An Alternate Process for the Solid-Phase Synthesis and Solid-Phase Purification of Synthetic Nucleic Acid Sequences.

The chemical synthesis of a riboside phosphoramidite has been achieved to provide a 5-O-capture linker and a 2-O-silyl ether protecting group with the intent of enabling an efficient solid-phase purification of synthetic DNA sequences. The riboside phosphoramidite has been incorporated into a DNA sequence while performing the penultimate automated solid-phase synthesis cycle of the sequence. The terminal 5-O-riboside moiety of the resulting DNA sequence is then conjugated to a capture linker to create an anchor for the solid-phase purification of the DNA sequence conjugate. Release of all DNA sequences from the synthesis support is achieved under standard basic conditions to yield a mixture of the desired DNA sequence conjugate along with unconjugated, shorter-than-full-length sequence contaminants. Upon exposure of all DNA sequences to a capture solid support, only the DNA sequence conjugate is chemoselectively captured, thereby allowing the unconjugated shorter-than-full-length DNA sequences to be efficiently washed away from the capture support. After 2-O-cleavage of the silyl ether protecting group from the terminal riboside ethylphosphate triester conjugate, the solid-phase-purified DNA sequence is efficiently released from the capture support through an innovative intramolecular cyclodeesterification of the ethylphosphate triester, prompted by the riboside's rigid cis-diol conformer, to provide a highly pure DNA sequence. Published 2023. This article is a U.S. Government work and is in the public domain in the USA. Basic Protocol 1: Preparation of 5-O-(4,4'-dimethoxytrityl)-2-O-tert-butyldimethylsilyl-1,4-anhydro-D-ribitol (3) Basic Protocol 2: Preparation of 5-O-(4,4'-dimethoxytrityl)-2-O-tert-butyldimethylsilyl-3-O-[(N,N-diisopropylamino)ethyloxyphosphinyl]-1,4-anhydro-D-ribitol (6). Basic Protocol 3: Automated synthesis of the chimeric solid-phase-linked DNA sequence 8. Support Protocol: Preparation of 2-cyanoethyl-(5-oxohexyl)-N,N-diisopropylphosphoramidite (9). Basic Protocol 4: Solid-phase purification of the chimeric DNA sequence 10.

Use of Arabinonucleosides for Development and Implementation of a Novel 2'-O-Protecting Group for Efficient Solid-Phase Synthesis and 2'-O-Deprotection of RNA Sequences.

The implementation of protecting groups for 2'-hydroxyl function of ribonucleosides is very demanding in that synthetic RNA sequences must be highly pure to ensure the safety and efficacy of nucleic acid-based drugs for treatment of human diseases. A synthetic approach consisting of a condensation reaction between 2'-O-aminoribonucleosides with ethyl pyruvate has been employed to provide stable 2'-O-imino-2-methyl propanoic acid ethyl esters. Conversion of these esters to fully protected ribonucleoside phosphoramidite monomers has allowed rapid and efficient incorporation of 2'-O-protected ribonucleosides into RNA sequences while minimizing the formation of process-related impurities during solid-phase synthesis. Two chimeric 20-mer RNA sequences have been synthesized and then exposed to a solution of sodium hydroxide to saponify the 2'-O-imino-2-methyl propanoic acid ethyl ester protecting groups to their sodium salts. When subjected to ion-exchange conditions at 65°C and near neutral pH, fully deprotected RNA sequences are isolated without production of alkylating side-products and/or formation of mutagenic nucleobase adducts. © 2022 Wiley Periodicals LLC. This article has been contributed to by US Government employees and their work is in the public domain in the USA. Basic Protocol 1: Synthesis of uridine 2'-O-imino-2-propanoic acid ethyl ester and its fully protected 3'-O-phosphoramidite Basic Protocol 2: Synthesis of N6 -protected adenosine 2'-O-imino-2-propanoic acid ethyl ester and its fully protected 3'-O-phosphoramidite Basic Protocol 3: Synthesis of N4 -protected cytidine 2'-O-imino-2-propanoic acid ethyl ester and its fully protected 3'-O-phosphoramidite Basic Protocol 4: Synthesis of N2 -protected guanosine 2'-O-imino-2-propanoic acid ethyl ester and its fully protected 3'-O-phosphoramidite Basic Protocol 5: Automated solid-phase RNA synthesis and deprotection using 2'-O-imino-2-proponate-protected phosphoramidites.

An Improved PEG-Linked Solid Support for Minimizing Process-Related Impurities During Solid-Phase Synthesis of DNA and RNA Sequences.

The preparation of controlled pore glass (CPG) supports, functionalized with several hexaethylene glycol spacers, to alleviate the problems associated with the porosity of commercial CPG supports is described in this article. The pore size of CPG restricts the diffusion of reagents to the leader nucleoside embedded in porous supports; this inhibits efficient solid-phase syntheses of DNA and RNA sequences and, by default, the purity of those sequences through formation of a shorter than full-length oligonucleotide. Functionalization of a CPG support with five hexaethylene glycol spacers led to a 42% reduction in process-related impurities contaminating oligonucleotide sequences, compared to that obtained using the commercial long-chain alkylamine (LCAA) CPG support. © 2021 Wiley Periodicals LLC. This article has been contributed to by US Government employees and their work is in the public domain in the USA. Basic Protocol 1: Preparation of the hydroxylated CPG support 3 Basic Protocol 2: Automated preparation of the CPG support 6 Basic Protocol 3: Automated preparation of the poly(hexaethylene glycol)-derived CPG 7 Basic Protocol 4: Automated functionalization of the poly(hexaethylene glycol)-derived CPG support 7 with leader deoxyribo- and ribonucleosides to provide the CPG support 9 Basic Protocol 5: Automated syntheses of DNA and RNA sequences on poly(hexaethylene glycol)-derived CPG support 9 and on a commercial long-chain alkylamine (LCAA) CPG support Support Protocol: Release and deprotection of the DNA and RNA sequences linked to the poly(hexaethylene glycol)-derived CPG support 10 and commercial LCAA-CPG support Basic Protocol 6: Comparative RP-HPLC analyses of crude, fully deprotected DNA or RNA sequences released from the poly(hexaethylene glycol)-derived CPG support 10 and from a commercial LCAA-CPG support.

Innovative 2'-O-Imino-2-propanoate-Protecting Group for Effective Solid-Phase Synthesis and 2'-O-Deprotection of RNA Sequences.

The implementation of protecting groups for the 2'-hydroxyl function of ribonucleosides is still challenging, particularly when RNA sequences must be of the highest purity for therapeutic applications as nucleic acid-based drugs. A 2'-hydroxyl-protecting group should optimally (i) be easy to install; (ii) allow rapid and efficient incorporation of the 2'-O-protected ribonucleosides into RNA sequences to minimize, to the greatest extent possible, the formation of process-related impurities (e.g., shorter than full-length sequences) during solid-phase synthesis; and (iii) be completely cleaved from RNA sequences without the production of alkylating side products and/or formation of mutagenic nucleobase adducts. The reaction of 2'-O-aminoribonucleosides with ethyl pyruvate results in the formation of stable 2'-O-imino-2-methyl propanoic acid ethyl esters and, subsequently, of the fully protected ribonucleoside phosphoramidite monomers, which are required for the solid-phase synthesis of two chimeric RNA sequences (20-mers) containing the four canonical ribonucleosides. Upon treatment of the RNA sequences with a solution of sodium hydroxide, the 2'-O-imino-2-methyl propanoic acid ethyl ester-protecting groups are saponified to their sodium salts, which after ion exchange underwent quantitative intramolecular decarboxylation under neutral conditions at 65 °C to provide fully deprotected RNA sequences in marginally better yields than those obtained from commercial 2'-O-tert-butyldimethylsilyl ribonucleoside phosphoramidites under highly similar conditions.

An expedient process for reducing the formation of process-related impurities during solid-phase synthesis of potential nucleic acid-based drugs.

With the intent of mitigating the formation of process-related impurities during solid-phase synthesis of DNA or RNA sequences, a hydroxylated controlled-pore glass support conjugated to three, five or seven hexaethylene glycol spacers was prepared and demonstrated to provide a more efficient and robust synthesis process. Indeed, the use of a support conjugated to five hexaethylene glycol spacers led to a 19% up to 42% reduction of process-related impurities contaminating synthetic nucleic acid sequences, when compared to that obtained from the same DNA/RNA sequences synthesized using a commercial long-chain alkylamine controlled-pore glass support under highly similar conditions.

Structural and Biological Investigations for a Series of N-5 Substituted Pyrrolo[3,2-d]pyrimidines as Potential Anti-Cancer Therapeutics.

Pyrrolo[3,2-d]pyrimidines have been studied for many years as potential lead compounds for the development of antiproliferative agents. Much of the focus has been on modifications to the pyrimidine ring, with enzymatic recognition often modulated by C2 and C4 substituents. In contrast, this work focuses on the N5 of the pyrrole ring by means of a series of novel N5-substituted pyrrolo[3,2-d]pyrimidines. The compounds were screened against the NCI-60 Human Tumor Cell Line panel, and the results were analyzed using the COMPARE algorithm to elucidate potential mechanisms of action. COMPARE analysis returned strong correlation to known DNA alkylators and groove binders, corroborating the hypothesis that these pyrrolo[3,2-d]pyrimidines act as DNA or RNA alkylators. In addition, N5 substitution reduced the EC50 against CCRF-CEM leukemia cells by up to 7-fold, indicating that this position is of interest in the development of antiproliferative lead compounds based on the pyrrolo[3,2-d]pyrimidine scaffold.

Anticancer Properties of Halogenated Pyrrolo[3,2-d]pyrimidines with Decreased Toxicity via N5 Substitution.

Halogenated pyrrolo[3,2-d]pyrimidine analogues have shown antiproliferative activity in recent studies, with cell accumulation occurring in the G2 /M stage without apoptosis. However, the mechanism of action and pharmacokinetic (PK) profile of these compounds has yet to be determined. To investigate the PK profile of these compounds, a series of halogenated pyrrolo[3,2-d]pyrimidine compounds was synthesized and first tested for activity in various cancer cell lines followed by a mouse model. EC50 values ranged from 0.014 to 14.5 µm, and maximum tolerated doses (MTD) in mice were between 5 and 10 mg kg-1 . This indicates a wide variance in activity and toxicity that necessitates further study. To decrease toxicity, a second series of compounds was synthesized with N5-alkyl substitutions in an effort to slow the rate of metabolism, which was thought to be leading to the toxicity. The N-substituted compounds demonstrated comparable cell line activity (EC50 values between 0.83-7.3 µm) with significantly decreased toxicity (MTD=40 mg kg-1 ). Finally, the PK profile of the active N5-substituted compound shows a plasma half-life of 32.7 minutes, and rapid conversion into the parent unsubstituted analogue. Together, these data indicate that halogenated pyrrolo[3,2-d]pyrimidines present a promising lead into potent antiproliferative agents with tunable activity and toxicity, and rapid metabolism.

Antiproliferative activities of halogenated pyrrolo[3,2-d]pyrimidines.

In vitro evaluation of the halogenated pyrrolo[3,2-d]pyrimidines identified antiproliferative activities in compounds 1 and 2 against four different cancer cell lines. Upon screening of a series of pyrrolo[3,2-d]pyrimidines, the 2,4-Cl compound 1 was found to exhibit antiproliferative activity at low micromolar concentrations. Introduction of iodine at C7 resulted in significant enhancement of potency by reducing the IC50 into sub-micromolar levels, thereby suggesting the importance of a halogen at C7. This finding was further supported by an increased antiproliferative effect for 4 as compared to 3. Cell-cycle and apoptosis studies conducted on the two potent compounds 1 and 2 showed differences in their cytotoxic mechanisms in triple negative breast cancer MDA-MB-231 cells, wherein compound 1 induced cells to accumulate at the G2/M stage with little evidence of apoptotic death. In contrast, compound 2 robustly induced apoptosis with concomitant G2/M cell cycle arrest in this cell model.

Distribution of methylone in four postmortem cases.

Drugs derived from amphetamine, methamphetamine and their methylenedioxy- analogues, although being sold as plant food or bath salts, are being used as legal alternatives to scheduled amphetamine stimulants. These products often contain methylone, mephedrone and methylenedioxypyrovalerone (MDPV)--three amphetamine derivatives shown to have strong pharmacological effects. Four postmortem cases were analyzed for methylone, mephedrone and MDPV, with drug levels quantitated in multiple biological matrices. All four cases had detectable levels of methylone, with heart blood concentrations of 0.740, 0.118, 0.060 and 1.12 mg/L. Analysis of several tissue samples shows that methylone does not sequester in a particular tissue type after death. The average liver-to-blood ratio was 2.68. Two cases also had MDPV present, but insufficient data were collected to formulate a hypothesis on postmortem sequestration or redistribution. Two different extraction methods, as well as analysis of derivatized and underivatized methylone, show that the drug is suitable for analysis in either method. The cases are believed to show one instance of chronic methylone use, with a urine concentration of 38 mg/L.

Dimethylamylamine: a drug causing positive immunoassay results for amphetamines.

The Department of Defense (DoD) operates six forensic urine drug-testing laboratories that screen close to 5 million urine samples for amphetamines yearly. Recently, the DoD laboratories have observed a significant decrease in the confirmation rates for amphetamines because of specimens screening positive by two separate immunoassays and confirming negative by gas chromatography-mass spectrometry (GC-MS). Previous studies conducted by the Division of Forensic Toxicology, Armed Force Institute of Pathology (AFIP) utilizing a GC-MS basic drug screen and a designer drug screen revealed no common compound or compound classes as to the cause of the immunoassay-positive results. Additional information obtained from an immunoassay vendor suggested the anorectic compound dimethylamylamine (DMAA) may be the cause of the false-positive screens. An additional 134 false-positive samples were received and analyzed using liquid chromatography-tandem mass spectrometry (LC-MS-MS) for DMAA. LC-MS-MS analysis revealed the presence of DMAA in 92.3% of the false-positive samples at a concentration of approximately 6.0 mg/L DMAA, causing a positive screen on both immunoassay kits.