Frans M. van de Rijke scite author profile

Vertebrate chromosomes terminate in variable numbers of T2AG3 nucleotide repeats. In order to study telomere repeats at individual chromosomes, we developed novel, quantitative fluorescence in situ hybridization procedures using labeled (C3TA2)3 peptide nucleic acid and digital imaging microscopy. Telomere fluorescence intensity values from metaphase chromosomes of cultured human hematopoietic cells decreased with the replication history of the cells, varied up to six-fold within a metaphase, and were similar between sister chromatid telomeres. Surprisingly, telomere fluorescence intensity values within normal adult bone marrow metaphases did not show a normal distribution, suggesting that a minimum number of repeats at each telomere is required and/or maintained during normal hematopoiesis.

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Rapid Detection of Human Cytomegalovirus Dna in Peripheral Blood Leukocytes of Viremic Transplant Recipients by the Polymerase Chain Reaction

Jiwa

Gemert²,

Raap³

et al. 1989

Transplantation

215

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Rapid detection of human parvovirus B19 DNA by dot-hybridization and the polymerase chain reaction

Salimans

Holsappel

Rijke

et al. 1989

Journal of Virological Methods

107

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Bicolor fluorescence in situ hybridization to intron and exon mRNA sequences

Raap

Rijke

Dirks

et al. 1991

Experimental Cell Research

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Fluorescence in situ hybridization using horseradish peroxidase-labeled oligodeoxynucleotides and tyramide signal amplification for sensitive DNA and mRNA detection

Corput¹,

Dirks²,

Gijlswijk³

et al. 1998

Histochemistry and Cell Biology

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We have used horseradish peroxidase-labeled 40 mer oligodeoxynucleotides (HRP-ODNs) specific for the human cytomegalovirus immediate early gene (HCMV-IE) and a novel dinitrophenol-tyramide signal amplification reagent (DNP-TSA plus) to evaluate their utility in fluorescence in situ hybridization (FISH). For DNA FISH, single or cocktails of HRP-ODNs were hybridized to metaphase chromosomes of rat 9G cells which, as determined by DNA fiber FISH, carry an integrated tandem repeat of 50-60 copies of the HCMV-IE gene. With one layer of DNP-TSA plus deposition and subsequent detection with a fluorochrome-conjugated antibody, four HRP-ODNs were needed to detect the HCMV-IE integration site. When employing two TSA amplification rounds, one HRP-ODN was sufficient for obtaining a strong signal of the integrated gene cluster, indicating that 50-60 HRP molecules can be detected with ease. In addition to DNA FISH, we report here the first use of HRP-ODN probes for mRNA detection by FISH. A single HRP-ODN and one DNP-TSA plus step resulted in clear visualization of the HCMV-IE gene transcripts in rat 9G cells induced for HCMV-IE expression by cycloheximide. Two TSA detection steps enhanced signal intensities even further. Parallel experiments with hapten-labeled ODN and cDNA probes and conventional detection methods illustrated the superiority of the HRP-ODN/TSA approach in DNA and RNA FISH.

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A multiplexed and miniaturized serological tuberculosis assay identifies antigens that discriminate maximally between TB and non-TB sera

Tong¹,

Jacobi²,

Rijke³

et al. 2005

Journal of Immunological Methods

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Automation of spot counting in interphase cytogenetics using brightfield microscopy

et al. 1996

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In situ hybridization techniques allow the enumeration of chromosomal abnormalities and form a great potential for many clinical applications. Although the use of fluorescent labels is preferable regarding sensitivity and colormultiplicity, chromogenic labels can provide an excellent alternative in relatively simple situations, e.g., where it is sufficient to use a centromere specific probe to detect abnormalities of one specific chromosome. When the frequency of chromosomal aberrations is low, several hundreds or even thousands of cells have to be evaluated to achieve sufficient statistical confidence. Since manual counting is tedious, fatiguing, and time consuming, automation can assist to process the slides more efficiently. Therefore, a system has been developed for automated spot counting using brightfield microscopy. This paper addresses both the hardware system aspects and the software image analysis algorithms for nuclei and spot detection. As a result of the automated slide analysis the system provides the frequency spot distribution of the selected cells. The automatic classification can, however, be overruled by human interaction, since each individual cell is stored in a gallery and can be relocated for visual inspection. With this system a thousand cells can be automatically analyzed in approximately 10 min, while an extra 5–10 min is necessary for visual evaluation. The performance of the system was analyzed using a model system for trisomy consisting of a mixture of male and female lymphocytes hybridized with probes for chromosomes 7 and Y. The sensitivity for trisomy detection in the seeding experiment was such that a frequency of 3% trisomic cells could be picked up automatically as being abnormal according to the multiple proportion test, while trisomy as low as 1.5% could be detected after interaction. © 1996 Wiley‐Liss, Inc.

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High resolution DNA Fiber–fish on yeast artificial chromosomes: direct visualization of DNA replication

Rosenberg¹,

Florijn²,

Rijke³

et al. 1995

Nat Genet

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Fluorescent in situ hybridization (FISH) is a powerful, direct and sensitive technique with a wide resolution range that enables the simultaneous study of multiple targets, labelled in different colours. Spreading techniques, denoted here as 'Fiber-FISH', increase FISH-resolution to the DNA fiber, using decondensed nuclear DNA as hybridization target. FISH could be a powerful analytical tool for thorough physical examination of yeast artificial chromosomes (YACs) which are often chimaeric or contain internal deletions. However, with one exception restricted to meiotic yeast chromosomes, FISH has not been used successfully on yeast/YAC DNA. We have developed a fast and simple method that can be applied routinely for compositional and structural analysis of cosmid and YAC DNA in yeast. It enables precise localization and ordering of clones, resolves overlaps and distances and gives a detailed picture of the integrity and colinearity of both probe and target. The combination of high resolution, signal abundance and short yeast cell cycle allows direct visualization of replicating DNA fibers. In a 400 kb region of the human dystrophin gene, we identified two replication origins, demonstrating that human DNA cloned in yeast is capable of initiating its own replication.

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