Aryldiazomethane Derivatives as Reagents for Site Specific Labeling of Nucleic Acids at Phosphate

Abstract

An efficient and direct labeling method based on direct alkylation of nucleic acids at phosphates by aryldiazomethane derivatives is described.     

Synthesis and Anti-Hiv Activity of 4′-Modified Cyclopentenyl Pyrimidine C-Nucleosides

Novel syntheses of 4′-modified cyclopentenyl pyrimidine C-nucleosides were performed via C-C bond formation using S_N2 alkylation via the key intermediate mesylates 6 and 16, which were prepared from acyclic ketone derivatives. When antiviral evaluation of synthesized compound was performed against various viruses such as HIV-1, HSV-1 and HSV-2, isocytidine analogue 20 showed moderate anti-HIV activity in CEM cell line (EC₅₀ = 13.1 μmol).7     

N- versus O-alkylation: Utilizing NMR methods to establish reliable primary structure determinations for drug discovery

A classic synthetic issue that remains unresolved is the reaction that involves the control of N- versus O-alkylation of ambident anions. This common chemical transformation is important for medicinal chemists, who require predictable and reliable protocols for the rapid synthesis of inhibitors. The uncertainty of whether the product(s) are N- and/or O-alkylated is common and can be costly if undetermined. Herein, we report an NMR-based strategy that focuses on distinguishing inhibitors and intermediates that are N- or O-alkylated. The NMR strategy involves three independent and complementary methods. However, any combination of two of the methods can be reliable if the third were compromised due to resonance overlap or other issues. The timely nature of these methods (HSQC/HMQC, HMBC. ROESY, and ¹³C shift predictions) allows for contemporaneous determination of regioselective alkylation as needed during the optimization of synthetic routes.     

Inhibition of DNA alkylation damage with inorganic salts

Human exposure to alkylating agents metabolized from tobacco- and food-borne carcinogens occurs regularly. Dietary inorganic compounds such as selenium and vanadium have been shown previously to provide chemoprotective benefits in rat and human trials. Here, we present biochemical data on the ability of inorganic compounds to protect DNA from alkylation damage. An enzyme cleavage assay is used to observe alkylated DNA. Simple salts (e.g., NaCl or NiCl₂) did not prevent DNA alkylation, whereas anionic oxo species (e.g., Na₂SeO₄ or Na₃VO₄) did inhibit alkylation. We propose that these oxo species behave as nucleophilic targets for the electrophilic alkylating agents, thereby preventing DNA damage.     

Chemical-modification rescue assessed by mass spectrometry demonstrates that gamma-thia-lysine yields the same activity as lysine in aldolase

The role of active site residues in fructose 1,6-bisphosphate aldolase is investigated by chemical-modification rescue. An active-site mutation, K107C, is constructed in a background where the four solvent-accessible cysteine residues are converted to alanine. The resulting mutant, tetK107C, when reacted with bromoethylamine (BrEA), shows a 40-fold increase in activity (to 80% that of wild type). Determination of the sites and their degree of modification using electrospray ionization Fourier transform mass spectrometry (ESI-FTMS) is developed, allowing correlation of activity after chemical modification rescue to the degree of modification. The stoichiometry of the reaction is 2.5 aminoethylations per subunit, as measured by ESI-FTMS. Protein modification with a double-labeled mix (1:1) of natural abundance isotope (d(0)-BrEA) and 2-bromoethyl-1,1,2,2-d4-amine hydrobromide (d(4)-BrEA), followed by dialysis and trypsin digestion, shows aminoethylated peptides as "twin peptides" separated by four mass units in ESI-FTMS analysis. Using this detection procedure under nondenaturing (native) conditions, C107 is aminoethylated, whereas the four buried thiols remain unlabeled. Aminoethylation of other residues is observed, and correlates with those peptides containing histidine, methionine, and/or the amino terminus. Quantification of the aminoethylation reaction is achieved by labeling with nondeuterated d(0)-BrEA under denaturing conditions following double labeling under native conditions. In addition to complete labeling all five thiols, the intensity of the d(0)-BrEA peak for C107 containing peptides increases, and the change in the d(0)/d(4) ratio between native and denaturing conditions shows 82 +/- 4.5% aminoethylation at C107. This correlation of modification with the recovered activity, indicates that gamma-thia-lysine replaces lysine in the catalytic mechanism. Kinetic constants measured for the rescued K107C mutant enzyme with the substrates fructose 1-phosphate and fructose 1,6-bisphosphate are consistent with the role of the positively charged lysine binding to the C6-phosphate. ESI-FTMS, combined with this double-labeling procedure, allows precise identification of sites and measurement of degree of protein modification.     

SN2 DNA-alkylating agent-induced phosphorylation of p53 and activation of p21 gene expression

p53 is an important player in the cellular response to genotoxic stress whose functions are regulated by phosphorylation of a number of serine and threonine residues. Phosphorylation of p53 influences its DNA-binding and gene regulation activities. This study examines p53 phosphorylation in HCT-116 (MMR-deficient) and HCT-116+ch3 (MMR-proficient) human colon cancer cells treated with a S(N)2 DNA-alkylating agent, methylmethane sulfonate (MMS). MMS induces phosphorylation of p53 on Ser15 and Ser392 in a dose- and time-dependent manner. MMS-induced p53 phosphorylation is independent of DNA mismatch repair (MMR) activity. Nuclear extracts from MMS-treated HCT-116 cells had higher p21WAF1/Cip1 (p21) promoter DNA-binding activity in vitro opposed to untreated cells. After MMS treatment, the activation of the cloned p21 promoter in a transient transfection assay and endogenous p21 mRNA levels in HCT-116(p53+/+) versus HCT-116(p53-/-) cells increased, which correlates with an increased levels of phospho-p53(Ser15) and phospho-p53(Ser392). These results suggest that SN2 DNA-alkylating agent-induced phosphorylation of p53 on Ser15 and Ser392 increases its DNA-binding properties to cause an increased expression of p21 that may play a role in cell cycle arrest and/or apoptosis of HCT-116 cells.     

Synthesis of orthogonally protected vicinal diamines with amino acid-based skeleton

A convenient route to amino acid-based orthogonally protected 1,2-diamines starting from materials readily available for a peptide chemist is presented. The key step of the procedure is the Mitsunobu reaction of N-protected aminoalcohol, obtained by the reduction of commercially available Z- or Boc-protected amino acid, with imidodicarbonate or sulfonylcarbamate related to standard amino-protecting groups used in peptide chemistry yielding triprotected vicinal diamines.     

Visual methods for the nanomolar detection of electrophilic reagents

A series of highly colored nitrophenolates and nitrothiophenolates has been tested as spray reagents for the detection of electrophilic species of the types commonly used in peptide and protein chemistry. Sensitive TLC detection of agents for alkylation, acylation, sulfonylation and phosphorylation was demonstrated. In addition, the thiophenolate sprays were sensitive for oxidizing agents in nanomolar quantities. Selective TLC detection of acylating and phosphorylating agents was accomplished by subsequent alkali treatment resulting in the restoration of color.