Nonallelic histone gene clusters of individual sea urchins (Lytechinus pictus): mapping of homologies in coding and spacer DNA

The linear arrangement and lengths of the spacers and coding regions in the two nonallelic histone gene variant clusters of L. pictus are remarkably homologous by R loop analysis and are similar in general topography to the histone gene repeat units of other sea urchins examined to date. No interventing sequences were detected. The coding regions of these two histone gene variants share considerable sequence homology; however, there are areas of nonhomology in every spacer region and the lengths of the nonhomologous spacers between the H2A and H1 genes are not the same for the two repeat unit classes (inter-gene heterogeneity). Combining length measurements obtained with both R loops and heteroduplexes suggests that the DNA sequences of the analogous leader regions for the two H1 mRNAs are nonhomologous. Similar observations were made for the H4 leader sequences, as well as the trailer region on H2B. S. purpuratus spacer DNA segments share little sequence homology with L. pictus; however, the analgous coding (and possibly flanking) regions have conserved their sequences. The various coding and spacer regions within a repeat unit do not share DNA sequences. Thus certain areas in the sea urchin histone gene repeat units have been highly conserved during evolution, while other areas have been allowed to undergo considerable sequence change not only between species but within a species.     

Molecular and chromosomal organization of DNA sequences coding for the ribosomal RNAs in cereals

The chromosomal locations of ribosomal DNA in wheat, rye and barley have been determined by in situ hybridization using high specific activity ¹²⁵I-rRNA. The 18S-5.8S-26S rRNA gene repeat units in hexaploid wheat (cv. Chinese Spring) are on chromosomes 1B, 6B and 5D. In rye (cv. Imperial) the repeat units occur at a single site on chromosome 1R(E), while in barley (cv. Clipper) they are on both the chromosomes (6 and 7) which show secondary constrictions. In wheat and rye the major 5S RNA gene sites are close to the cytological secondary constrictions where the 18S-5.8S-26S repeating units are found, but in barley the site is on a chromosome not carrying the other rDNA sequences. — Restriction enzyme and R-loop analyses showed the 18S-5.8S-26S repeating units to be approximately 9.5 kb long in wheat, 9.0 kb in rye and barley to have two repeat lengths of 9.5 kb and 10 kb. Electron microscopic and restriction enzyme data suggest that the two barley forms may not be interpersed. Digestion with EcoR1 gave similar patterns in the three species, with a single site in the 26S gene. Bam H1 digestion detected heterogeneity in the spacer regions of the two different repeats in barley, while in rye and wheat heterogeneity was shown within the 26S coding sequence by an absence of an effective Bam H1 site in some repeat units. EcoR1 and Bam H1 restriction sites have been mapped in each species. — The repeat unit of the 5S RNA genes was approximately 0.5 kb in wheat and rye and heterogeneity was evident. The analysis of the 5S RNA genes emphasizes the homoeology between chromosomes 1B of wheat and 1R of rye since both have these genes in the same position relative to the secondary constriction. In barley we did not find a dominant monomer repeat unit for the 5S genes.     

Hepatitis B virus transcripts in a human hepatoma cell line, Hep 3B

Hep 3B, a human hepatoma cell line was examined for its RNA hybridizable to the hepatitis B virus sequence. Using probes that covered different regions of the hepatitis B virus genome, five species of RNA were observed of sizes 4.0, 3.3, 2.9, 2.6 and 2.2 kilobases. The RNAs covered surface antigen gene, pre-S and X regions. None of them had a core antigen sequence. RNA with a 4.0 kilobase size was the most abundant. Using S1 nuclease analysis, its 5' end of hepatitis B virus sequence was mapped at pre-S region and its 3' end of viral sequence was mapped at DR region.     

Genetic heterogeneity of Borrelia afzelii in the natural focus of the Middle Urals

As shown by sequencing the spacer rrf (5S)--rrl (23S) in 72 isolates of B. afzelii (one of the causative agents of Ixodes tick borne Borrelia infections) and the chromosomal gene coding protein P66 in 22 isolates, that in the natural focus located in the Middle Urals two different genetic subgroups (VS461 and NT28) of this genospecies simultaneously circulate. These subgroups are represented by 5 gene variants (rrf) 5S--(rrl) 23S and 5 allelic variants in gene p66. The latter, similarly to spacer gene variants, are not linked with a definite host and occur in different rrf--rrl variants of the infective agent. At the same time the definite species of vectors and carriers may be the host of several different B. afzelii variants, both in the spacer and in the gene coding protein P66, which maintains the genetic heterogeneity of B. afzelii population in the natural focus.     

Characterization of the 7S RNA and its gene from halobacteria.

The 7S RNA is an abundant nonribosomal RNA in H. halobium and other halobacteria. A specific 7S RNA gene probe shows high homology to genomic DNA of all halobacteria tested but not to those of several other archaebacteria, eubacteria and eukaryotes. All halobacterial genomes seem to carry a single copy of the 7S RNA gene. The coding region of the 7S RNA gene is highly G+C rich whereas the 5'- and 3'-noncoding regions possess a rather low G+C content. An extended double stranded structure for the 7S RNA is deduced from its nucleotide sequence. The 7S RNA of H. halobium (304 nucleotides) resembles in size and structure the 7S-L RNA from mammalian cells and shares with it a sequence homology of about 50% when arranged in a colinear fashion. The similarities in sequence are found particularly at the 3'- and 5'-termini. No similarity was detected between the 7S RNA from H. halobium and the nonribosomal 6S RNA from Escherichia coli.     

Dispersed 5S RNA genes in N. crassa: structure, expression and evolution

The 5S RNA genes (5S genes) in N. crassa are not tandemly arranged or tightly clustered as in other eucaryotes that have been examined. 55 RNA or cloned 5S DNA hybridizes to at least 30 different restriction fragments of Neurospora DNA. Of 34 5S DNA clones examined, each contains a single 5S gene. Saturation hybridization analyses indicate that there are about 100 copies of 5S genes in the genome of this organism. We have partially or completely sequenced the 5S region of 15 clones. Both identical and highly divergent 5S coding regions were found. Nine are of one type (alpha). The other six include four different types (beta, beta', gamma and delta) which differ from each other and from the alpha genes to various degrees. Eleven of 15 genes have distinct flanking regions. Analysis of Neurospora 5S RNA showed that it consists of one principal species which matches the alpha-type gene sequence. Additional 5S species corresponding to the less abundant 5S gene types were also detected. The pattern of nucleotide substitutions between the predicted Neurospora 5S RNAs and between these and S. cerevisiae 5S RNA suggests that a particular 5S RNA secondary structure occurs in vivo and is conserved.     

Polymorphism in the structure of the yeast mitochondrial tRNA synthesis locus.

Yeast mitochondrial DNA contains a genetic locus, called the tRNA synthesis locus, which codes for information necessary for mitochondrial tRNA biosynthesis. A 9S RNA molecule coded by this locus is thought to be the trans-acting element required for the removal of 5' extensions from tRNA precursors. The DNA coding for this RNA maps to a region of mitochondrial DNA known to contain strain specific restriction site polymorphisms. Comparison of the tRNA synthesis locus in two such strains by sequence analysis demonstrates that the restriction enzyme polymorphisms are due to the deletion/insertion of a 50 base pair GC-rich element in the 5' flanking sequence of the 9S RNA coding region. There are also several differences between the 9S RNA coding region of these two strains which do not interfere with the tRNA synthesis function.     

Sequence and heterogeneity in the 5S RNA gene cluster of Drosophila melanogaster.

The sequence of the entire 5S RNA gene of Drosophila melanogaster was determined by sequencing collectively 23 copies contained in a cloned fragment of Drosophila DNA and by sequencing individually four subcloned gene copies. A repetitive heptamer (GCTG CCT) present in variable numbers immediately following the coding sequence, is responsible for the length heterogeneity in the spacer region. Some of the gene copies contain a nucleotide change in the coding region which results in a new site for the restriction enzyme Mn1 I. The variant 5S RNA produced by these gene copies has not been detected in vivo. Two other single nucleotide variations were identified in the spacer region.     

Euglena gracilis chloroplast ribosomal RNA transcription units. Nucleotide sequence polymorphism in 5 S rRNA genes and 5 S rRNAs

The three tandemly repeated ribosomal RNA operons from the chloroplast genome of Euglena gracilis Klebs, Pringsheim Strain Z each contain a 5 S rRNA gene distal to the 23 S rRNA gene (Gray, P.W., and Hallick, R.B. (1979) Biochemistry 18, 1820-1825). We have cloned two distinct 5 S rRNA genes, and determined the DNA sequence of the genes, their 5'- and 3'-flanking sequences, and the 3'-end of the adjacent 23 S rRNA genes. The two genes exhibit sequence polymorphism at five bases within the "procaryotic loop" coding region, as well as internal restriction endonuclease site heterogeneity. These restriction endonuclease site polymorphisms are evident in chloroplast DNA, and not just the cloned examples of 5 S genes. Chloroplast 5 S rRNA was isolated, end labeled, and sequenced by partial enzymatic degradation. The same polymorphisms found in 5 S rDNA are present in 5 S rRNA. Therefore, both types of 5 S rRNA genes are transcribed and are present in chloroplast ribosomes.     

The nucleotide sequence of the 4.5S and 5S rRNA genes and flanking regions from Spirodela oligorhiza chloroplasts

The base sequence of Spirodela oligorhiza chloroplast DNA coding for 4.5S and 5S ribosomal RNA, the flanking regions and the spacer between these two genes has been determined. We have compared these sequences with the corresponding ones in other higher plants. Besides a high degree of homology, some interesting differences are found.     

Ribosomal RNA genes of Trypanosoma brucei: mapping the regions specifying the six small ribosomal RNAs

There are six small ribosomal RNAs in trypanosome ribosomes. sRNA3 and sRNA5 of Trypanosoma brucei brucei have been partially sequenced. Sequence homologies indicate that sRNA3 is 5.8S RNA and sRNA5 is 5S RNA of T. b. brucei. The regions specifying these two, and the remaining four small RNAs, have been identified within clones of rRNA genes and in the genome. Five of the small RNAs, 1, 2, 3, 4 and 6, hybridise exclusively within the major rRNA gene repeat. A map of the regions specifying these small RNAs is presented. sRNA3 (5.8S RNA) hybridises to a region corresponding to the transcribed spacer of other eukaryotes. sRNA1 hybridises to a region between sequences specifying the two large subunit RNA molecules of 2.3 kb and 1.8 kb. Sequences specifying sRNAs 2 and 4 are present near the sequence specifying sRNA1, while sRNA6 appears to be specified 3' to the sequence specifying the 1.8-kb RNA sequence. In addition regions of secondary hybridisation for small RNAs 2, 3, 4 and 6 have also been identified. Though sRNA5 (5S RNA) hybridises within the major rRNA repeat, a separate 5S RNA gene repeat with unit size of 760 bp is also present. It is 10 to 20 times more abundant than the major rRNA gene repeat.