Addressable bipartite molecular hook (ABMH): immobilized hairpin probes with sensitivity below 50 fM.

Sensitivity and specificity of nucleic acid binding probes immobilized on solid supports are essential features of microarrays. Whereas conventional biochips apply nonquenched linear probes (cDNA, oligonucleotides), hairpin structures containing a fluorophore-quencher system comprise important prerequisites required for ideal transcriptional probes. We describe here the generation of addressable bipartite molecular hook (ABMH) probes and the characterization of their performance analyzing biological and clinical samples, also in comparison to linear oligonucleotide arrays. ABMH can be immobilized subsequent to reaction with the target sequence or the reaction carried out directly with the immobilized probe; target sequences are recognized with excellent sensitivity, specificity, and a detection limit below 50 fM. Due to excellent sensitivity and specificity, ABMH represent ideal candidates for the nonamplified microarray-based detection of low abundance nucleic acids, e.g., required in diagnostic assays.

Transcription in response to physical stress--clues to the molecular mechanisms of exercise-induced asthma.

To clarify stress-induced immunological reactions and molecular events during exercise and the potential relevance to exercise-induced bronchoconstriction, transcriptional responses to standardized physical stress were determined. Six healthy, young volunteers underwent an endurance exercise of 90% of their individual anaerobic threshold for 90 min. Time-dependent alterations in the expression pattern of leukocytes from healthy, trained subjects were analyzed by DNA microarrays before and 2 h and 6 h after exercise. Starting out from a large collection of cDNA library clones comprising more than 70,000 human expressed sequence tags, we selected, designed, and immobilized oligonucleotide probes (60-70mers) for transcripts of 5000 stress- and inflammation-relevant genes. Exercise-induced stress provoked changes in the expression of 433 gene activities 2 h and/or 6 h after exercise, which could be grouped into six clusters. The most prominent feature was an enhanced transcription of two genes, coding for 5-lipoxygenase (ALOX5) and ALOX5-activating protein. Moreover, enhanced levels of leukotriene B4 (LTB4) and LTC4 (P<0.05) were detected in plasma after exercise. Our data demonstrate that exercise alters the activities of a distinct number of genes. In particular, they possibly provide novel insights into the molecular mechanisms of exercise-induced bronchoconstriction and suggest that enhanced transcription of ALOX5 and its activating protein together with a present predisposition of the subject critically contribute to exercise-induced asthma.

Human endothelial cells selectively express large amounts of pancreatic-type ribonuclease (RNase 1).

Pyrimidine-specific ribonucleases are a superfamily of structurally related enzymes with distinct catalytic and biological properties. We used a combination of enzymatic and non-enzymatic assays to investigate the release of such enzymes by isolated cells in serum-free and serum-containing media. We found that human endothelial cells typically expressed large amounts of a pancreatic-type RNase that is related to, if not identical to, human pancreatic RNase. This enzyme exhibits pyrimidine-specific catalytic activity, with a marked preference for poly(C) substrate over poly(U) substrate. It was potently inhibited by placental RNase inhibitor, the selective pancreatic-type RNase inhibitor Inhibit-Ace, and a polyclonal antibody against human pancreatic RNase. The enzyme isolated from medium conditioned by immortalized umbilical vein endothelial cells (EA.hy926) possesses an amino-terminal sequence identical to that of pancreatic RNase, and shows molecular heterogeneity (molecular weights 18,000-26,000) due to different degrees of N-glycosylation. Endothelial cells from arteries, veins, and capillaries secreted up to 100 ng of this RNase daily per million cells, whereas levels were low or undetectable in media conditioned by other cell types examined. The corresponding messenger RNA was detected by RT-PCR in most cell types tested so far, and level of its expression was in keeping with the amounts of protein. The selective strong release of pancreatic-type RNase by endothelial cells suggests that it is endowed with non-digestive functions and involved in vascular homeostasis.

Combination genetic therapy to inhibit HIV-1.

Compared with single agents, combination antilentiviral pharmacotherapy targets multiple HIV-1 functions simultaneously, maximizing efficacy and decreasing chances of escape mutations. Combination genetic therapy could theoretically enhance efficacy similarly, but delivery of even single genes to high percentages of hematopoietic cells or their derivatives has proven problematic. Because of their high efficiency of gene delivery, we tested recombinant SV40-derived vectors (rSV40s) for this purpose. We made six rSV40s, each carrying a different transgene that targeted a different lentiviral function. We tested the ability of these constructs, individually and in double and triple combinations, to protect SupT1 human T lymphoma cells from HIV-1 challenge. Single chain antibodies (SFv) against CXCR4 and against HIV-1 reverse transcriptase (RT) and integrase (IN) were used, as were polymeric TAR decoys (PolyTAR) and a dominant-negative mutant of HIV-1 Rev (RevM10). Immunostaining showed that virtually all doubly treated cells expressed both transgenes. All transgenes individually protected from HIV-1 but, except for anti-CXCR4 SFv, their effectiveness diminished as challenge doses increased from 40 through 2500 tissue culture infectious dose(50) (TCID(50))/10(6) cells. However, all combinations of transgenes protected target cells better than individual transgenes, even from the highest challenge doses. Thus, combination gene therapies may inhibit HIV-1 better than single agents, and rSV40s may facilitate delivery of multigene therapeutics.