A high molecular weight RNA fraction in chromatin.

Utilizing a new chromatin isolation and fractionation technique we have obtained a high molecular weight RNA fraction from L-929 cell chromatin. The synthesis of this RNA is not greatly inhibited by concentrations of 0.04 mug/ml actinomycin D in the medium. Its synthesis appears to be strongly inhibited by 2 mug/ml of alpha-amanitin. The RNA appears to be quickly degraded (or removed from the chromatin) and does not contain a poly(A) sequence at its 3'-OH terminal end. Our working hypothesis is that this RNA is "nascent" heterogenous nuclear RNA partially transcribed from regions of the chromatin.     

Low molecular weight metabolites produced by various Penicillium species

Low-molecular weight volatile metabolites produced by Penicillium farinosum, P. citrinum, P. camemberti and P. chrysogenum were investigated. During first 40 days of cultivation the fungi produced mainly C-8 compounds, and later mainly 2-hexenal was synthesized. Addition of 0.1% linoleic acid significantly stimulated the secretion of volatile metabolites. P. citrinum and P. farenosum produced large quantities of geosmin.     

Appearance of rapidly labeled, high molecular weight RNA in nuclear ribonucleoprotein. Release from chromatin and association with protein.

Chromatin and nuclear ribonucleoprotein (nRNP) have been prepared from a human carcinoma cell line. Following a 1-hour (3H)uridine pulse, 60 to 70% of the nuclear radioactivity, after removal of nucleoli, was found in the chromatin, the balance in nRNP. This was true whether the chromatin and nRNP were separated by velocity centrifugation or by isopycnic centrifugation on Metrizamide gradients. Radioactivity in chromatin and nRNP was found in high molecular weight RNA, with mean sedimentation coefficients of 20 S and 15 S, respectively, as determined on sodium dodecyl sulfate-sucrose gradients. Experiments on the kinetics of appearance of radioactivity in the RNA of the two fractions suggest that some of the chromatin-associated RNA is precursor to nRNP-RNA. The proteins of nRNP are complex as revealed by sodium dodecyl sulfate gel electrophoresis. The contamination by chromatin protein was estimated to be 5%. Experiments involving short pulses of (3H)tryptophan, and pulse-chase, suggested that the rapidly turning over proteins of nRNP were not complexed with RNA while still associated with chromatin. However, it was also shown that the radioactivity in nRNP following short pulses of (3H)tryptophan did not correspond to the major bands seen on stained sodium dodecyl sulfate gels. It is therefore concluded that the protein of nRNP consists of two classes: species present in large amounts, possibly common to all RNA in nRNP, which are relatively stable and may be complexed to RNA still associated with chromatin; and a large number of rapidly turning over species, each present in small amounts and associated with nRNP only after its release from chromatin.     

Rat liver nuclear skeleton and small molecular weight RNA species

Small molecular weight RNA species (smwRNAs) were studied in rat liver nuclei with and without chromatin as well as with and without nuclear envelope and nucleoplasm. From all the species identified, only two, N5 and 5Sb, were related to ribosomes. The others were localized exclusively in the nuclear skeleton or the spongelike network that was described in the preceding communication. This network or protein matrix contains a less abundant but exclusive set of molecules designated 5Sa, N1, and 4.5S, as well as other more abundant molecules which also exist in rat liver endoplasmic reticulum but not in polysomes or postribosomal RNP complexes. The smwRNAs behave like HnRNA; they remain located in the nuclear skeleton when nuclei are deprived of nucleoplasm and chromatin. With the information presently available, it is not possible to know whetherer both species are in the same or different RNP complexes and whether some of the smwRNAs contribute to the architecture of the nuclear skeleton. Distinct from any other nuclear RNA species, smwRNAs have two unique properties: facility of extraction, and resistance to nuclear ribonuclease digestion.     

Formation of low molecular weight RNA species in HeLa cells

It has been previously shown that newly synthesized nuclear low molecular weight RNA species C and D are first detected in the cytoplasm for a few minutes before they are finally found in the nucleus. The following are some of the observations made in the present study, regarding the formation of C and D RNA: (1) The 5′ end cap ribose methylation of the C RNA precursor is complete in its cytoplasmic stage; the internal ribose methylation of the precursor seems to be completed about the time of its apparent transition from cytoplasm to nucleus. (2) The few nucleotides lost from the D RNA precursor during maturation seem to be excised sometime near its apparent cytoplasmic → nuclear transition. Newly synthesized C RNA also appears to lose some of its non-conserved nucleotides about the time of that transition, while the other extra nucleotides are lost later, in the nucleus. (3) The maturation of C and D RNA is inhibited early during suppression of protein synthesis by cycloheximide, while their synthesis is not. (4) The cytoplasmic precursors of C and D RNA are not associated with ribonucleoprotein particles as large as those reported for mature C and D RNA, although they do not appear to be free in the cytoplasm. (5) When the cellular UTP pool is depleted by exposure of the cells to amino sugars, and the synthesis of C, D, and other RNA species decreases, the level of[³H]uridine labeling of C and D RNA increases, while that of 4 S and 5 S RNA does not. These data are compatible with the existence of more than one nuclear UTP pool.     

Intracellular distribution of low molecular weight RNA species in HeLa cells

Intracellular distributions of the low molecular weight RNA species of HeLa cells were determined by a nonaqueous method of cell fractionation, in which lyophilized cells were homogenized and centrifuged in anhydrous glycerol. The nonaqueous method was used to avoid artifactual extraction of weakly bound nuclear RNA during cell fractionation. We found that the mature small RNA species K, A, C, and D were almost entirely (greater than 95%) nuclear, and that mature 4S tRNA was partially (5-10%) nuclear. Our results gave higher nuclear content of the mature species K, A, C, and 4S than was shown previously with conventional aqueous cell fractionation. The nonaqueous method also gave higher nuclear proportions of some short-lived precursors to mature small RNAs. We found that approximately one-half of recently synthesized pre-4S RNA and more than one-half of recently synthesized 5S RNA were nuclear, whereas these species had been thought to be cytoplasmic from previous work. The species C' and D', precursors to the stable nuclear species C and D respectively, were found to be partially nuclear, also in contrast to earlier work. The stable cytoplasmic species L (oncornavirus 7S RNA) was found to be mostly nuclear shortly after synthesis.     

Low molecular weight angiotensin I converting enzyme from rat lung.

A low molecular weight angiotensin I converting enzyme (light angiotensin enzyme) was isolated from a homogenate of rat lung subjected to dialysis against sodium acetate at pH 4.8. This enzyme has a molecular weight of 84 000 on Sephadex G-200 and a molecular weight of 91 000 on SDS-poly-acrylamide gel as compared with a molecular weight of 139 000 for angiotensin I converting enzyme on SDS-polyacrylamide. Light angiotensin enzyme was activated by NaCl and inhibited by EDTA, angiotensin II, and bradykinin potentiating factor nonapeptide. Light angiotensin enzyme cross-reacted with antibody prepared against angiotensin I converting enzyme and stained with periodic acid-Schiff reagent as a glycoprotein. The evidence suggests that light angiotensin enzyme is a fragment of the higher molecular weight enzyme.     

Low molecular weight peptides controlling transcription are present in the calf thymus chromatin structure

A calf thymus peptide fraction controlling DNA and chromatin template has been purified by DNA-cellulose and Dowex 50 WX2 chromatography and its amino acid composition determined. The active peptide fraction can be extracted in high pH buffer from calf thymus native chromatin previously deproteinized by chloroform-isamyl alcohol and phenol. These data demonstrate that the thymic peptide(s) is (are) a chromatin protein constituent strongly linked to DNA. The specificity in association of the peptide(s) to DNA has also been considered.