Sequence organization of animal nuclear DNA

Functional cDNA expression cloning: pushing it to the limit

The 1970s and the following decade are the era of the birth and early development of recombinant DNA technologies, which have entirely revolutionized the modern life science by providing tools that enable us to know the structures of genes and genomes and to dissect their components and understand their functions at the molecular and submolecular levels. One major objective of the life sciences is to achieve molecular and chemical understandings of the functions of genes and their encoded proteins, which are responsible for the manifestation of all biological phenomena in organisms. In the early 1980s, I developed, together with Paul Berg, a new technique that enables the cloning of full-length complementary DNAs (cDNAs) on the basis of their functional expression in a given cell of interest. I review the development, application and future implications in the life sciences of this gene-cloning technique.

Rad51 inhibits translocation formation by non-conservative homologous recombination in Saccharomyces cerevisiae

Chromosomal translocations are a primary biological response to ionizing radiation (IR) exposure, and are likely to result from the inappropriate repair of the DNA double-strand breaks (DSBs) that are created. An abundance of repetitive sequences in eukaryotic genomes provides ample opportunity for such breaks to be repaired by homologous recombination (HR) between non-allelic repeats. Interestingly, in the budding yeast, Saccharomyces cerevisiae the central strand exchange protein, Rad51 that is required for DSB repair by gene conversion between unlinked repeats that conserves genomic structure also suppresses translocation formation by several HR mechanisms. In particular, Rad51 suppresses translocation formation by single-strand annealing (SSA), perhaps the most efficient mechanism for translocation formation by HR in both yeast and mammalian cells. Further, the enhanced translocation formation that emerges in the absence of Rad51 displays a distinct pattern of genetic control, suggesting that this occurs by a separate mechanism. Since hypomorphic mutations in RAD51 in mammalian cells also reduce DSB repair by conservative gene conversion and stimulate non-conservative repair by SSA, this mechanism may also operate in humans and, perhaps contribute to the genome instability that propels the development of cancer.

Organization and chromosomal location of repetitive DNA sequences in three species of squamate reptiles

Repetitive DNA sequences were isolated from the genomes of species representing three major clades of squamate reptiles. A repetitive sequence (Cn4C7) was isolated from the New Mexican whiptail lizard, Cnemidophorus neomexicanus. This sequence is distributed throughout the chromosomes, but is more concentrated in the telomeric region. Cn4C7 also hybridizes to the chromosomes of other Cnemidophorus. Some evidence was found for concerted evolution of this repeat in hybrid unisexual lineages. In the lesser earless lizard, Holbrookia maculata, the predominant repeat in the genome is represented by a sequence (Hm1E11) which is restricted to the area flanking the centromere in all species of Holbrookia. Two families of repetitive sequences (one dispersed, and the other telomeric) were isolated from the western diamondback rattlesnake, Crotalus atrox. The type and distribution of repetitive sequences in squamates is often taxon-specific, and may be useful as characters for elucidating taxonomic relationships.

The genome size and the structure and content of ribosomal RNA genes in Atlantic cod (Gadus morhua L.)

1. The haploid genome size of the Atlantic cod was estimated to 3.4 x 10(8)kb by reassociation kinetics analysis of cod sperm DNA. 2. The size of the small and large subunit ribosomal RNAs is 1.85 and 4.1 kb, respectively. 3. Restriction enzyme mapping of the rRNA coding unit revealed conservation of an Eco RI site in the coding regions of 18 S and 28 S rRNA and a Bam HI site in the 28 S rRNA coding region compared to other fish species. 4. The length of the repeat unit of the cod rDNA was found to be 30 kb. 5. The rRNA genes are repeated approximately 50 times in the cod genome and constitutes 0.08% of the cod genetic material.

Avian species-specific tandem repeats contain nuclear protein binding sites

Three avian highly repetitive tandem repeats were identified and examined. These repeats had similar unit lengths (about 42 bp long) but completely different sequences each containing particular protein binding sites. Each of these repeats was found within only one of the five closely related genera studied.

The 5' region of the human thyroglobulin gene contains members of the Alu family

Repeated sequences were identified in the 5' region of the human Tg gene in introns 4, 5, 10, and 11. Another repeated cluster was located in the 5' flanking sequences, approximately 6 Kb upstream from the first exon. The nucleotide sequence analysis indicated that these repeated sequences are members of the Alu family. The homology between the sequences of the intron 4 and the Alu consensus was 86%. The Alu member studied was oriented in the direction of transcription of the Tg.

Genome size evolution in vertebrates: trends and constraints

1. Studies on the genomic evolution in vertebrates have highlighted the differences existing between anamniotes and amniotes, both in quantitative and compositional terms. 2. These differences do not seem to depend on a different tendency to genic amplification, but rather on the existence of more strict and efficient constraints in amniotes. 3. Some constraints, that may be defined as "intrinsic", would act directly on the genome; among these particularly important is the chiasma frequency during meiosis. 4. Other, "extrinsic", constraints, would act indirectly through genic products or through cell morphometric parameters. 5. The genome size increase seems to depend on various mechanisms. The most wide-spread one seems to be the amplification of interspersed repetitive and non-repetitive sequences.

Size and structure of the bird genome. II. Repetitive DNA and sequence organization

1. Highly repetitive, middle repetitive and single copy DNA were evaluated in 19 species of birds, belonging to nine orders, by means of a reassociation kinetics method. 2. A rather uniform pattern is present in all the species studied (single copy = 60-75%; middle repetitive = 13-20% and highly repetitive 10-20%). 3. Reassociation kinetics of fragments of different length confirms the presence of a long period interspersion pattern. 4. Among different orders, no significant differences are observed. 5. DNA sequence organization seems to be related to genome size, with an inverse correlation between DNA nuclear content and amount of interspersed repetitive sequences.

The expression of the evolutionarily conserved GATA/GACA repeats in mouse tissues

Simple repeated GATA and GACA sequences were initially identified in sex-specific snake satellite DNA. The organization of these sequences in the mouse genome is described in Schäfer et al. 1986. The expression of these simple repeats was studied here in several mouse tissues using a variety of different probes: oligonucleotides and "single-stranded" as well as nick-translated DNA. The transcription of discrete RNA species was found to be differentially regulated in several organs but sex differences in transcription were not observed. GATA- and GACA-containing cDNA clones were isolated and sequenced and a genomic clone was characterized with respect to the transcription of GATA flanking sequences. Functional aspects of GATCA simple DNA repeats are discussed in terms of internally repetitive, hydrophobic translation products.

Peripheral location of the Y chromosome: relationship to race and length heteromorphism

In the present report we examined the position of the Y chromosome with respect to its size and race to determine their relationship to its peripheral location. Peripheral blood lymphocytes were cultured from 172 normal male individuals (70 Asian Indians; 49 American Blacks; and 53 Caucasians) and 2770 QFQ cells were photographed. The length of the Y chromosome was classified into four groups i.e., small, average, large and very large as described earlier (Verma et al., J. Med. Genet., 15, 227-281, 1978). The average incidence of peripheral location of all races for small, average, large and very large was 3.64, 5.84, 10.51 and 11.17 per cent respectively. For blacks and caucasians, the peripheral location was influenced by its size while the incidence remained the same for Indians for all sizes. Consequently, it is presumed that the position of the Y chromosome in somatic metaphases depends upon race as well as its size. Furthermore, we have provided a method for determining the position of the Y chromosome which should suffice for most situations.

Spatial relationship of human X and Y chromosomes at somatic metaphase

A total of 592 cells was examined from 38 normal humans who had either small or very large Y chromosomes. Chromosome identification was based on the QFQ technique. The distance between the X and Y chromosome was measured from centromere to centromere. The spatial distance between X and Y was significantly smaller when the Y was small as compared to a very large Y (p less than 0.05). The distance increased as the length of the Y chromosome increased and a significant correlation coefficient (r = 0.58) was found (p less than 0.05). It is concluded that the length of the Y chromosome appears to play a major role in the non-random distribution of X and Y at somatic metaphase. The size and XY relationship in aneuploidy resulting from paternal non-disjunction and in patients with XXY and XYY should be investigated.

Progress in visualization of eukaryotic gene transcription

Methods for visualization of the ultrastructure of transcriptionally active eukaryotic genes have been developed using chromatin from giant nuclei of amphibian oocytes (Miller and Beatty 1969). Rapidly isolated chromatin is subjected to low salt treatment in order to dissociate most chromatin associated proteins. As a result, gene-chromatin with associated RNA polymerase particles and RNA transcripts can be directly analysed in electron microscope chromatin spread preparations. More recently, progress has been made in utilising living amphibian oocyte nuclei as a transcription system for cloned eukaryotic genes. In this article, an account of such experiments is given, with emphasis on results and problems of chromatin and transcription organization of microinjected cloned genes. The described transcription assay system possesses important potential for investigation of gene mutations and in particular for the elucidation of molecular aspects of experimental oncology and molecular human genetics.

Sex chromosome-specific DNA sequences

Genetic linkage analysis using restriction fragment length polymorphisms is feasible for a human sex-linked disorder even when the primary gene product is not known. Distant probes localise a defect, while more closely linked clones can be used either for unambiguous carrier detection, particularly if sequences on both sides of the gene defect can be isolated, or for prenatal diagnosis using DNA obtained in early pregnancy by trophoblast sampling. Furthermore, with the isolation of sex chromosome libraries and the development of molecular biological techniques, a greater understanding of the basis of gonadal differentiation and sex-linked diseases should be achieved in the next few years.

Comparative DNA/DNA reassociation kinetics in three hamster species

1. Three major DNA repetition classes can be distinguished in the genomes of three hamster species Mesocricetus auratus, Cricetulus griseus, and Phodopus sungorus sungorus: A very fast reassociating fraction of about 13% of the DNA, a fast reassociating fraction comprising 10-23% of the DNA, and a slowly reassociating fraction containing single-copy sequences of 63-78% of hamster DNA. 2. In the DNA of the Syrian and Djungarian hamster 43%-53%, and in the DNA of the Chinese hamster 80% of the single-copy sequences are interspersed with repetitive sequences. 3. The lengths of repetitive DNA sequences, vary between more than 3 kb and 0.3 kb, with the majority of sequences having a length of 0.3 kb to 0.5 kb. 4. The findings suggest that the genomes of the hamster species studied are organized in a short period interspersion pattern. 5. Unlike other vertebrate and invertebrate genomes, moderately repetitive sequences exhibit a high degree of intraspecific homology in the hamster genome.

The application of DNA recombinant technology to the analysis of the human genome and genetic disease

Recombinant DNA technology permits the isolation of libraries of DNA sequences corresponding to either the whole genome of an individual or the expressed sequences of a given cell type. Gene-specific probes isolated from these libraries may be used for the identification of DNA sequences in the genome necessary for normal gene function and for the study of the consequences of mutations and rearrangements in these sequences which give rise to the clinical symptoms in genetic disease. DNA sequence polymorphisms can be used to construct a genetic linkage map of the entire human genome. This allows the development of antenatal diagnoses for monogenic diseases even in the absence of an understanding of the biochemical defect.