HFE genotyping using multiplex allele-specific polymerase chain reaction and capillary electrophoresis.

CONTEXT: Hereditary hemochromatosis is recognized as one of the most common autosomal recessive disorders, with a prevalence of 1 in 200 to 400 in the white population. Early detection and treatment are completely effective in preventing pathology. It is anticipated that testing for hereditary hemochromatosis will increase, as will the need for a technology that can handle the demand. OBJECTIVE: To describe a high-throughput, single-tube, allele-specific multiplex polymerase chain reaction assay for identifying the 2 mutations in the HFE gene associated with hereditary hemochromatosis. DESIGN: Fluorescence-labeled polymerase chain reaction products from a multiplex polymerase chain reaction are analyzed by automated capillary electrophoresis. DATA ANALYSIS: The assay was validated by analysis of 25 blinded samples, and results were concordant with an established laboratory assay. CONCLUSION: The assay described offers a significant improvement over manual laboratory assays in throughput, reduced technologist time, and cost.

T-loop assembly in vitro involves binding of TRF2 near the 3' telomeric overhang.

Mammalian telomeres contain a duplex TTAGGG-repeat tract terminating in a 3' single-stranded overhang. TRF2 protein has been implicated in remodeling telomeres into duplex lariats, termed t-loops, in vitro and t-loops have been isolated from cells in vivo. To examine the features of the telomeric DNA essential for TRF2-promoted looping, model templates containing a 500 bp double-stranded TTAGGG tract and ending in different single-stranded overhangs were constructed. As assayed by electron microscopy, looped molecules containing most of the telomeric tract are observed with TRF2 at the loop junction. A TTAGGG-3' overhang of at least six nucleotides is required for loop formation. Termini with 5' overhangs, blunt ends or 3' termini with non-telomeric sequences at the junction are deficient in loop formation. Addition of non-telomeric sequences to the distal portion of a 3' overhang beginning with TTAGGG repeats only modestly diminishes looping. TRF2 preferentially localizes to the junction between the duplex repeats and the single-stranded overhang. Based on these findings we suggest a model for the mechanism by which TRF2 remodels telomeres into t-loops.

Mammalian telomeres end in a large duplex loop.

Mammalian telomeres contain a duplex array of telomeric repeats bound to the telomeric repeat-binding factors TRF1 and TRF2. Inhibition of TRF2 results in immediate deprotection of chromosome ends, manifested by loss of the telomeric 3' overhang, activation of p53, and end-to-end chromosome fusions. Electron microscopy reported here demonstrated that TRF2 can remodel linear telomeric DNA into large duplex loops (t loops) in vitro. Electron microscopy analysis of psoralen cross-linked telomeric DNA purified from human and mouse cells revealed abundant large t loops with a size distribution consistent with their telomeric origin. Binding of TRF1 and single strand binding protein suggested that t loops are formed by invasion of the 3' telomeric overhang into the duplex telomeric repeat array. T loops may provide a general mechanism for the protection and replication of telomeres.

TRF1 binds a bipartite telomeric site with extreme spatial flexibility.

TRF1 is a key player in telomere length regulation. Because length control was proposed to depend on the architecture of telomeres, we studied how TRF1 binds telomeric TTAGGG repeat DNA and alters its conformation. Although the single Myb-type helix-turn-helix motif of a TRF1 monomer can interact with telomeric DNA, TRF1 predominantly binds as a homodimer. Systematic Evolution of Ligands by Exponential enrichment (SELEX) with dimeric TRF1 revealed a bipartite telomeric recognition site with extreme spatial variability. Optimal sites have two copies of a 5'-YTAGGGTTR-3' half-site positioned without constraint on distance or orientation. Analysis of binding affinities and DNase I footprinting showed that both half-sites are simultaneously contacted by the TRF1 dimer, and electron microscopy revealed looping of the intervening DNA. We propose that a flexible segment in TRF1 allows the two Myb domains of the homodimer to interact independently with variably positioned half-sites. This unusual DNA binding mode is directly relevant to the proposed architectural role of TRF1.