Nonradioactive in Situ Hybridization with Digoxigenin Labeled DNA Probes

Nonradioactive in situ hybridization techniques are becoming increasingly important tools for rapid analysis of the topological organization of DNA and RNA sequences within cells. Prerequisite for further advances with these techniques are multiple labeling and detection systems for different probes. Here we summarize our results with a recently developed labeling and detection system. The DNA probe for in situ hybridization is modified with digoxigenin-labeled deoxyuridine-triphosphate. Digoxigenin is linked to dUTP via an 11-atom linear spacer (Dig-[11]-dUTP). Labeled DNA probes were hybridized in situ to chromosome preparations. The hybridization signal was detected using digoxigenin-specific antibodies covalently coupled to enzyme markers (alkaline phosphatase or peroxidase) or to fluorescent dyes. Color reactions catalyzed by the enzymes resulted in precipitates located on the chromosomes at the site of probe hybridization. This was verified by hybridizing DNA probes of known chromosomal origin. The signals were analyzed by bright field, reflection contrast and fluorescence microscopy. The results indicate that the new technique gives strong signals and can also be used in combination with other systems (e.g., biotin) to detect differently labeled DNA probes on the same metaphase plate.     

用原位杂交法定位猪乳铁蛋白基因于染色体2q^12

本研究以非放射性标记的猪乳铁蛋白（Ｐｏｒｃｉｎｅ Ｌｉａｃｔｏｆｅｒｒｉｎ简称ＰＬＦ）ｃＤＮＡ为探针,通过染色体原位杂交法,对ＰＬＦ基因了染色体进行了染色体定位。实验中采用金胶抗体技术并结合使用银增强系统,提高了方法的灵敏度。利用染色体的组型分析,对杂交点的分布进行了统计学分析。５２％（２６／５０）的分裂相在第２号染色体具银粒分布,实验结果表明：ＰＬＦ基因定位于猪２号染色体２ｑ＾１２区域。     

Rapid interphase and metaphase assessment of specific chromosomal changes in neuroectodermal tumor cells by in situ hybridization with chemically modified DNA probes

Repeated DNAs from the constitutive heterochromatin of human chromosomes 1 and 18 were used as probes in nonradioactive in situ hybridization experiments to define specific numerical and structural chromosome aberrations in three human glioma cell lines and one neuroblastoma cell line. The number of spots detected in interphase nuclei of these tumor cell lines and in normal diploid nuclei correlated well with metaphase counts of chromosomes specifically labeled by in situ hybridization. Rapid and reliable assessments of aneuploid chromosome numbers in tumor lines in double hybridization experiments were achieved, and rare cells with bizarre phenotype and chromosome constitution could be evaluated in a given tumor cell population. Even with suboptimal or rare chromosome spreads specific chromosome aberrations were delineated. As more extensive probe sets become available this approach will become increasingly powerful for uncovering various genetic alterations and their progression in tumor cells.     

An improved method for chromosome-specific labeling of alpha satellite DNA in situ by using denatured double-stranded DNA probes as primers in a primed in situ labeling (PRINS) procedure.

An improved primed in situ labeling (PRINS) procedure that provides fast, highly sensitive, and nonradioactive cytogenetic localization of chromosome-specific tandem repeat sequences is presented. The PRINS technique is based on the sequence-specific annealing in situ of unlabeled DNA. This DNA then serves as primer for chain elongation in situ catalyzed by a DNA polymerase. If biotin-labeled nucleotides are used as substrate for the chain elongation, the hybridization site becomes labeled with biotin. The biotin is subsequently made visible through the binding of FITC-labeled avidin. Tandem repeat sequences may be detected in a few hours with synthetic oligonucleotides as primers, but specific labeling of single chromosomes is not easily obtained. This may be achieved, however, if denatured double-stranded DNA fragments from polymerase-chain-reaction products or cloned probes are used as primers. In the latter case, single chromosome pairs are stained with a speed and ease (1 h reaction and no probe labeling) that are superior to traditional in situ hybridization. Subsequent high-quality Q banding of the chromosomes is also possible. The developments described here extends the range of applications of the PRINS technique, so that it now can operate with any type of probe that is available for traditional in situ hybridization.     

Nonradioactive detection of nucleic acid by the universal probe system

A convenient and nonradioactive method for DNA hybridization tests termed the "Universal probe system" has been developed. This method is based on the principle of sandwich hybridization. This system consists of two single-stranded DNA probes (a primary probe and a biotin-labeled secondary probe). The primary probe is prepared from a chimeric phage-plasmid vector containing the complementary sequence to a target gene. The secondary probe has a sequence complementary to the vector portion of the primary probe and is labeled with biotin via the transamination reaction. An advantage of this method is that the single-stranded primary probe can be prepared with ease by using the chimeric phage-plasmid vector system, thereby avoiding tedious labeling of individually different probes. As the primary probe is not modified with biotin and other labels, it conserves the sequence to be hybridized with a target. Accordingly, the primary probe containing a relatively short hybridizing region (ca. 50 bp) can efficiently hybridize with the target. In fact, the universal probe is sensitive enough to detect a single-copy human gene on Southern blots.     

Enzymatic labeling of nucleic acids

Enzymatic labeling of nucleic acids is a fundamental tool in molecular biology with virtually every aspect of nucleic acid hybridization technique involving the use of labeled probes. Different methods for enzymatic labeling of DNA, RNA and oligonucleotide probes are available today. In this review, we will describe both radioactive and nonradioactive labeling methods, yet the choice of system for labeling the probe depends on the application under study.     

地高辛标记反意RNA探针检测脑组织切片生长抑素mRNA

本实验采用含大鼠生长抑素基因的ｐＳＰ６５ｃＤＮＡ质位通过转化至噬菌体内大量扩增,经提取,纯化后,用限制性内切酶进行酶切使质枝线性化,并将其作为模板,用地高辛（ＤｉｇｏｘｉｇｅｎｉｎＤｉｇ）作为标记物,体外转录合成生长抑素反意ＲＮＡ（ｃＲＮＡ）探针。实验动物选用ｗｉｓｔａｒ新生大鼠。冰冻切片,端、间脑切片经杂交前用Ｄｉｇ－ＵＴＰ标记的ｃＲＮＡ探针杂交,杂交后用抗Ｄｉｇ－碱性磷酸酶复合物进行酶联免疫反应。Ｘ－磷酸盐－ＮＢＴ显色。结果显示新生大鼠脑内生长抑素ｍＲＮＡ神经元着紫蓝色。杂交反应物集中于核周的胞浆及短小的突起内。胞核不着色。胞体轮廓清晰,周围背底浅淡。结果表明Ｄｉｇ标记ｃＲＮＡ探针不仅具备非同位素标记探针的优点而且能快速和准确检测组织细胞内ｍＲＮＡ的表达。     

Use of non-radioactive DNA probes for the characterization of adult T-cell leukemia cells

DNA fragments were labeled with dinitrophenyl (DNP) residues by the reaction with 2,4-dinitrobenzaldehyde in alkaline condition and the labeled DNA was used as a probe for non-radioactive in situ hybridization. DNP-labeled DNA probes for T cell receptor beta chain, c-myc and HTLV-1 were hybridized in situ to mRNA on cell specimens fixed with Carnoy's fixative. DNA-mRNA hybrids were detected immunohistochemically using anti-DNP antibodies. Cytoplasms of adult T cell leukemia cells were stained with varied intensity when these probes were used. More than 70% of cells were positively stained with T cell receptor probe. However, less than 30% of cells were stained with c-myc and HTLV-1 probes. The present study indicates that non-radioactive in situ hybridization can be used for the characterization and classification of leukemia.     

In situ hybridization technique to localize rRNA and mRNA in mammalian neurons

In situ hybridization provides a method for identifying cells that contain specific nucleic acid sequences. This report outlines an in situ hybridization procedure for mammalian neural tissue. The method maintains morphological quality and produces excellent specificity. Seven tritiated nucleic acid probes were examined: two ribosomal RNA probes, a control pBR322 plasmid probe, two probes encoding portions of the gene for oxytocin, one probe each encoding a portion of vasopressin glycoprotein, and neurophysin. Using cryostat-cut rat brain sections, rRNA probes labeled the cytoplasm of all cells and the nucleoli of larger neurons. The plasmid probe failed to produce a strong signal. Oxytocin and vasopressin probes appropriately labeled the cytoplasm of hypothalamic magnocellular neurons. Vasopressin parvocellular neurons were not identified by the current method, and the shorter length neurophysin probe failed to produce a signal. Methodological variables were examined by counting autoradiographic grains in cells. The longer oxytocin probe produced a stronger signal than the shorter oxytocin and vasopressin probes, and higher probe concentrations resulted in stronger signal. Hybridization could be abolished by tissue pretreatment with RNAse A, and longer exposure time increased signal strength. The outlined fixation steps with fresh-frozen tissue produced a superior signal compared to paraformaldehyde-perfused tissue.     

Highly fluorochrome labeled gene probes for quantitative tracing of RNA in individual cells by in situ hybridization.

A new method is presented for preparing highly fluorochrome labeled gene probes suitable for in situ hybridization. For this purpose fluorochromes were attached to a synthetic polypeptide, which was then coupled covalently to various gene probes. The advantage of the reported method is its high labeling efficiency and the easy coupling procedure. The method allows rapid and quantitative detection of homologous RNA at the single cell level. Optimal conditions for the hybridization of fluorochrome-labeled gene probes were established microfluorimetrically, and the specificity and sensitivity of the method were tested. Quantitation of the RNA with a fluorochrome-labeled gene probe in situ in individual cells allows determination of the degree of gene activation in individual cells and may thus provide a new tool for investigation of normal and malignant cells with respect to activation of genes controlling differentiation and proliferation.     

Differential localization of mRNAs of collagen types I and II in chick fibroblasts, chondrocytes, and corneal cells by in situ hybridization using cDNA probes

We have employed a highly specific in situ hybridization protocol that allows differential detection of mRNAs of collagen types I and II in paraffin sections from chick embryo tissues. All probes were cDNA restriction fragments encoding portions of the C-propeptide region of the pro alpha-chain, and some of the fragments also encoded the 3'-untranslated region of mRNAs of either type I or type II collagen. Smears of tendon fibroblasts and those of sternal chondrocytes from 17-d-old chick embryos as well as paraffin sections of 10-d-old whole embryos and of the cornea of 6.5-d-old embryos were hybridized with 3H-labeled probes for either type I or type II collagen mRNA. Autoradiographs revealed that the labeling was prominent in tendon fibroblasts with the type I collagen probe and in sternal chondrocytes with the type II collagen probe; that in the cartilage of sclera and limbs from 10-d-old embryos, the type I probe showed strong labeling of fibroblast sheets surrounding the cartilage and of a few chondrocytes in the cartilage, whereas the type II probe labeled chondrocytes intensely and only a few fibroblasts; and that in the cornea of 6.5-d-old embryos, the type I probe labeled the epithelial cells and fibroblasts in the stroma heavily, and the endothelial cells slightly, whereas the type II probe labeled almost exclusively the epithelial cells except for a slight labeling in the endothelial cells. These data indicate that embryonic tissues express these two collagen genes separately and/or simultaneously and offer new approaches to the study of the cellular regulation of extracellular matrix components.     

ULS: a versatile method of labeling nucleic acids for FISH based on a monofunctional reaction of cisplatin derivatives with guanine moieties

The broad extension of an existing chemical DNA labeling technique for molecular cytogenetics is described. Called the Universal Linkage System (ULS(TM)), it is based on the capability of monoreactive cisplatin derivatives to react at the N7 position of guanine moieties in DNA. Simple repetitive probes, cosmids, PACs, and chromosome-specific painting probes were labeled by ULS and used in a series of multicolor fluorescence in situ hybridization experiments on interphase and metaphase cells. It is demonstrated that ULS-labeled probes, in general, perform as well as the more conventional enzymatically labeled probes. The advantage of ULS labeling over enzymatic labeling techniques is that it is a fast and simple procedure, and that the labeling can easily be scaled up for bulk probe synthesis. In addition, with ULS labeling it is possible to label degraded DNA, a situation in which enzymatic labeling is known to perform unsatisfactorily.     

In situ hybridization of semithin Epon sections with BrdU labelled oligonucleotide probes

We recently described a nonradioactive method for in situ hybridization with 5-bromo-2-deoxyuridine (BrdU) labelled oligonucleotide probes. An antibody to BrdU and immunocytochemistry were used in order to detect the hybridization signal. We have now applied this method to semithin Epon sections, in order to hybridize consecutive sections through single cells with different probes and to stain them with antibodies to neuropeptides. It could be shown that Epon embedding reserves mRNA well. In the present study we used a BrdU labelled synthetic oligonucleotide probe complementary to a fragment of the vasopressin precursor and an antibody to Arg-vasopressin. Vasopressin mRNA was demonstrable in a fraction of the vasopressin immunoreactive neurons in the magnocellular nuclei. In addition some of the magnocellular neurons showed either hybridization or vasopressin immunostaining only, perhaps indicating different stages of synthetic and secretory activity. The method described seems to be a valuable tool for studying synthetic activity in peptidergic neurons on a single cell level. The method might also have potential for in situ hybridization on the electron-microscopical level.     

DNA fiber-FISH staining mechanism.

Fluorescence in situ hybridization to DNA fibers (Fiber-FISH) is a high-resolution, wide-ranging physical DNA mapping method that finds increasing application in the study of pathological gene rearrangements. Here we present experiments designed to understand the nature of the discontinuous FISH signal patterns seen after Fiber-FISH. Use of a novel cisplatin-based chemical labeling method enabled us to produce intact biotin-labeled cosmid target DNA molecules. We monitored by immunofluorescence the fate of such cosmid targets during denaturation and hybridization. The same cosmid DNA labeled with digoxigenin by nick-translation was used to analyze the FISH probe signal distribution in a different color. The probe signals proved to be a subset of the target signals remaining after denaturation and hybridization. We argue that the discontinuity of probe signals in Fiber-FISH is mainly caused by loss of target DNA and limited accessibility due to in situ renaturation and attachment. Furthermore, we conclude that FISH sensitivity is determined by hybridization efficiency and not the ability to generate sufficient signal from small probes. (J Histochem Cytochem 48:743-745, 2000)     

In situ hybridization of semithin Epon sections with BrdU labelled oligonucleotide probes

Summary We recently described a nonradioactive method for in situ hybridization with 5-bromo-2-deoxyuridine (BrdU) labelled oligonucleotide probes. An antibody to BrdU and immunocytochemistry were used in order to detect the hybridization signal. We have now applied this method to semithin Epon sections, in order to hybridize consecutive sections through single cells with different probes and to stain them with antibodies to neuropeptides. It could be shown that Epon embedding preserves mRNA well. In the present study we used a BrdU labelled synthetic oligonucleotide probe complementary to a fragment of the vasopressin precursor and an antibody to Arg-vasopressin. Vasopressin mRNA was demonstrable in a fraction of the vasopressin immunoreactive neurons in the magnocellular nuclei. In addition some of the magnocellular neurons showed either hybridization or vasopressin immunostaining only, perhaps indicating different stages of synthetic and secretory activity. The method described seems to be a valuable tool for studying synthetic activity in peptidergic neurons on a single cell level. The method might also have potential for in situ hybridization on the electronmicroscopical level.     

<Emphasis Type="Italic">In situ</Emphasis>detection of non-polyadenylated RNA molecules using Turtle Probes and target primed rolling circle PRINS

Background  

In situ detection is traditionally performed with long labeled probes often followed by a signal amplification step to enhance the labeling. Whilst short probes have several advantages over long probes (e.g. higher resolution and specificity) they carry fewer labels per molecule and therefore require higher amplification for detection. Furthermore, short probes relying only on hybridization for specificity can result in non-specific signals appearing anywhere the probe attaches to the target specimen. One way to obtain high amplification whilst minimizing the risk of false positivity is to use small circular probes (e.g. Padlock Probes) in combination with target primed rolling circle DNA synthesis. This has previously been used for DNA detection in situ, but not until now for RNA targets.     

In situ hybridization of an acetylaminofluorene-modified probe recognized by Z-DNA antibodies in vitro

An in situ hybridization procedure, based on the chemical modification of DNA by acetylaminofluorene (AAF), followed by a specific immunoreaction was used to localize a Z-DNA sequence isolated from the satellite DNA of Cebus appella. The AAF probe is localized on the R-band-positive heterochromatic segments of Cebus chromosomes, which strongly react with Z-DNA antibodies. The use of a nonradioactive single-stranded labeled probe confirms the reliability and the rapidity of immunochemical methods for the detection of DNA sequences on chromosomes.