Gene distribution and nucleotide sequence organization in the mouse genome

Mouse DNA was fractionated by preparative centrifugation in density gradients of Cs2SO4 containing 3,6-bis(acetatomercurimethyl)dioxane (BAMD). The effects of temperature, BAMD/nucleotide molar ratio and solvent on the fractionation were explored. The fractions so obtained were investigated by analytical centrifugation in CsCl density gradient and by hybridization with a number of gene probes. These approaches led to the definition of satisfactory conditions for the rapid fractionation of mouse DNA; to the localization of a number of genes in mouse DNA fractions; and to a better understanding of the mosaic organization of the mouse genome and, more specifically, to a better estimate of both the intermolecular and intramolecular compositional heterogeneity of mouse DNA in the (75-150) X 10(3)-base size range.     

Structural organization of the tissue-specific middle repetitive sequence of the mouse genome

The structural genes closely linked to the particular middle repetitive sequence (MRS) expressed in liver nuclei were cloned from the mouse genomic library. From one-fourth of 3,200 MRS-containing clones, 21 clones were obtained as mRNA coding sequence-linked MRS clones. From examination of the structural organization and specificity of expression of the MRS and the mRNA coding sequence, it was concluded that expressions of the MRS and the structural genes closely linked to the MRS are independently regulated.     

Complete nucleotide sequence and genome organization of tobacco mosaic virus isolated fromVicia faba

Based on reported TMV-U1 sequence, primers were designed and fragments covering the entire genome of TMV broad bean strain (TMV-B) were obtained with RT-PCR. These fragments were cloned and sequenced and the 5’ and 3’ end sequences of genome were confirmed with RACE. The complete sequence of TMV-B comprises 6 395 nucleotides (nt) and four open reading frames, which correspond to 126 ku (1 116 amino acids), 183 ku (1 616 amino acids), 30 ku (268 amino acids) and 17.5 ku proteins (159 amino acids). The complete nucleotide sequence of TMV-B is 99.4% identical to that of TMV-U1. The two virus isolates share the same sequence of 5’, 3’ non-coding region and 17.5 K ORF, and 6, 1 and 3 amino acid changes are found in 126 K protein, 54 K protein and 30 K protein, respectively. The possible mechanism on the infection of TMV-B inVicia faba is discussed. The EMBL accession number of the sequence reported in this paper is AJ011933.     

Complete nucleotide sequence and genome organization of tobacco mosaic virus isolated from Viciafaba

Based on reported TMV-U1 sequence, primers were designed and fragments covering the entire genome of TMV broad bean strain (TMV-B) were obtained with RT-PCR. These fragments were cloned and sequenced and the 5' and 3' end sequences of genome were confirmed with RACE. The complete sequence of TMV-B comprises 6 395 nucleotides (nt) and four open reading frames, which correspond to 126 ku (1 116 amino acids), 183 ku (1 616 amino acids), 30 ku (268 amino acids) and 17.5 ku proteins (159 amino acids). The complete nucleotide sequence of TMV-B is 99.4% identical to that of TMV-U1. The two virus isolates share the same sequence of 5', 3' non-coding region and 17.5 K ORF, and 6, 1 and 3 amino acid changes are found in 126 K protein, 54 K protein and 30 K protein, respectively. The possible mechanism on the infection of TMV-B in Vicia faba is discussed.     

Complete nucleotide sequence and genome organization of tobacco mosaic virus isolated fromVicia faba

Based on reported TMV-U1 sequence, primers were designed and fragments covering the entire genome of TMV broad bean strain (TMV-B) were obtained with RT-PCR. These fragments were cloned and sequenced and the 5’ and 3’ end sequences of genome were confirmed with RACE. The complete sequence of TMV-B comprises 6 395 nucleotides (nt) and four open reading frames, which correspond to 126 ku (1 116 amino acids), 183 ku (1 616 amino acids), 30 ku (268 amino acids) and 17.5 ku proteins (159 amino acids). The complete nucleotide sequence of TMV-B is 99.4% identical to that of TMV-U1. The two virus isolates share the same sequence of 5’, 3’ non-coding region and 17.5 K ORF, and 6, 1 and 3 amino acid changes are found in 126 K protein, 54 K protein and 30 K protein, respectively. The possible mechanism on the infection of TMV-B inVicia faba is discussed.     

Genomic organization of the canrep repetitive DNA in Brassica juncea

Canrep is a heterogeneous, tandemly repeated, 176 bp nucleotide sequence that contains a single Hind III site and is present in high copy numbers in the genomes of many Brassica species. Complete clusters of repeats of this DNA were cloned from the nuclear DNA of Brassica juncea. Restriction-fragment dimers and higher multimers of the 176 bp sequence have arisen by mutations within the Hind III recognition sequence. Adjacent repeats from within the same cluster usually have different nucleotide sequences with features indicating that diversity is generated by a mechanism that causes site-specific base substitutions. While most of the units of canrep DNA are clustered in long arrays of tandem repeats, some are dispersed throughout the genome as isolated copies or in small clusters. Regardless of the size of the arrays, each cluster begins and ends with a variable-length, truncated repeat and is flanked by inverted copies of the sequence 5-ATCTCAT3-,which is not part of the basic sequence of the canrep family of DNAs. Furthermore, some clusters are located close to nucleotide sequences related to those of known plant transposons. Thus, canrep elements may be dispersed by transposition. There are two distinct subfamilies of canrep sequences in B. juncea, and one of these is closely related to one of the two subfamilies of this type of DNA from B. napus, indicating that it originated from B. campestris, the common diploid ancestor of both amphidiploid species. Neither the repetitive DNA nor nucleotide sequences flanking canrep clusters are transcribed in seedlings, suggesting that even small arrays of repeats are located in heterochromatic regions and might be involved in chromatin condensation and/or chromosome segregation.     

Gene distribution and nucleotide sequence organization in the human genome

Human DNA was fractionated by centrifugation in Cs2SO4 density gradients containing 3,6-bis(acetatomercurimethyl)dioxane (BAMD). Fractions were investigated in their analytical CsCl profiles and a number of specific sequences were localized in them. The results so obtained led to an improved understanding of the organization of nucleotide sequences in the human genome, as well as to the discovery that a class of DNA having a very high G + C content and not represented in the mouse genome, is particularly rich in genes and interspersed repetitive sequences.     

Genomic organization and DNA sequence of the mouse kidney androgen-regulated protein (KAP) gene

The gene for kidney androgen-regulated protein (KAP) is expressed under androgenic control in the epithelial cells of the renal cortical proximal tubules. However, there is an androgen-independent component of the expression of this gene that occurs specifically in the outermedullary S3 segments of the proximal tubules. In these cells, the KAP gene is estrogen responsive and its expression is dependent on pituitary function. As a first step in correlating its interesting cell-specific and hormonal regulation with the structure of the gene, the genomic organization of the KAP gene was described and sequence of the gene and the proximal 1 kb of 5'-flanking DNA was determined. Sequence motifs were identified in the 5'-flanking DNA that may function in the regulation KAP gene expression by androgen, estrogen, and pituitary glycoprotein hormones. The gene is present in a single copy in the mouse genome and is 3,807 nucleotides in length. It contains 4 exons of 120, 177, 63, and 251 nucleotides and three intervening sequences of 1,450, 126, and 1,620 nucleotides. The gene exhibits a high degree of a genetic polymorphism as revealed by comparison of restriction digests of DNA from two highly inbred strains, BALB/c and C57BL/6.     

DNA sequence organization and transcription of the chicken genome

A new approach has been used to examine DNA sequence organization in the chicken genome. The interspersion pattern was determined by studying the fraction of labelled DNA fragments of different lengths that hybridized to an excess of short chicken repeated DNA sequences. The results indicate that chicken DNA has a pattern of sequence organization quite different than the standard ‘Xenopus’ or ‘Drosophila’ patterns. Two classes of unique sequences are found. One, 34% of the genome, consists of unique sequences approx. 4 kb long interspersed with repeated sequences. The second, non-interspersed fraction, 38% of the genome, consists of unique sequences found in long tracts, a minimum of approx. 22 kb in length. In an attempt to determine whether a relationship exists between DNA sequence organization and the distribution of structural genes we have isolated chicken DNA sequences belonging to different interspersion classes and tested each for the presence of structural genes by hybridization to excess poly(A)⁺ mRNA. Sequences complementary to poly(A)⁺ mRNA can be found with approximately the same frequency in both the non-interspersed fraction of the genome and a repeat-contiguous fraction enriched for interspersed sequences.     

DNA sequence organization in the genome of Cycas revoluta

The pattern of DNA sequence organization in the genome of Cycas revoluta was analyzed by DNA/DNA reassociation. Reassociation of 400 base pair (bp) fragments to various C₀t values indicates the presence of at least four kinetic classes: the foldback plus very highly repetitive sequences (15%), the fast repeats (24%), the slow repeats (44%), and the single copy (17%). The latter component reassociates with a rate constant 1×10^–4 M^–1S^–1 corresponding to a complexity of 1.6× 10⁶ kb per haploid genome. A haploid C. revoluta nucleus contains approximately 10.3 pg DNA. The single-copy sequences account for about 28% of the DNA, but only 17% reassociate with single-copy kinetics because of interspersion with repetitive sequences. — The interspersion of repetitive and single-copy sequences was examined by reassociation of DNA fragments of varying length to C₀t values of 70 and 500. A major (65%) and homogeneous class of single-copy sequences averaging 1,100 bp in length is interspersed in a short period pattern with repeated sequences. A minor (35%) heterogeneous single-copy component is interspersed in a long-period pattern. The majority of repetitive sequences have a length distribution of 100–350 bp with subclasses averaging 150 and 300 bp in length. Repeat sequences with a wide range in sizes exceeding 2 kilobase pair (kb) are also present in this genome. — The size and distribution of inverted repeat (ir) sequences in the DNA of C. revoluta were studied by electron microscopy. It is estimated that there are approximately 4 × 10⁶ ir pairs (one per 2.33 kb) that form almost equal numbers of looped and unlooped palindromes. This high value is 2.5 times that found in wheat DNA. These palindromes are in general randomly distributed in the genome with an average interpalindrome distance of 1.6 kb. The majority (about 85%) of ir sequences of both types of palindromes belong to a main-size class, with an average length of 210 bp in the unlooped and and 163 bp in the looped type. These values are comparable to those reported for some other plant and animal genomes. Distribution of length of single stranded loops showed a main-size class (75%) with an average length of 220 bp.     

Complete nucleotide sequence and genome organization of bovine parvovirus.

We determined the complete nucleotide sequence of bovine parvovirus (BPV), an autonomous parvovirus. The sequence is 5,491 nucleotides long. The terminal regions contain nonidentical imperfect palindromic sequences of 150 and 121 nucleotides. In the plus strand, there are three large open reading frames (left ORF, mid ORF, and right ORF) with coding capacities of 729, 255, and 685 amino acids, respectively. As with all parvoviruses studied to date, the left ORF of BPV codes for the nonstructural protein NS-1 and the right ORF codes for the major parts of the three capsid proteins. The mid ORF probably encodes the major part of the nonstructural protein NP-1. There are promoterlike sequences at map units 4.5, 12.8, and 38.7 and polyadenylation signals at map units 61.6, 64.6, and 98.5. BPV has little DNA homology with the defective parvovirus AAV, with the human autonomous parvovirus B19, or with the other autonomous parvoviruses sequenced (canine parvovirus, feline panleukopenia virus, H-1, and minute virus of mice). Even though the overall DNA homology of BPV with other parvoviruses is low, several small regions of high homology are observed when the amino acid sequences encoded by the left and right ORFs are compared. From these comparisons, it can be shown that the evolutionary relationship among the parvoviruses is B19 in equilibrium with AAV in equilibrium with BPV in equilibrium with MVM. The highly conserved amino acid sequences observed among all parvoviruses may be useful in the identification and detection of parvoviruses and in the design of a general parvovirus vaccine.     

DNA sequence organization in the genome of Nicotiana tabacum

The genome of Nicotiana tabacum was investigated by DNA/DNA reassociation for its spectrum of DNA repetition components and pattern of DNA sequence organization. The reassociation of 300 nucleotide DNA fragments analyzed by hydroxyapatite chromatography reveals the presence of three major classes of DNA differing in reiteration frequency. Each class of DNA was isolated and characterized with respect to kinetic homogeneity and thermal properties on melting. These measurements demonstrate that the genome of N. tabacum has a 1C DNA content of 1.65 pg and that DNA sequences are represented an average of 12,400, 252, and 1 times each. — The organization of the DNA sequences in the N. tabacum genome was determined from the reassociation kinetics of long DNA fragments as well as S1 nuclease resistance and hyperchromicity measurements on DNA fragments after annealing to C₀t values at which only repetitive DNA sequences will reassociate. At least 55% of the total DNA sequences are organized in a short period interspersion pattern consisting of an alternation of single copy sequences, averaging 1400 nucleotides, with short repetitive elements approximately 300 nucleotides in length. Another 25% of the genome contains long repetitive DNA sequences having a minimal genomic length of 1500 nucleotides. These repetitive DNA sequences are much less divergent than the short interspersed DNA sequence elements. These results indicate that the pattern of DNA sequence organization in the tobacco genome bears remarkable similarity to that found in the genomes of most animal species investigated to date.     

The organization of DNA sequences in the mouse genome

Analysis of the organization of nucleotide sequences in mouse genome is carried out on total DNA at different fragment size, reannealed to intermediate value of Cot, by Ag⁺-Cs₂SO₄ density gradient centrifugation. — According to nuclease S-1 resistance and kinetic renaturation curves mouse genome appears to be made up of non-repetitive DNA (76% of total DNA), middle repetitive DNA (average repetition frequency 2×10⁴ copies, 15% of total DNA), highly repetitive DNA (8% of total DNA) and fold-back DNA (renatured density 1.701 g/ml, 1% of total DNA).— Non-repetitive sequences are intercalated with short middle repetitive sequences. One third of non-repetitive sequences is longer than 4500 nucleotides, another third is long between 1800 and 4500 nucleotides, and the remainder is shorter than 1800 nucleotides. —Middle repetitive sequences are transcribed in vivo. The majority of the transcribed repeated sequences appears to be not linked to the bulk of non-repeated sequences at a DNA size of 1800 nucleotides. — The organization of mouse genome analyzed by Ag⁺-Cs₂SO₄ density gradient of reannealed DNA appears to be substantially different than that previously observed in human genome using the same technique.     

A unique repetitive DNA sequence in the Myxococcus xanthus genome.

We found a novel type of repetitive DNA sequence in the Myxococcus xanthus genome. The first repetitive sequence is located in the spacer region between the ops and tps genes. We cloned five other repetitive sequences using the first repetitive sequence as a probe and determined their nucleotide sequences. Comparison of these sequences revealed that the repetitive sequences consist of a 87-bp core sequence and that some clones share additional homology on their flanking regions.     

Exploration of long and short repetitive sequence relationships in the sea urchin genome.

Long and short repetitive sequences of sea urchin DNA were prepared by reassociation of 2000 nucleotide long fragments to Cot 4 and digestion with the single strand specific nuclease S1. The S1 resistant duplexes were separated into long repetitive and short repetitive fractions on Agarose A50. The extent of shared sequences was studied by reassociating a labeled preparation of short repetitive DNA with an excess of unlabeled long repetitive DNA. Less than 10% of the long repetitive DNA preparation was able to reassociate with the short repetitive DNA. Thus the long and short repetitive elements appear to be principally independent sequence classes in sea urchin DNA. Precisely reassociating repetitive DNA was prepared by four successive steps of reassociation and thermal chromatography on hydroxyapatite. This fraction (3% of the genome) was reassociated by itself or with a great excess of total sea urchin DNA. The thermal stability of the products was identical in both cases (Tm=81 degrees C), indicating that precisely repeated sequences do not have many imprecise copies in sea urchin DNA.