Thermotolerance induced by heat shock in Chlorella

Thermotolerance in cultures of Chlorella zofingiensis was induced by heat shock treatment at supraoptimal temperatures (40and 45 °C for 30 min). Thermotolerance was assayed by two methods: the survival of the cells at 70 °C and the growth of diluted cultures at 35 and 45 °C. A culture without heat shock treatment was unable to grow at 45 °C. According to eletrophoretic analyses, the synthesis of proteins of 95, 73, 60, 43 and 27 kDa was induced by heat shock treatment. The large molecular weight proteins (95, 73, 60 and43 kDa) were present in non-heat treated cells, but the heat shock treatment increased their quantity in cells. The synthesis of a low molecular weight protein (27 kDa) was induced by heat shock treatment. The induced thermotolerance could be inhibited by the presence of an 80S ribosomal translation inhibitor, cycloheximide(CHI). The first 12 amino acid residues from the N-terminus of the27 kDa heat shock induced protein are Val-Glu-Trp-Try-Gly-Pro-Asn-Arg-Ala-Lys-Phe-Leu. This revised version was published online in August 2006 with corrections to the Cover Date.     

Unusual processing of nucleolar RNA synthesized during a heat shock in CHO cells

Maturation of pre-rRNA has been investigated through heat shock experiments in which pre-rRNA synthesis is successively turned off and turned on. After one hour at 43°C high molecular weight RNA is no longer synthesized and both the methylation and the maturation of pre-rRNA synthesized before heat shock are blocked. After two hours recovery at 37°C, methylation and simultaneous maturation, of pre-existing RNA occur while pre-rRNA synthesis is reinitiated only after 7 hours at 37°C. During the first 30 min. at 43°C, a residual synthesis of high molecular weight RNA is observed in the nucleolus with an average molecular weight slightly higher than pre-rRNA (4.6 10⁶). During the recovery period at 37°C, RNA synthesized at 43°C is slowly processed into unusual species (39S, 35S, 29S). No new ribosomal RNA appeared in the cytoplasm. This unusual maturation pathway could be a minor pathway of nucleolar RNA processing in exponentially growing cells.     

Sixteen discrete RNA components in the cytoplasmic ribosome of Euglena gracilis

We have isolated cytoplasmic ribosomes from Euglena gracilis and characterized the RNA components of these particles. We show here that instead of the four rRNAs (17-19 S, 25-28 S, 5.8 S and 5 S) found in typical eukaryotic ribosomes, Euglena cytoplasmic ribosomes contain 16 RNA components. Three of these Euglena rRNAs are the structural equivalents of the 17-19 S, 5.8 S and 5 S rRNAs of other eukaryotes. However, the equivalent of 25-28 S rRNA is found in Euglena as 13 separate RNA species. We demonstrate that together with 5 S and 5.8 S rRNA, these 13 RNAs are all components of the large ribosomal subunit, while a 19 S RNA is the sole RNA component of the small ribosomal subunit. Two of the 13 pieces of 25-28 S rRNA are not tightly bound to the large ribosomal subunit and are released at low (0 to 0.1 mM) magnesium ion concentrations. We present here the complete primary sequences of each of the 14 RNA components (including 5.8 S rRNA) of Euglena large subunit rRNA. Sequence comparisons and secondary structure modeling indicate that these 14 RNAs exist as a non-covalent network that together must perform the functions attributed to the covalently continuous, high molecular weight, large subunit rRNA from other systems.     

A possible novel interaction between the 3′-end of 18 S ribosomal RNA and the 5'-leader sequence of many eukaryotic messenger RNAs

A novel interaction between the 5′-untranslated region of eukaryotic messenger RNAs and non-contiguous sequences in the 18 S ribosomal RNA is proposed. The small ribosomal RNA contains, at its 3′-terminus, a heavily conserved hairpin structure. It is suggested that mRNA 5′-leader sequence stabilises this structure by interacting with other conserved nucleotides which flank it. Sequences closely related to the required sequence (A—U—C—C—A—C—C) occur quite commonly in eukaryotic mRNAs and are often found immediately upstream from the AUG-codon. This interaction may have a role in the events which lead up to the initiation of protein synthesis.     

Unusual ribosomal RNA of the intestinal parasite Giardia lamblia.

The anaerobic protozoan Giardia lamblia is a common intestinal parasite in humans, but is poorly defined at molecular and phylogenetic levels. We report here a structural characterization of the ribosomal RNA (rRNA) and rRNA genes of G. lamblia. Gel electrophoresis under native or non-denaturing conditions identified two high molecular weight rRNA species corresponding to the 16-18S and 23-28S rRNAs. Surprisingly, both species (1300 and 2300 nucleotides long, respectively) were considerably shorter than their counterparts from other protozoa (typically 1800 and 3400 nucleotides), and from bacteria as well (typically 1540 and 2900 nucleotides long). Denaturing polyacrylamide gel electrophoresis identified a major low molecular RNA of 127 nucleotides and several minor species, but no molecules with the typical lengths of 5.8S (160 nucleotides) and 5S (120 nucleotides) rRNA. The G. lamblia 1300, 2300, and 127 nucleotide RNAs are encoded within a 5.6 kilobase pair tandemly repeated DNA, as shown by Southern blot analysis and DNA cloning. Thus, the rRNA operon of this eukaryotic organism can be no longer than a typical bacterial operon. Sequence analysis identified the 127 nucleotide RNA as homologous to 5.8S RNA, but comparisons to archaebacterial rRNA suggest that Giardia derived from an early branch in eukaryotic evolution.     

Thymidine nucleotide synthesis and catabolism by CHO cells and their changes during the cell cycle

At 0°C, CHO cells efficiently incorporated [³H]thymidine into the nucleotide fraction, but not into DNA. Upon reincubation of asynchronous cultures at 37°C, 15–25% of the radioactivity contained in the cellular nucleotide fraction was released, in the form of thymidine, into the culture medium. At 0°C, however, radioactivity of the nucleotide fraction was retained within the cells. Similarly, dTMP phosphatase (EC 3.1.3.35) in cell extracts was active at 37°C, but not at 0°C, whereas thymidine kinase (EC 2.7.1.21) was active at both temperatures. If synchronous cultures in Gl phase were prelabeled at 0°C and reincubated at 37°C, almost all radioactivity in the nucleotide fraction was released into the medium, whereas in S-phase cultures nearly all radioactivity of the nucleotide fraction was incorporated into DNA. In synchronous S-phase cultures treated with hydroxyurea, radioactivity in the nucleotide fraction was released into the medium at a rate considerably lower than that observed for Gl-phase cells. Rates of endogenous synthesis of thymidine nucleotides were calculated from changes of cellular thymidine nucleotide content, incorporation of thymidine nucleotides into DNA and release of thymidine into the medium during reincubation of prelabeled cultures in thymidine-free medium. The results obtained (see Table III) reveal marked differences between Gl and S phases with respect to the determinants of thymidine nucleotide metabolism.     

Temperature of acrylamide polymerization and electrophoretic mobilities of nucleic acids.

The electrophoretic mobilities of DNA, ribosomal RNAs, and pulse-labeled RNAs were compared on polyacrylamide gels polymerized at temperatures from 4 to 35°C and subjected to electrophoresis at a fixed temperature. DNA migrated the same distance irrespective of polymerization temperature, the ribosomal RNAs, and the major pulse-labeled species (a putative rRNA precursor) migrated more rapidly in gels polymerized at higher temperatures. The linearity of the migration versus the log of the molecular weight remained for the five rRNA species used, but the extrapolated molecular weight of the putative precursor ranged from 1.8 × 10⁶ to 2.5 × 10⁶ depending on polymerization temperatures. By varying polymerization temperatures, the optimal resolution of various groups of RNA species can be obtained. The results are explained in terms of polymerization temperature effects on gel structure as well as nucleic acid conformation.     

Alteration in the processing of ribosomal ribonucleic acid inSaccharomyces cerevisiae caused by ethidium bromide

Ethidium bromide in a concentration of 200 μg/ml causes a full inhibition of RNA synthesis in aSaccharomyces cerevisiae ρ° strain, while protein synthesis continues at a reduced rate. Under these conditions, processing of rRNA is slowed down and part of the 37S rRNA precursor molecules are cleaved to a 32S RNA fraction (molecular weight 2.15×10⁶). The 32S RNA accumulates in cells treated with ethidium bromide but cannot be processed to mature 25S and 18S rRNA and is degraded. The 32S RNA fraction also appears when processing of rRNA occurs in cells starved for required amino acids. The degradation of 37S precursor molecules through 32S RNA may be a regulatory mechanism of rRNA biosynthesis in yeast, which operates when excess rRNA must be wasted.