Screening H3 Histone Acetylation in a Wild Bird, the House Sparrow (Passer Domesticus).

Epigenetic mechanisms are increasingly understood to have major impacts across ecology. However, one molecular epigenetic mechanism, DNA methylation, currently dominates the literature. A second mechanism, histone modification, is likely important to ecologically relevant phenotypes and thus warrants investigation, especially because molecular interplay between methylation and histone acetylation can strongly affect gene expression. There are a limited number of histone acetylation studies on non-model organisms, yet those that exist show that it can impact gene expression and phenotypic plasticity. Wild birds provide an excellent system to investigate histone acetylation, as free-living individuals must rapidly adjust to environmental change. Here, we screen histone acetylation in the house sparrow (Passer domesticus); we studied this species because DNA methylation was important in the spread of this bird globally. This species has one of the broadest geographic distributions in the world, and part of this success is related to the way that it uses methylation to regulate its gene expression. Here, we verify that a commercially available assay that was developed for mammals can be used in house sparrows. We detected high variance in histone acetylation among individuals in both liver and spleen tissue. Further, house sparrows with higher epigenetic potential in the Toll Like Receptor-4 (TLR-4) promoter (i.e., CpG content) had higher histone acetylation in liver. Also, there was a negative correlation between histone acetylation in spleen and TLR-4 expression. In addition to validating a method for measuring histone acetylation in wild songbirds, this study also shows that histone acetylation is related to epigenetic potential and gene expression, adding a new study option for ecological epigenetics.

Epigenetic and genetic variation among three separate introductions of the house sparrow (Passer domesticus) into Australia.

Invasive populations are often associated with low levels of genetic diversity owing to population bottlenecks at the initial stages of invasion. Despite this, the ability of invasive species to adapt rapidly in response to novel environments is well documented. Epigenetic mechanisms have recently been proposed to facilitate the success of invasive species by compensating for reduced levels of genetic variation. Here, we use methylation sensitive-amplification fragment length polymorphism and microsatellite analyses to compare levels of epigenetic and genetic diversity and differentiation across 15 sites in the introduced Australian house sparrow population. We find patterns of epigenetic and genetic differentiation that are consistent with historical descriptions of three distinct, introductions events. However unlike genetic differentiation, epigenetic differentiation was higher among sample sites than among invasion clusters, suggesting that patterns of epigenetic variation are more strongly influenced by local environmental stimuli or sequential founder events than the initial diversity in the introduction population. Interestingly, we fail to detect correlations between pairwise site comparisons of epigenetic and genetic differentiation, suggesting that some of the observed epigenetic variation has arisen independently of genetic variation. We also fail to detect the potentially compensatory relationship between epigenetic and genetic diversity that has been detected in a more recent house sparrow invasion in Africa. We discuss the potential for this relationship to be obscured by recovered genetic diversity in more established populations, and highlight the importance of incorporating introduction history into population-wide epigenetic analyses.

Spontaneous dissection of the superior mesenteric artery.

Spontaneous dissection of the superior mesenteric artery (SMA) is a rare occurrence, especially when not associated with aortic dissection [1]. Currently, only 28 cases appear to have been reported. Due to the scarcity of cases in the literature, the natural history of isolated, spontaneous SMA dissection is unclear. CT has been reported to be useful for the initial diagnosis of SMA dissection [2-5]. We present two recent cases of spontaneous SMA dissection in which enhanced spiral CT was instrumental in following the disease process and guiding clinical decision making.

Preparation and hybridization analysis of DNA/RNA from E. coli on microfabricated bioelectronic chips.

Escherichia coli were separated from a mixture containing human blood cells by means of dielectrophoresis and then subjected to electronic lysis followed by proteolytic digestion on a single microfabricated bioelectronic chip. An alternating current electric field was used to direct the bacteria to 25 microlocations above individually addressable platinum microelectrodes. The platinum electrodes were 80 microns in diameter and had center-to-center spacings of 200 microns. After the isolation, the bacteria were lysed by a series of high-voltage pulses. The lysate contained a spectrum of nucleic acids including RNA, plasmid DNA, and genomic DNA. The lysate was further examined by electronically enhanced hybridization on separate bioelectronic chips. Dielectrophoretic separation of cells followed by electronic lysis and digestion on an electronically active chip may have potential as a sample preparation process for chip-based hybridization assays in an integrated DNA/RNA analysis system.

Isolation of cultured cervical carcinoma cells mixed with peripheral blood cells on a bioelectronic chip.

The separation and subsequent isolation of the metastatic human cervical carcinoma cell line (HeLa cells) from normal human peripheral blood cells has been achieved by exploiting their differential dielectric properties. The isolation process is carried out on a silicon chip containing a five-by-five array of microlocations. These microlocations contain underlying circular platinum electrodes with 80-micron diameters and center-to-center spacing of 200 microns. The surfaces of the electrodes and nonmetallized areas have been coated with a permeation layer to prevent the direct contact of cells with the electrode and also to minimize the nonspecific adhesion of the cells to the chip surface. An inhomogenous ac field is applied to the electrodes to create the conditions for dielectrophoretic separation of cells. Cell separation using dielectrophoresis as well as electronic lysis on a silicon chip would provide essential sample-processing steps which may be combined with a later multiplex electronic hybridization step in an integrated assay system.

Quantitation of DNA hybridization in a silicon sensor-based system: application to PCR.

Rapid, quantitative hybridization assays with good sensitivity are needed in many applications, for example, determining the amount of specific product from PCR. We have developed an assay which relies on the hybridization of a biotinylated oligomer and a fluoresceinated oligomer to a single-stranded target in solution. The hybridized complex is captured by streptavidin to a biotinylated membrane. After capture, the hybridization complex is detected by an antifluorescein-urease conjugate which binds to the fluoresceinated probe. The membrane-bound urease conjugate is exposed to urea and assayed with a pH-sensitive silicon sensor. The total assay time is less than 2 h and the sensitivity limit is 20 x 10(6) molecules with a coefficient of variation, CV, of less than 10%. The assay was applied to the analysis of a model target using PCR. We were able to measure the amount of specific product and the amplification factor during the exponential phase of PCR. Using extrapolation from the measured amounts of amplified product, the initial amounts of target molecules were calculated to be 1.2 x 10(6) and 4.0 x 10(2) when the added quantities were 3 x 10(6) and 3 x 10(3), as determined by serial dilution.

Picogram quantitation of total DNA using DNA-binding proteins in a silicon sensor-based system.

We report a rapid and reproducible method to quantify total DNA at picogram levels. Two high-affinity DNA-binding proteins are used to construct a sandwich assay and a semiconductor sensor is used for quantitation. Single-stranded DNA-binding protein (SSB) from Escherichia coli is conjugated with a linker molecule, biotin, for specific capture of the DNA complex onto a membrane. Monoclonal anti-DNA antibody is conjugated with an enzyme, urease, for signal generation. To detect DNA, a sample is denatured to form single-stranded DNA and then incubated with a reagent containing both DNA-binding protein conjugates and streptavidin. After incubation of the reagent with the DNA sample for 1 h at 37 degrees C to form a complex of streptavidin--biotin--SSB--DNA--anti-DNA--urease, the mixture is filtered through a biotin-coated nitrocellulose membrane which binds the streptavidin component of the complex. The unbound reagent is washed off the membrane, and then the captured DNA complex is detected with a light-addressable potentiometric sensor which measures the pH change catalyzed by the urease in the complex. This assay can detect 2 pg of DNA with a quantitation coefficient of variation of less than 10% in the range 10 to 200 pg.

Detection of total DNA with single-stranded DNA binding protein conjugates.

We have developed a rapid and sensitive method for total DNA measurement using single-stranded DNA binding protein from E coli conjugated with horseradish peroxidase or urease. To detect DNA, the sample is heated or alkali treated to denature the DNA and then filtered through nylon or nitrocellulose membranes. After the single-stranded DNA is bound to the membrane, single-stranded DNA binding protein enzyme-conjugate is incubated with the membrane. Next, the unbound conjugate is washed off the membrane and the bound conjugate detected colorimetrically. The assay can detect 10 pg of DNA in less than 3 hr. This method can be applied to the detection of DNA contamination in therapeutic proteins produced by recombinant DNA or hybridoma techniques.

Use of nonisotopic M13 probes for genetic analysis: application to HLA class II loci.

Previously, DNA polymorphisms in the HLA gene cluster have been analyzed using radioactive probes in Southern blot experiments; the restriction fragment length polymorphisms (RFLPs) revealed by this analysis are capable of subdividing HLA serological types. Here, we report the use of DNA probes labeled with biotinylated psoralen to provide nonisotopic detection of HLA class II RFLP patterns. These biotinylated probes contain cDNA sequences encoding the alpha and beta chains of DP, DQ, and DR HLA class II genes as inserts in M13 vectors. The recombinant M13 molecules are partially double-stranded with single-stranded HLA cDNA regions and contain biotinylated psoralen covalently linked to duplex DNA by UV irradiation. Following hybridization, the presence of biotinylated probe bound to target DNA is detected using a streptavidin-horseradish peroxidase conjugate, which converts the colorless substrate 3,3',5,5'-tetramethylbenzidine to a blue precipitate in less than 1 hr. The probe and detection system described here can detect single-copy genes in less than 0.5 microgram of total human DNA on Southern blots and generates the same specific RFLP patterns as do probes labeled with 32P by nick-translation. These biotinylated HLA class II probes have been applied to tissue typing for bone marrow transplantation and the study of insulin-dependent diabetes susceptibility, revealing in each case relevant polymorphisms not detected by serologic typing.

Charon phages: safer derivatives of bacteriophage lambda for DNA cloning.

The Charon lambda bacteriophages have been developed as vectors for cloning. Their construction incorporates mutations that make them simple to use and also greatly increases their safety for the biological containment of cloned recombinant DNA. Three of the Charon vector phages, 3A, 4A, and 16A, have been certified for use as EK2 vector-host systems, when propagated in bulk in a special bacterial host, DP50SupF. We present here some of the data on which the safety of these systems was evaluated. DNA fragments ranging in size from 0 to 2.2 X 10(4) base pairs can be cloned in these EK2 Charon phages.