Studies on the chromatin of barley leaves during senescence

1. The activity of soluble ribonuclease and deoxyribonuclease first declined during senescence, but later increased during advanced stages of senescence. 2. Young leaves had very low ribonuclease or deoxyribonuclease activity associated with the chromatin, but the activity of these enzymes increased progressively during senescence until the leaves died. 3. No significant changes in the composition of chromatin from first seedling leaves of barley plants during aging (from 7 to 25 days) were noted. 4. The amount of RNA synthesized by chromatin in vitro declined as the leaf aged. However, if the loss of RNA due to chromatin-associated ribonuclease was taken into account, the RNA-synthesizing activity of chromatin from senescing (15-16-day-old) leaves appeared to be somewhat higher than that of chromatin from young (7-8-day-old) leaves. In leaves at the terminal stages of senescence (23 days old) the estimates of RNA synthesis by chromatin could not be made owing to complications created by high nuclease activities. 5. It is suggested that senescence may be triggered by a decline in some hormonal factor in leaves, and that the resulting production of chromatin-associated deoxyribonuclease and ribonuclease in increasing proportions may progressively cause increased degradation of DNA and newly synthesized RNA, so that ultimately the cellular functions are impaired and the cells die.     

Replication of vesicular stomatitis virus defective interfering particle RNA in vitro: transition from synthesis of defective interfering leader RNA to synthesis of full-length defective interfering RNA.

The replication of the RNA of vesicular stomatitis virus (VSV) defective interfering (DI) particles was established in a defined cell-free system. The transition from synthesis of only the DI-leader RNA to replication of the full-length DI RNA was effected in the system by newly synthesized VSV proteins and occurred in the absence of VSV helper virus. Both positive- and negative-polarity full-length DI RNA were synthesized. Furthermore, the products of RNA replication associated with newly synthesized viral proteins to form complexes that were indistinguishable from authentic DI particle nucleocapsids on the basis of buoyant density and resistance to ribonuclease digestion. The DI-leader RNA did not form ribonuclease-resistant structures. We conclude that this in vitro system successfully executes many of the reactions of VSV DI particle replication and assembly.     

The conformation of ribonucleic acids in Escherichia coli ribosomes: Inferences from the mode of action of ribonuclease II

1. Ribonuclease II of Escherichia coli degrades pulse-labelled RNA associated with ribosomes and polyuridylic acid on ribosomes and in solution to mononucleotides. 2. Ribosomal and pulse-labelled RNA in solution and ribosomal RNA in chloramphenicol particles (protein-deficient ribosomes) are degraded to oligonucleotides. 3. Ribosomal RNA in mature ribosomes is not attacked by the enzyme. 4. From the mode of action of ribonuclease II, which is specific for single-stranded polyribonucleotides and does not attack helical forms, it is inferred that pulse-labelled RNA associated with ribosomes of E. coli exists as a single-stranded structure and that ribosomal RNA in chloramphenicol particles has a pronounced helical character. 5. The different behaviour of ribonuclease II towards newly synthesized RNA, ribosomal RNA and chloramphenicol-particle RNA in E. coli ribosomes is discussed.     

Ribonucleic Acid Dependent Ribonucleic Acid Replicase in the Immune Response

An immune ribonucleic acid (iRNA) preparation was made using phenol extracts of spleens of mice previously immunized with Salmonella tennessee flagella. An enzyme, also prepared from the spleens of these mice, induced the incorporation of ³H-UTP into the acid-insoluble fraction in a cell-free system in the presence of this RNA. The enzyme activity could be demonstrated from the spleens of immunized mice but not from normal ones, and this activity was also inhibited by two derivatives of rifamycin. Treatment with ribonuclease or heating at alkaline pH resulted in a loss of activity in added RNA. The ³H-uridine-labeled product was found resistant to ribonuclease treatment but became sensitive when the product was subjected to heat treatment. However, actinomycin D, mitomycin C or bleomycin A₂ did not inactivate the enzyme activity. These results suggest that this enzyme induces the incorporation of UTP into the acid-insoluble fraction using iRNA as a template and the product may be a newly synthesized RNA which forms a hybrid with iRNA. This enzyme activity may play a role in the antibody formation process, and may account for the in vivo replication of iRNA by this enzyme, viz., probably an RNA-dependent RNA replicase.