The disassembly, reassembly and stability of CCMV protein capsids.

Efficient procedures are described for the disassembly of Cowpea Chlorotic Mottle Virus (CCMV) into its viral-RNA and capsid-protein components, the separation of the RNA and protein, and the reassembly of the purified protein into higher order nanoscale structures. These straightforward biochemical techniques result in high yield quantities of protein suitable for further biophysical studies (AFM, X-ray scattering, NMR, osmotic stress experiments, protein phase-diagram) and nanotechnology applications (protein enclosed nanoparticles, protein-lipid nanoemulsion droplets). Also discussed are solution conditions that affect the stability of the self-assembled protein structure and explicitly show that divalent cation is not required to obtain stable protein structures, while the presence of even small amounts of Ba(2+) have a significant impact on protein self-assembly. However, since high ionic strength solution conditions result in good yields of CCMV-like protein capsids, it is suggested that the highly charged cationic protein N-terminus could act as an electrostatic switch for protein self-assembly and therefore be modulated by ionic strength and salt type. It was also found that CaCl(2)/RNA precipitation methods do not yield sufficiently pure protein samples.

Efficient purification of bromoviruses by ultrafiltration.

Ultrafiltration using polyethersulfone-membranes was evaluated as an efficient and preferred method for purifying Cowpea Chlorotic Mottle Virus (CCMV). Cesium chloride (CsCl) ultracentrifugation and ultrafiltration protocols are described, and comparative UV-spectroscopic and electron micrograph results are presented. CCMV purified by ultrafiltration are shown to be equivalent to CCMV purified by ultracentrifugation, while reducing purification time by two days and avoiding the need for expensive capital overheads such as ultracentrifuges, rotors and toxic CsCl chemical waste.

An unusual sugar conformation in the structure of an RNA/DNA decamer of the polypurine tract may affect recognition by RNase H.

Retroviral conversion of single-stranded RNA into double-stranded DNA requires priming for each strand. While host cellular t-RNA serves as primer for the first strand, the viral polypurine tract (PPT) is primer for the second. Therefore, polypurine tracts of retroviruses are essential for viral replication by reverse transcriptase (RT). These purine tracts are resistant to cleavage during first strand synthesis. In obtaining the primer for second strand synthesis, the RNase H function of RT must cleave the PPT exactly for in vivo transcription to proceed efficiently and proper integration to occur. At the RNase H active site the protein makes contacts primarily along the backbone, with hydrogen bonds to the sugar-phosphate oxygen atoms. A high-resolution structure (1.10A) of the first ten base-pairs of the RNA/DNA hybrid PPT, r-(c-a-a-a-g-a-a-a-a-g)/d-(C-T-T-T-T-C-T-T-T-G), contains the highly deformable r-(a-g-a) steps found in retroviral polypurine tracts. This r-(a-g-a) motif is utilized in the "unzipping" or unpairing of bases that occurs when RT binds a malleable PPT. Another unusual feature found in our high-resolution PPT structure is the sugar switch at RNA adenine 2. All the RNA sugars are the expected C3'-endo, except sugar 2, which is C2'-endo, characteristic of B-form sugars. This local A-to-B conversion adversely affects the pattern of hydrogen bonds from protein to sugar-phosphate backbone, disrupting the catalytic site. Disruption could cause the enzyme to pause at the 5'-end of the PPT, leaving it intact. Pyrimidine-purine (YR) steps are most deformable and the T-A step especially can undergo A-to-B transitions readily.

Stabilization of nucleic acid triplexes by high concentrations of sodium and ammonium salts follows the Hofmeister series.

The thermal stability of the triplexes d(C(+)-T)(6):d(A-G)(6);d(C-T)(6) and d(T)(21):d(A)(21);d(T)(21) was studied in the presence of high concentrations of the anions Cl(-), HPO(4)(2-), CH(3)COO(-), SO(4)(2-) and ClO(4)(-). Thermally-induced triplex and duplex transitions were identified by UV- and CD-spectroscopy and T(m) values were determined from melting profiles. A thermodynamic analysis of triplex transitions shows the limitations of commonly used treatments for determining the associated release or uptake of salt, solute or water. Enhancement of the stability of these triplexes follows the rank order of the Hofmeister series for anions of sodium and ammonium salts, whereas water structure-breaking solutes have the opposite effect. The rank order for the Hofmeister series ClO(4)(-)

Enhanced stabilization of the triplexes d(C(+)-T)(6):d(A-G)(6);d(C-T)(6), d(T)(21):d(A)(21);d(T)(21) and poly r(U:AU) by water structure-making solutes.

A variety of organic cations, cationic lipids, low molecular weight alcohols, sodium dodecylsulfate, trehalose, glycerol, low molecular weight polyethylene glycols, and DMSO were tested for their ability to modulate the stability of the triplexes d(C(+)-T)(6):d(A-G)(6);d(C-T)(6), d(T)(21):d(A)(21);d(T)(21), poly r(U:A U) and their respective core duplexes, d(A-G)(6);d(C-T)(6), d(A)(21);d(T)(21), poly r(A-U). Very substantial enhancement of triplex stability over that in a physiological salt buffer at pH 7 is obtained with different combinations of triplex and high concentrations of these additives, e.g. trimethylammonium chloride and d(C(+)-T)(6):d(A-G)(6);d(C-T)(6); 2-propanol and d(T)(21):d(A)(21);d(T)(21); ethanol and poly r(U:A;U). Triplex formation is even observed with a 1:1 strand mixture of d(A-G)(6) and d(C-T)(6) in the presence of dimethylammonium, tetramethylammonium, and tetraethylammonium-chloride, as well as methanol, ethanol, and 2-propanol. Triplex stability follows the water structure-making ability (and in some cases the duplex unwinding ability) of the organic cations, the low molecular weight alcohols and other neutral organic compounds, whereas water structure-breaking additives decrease triplex stability. These findings are consistent with those reported in the accompanying paper that triplex formation occurs with a net uptake of water. Since the findings suggest that third strand-binding is facilitated by unwinding of the target duplex, it is inferred that triplex formation may be enhanced by nucleic acid binding proteins operating similarly.

Osmotic pressure inhibition of DNA ejection from phage.

Bacterial viral capsids in aqueous solution can be opened in vitro by addition of their specific receptor proteins, with consequent full ejection of their genomes. We demonstrate that it is possible to control the extent of this ejection by varying the external osmotic pressure. In the particular case of bacteriophage lambda, the ejection is 50% inhibited by osmotic pressures (of polyethylene glycol) comparable to those operative in the cytoplasm of host bacteria; it is completely suppressed by a pressure of 20 atmospheres. Furthermore, our experiments monitor directly a dramatic decrease of the stress inside the unopened phage capsid upon addition of polyvalent cations to the host solution, in agreement with many recent theories of DNA interactions.