Detection of Legionella spp. by fluorescent in situ hybridization in dental unit waterlines

AIMS: To confirm the presence of viable Legionella spp. in dental unit waterlines (DUWL) using fluorescent in situ hybridization (FISH) and compare this method with culture approach and also to validate the utility of an enrichment to increase FISH sensitivity. METHODS AND RESULTS: Water samples from 40 dental units were analysed. Three different techniques for detecting Legionella spp. were compared: (i) culture approach, (ii) direct FISH and (iii) FISH with a previous R2A medium enrichment (R2A/FISH). The FISH detection was confirmed by PCR. The use of the direct FISH does not improve significantly the detection of legionellae when compared with the culture. On the contrary, when R2A/FISH was performed, sensitivity was, respectively, two- and threefold higher than that with the direct FISH and culture approach. Using R2A/FISH, 63% of water samples analysed showed a contamination by legionellae. CONCLUSIONS: Legionellae detection by direct FISH and R2A/FISH in dental unit water is possible but is more rapid and more sensitive (R2A/FISH) than the culture approach. SIGNIFICANCE AND IMPACT OF THE STUDY: R2A/FISH showed that several pathogens present in DUWL are viable but may not be culturable. Unlike PCR, R2A/FISH is designed to detect only metabolically active cells and therefore provides more pertinent information on infectious risk.     

Hyperdiploidy and apparent aneusomy in mesothelial cells from non-malignant effusions as detected by fluorescence in situ hybridization (FISH)

Interphase cytogenetics by fluorescence in situ hybridization (FISH) can be used to detect malignant cells characterized by chromosomal aneuploidy. However, apparent aneusomy in normal "control" tissues has to be considered when using FISH as diagnostic tool. In effusions as model tissue exposed to metastasis, the definition of cut-off levels for background aneusomy by FISH was aimed in this study. Using centromeric probes representing chromosomes 7, 8, 11, 12, 17 and 18, extensive chromosome copy number enumeration by single-color FISH analysis was performed in pleural and ascitic effusions derived from 15 patients with various, non-malignant diseases. In all effusions, cells with gain of hybridization signals for several or all chromosomes tested were found (in up to 1.94% of cells). A consistent finding was high grade hyperdiploidy (>4 centromeric signals). Mesothelial elements mainly contributed to hyperdiploidy in effusions, as demonstrated by a combined analysis of FISH and immunocytochemistry with staining for cytokeratin. Dual-color FISH analysis showed that hyperdiploidy was predominantly corresponding to polyploidization; however, there were always minor cell populations classified as aneuploid by dual-color FISH. In conclusion, stringent criteria have to be applied to distinguish malignancy-related aneuploidy from background aneusomy by FISH.     

植物荧光原位杂交技术的发展及其在植物基因组分析中的应用

荧光原位杂交(FISH)是在染色体、间期核和DNA纤维上定位特定DNA序列的一种有效而精确的分子细胞遗传学方法。20年来,植物荧光原位杂交技术发展迅速:以增加检测的靶位数为目的,发展了双色FISH、多色FISH和多探针FISH鸡尾酒技术;为增加很小染色体目标的检测灵敏度,发展了BAC-FISH和酪胺信号放大FISH(TSA-FISH)等技术;以提高相邻杂交信号的空间分辨力为主要目的,发展了高分辨的粗线期染色体FISH、间期核FISH、DNA纤维FISH和超伸展的流式分拣植物染色体FISH技术。在植物基因组分析中,FISH技术发挥了不可替代的重要作用,它可用于:物理定位DNA序列,并为染色体的识别提供有效的标记;对相同DNA序列进行比较物理定位,探讨植物基因组的进化;构建植物基因组的物理图谱;揭示特定染色体区域的DNA分子组织;分析间期核中染色质的组织和细胞周期中染色体的动态变化;鉴定植物转基因。     

Simultaneous visualization of rDNA clusters and the nucleolus by combining fluorescence in situ hybridization and silver staining.

We designed two procedures to visualize simultaneously clusters of ribosomal RNA genes (rDNA) and the nucleolus in plant cells. The procedures combine fluorescence in situ hybridization (FISH) to visualize the rDNA clusters and silver staining to observe the nucleolus. When FISH is followed by silver staining, many minute FISH signals are localized in the nucleolus, and several large FISH signals are seen on the nucleolar periphery. When FISH was applied to the specimens with silver nitrate staining, large FISH signals were visualized in the nucleoplasm associated with the nucleolar periphery, but no signals were seen in the nucleoli. Thus, the two combinations of FISH and silver staining provided different details regarding the arrangement of rDNA clusters in the nucleolus of plant cells.     

Simultaneous visualization of rDNA clusters and the nucleolus by combining fluorescence in situ hybridization and silver staining

We designed two procedures to visualize simultaneously clusters of ribosomal RNA genes (rDNA) and the nucleolus in plant cells. The procedures combine fluorescence in situ hybridization (FISH) to visualize the rDNA clusters and silver staining to observe the nucleolus. When FISH is followed by silver staining, many minute FISH signals are localized in the nucleolus, and several large FISH signals are seen on the nucleolar periphery. When FISH was applied to the specimens with silver nitrate staining, large FISH signals were visualized in the nucleoplasm associated with the nucleolar periphery, but no signals were seen in the nucleoli. Thus, the two combinations of FISH and silver staining provided different details regarding the arrangement of rDNA clusters in the nucleolus of plant cells.     

An approach for quantitative assessment of fluorescence in situ hybridization (FISH) signals for applied human molecular cytogenetics.

A number of applied molecular cytogenetic studies require the quantitative assessment of fluorescence in situ hybridization (FISH) signals (for example, interphase FISH analysis of aneuploidy by chromosome enumeration DNA probes; analysis of somatic pairing of homologous chromosomes in interphase nuclei; identification of chromosomal heteromorphism after FISH with satellite DNA probes for differentiation of parental origin of homologous chromosome, etc.). We have performed a pilot study to develop a simple technique for quantitative assessment of FISH signals by means of the digital capturing of microscopic images and the intensity measuring of hybridization signals using Scion Image software, commonly used for quantification of electrophoresis gels. We have tested this approach by quantitative analysis of FISH signals after application of chromosome-specific DNA probes for aneuploidy scoring in interphase nuclei in cells of different human tissues. This approach allowed us to exclude or confirm a low-level mosaic form of aneuploidy by quantification of FISH signals (for example, discrimination of pseudo-monosomy and artifact signals due to over-position of hybridization signals). Quantification of FISH signals was also used for analysis of somatic pairing of homologous chromosomes in nuclei of postmortem brain tissues after FISH with "classical" satellite DNA probes for chromosomes 1, 9, and 16. This approach has shown a relatively high efficiency for the quantitative registration of chromosomal heteromorphism due to variations of centromeric alphoid DNA in homologous parental chromosomes. We propose this approach to be efficient and to be considered as a useful tool in addition to visual FISH signal analysis for applied molecular cytogenetic studies.     

Sexing using single blastomere derived from IVF bovine embryos by fluorescence in situ hybridization (FISH)

Fluorescence in situ hybridization (FISH) is a sensitive technique for molecular diagnosis of chromosomes on single cells and can be applied to sex determination of embryos. The objective has been to develop an accurate and reliable bovine Y chromosome-specific DNA probe in order to sex biopsed blastomeres derived from IVF bovine embryos by FISH. Bovine Y chromosome-specific PCR product derived from BtY2 sequences was labeled with biotin-16-dUTP (BtY2-L1 probe), and FISH was performed on karyoplasts of biopsed blastomeres and matched demi-embryos. Our FISH signal was clearly detected in nuclei of blastomeres of male embryos. FISH analysis of bovine embryos gave high reliability (96%) between biopsied blastomeres and matched demi-embryos. These results indicated that the BtY2-L1 bovine Y chromosome-specific FISH probe was an effective probe for bovine embryo sexing, and the FISH technique of probe detection could improve the efficiency and reliability.     

Simultaneous visualization of rDNA clusters and the nucleolus by combining fluorescence in situ hybridization and silver staining

We designed two procedures to visualize simultaneously clusters of ribosomal RNA genes (rDNA) and the nucleolus in plant cells. The procedures combine fluorescence in situ hybridization (FISH) to visualize the rDNA clusters and silver staining to observe the nucleolus. When FISH is followed by silver staining, many minute FISH signals are localized in the nucleolus, and several large FISH signals are seen on the nucleolar periphery. When FISH was applied to the specimens with silver nitrate staining, large FISH signals were visualized in the nucleoplasm associated with the nucleolar periphery, but no signals were seen in the nucleoli. Thus, the two combinations of FISH and silver staining provided different details regarding the arrangement of rDNA clusters in the nucleolus of plant cells.     

Assessment of NMYC amplification: a comparison of FISH, quantitative PCR monoplexing and traditional blotting methods used with formalin-fixed, paraffin-embedded neuroblastomas

OBJECTIVE: To determine the degree of agreement between fluorescence in situ hybridization (FISH), Southern blot analysis and LightCycler monoplex polymerase chain reaction (PCR) analysis in the assessment of NMYC gene amplification status in neuroblastoma. STUDY DESIGN: We performed a retrospective analysis of NMYC amplification, using FISH, LightCycler monoplex PCR and Southern blot techniques to assess NMYC amplification in a series of 18 neuroblastomas and 20 histologically normal tissues (15 lymph nodes, 2 pancreas specimens, 1 section each of thyroid, prostate and uterus). RESULTS: Nine neuroblastomas were NMYC amplified, and the remaining cases were nonamplified. All cases yielded interpretable results by Southern blotting and PCR monoplexing techniques. A single case of neuroblastoma was difficult to interpret by FISH due to high background debris. A single case demonstrated low-level NMYC amplification by LightCycler PCR monoplexing but was nonamplified by the other 2 techniques. FISH analysis in 1 case showed amplification, while the other 2 techniques demonstrated nonamplified status. The case in which FISH analysis incorrectly demonstrated amplification was the same one in which there was high background debris. The Southern blot results were reported as amplified or nonamplified, while numeric amplification ratios were obtained by both FISH and PCR LightCycler monoplex analysis. Comparison of these techniques demonstrated FISH to underestimate the degree of amplification in cases in which the amplification level was high by PCR. In fact, FISH appeared to saturate at amplification ratios > 10. CONCLUSION: The study revealed a high level of concordance between the 3 techniques for assessment of NMYC amplification status. However, FISH analysis has the advantage of allowing concurrent assessment of NMYC amplification status and architecture. LightCycler PCR monoplexing appears to have the advantage of more accurately quantitating high levels of NMYC amplification, including those amplified 20-fold or higher. Both FISH and PCR LightCycler monoplexing have the advantage of being performable on formalin-fixed, paraffin-embedded tissue.     

FISH landmarks for barley chromosomes (Hordeum vulgare L.).

Barley metaphase chromosomes (2n = 14) can be identified by fluorescence in situ hybridization (FISH) and digital imaging microscopy using heterologous 18S rDNA and 5S rDNA probe sequences. When these sequences are used together, FISH landmark signals were seen so that all 7 chromosomes were uniquely identified and unambiguously oriented. The chromosomal location of the landmark signals was determined by FISH to a barley trisomic series using the 18S and 5S probes labeled with different fluorophores. The utility of these FISH landmarks for barley physical mapping was also demonstrated when an Amy-2 cDNA clone and a BAC clone were hybridized with the FISH landmark probes.     

Determination of Cryptosporidium parvum oocyst viability by fluorescence in situ hybridization using a ribosomal RNA-directed probe

AIMS: Fluorescence in situ hybridization (FISH) has been proposed for species-specific detection, and viability determination of Cryptosporidium parvum oocysts. FISH-based viability determination depends on rRNA decay after loss of viability. We examined the effects of RNase(s) and RNase inhibitors on FISH of C. parvum. METHODS AND RESULTS: FISH was performed using a 5'-Texas red-labelled DNA oligonucleotide probe at 1 pM microl(-1). Intact and heat-permeabilized oocysts were treated with 1-100 microg ml(-1) RNase. FISH of intact oocysts appeared unaffected by exogenous RNase if this was neutralized before permeabilization. FISH fluorescence of heat-killed oocysts stored in phosphate-buffered saline at room temperature decayed by 1/2 after 55 h, but remained detectable after 6 days. Addition of vanadyl ribonucleoside complex (VRC) extended rRNA half-life of heat-permeabilized oocysts to 155 h. CONCLUSIONS: Extended rRNA half-life may result in viability overestimation using FISH. RNase pretreatment before FISH is recommended to destroy residual rRNA in recently killed oocysts. Incorporation of 1-10 mM l(-1) VRC before FISH permeabilization steps should neutralize RNase activity. SIGNIFICANCE AND IMPACT OF THE STUDY: Elimination of FISH fluorescence of nonviable C. parvum is desirable. Use of RNase and VRC is suggested to reduce numbers of false-positive 'viable' oocysts.     

Comparison of metaphase and interphase FISH monitoring of minimal residual disease with MLL gene probe: case study of AML with t(9;11).

The place of FISH in the monitoring of minimal residual disease (MRD) is yet to be fully characterised. Routine bone marrow cytogenetics at diagnosis in a 22 year old patient with acute myeloid leukemia FAB type M5 detected a translocation t(9;11)(p22;q23). We report our investigations to assess residual levels of translocation using a FISH probe designed to detect a gene split by the translocation. We used MLL (Oncor), a probe which spans the MLL gene at 11q23, in both metaphase and interphase preparations. At diagnosis, metaphase FISH showed 3 distinct cell lines-normal with 2 signals, abnormal with 3 signals and abnormal with 2 signals, while interphase FISH showed only 2 cell lines, one with 2 signals (which could be normal or abnormal) and one with 3 signals (split MLL). Following treatment, with the patient in clinical remission, 7 further cytogenetic analyses and 2 further FISH analyses were compared. Our results suggest that monitoring of the t(9;11) by metaphase FISH is feasible and straightforward compared to cytogenetics but interphase FISH may be problematic.     

Fluorescence In Situ Hybridization in Studying the Human Genome

Physical chromosome mapping by fluorescence in situ hybridization (FISH) is among the major lines of research on the human genome (as well as genomes of numerous other organisms). To localize particular genes or anonymous DNA sequences on individual chromosomes or chromosome regions, FISH was developed in the late 1980s and early 1990s, when the International Human Genome Project and the Russian program Human Genome were launched. Now FISH continues to play a prominent part in studies of the human genome. The review considers the major steps of FISH development in Russia, with special emphasis on the key roles of the Institute of Cytology and Genetics (Novosibirsk) and Engelhardt Institute of Molecular Biology (Moscow). Physical mapping of human chromosomes 3 and 13 by FISH is described in detail. The acquisition of FISH in Russia contributed to the progress in the related fields such as comparative animal genomics (ZOOFISH) and studies of plant chromosomes.     

荧光原位杂交技术的研究进展

荧光原位杂交(FISH)是在染色体、间期细胞核和DNA纤维上进行DNA序列定位的一种有效手段。近年来,围绕提高检测的分辨率和灵敏性,不断将免疫染色、量子点和微流控芯片等物理化学技术引入到荧光原位杂交中,促进了它的快速发展。本文主要综述了荧光原位杂交的基本原理和发展历程,重点介绍了免疫染色-荧光原位杂交(immuno-FISH)、量子点-荧光原位杂交(QD-FISH)和微流控芯片-荧光原位杂交(FISH on microchip)等多种新技术及其检测特点,如快速、灵敏、动态、多样化等。随着荧光原位杂交技术的不断完善与发展,将在细胞遗传学、表观遗传学及分子生物学等领域发挥更加重要的作用。     

An approach to the validation of novel molecular markers of breast cancer via TMA-based FISH scanning

Tissue microarrays (TMA) are valuable tools for validating results of array-based comparative genomic hybridization (ACGH) and other translational research applications requiring independent verification of genomic gains and losses by fluorescence in situ hybridization (FISH). However, spatial orientation and accurate manual tracking of the TMA cores is challenging and prone to error. Image analysis combined with core tracking software, implemented via an automated FISH scanning workstation, represents a new approach to FISH and TMA-based validation of novel genomic changes discovered by ACGH in breast and other cancers. Automated large-scale tissue microarray validation FISH studies of genomic gains and losses identified by ACGH for breast cancer are feasible using an automated imaging scanner and tracking/classifying software. Furthermore, by leveraging the bifunctional fluorescent and chromogenic properties of the alkaline phosphatase chromogen fast red K and combining the technology with FISH, correlative and simultaneous phenotype/genotype studies may be enabled.     

Fluorescence in situ hybridization in studying the human genome

Physical chromosome mapping by fluorescence in situ hybridization (FISH) is among the major lines of research on the human genome (as well as genomes of numerous other organisms). To localize particular genes or anonymous DNA sequences on individual chromosomes or chromosome regions, FISH was developed in the late 1980s and early 1990s, when the International Human Genome Project and the Russian program Human Genome were launched. Now FISH continues to play a prominent part in studies of the human genome. The review considers the major steps of FISH development in Russia with special emphasis on the key roles of the Institute of Cytology and Genetics (Novosibirsk) and Engelhardt Institute of Molecular Biology (Moscow). Physical mapping of human chromosomes 3 and 13 by FISH is described in detail. The promotion of FISH in Russia contributed to the progress in the related fields such as comparative animal genomics (ZOO-FISH) and studies of plant chromosomes.     

Multi-locus (ML)-FISH is a reliable tool for nondisjunction studies in human oocytes

In the present study, we developed a fluorescence in situ hybridization (FISH) strategy, which allows a reliable determination of the chromatid number of specific chromosomes in mature human oocytes. 168 unfertilized oocytes were analyzed by dual-color FISH with two direct-labeled locus-specific DNA probes for chromosome 13 and 21. To exclude FISH failures, metaphases with abnormal signal patterns were reanalyzed by multi-locus-FISH (ML-FISH) for chromosome 13 and 21. Following dual-color FISH, abnormal signal patterns were detected in 21 out of 108 metaphases (19.4%). 17 of these metaphases were reanalyzed by ML-FISH. In contrast to the first FISH, seven metaphases showed normal signal patterns after rehybridization, whereas ten metaphases remained abnormal. Out of these real aneuploid metaphases, five showed gain or loss of a single signal (= chromatid), two showed missing double signals (= chromosome) and three showed both. In conclusion, locus-specific FISH probes facilitate differentiation between first meiotic nondisjunction of whole chromosomes and prematurely divided chromatids. Moreover, simultaneous hybridization with a second locus-specific probe on the same chromatid (ML-FISH) helps to differentiate between FISH failures and real meiotic division errors and therefore, allows a more reliable analysis of aneuploidies in human oocytes.     

荧光原位杂交技术在医学微生物学中的应用

以16S rRNA 为靶序列的寡核苷酸探针荧光原位杂交技术已广泛应用于分析复杂环境中的微生物群落构成,包括监测和鉴定病原微生物以及未被培养微生物．通过对临床样品中微生物细胞的检测能提供微生物在人体中的种类、数量和空间分布等信息．其结果快速准确,较之传统的病原微生物诊断方法具有明显的优越性,在临床应用中有广泛的前景．     

HER-2/neu evaluation by fluorescence in situ hybridization on destained cytologic smears from primary and metastatic breast cancer

OBJECTIVE: To evaluate HER-2/neu amplification by fluorescence in situ hybridization (FISH) (HER-2/neu by FISH) on archival cytologic smears stained with May-Grünwald-Giemsa (MGG) stain. STUDY DESIGN: Cytologic specimens from 69 breast cancer lesions (48 primary and 21 metastatic), stained with MGG stain for routine diagnostic cytology, were destained and subjected to HER-2/neu by FISH. Fifteen of the 69 samples were also evaluated by FISH on paired fresh smears. RESULTS: HER-2/neu by FISH was successfully assayed in 25 of the 48 primary tumors and in 15 of the 21 metastatic lesions, corresponding to an overall feasibility of 58%. These cases had been archived between 1 month and 10 years prior to FISH analysis. Eight of the 25 primary and 5 of the 15 metastatic tumors were amplified. In 15 of the 40 evaluable cases, HER-2/neu was also assessed on the corresponding fresh smears: 8 tumors were amplified and 7 unamplified on both destained MGG and fresh smears. CONCLUSION: HER-2/neu can be detected by FISH on routinely MGG-stained cytologic slides. This approach allows HER-2/neu evaluation whenever histologic sections or fresh cytologic material are not available. In these cases, HER-2/neu assessment on destained cytologic smears plays a role in the selection of targeted therapy.