Chromosomal localization of zebrafish AluI repeats by primed in situ (PRINS) labeling.

Two zebrafish AluI repeats were localized in metaphase chromosomes by means of the primed in situ (PRINS) labeling technique, using oligonucleotide primers based on published sequences. An AT-rich, tandemly repeated, long AluI restriction fragment (RFAL1) labeled the (peri)centromeric regions of all chromosomes. The GC-rich short fragment (RFAS) was found to be localized in the paracentromeric regions of 17 chromosome pairs, which were mostly subtelocentric. The RFAS labeling pattern generally fits the previously described chromomycin A3 (CMA3) staining pattern. The differential composition of heterochromatin in zebrafish chromosomes is discussed.     

Primedin situ labeling (PRINS)

PRimedIn Situ labeling (PRINS) is a fast and sensitive alternative to fluorescencein situ hybridization (FISH) for identification of chromosome aberrations. In this article, we present the detailed protocols for detection of repeat sequences using oligonucleotides or fragments of cloned probes as primers for PRINS. We describe a multicolor PRINS procedure for simultaneous visualization of more probes in different colors on a metaphase preparation, and a PRINS-painting procedure, which combines PRINS and chromosome painting. Finally, a protocol for detection of single-copy genes is presented.     

Single- and double-color oligonucleotide primed in situ labeling (PRINS): applications in pathology

 Molecular cytogenetics is mostly performed by fluorescence in situ hybridization using long DNA probes that are generated by vector cloning. Oligonucleotide primed in situ labeling (PRINS) is a recent method that has been established for the detection of the centromeric or telomeric region in metaphase chromosomes. In this overview, we demonstrate the possible applications of PRINS and provide elaborated protocols for its use in intact interphase cells of routine cytological preparations, e.g., cell smears, touch preparations, and cytospins of non-neoplastic and neoplastic tissues. Moreover, the various modifications of the PRINS method, such as multi-color PRINS for targetting different chromosomes within one cell or the enzymatic detection of the PRINS product instead of the more commonly used fluorochromes, are discussed. Accepted: 4 July 1997     

Mouse telomere analysis using an optimized primed in situ (PRINS) labeling technique

Telomeres are chromosomal elements composed of variable numbers of a TTAGGG repeated DNA sequence required for genomic stability. Telomeric length is correlated with the number of copies of this repeated DNA sequence and is an important property relevant to telomeric function. Recently, it has been demonstrated that the length of the shortest telomere, not average telomeric length, is important for cell viability and chromosomal stability. Consequently, assays permitting assessment of telomeric length are important for the analysis of genomic instability disorders. The length of individual telomeres can be analyzed using the primed in situ (PRINS) labeling reaction, which produces a labeled copy of the telomeric DNA repeats in situ. In this study, we tested different variables to optimize the PRINS reaction to enable it to be applied to the detection of mouse telomeric DNA and the study of telomeric length. The specificity, efficiency and uniformity of staining were evaluated using digital fluorescence microscopy. Labeling efficiency is dependent upon the conditions used to denature the telomeric DNA and reaction duration. Staining uniformity is increased at higher annealing and elongation temperatures as well as when a fluorescently labeled nucleotide is incorporated during the elongation step. Our results also indicate that chromosomal background staining is observed when a fluorochrome-labeled nucleotide is used as opposed to a hapten-labeled nucleotide. From this study, we conclude that an optimized PRINS technique can be reliably employed to analyze mouse telomeres and, compared with the FISH (fluorescence in situ hybridization) technique, presents advantages including greater cost efficiency and reduced processing time. These advantages may encourage wider use of the PRINS technique for quantitative evaluation of the length of individual telomeres in situ.     

Rapid detection of yeast rRNA genes with primed in situ (PRINS) labeling

In yeast, rRNA genes can be detected with the FISH technique using rRNA gene probes. This technique yields reliable, reproducible and precise results, but is time-consuming. Here, the primed in situ DNA synthesis (PRINS) procedure has been optimized for rapid detection of yeast rRNA genes. PRINS, which is as sensitive as PCR and allows cytological localization of analyzed sequences, can be adapted for various screening tests requiring fast labeling of rRNA genes.     

Localization of repetitive DNA sequences on in vitro Xenopus laevis chromosomes by primed in situ labeling (PRINS)

Xenopus laevis is an important reference model organism used in many vertebrate studies. Gene mapping in X. laevis, in comparison to other reference organisms, is in its early stages. Few studies have been conducted to localize DNA sequences on X. laevis chromosomes. Primed in situ labeling (PRINS) is a recently developed innovative tool that has been used to locate specific DNA sequences in various organisms. PRINS has been reported to have increased sensitivity compared to other in situ hybridization techniques. In the present study, PRINS was first used to label the location of telomeres at the ends of in vitro X. laevis chromosomes. The terminal location was as expected from in vivo reports, however, the overall amount seemed to decrease in the in vitro chromosomes. Once the PRINS technique was optimized, this technique was used to determine the chromosomal location of the satellite 1 repetitive sequence, which is an important sequence in X. laevis development. The sequence was observed on the interstitial regions of the majority of the chromosomes similar to the in vivo locations reported. In contrast to the telomeric sequence, the amount of sequence appeared to increase in the satellite 1 sequence. PRINS was found to be useful in the localization of repetitive DNA sequences in the X. laevis genome.     

Use of primed in situ labeling (PRINS) for the detection of telomeric deletions associated with mental retardation

Rearrangements involving the telomeric regions of human chromosomes are often associated with mental retardation. These rearrangements, however, are difficult to detect using conventional cytogenetic techniques. We propose the use of primed in situ (PRINS) labeling as an alternative to fluorescence in situ hybridization because it is very fast, reproducible, and simple to perform. Sixty-five children with unexplained mental retardation were studied using PRINS technology; two of them were shown to have a telomeric deletion.     

引物原位标记技术快速检测人类染色体非整倍性

染色体数目异常是人类染色体疾病的重要类型, 经常导致胚胎丢失、胎儿流产、婴儿死亡、先天畸形和神经发育异常等出生缺陷。文章应用引物原位标记(Primed in situ labeling, PRINS)技术快速检测人类染色体非整倍性, 率先采用更新的非ddNTP阻断的多色PRINS技术, 对人类外周血淋巴细胞和精子等多种样本进行标记; 然后对不同靶标序列的标记效率及不同荧光色素的发光特点通过实验进行评估, 获得关于PRINS技术的多项反应原理参数, 并筛选标记顺序以获得均一稳定的标记效果, 最后进行临床FISH探针与PRINS的标记比较实验。通过实验比较PRINS技术与传统FISH技术之间的标记特点与差别, 评估PRINS的实际应用效果。在2.5 h内标记了同一精子核内的多条染色体, 单色以上标记达到99％。同时在人类外周血淋巴细胞中也得到较好的标记效果。与FISH技术相比, PRINS的这些优点使得它成为诊断染色体非整倍性变异的首选技术。     

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.     

Chromosomal localization of human aspartate aminotransferase genes by in situ hybridization

Summary The localization of the human genes for cytosolic and mitochondrial aspartate aminotransferase (AspAT) has been determined by chromosomal in situ hybridization with specific human cDNA probes previously characterized in our laboratory. The cytosolic AspAT gene is localized on chromosome 10 at the interface of bands q241–q251. Mitochondrial AspAT is characterized by a multigene family located on chromosomes 12 (p131–p132), 16 (q21), and 1 (p32–p33 and q25–q31). Genomic DNA from ten blood donors was digested by ten restriction enzymes, and Southern blots were hybridized with the two specific probes. Restriction fragment length polymorphism was revealed in only one case for cytosolic AspAT, with PvuII, while no polymorphism for mitochondrial AspAT was found.     

Localisation of the classical DNA satellites on human chromosomes as determined by primed in situ labelling (PRINS)

The chromosomal localisation and relative amounts in humans of the classical DNA satellites I, II and III have been determined by using the primed in situ labelling reaction with a variety of oligonucleotide primers. The centromeres of seven of the human chromosomes, viz. nos 6, 8, 11, 12, 18, 19 and X, are not identifiably marked by any of the primers. A possible phylogenetic explanation of this is suggested and the possible relationship of the classical satellites to the function of the centromere is discussed. Received: 5 November 1996 / Accepted: 25 March 1997     

Interactions between SRY and SOX genes in mammalian sex determination

The SRY gene on the mammalian Y chromosome undoubtedly acts to determine testis, but it is still quite unclear how. It was originally supposed that SRY acts directly to activate other genes in the testis-determining pathway. This paper presents an alternative hypothesis that SRY functions indirectly, by interacting with related genes SOX3 (from which SRY evolved) and SOX9 (which appears to be intimately involved in vertebrate gonad differentiation). Specifically, I propose that in females SOX3 inhibits SOX9 function, but in males, SRY inhibits SOX3 and permits SOX9 to enact its testis-determining role. This hypothesis makes testable predictions of the phenotypes of XX and XY individuals with deficiencies or overproduction of any of the three genes, and is able to account for the difficult cases of XX(SRY−) males and transdifferentiation in the absence of SRY. The hypothesis also suggests a way that the dominant SRY sex-determining system of present-day mammals may have evolved from an ancient system relying on SOX3 dosage. BioEssays 20 :264–269, 1998. © 1998 John Wiley & Sons, Inc.     

A polymorphic alpha satellite sequence specific for human chromosome 13 detected by oligonucleotide primed in situ labelling (PRINS)

The centromeric alpha satellite DNA subfamilies from chromosomes 13 and 21 are almost identical in sequence and cannot be easily distinguished by mean of probes for Southern blot or in situ hybridisation. We have used the oligonucleotide-primed in situ (PRINS) labelling technique with primers defined from the alpha satellite sequence of chromosome 13. One primer was found to label specifically the centromeric region of chromosomes 13 and allowed the detection of a polymorphism between two chromosome 13 homologues in one individual.     

Chromosomal localization of zein genes by in situ hybridization in Zea mays

Summary In order to localize the genes coding for zein, the major storage protein of maize endosperm, zein ¹²⁵I-mRNA and ³H-cDNA labelled at high specific activity were used for in situ hybridization on heterozygous interchanges and paracentric inversions of the KYS strain of Zea mays. The analysis of the diplotene-metaphase I microsporocytes indicated the presence of zein structural genes on the long arm of chromosomes 4 and 5, the short arm of chromosome 7 and the distal segment of the long arm of chromosome 10. The two hybridization sites on chromosomes 7 and 10 are found near opaque-2 and opaque-7 loci which are known to regulate zein synthesis. The present data are discussed in relation to results obtained by other authors using genetical mapping of zein genes.     

Chromosomal localization of the mouse prealbumin gene (Ttr) by in situ hybridization.

Prealbumin is a serum protein which plays an important role in plasma transport of retinol and thyroxine. The accumulation of a variant prealbumin is associated with a hereditary disorder, familial amyloidotic polyneuropathy (FAP). In situ hybridization with a mouse prealbumin gene cDNA probe was carried out in mouse fibroblasts. Analysis of 114 R-banded metaphases showed that 13% of the total grains were located on chromosome 4 and 46% of the grains on this chromosome were in the region C6-D1. Linkage and syntenic group analysis showed that the prealbumin gene (Ttr) is located between two syntenic groups on mouse chromosome 4, which corresponded to two syntenic groups present on human chromosomes 1 and 9.     

Chromosomal localization of group-specific component by in situ hybridization

Group-specific component (GC), an alpha 2-globulin plasma protein synthesized primarily in the liver, is the major vitamin D-binding protein in plasma. It has two common phenotypes, GC1 and GC2, which appear in all human populations. Using the cDNA insert containing the entire coding sequence of GC2, the GC gene was mapped to human chromosomal bands 4q13----q21.1 by in situ hybridization.