The effects of allantoin, arginine and NaCl on thermal melting and aggregation of ribonuclease, bovine serum albumin and lysozyme.

Allantoin is widely used as a skin care agent and readily forms crystals, which were recently shown to bind endotoxins and high molecular weight aggregates in cell culture harvests. Here, we have investigated the effects of allantoin on thermal stability and aggregation of protein using ribonuclease, bovine serum albumin and lysozyme using temperature-regulated circular dichroism (CD) and differential scanning microcalorimetry (DSC). Ribonuclease showed no change in thermal stability and aggregation by the addition of allantoin. While allantoin showed no effects on the thermal stability of bovine serum albumin, it enhanced aggregation. Similarly, allantoin showed no stabilizing effects on lysozyme, but it strongly suppressed aggregation. Such suppressed aggregation resulted in reversibility of thermal unfolding of lysozyme. These effects of allantoin were then compared with those of NaCl and arginine hydrochloride. Arginine was similar to allantoin at low concentrations, where both solvent additives can be compared due to limited solubility of allantoin.

Biophysical characterization of a model antibody drug conjugate.

Antibody drug conjugates (ADC) are important next-generation biopharmaceuticals and thus require stringent structure characterization as is the case for monoclonal antibodies. We have tested several biophysical techniques, i.e., circular dichroism, analytical ultracentrifugation, differential scanning calorimetry and fluorescence spectroscopy, to characterize a fluorescein-labeled monoclonal antibody as a model ADC. These techniques indicated possible small structure and stability changes by the conjugation, while largely retaining the tertiary structure of the antibody, consistent with unaltered biological activities. Thus, the above biophysical techniques are effective at detecting changes in the structural properties of ADC.

Analytical Ultracentrifugation as a Tool to Study Nonspecific Protein-DNA Interactions.

Analytical ultracentrifugation (AUC) is a powerful tool that can provide thermodynamic information on associating systems. Here, we discuss how to use the two fundamental AUC applications, sedimentation velocity (SV), and sedimentation equilibrium (SE), to study nonspecific protein-nucleic acid interactions, with a special emphasis on how to analyze the experimental data to extract thermodynamic information. We discuss three specific applications of this approach: (i) determination of nonspecific binding stoichiometry of E. coli integration host factor protein to dsDNA, (ii) characterization of nonspecific binding properties of Adenoviral IVa2 protein to dsDNA using SE-AUC, and (iii) analysis of the competition between specific and nonspecific DNA-binding interactions observed for E. coli integration host factor protein assembly on dsDNA. These approaches provide powerful tools that allow thermodynamic interrogation and thus a mechanistic understanding of how proteins bind nucleic acids by both specific and nonspecific interactions.

Novel DNA packaging recognition in the unusual bacteriophage N15.

Phage lambda's cosB packaging recognition site is tripartite, consisting of 3 TerS binding sites, called R sequences. TerS binding to the critical R3 site positions the TerL endonuclease for nicking cosN to generate cohesive ends. The N15 cos (cos(N15)) is closely related to cos(λ), but whereas the cosB(N15) subsite has R3, it lacks the R2 and R1 sites and the IHF binding site of cosB(λ). A bioinformatic study of N15-like phages indicates that cosB(N15) also has an accessory, remote rR2 site, which is proposed to increase packaging efficiency, like R2 and R1 of lambda. N15 plus five prophages all have the rR2 sequence, which is located in the TerS-encoding 1 gene, approximately 200 bp distal to R3. An additional set of four highly related prophages, exemplified by Monarch, has R3 sequence, but also has R2 and R1 sequences characteristic of cosB-λ. The DNA binding domain of TerS-N15 is a dimer.

The leucine-rich amelogenin protein (LRAP) is primarily monomeric and unstructured in physiological solution.

Amelogenin proteins are critical to the formation of enamel in teeth and may have roles in controlling growth and regulating microstructures of the intricately woven hydroxyapatite (HAP). Leucine-rich amelogenin protein (LRAP) is a 59-residue splice variant of amelogenin and contains the N- and C-terminal charged regions of the full-length protein thought to control crystal growth. Although the quaternary structure of full-length amelogenin in solution has been well studied and can consist of self-assemblies of monomers called nanospheres, there is limited information on the quaternary structure of LRAP. Here, sedimentation velocity analytical ultracentrifugation (SV) and small angle neutron scattering (SANS) were used to study the tertiary and quaternary structure of LRAP at various pH values, ionic strengths, and concentrations. We found that the monomer is the dominant species of phosphorylated LRAP (LRAP(+P)) over a range of solution conditions (pH 2.7-4.1, pH 4.5-8, 50 mmol/L(mM) to 200 mM NaCl, 0.065-2 mg/mL). The monomer is also the dominant species for unphosphorylated LRAP (LRAP(-P)) at pH 7.4 and for LRAP(+P) in the presence of 2.5 mM calcium at pH 7.4. LRAP aggregates in a narrow pH range near the isoelectric point of pH 4.1. SV and SANS show that the LRAP monomer has a radius of ∼2.0 nm and an asymmetric structure, and solution NMR studies indicate that the monomer is largely unstructured. This work provides new insights into the secondary, tertiary, and quaternary structure of LRAP in solution and provides evidence that the monomeric species may be an important functional form of some amelogenins.

Characterization of the non-specific DNA binding properties of the Adenoviral IVa2 protein.

Human Adenovirus (Ad) is a non-enveloped, icosahedral virus with a linear, double-stranded DNA genome. The Ad IVa2 protein is involved in multiple viral processes including viral late gene transcription and virus assembly. Previous studies have shown that IVa2 loads additional viral proteins onto conserved DNA elements within the Ad genome to regulate these viral processes. IVa2 also possesses strong non-specific DNA binding activity, and it is likely it uses this activity to recruit proteins to the conserved DNA elements. Here we have investigated the non-specific DNA binding activity of IVa2 using nitrocellulose/DEAE filter binding and sedimentation equilibrium techniques. We have analyzed our data using the McGhee and Von Hippel approach [1], and find that IVa2 binds with strong, positive nearest-neighbor cooperativity. In addition, we describe how to apply the McGhee and von Hippel approach to directly analyze sedimentation equilibrium data using non-linear least-squares methods. We discuss the implications of these results with respect to current virus assembly mechanisms.

Cooperative heteroassembly of the adenoviral L4-22K and IVa2 proteins onto the viral packaging sequence DNA.

Human adenovirus (Ad) is an icosahedral, double-stranded DNA virus. Viral DNA packaging refers to the process whereby the viral genome becomes encapsulated by the viral particle. In Ad, activation of the DNA packaging reaction requires at least three viral components: the IVa2 and L4-22K proteins and a section of DNA within the viral genome, called the packaging sequence. Previous studies have shown that the IVa2 and L4-22K proteins specifically bind to conserved elements within the packaging sequence and that these interactions are absolutely required for the observation of DNA packaging. However, the equilibrium mechanism for assembly of IVa2 and L4-22K onto the packaging sequence has not been determined. Here we characterize the assembly of the IVa2 and L4-22K proteins onto truncated packaging sequence DNA by analytical sedimentation velocity and equilibrium methods. At limiting concentrations of L4-22K, we observe a species with two IVa2 monomers and one L4-22K monomer bound to the DNA. In this species, the L4-22K monomer is promoting positive cooperative interactions between the two bound IVa2 monomers. As L4-22K levels are increased, we observe a species with one IVa2 monomer and three L4-22K monomers bound to the DNA. To explain this result, we propose a model in which L4-22K self-assembly on the DNA competes with IVa2 for positive heterocooperative interactions, destabilizing binding of the second IVa2 monomer. Thus, we propose that L4-22K levels control the extent of cooperativity observed between adjacently bound IVa2 monomers. We have also determined the hydrodynamic properties of all observed stoichiometric species; we observe that species with three L4-22K monomers bound have more extended conformations than species with a single L4-22K bound. We suggest this might reflect a molecular switch that controls insertion of the viral DNA into the capsid.

Thermodynamic linkage of large-scale ligand aggregation with receptor binding.

There are many examples in the literature that deal explicitly with the coupling of ligand oligomerization with receptor binding. For example, many transcription factors dimerize and this plays a fundamental role in sequence specific DNA recognition. However, many biological macromolecules undergo reversible, large scale aggregation processes, some of which are indefinite. The thermodynamic coupling of these aggregation processes to other processes, such as protein-protein and protein-DNA interactions, has not been explored in depth. Here we consider the thermodynamic consequences of large scale ligand aggregation on the determination of fundamental thermodynamic parameters, such as equilibrium binding constants and ligand-receptor stoichiometries. We find that a fundamental consequence of an aggregating ligand is that the free ligand concentration (ligand that is not found in aggregates) is buffered over a wide total ligand concentration range. In general, the larger the size of the aggregates, the wider the range over which the free ligand concentration is buffered. An additional consequence of this observation is that an upper limit is set on the fractional occupancy of the ligand's receptor, such that even if the ligand is over-expressed to very high levels in the cell, this will not necessarily ensure that 100% of the ligand's receptors will be occupied. The implications of these results for sequence specific DNA binding proteins will be discussed.

Self-association of the adenoviral L4-22K protein.

Human adenovirus (Ad) is an icosahedral, double-stranded DNA virus that causes infections of the respiratory tract, urinary tract, and gastrointestinal tract. Assembly of virus particles requires condensation and encapsidation of the linear viral genome. This process requires sequence specific binding of two viral proteins, called IVa2 and L4-22K, to a conserved sequence located at the left end of the viral genome, called the packaging sequence (PS). IVa2 and an alternatively spliced form of L4-22K, called L4-33K, also function as transcriptional activators of the major late promoter (MLP), which encodes viral structural and core proteins. IVa2 and L4-33K bind to identical conserved DNA sequences downstream of the MLP, called the downstream element (DE), to activate transcription. To begin to dissect how the IVa2, L4-22K, and L4-33K proteins simultaneously function as transcriptional activators and DNA packaging proteins, we need to understand the thermodynamics of assembly of these proteins on DNA that contains the PS as well as the DE. Toward this end, we have characterized the self-assembly properties of highly purified, recombinant L4-22K protein. We show that L4-22K reversibly assembles into higher-order structures according to an indefinite, isodesmic assembly scheme. We show that the smallest polymerizing unit is likely the L4-22K monomer (s(20,w) = 2.16 ± 0.04 S) and that the monomer assembles with itself and/or other aggregates with an equilibrium association constant, L, of 112 (102, 124) µM(-1) (0.1 M NaCl, pH 7, 25 °C). A mechanistic consequence of an isodesmic, indefinite assembly process is that the free concentration of the smallest polymerizing unit cannot exceed 1/L. We discuss the implications of this observation with respect to the thermodynamics of assembly of L4-22K and IVa2 on the PS.

Kinetic analysis of the genome packaging reaction in bacteriophage lambda.

Bacteriophage lambda is a double-stranded DNA virus that infects the Escherichia coli bacterium. lambda genomic DNA is replicated via rolling circle replication, resulting in multiple genomes linked head to tail at the cos site. To insert a single lambda genome into the viral capsid, the lambda terminase enzyme introduces symmetric nicks, 12 bp apart, at the cos site, and then promotes a strand separation reaction, releasing the tail end of the previous genome and leaving a binary complex consisting of lambda terminase bound to the head end of the adjacent genome. Next, the genome is translocated into the interior of the capsid particle, in a process that requires ATP hydrolysis by lambda terminase. Even though DNA packaging has been studied extensively, currently no bulk assays are available that have been optimized to report directly on DNA translocation. Rather, these assays are sensitive to assembly steps reflecting formation of the active, DNA packaging machine. In this work, we have modified the DNase protection assay commonly used to study DNA packaging in several bacteriophage systems, such that it reports directly on the kinetics of the DNA packaging reaction. We have analyzed our DNA packaging data according to an N-step sequential minimal kinetic model and have estimated an overall packaging rate of 119 +/- 8 bp/s, at 4 degrees C and 1 mM ATP. Furthermore, we have measured an apparent step size for the this reaction (m(obs)) of 410 +/- 150 bp. The magnitude of this value indicates that our assay is most likely sensitive to both mechanical steps associated with DNA insertion as well as occasional slow steps that are repeated every >410 bp. These slow steps may be reflective of the pausing events observed in recent single-molecule studies of DNA packaging in bacteriophage lambda [Fuller, D. N., et al. (2007) J. Mol. Biol. 373, 1113-1122]. Finally, we show that either ATP or ADP is required for terminase cutting at cos, to generate the active, DNA packaging complex.

Interaction of the adenoviral IVa2 protein with a truncated viral DNA packaging sequence.

Adenoviral (Ad) infection typically poses little health risk for immunosufficient individuals. However, for immunocompromised individuals, such as AIDS patients and organ transplant recipients, especially pediatric heart transplant recipients, Ad infection is common and can be lethal. Ad DNA packaging is the process whereby the Ad genome becomes encapsulated by the viral capsid. Specific packaging is dependent upon the packaging sequence (PS), which is composed of seven repeated elements called A repeats. The Ad protein, IVa2, which is required for viral DNA packaging, has been shown to bind specifically to synthetic DNA probes containing A repeats I and II, however, the molecular details of this interaction have not been investigated. In this work we have studied the binding of a truncated form of the IVa2 protein, that has previously been shown to be sufficient for virus viability, to a DNA probe containing A repeats I and II. We find that the IVa2 protein exists as a monomer in solution, and that a single IVa2 monomer binds to this DNA with high affinity (K(d)< approximately 10 nM), and moderate specificity, and that the trIVa2 protein interacts in a fundamentally different way with DNA containing A repeats than it does with non-specific DNA. We also find that at elevated IVa2 concentrations, additional binding, beyond the singly ligated complex, is observed. When this reaction is modeled as representing the binding of a second IVa2 monomer to the singly ligated complex, the K(d) is 1.4+/-0.7 microM, implying a large degree of negative cooperativity exists for placing two IVa2 monomers on a DNA with adjacent A repeats.

Packaging of a unit-length viral genome: the role of nucleotides and the gpD decoration protein in stable nucleocapsid assembly in bacteriophage lambda.

The developmental pathways for a variety of eukaryotic and prokaryotic double-stranded DNA viruses include packaging of viral DNA into a preformed procapsid structure, catalyzed by terminase enzymes and fueled by ATP hydrolysis. In most instances, a capsid expansion process accompanies DNA packaging, which significantly increases the volume of the capsid to accommodate the full-length viral genome. "Decoration" proteins add to the surface of the expanded capsid lattice, and the terminase motors tightly package DNA, generating up to approximately 20 atm of internal capsid pressure. Herein we describe biochemical studies on genome packaging using bacteriophage lambda as a model system. Kinetic analysis suggests that the packaging motor possesses at least four ATPase catalytic sites that act cooperatively to effect DNA translocation, and that the motor is highly processive. While not required for DNA translocation into the capsid, the phage lambda capsid decoration protein gpD is essential for the packaging of the penultimate 8-10 kb (15-20%) of the viral genome; virtually no DNA is packaged in the absence of gpD when large DNA substrates are used, most likely due to a loss of capsid structural integrity. Finally, we show that ATP hydrolysis is required to retain the genome in a packaged state subsequent to condensation within the capsid. Presumably, the packaging motor continues to "idle" at the genome end and to maintain a positive pressure towards the packaged state. Surprisingly, ADP, guanosine triphosphate, and the nonhydrolyzable ATP analog 5'-adenylyl-beta,gamma-imidodiphosphate (AMP-PNP) similarly stabilize the packaged viral genome despite the fact that they fail to support genome packaging. In contrast, the poorly hydrolyzed ATP analog ATP-gammaS only partially stabilizes the nucleocapsid, and a DNA is released in "quantized" steps. We interpret the ensemble of data to indicate that (i) the viral procapsid possesses a degree of plasticity that is required to accommodate the packaging of large DNA substrates; (ii) the gpD decoration protein is required to stabilize the fully expanded capsid; and (iii) nucleotides regulate high-affinity DNA binding interactions that are required to maintain DNA in the packaged state.

Assembly of bacteriophage lambda terminase into a viral DNA maturation and packaging machine.

Terminase enzymes are common to complex double-stranded DNA viruses and function to package viral DNA into the capsid. We recently demonstrated that the bacteriophage lambda terminase gpA and gpNu1 proteins assemble into a stable heterotrimer with a molar ratio gpA1/gpNu1(2). This terminase protomer possesses DNA maturation and packaging activities that are dependent on the E. coli integration host factor protein (IHF). Here, we show that the protomer further assembles into a homogeneous tetramer of protomers of composition (gpA1/gpNu1(2))4. Electron microscopy shows that the tetramer forms a ring structure large enough to encircle duplex DNA. In contrast to the heterotrimer, the ring tetramer can mature and package viral DNA in the absence of IHF. We propose that IHF induced bending of viral DNA facilitates the assembly of four terminase protomers into a ring tetramer that represents the catalytically competent DNA maturation and packaging complex in vivo. This work provides, for the first time, insight into the functional assembly state of a viral DNA packaging motor.