DNA repair defects associated with chromosomal translocation breaksite regions.

Using an assay that measures the removal of UV-induced pyrimidine dimers in specific DNA sequences, we have found that the Pvt-1, immunoglobulin H-C alpha (IgH-C alpha), and IgL-kappa loci are poorly repaired in normal B lymphoblasts from plasmacytoma-susceptible BALB/cAnPt mice. Breaksites in these genes are associated with the chromosomal translocations that are found in > 95% of BALB/cAnPt plasmacytomas. In contrast to those from BALB/cAnPt mice, B lymphoblasts from plasmacytoma-resistant DBA/2N mice rapidly repair Pvt-1, IgH-C alpha, and IgL-kappa. Further, (BALB/cAnPt x DBA/2N)F1 hybrids, which are resistant to plasmacytoma development, carry an efficient (DBA/2N-like) repair phenotype. Analysis of allele-specific repair in the IgH-C alpha locus indicates that efficient repair is controlled by dominant, trans-acting factors. In the F1 heterozygotes, these factors promote efficient repair of BALB/cAnPt IgH-C alpha gene sequences. The same sequences are poorly repaired in the BALB/cAnPt parental strain. Analysis of the strand specificity of repair indicates that both strand-selective and nonselective forms of repair determine repair efficiency at the gene level in nonimmortalized murine B lymphoblasts.     

Strong sequence patterns in eukaryotic promoter regions: Potential implications for DNA structure

• 1.1. Analysis of eukaryotic sequences reveals recurring trends in upstream regions. Oligomers composed of (G/C)_n and (A/T)_m blocks are preferentially flanked by (G/C)₂ doublets on their 3' rather than on their 5′ ends, that is (G/C)_nä(A/T)_m(G/C)₂ > (G/C)_n+2(A/T)_m.
• 2.2. These trends are stronger for larger n and smaller m. Additional trends are outlined below.
• 3.3. The trends are correlated with DNA structural parameters, in particular with twist and roll angles.
• 4.4. Generally, the trends hold if the base pair step joining the 5′ (G/C)₂ doublet to the (G/C)_n (A/T)_m oligomer is not undertwisted and is not strongly rolled into the major groove.
• 5.5. Other DNA parameters crucial for DNA-protein interactions are discussed as well.

     

Association of eukaryotic DNA topoisomerase I with nucleosomes and chromosomal proteins.

A DNA topoisomerase activity is found to be associated with the nucleosomes released by the Staphylococcal nuclease digestion of HeLa nuclei. Such an association is found to be salt dependent. A number of criteria have established that this DNA topoisomerase activity is due to HeLa topo I (Liu, L. F. and Miller, K. G. (1980) Proc. Natl. Acad. Sci. USA 78, 3489-3491). A similar association has been demonstrated from the in vitro studies using purified mononucleosomes and eukaryotic DNA topoisomerase I. Nonhistone HMG proteins and histone H1 are found to stimulate topoisomerase activity in vitro and form tight complexes with eukaryotic DNA topoisomerase I. The intimate interactions of topoisomerase I with chromosomal proteins and nucleosomes may be an essential feature of the topoisomerase function in vivo.     

Control of eukaryotic DNA replication at the chromosomal level.

A hypothesis for the control of eukaryotic DNA replication at the chromosomal level is proposed. The specific regulatory problem arises from the subdivision of the genome into thousands of individually replicating units, each of which must be duplicated a single time during S-phase. The hypothesis is based on the finding of direct repeats at replication origins. Such repeats can adopt, beyond the full-length double helical structure, another configuration exposing two single-stranded loops that provide suitable templates for the initiation of DNA replication. Any further initiation at the same origin is excluded as the single strandedness is eliminated by the replication process. Restoration of the initiable loop structure is proposed to occur by DNA-protein rearrangements involved in chromosome condensation and duplication of the chromosomal protein backbone during mitosis. A possible role of the maturation promoting factor (MPF) is suggested.     

Modular structural elements in the replication origin region of Tetrahymena rDNA.

Computer analyses of the DNA replication origin region in the amplified rRNA genes of Tetrahymena thermophila identified a potential initiation zone in the 5'NTS [Dobbs, Shaiu and Benbow (1994), Nucleic Acids Res. 22, 2479-2489]. This region consists of a putative DNA unwinding element (DUE) aligned with predicted bent DNA segments, nuclear matrix or scaffold associated region (MAR/SAR) consensus sequences, and other common modular sequence elements previously shown to be clustered in eukaryotic chromosomal origin regions. In this study, two mung bean nuclease-hypersensitive sites in super-coiled plasmid DNA were localized within the major DUE-like element predicted by thermodynamic analyses. Three restriction fragments of the 5'NTS region predicted to contain bent DNA segments exhibited anomalous migration characteristic of bent DNA during electrophoresis on polyacrylamide gels. Restriction fragments containing the 5'NTS region bound Tetrahymena nuclear matrices in an in vitro binding assay, consistent with an association of the replication origin region with the nuclear matrix in vivo. The direct demonstration in a protozoan origin region of elements previously identified in Drosophila, chick and mammalian origin regions suggests that clusters of modular structural elements may be a conserved feature of eukaryotic chromosomal origins of replication.     

Ori-somes, nucleoprotein complexes descending from origin regions of animal chromosomal DNA replication. A micromorphological study.

Micromorphology of nucleoprotein (NP) complexes designated according to their descent and shape as Ori-somes is presented. These NP complexes of three different types harbor molecules of cytoplasmic "small" polydisperse DNA, which descend from origin regions of chromosomal DNA replication and are equipped, as shown previously, with early DNA-synthesizing activities. By negative staining the Ori-somes are visualized as particles of irregular shape, sometimes of a subunit-like structure. Micromorphological differences in size and structural compactness noted among individual Ori-somes are dependent on their type similarly as earlier shown physico-chemically and biochemically. Such differences were also confirmed by two different spreading techniques. The most unravelled structures with electron diffuse centers belong to Ori-somes of component B associated with most active DNA synthesis. In contrast, the Ori-somes of components A and C, associated with pronounced RNA synthesis, revealed large electron-dense centers. The incidence of replicative structures present in Ori-somes corresponds with the level of their DNA-synthesizing activities.     

DNA sequence selection by tightly-bound nonhistone chromosomal proteins.

Extraction of chicken reticulocyte chromatin with 2.0 M NaCl removed 96% of chromosomal protein and yields two DNA components after dialysis and high-speed centrifugation. The bulk of chromosomal DNA (ca. 99%) is rendered free of protein, and is thus soluble in 10 mM Tris-HCl, pH 8.0. The other component (ca. 1%) displays a high protein/DNA ratio, and is insoluble in 10mM Tris-HCl, pH 8.0. These DNAs can be separated on the basis of their solubilities. Analysis of the reassociation kinetics with total chicken DNA of these DNAs reveals marked differences. Whereas total DNA and the soluble component (DNA-S) have rapidly reassociating components, the insoluble component (DNA-P) is devoid of these components, and is therefore composed completely of unique sequence DNA. Cot 1/2 values indicate that DNA-S is substantially depleted of some DNA-P sequences. We conclude that this segregation, as determined by tightly-bound nonhistone chromosomal proteins, selects a subset of total genomic DNA sequences, and suggests sequence-specific interaction between the tightly-bound nonhistones and DNA.     

Conserved sequence elements associated with exon skipping

One of the major forms of alternative splicing, which generates multiple mRNA isoforms differing in the precise combinations of their exon sequences, is exon skipping. While in constitutive splicing all exons are included, in the skipped pattern(s) one or more exons are skipped. The regulation of this process is still not well understood; so far, cis- regulatory elements (such as exonic splicing enhancers) were identified in individual cases. We therefore set to investigate the possibility that exon skipping is controlled by sequences in the adjacent introns. We employed a computer analysis on 54 sequences documented as undergoing exon skipping, and identified two motifs both in the upstream and downstream introns of the skipped exons. One motif is highly enriched in pyrimidines (mostly C residues), and the other motif is highly enriched in purines (mostly G residues). The two motifs differ from the known cis-elements present at the 5′ and 3′ splice site. Interestingly, the two motifs are complementary, and their relative positional order is conserved in the flanking introns. These suggest that base pairing interactions can underlie a mechanism that involves secondary structure to regulate exon skipping. Remarkably, the two motifs are conserved in mouse orthologous genes that undergo exon skipping.     

Variation in chromosomal DNA associated with the evolution of Arachis species.

The 2C nuclear DNA amounts were determined for 99 accessions, representing 23 Arachis species from 8 of 9 taxonomic sections, and two synthetic amphidiploids. Mean 2C DNA amounts varied by 15.20%, ranging from 10.26 to 11.82 pg, between accessions of Arachis hypogaea (2n = 4x = 40). Nuclear DNA content variation (5.33-5.91 pg) was also detected among Arachis duranensis (2n = 2x = 20) accessions. The intraspecific variation in the two species may have resulted from indirect selection for favourable genome sizes in particular environmental conditions. The accessions belonging to A. hypogaea ssp. hypogaea (mean value 11.27 pg) with longer life cycle had significantly larger mean DNA content than the accessions of A. hypogaea ssp. fastigiata (mean value 10.97 pg). For 20 diploid (2n = 2x = 20) species of the genus, 2C nuclear DNA amounts ranged from approximately 3 to 7 pg. The diploid perennial species of section Arachis have about 12% more DNA than the annual species. Comparisons of DNA amounts show that evolutionary rating is not a reliable guide to DNA amounts in generic sections of the genus; lower DNA values with evolutionary advancement were found in sections Heteranthae and Triseminatae, but the same was not true for sections Arachis and Caulorrhizae. Similarly, there is evidence of significant differences in DNA content between 4 ancient sections (Procumbentes, Erectoides, Rhizomatosae, and Extranervosae) of the genus. The occurrence of genome size plasticity in both A. duranensis and A. hypogaea provides evidence that A. duranensis could be one of the diploid progenitors of A. hypogaea. The DNA content in the two synthetic amphidiploids corresponded to the sum value estimated for parental species. Key words : Arachis species, genome size, Arachis hypogaea, Arachis duranensis, intraspecific variation.     

The Chinese hamster dihydrofolate reductase replication origin beta is active at multiple ectopic chromosomal locations and requires specific DNA sequence elements for activity

To identify cis-acting genetic elements essential for mammalian chromosomal DNA replication, a 5.8-kb fragment from the Chinese hamster dihydrofolate reductase (DHFR) locus containing the origin beta (ori-beta) initiation region was stably transfected into random ectopic chromosomal locations in a hamster cell line lacking the endogenous DHFR locus. Initiation at ectopic ori-beta in uncloned pools of transfected cells was measured using a competitive PCR-based nascent strand abundance assay and shown to mimic that at the endogenous ori-beta region in Chinese hamster ovary K1 cells. Initiation activity of three ectopic ori-beta deletion mutants was reduced, while the activity of another deletion mutant was enhanced. The results suggest that a 5.8-kb fragment of the DHFR ori-beta region is sufficient to direct initiation and that specific DNA sequences in the ori-beta region are required for efficient initiation activity.     

Nucleotide sequence analysis of a mouse Y chromosomal DNA fragment containing Bkm and LINE elements

The strong suppression of crossing-over between the X and Y chromosomes permits rapid accumulation of repetitive sequences in the Y chromosome. To gain insight into the mechanism responsible for the sequence amplification, it is essential to characterize Y chromosomal repetitive sequences at the molecular level. Here, we report the entire nucleotide sequence (3,902bp) of AC11, a mouse sequence that is repeated 300 times in the Y chromosome. AC11 is AT rich (32.8% GC), and contains many short poly(A) sequences. In addition, it has Bkm and LINE sequences as well as a Y chromosome-specific sequence. The Bkm sequence consists of typical (GATA) and (GACA) repeating units, whereas the LINE sequence deviates considerably from other mouse LINE sequences (71–76% identity) and may be considered atypical. The Y chromosome-specific region seems to be unique and does not identify similar sequences in the GenBank library. The information obtained from the nucleotide sequence should form the foundation to study the evolutionary processes through which AC11-related sequences have accumulated in the mouse Y chromosome.     

cis-active elements from mouse chromosomal DNA suppress simian virus 40 DNA replication.

Simian virus 40 (SV40)-containing DNA was rescued after the fusion of SV40-transformed VLM cells with permissive COS1 monkey cells and cloned, and prototype plasmid clones were characterized. A 2-kilobase mouse DNA fragment fused with the rescued SV40 DNA, and derived from mouse DNA flanking the single insert of SV40 DNA in VLM cells, was sequenced. Insertion of the intact rescued mouse sequence, or two nonoverlapping fragments of it, into wild-type SV40 plasmid DNA suppressed replication of the plasmid in TC7 monkey cells, although the plasmids expressed replication-competent T antigen. Rat cells were transformed with linearized wild-type SV40 plasmid DNA with or without fragments of the mouse DNA in cis. Although all of the rat cell lines expressed approximately equal amounts of T antigen and p53, transformants carrying SV40 DNA linked to either of the same two replication suppressor fragments produced significantly less free SV40 DNA after fusion with permissive cells than those transformed by SV40 DNA without a cellular insert or with a cellular insert lacking suppressor activity. The results suggest that two independent segments of cellular DNA act in cis to suppress SV40 replication in vivo, either as a plasmid or integrated in chromosomal DNA.     

Evolutionarily conserved regions in Caenorhabditis transposable elements deduced by sequence comparison.

In this paper we present the sequence of an intact Caenorhabditis briggsae transposable element, Tcb2. Tcb2 is 1606 base pairs in length and contains 80 base pair imperfect terminal repeats and a single open reading frame. We have identified blocks of T-rich repeats in the regions 150-200 and 1421-1476 of this element which are conserved in the Caenorhabditis elegans element Tc1. The sequence conservation of these regions in elements from different Caenorhabditis species suggests that they are of functional importance. A single open reading frame corresponding to the major open reading frame of Tc1 is conserved among Tc1, Tcb1, and Tcb2. Comparison of the first 550 nucleotides of the sequence among the three elements has allowed the evaluation of a model proposing an extension of the major open reading frame. Our data support the suggestion that Tc1 is capable of producing a 335 amino acid protein. A comparison of the sequence coding for the amino and carboxy termini of the 273 amino acid transposase from Caenorhabditis Tc1-like elements and Drosophila HB1 showed different amounts of divergence for each of these regions, indicating that the two functional domains have undergone different amounts of selection. Our data are not compatible with the proposal that Tc1-related sequences have been acquired via horizontal transmission. The divergence of Tc1 from the two C. briggsae elements, Tcb1 and Tcb2, indicated that all three elements have been diverging from each other for approximately the same amount of time as the genomes of the two species.     

Role of conserved sequence elements in yeast centromere DNA.

Conserved sequence features in Saccharomyces cerevisiae CEN DNA are confined to a region of approximately 120 bp. The highly conserved 8 bp at the left (PuTCACPuTG) constitute the left boundary of a functional CEN DNA as shown by the analysis of a series of Bal31 deletions. The right boundary of a functional CEN DNA lies within the conserved 25 bp at the right (TGT-T-TG--TTCCGAA-----AAA) or a few base pairs further outside of the 120-bp region. One mutant which just lacks the left conserved DNA element PuTCACPuTG can still assemble into a partially functional mitotic centromere and it assembles into a well functioning meiotic centromere. The sequences between the two conserved terminal DNA elements can be increased in length (+50%) or in GC content (from 6% to 12%) without measurable changes in mitotic and meiotic segregations of plasmids carrying such CEN mutations. The naturally occurring length and GC content of this centromere DNA sequence element is, therefore, not essential for centromere function. We discuss the possibility that it partly acts as a hinge region between two domains. Finally, we tested integrations of CEN DNA into the genome and found a toleration of wild-type CEN6 DNA when present 3' of the LYS2 gene.     

A bipartite sequence element associated with matrix/scaffold attachment regions.

We have identified a MAR/SAR recognition signature (MRS) which is common to a large group of matrix and scaffold attachment regions. The MRS is composed of two degenerate sequences (AATAAYAA and AWWRTAANNWWGNNNC) within close proximity. Analysis of >300 kb of genomic sequence from a variety of eukaryotic organisms shows that the MRS faithfully predicts 80% of MARs and SARs. In each case where we find a MRS, the corresponding DNA region binds specifically to the nuclear scaffold. Although all MRSs are associated with a SAR, not all known SARs and MARs contain a MRS, suggesting that at least two classes exist, one containing a MRS, the other not. Evidence is presented that the two sequence elements of the bipartite MRS occupy a position on the nucleosome near the dyad axis, together creating a putative protein binding site. The identification of a MAR- and SAR-associated DNA element is an important step forward towards understanding the molecular mechanisms of these elements. It will allow: (i) analysis of the genomic location of SARs, e.g. in relationship to genes, based on sequence information alone, rather than on the basis of an elaborate biochemical assay; (ii) identification and analysis of proteins that specifically bind to the MRS.     

Occurrence of protein structure elements in conserved sequence regions

Background  

Conserved protein sequence regions are extremely useful for identifying and studying functionally and structurally important regions. By means of an integrated analysis of large-scale protein structure and sequence data, structural features of conserved protein sequence regions were identified.     

The ARS consensus sequence is required for chromosomal origin function in Saccharomyces cerevisiae.

Replication origins have been mapped to positions that coincide, within experimental error (several hundred base pairs), with ARS elements. To determine whether the DNA sequences required for ARS function on plasmids are required for chromosomal origin function, the chromosomal copy of ARS306 was deleted and the chromosomal copy of ARS307 was replaced with mutant derivatives of ARS307 containing single point mutations in domain A within the ARS core consensus sequence. The chromosomal origin function of these derivatives was assayed by two-dimensional agarose gel electrophoresis. Deletion of ARS306 deleted the associated replication origin. The effects on chromosomal origin function of mutations in domain A paralleled their effects on ARS function, as measured by plasmid stability. These results demonstrate that chromosomal origin function is a property of the ARS element itself.