A unique nucleoprotein structure associated with the Drosophila melanogaster 18-28 S rDNA nontranscribed spacer

We have detected unique nucleoprotein particles specific for the 18-28 S rDNA nontranscribed spacer of Drosophila melanogaster. The particles migrate between di- and trinucleosomes on nucleoprotein gels, and are between mono- and dinucleosomal in DNA length. These migration properties suggest that the nontranscribed spacer particles could have a protein component larger than a histone core. The variant nucleoprotein structures map primarily within the nontranscribed spacer 235 base pair internal subrepeat, which is AT-rich and possesses a 50 base pair sequence homologous to the RNA polymerase I binding site.     

Interaction of a protein with a palindromic sequence from murine rDNA increases the occurrence of amplification-dependent transformation in mouse cells

muNTS1, an element isolated from the nontranscribed spacer of murine rDNA, increases the occurrence of amplification-dependent transformation in mouse cells when integrated into plasmid DNA containing a selectable marker (Wegner, M., Zastrow, G., Klavinius, A., Schwender, S., Müller, F., Luksza, H., Hoppe, J., Wienberg, J., and Grummt, F. (1989) Nucleic Acids Res. 17, 9909-9932). In an initial attempt to dissect muNTS1 into its structural components we localized part of the transformation increasing activity to a long AT-rich stretch from the 5' region which interacts with HMG-I. Here we identify a second element on muNTS1 which also stimulates the rate of amplification-coupled transformation in cis. It is found in the 3' region of muNTS1 and contains the 11-base pair palindrome ATGGCTGCCAT. It is conserved in the otherwise strongly divergent ribosomal NTS regions from mouse, rat, and man and is also found in the origin/enhancer region of human papovavirus JC. The palindromic sequence interacts specifically with proteins from mouse cell extracts. Protein-DNA interaction was dependent on the presence of zinc ions in the extract. Point-specific mutations within the palindrome reduced protein-DNA complex formation substantially and concomitantly abolished the ability to stimulate the frequency of transformation. The binding activity was purified and shown to consist of two polypeptides with molecular masses of 70 and 73 kDa.     

Structural homologies and functional similarities between mammalian origins of replication and amplification promoting sequences

MuNTS2, a 423 bp sequence isolated from the non-transcribed spacer of murine rDNA stimulates the amplification of cis-linked plasmid DNA in mouse cells under selective conditions. Here we demonstrate that a 180 bp subdomain of muNTS2 is highly homologous (approximately 70%) to three domains of the first well-characterized origin of replication of mammalian chromosomes, i.e. the origin of bidirectional replication (OBR) of the dihydrofolate reductase (DHFR) locus in Chinese hamester ovary (CHO) cells. When subcloned, the 180 bp homology region of muNTS2 was revealed to be essential for the amplification promoting activity of muNTS2. Fragments of the initiation zone of DNA replication from the DHFR locus of hamster cells containing the domains of homology to the mouse muNTS2 element proved also to promote DNA amplification. Thus, the screening system for amplification promoting elements turned out to detect an origin of bidirectional replication.     

Organization of ribosomal RNA gene repeats of the mouse.

The organization of the ribosomal RNA (rRNA) genes of the mouse was determined by Southern blot hybridization using cloned rDNA fragments as probes, which could encompass the entire spacer region between two rRNA gene regions. The rRNA genes are organized into tandem repeats of nearly uniform length of about 44 kb. The heterogeneity detected in the nontranscribed spacer appears to be caused by its sequence rather than its length difference. At least three kinds of repetitive sequences are present in the non-transcribed spacer region; two of them are located 13 kb upstream from the 5'-end of 18S RNA gene and the other located 1 to 4 kb downstream from the 3'-end of 28S RNA gene.     

Interaction of nucleolar phosphoprotein C23 with cloned segments of rat ribosomal deoxyribonucleic acid

Protein C23, a predominant nucleolar phosphoprotein and a putative nucleolus organizer protein, was analyzed for its general DNA binding characteristics and for its selectivity in binding plasmid DNAs containing cloned fragments of the genes that code for ribosomal RNA (rDNA). By use of nitrocellulose filter disk assays, the protein bound saturably to nuclear DNA with a relatively high affinity. Binding was maximal at low ionic strength (0-0.1 M KCl) with progressively decreasing binding at or above 0.2 M. In competition assays protein C23 showed a marked preference for linear single-stranded vs. double-stranded DNA and little or no affinity for ribosomal RNA. The relative affinities of rDNA sequences for protein C23 were determined with cloned fragments spanning 15.8 kilobases (kb) of DNA starting approximately 3.7 kb upstream from the initiation site for 45S preribosomal RNA to near the 3' end of the sequence coding for 28S RNA. Of the five linearized plasmids tested, only one (pKW1) was an effective competitor for 32P-labeled nuclear DNA. As measured by the concentration of competing DNA required to achieve 50% competition, pKW1 was approximately 20-fold more effective than the second best competitor. The DNA insert in pKW1 is a 3.5-kb sequence which is located in the nontranscribed spacer region less than 0.5 kb upstream from the initiation site for 45S preribosomal RNA. These results suggest that protein C23 has a preference for binding DNA sequences in the nontranscribed spacer of rDNA.     

Sequence polymorphism and chromosomal localization of 5S rDNA of three cultivated varieties of sweetpotato (Ipomoea batatas (L.) Lam.)

The 5S rDNA of plant is organized into clusters of tandem repeat units which include a coding region of 5S rRNA gene and variable sequences of nontranscribed spacer (NTS). In this study, we investigated sequence polymorphism and chromosomal localization of 5S rDNA in three cultivated varieties of sweet potato (Ipomoea batatas Lam.). Two different PCR products of 5S rDNA were amplified from all three varieties, as approximately 0.25 kb and 0.34 kb with multiples. In sequence analysis, the 5S rDNA ofI. batatas were discriminated from four consensus sequences by in reasonable sizes and molecular informative factors. Four consensus sequences were divided into three short sequences, including 263, 253, and 243 – 283 bp by sequence variation between 160 and 186 bp in NTS region, and one long sequence with 340 bp. To identify molecular relationship among varieties, phylogenetic analysis was applied. A total of 35 sequenced clones in this study were classified into four groups in phylogenetic tree. Interestingly, two varieties included all four groups, but one variety only two groups. To localize the physical map of 5S rDNA, fluorescencein situ hybridization (FISH) was performed in metaphase chromosomes of each varieties. In 90 chromosomes ofI. batatas, 6 loci of 5S rDNA were detected in chromosomes for all varieties. Our results will help to further more understand the genomic relationship inI. batatas, to investigate molecular relationship among varieties.     

Sequence organization of two recombinant plasmids containing genes for the major heat shock-induced protein of D. melanogaster.

We have isolated recombinant DNA clones which include cDNA and chromosomal DNA sequences of the major heat shock-inducible gene of Drosophila. With the cDNA fragments used as specific hybridization probes, DNA:DNA reassociation and in situ hybridization analysis demonstrated that the DNA sequences are repeated approximately 7 times in the haploid Drosophila genome, and that gene sequences are present at both the 87A and 87C loci on the cytological map. The cloned cDNA and homologous cloned chromosomal DNA hybridized to mRNA which translated in vitro into the major 70K heat shock-specific protein. Here we summarize a study of the organization of genes coding for the 70K heat shock-specific protein contained in the two recombinant chromosomal DNA plasmids pG3 and pG5. On the basis of R loop hybridization experiments and restriction enzyme analysis, we conclude that a 14 kb fragment, G3, contains three copies of the gene coding for the 70K protein. A second 9.2 kb fragment, G5, contains one copy of the gene coding for the 70K protein. Hybridization of labeled poly(A)-containing RNA to restriction endonuclease-cleaved DNA indicates that the mRNA coding regions in G3 and G5 are each approximately 2100 bp long. The three tandemly repeated genes of G3 are separated by approximately 1400 bp of spacer DNA. The two internal spacer regions in G3 appear to be identical, whereas differences in restriction enzyme sites indicate that the sequences adjacent to the cluster differ from the internal spacer and from each other.