Oligomerization reactions of deoxyribonucleotides on montmorillonite clay: The effect of mononucleotide structure,phosphate activation and montmorillonite composition on phosphodiester bond formation

2-d-5-GMP and 2-d-5-AMP bind 2 times more strongly to montmorillonite 22A than do 2-d-5-CMP and 5-TMP. The dinucleotide d(pG)₂ forms in 9.2% yield and the cyclic dinucleotide c(dpG)₂ in 5.4% yield in the reaction of 2-d-5-GMP with EDAC in the presence of montmorillonite 22A. The yield of d(pC)₂ (2.0%) is significantly lower but comparable to that obtained from 5-TMP. The yield of dimers which contain the phosphodiester bond decreases as the reaction medium is changed from 0.2 M NaCl to a mixture of 0.2 M NaCl and 0.075 M MgCl₂. A low yield of d(pA)₂ was observed in the condensation reaction of 5-ImdpA on montmorillonite 22A. The cyclic nucleotide (3,5-cdAMP) was obtained in 14% yield from 3-ImdpA. The yield of d(pA)₂ obtained when EDAC is used as the condensing agent increases with increasing iron content of the Na⁺-montmorillonite used as catalyst. Evidence is presented which shows that the acidity of the Na⁺-montmorillonite is a necessary but not sufficient factor for the montmorillonite catalysis of phosphodiester bond formation.     

Oligomerization reactions of ribonucleotides: The reaction of the 5′-phosphorimidazolide of nucleosides on montmorillonite and other minerals

The reaction of ImpA in the presence of Na⁺-montmorillonite 22A or Na⁺-Volclay in aqueous, pH 8 solution gives a 50–60% yield of dimers and trimers (pA)₂ and (pA)₃. The ratio of 3,5-phosphodiester bond formation is twice as great as 2,5-bond formation. The reaction requires the presence of Mg²⁺ and is inhibited by 0.4 M imidazole. N-methylimidazole enhances the rate of the reaction but does not cause major changes in yield or product composition. Higher yields were obtained when Li⁺- or Ca²⁺-montmorillonites were used in place of Na⁺-montmorillonite. Little or no phosphodiester bond formation was observed with Mg²⁺- or Al³⁺-montmorillonite. Montmorillonites other than 22A and Volclay exhibited little or no catalysis. In addition, little or no catalysis was exhibited in ferrugenous smectite, nontronite, allophane, imogolite or sepiolite. Oligomers were also formed by the reaction of ImpG, 2-methylImpG, ImpC and ImpU in the presence of Na⁺-montmorillonite. The pyrimidine nucleotides gave significantly lower yields of oligomers.     

Enhanced transfection efficiency of a systemically delivered tumor-targeting immunolipoplex by inclusion of a pH-sensitive histidylated oligolysine peptide

Successful cancer gene therapy depends on the development of non-toxic, efficient, tumor cell- specific systemic gene delivery systems. Our laboratory has developed a systemically administered, ligand–liposome complex that can effectively and preferentially deliver its therapeutic payload to both primary and metastatic tumors. To further improve the transfection efficiency of this targeting complex, a synthetic pH-sensitive histidylated oligolysine K[K(H)KKK]₅-K(H)KKC (HoKC), designed to aid in endosomal escape and condensation of DNA, was included in the complex. The presence of HoKC increased the in vitro transfection efficiency over that of the original complex. Moreover, no increase in cytotoxicity was observed due to the presence of the HoKC peptide. In a DU145 human prostate cancer xenograft tumor model in athymic nude mice, inclusion of the HoKC peptide did not interfere with the tumor targeting specificity of the i.v. administered ligand/liposome/DNA complex. Most importantly, the level of transgene expression was significantly elevated in the tumors, but not in the normal tissue in those animals receiving the complex incorporating HoKC. The in vivo enhancement of transfection efficiency by this modified gene delivery vehicle could lead to a reduction in the number of administrations required for antitumor efficacy.     

Lack of an association between candidate gene loci and idiopathic generalized epilepsy in Kuwaiti Arab children

Summary Idiopathic generalized epilepsies (IGEs) are the most common types of epilepsy in childhood and adolescence. A variety of data suggest that IGEs have a predominant genetic etiology. Recently, a number of gene mutations have been found to be associated with various types of epilepsy in mainly the Caucasian populations. The objective of this study was to investigate the association of three different candidate genes with IGE in Kuwaiti Arab children. This study includes 123 Kuwaiti patients with a confirmed diagnosis of epilepsy. Most of the patients have had a diagnostic EEG with generalized spike-wave discharges (GSWs). All patients were evaluated by using a validated seizure questionnaire. The clinical type of epilepsy was determined by a trained neurologist/pediatrician. The study also include 100 controls, the control subjects were children which did not have any history of neurological disorders. Blood samples were collected from all patients and control subjects after taking informed consent. DNA was isolated and analyzed by molecular methods. A FokI polymorphism in neuronal nicotinic acetylcholine receptor alpha-4 subunit (CHRNA4) gene was detected by PCR-RFLP method. A missense mutation (Ser248Phe) in CHRNA4 gene was analyzed by PCR-RFLP using HpaII. A C121W mutation in sodium-channel beta-1 subunit (SCN1B) gene was screened by a PCR-RFLP method using HinPI. A 2-bp deletion in Cystatin B gene was detected by PCR-RFLP using XcmI. The incidence of three FokI polymorphism genotypes in Kuwaiti IGE patients was 1,1 (85%), 1,2 (14%) and 2,2 (1%) respectively. The missense mutation Ser248Phe of CHRNA4 gene was not detected at all in Kuwaiti IGE patients. The C387G transversion resulting in C121W change in third exon of the SCN1B gene was detected in 3/123 patients (2%). The patients carrying this mutation also exhibited febrile seizures. The incidence of 2 bp deletion in the cystatin B gene was found to be 4% (5/123 IGE patients). The data obtained from molecular analysis show a lack of association between three candidate genes and clinical expression of IGE in Kuwaiti Arab children. This is completely different from the findings reported from Caucasian populations of France, Australia and USA in which case a strong association has been reported between IGE and these genes. To whom corresspondence should be addressed. Tel: +965-5319486; Fax: +965-5338940; E-mail: haider@hsc.edu.kw     

Mineral catalysis of the formation of dimers of 5′-AMP in aqueous solution: The possible role of montmorillonite clays in the prebiotic synthesis of RNA

The reaction of the 5-AMP with water soluble carbodiimide (EDAC) in the presence of Na⁺-montmorillonite 22A results in the formation of 2,5-(pA)₂ (18.9%), 3,5-(pA)₂ (11%), and AppA (4.8%). When poly(U) is used in place of the clay the product yields are 2,5-(pA)₂ (15.5%), 3,5-(pA)₂ (3.7%) and AppA (14.9%). The 3,5-cyclic dinucleotide, 3,5-c(pA)₂, is also formed when poly(U) is used. AppA is the principal reaction product when neither clay nor poly(U) is present in the reaction mixture. Products which contain the phophodiester bond are formed at different ionic strengths, pH and temperatures using Na⁺-montmorillonite. Phosphodiester bond formation was not observed when Cu²⁺-montmorillonite was used or when DISN was used in the place of EDAC. The extent catalysis of phophodiester bond formation varied with the particular clay mineral used. Those Na⁺-clays which bind 5-AMP more strongly are better catalysts. Cu²⁺-montmorillonite, which binds 5-AMP strongly, exhibits no catalytic activity.     

N–O bond cleavage mechanism(s) in nitrous oxide reductase

Quantum chemical calculations of active-site models of nitrous oxide reductase (N(2)OR) have been undertaken to elucidate the mechanism of N-O bond cleavage mediated by the supported tetranuclear Cu(4)S core (Cu(Z)) found in the enzymatic active site. Using either a minimal model previously employed by Gorelsky et al. (J. Am. Chem. Soc. 128:278-290, 2006) or a more extended model including key residue side chains in the active-site second shell, we found two distinct mechanisms. In the first model, N(2)O binds to the fully reduced Cu(Z) in a bent μ-(1,3)-O,N bridging fashion between the Cu(I) and Cu(IV) centers and subsequently extrudes N(2) while generating the corresponding bridged μ-oxo species. In the second model, substrate N(2)O binds loosely to one of the coppers of Cu(Z) in a terminal fashion, i.e., using only the oxygen atom; loss of N(2) generates the same μ-oxo copper core. The free energies of activation predicted for these two alternative pathways are sufficiently close to one another that theory does not provide decisive support for one over the other, posing an interesting problem with respect to experiments that might be designed to distinguish between the two. Effects of nearby residues and active-site water molecules are also explored.