An inhibitor of protein synthesis prepared by protease treatment of mouse cerebral cortex cells

A substance was isolated from mouse brain cortical tissue that inhibits both cell division and protein synthesis by cells in culture. The inhibitor was released from cerebral cortex tissue by mild protease treatment. A single exposure of cells to as little as 1.25 μg of the isolated material was sufficient to inhibit BHK-21 cell protein synthesis by 20%. Higher concentrations and continual exposure resulted in 87% reduction in protein synthesis. The inhibition was shown to be independent of amino acid uptake and most effective against primary mouse embryo fibroblasts and neonatal mouse brain cell suspensions. Cells previously adapted to culture or transformed cells derived from the nervous system were less affected by, or refractory to, the inhibitor. The substance was shown to be nondialyzable, relatively resistant to thermal inactivation and the inhibitor activity was not removed by chloroform extraction. Two active fractions were identified by Bio-Gel P-100 chromatography and the protein synthetic inhibitor was removed by affinity chromatography with $\text{Ulex}$$\text{europus}$ agglutinin.     

Preferential synthesis of yeast mitochondrial DNA in alpha factor-arrested cells

α factor is a diffusible substance produced by $\text{S. cerevisiae}$ cells of the $\text{α}$ mating type which inhibits cell division (1) and the initiation of nuclear DNA synthesis (2) in cells of the $\text{a}$ mating type. In this report, it is shown that mitochondrial DNA synthesis continues at a normal rate in $\text{a}$ cells for at least 6 hours in the presence of α factor, resulting in a 5-fold increase in the amount of mitochondrial DNA per cell. The continued synthesis of mitochondrial DNA in the absence of nuclear DNA synthesis allows specific labeling of yeast mitochondrial DNA.     

The lack of effect of tunicamycin on cilia regeneration in Tetrahymenapyriformis

$\text{Tetrahymena}\text{pyriformis}$ cultures were starved, deciliated and incubated in a reciliation medium in the presence and absence of tunicamycin. This antibiotic was shown to have no effect on the rate of reciliation or the appearance of the organisms even when present in relatively large amounts, although cell division was blocked. A small inhibition of protein synthesis was noted in the presence of tunicamycin, but mannose incorporation was totally abolished. It was concluded that the reciliation of these organisms takes place by a mechanism that does not require the $\text{de}\text{novo}$ synthesis of glycoprotein.     

The foundation of two distinct cell lineages within the mouse morula

The division of single cells, isolated from an 8-cell mouse embryo, to give $\text{2 ×}\text{1}\text{16}$ cells has been studied by sampling cells for analysis at defined stages during and after the division. Cells were analyzed for evidence of polarity in their surface organization as assessed by fluorescent ligand binding and distribution of microvilli. Individual $\text{1}\text{8}$ cells are polarized. At division, most (82%) divide such that both the pole of ligand binding and the pole of microvilli are distributed to only one of the two daughter cells. A couplet is thereby formed with a large polar cell and a small apolar cell. Some $\text{case1}\text{8}$ cells divide through the pole, generating a couplet of two polar cells, the poles being contiguous at the midbody. Elements of the surface polarity observed in the $\text{1}\text{8}$ cells can be found at all stages throughout division. Analysis of couplets of cells derived from newly formed 16-cell morulae also reveals that most consist of a polar:apolar pair and some consist of a polar:polar couplet in which the poles are contiguous at the midbody.The results indicate that two distinct cell populations are generated at division. These cells are known to occupy different positions within the morula, the polar cells being peripheral and the apolar cells being central. Since peripheral and central cells give rise to trophectoderm and inner cell mass in the blastocyst, we therefore suggest that the foundation of the trophectoderm and inner cell mass lineages may occur by a process of differential inheritance. This conclusion supports the recently proposed polarization hypothesis, which is discussed.     

Effect of amino acid and serum deprivation on the regulation of RNA synthesis in cultured Chinese hamster ovary cells

In a proline-requiring Chinese hamster ovary cell line, if both proline and serum are removed from the culture medium, net RNA synthesis is reduced to about 12 % of the unstarved control. This reduction in RNA synthesis is comparable to the stringent regulation of RNA in bacteria. A beta-globulin carbohydrate containing (3.5 % $\text{w}\text{w}$) protein factor was isolated and partially purified from fetal calf serum. The isolated serum factor is able to replace whole serum in stimulating cellular RNA synthesis and has an RNAase inhibitory effect in vitro. The effect of proline starvation and serum factor deprivation on RNA synthesis are independent and additive; each regulates about half of the total RNA synthesized. The regulation appears to affect the synthesis of all species of cytoplasmic RNA.     

Stimulation of the release of two glycoproteins from mouse 3T3 cells by growth factors and by agents that increase intralysosomal pH

Peptide growth factors selectively increase the amount of mitogen-regulated protein (MRP) and major excreted protein (MEP) released by mouse 3T3 cells. $\text{Balb}\text{c}$ 3T3 cells release mainly MEP and Swiss 3T3 cells release mainly MRP. Fibroblast growth factor, epidermal growth factor, nerve growth factor, serum, and concanavalin A increase the extracellular appearance of both MEP and MRP, but to different extents. Several agents that have been shown to, or would be expected to increase, intralysosomal pH also selectively increase the release of MEP and MRP from both $\text{Balb}\text{c}$ and Swiss 3T3 cells. The effective agents are monensin, nigericin, ammonium chloride, methylamine, chloroquine, and high extracellular pH.     

Structural requirements of quassinoids for the inhibition of cell transformation

The effects of eleven quassinoids on Rous sarcoma virus induced cell transformation and on growth of normal cells were examined. At concentrations of 0.15-1 μg/ml they inhibited foci formation (76–99 %) without toxic effects on normal cells. The most active compounds also affected virus production by transformed cells. In intact normal and transformed cells, protein and DNA synthesis was equally affected after 3 hours of exposure to quassinoids of both cell types. RNA synthesis was not inhibited. This study has shown that the structural requirement of a C-15 ester in the quassinoids for antileukemic activity $\text{in vitro}$ and $\text{in vivo}$ is not essential for their antitransforming activity.     

DNA synthesis and the cell cycle in cultures of normal and mutant (mdg/mdg) embryonic mouse muscle cells.

The relationship between cell fusion, DNA synthesis and the cell cycle in cultured embryonic normal and dysgenic ($\text{mdg}\text{mdg}$) mouse muscle cells has been determined by autoradiography. The experimental evidence shows that the homozygous mutant myotubes form by a process of cell fusion and that nuclei within the myotubes do not synthesize DNA or undergo mitotic or amitotic division. The duration of the total cell cycle and its component phases was statistically the same in 2-day normal and mutant ($\text{mdg}\text{mdg}$) myogenic cultures with the approximate values: T, 21.5 hr; G₁, 10.5 hr; S, 7.5 hr; and G₂, 2.5 hr. In both kinds of cultures, labeled nuclei appeared in myotubes 15–16 hr after mononucleated cells were exposed to [³H]thymidine, and the rate of incorporation of labeled nuclei into multinucleated muscle cells was comparable in control and dysgenic cultures. Thus, homozygous $\text{mdg}\text{mdg}$ muscle cells in culture are similar to control cells with respect to their mechanism of myotube formation and the coordinate regulation of DNA synthesis and the cell cycle during myogenesis.     

Inhibition of human erythrocyte Ca++-transport ATPase by phenothiazines and butyrophenones

Indirect immunofluorescent staining revealed that Prostatic Binding Protein, the major androgen-dependent protein in rat ventral prostate $\text{in}\text{vivo}$, is associated specifically with the epithelial cells in primary cell cultures derived from rat ventral prostate. The epithelial cells release Prostatic Binding Protein into the medium during primary culture. $\text{De}\text{novo}$ synthesis of Prostatic Binding Protein is demonstrable during early phases of cell culture. Prostatic Binding Protein is an excellent marker for the identification of functional prostate epithelial cells and for the study of regulation at the cellular level of the synthesis and secretion of a major androgen-dependent prostate protein.     

Rat hepatoma 5123TC albumin mRNA directs the synthesis of pre-proalbumin identical to rat liver pre-proalbumin.

Effect of hemin, mild periodate oxidation and concanavalin A (Con A) on $\text{in vitro}$ biosynthesis of membrane proteins and hemoglobin, in the rabbit reticulocyte, was examined. Whereas addition of hemin to the incubation medium stimulates synthesis of both hemoglobin and membrane proteins, addition of Con A, at concentrations which agglutinate cells, selectively stimulates membrane protein biosynthesis. Mild periodate treatment of cells inhibits synthesis of hemoglobin and membrane proteins; this inhibition is not related to oxidation of a membrane component since hemoglobin synthesis in a cell free lysate of treated cells is similarily inhibited.     

Initiation of chromosome replication in Escherichia coli. I. Requirements for RNA and protein synthesis at different growth rates

The effects of inhibition of protein and RNA synthesis on initiation of chromosome replication in Escherichia coli$\text{B}\text{r}$ were determined by measuring rates of DNA synthesis during the division cycle before and after addition of chloramphenicol and rifampicin. The ability of cells to initiate a round of replication depended upon the pattern of chromosome replication during the division cycle. Initiation in the presence of chloramphenicol (200 μ/ml) and rifampicin (100 gmg/ml) was observed only in slowly growing cells which normally initiated a new round between the end of the previous round and the subsequent division (i.e. in the D period of the division cycle). The cells that initiated were in the D period at the time of addition of the drugs. Rapidly growing cells which normally initiated before the D period and slowly growing cells which normally initiated after the D period did not initiate in the presence of the drugs. The contrasting effects of the drugs in cells possessing different chromosome replication patterns, and the coupling between septum-crosswall formation (the D period) and initiation suggest that the timing of initiation of chromosome replication in E. coli is controlled by the cell envelope.     

Identification of the outer membrane protein of E.coli that produces transmembrane channels in reconstituted vesicle membranes

Outer membrane of $\text{Escherichia}$$\text{coli}$ allows a rapid diffusion of saccharides of molecular weights less than 550. This permeability property could be restored in vesicle membranes reconstituted from isolated phospholipids, lipopolysaccharide, and an outer membrane protein. The active protein aggregates were isolated from the insoluble material left after solubilization of cell envelope of $\text{Escherichia}$$\text{coli}$ B with sodium dodecyl sulfate at 35°. Analysis by acrylamide gel electrophoresis, isoelectric focusing and amino terminal amino acid determination revealed that only a single species of protein, with a molecular weight of 36,500 forms the oligoprotein aggregates which produces diffusion channels.     

Aldehyde content and cross-linking of type III collagen.

Three phosphorylated dinucleosides designated HS1, HS2, and HS3, isolated from the water-mould $\text{Achlya}$, were shown to significantly inhibit ribonucleotide reductase activity from $\text{Achlya}$. All three compounds decreased CDP reduction in fungal extracts by 50% at concentrations of 0.1mM. At the same concentration HS3 also inhibited partially purified CDP reductase from Chinese hamster ovary cells by at least 80% but showed only 10% inhibition with enzyme from $\text{E.}\text{coli}$. ADP reductase activity from $\text{Achlya}$ was inhibited 50% by both HS1 and HS3 at 0.1mM. HS2 however, showed no inhibitory effect on purine reduction. The levels of ribonucleotide reductase during the asexual growth cycle of $\text{Achlya}$ correlated with thymidine uptake into DNA and with the synthesis of HS compounds.     

Phosphorylated guanosine derivatives of eukaryotes: Regulation of DNA-dependent RNA polymerases I,II, and III in fungal development

Three phosphorylated guanosine derivatives designated HS-1, HS-2 and HS-3 synthesised during active protein synthesis in the water-mould, $\text{Achlya}$ sp (1969) were shown to regulate the enzymatic activities of nucleoplasmic and nucleolar DNA-dependent RNA polymerases (RNAP-I, II and III) from both $\text{Achlya}$ and another unrelated water-mould, $\text{Blastocladiella emersonii}$. These HS compounds were without effect on $\text{E. coli}$ DNA-dependent RNA polymerase holoenzyme. The most potent of the three compounds was HS-3 which inhibited the activity of all enzymes completely at 100 μg/ml. HS-1, on the other hand, activated maximally at 1 to 10 μg/ml. HS-1 activation (3-fold) was restricted to enzyme III, and it had only partial inhibitory effects on enzymes I and II. The pattern of synthesis of HS-compounds throughout the 20-hour asexual growth cycle of the organism correlated with the detectable levels of the different RNA polymerases of $\text{Achlya}$.     

Suppressive actions of inorganic ions on the bioactivity of aminoglycoside antibiotics.

Many independent studies have shown that inorganic salts can suppress the inhibitory activities of aminoglycoside antibiotics against various bacterial species. From studies on the nature and mechanism of this suppressive ion effect, several conclusions can be drawn. Both monovalent and divalent cation salts can inhibit aminoglycoside action. At least two different mechanisms are apparently involved. The first is divalent cation dependent and has been described with $\text{Pseudomonas aeruginosa}$ and $\text{Mycobacterium smegmatis}$. With $\text{M. smegmatis}$, the effect aappears to be dependent more on a double positive charge than on particular metal ion species. The second mechanism is related to ionic strength and is elicited by both monovalent and divalent cation salts against many different organisms. However, based on studies with $\text{M. smegmatis}$, it appears that each of the two mechanisms involves interferance with the initial instantaneous electrostatic binding of drug at the cell surface.     

Role of calcium ions in the stimulatory actions of luteinizing hormone in isolated ovarian cells: Studies with divalent-cation ionophores

The divalent-cation ionophores A23187 and ionomycin exert dose-dependent suppressive effects on the stimulatory actions of luteinizing hormone in ovarian cells $\text{in}\text{vitro}$. Micromolar concentrations of both A23187 and ionomycin can inhibit the production of progesterone and the stimulation of ornithine decarboxylase activity. Inhibitory concentrations of these ionophores deplete total cell content of calcium, and also seem to suppress protein synthesis.     

Nuclear transfer studies of amoeba proteus after the inhibition of cell division by injection of non-homologous cytoplasm

Following the injection of the post-microsomal supernatant fraction of $\text{Amoeba discoides}$ cytoplasm into $\text{A.proteus}$, cell division is inhibited in at least 90% of the recipient cells. Nuclear transfers were performed to determine the site of inhibition in these injected cells. When nuclei from injected, inhibited cells one day after injection were transferred into new $\text{A.proteus}$ cytoplasms, 62% of the transfers divided. This ability to promote division declined with the length of time between transfer and the original_ injection. However, when nuclei from $\text{A.proteus}$ were transferred into injected, inhibited cytoplasms, only a low number of cells divided, comparable to the number obtained after the injection operation only, namely less than 10%. Thus although many nuclei could recover from inhibition, it was not possible to restore the cytoplasms of inhibited cells by new nuclei.     

Evidence for peptidoglycan-associated protein(s) in Neisseria gonorrhoeae.

Growth pH markedly influenced the composition of the cell envelope of $\text{Neisseria gonorrhoeae}$. The composition of the peptidoglycan from cells grown at pH 7.2 and 8.0 consisted primarily (91%) of muramic acid, glutamic acid, alanine, $\text{meso}$-diaminopimelic acid, and glucosamine in approximate molar ratios of 1:1:2:1:1. The peptidoglycan from cells grown at pH 6.0 contained an accessory protein(s) which accounted for 42% of the weight of the isolated complex.     

DNA synthesis during the division cycle of three substrains of Escherichia coliBr

The relationship between chromosome replication and the bacterial division cycle has been examined in three substrains of Escherichia coli$\text{B}\text{r}$ obtained from different sources and designated $\text{B}\text{r}$ A, $\text{B}\text{r}$ F and $\text{B}\text{r}$ K. At growth rates greater than 1.0 doubling per hour (μ > 1.0), the time for a round of chromosome replication (C) was 42 minutes in all three substrains, but the time between the end of a round and cell division (D) was 22 minutes in $\text{B}\text{r}$ A, 16 minutes in $\text{B}\text{r}$ F and 14 minutes in $\text{B}\text{r}$ K. At slower growth rates C and D increased, but to significantly different extents in the three substrains. When μ = 0.5, C and D were approximately 80 and 40 minutes in $\text{B}\text{r}$ A, 60 and 20 minutes in $\text{B}\text{r}$ F, and 70 and 20 minutes in $\text{B}\text{r}$ K.As a consequence of the lengths of the C and D periods in the three stocks of E. coli$\text{B}\text{r}$, the patterns of chromosome replication during the division cycle differed. The most obvious difference was that E. coli$\text{B}\text{r}$ F and E. coli$\text{B}\text{r}$ K possessed periods devoid of DNA synthesis at both the beginning and the end of the division cycle during slow growth, whereas E. coli$\text{B}\text{r}$ A contained only one period devoid of DNA synthesis at the end of the cycle.     

A cell surface glycoprotein virus inhibitor that is not interferon

The possible relationship between a newly isolated glycoprotein virus inhibitor and interferon was assessed. Comparisons of the cell surface glycopeptide, obtained from mouse cerebral cortex, and interferon included antiviral activity, radioimmune assays, and the ability of antibodies raised against the brain cell surface glycoprotein (BCSG) and against mouse L cell interferon to precipitate the biological activity. BCSG was able to inhibit virus replication but only in a transient fashion. Although anti-BCSG precipitated a major portion of the radiolabelled inhibitor in a double antibody assay, anti-mouse interferon did not. Over 90% of the inhibitory activity was removed with anti-BCSG and $\text{Staphylococcus}$ protein A while anti-mouse interferon removed little, or none, of the activity under similar reaction conditions. Other properties of the BCSG that distinguish it from interferon are presented.