Macromolecular crowding extends the range of conditions under which DNA polymerase is functional.

The nick-translation reaction of E. coli DNA polymerase I (Pol I) was used as a model system to demonstrate the ability of macromolecular crowding to alter the response of an enzyme to a number of basic parameters, such as pH, temperature or inhibitors. In the presence of high concentrations of non-specific polymers, nick translation occurred under a variety of otherwise strongly inhibitory conditions. The conditions tested included a range of pH values or temperatures or inhibitory concentrations of urea, formamide or ethidium bromide. These crowding effects are accentuated at higher ionic strengths, suggesting their origin in increased binding between the polymerase and its DNA template-primer under crowded conditions. Kinetic measurements were consistent with such a mechanism.

Estimation of macromolecule concentrations and excluded volume effects for the cytoplasm of Escherichia coli.

The very high concentration of macromolecules within cells can potentially have an overwhelming effect on the thermodynamic activity of cellular components because of excluded volume effects. To estimate the magnitudes of such effects, we have made an experimental study of the cytoplasm of Escherichia coli. Parameters from cells and cell extracts are used to calculate approximate activity coefficients for cytoplasmic conditions. These calculations require a representation of the sizes, concentrations and effective specific volumes of the macromolecules in the extracts. Macromolecule size representations are obtained either by applying a two-phase distribution assay to define a related homogeneous solution or by using the molecular mass distribution of macromolecules from gel filtration. Macromolecule concentrations in cytoplasm are obtained from analyses of extracts by applying a correction for the dilution that occurs during extraction. That factor is determined from experiments based upon the known impermeability of the cytoplasmic volume to sucrose in intact E. coli. Macromolecule concentrations in the cytoplasm of E. coli in either exponential or stationary growth phase are estimated to be approximately 0.3 to 0.4 g/ml. Macromolecule specific volumes are inferred from the composition of close-packed precipitates induced by polyethylene glycol. Several well-characterized proteins which bind to DNA (lac repressor, RNA polymerase) are extremely sensitive to changes in salt concentration in studies in vitro, but are insensitive in studies in vivo. Application of the activity coefficients from the present work indicates that at least part of this discrepancy arises from the difference in excluded volumes in these studies. Applications of the activity coefficients to solubility or to association reactions are also discussed, as are changes associated with cell growth phase and osmotic or other effects. The use of solutions of purified macromolecules that emulate the crowding conditions inferred for cytoplasm is discussed.

Effects of macromolecular crowding on the association of E. coli ribosomal particles.

The equilibrium for the binding reaction between the 30 S and 50 S ribosomal subunits of E. coli is shifted towards formation of 70 S ribosomes in the presence of a variety of polymers. The polymers also increase a further interaction between 70 S particles to form the 100 S dimer. The requirement for relatively high concentrations of non-specific polymers indicates that the shifts in equilibria arise from excluded volume effects. Analysis using scaled particle theory is consistent with this mechanism. The effects of high concentrations of polymers on the interactions between ribosomal species may make important changes in the function of ribosomes under the crowded conditions which occur in vivo.

Quantitation of specific fragments in DNA restriction digests: application to the cohesive fragments in lambda DNA digests.

A procedure for the quantitation of reactions between specific members of a set of DNA restriction fragments is presented. Quantitation of the cohesive fragments in NruI nuclease digests of lambda DNA is used as an example. Restriction fragments are resolved on agarose gels and their amounts are estimated from densitometer scans of photographic negatives of ethidium bromide-stained gels. A linear relationship is found between the peak height of given fragment on the scan and the logarithm of the molecular weight of the fragment, arising in part from the stoichiometry of the digest; this relationship allows simple interpolation between the peak heights of the nonreacting fragments in each gel lane to determine the theoretical maximal amount of each reactive fragment in that gel lane. Similar procedures should be applicable to enzymatic ligation or to site-specific cleavage of specific restriction fragments or to autoradiographic detection of the fragments. Since each lane of the gel is analyzed independently, the method is largely self-correcting for variations in amounts applied to the gel.

Excluded volume effects on the partition of macromolecules between two liquid phases.

Partition parameters of several proteins and other macromolecules are measured in an aqueous two-phase liquid system containing polyethylene glycol and phosphate buffer. Distribution of macromolecules is a function of the relative volume excluded to the macromolecules in the two phases. A simple model with no adjustable parameters yields covolumes of the macromolecules with the polyethylene glycol. Covolumes are used to estimate effective molecular volumes and the magnitudes of excluded volume effects. The same approach is applied to mixtures of macromolecules.