Fine structure of ribosomal RNA. II. Distribution of methylated sequences within Xenopus laevis rRNA.

The distribution of methyl groups in rRNA from Xenopus laevis was analyzed by hybridization of rRNA to subfragments of either of two cloned rDNA fragments, X1r11 and X1r12, which together constitute a complete rDNA repeat unit. Using a mixture of 3H-methyl plus 32P-labelled rRNA as probe, the molar yield of methyl groups per rRNA region in hybrid could be calculated. For this calculation the length of the rRNA coding region in each DNA subfragment is needed, which was determined for X1r11 subfragments by the nuclease S1 mapping method of Berk and Sharp. The results show that both in 18S and 28S rRNA the methyl groups are nonrandomly distributed. For 18S rRNA, clustering was found within a 3' terminal fragment of 310 nucleotides. For 28S rRNA, clustering of methyl groups was found within a region of 750 nucleotides in length, which ends 500 nucleotides from the 3' end. In contrast, the 28S rRNA 5' terminal region of 900 nucleotides is clearly undermethylated. The general position of methyl groups in 28S rRNA correlates with the location of evolutionarily conserved sequences in this molecule, as recently determined in our laboratory.     

Sequence of the Small Subunit Ribosomal RNA Gene Expressed in the Bloodstream Stages of Plasmodium berghei: Evolutionary Implications1

ABSTRACT. We have determined the complete nucleotide sequence of the coding region of the small subunit rRNA gene expressed by bloodstream stages of the apicomplexan Plasmodium berghei. It is 2059 nucleotides long. Elements contributing to its relatively large size are all concentrated in regions known to be variable in length among eukaryotes. In a phylogenetic tree constructed from pairwise comparisons of eukaryotic small subunit rRNA sequences, the apicomplexan line branches at a rather early point in eukaryotic evolution before any multicellular kingdoms had yet appeared.     

The complete nucleotide sequence of the small-subunit ribosomal RNA coding region for the cycadZamia pumila: Phylogenetic implications

Summary The DNA sequence of the small-subunit ribosomal RNA coding region for the cycadZamia pumila L. was determined. TheZamia smallsubunit rRNA was found to be 1813 nucleotides in length and approximately 92% identical to published angiosperm small-subunit rRNA sequences. Conserved regions interspersed with variable regions are observed corresponding to those found in other eukaryotic small-subunit sequences. Using representatives from protist, fungal, plant, and animal groups, a distance matrix was constructed of average nucleotide substitution rates for pairs of organisms. Phylogenetic trees were inferred from similarities between sequences. The sequence ofZamia represents the earliest divergence from the higher plant lineage reported to date for small-subunit rRNA data. Inferred phylogenies also support a monophyletic origin for the angiosperms consistent with studies citing phenotypic characters.     

The NADH-dehydrogenase subunit 5 gene in Oenothera mitochondria contains two introns and is co-transcribed with the 5 S rRNA gene

Summary The gene encoding subunit 5 of the NADH dehydrogenase complex (ND 5) has been identified in Oenothera mitochondria from a cDNA clone. The coding region is interrupted by a type II intron of 850 nucleotides and a second intervening sequence of 357 nucleotides. Genomic sequence rearrangement within the first intron creates a nontranscribed partial copy of the gene. The intact ND 5 gene is transcribed in a complex pattern with mRNAs including the 5 S rRNA sequence. Excision of the two introns appears to proceed slowly in vivo since the steady state mitochondrial RNA contains significant proportions of unprocessed precursor molecules.     

The 10 kb Drosophila virilis 28S rDNA intervening sequence is flanked by a direct repeat of 14 base pairs of coding sequence

Most repeat units of rDNA in Drosophila virilis are interrupted in the 28S rRNA coding region by an intervening sequence about 10 kb in length; uninterrupted repeats have a length of about 11 kb. We have sequenced the coding/intervening sequence junctions and flanking regions in two independent clones of interrupted rDNA, and the corresponding 28S rRNA coding region in a clone of uninterrupted rDNA. The intervening sequence is terminated at both ends by a direct repeat of a fourteen nucleotide sequence that is present once in the corresponding region of an intact gene. This is a phenomenon associated with transposable elements in other eukaryotes and in prokaryotes, and the Drosophila rDNA intervening sequence is discussed in this context. We have compared more than 200 nucleotides of the D. virilis 28S rRNA gene with sequences of homologous regions of rDNA in Tetrahymena pigmentosa (Wild and Sommer, 1980) and Xenopus laevis (Gourse and Gerbi, 1980): There is 93% sequence homology among the diverse species, so that the rDNA region in question (about two-thirds of the way into the 28S rRNA coding sequence) has been very highly conserved in eukaryote evolution. The intervening sequence in T. pigmentosa is at a site 79 nucleotides upstream from the insertion site of the Drosophila intervening sequence.     

The characterization of enzymatically amplified eukaryotic 16S-like rRNA-coding regions

Polymerase chain reaction conditions were established for the in vitro amplification of eukaryotic small subunit ribosomal (16S-like) rRNA genes. Coding regions from algae, fungi, and protozoa were amplified from nanogram quantities of genomic DNA or recombinant plasmids containing rDNA genes. Oligodeoxynucleotides that are complementary to conserved regions at the 5' and 3' termini of eukaryotic 16S-like rRNAs were used to prime DNA synthesis in repetitive cycles of denaturation, reannealing, and DNA synthesis. The fidelity of synthesis for the amplification products was evaluated by comparisons with sequences of previously reported rRNA genes or with primer extension analyses of rRNAs. Fewer than one error per 2000 positions were observed in the amplified rRNA coding region sequences. The primary structure of the 16S-like rRNA from the marine diatom, Skeletonema costatum, was inferred from the sequence of its in vitro amplified coding region.     

Identification of a Molecular Marker and Chromosome Mapping of the 5S rRNA Gene in<Emphasis Type="Italic">Allium sacculiferum</Emphasis>

The 5S rRNA gene in higher eukaryotes is organized into repeated units of tandem array that comprise a conserved 120-bp coding region and a non-transcribed spacer (NTS) of variable length with nucleotides. The allotetraploid genome ofAllium sacculiferum consists of two unknown diploids (2n=32). Analyses have not been successful toward clarifying the origin of each genome due to their similar chromosome morphology and unmatched C-banding patterns. We PCR-amplified the coding and NTS regions of its 5S rRNA genes, cloned them into vectors, and determined their DNA sequences. Interestingly, the aligned sequences of the NTS clones could be divided into two distinctive groups based on the existence of a 3-bp CCT insertion/deletion at the beginning of the NTS region. This feature makes it an important genetic marker for distinguishing the origin of theA. sacculiferum chromosomes. Furthermore, by applying fluorescencein situ hybridization, we located the 5S rRNA gene loci on Chromosomes 5, 7, 8, 9, and 14; their distribution is unique toA. sacculiferum. These data support the idea that one set of this genome has originated from a CCT-containing close relative --A. deltoid-fistulosum -- and that the NTS region may be used as a molecular marker for identifying parental lines for the allotetraploidityof A. sacculiferum.     

Sequence of the Small Subunit Ribosomal RNA Gene from the Hypotrichous Ciliate Euplotes aediculatus1

ABSTRACT. We have determined the complete nucleotide sequence of the coding region of the small subunit rRNA gene of the hypotrichous ciliate Euplotes aediculatus. It is 1882 nucleotides long and contains several inserts not present in the small subunit rRNA genes of the hypotrichs Oxytricha nova and Stylonychia pustulata. A comparison of the sequences suggests that E. aediculatus is much less closely related to these other two hypotrichs than they are to each other. Although the gene sequence of E. aediculatus is drifting more rapidly than those of these other two species, its faster evolutionary clock is not enough to account for the degree of difference between them.     

Length heterogeneity of amplified circular rDNA molecules in oocytes of the house cricket Acheta domesticus (Orthoptera: Gryllidae)

Amplification of the genes coding for rRNA occurs in the oocytes of a wide variety of organisms. The amplification process appears to be mediated through a rolling-circle mechanism. The approximate molecular weight of the smallest rDNA circles is equivalent to the estimated combined molecular weight of DNA which codes for a single ribosomal RNA precursor molecule and an associated non-transcribed spacer DNA sequence. RNA-DNA hybridization studies carried out on oocytes of the house cricket, Acheta domesticus, suggest that DNA coding for rRNA accounts for only a small fraction of the rDNA satellite, all of which is amplified in the oocyte. In order to test the possibility that the remainder of the amplified rDNA represents spacer and to determine whether a rolling-circle mechanism might also be involved in amplification in A. domesticus oocytes, rDNA was isolated from ovaries of A. domesticus and spread for electron microscopy. A large proportion of the rDNA isolated from ovaries is circular, while main-band DNA and rDNA prepared from other tissues demonstrates few if any circles. The mean size of the smallest rDNA circles is approximately 8 times longer than the length estimated for DNA which codes for 18 S and 28 S rRNA. Denaturation mapping shows the rDNA circles to contain two major readily denaturing regions located about equidistant from one another on the circle. Each readily denaturing region accounts for 4–6% of the total DNA in the circle. The fact that only 12% of the average molecule is required to code for A. domesticus 18 S and 28 S rRNA is consistent with the hybridization data. Considerable size heterogeneity exists in the length of the smallest class of rDNA molecules. In the rDNA of other species such heterogeneity has been shown to reside in the non-transcribed spacer.     

Distribution of 5S ribosomal RNA genes in somatic and germ cells of the house cricket,Acheta domesticus

In the house cricket,Acheta domesticus, the 110 genes per haploid genome encoding 18S and 28S rRNA are contained within rDNA repeats which are amplified during oogenesis. The 5S rRNA coding sequences of this cricket are found in two sizes of 5S DNA repeating units (measuring 2.1 and 3.0 kb). The 3.0 kb repeats account for more than 90% of the totalAcheta 5S DNA. We have determined the number of cricket 5S rRNA genes by RNA-DNA hybridization analysis: 310 5S DNA repeats/haploid genome clearly approximates the number of 18S and 28S rRNA genes. Because of the relatively low copy number of 5S rRNA genes the possibility of 5S DNA amplification in oocytes ofA. domesticus was also examined. Although amplification of rDNA is readily detectable, amplification of 5S DNA is not observed in oocytes ofA. domesticus. Unlike the genes coding for 18S and 28S rRNA which are localized at a single chromosomal site in the genome ofA. domesticus, the 5S rRNA genes occupy numerous sites distributed along the length of most chromosomes.     

Molecular identification of pufferfish species using PCR amplification and restriction analysis of a segment of the 16S rRNA gene

This study amplified the mitochondrial 16S rRNA gene using polymerase chain reaction (PCR) with a template of total DNA from muscle tissues of nine pufferfish species collected from the coastal area of Okinawa Islands in Japan: Pleuranacanthus sceleratus, Triodon macropterus, Chelonodon patoca, Sphoeroides pachygaster, Arothron hispidus, A. stellatus, A. manilensis, A. mappa, and A. nigropunctatus. Then nucleotide sequence encoding a partial region of the 16S rRNA gene was compared among species. The sequenced fragment was also used to select restriction enzymes, yielding species-specific restriction fragment length polymorphisms (RFLP). The sequence of the segment of the 16S rRNA gene consisted of about 615 nucleotides and showed interspecies variations in the targeted region. After calculation of corresponding RFLP-patterns of nine species investigated with suitable restriction enzymes, three restriction enzymes – BanII, DdeI, and NlaIII – were found to be sufficient for identification of all nine species. Successful testing of this methodology in frozen and heated food samples suggests its utility for pufferfish species authentication in food products.     

PHYLOGENY OF GRACILARIA LEMANEIFORMIS (RHODOPHYTA) BASED ON SEQUENCE ANALYSIS OF ITS SMALL SUBUNIT RIBOSOMAL RNA CODING REGION1

The small subunit ribosomal RNA (rRNA) sequence of Gracilaria lemaneiformis Bory Weber-van Bosse was inferred from analysis of rRNA coding regions that were amplified by the polymerase chain reaction method. Comparison of the G. lemaneiformis small subunit rRNA to homologous genes of diverse eukaryotes demonstrated that the red algal divergence was nearly simultaneous with the separation of plants, fungi, animals and many other protist lineages. This result conflicts with those of 5S rRNA sequence and plastid based phytogenies which suggest that red algae represent an early divergence in the eukaryotic line of descent. Further, algae appear to be of polyphyletic origin and red algae are unrelated to higher fungi.     

Molecular characterization of gap region in 28S rRNA molecules in brine shrimp <Emphasis Type="Italic">Artemia parthenogenetica</Emphasis> and planarian <Emphasis Type="Italic">Dugesia japonica</Emphasis>

In most insects and some other protostomes, a small stretch of nucleotides can be removed from mature 28S rRNA molecules, which could create two 28S rRNA subunits (28Sα and 28Sβ). Thus, during electrophoresis, the rRNA profiles of these organisms may differ significantly from the standard benchmark since the two subunits co-migrate with the 18S rRNA. To understand the structure and mechanism of the atypical 28S rRNA molecule, partial fragments of 28Sα and 28Sβ in brine shrimp Artemia parthenogenetica and planarian Dugesia japonica were cloned using a modified technology based on terminal transferase. Alignment with the corresponding sequences of 28S rDNAs indicates that there are 41 nucleotides in A. parthenogenetica and 42 nucleotides in D. japonica absent from the mature rRNAs. The AU content of the gap sequences of D. japonica and A. parthenogenetica is high. Both the gaps may form stem-loop structure. In D. japonica a UAAU cleavage signal is identified in the loop, but it is absent in A. parthenogenetica. Thus, it is proposed that the gap processing of 28S rRNA was a late enzyme-dependent cleavage event in the rRNA maturational process based on the AU rich gap sequence and the formation of the stem-loop structure to expose the processing segment, while the deletion of the gap region would not affect the structure and function of the 28S rRNA molecule.     

Complex structure of the ribosomal DNA spacer of Cucumis sativus (cucumber)

Summary The nuclear 18 S, 5.8 S and 25 S ribosomal RNA genes (rDNA) of Cucumis sativus (cucumber) occur in at least four different repeat types of 10.2, 10.5, 11.5, and 12.5 kb in length. The intergenic spacer of these repeats has been cloned and characterized with respect to sequence organization. The spacer structure is very unusual compared to those of other eukaryotes. Duplicated regions of 197 bp and 311 bp containing part of the 3 end of the 25 S rRNA coding region and approximately 470 bp of 25 S rRNA flanking sequences occur in the intergenic spacer. The data from sequence analysis suggest that these duplications originate from recombination events in which DNA sequences of the original rDNA spacer were paired with sequences of the 25 S rRNA coding region. The duplicated 3ends of the 25 S rRNA are separated from each other mostly by a tandemly repeated 30 bp element showing a high GC-content of 87.5%. In addition, another tandemly repeated sequence of 90 bp was found downstream of the 3flanking sequences of the 25 S rRNA coding region. These results suggest that rRNA coding sequences can be involved in the generation of rDNA spacer sequences by unequal crossing over.     

Nucleolar DNA in oocytes of crickets: representatives of the subfamilies Oecanthinae and Gryllotalpinae (Orthoptera: Gryllidae)

A large extrachromosomal mass of Feulgen positive material, the DNA body, has been visualized in early prophase oocytes of crickets (Orthoptera: Gryllidae) representative of the closely related subfamilies Gryllinae and Nemobiinae. A similar structure is present in oocytes of representatives of two subfamilies of crickets (subfamilies Oecanthinae and Gryllotalpinae) which taxonomically and phylogenetically are quite separate from those mentioned previously. In situ hybridization demonstrates that the body contains amplified copies of genes coding for ribosomal RNA. Unlike the DNA body in early diplotene oocytes of representatives of the subfamily Gryllinae, which is closely associated with the developing nucleolar apparatus, the DNA body in oocytes of the Oecanthinae and Gryllotalpinae cannot be demonstrated during diplotene. In the Oecanthinae, the nucleolar apparatus of early diplotene stage oocytes is composed of four to seven separate structures, the ribonucleoprotein of which has a characteristically lamellated appearance. During late diplotene, these nucleoli give rise to many smaller structures which are distributed throughout the germinal vesicle. In early diplotene stage oocytes of Scapteriscus acletus (Subfamily: Gryllotalpinae), the nucleolar apparatus consists of a single compact mass of ribonucleoprotein. In contrast to the oocytes of all other crickets that have been studied, the nucleolus of S. acletus remains single throughout diplotene. In situ hybridization analysis indicates that the amplified genes coding for rRNA which are localized in the DNA body of early prophase oocytes become incorporated into this compact nucleolar mass. Differences in nucleolar structure appear to reflect differences in the organization of amplified genes coding for rRNA.     

Cloning and characterization of genes coding for ribosomal RNA inCampylobacter jejuni

The DNA fragments coding for ribosomal RNA inCampylobacter jejuni have been cloned from a genomic library ofC. jejuni constructed inEscherichia coli. Clones carrying DNA Sequences for rRNA were identified by hybridization of 5-end-labeled rRNA fromC. jejuni to colony blots of transformants from this gene library. Cloned DNA sequences homologous to each of 5S, 16S, and 23S rRNA were idenfified by hybridization of labeled plasmid DNA to Northern blots of rRNA. The gene coding for 23S rRNA was found to be located on a 5.5kb HindIII fragment, while the 5S and 16S rRNA genes were on HindIII fragments of 1.65 and 1.7 kb, respecitively. The DNA fragment containing the 16S rRNA gene was characterized by restriction endonuclease mapping, and the location of the 16S rRNA gene on this fragment was determined by hybridization of 5-end-labeled rRNA to restriction fragments and also by DNA sequence determination. It appears that the major portion of the coding region for 16S rRNA is located on the 1.7-kb HindIII fragment, while a small portion is carried on an adjacent HindIII fragment of 7.5 kb. Cloned rRNA genes fromC. jejuni were used to study the organization of the rDNA inC. jejuni and other members of the genùsCampylobacter.