Molecular cytogenetics and taxonomy of insects,with particular reference to the coleoptera

We assess and review the impact of the new cytogenetic techniques in insects for their roles in taxonomy and for a better knowledge of their chromosomal structure. Particular emphasis is given to molecular cytogenetics by fluorescent in situ hybridization, localization of AT- or GC-rich regions with fluorochromes, and restriction endonuclease banding in beetle chromosomes. The main features of the cytogenetics of Coleoptera are treated in detail, taking into account the range of variation in chromosome number and genome size, and our in-depth findings on the constitutive heterochromatin and satellite DNAs of tenebrionid beetles. Some other topics of interest for insect cytogenetics, such as the meiotic association of sex chromosomes, the nucleolar organizing regions (NORs), and the molecular constitution of telomeres, are also discussed from the taxonomic and structural viewpoints.     

Veterinary cytogenetics: past and perspective

Cytogenetics was conceived in the late 1800s and nurtured through the early 1900s by discoveries pointing to the chromosomal basis of inheritance. The relevance of chromosomes to human health and disease was realized more than half a century later when improvements in techniques facilitated unequivocal chromosome delineation. Veterinary cytogenetics has benefited from the information generated in human cytogenetics which, in turn, owes its theoretical and technical advancement to data gathered from plants, insects and laboratory mammals. The scope of this science has moved from the structure and number of chromosomes to molecular cytogenetics for use in research or for diagnostic and prognostic purposes including comparative genomic hybridization arrays, single nucleotide polymorphism array-based karyotyping and automated systems for counting the results of standard FISH preparations. Even though the counterparts to a variety of human diseases and disorders are seen in domestic animals, clinical applications of veterinary cytogenetics will be less well exploited mainly because of the cost-driven nature of demand on diagnosis and treatment which often out-weigh emotional and sentimental attachments. An area where the potential of veterinary cytogenetics will be fully exploited is reproduction since an inherited aberration that impacts on reproductive efficiency can compromise the success achieved over the years in animal breeding. It is gratifying to note that such aberrations can now be tracked and tackled using sophisticated cytogenetic tools already commercially available for RNA expression analysis, chromatin immunoprecipitation, or comparative genomic hybridization using custom-made microarray platforms that allow the construction of microarrays that match veterinary cytogenetic needs, be it for research or for clinical applications. Judging from the technical refinements already accomplished in veterinary cytogenetics since the 1960s, it is clear that the importance of the achievements to date are bound to be matched or out-weighed by what awaits to be accomplished in the not-too-far future.     

Cytogenetic analysis from DNA by comparative genomic hybridization

Comparative genomic hybridization (CGH) is a modified in situ hybridization technique which allows detection and mapping of DNA sequence copy differences between two genomes in a single experiment. In CGH analysis, two differentially labelled genomic DNA (study and reference) are co-hybridized to normal metaphase spreads. Chromosomal locations of copy number changes in the DNA segments of the study genome are revealed by a variable fluorescence intensity ratio along each target chromosome. Since its development, CGH has been applied mostly as a research tool in the field of cancer cytogenetics to identify genetic changes in many previously unknown regions. CGH may also have a role in clinical cytogenetics for detection and identification of unbalanced chromosomal abnormalities.     

荧光原位杂交技术在植物细胞遗传学和绘制基因图谱中的应用现状与展望

荧光原位杂交是在分子水平上检测外源染色质的一种有效方法。其探针主要有染色体重复序列、总基因组DNA、寡单拷贝序列和染色体涂色集中等,该技术在研究植物细胞遗传学、基因扩增、基因作图及植物进化和亲缘关系的鉴定上已广泛应用。简要概述了荧光原位杂交技术在植物细胞遗传学和绘制基因图谱中的应用现状与展望。     

Improvements in cytogenetic slide preparation: controlled chromosome spreading, chemical aging and gradual denaturing

BACKGROUND: Metaphase spreading is an essential technique for clinical and molecular cytogenetics. Results of classical banding techniques as well as complex fluorescent in situ hybridization (FISH) applications, such as comparative genomic hybridization (CGH) or multiplex FISH (M-FISH), are greatly influenced by the quality of chromosome spreading and pretreatment of the slide prior to hybridization. Materials and Methods Using hot steam and a metal plate with a temperature gradient across its surface, a reproducible protocol for slide preparation, aging, and hybridization was developed. RESULTS: This protocol yields good chromosome spreads from even the most difficult cell suspensions and is unaffected by the environmental conditions. Chromosome spreads were suitable for both banding and FISH techniques common to the cytogenetic laboratory. Chemical aging is a rapid slide pretreatment procedure for FISH applications, which allows freshly prepared cytogenetic slides to be used for in situ hybridization within 30 min, thus increasing analytical throughput and reducing benchwork. Furthermore, the gradually denaturing process described allows the use of fresh biologic material with optimal FISH results while protecting chromosomal integrity during denaturing. CONCLUSION: The slide preparation and slide pretreatment protocols can be performed in any laboratory, do not require specialized equipment, and provide robust results.     

Region-specific YAC banding and painting probes for comparative genome mapping: implications for the evolution of human chromosome 2

To date, several hundred nonchimeric yeast artificial chromosomes (YACs) from the Centre d'Étude du Polymorphisme Humain containing polymorphic sequence-tagged sites have been mapped by fluoresence in situ hybridization (FISH) on human metaphase chromosomes. Because they carry an average of 1 Mb of human genomic DNA, CEPH YACs generate high-intensity in situ hybridization signals. The available set of cytogenetically and genetically anchored YACs, approximately one every 5–10 cM evenly spaced over almost the entire human genome, provides complex region-specific probes for molecular cytogenetics. YAC probes can be adapted with unlimited flexibility to specific FISH applications such as the study of chromosomal evolution. We have generated representational probes for YAC banding and painting of human chromosome 2 and its great ape homologs. Convergent inversions were found in the pericentric region of the gorilla and orangutan homologs of chromosome 2p.     

Zukunft der Zytogenetik

This issue of the journal “Medizinische Genetik” emphasizes the current development of cytogenetic technologies. Changes in classical banding analysis, which has been a cornerstone of routine human genetics diagnostics for decades, are illustrated by means of quality assurance measures. Several contributions in this issue describe molecular cytogenetic technologies, which are based on fluorescence in situ hybridization (FISH). The introduction of comparative genomic hybridization, especially on various array platforms, revolutionized cytogenetics even further and now allows researchers to address entirely new questions and problems in human genetics. An especial stronghold of cytogenetics that distinguishes it from other molecular technologies is the option to perform analyses on a single-cell level. In this issue, possible future developments in cytogenetics are also discussed.     

Comparative genomic hybridization arrays in clinical pathology: progress and challenges

Array-based comparative genomic hybridization (array CGH) genome scanning is a powerful method for the global detection of gains and losses of genetic material in both congenital and neoplastic disorders. When used as a clinical diagnostic test, array CGH combines the whole genome perspective of traditional G-banded cytogenetics with the targeted identification of cryptic chromosomal abnormalities characteristic of fluorescence in situ hybridization (FISH). However, the presence of structural variants in the human genome can complicate analysis of patient samples, and array CGH does not provide morphologic information about chromosome structure, balanced translocations, or the actual chromosomal location of segmental duplications. Identification of such anomalies has significant diagnostic and prognostic implications for the patient. We therefore propose that array CGH should be used as a guide to the presence of genomic structural rearrangements in germline and tumor genomes that can then be further characterized by FISH or G-banding, depending on the clinical scenario. In this article, we share some of our experiences with diagnostic array CGH and discuss recent progress and challenges involved with the integration of array CGH into clinical laboratory medicine.     

Sugarcane genomics: depicting the complex genome of an important tropical crop

In the past few years, approaches such as molecular cytogenetics and the use of molecular markers have permitted significant advances in the establishment of the evolutionary origin and genome structure of sugarcane, an important polyploid crop. The availability of new resources, such as a bacterial artificial chromosome library and a huge collection of expressed sequence tags, has opened the gateway to promising functional analyses on a genomic scale.     

Evolutionary Molecular Cytogenetics of Catarrhine Primates: Past, Present and Future. R. Stanyon M. Rocchi(b) F. Bigoni(a) N. Archidiacono(b)

The catarrhine primates were the first group of species studied with comparative molecular cytogenetics. Many of the fundamental techniques and principles of analysis were initially applied to comparisons in these primates, including interspecific chromosome painting, reciprocal chromosome painting and the extensive use of cloned DNA probes for evolutionary analysis. The definition and importance of chromosome syntenies and associations for a correct cladistics analysis of phylogenomic relationships were first applied to catarrhines. These early chromosome painting studies vividly illustrated a striking conservation of the genome between humans and macaques. Contemporarily, it also revealed profound differences between humans and gibbons, a group of species more closely related to humans, making it clear that chromosome evolution did not follow a molecular clock. Chromosome painting has now been applied to more that 60 primate species and the translocation history has been mapped onto the major taxonomic divisions in the tree of primate evolution. In situ hybridization of cloned DNA probes, primarily BAC-FISH, also made it possible to more precisely map breakpoints with spanning and flanking BACs. These studies established marker order and disclosed intrachromosomal rearrangements. When applied comparatively to a range of primate species, they led to the discovery of evolutionary new centromeres as an important new category of chromosome evolution. BAC-FISH studies are intimately connected to genome sequencing, and probes can usually be assigned to a precise location in the genome assembly. This connection ties molecular cytogenetics securely to genome sequencing, assuring that molecular cytogenetics will continue to have a productive future in the multidisciplinary science of phylogenomics.     

Construction of a bacterial artificial chromosome (BAC) library for potato molecular cytogenetics research.

Lack of reliable techniques for chromosome identification is the major obstacle for cytogenetics research in plant species with large numbers of small chromosomes. To promote molecular cytogenetics research of potato (Solanum tuberosum, 2n = 4x = 48) we developed a bacterial artificial chromosome (BAC) library of a diploid potato species S. bulbocastanum. The library consists of 23,808 clones with an average insert size of 155 kb, and represents approximately 3.7 equivalents to the potato genome. The majority of the clones in the BAC library generated distinct signals on specific potato chromosomes using fluorescence in situ hybridization (FISH). The hybridization signals provide excellent cytological markers to tag individual potato chromosomes. We also demonstrated that the BAC clones can be mapped to specific positions on meiotic pachytene chromosomes. The excellent resolution of pachytene FISH can be used to construct a physical map of potato by mapping molecular marker-targeted BAC clones on pachytene chromosomes.     

Classical and molecular cytogenetics of the zebrafish, Danio rerio (Cyprinidae, Cypriniformes): an overview

The zebrafish, Danio rerio, has recently become the model system for the genetic analysis of vertebrate development. This paper reviews the advances in zebrafish cytogenetics, obtained through classical and molecular techniques, which will lead to the assignment of specific linkage groups to specific chromosome pairs in the zebrafish genome project. Several chromosome pairs of the 50-chromosome karyotype of D. rerio were differentially stained by classical staining techniques and additional information has been obtained by molecular cytogenetics. Indeed, the analysis of constitutive heterochromatin by C-banding and base-specific fluorochrome staining had suggested a differential composition of peri- and paracentromeric constitutive heterochromatin. The chromosome mapping of distinct AT- and GC-rich zebrafish satellite DNAs by means of PRINS (Primed in situ) and multicolor FISH (Fluorescence in situ Hybridization) has confirmed this hypothesis, which therefore provided the chromosome localization of 10% of the zebrafish genome. The analysis of nucleolus organizer regions (NORs) by silver staining and by FISH with 18S rDNA has also revealed the existence of variable and inactive NORs, in addition to those on the terminal regions of the long arms of the three NOR-bearing chromosome pairs. Other multicopy genes, such as minor ribosomal genes, or multicopy repeats, such as telomere specific sequences, have now been mapped on zebrafish chromosomes. The latest advancement in zebrafish molecular cytogenetics is the chromosome mapping of single locus genes. Single-copy genes from each of the 25 genetic linkage groups are now being mapped on zebrafish chromosomes by using PAC clones.     

Chromosome landmarks as tools to study the genome of Arabidopsis thaliana

The model plant Arabidopsis thaliana has long been used for genetic, cellular and molecular studies. Whereas this plant was used as a model of genetics in the 1940's, the first cytogenetic observation of A. thaliana chromosomes was published in the beginning of the 20th century. Although Arabidopsis was not originally considered to be a good plant model for cytogenetics due to smallness of its genome, the number of published chromosome studies has expanded enormously in recent years. The advent of fluorescence in situ hybridization techniques on meiotic chromosomes together with indirect immuno-fluorescence localization of key chromosomal and nuclear proteins and wide accessibility of Arabidopsis mutants have resulted in a synergistic boost in Arabidopsis cytogenetics. In comparison to other plant species, the small genome with under-represented DNA repeats together with a small number of chromosomes makes this model plant easy to comprehend for a cytologist.     

家蚕细胞遗传学及其应用

由于家蚕染色体数目较多、着丝粒弥散, 在较长时期内, 家蚕染色体识别、核型分析、染色体结构和功能的研究都受到很大限制。近年来, 应用比较基因组杂交、基因组原位杂交、基于细菌人工染色体克隆的原位杂交技术建立了家蚕的细胞学图, 综合分子连锁图构建高密度的细胞遗传学图已成为可能。分子细胞遗传学的应用正在推动家蚕染色体结构和功能的研究, 揭示出家蚕W染色体密集地分布着嵌套结构的逆转座子, 染色体端粒由重复序列(TTAGG)n以及端粒特异的非长末端逆转座子TRAS1和SART1组成, TRAS1、SART1具有较高的转录活性, 可能与维持染色体的稳定性有关。     

Fluorescence in situ hybridization (FISH)--application in research and diagnostics

The methods of molecular cytogenetics, in particular fluorescence in situ hybridization (FISH), are widely applied in cytogenetics for identification of numerical and structural chromosomal abnormalities, which are difficult to detect by routine cytogenetic techniques. Due to many advantages, FISH is used in research (gene mapping, gene expression studies, interspecies chromosome homology), and clinical diagnostics (chromosomal aberrations analysis in pre- and postnatal diagnostics, oncology). The techniques of in situ hybridization (ISH) are often employed in addition to classical banding techniques, in case where banding pattern is not reliable. This paper focuses on particular clinical examples, where FISH was successfully used to identify structural and numerical chromosomal aberrations.     

Methods of molecular cytogenetics for studying interphase chromosomes in human brain cells

One of the main genetic factors determining the functional activity of the genome in somatic cells, including brain nerve cells, is the spatial organization of chromosomes in the interphase nucleus. For a long time, no studies of human brain cells were carried out until high-resolution methods of molecular cytogenetics were developed to analyze interphase chromosomes in nondividing somatic cells. The purpose of the present work was to assess the potential of high-resolution methods of interphase molecular cytogenetics for studying chromosomes and the nuclear organization in postmitotic brain cells. A high efficiency was shown by such methods as multiprobe and quantitative fluorescence in situ hybridization (Multiprobe FISH and QFISH), ImmunoMFISH (analysis of the chromosome organization in different types of brain cells), and interphase chromosome-specific multicolor banding (ICS-MCB). These approaches allowed studying the nuclear organization depending on the gene composition and types of repetitive DNA of specific chromosome regions in certain types of brain cells (in neurons and glial cells, in particular). The present work demonstrates a high potential of interphase molecular cytogenetics for studying the structural and functional organizations of the cell nucleus in highly differentiated nerve cells. Analysis of interphase chromosomes of brain cells in the normal and pathological states can be considered as a promising line of research in modern molecular cytogenetics and cell neurobiology, i. e., molecular neurocytogenetics.     

Molecular cytogenetics in metaphase and interphase cells for cancer and genetic research, diagnosis and prognosis. Application in tissue sections and cell suspensions

As the pioneer among molecular cytogenetics techniques, fluorescence in situ hybridization (FISH) allows identification of specific sequences in a structurally preserved cell, in metaphase or interphase. This technique, based on the complementary double-stranded nature of DNA, hybridizes labeled specific DNA (probe). The probe, bound to the target, will be developed into a fluorescent signal. The fact that the signal can be detected clearly, even when fixed in interphase, improves the accuracy of the results, since in some cases it is extremely difficult to obtain mitotic samples. FISH is still used mostly in research, but there are diagnostic applications. New nomenclature is being developed in order to define many of the aberrations that were not distinguished before FISH. Prenatal diagnosis of aneuploidies and malignancies are promptly detected with FISH, which is very useful in critical cases. In some tumors, where chromosomal abnormalities are too complicated to classify manually, the technique of comparative genomic hybridization (CGH), a competitive FISH, allows examiners to determine complete or partial gain or loss of chromosomes. CGH results allow the classification of many tumor cell lines and along with other complementary techniques, like microdissection-FISH, PRINS, etc., increase the possibility of choosing an appropriate treatment for cancer patients.     

Current developments in human molecular cytogenetic techniques

In the last decade a variety of fluorescence in situ hybridization (FISH) assays have been developed. In this paper we present an overview on the currently available methods in molecular cytogenetics, highlighting their advantages and limitations, as well as their applications. Even though one has to be impressed by the total number of new techniques introduced in molecular cytogenetics, one has to be aware of the fact that it is not the brilliance of a technique that is important but the scientific question that can be addressed by it. In this review special emphasis has given in describing possible strategies for the characterization of marker and derivative chromosomes in tumor- and clinical cytogenetics.     

Next-generation hybridization and introgression

Hybridization has a major role in evolution-from the introgression of important phenotypic traits between species, to the creation of new species through hybrid speciation. Molecular studies of hybridization aim to understand the class of hybrids and the frequency of introgression, detect the signature of ancient hybridization, and understand the behaviour of introgressed loci in their new genomic background. This often involves a large investment in the design and application of molecular markers, leading to a compromise between the depth and breadth of genomic data. New techniques designed to assay a large sub-section of the genome, in association with next-generation sequencing (NGS) technologies, will allow genome-wide hybridization and introgression studies in organisms with no prior sequence data. These detailed genotypic data will unite the breadth of sampling of loci characteristic of population genetics with the depth of sequence information associated with molecular phylogenetics. In this review, we assess the theoretical and methodological constraints that limit our understanding of natural hybridization, and promote the use of NGS for detecting hybridization and introgression between non-model organisms. We also make recommendations for the ways in which emerging techniques, such as pooled barcoded amplicon sequencing and restriction site-associated DNA tags, should be used to overcome current limitations, and enhance our understanding of this evolutionary significant process.