Comparison of efficacy of three commercially available antibiotic discs.

A study was undertaken to evaluate the efficacy of commercially available antimicrobial discs manufactured by Oxoid, UK, HiMedia Laboratories, Mumbai and Span Diagnostics, Surat. The discs were evaluated for their performance on the basis of percentage of coefficient of variation (%CV) which is a measure of reproducibility, mean zone diameters which is a measure of accuracy and range of zone diameter using both standard ATCC strains and clinical isolates. The data showed variation for all three manufacturers and therefore routine and regular quality control of discs as well as meticulous following of good laboratory practices is strongly advocated in clinical laboratories.

Preferential cross-linking of matrix-attachment region (MAR) containing DNA fragments to the isolated nuclear matrix by ionizing radiation.

The sequences that anchor DNA, matrix-attachment regions (MARs), can be identified by their specific and preferential binding to the nuclear matrix. This microenvironment may be hypersensitive to the formation of ionizing radiation-induced DNA damage, including DNA-protein cross-links (DPC). To examine the induction of DPC at or near MARs, we developed an in vitro binding assay by using nuclear matrices isolated from murine erythroleukemia cells by high-salt extraction of DNase I-digested nuclei. The cross-linking of nuclear matrix protein to DNA fragments containing kappa-immunoglobulin (kappa-Ig) or an hsp 70 MAR was studied. Fragments of pBR322 of similar size to the MAR-containing fragments served as non-MAR controls. Two types of experiments were conducted: type A in which nuclei were irradiated and nuclear matrices were isolated and assayed for the binding of exogenous 32P-labeled DNA fragments, and type B in which mixtures of isolated nuclear matrices and [32P]DNAs were irradiated and assayed for binding. Poly(dAT) served as a competitor in the binding assays, because it eliminated nonspecific binding of DNA to the nuclear matrix and revealed the radiation-induced increase in tightly bound DNA. When nuclear matrices were isolated from irradiated nuclei (0-200 Gy) and incubated with the kappa-Ig MAR fragment in the absence of poly(dAT) (type A experiments), much nonspecific, non-dose-dependent binding was observed. With poly(dAT) in the incubation mixture, a dose-dependent decrease (p < 0.001) in the binding was revealed, indicating a radiation-induced loss of available binding sites, perhaps due to the cross-linking of endogenous sequences. The pBR322 fragment did not show a similar loss of binding sites. Irradiation of mixtures of isolated nuclear matrices and end-labeled fragments (type B experiments) allowed the study of radiation-induced cross-linking of exogenous fragments to the matrices. If poly(dAT) was present during irradiation, nonspecific binding was eliminated; however, no significant increase (p = 0.5) in the specific binding of the DNA to the nuclear matrix was observed. In contrast, if poly(dAT) was added after irradiation, in addition to the elimination of nonspecific binding, a radiation dose-dependent increase in binding was revealed for both the kappa-Ig MAR and the hsp MAR (p < 0.001), but not for either of the pBR322 fragments. The results indicate that the specific interaction of MARs with proteins of the nuclear matrix provides a radiation-sensitive substrate for the formation of DNA-protein cross-links.

Nuclear structure and the microdistribution of radiation damage in DNA.

Evidence for the roles of proteins and metal ions in the microheterogeneity of DNA damage is reviewed. Decondensation of chromatin in hypotonic buffers markedly sensitizes the DNA to radiation, while treatment of nuclei with hypertonic buffers strips the DNA of histones and other nuclear proteins and enhances the radiosensitivity of the DNA with respect to double-strand break (dsb) formation. Addition of the radical scavenger DMSO reduces the yield of strand breaks, but dehistonized chromatin remains approximately 2.5 times more sensitive to radiation than does native chromatin at 0.1 M DMSO. DNA-protein crosslink (DPC) formation is relatively unaffected by the removal of the majority of histones from chromatin. Most DPC form at or near the nuclear matrix, and matrix is stabilized and radiosensitized by Cu++. To elucidate the role of Cu++, the induction of dsb and DPC by gamma-radiation has been compared with that by hydroxyl radical from Fe(++)-EDTA, or Cu++ catalysed Fenton reactions. Data comparing the size of DNA fragments produced, the effect of expanding or dehistonizing chromatin, and the effects of radical scavengers suggest that gamma-radiation and Fe(++)-EDTA produce dsb at open chromatin sites, whereas Cu(++)-generated dsb are similar to radiation-induced DPC in their location at the nuclear matrix. Both metal ions appeared to produce damage by site-specific generation of hydroxyl radicals. The nuclear matrix, the proteinaceous skeleton which anchors chromosomal loops and provides sites for DNA replication and transcription, binds metal ions and matrix-attachment DNA regions (MARs) consisting of 300 + bp of AT-rich DNA. The interaction of cloned MARs with isolated nuclear matrices has been found to be hypersensitive to crosslinking upon gamma-irradiation, in comparison with associations formed by similarly sized DNA fragments lacking MAR sequences. Thus, the non-random distribution of radiation damage is partially explained by the protection of DNA afforded by histones and chromatin structure and partially by the hypersensitivity of DNA-nuclear matrix associations.