Maturation of ribosomal RNA's in suspensions of higher plant cells a DNA-RNA hybridization study

Cytological localization of the genes for the four classes of ribosomal RNA (25S, 18S, 5.8S and 5S) in polytene chromosomes of Phaseolus coccineus

Homologous tritiated 25S, 18S and 5.8S rRNAs were used separately for in situ hybridization to the polytene chromosomes of the embryo suspensor cells of phaseolus coccineus. Hybridization occurred at the same chromosomal sites which were labeled in previous in situ hybridization experiments with 25 + 18S rRNAs in the same material (Avanzi et al., 1972), namely: nucleolus organizing system (satellite, nucleolar constriction and organizer) of chromosome pairs I (S1) and V (S2), proximal heterochromatic segment of the long arm of chromosome pair I, and terminal heterochromatic segment of chromosome pair II. Competition hybridization experiments confirmed for P. coccineus the high sequence homology between 25S and 18S rRNA already known for other plants. Homologous 125I-5S rRNA was found to hybridize to three sites in the polytene chromosomes of P. coccineus: the proximal heterochromatic segment in the long arm of chromosome pair I (which also bears the sequences complementary to 25S, 18S and 5.8S RNAs), most of the proximal heterochromatic segment plus a small portion of adjoining euchromatin in the long arm of chromosome pair VI and the large intercalary heterochromatic segment in the same chromosome pair. Simultaneous labeling of the two 5S RNA sites in chromosome VI was quite rare (3%), the rule being labelling of one site to the exclusion of the other, with a labeling frequency of 43.7% and 53.3% for sites no. 1 and no. 2 respectively. These results are interpreted as being due to differential hybridizability of chromosomal sites such as described in other materials.

Ribosomal cistrons in higher plant cells. II. Sequence homology between the two mature rRNAs of sycamore cells and intracistronic reiteration. A DNA - rRNA hybridization study

1. Uniformly labelled rRNA of sycamore cells has been annealed with homologous DNA. The fractions of DNA complementary to the 17S, or 26S, or 17S + 26S rRNAs are found to be 0.19%, 0.15% and 0.23%. They are not in the ratio of the molecular weight values (0.8, 1.2 and 2 - 10(6), respectively for the 17S, 26S and 17S + 26S rRNAs). This result is compatible with the large hybridization competition observed between the two rRNAs (53 and 72%) and with the shift-down of saturation curves when DNA is presaturated with unlabelled rRNA before the incubation with the other labelled rRNA. 2. Under the selected experimental procedure, the DNA - rRNA hybrids formed appear to be specific. Since there is an equal number of structural genes for the 17S and 26S rRNAs, these results mean the occurrence of a great sequence homology, strictly restricted to the two rRNAs. Homologous and specific sequences have been estimated to 0.1 and 0.7, or 0.85 and 0.35 million daltons, respectively in the 17S or 26S structural genes. 3. From the calculated lengths of homologous sequences, an intracistronic reiteration of some ribosomal sequences can be deduced. This internal reiteration is directly evidenced by the complex pattern of DNA - rRNA annealing curves. As demonstrated by base-composition analysis, the internal reiteration is heterogeneous and concerns both the homologous and specific sequences. In addition, the DNA saturation values allow the calculation of 4000 copies for the ribosomal cistron in the whole sycamore genome.

Ribosomal cistrons in higher plant cells. I. A definitive scheme for the maturation pathway of the primary transcriptional product of ribosomal cistrons in Acer pseudoplatanus L. cells

1. Four precursor ribosomal RNAs have been previously characterized in cultured sycamore cells (Acer pseudoplatanus L.). The present paper reports a study of the two smallest ones. 2. (Me-3H)-labelling of the precursor and mature rRNAs has been submitted to kinetic analysis. From pulse-chase experiments it is concluded that the 27S and 20S precursor rRNAs behave like intermediate molecules in the maturation of the 42S and 36S precursor rRNAs into the 26S and 17S components. They are direct precursors to the cytoplasmic and mature rRNAs. 3. Base-composition analyses have been performed on carefully purified molecules. They show that the 27S and 20S precursor rRNAs arise from a single cleavage of the 36S precursor rRNA. In addition, they strongly suggest that the 27S and 20S precursor rRNAs can be taken as specific precursors to the 26S and 17S rRNAs, respectively. These results are reinforced by DNA - RNA hybridization experiments, the measured values being in good agreement with the theoretical ones expected from a specific relationship between the four smallest molecules. Base-compositions of the conserved and non-conserved nucleotide sequences of the primary transcriptional product have been estimated or calculated. 4. On the basis of the present results and those previously reported, a scheme for the biosynthesis of ribosomal RNA in sycamore cells is proposed.

Early ribonucleic acid synthesis during the germination of rye (Secale cereale) embryos and the relationship to early protein synthesis

Incorporation studies with radioactive precursors showed that synthesis of protein and RNA is initiated in germinating embryos of rye within the first hour of imbibition of water. By polyacrylamide-gel fractionations of radioactive nucleic acid components, the appearance of products of transcription of the genome was shown to follow the sequence: heterogeneous (ribonuclease-sensitive) RNA, 4S and 5S RNA by 20min, 31S and 25S rRNA by 40min, and 18S RNA by 60min. "Fingerprint' analysis of T1-ribonuclease digests show that all the large oligonucleotides present in 25S and 18S RNA are present in the 31S species, indicating that 31S RNA is the precursor rRNA molecule to both 25S and 18S RNA. The importance of these early RNA syntheses and in particular the possible template function of the heterogeneous RNA is discussed in relation to the concept of long-lived mRNA and the coding for protein synthesis in the first hours of germination.