Sarah N. McCurdy

The investigation of the three-dimensional structure of the DNA aptamer d(G1G2T3-T4G5G6T7G8T9G10G11T12T13G14G15) which binds to and inhibits thrombin has been carried out by NMR methods. This DNA exhibits a number of long-range NOEs between residues which are not adjacent in sequence, which allowed the determination of the novel tertiary structure adopted. This DNA adopts a highly compact, highly symmetrical structure which consists of two tetrads of guanosine base pairs and three loops. The residues of the tetrads alternate anti-syn-anti-syn. This novel structural motif for DNA may also be relevant to the structure of telomere DNA.

A new class of thrombin inhibitors based on sequence-specific single-stranded DNA oligonucleotides (thrombin aptamer) has recently been identified. The aptamer-binding site on thrombin was examined by a solid-phase plate binding assay and by chemical modification. Binding assay results demonstrated that the thrombin aptamer bound specifically to alpha-thrombin but not to gamma-thrombin and that hirudin competed with aptamer binding, suggesting that thrombin's anion-binding exosite was important for aptamer-thrombin interactions. To identify lysine residues of thrombin that participated in the binding of the thrombin aptamer, thrombin was modified with fluorescein 5'-isothiocyanate in the presence or absence of the thrombin aptamer, reduced, carboxymethylated, and digested with endoproteinase Arg-C. The digestion products were analyzed by reversed-phase high performance liquid chromatography and the peptide maps compared. Four peptides with significantly decreased modification in the presence of the aptamer were identified and subjected to N-terminal sequence analysis. Results indicated that B chain Lys-21 and Lys-65, both located within the anion-binding exosite, are situated within or in close proximity to the aptamer-binding site of human alpha-thrombin. The thrombin aptamer binds to the anion-binding exosite and inhibits thrombin's function by competing with exosite binding substrates fibrinogen and the platelet thrombin receptor.

Despite the global importance of As in rice, research has primarily focused on Bangladesh, India, China, and the United States with limited attention given to other countries. Owing to both indigenous As within the soil and the possible increases arising from the onset of irrigation with groundwater, an assessment of As in rice within Cambodia is needed, which offers a "base-case" comparison against sediments of similar origin that comprise rice paddy soils where As-contaminated water is used for irrigation (e.g., Bangladesh). Here, we evaluated the As content of rice from five provinces (Kandal, Prey Veng, Battambang, Banteay Meanchey, and Kampong Thom) in the rice-growing regions of Cambodia and coupled that data to soil-chemical factors based on extractions of paddy soil collected and processed under anoxic conditions. At total soil As concentrations ranging 0.8 to 18 μg g(-1), total grain As concentrations averaged 0.2 μg g(-1) and ranged from 0.1 to 0.37 with Banteay Meanchey rice having significantly higher values than Prey Veng rice. Overall, soil-extractable concentrations of As, Fe, P, and Si and total As were poor predictors of grain As concentrations. While biogeochemical factors leading to reduction of As(V)-bearing Fe(III) oxides are likely most important for predicting plant-available As, husk and straw As concentrations were the most significant predictors of grain-As levels among our measured parameters.

Triple-helix formation by oligodeoxynucleotides in a sequence-specific manner is limited to polypurine tracts of duplex DNA. To increase the number of biologically relevant targets for triple-helix formation, we have utilized oligodeoxynucleotides containing a 3'-3' internucleotide junction to allow for binding to opposite strands of duplex DNA. Molecular modeling was used to aid in the design of the xylose dinucleoside linker 1 that is rigid and minimizes the number of conformers to minimize the entropy of binding. Thermal denaturation studies show that a 3'-3'-linked oligodeoxynucleotide, bearing nine nucleotides on each side of the linker, has a higher Tm (47.6 degrees C) than that of a 21-mer binding to a single polypurine tract (45.3 degrees C). Binding domain minimization studies and sequence-specific alkylation of a target duplex demonstrate a high degree of cooperativity between the two triple-helix binding domains, thus allowing for an increase in the number of biologically relevant targets for triple-helix formation.