2-Nitro-5-Thiosulfobenzoic Acid as a Novel Inhibitor Specific for Deoxyribonuclease I

Screening of deoxyribonuclease I inhibitors from autodisplayed Fv-antibody library

Deoxyribonuclease (DNase) I inhibitors have been developed based on proteins, nucleotides and synthetic compounds. In this work, amino acid sequences with the activity of DNase I inhibitor were screened from an Fv-antibody library expressed on the outer membrane of Escherichia coli. The Fv-antibody indicated the heavy chain variable region (VH) of immunoglobulin G (IgG) and the Fv-antibody library was generated with a randomized complementarity-determining region 3 (CDR3). From the Fv-antibody library, two clones were screened for their binding affinity to DNase I and expressed as soluble recombinant proteins as well as peptides. The binding affinity (KD) to DNase I was estimated for the expressed Fv-antibodies (73.4 nM for Fv-1 and 89.0 nM for Fv-19) and synthesized peptides (279.2 nM for Peptide-1 and 243.2 nM for Peptide-19) using SPR biosensor. The inhibitory activity (IC50) of the expressed Fv-antibodies (550.0 nM for Fv-1 and 660.2 nM for Fv-19) and synthetic peptides (864.5 nM for Peptide-1 and 974.6 nM for Peptide-19) was measured using agarose-gel assay and TaqMan-like fluorescence assay. These IC50 values indicated that both expressed Fv-antibodies and synthesized peptides exerted an effective inhibitory activity against DNase I. The interaction between the screened inhibitors and DNase I was analyzed by docking simulation.

Novel high-throughput deoxyribonuclease 1 assay

Deoxyribonuclease I (DNase I), the most active and abundant apoptotic endonuclease in mammals, is known to mediate toxic, hypoxic, and radiation injuries to the cell. Neither inhibitors of DNase I nor high-throughput methods for screening of high-volume chemical libraries in search of DNase I inhibitors are, however, available. To overcome this problem, we developed a high-throughput DNase I assay. The assay is optimized for a 96-well plate format and based on the increase of fluorescence intensity when fluorophore-labeled oligonucleotide is degraded by the DNase. The assay is highly sensitive to DNase I compared to other endonucleases, reliable (Z' ≥ 0.5), and operationally simple, and it has low operator, intraassay, and interassay variability. The assay was used to screen a chemical library, and several potential DNase I inhibitors were identified. After comparison, 2 hit compounds were selected and shown to protect against cisplatin-induced kidney cell death in vitro. This assay will be suitable for identifying inhibitors of DNase I and, potentially, other endonucleases.

Deoxyribonuclease inhibitors

Deoxyribonucleases (DNases) are a class of enzymes able to catalyze DNA hydrolysis. DNases play important roles in cell function, while DNase inhibitors control or modify their activities. This review focuses on DNase inhibitors. Some DNase inhibitors have been isolated from various natural sources, such as humans, animals (beef, calf, rabbit and rat), plants (Nicotiana tabacum), and microorganisms (some Streptomyces and Adenovirus species, Micromonospora echinospora and Escherichia coli), while others have been obtained by chemical synthesis. They differ in chemical structure (various proteins, nucleotides, anthracycline and aminoglycoside antibiotics, synthetic organic and inorganic compounds) and mechanism of action (forming complexes with DNases or DNA). Some of the inhibitors are specific toward only one type of DNase, while others are active towards two or more. Physico-chemical properties of DNase inhibitors are calculated using the Molinspiration tool and most of them meet all criteria for good solubility and permeability. DNase inhibitors may be used as pharmaceuticals for preventing, monitoring and treating various diseases.

Dead cell counts during serum cultivation are underestimated by the fluorescent live/dead assay

The live/dead fluorescent assay provides a quick method for assessing the proportion of live and dead cells in cell culture systems or tissues and is widely used. Dead cells are detected by the fluorescence produced when propidium iodide (PI) binds to DNA; PI and similar molecules are excluded from live cells but can penetrate dead cells because of their loss of membrane integrity. Here we investigated the effect of serum in the culture medium on the reliability of the method. We assessed viability of chondrocytes with/without serum using both a live/dead assay kit and also trypan blue staining. We found that after 2 days of culture, the DNA-binding dye PI could no longer detect dead cells if serum was present but they were readily detected in serum-free medium or if an inhibitor to DNase I was added to the serum-containing medium. Dead cells could be detected by trypan blue staining in all cultures. Hence dead cells are no longer detected as the DNase I present in serum degrades their DNA. DNA-binding dyes may thus not give a reliable estimate of the number of dead cells in systems that have been cultured in the presence of serum for several days.