A Unique Ribonucleic Acid of Low Molecular Weight from Rat Liver Microsomes

A proposal that malignancies represent genetic changes in cell surface RNA

A great number of experimental studies have now been performed with malignant cells. The mass of data generated presents a confusing and often apparently contradictory picture of the fundamental molecular biological defect which most scientists sense must be the cause of transformation of a normal cell into a malignant one. This paper proposes the hypothesis that RNA on the exterior of the cell membrane organizes the various functional molecular aggregates such as transport complexes (permeases), lectin receptor sites, transmembrane microfilament attachment sites, hormone receptor complexes, and the elusive contact inhibition components. Furthermore it is proposed that a defect in the production of or competition for the assembly of exterior-organizer RNA (exoRNA) complexes is the primary molecular defect inherent in all malignancies. The defect could be caused by deletion of a chromosome region producing or controlling exoRNA, mutation of the genes involved in exoRNA production or by insertion of viral genetic material into the genome thereby producing an incomplete viral RNA (vRNA) which competes for exoRNA binding sites in cell surface complexes. Such changes would be genetically transmitted and could represent a range of genetic change between chromosomal deletion and point mutation. Several experiments are suggested to directly test the hypothesis.

Characterization of the membrane matrix derived from the microsomal fraction of rat hepatocytes

A highly purified membrane preparation derived from the microsomal fraction of rat hepatocytes has been chemically characterized and fractionated by means of gel filtration. The preparation has been freed of ribosomes and intravesicular protein and has a composition on a w/w basis of 52.1% protein, 45.0% phospholipid, 2.9% carbohydrate and no RNA. 97 +/- 2% of the total membrane phosphorus is accounted for as phospholipid phosphorus. Determination of the molecular weight distribution of the constituent polypeptides by sodium dodecyl sulfate-polyacrylamide gel electrophoresis gave values ranging from 171 000 to 16 000 for the major classes of proteins. Although several membrane glycoproteins have been indentified, the most prominent species has an apparent molecular weight of 171 000, 40% of the total microsomal protein is present in the 49 000-60 000 molecular weight region. Examination of the intrinsic polypeptide composition of membranes obtained from smooth and degranulated rough endoplasmic reticulum revealed no detectable qualitative differences. Sodium dodecyl sulfate-solubilized microsomal membrane proteins were separated by gel filtration into much simplified molecular weight classes, some of which showed predominantly a single electrophoretic component. Amino acid analysis of individual fractions showed a noticeable trend toward a decreasing ratio of acidic to basic residues with decreasing molecular weight. Membrane phosphorus was distributed between two chromatographic fractions: one containing membrane phospholipid (97% of the total) as well as essentially all the cholesterol, the other, at the inclusion volume of the gel filtration system, containing small molecular weight species (3% of the total phosphorus). The absence of a ribonuclease-resistant RNA component eluting near the void volume clearly distinguishes the microsomal membrane from the nuclear envelope.

Interactions of liver encoplasmic reticulum membranes and polysomes in vitro

The interactions of various preparations of endoplasmic reticulum membranes and polysomes have been studied by means of a sandwich sucrose gradient that clearly isolates free ribosomes, smooth endoplasmic reticulum (S.E.R.) and rough endoplasmic reticulum (R.E.R.) from the microsomal fraction of rat liver homogenates. Reconstructed rough membranes separate well from the native R.E.R. but occupy the same position along the gradient as the S.E.R. and the rough membranes, stripped of their ribosomes by means of LiCl. Native R.E.R. and S.E.R. do not bind any added labeled polysomes at 0 degree C; previous treatment with LiCl does not modify the behavior of S.E.R. The presence of cell sap during the binding reaction does not increase polysome fixation by stripped-rough membranes but protects in some way the polysomes and preserves all their original functional capacity of amino acid incorporation into protein.