Spectrally resolved chemiluminescent probes for sensitive multiplex molecular quantification.

Luminophores are frequently utilized probe labels for detecting biological analytes. Multiple fluorescent luminophores, or fluorophores, can be readily distinguished from one another based on different energy excitation and emission wavelengths and lifetimes. However, suitable methods and reagents for distinguishing multiples of the much more sensitive chemically initiated luminophores have been limited. Herein we describe a new class of hybrid luminophore probes that emit light of distinct wavelength ranges and intensities upon energy transfer (ET) from an in-common, acridinium ester chemiluminophore to a covalently conjugated fluorophore. This format supports rapid, rational design of spectrally resolvable, chemically initiated probes. Time-resolved spectrographic and luminescence characterizations indicate that ET is not dependent on overlap in the emission spectrum of the luminophore and the absorption spectra of acceptors, suggesting a non-Förster resonance ET mechanism. Analysis of a combination of the chemiluminophore and new chemiluminophore-acceptor conjugate probes demonstrates the benefits of their use in sensitive, multiplex quantification of nucleic acid sequences indicative of environmentally relevant microbes without prior enzymatic amplification.

Simultaneous quantification of multiple nucleic acid targets using chemiluminescent probes.

A novel method is described for simultaneous detection and quantification of attomoles or a few femtomoles of two (or potentially more) nucleic acid targets, without need for amplification. The technique depends on spectral-temporal resolution of chemiluminescence emitted from independent hybridization-induced chemiluminescent signal probes. The probes are internally quenched except in the presence of their specific targets, thereby allowing detection limits up to 10,000 times lower than with fluorescent probes. This is sufficient to obviate the need for amplification in many cases. The utility of the technique has been demonstrated by use of resolvable N-linked acridinium and 2,7-dimethoxyacridinium ester labeled probes in a homogeneous assay for sensitive and simultaneous independent quantification of pan-bacterial and pan-fungal target sequences in seawater.

Sequence-specific, self-reporting hairpin inversion probes.

Sequence-specific probes for detecting target nucleic acids are the cornerstone of the genomics revolution (e.g., microarrays) and of molecular diagnostics. Molecular beacons are self-reporting, nucleic acid probes whose structure includes complementary terminal arm sequences and a loop that is complementary to a target sequence; fluorescence detection is by changes in proximity of fluorophore and quencher pairs attached on opposite arms. However, molecular beacon design is not as simple as attaching arbitrary arm sequences onto previously designed linear probes. The stem arms can also interact with flanking target sequences, changing the hybridization specificity; constantly adapting the arms to avoid such interactions, if not desired, increases design complexity. Herein, I report the use of inversion linkages in probe backbones leading to stem arms of sequence polarity opposite to that of the target-binding region, thereby eliminating potential hybridization of the arms with the target. Using two microbial sequence categories, thermal denaturation and target titration analyses demonstrate that these new hairpin inversion probes retain closed-state stability comparable to that of molecular beacons, contain easily designed arm sequences that do not interact with targets, and, therefore, can be used universally with optimized linear probe sequences.

Metal ion-catalyzed nucleic acid alkylation and fragmentation.

Nucleic acid microarrays are a growing technology in which high densities of known sequences are attached to a substrate in known locations (addressed). Hybridization of complementary sequences leads to a detectable signal such as an electrical impulse or fluorescence. This combination of sequence addressing, hybridization, and detection increases the efficiency of a variety of genomic disciplines including those that profile genetic expression, search for single nucleotide polymorphisms (SNPs), or diagnose infectious diseases by sequencing portions of microbial or viral genomes. Incorporation of reporter molecules into nucleic acids is essential for the sensitive detection of minute amounts of nucleic acids on most types of microarrays. Furthermore, polynucleic acid size reduction increases hybridization because of increased diffusion rates and decreased competing secondary structure of the target nucleic acids. Typically, these reactions would be performed as two separate processes. An improvement to past techniques, termed labeling-during-cleavage (LDC), is presented in which DNA or RNA is alkylated with fluorescent tags and fragmented in the same reaction mixture. In model studies with 26 nucleotide-long RNA and DNA oligomers using ultraviolet/visible and fluorescence spectroscopies as well as high-pressure liquid chromatography and mass spectrometry, addition of both alkylating agents (5-(bromomethyl)fluorescein, 5- or 6-iodoacetamidofluorescein) and select metal ions (of 21 tested) to nucleic acids in aqueous solutions was critical for significant increases in both labeling and fragmentation, with >or=100-fold increases in alkylation possible relative to metal ion-free reactions. Lanthanide series metal ions, Pb(2+), and Zn(2+) were the most reactive ions in terms of catalyzing alkylation and fragmentation. While oligonucleotides were particularly susceptible to fragmentation at sites containing phosphorothioate moieties, labeling and cleavage reactions occurred even without incorporation of phosphorothioate moieties into the RNA and DNA target molecules. In fact, LDC conditions were found in which RNA could be fragmented into its component monomers, allowing simultaneous sequencing from both the 5'- and the 3'-termini by mass spectrometry. The results can be explained by alkylation of the (thio)phosphodiester linkages to form less hydrolytically stable (thio)phosphotriesters, which then decompose into 2',3'-cyclic phosphate (or 2'-phosphate) and 5'-hydroxyl terminal products. Analysis of fragmentation and alkylation products of Mycobacterium tuberculosis (Mtb) ribosomal RNA (rRNA) transcripts by polyacrylamide gel electrophoresis was consistent with the model studies. Building upon these results, I found that products from Mtb rRNA amplification products were processed with fluorescent reporters and metal ions in a single reaction milieu for analysis on an Affymetrix GeneChip. Mild conditions were discovered which balanced the need for aggressive alkylation and the need for controlled fragmentation, advantageously yielding GeneChip results with greater than 98% of the nucleotides reported correctly relative to reference sequences, results sufficient for accurately identifying Mtb from other Mycobacterium species. Thus, LDC is a new, straightforward, and rapid aqueous chemistry that is based on metal ion-catalyzed alkylation and alkylation-catalyzed fragmentation of nucleic acids for analysis on microarrays or other hybridization assays and that, possibly, has utility in similar processing of other appropriately functionalized biomolecules.