Structure-activity relationships for a class of inhibitors of purine nucleoside phosphorylase.

Values of inhibition constants, Ki, for a family of structurally related, competitive inhibitors of calf spleen purine nucleoside phosphorylase (PNP) have been determined employing both inosine as substrate and a manual assay and 2-amino-6-mercapto-7-methylpurine ribonucleoside (MESG) as substrate and a robot-based enzyme kinetics facility. Several of the values determined robotically were confirmed employing the same substrate and a manual assay. Surprisingly, for many of the inhibitors examined, values of Ki determined with MESG as substrate are smaller than those obtained employing inosine as substrate by a factor that varies from less than 2 to 10. Values of concentrations required for 50% inhibition of PNP, IC50, have also been determined for the same family of inhibitors employing inosine as substrate. Values of IC50ino and those for Kiino and Kimesg for subsets of the inhibitors have been employed as training sets to create quantitative structure-activity relationships (QSAR) which have substantial power to predict values of IC50 and Ki for inhibitors outside the training set. These QSAR models should be useful in guiding future medicinal chemistry efforts designed to discover inhibitors of PNP having increased potency.

Three-dimensional model for slipped loop RNA.

Earlier a three-dimensional model for a new unusual DNA conformation referred to as Slipped Loop Structure (SLS) has been suggested by us (1). The same type of folding could occur with RNA as well which means that one must use the A-form of the double helix rather than the B-one. The present paper discusses the creation of an all-atom stereochemically sound model for SLS-RNA. This calculated model, while possessing the same folding topology as the SLS-DNA, differs dramatically from the SLS-DNA by an overall folding geometry. It also differs radically from the RNA-pseudoknot and can thus be regarded as a new type of an RNA folding.

Incorporation of nuclear matrix attachment regions into the herpes simplex virus type 1 genome does not induce long-term expression of a foreign gene during latency.

The nuclear matrix plays a critical role in DNA replication, gene transcription and RNA processing. Transcriptionally active genes are usually associated with the nuclear matrix through DNA sequences, matrix attachment regions or MARs, which tether looped DNA to the matrix. In stable transfection and in transgenic mice MAR elements placed at the flanks of genic constructs may enhance expression and insulate against position effect variability, suggesting that independent units of transcription are established insulated from the regulatory controls of their neighbors. Herpes simplex virus type 1 (HSV-1) establishes lifelong latency in the infected host. Latency repression of viral genes extends to foreign genes incorporated into the viral genome. We report here a test of the hypothesis that MAR elements, flanking a foreign gene in the HSV-1 genome, would act to insulate it from latency repression, achieving long-term expression. A recombinant virus was produced which has an expression construct inserted into the HSV-1 genome at the Us3 locus. The expression construct consists of the A MAR element on one flank, an HIV-LRT driving the lacZ gene and the B MAR element on the other flank. The A MAR element is a 3 kb pair fragment of the 5' portion of the chicken lysozyme gene and the B MAR element is a 2.6 kb pair fragment from the 5' end of the human beta-globin gene locus control region. The LTR is derived from a human immunodeficiency virus isolated from the brain of an AIDS patient. Virus was stereotactically injected in the hippocampus, olfactory bulb and striatum of rat brains. Intense blue reaction product indicating beta-galactosidase activity was found in cells in each injected area at 2 days after injection. At 14 days after injection beta-galactosidase activity was no longer detected at any of the injected sites. We conclude that the MAR element construct did not escape latency repression.

[SLS--a new type of polynucleotide chain folding]. / SLS--novyi tip ukladki polinukleotidnoi tsepi.

Short tandem repeats (5-8 base pairs) are not uncommon in the prokaryotic and eukaryotic DNA. Regions with such sequence motifs, when under superhelical stress, manifest unusual sensitivity to single-strand specific nuclease. To explain this, it has been suggested that one DNA thread should be shifted relatively to another, so that they could form two single-stranded loops protruding from the opposite chains and separated on the DNA helix by the length of a direct repeat. The structure was proposed to play a role in the regulation of transcription, organization of chromatin and in the recombination. Such type of folding could have been extra-stabilized by base pairing between the loops. This attractive possibility of the interloop minihelix formation requires a delicate stereochemical analysis and direct experimental support. Formation of the interloop minihelix in the Slipped Loop Structure (SLS) was tested by a chemical modification method at one nucleotide level resolution. The results show that bases located within the proposed interloop helix are well protected from the probes used. This fact encourages us to publish a 3-D model for the SLS-form DNA (and RNA). The SLS is characterized by a remarkable symmetry having three mutually perpendicular dyad axes. Scanning the bank of nucleotide sequences has revealed more than 500 sites, the transcripts of which are capable of folding into the SLS form, which allow us to regard the SLS form as a novel universal structural form. Remarkably, the abundance of SLS in intrones three times exceeds that of the coding sequences. This may reflect a functional role (or roles) of the SLS conformation.