncoiling of the linker regions between the nucleosomes due to the shearing. The structural transition of chromatin to a compact form can be observed as a reduction of the positive LD of the nuclease-digested chromatin to almost zero in 0.1 M NaCl or in 0.1 mM MgCl₂. This transition is due to a decreased electrostatic repulsion between negative phosphate groups on the DNA chain. In the case of Na⁺, this can be explained as a screening effect due to the bulk concentration of Na⁺. With Mg²⁺ a considerably stronger effect may indicate a more localized binding to the phosphates. At ionic strengths higher than 0.5M NaCl, the dissociation of the histones from DNA leads to uncoiling of chromatin. The change in LD during this process shows that histone H1 contributes only to a small degree to the coiling of the DNA chain, whereas histones H3 and H4 play the major role in the coiling.     

Interactions of nucleic acid double helices induced by electric field pulses

Electric field pulses induce a substantial increase of the light scattering intensity of double-helical DNA. The relative change of light scattering and also the reciprocal relaxation time constants under electric field pulses increase with increasing nucleotide concentration. These observations, together with a large difference between dichroism orientation time constants and light scattering time constants under electric field pulses, demonstrate that the main part of the light scattering effect is due not to field-induced orientation but to interactions between DNA helices. From the concentration dependence of the light scattering time constants we obtain, according to an isodesmic reaction model, association rate constants in the range 3 × 10¹⁰ M^?1 helices s^?1 for DNA with approx. 300 base-pairs. These values are at the limit of a diffusion-controlled DNA association and do not show any dependence upon the field strength. The dissociation rate constants k_d decrease strongly with increasing field strength E and thus demonstrate that the interactions between the helices are induced by the electric field. This conclusion is consistent with independent measurements which do not reveal any DNA association at zero field strength. The observed linear relation between log(k_d) and E² suggests a field-induced reaction driven by dipole changes. According to this interpretation the change of dipole moment should be in the range of approx. 1400 debye. The dissociation rates for DNA helices with approx. 300 to approx. 800 base-pairs strongly increase with increasing sail concentration (measured in the range 1–5 mM ionic strength), whereas the association rate constants remain virtually unchanged. Measurements of the linear dichroism in the same range of DNA chain length demonstrate that for long field pulses of e.g., 40 μs, the amplitude approaches a maximum value and then decreases. The dichroism relaxation curves observed after long field pulses exhibit a component with a positive dichroism and an increased decay time. These observations suggest the formation of a DNA aggregate with an unusual arrangement of the bases.     

Influence of ionic strength on the dichroism properties of polynucleosomal fibers

We report electric-dichroism and electron-microscopic studies of chromatin fibers fixed by protein–protein crosslinking at salt concentrations ranging from 10 to 100 mM. The results confirm a progressive disorganization of the fiber as the salt concentration is lowered. The positive dichroism and large polarizability anisotropy characteristic of the 300-Å diameter fiber found in 100 mM salt are replaced by negative dichroism and smaller effective polarizability anisotropy or dipole moment for samples fixed at lower salt concentration. We interpret the results in terms of segmental, field-induced orientation of the disorganized structure which is present in low salt concentrations. We also observed a field-induced absorbance decrease in chromatin fibers fixed at salt concentration at and below 100 mM. All three optical effects, namely overall orientation of the high-salt fixed fiber, segmental orientation of the low-salt fixed fiber, and field-induced absorbance decrease, occur on roughly the same time scale, 20–100 μs for 50 nucleosome polynucleosomes. The polarizability anisotropy of fibers fixed in 100 mM salt was found to be proportional to the length of the fragment and to the reciprocal square root of the conductivity of the solution used for electric-dichroism measurements. Addition of Mg²⁺ to the measurement buffer affected the dichroism amplitude of samples fixed below 100 mM salt but not those fixed at 100 mM salt. The results reinforce the need for caution in interpreting electric-dichroism measurements on chromatin fibers because of possible field-induced distortion effects.     

Influence of buffer ions and divalent cations on coated vesicle disassembly and reassembly

Disruption of the coat of coated vesicles is accompanied by the release of clathrin and other proteins in soluble form. The ability of solubilized coated vesicle proteins to reassemble into empty coats is influenced by Mg²⁺, Tris ion concentration, pH, and ionic strength. The proteins solubilized by 2 M urea spontaneously reassemble into empty coats following dialysis into isolation buffer (0.1 M MES–1 mM EGTA–1 mM MgCl₂–0.02% NaN₃, pH 6.8). Such reassembled coats have sedimentation properties similar to untreated coated vesicles. Clathrin is the predominant protein of reassembled coats; most of the other proteins present in native coated vesicles are absent. We have found that Mg²⁺ is important in the coat assembly reaction. At pH 8 in 0.01 M or 0.1 M Tris, coats dissociate; however, 10 mM MgCl₂ prevents dissociation. If the coats are first dissociated at pH 8 and then the MgCl₂ raised to 10 mM, reassembly occurs. These results suggest that Mg²⁺ stabilizes the coat lattice and promotes reassembly. This hypothesis is supported by our observations that increasing Mg²⁺ (10 μM–10 mM) increases reassembly whereas chelation of Mg²⁺ by (EGTA) inhibits reassembly. Coats reassembled in low-Tris (0.01 M, pH 8) supernatants containing 10 mM MgCl₂ do not sediment, but upon dialysis into isolation buffer (pH 6.8), these coats become sedimentable. Nonsedimentable coats are noted also either when partially purified clathrin (peak I from Sepharose CL4B columns) is dialyzed into low-ionic-strength buffer or when peaks I and II are dialyzed into isolation buffer. Such nonsedimentable coats may represent intermediates in the assembly reaction which have normal morphology but lack some of the physical properties of native coats. We present a model suggesting that tightly intertwined antiparallel clathrin dimers form the edges of the coat lattice.     

Effect of polyamines and cations on the in vitro methylation of histones

Na⁺ (0.05–0.15 M) increases both the rate and extent of methylation of chromosomal bound histone H4, while spermidine markedly inhibits this reaction. The effects of spermidine could be mimicked by increasing the concentration of Mg²⁺ or Ca²⁺ to 5–10 mM. At the concentrations listed above, these cations have no significant effect on the methylation of free or chromosomal bound histone H3, nor do they affect the rate or extent of methylation of soluble histone H4. Apparently, the accessibility of histone H4 to the methyltransferase is influenced by chromatin structure. Increasing concentrations of Na⁺ alter the conformation of chromatin (DNA) in such a way as to expose lysine residues in the N-terminal region of histone H4 to the methyltransferase, whereas Mg²⁺ or spermidine acts in an opposite manner.     

In vitro formation of glucose-6-phosphate from glyceraldehyde-3-phosphate by liver cytosol from fed and starved rats. Effect of divalent cations on the conversion rate.

Liver cytosol preparations from fed rats are shown to form glucose-6-phosphate from glyceraldehyde-3-phosphate at a rate of 1.6 μmoles·min^?1·g liver wet weight^?1 in presence of 0.4 mM Mg²⁺. This rate is more than doubled by 30 μM EGTA and/or Mg²⁺-concentrations ≥2 mM. 48 hours starvation increases the rate of glucose-6-phosphate formation at 0.4 mM Mg²⁺ to 3.0 μmoles·min^?1·g liver wet weight^?1 and greatly diminishes the effect of EGTA and of higher Mg²⁺-concentrations. Inhibition of glucose-6-phosphate formation by Ca²⁺ and Zn²⁺ is shown to be more pronounced with cytosol from fed than from 48 hours starved rats.     

Solubilization and characterization of RNA polymerase from a higher plant

RNA polymerase has been solubilized from sugar beet chromatin. With calf thmus or sugar beet DNA as template enzyme activity was linear with respect to protein concentration and required the presence of all four nucleoside triphospahates, added DNA and divalent metal ions. The enzyme exhibited a sharp Mn²⁺ optimum of 1·25 mM and a Mg²⁺ optimum at 10mM. The Mn²⁺/Mg²⁺ activity ratio (activity at optimum concentrations) was 2·0 with an optimum salt concentration of 50 mM. Based on data including inhibition with α-amanitin (0·025 μg/ml), the majority of the total activity appeared to be RNA polymerase I. Subsequent fractionation by DEAE-Sephadex column chromatography resulted in one peak of activity eluted with 0·18 M (NH₄)₂SO₄.     

Salt-induced conformational transitions in chromatin. A flow linear dichroism study

The chromatin structure in solution has been studied by the flow linear dichroism method (LD) in a wide range of ionic strengths. It is found that increasing the ionic strength from 0.25 mM Na2EDTA, pH 7.0 to 100 mM NaCl leads to a strong reduction of the LD amplitude of chromatin and inversion of the LD sign from negative to positive at 2 mM NaCl. Chromatin exhibits a positive LD maximum value at 10-20 mM NaCl. These data enable us to conclude that in very low ionic strength (0.25 mM Na2EDTA) the nucleosome discs are oriented with their flat faces more or less parallel to the chromatin filament axis. Increasing ionic strength up to 20 mM NaCl leads to reorientation of the nucleosome discs and to formation of chromatin structures with nucleosome flat faces inclined to the fibril axis. A conformational transition of that kind is not revealed in H1-depleted chromatin. The condensation of the chromatin filaments with increasing concentration of NaCl from 20 mM to 100 mM slightly influences the orientation of the nucleosomes.     

Studies of Glu-416 Variants of β-Galactosidase (<Emphasis Type="Italic">E. coli</Emphasis>) Show that the Active Site Mg<Superscript>2+</Superscript> is Not Important for Structure and Indicate that the Main Role of Mg<Superscript>2+</Superscript> is to Mediate Optimization of Active Site Chemistry

Variants of β-galactosidase with Valine and with Glutamine replacing Glutamate-416 did not have a Mg²⁺ bound at the active site even at high Mg²⁺ concentrations (200 mM). They had low catalytic activity and the pH profiles were very different from those of the native enzyme. In addition, substrates, substrate analogs, transition state analogs and galactose bound very poorly. However, the orientation and conformation of the Mg²⁺ ligands (residues 416, 418, and 461) as well as the B-factors of these three side chains did not change significantly. The structures, conformations and B-factors of other active site residues were also essentially unchanged. These studies show that the active site Mg²⁺ is not necessary for structure and is, therefore, mainly important for modulating the chemistry and mediating the interactions between the active site components.     

Reinterpretation of linear dichroism of chromatin supports a perpendicular linker orientation in the folded state

We present a reinterpretation of linear dichroism data for the salt induced condensation of chromatin. A conflict between electric and flow linear dichroism data for identical chromatin samples, studied at varying degrees of Mg2+ induced folding, can be solved if the orientation in electric fields is mainly determined through the polarization of counter ions along the linker parts, whereas the orientation in flow is governed by the hydrodynamical response of the entire chromatin fiber. The orientation of a chromatin fiber in an electric field would then depend on the linker tilt angle so that at an angle larger than 55 degrees the fiber would tend to orient perpendicular to the applied field. The different orientation distributions obtained with the two methods of alignment may in this way provide extra information about the structure and folding of chromatin.     

DNA orientation in shear flow

The linear dichroism (LD) has been measured for DNA molecules 239–164,000 base pairs long oriented in shear flow over a large range of velocity gradients (30–3,000 s ^?1) and ionic strengths (2–250 mM). At very low gradients, the degree of DNA orientation increases quadratically with the applied shear as predicted by the Zimm theory [J. Zimm, (1956) Chemical Physics, Vol. 24, p. 269]. At higher gradients, the orientation of fragments ≥ 7 kilobase pairs (kbp) increases linearly with increasing shear, whereas the orientation of fragments ≥ 15 kbp shows a more complicated dependence. In general, the orientation decreases with increasing ionic strength throughout the studied ionic strength interval, owing to a decrease in the persistence length of the DNA. The effect is most dramatic at ionic strengths below 10 mM, and is more pronounced for longer DNA fragments. For fragments ≥ 15 kbp and velocity gradients ≥ 100 s^?1, the orientation can be adequately described by the empirical relation: LD^r= –(k₁-G)/(k₂ + G), where k₁is a linear function of the square root of the ionic strength and k₂ depends on the DNA contour length. Since the DNA persistence length can be represented as a linear function of the reciprocal square root of the ionic strength [D. Porschke, (1991) Biophysical Chemistry, Vol. 40, p. 169], extrapolation of the empirical relation provides information about the stiffness of the DNA fibers. © 1993 John Wiley & Sons, Inc.     

Ionic and cofactor requirements for the activity of the apoptotic endonuclease DFF40/CAD

The endonuclease DFF40/CAD mediates regulated DNA fragmentation and chromatin condensation in cells undergoing apoptosis. Here we report the enzyme's co-factor requirements, and demonstrate that the ionic changes that occur in apoptotic cells maximize DFF40/CAD activity. The nuclease requires Mg²⁺, exhibits a trace of activity in the presence of Mn²⁺, is not co-stimulated by Ca²⁺, is inhibited by Zn²⁺ or Cu²⁺, and has high activity over a rather broad pH range (7.0–8.5). The enzyme is thermally unstable, and is rapidly inactivated at 42°C. Enzyme activity is markedly affected by ionic strength. At the optimal [K⁺] of 50–125 mM, which is in the range of the cytoplasmic [K⁺] for cells undergoing apoptosis, the activity of DFF40/CAD for naked DNA cleavage is about 100-fold higher than at 0 or 200 mM [K⁺]. Although these ranges of ionic strength do not affect DFF40 homo-oligomer formation, at higher ionic strengths the enzyme introduces single-stranded nicks into supercoiled DNA.