Viral DNA-synthesizing intermediate complex isolated during assembly of bacteriophage phi X174.

A DNA protein complex that is a precursor of mature phi X174 phage was isolated. The complex sedimented with an S value of 50 in a sucrose gradient and contained phage DNA consisting of a replicative form molecule with an extended tail of single-stranded viral DNA. The viral-strand DNA ranged from one to two genomes in length. Proteins coded on the phi X174 genome as well as the host genome were associated with the viral DNA in the 50S precursor complex. Our results indicated that both viral DNA synthesis and cleavage of the growing viral-strand DNA occurred in the 50S complex.     

Spontaneous Formation of Compound X Chromosomes in Drosophila Melanogaster

Males carrying different X chromosomes were tested for the ability to produce daughters with attached-X chromosomes. This ability is characteristic of males carrying an X chromosome derived from 59b-z, a multiply marked X chromosome, and is especially pronounced in males carrying the unstable 59b-z chromosomes Uc and Uc-lr. Recombination experiments with one of the Uc-lr chromosomes showed that the formation of compound chromosomes depends on two widely separated segments. One of these is proximal to the forked locus and is probably proximal to the carnation locus. This segment may contain the actual site of chromosome attachment. The other essential segment lies between the crossveinless and vermilion loci and may contain multiple factors that influence the attachment process.     

An improved enzymatic cycle for nicotinamide-adenine dinucleotide phosphate.

We describe the use of column chromatography on the nonpolar adsorbent. Amberlite XAD-2, and on silanized silica gel in the desalting and partial purification of cobalamins. These techniques are both simpler and more versatile than phenol extraction, without sacrificing efficiency. In addition, a solvent system for thin-layer chromatography on silanized silica gel is described which rapidly separates naturally occurring cobalamins.     

Snapshots of enzymatic Baeyer-Villiger catalysis: oxygen activation and intermediate stabilization

Baeyer-Villiger monooxygenases catalyze the oxidation of carbonylic substrates to ester or lactone products using NADPH as electron donor and molecular oxygen as oxidative reactant. Using protein engineering, kinetics, microspectrophotometry, crystallography, and intermediate analogs, we have captured several snapshots along the catalytic cycle which highlight key features in enzyme catalysis. After acting as electron donor, the enzyme-bound NADP(H) forms an H-bond with the flavin cofactor. This interaction is critical for stabilizing the oxygen-activating flavin-peroxide intermediate that results from the reaction of the reduced cofactor with oxygen. An essential active-site arginine acts as anchoring element for proper binding of the ketone substrate. Its positively charged guanidinium group can enhance the propensity of the substrate to undergo a nucleophilic attack by the flavin-peroxide intermediate. Furthermore, the arginine side chain, together with the NADP(+) ribose group, forms the niche that hosts the negatively charged Criegee intermediate that is generated upon reaction of the substrate with the flavin-peroxide. The fascinating ability of Baeyer-Villiger monooxygenases to catalyze a complex multistep catalytic reaction originates from concerted action of this Arg-NADP(H) pair and the flavin subsequently to promote flavin reduction, oxygen activation, tetrahedral intermediate formation, and product synthesis and release. The emerging picture is that these enzymes are mainly oxygen-activating and "Criegee-stabilizing" catalysts that act on any chemically suitable substrate that can diffuse into the active site, emphasizing their potential value as toolboxes for biocatalytic applications.     

Sites of direct and indirect halogenation of albumin.

The sites of radiohalogenation in proteins vary with the labeling method and the pH of the labeling reaciton. We have directly halogenated albumin with carrier-free radioiodide by three methods (pH range 2.2--9.3), and with carrier-free radiobromide by the chloroperoxidase method (pH range 2.2--4.6). Albumin was also indirectly halogenated by attaching a radioiodinated acylating agent, N-succinimidyl-3-(4-hydroxyphenyl) propionate (SHPP). The labeled proteins were proteolyzed enzymatically at neutral pH and the labeled amino acids produced were analyzed by liquid chromatography. Iodination at pH 7 yielded predominantly monoiodotyrosine, but at lower pH, fewer tyrosyl residues are labeled and a greater number of unstable sulfur-iodine bonds are formed at cysteinyl residues. Bromination with chloroperoxidase resulted in a high degree of labeling of cysteinyl residues at pH 2.8, the condition for optimum activity of this halogenating enzyme. Indirect halogenation with SHPP resulted in labeling of mid-chain lysyl, histidyl and tyrosyl residues.     

The rolling circle . capsid complex as an intermediate in phi X DNA replication and viral assembly

Late in the life cycle of the single-stranded DNA phage phi X, the synthesis of positive strand DNA is coupled to the maturation of progeny virions. DNA synthesis and packaging take place in a replication-assembly complex, which we have purified to homogeneity and characterized. The following conclusions can be drawn: 1. The DNA component of the replication-assembly complex is a rolling circle with a single-stranded DNA tail which is less than or equal to genome length. 2. The major protein component of the replication-assembly complex is an intact viral capsid, as shown by gel analysis of 35S-labeled complexes. As replication proceeds at the DNA growing point, the positive strand tail of the rolling circle is displaced directly into the capsid. In addition to the capsid, the complex contains at least 1 molecule of the phi X gene A nicking protein, which appears to be covalently linked to the DNA. 3. The rolling circle . capsid complex can be purified to homogeneity by taking advantage of its uniform sedimentation velocity (35 S) and its uniform density upon equilibrium centrifugation in CsCl (1.50 g/cc). 4. The replication-assembly complex can be visualized in the electron microscope. An electron-dense particle, which has the dimensions of a viral capsid, is observed attached to a rolling circle at the DNA growing point. 5. Hybridization of specific phi X restriction fragments to the deproteinized, single-stranded tails of intact rolling circles has allowed the use of these replicating intermediates to determine both the origin/terminus and the direction of phi X positive strand DNA synthesis. The ends of the rolling circle tails map in the Hae III restriction Fragment Z6b, at the position on the phi X genome at which the gene A endonuclease is known to cut. This result indicates that this endonuclease participates in the "termination" of each round of synthesis by cutting off unit-length viral genomes. 6. Rolling circle . capsid complexes were also isolated from two other icosahedral, single-stranded DNA phages: G4 and St-1. The rolling circle . capsid complex seen in the case of the single-stranded DNA phages represents the first example of a structure in which DNA synthesis and viral assembly occur in a coupled manner. This tight coordination explains why double-stranded DNA circles are the net product of synthesis early in the viral life cycle while only single-stranded DNA circles are produced later. The single-stranded tails of the rolling circle intermediates are available for conversion to the duplex state at early times, whereas the concentration of preformed capsids later is high enough to bind to all of the replicating molecules and package the emerging positive strand DNA.     

Development of enzymatic activity during protein folding. Detection of a spectroscopically silent native-like intermediate of muscle acylphosphatase.

The recovery of enzymatic activity during the folding of muscle acylphosphatase and two single residue mutants (proline 54 to alanine and proline 71 to alanine) from 7 M urea has been monitored and compared with the development of intrinsic fluorescence emission. Fluorescence measurements reveal the presence in the wild-type protein of a major rapid refolding phase followed by a second low amplitude slow phase. The slow phase is absent in the fluorescence trace acquired with the proline 54 to alanine mutant, suggesting the involvement of this proline residue in the fluorescence-detected slow phase of the wild-type protein. The major kinetic phase is associated with a considerable recovery of enzymatic activity, indicating that a large fraction of molecules refolds with effective two-state behavior. The use of time-resolved enzymatic activity as a probe to follow the folding process reveals, however, the presence of another exponential slow phase arising from proline 71. This slow phase is not observable by utilizing optical probes, indicating that, unlike proline 54, the cis to trans isomerization of proline 71 can take place in an intermediate possessing a native-like fold. We suggest that, although spectroscopically silent and structurally insignificant, the cis-trans interconversion of proline residues in native-like intermediates may be crucial for the generation of enzymatic activity of functional enzymes.     

An enzymatic method for the estimation of L-leucine in rat blood.

A specific enzymatic method for the routine measurement of L-leucine in blood samples is presented. The method uses a commercial preparation of tRNAs and amino acetyl-tRNA synthetases for the specific loading of L-leucine into the tRNA(Leu) present, competing with carrier-free L-[U-14C]leucine. The radioimmunoassay-like plot of radioactivity found in the acid-insoluble (tRNA) fraction was used to determine the amount of unlabelled L-leucine of the samples when compared against a standard curve. The interference of L-isoleucine, L-valine and L-alanine was very low.     

An enzymatic determination of hydrogen peroxide by using spectrophotometry.

A new spectrophotometric method for determining low hydrogen peroxide concentrations by using horseradish peroxidase in the presence of NADH at pH 7.5 has been described. Both total NADH consumption and initial reaction rate may be used for the determination. Using the NADH consumption, a linear response with respect to hydrogen peroxide was observed in the concentration range 7 x 10(-8)-2.5 x 10(-6) M. Due to the presence of superoxide dismutase, hydrogen peroxide is partly regenerated and an amplification of the signal results, which explains the sensitivity.