Cyclic 3',5'-adenosine monophosphate stimulates trehalose degradation in baker's yeast

The levels of cyclic 3′,5′-AMP and trehalose, as well as the specific activity of the trehalase have been investigated in cells of baker's yeast ($\text{Saccharomyces cerevisiae}$) during the lag phase preceding growth. During the first few minutes a substantial increase in the intracellular concentration of cyclic 3′,5′-AMP was observed, followed by a 6–8 fold increase in trehalase activity concomitant with the rapid degradation of trehalose. Cell free extracts prepared from resting yeast were shown to contain a cryptic trehalase, which under physiological conditions could be activated by cyclic 3′,5′-AMP to the same degree as $\text{in vivo}$. These observations suggest that in the lag phase of growth, the level of trehalose in baker's yeast is under control of a system, regulated by the level of cyclic 3′,5′-AMP.     

Evidence for existence and a tentative identification of coenzyme in yeast thiamine pyrophosphokinase.

Thiamine pyrophosphokinase (E.C. 2.7.6.2.) from $\text{Saccharomyces cerevisiae}$ was found to require the presence of a non-protein, non-metal compound for its activity. $\text{myo}$-Inositol was found capable of stimulating the kinase activity in the presumably resolved but otherwise crude sample of the enzyme. The hexytol was also found capable of inducing the enzyme in growing yeast cells. The cultured yeast cells, in which the kinase had been induced, were used as source of the enzyme for its purification. The compound that had been left adsorbed to the final column of DEAE-Sephadex was proved to have a coenzyme activity towards the enzyme and tentatively identified with $\text{myo}$-inositol 1-pyrophosphate. A sample of synthetic $\text{myo}$-inositol 1-pyrophosphate was made and its coenzyme activity was observed.     

Coenzyme A: fatty acid synthetase apoenzyme 4'-phosphopantetheine transferase in yeast

A mixture of two pantetheine-free mutant fatty acid synthetases was dissociated and recombined $\text{in}$$\text{vitro}$ to form a hybrid apoenzyme complex. $\text{In}$$\text{vivo}$ the corresponding $\text{Saccharomyces}$$\text{cerevisiae}$$\text{fas}$-mutants exhibit interallelic complementation when crossed with each other and the enzyme synthesized in the resulting diploid contains pantetheine and exhibits overall fatty acid synthetase activity. Accordingly, the hybrid apoenzyme formed $\text{in}$$\text{vitro}$ could be activated to holo-fatty acid synthetase when incubated with coenzyme A and a partially purified yeast cell extract. The enzyme coenzyme A: fatty acid synthetase apoenzyme 4′-phosphopantetheine transferase has thus been identified in yeast. Further studies on the mechanism of fatty acid synthetase holoenzyme formation will now be possible.     

Studies of odd bases in yeast mitochondrial tRNA: II. Characterization of rare nucleosides

The nucleoside composition of tRNA from highly purified yeast mitochondria shows the presence of T, ψ, hU, m¹G, m²G, m₂²G, I and t⁶A whereas neither m⁷G, m⁵C, m³C, m¹A, i⁶A and Y nor O′-methylated nucleosides (which are common in yeast cytoplasmic tRNA) were found. The G+C content is very low (35%). The overall methylation content is 2.7% which is about half the content of yeast cytoplasmic tRNA but similar to that of $\text{E. coli}$ tRNA. Some rare nucleosides however which are found in $\text{E. coli}$ (s⁴U, acp³U, m²A, m⁶A, ms²i⁶A, Q) were not found in yeast mitochondrial tRNA.     

Complex formation between transfer RNAs with complementary anticodons: use of matrix bound tRNA

It is shown that yeast tRNA^Phe, chemically coupled by its oxidized 3′CpCpA end behaves exactly as free tRNA^Phe in its ability to form a specific complex with $\text{E. coli}$ tRNA₂^Glu having a complementary anticodon. The results support models of tRNA in which the 3′CpCpA_OH end and the anticodon are not closely associated in the tertiary structure, and provide a convenient tool of general use to characterize others pairs of tRNA having complementary anticodons, as well as for highly selective purification of certain tRNA species.     

The synthesis,characterization, and preliminary biological evaluation of 1-β-D-arabinofuranosylcytosine-5′-diphosphate-L-1,2-dipalmitin

Recently, 1-β-$\text{D}$-arabinofuranosylcytosine-5′-diphosphate-$\text{DL}$-1,2-dipalmitin (VIa) was reported to inhibit the growth of L51784 cells in mice and of human colon carcinoma HCT-15 cells, also in mice. This paper describes the synthesis of a single diastereomer by conversion of 1-β-$\text{D}$-arabinofuranosylcytosine 5′-monophosphate (II) to the nucleoside 5′-phosphomorpholidate (III), followed by reaction with $\text{L}$-α-dipalmitoylphosphatidic acid (IV) to give 1-β-$\text{D}$-arabinofuranosylcytosine-5′-diphosphate-$\text{L}$-1,2-dipalmitin (V) in good yield. The separation of the product is described and its characterization by chromatography, elemental analysis, and spectroscopic methods. The lipophilic nature of V renders it insoluble in aqueous media and a method of sample preparation utilizing sonication techniques is described which provides a clear solution suitable for biological evaluation. In addition, the ability of V to inhibit the $\text{in}\text{vitro}$ growth of L1210 cells and of mouse myeloma MPC 11 cells is desscribed and compared with 1-β-$\text{D}$-arabinofuranosylcytosine (I) and other lipophilic prodrugs of I.     

5-Nitro-2'-deoxyuridine 5'-monophosphate is a potent irreversible inhibitor of Lactobacillus caesi thymidylate synthetase.

5-Nitro-2′-deoxyuridine 5′-monophosphate was found to be an active sitedirected irreversible inhibitor of thymidylate synthetase from $\text{Lactobacillus caesi}$. It's K_I was determined as 2.9 × 10^?8$\text{M}$ from a double-reciprocal plot of velocity $\text{vs}$ substrate concentration.     

Interaction of manganese with fragments, complementary fragment recombinations, and whole molecules of yeast phenylalanine specific transfer RNA

Binding of Mn²⁺ to the whole molecule, fragments and complementary fragment recombinations of yeast tRNA^Phe, and to synthetic polynucleotides was studied by equilibrium dialysis. The comparison of the binding patterns of the fragments, fragment recombinations and synthetic polynucleotides with that of intact tRNA^Phe permits reasonable conclusions concerning the nature and location of the various classes of sites on tRNA^Phe. Binding of Mn²⁺ to intact tRNA^Phe consists of a co-operative and a non-co-operative phase. There are about 17 “strong” sites and several “weak” ones. Five of the 17 strong sites are associated with the co-operative phase. This phase is completely lacking in the binding of Mn²⁺ to tRNA^Phe fragments (5′-$\text{1}\text{2}$, 3′-$\text{1}\text{2}$, 5′-$\text{3}\text{5}$, 3′-$\text{2}\text{5}$), poly-(A):poly(U) and poly(I):poly(C) helices, and single stranded poly(A) and poly(U). This argues that the co-operative sites arise from the tRNA tertiary structure. This conclusion is further strengthened by the observation that cooperativity is present in a tRNA^Phe molecule which has been split in the anticodon loop, but it is absent in one which has been split in the extra loop. It is in the vicinity of the latter loop, but not the former, that tertiary interactions are seen in the crystal structure. The remaining 12 strong sites are “independent” and appear to be associated with cloverleaf helical sections.     

Selective killing of Leishmania infected mouse macrophages by 6-methylpurine 2′-deoxyriboside

6-methylpurine 2′-deoxyriboside killed mouse macrophages infected with amastigotes of $\text{Leishmania donovani}$ and $\text{Leishmania mexicana}$, but did not affect the growth of non-parasitized cells. $\text{Leishmania}$ extracts cleaved the non-toxic 6-methylpurine 2′-deoxyriboside to 6-methylpurine, a potent adenine antimetabolite for mammalian cells. By eliminating macrophages latently infected with $\text{Leishmania donovani}$ amastigotes, 6-methylpurine 2′-deoxyriboside could augment the effects of leishmanicidal agents $\text{in vivo}$.     

Localization of the structural gene for the ' subunit of RNA polymerase in Escherichia coli

A minicell-producing strain of $\text{E.}$$\text{coli}$ carrying an F′ factor, KLF10-1, forms minicells that contain plasmid but not chromosomal DNA. These minicells were found to synthesize two polypeptides corresponding precisely to the β and β′ subunits of RNA polymerase in SDS-polyacrylamide gel electrophoresis. In contrast, minicells obtained from an isogenic strain carrying F13-1 do not synthesize these proteins under similar conditions. These results indicate that the structural genes for the β′ as well as β subunits of the polymerase are located on the chromosomal segment (78 to 81 min on the standard genetic map of $\text{E.}$$\text{coli}$) carried by KLF10-1.     

Occurrence of proteinase a isoinhibitors in wild type yeast strains and commercial baker's yeast

The occurrence of the proteinase A inhibitors 2 and 3 was investigated in wild type strains of $\text{Saccharomyces}\text{cerevisiae}$ and $\text{Saccharomyces}\text{carlsbergensis}$ as well as in several strains of commercial baker's yeast. Haploid and diploid strains of $\text{Saccharomyces}\text{cerevisiae}$ contain only proteinase A inhibitor 3 whereas in $\text{Saccharomyces}\text{carlsbergensis}$ only proteinase A inhibitor 2 is found. Strains of commercial baker's yeast contain either proteinase A inhibitor 3 or both inhibitors in a constant ratio of 1:3. Single cell cultures isolated from a strain of commercial baker's yeast also contain a mixture of the two inhibitors. Therefore, baker's yeast is not a mixture of two different cell types but the genome for both inhibitors is present in each single cell. In general, the results indicate that the occurrence of the two proteinase A inhibitors is determined genetically and, therefore, they may be called “isoinhibitors”.     

Preparation and biological activity of taxol acetates

Synthesis and biological activity of 2′-acetyltaxol and 7-acetyltaxol are reported. Activity is measured $\text{in}\text{vivo}$ by cytotoxicity toward the macrophage-like cell line J774.2, and $\text{in}\text{vitro}$ by promotion of microtubule assembly in the absence of exogenous GTP. Addition of an acetyl moiety at C-2′ results in loss of $\text{in}\text{vitro}$ activity but not cytotoxicity. The properties of 7-acetyltaxol are similar to those of taxol in its effects on cell replication and on $\text{in}\text{vitro}$ microtubule polymerization. Therefore a free hydroxyl group at C-7 is not required for $\text{in}\text{vitro}$ activity and this position is available for structural modifications.     

Cytotoxicity of a hybrid prepared by coupling diphtheria toxin A-chain with immunoglobulin Fab′ with N,N′-o-phenylenedimaleimide

A hybrid protein was prepared by coupling the A-chain of diphtheria toxin with the Fab′ fragment of immunoglobulin with $\text{N}\text{,}\text{N′}\text{-}\text{o}$-phenylenedimaleimide (PDM). Although in this hybrid, the two components were linked with each other with bonds which could not be reductively cleaved with 2-mercaptoethanol as in a hybrid cross-linked with a disulfide bond (e.g. Fab′-S-S-A-chain), it exhibited a potent cytotoxicity $\text{in}\text{vitro}$, one-third of that of Fab′-S-S-A-chain, against the target L1210 cells.     

Cyclic adenosine 3':5'-monophosphate levels in normal and transformed cells of higher plants

Cyclic adenosine 3′:5′-monophosphate (cAMP) concentrations were determined for various normal and transformed (crown-gall) plant tissues grown in sterile culture. No significant differences in cAMP concentrations were found between normal and transformed cells of $\text{Vinca rosea, Helianthus annuus}$, and $\text{Nicotiana tabacum}$, unlike the suppressed synthesis observed in transformed cells of mammalian systems. cAMP concentrations of these tissues in culture averaged 135 nanomolar. No correlation was found between cAMP concentrations and tissue culture generation times.     

The role of cAMP on neoplastic cell growth and regression. III. Altered cAMP-binding in DBcAMP-unresponsive Walker 256 mammary carcinoma.

An exogenous supply of N⁶,O^2′-dibutyryl cyclic adenosine 3′,5′-monophosphate (DBcAMP) $\text{in vivo}$ produces regression of one type of Walker 256 mammary carcinoma cell population (DBcAMP-responsive); a second type of cell population continues to grow despite DBcAMP treatment (DBcAMP-unresponsive). A correlation was found between altered cAMP-binding of the tumor cytosol and DBcAMP-unresponsiveness. It was found that there was: a) a higher apparent dissociation constant (Kd) for cAMP-binding in unresponsive tumor cytosol $\text{in vitro}$, and b) unsaturability of cAMP-binding by unresponsive tumor cytosol in response to elevated cAMP levels $\text{in vivo}$. Cycloheximide abolished the saturation of cAMP binding $\text{in vivo}$ as well as tumor regression produced by DBcAMP.     

The extraction of guanosine 5'-diphosphate, 3'-diphosphate (ppGpp) from Escherichia coli using low pH reagents: a reevaluation.

It has been found that the most widely used method for the extraction of guanosine 5′-diphosphate, 3′-diphosphate (ppGpp) from $\text{E. coli}$ (1 M formic acid at 0°) results in its $\text{in vitro}$ degradation to ppGp and GDP. A comparison with several other extraction procedures indicated that this breakdown is due to the low pH of the reagents used during extraction. This degradation can largely be prevented by using a new extraction technique which involves freezing and thawing of the cells in the presence of lysozyme at a neutral pH followed by treatment with deoxycholate. With this method it is possible to recover from three to five times as much ppGpp from both unstarved and amino acid starved stringent strains of $\text{E. coli}$ as compared with the most widely used formic acid procedure. Consequently, it will be necessary to reevaluate the ppGpp values obtained from cells when formic acid or other low pH reagents were used during extraction.     

A nucleotide with the properties of adenosine 5′ phosphoramidate from Chlorella cells

We have extracted and purified a nucleotide from cells of $\text{Chlorella}\text{,}\text{pyrenoidose}$ Chick which shares the following properties with adenosine 5′ phosphoramidate; electrophoretic mobility in sodium bicarbonate and in sodium borate buffer (pH 8.0); retention time on high performance liquid chromatography; ultraviolet absorption spectrum at pH 1–2 and 7–9; a yield of one mole each of adenine, ribose, total phosphate and ammonia released at low pH; and formation of adenosine 5′ monophosphate on acidification or treatment with 3′:5′-cyclic-nucleotide phosphodiesterase (EC3.1.4.17). Although formation of APA from its precursor adenosine 5′ phosphosulfate during extraction and purification is not expected this appears to be excluded by the use of low temperature throughout purification and the finding that [¹⁴C] APS added before extraction does not significantly label the adenosine 5′ phosphoramidate isolated. Thus adenosine 5′ phosphoramidate appears to be a normal constituent of $\text{Chlorella}$ cells like the enzyme which forms it: adenylyl sulfate: ammonia adenylyl transferase.     

Primary structure of E. coli alanine transfer RNA: relation to the yeast phenylalanyl tRNA synthetase recognition site

Nucleotide sequence comparison of tRNAs aminoacylated by yeast phenylalanyl tRNA synthetase (PRS) have lead to the proposal that the specific nucleotides of the dihydrouridine (diHU) stem region and adenosine at the fourth position from the 3′ end are involved in the PRS recognition site. Kinetic analysis and enzymatic methylation have shown that the size of the diHU loop and the methylation of guanine at position 10 from the 5′ end both directly affect the PRS aminoacylation kinetics. $\text{E. coli}$ tRNA₁^A1a, which is aminoacylated by PRS, should therefore have 1- the specific nucleotides of the diHU stem region and, 2- adenosine at position 4 from the 3′ end. The PRS aminoacylation kinetics of this tRNA indicates that this molecule 3- has a diHU loop of 8 nucleotides and 4- has an unmethylated guanine at position 10 from the 5′ end. We report here the complete sequence of $\text{E. coli}$ tRNA₁^A1a and confirmation of each of these four predictions.     

Stimulation by interferon of induction of differentiation of human promyelocytic leukemia cells

F₁-ATPase was isolated from yeast $\text{S.}\text{cerevisiae}$. The constituent subunits 1 and 2 were purified by gel permeation chromatography, and their amino acid compositions determined. Both subunits have a similar composition except for $\text{1}\text{2}$ cystine, methionine, leucine, histidine, and tryptophan. When F₁ is treated for three hours with 5′-p-[³H]fluorosulfonylbenzoyl adenosine in dimethylsulfoxide, 90% of the activity is lost. Disc gel electrophoresis of the modified complex showed that over 90% of the label was associated with subunit 2. A labelled peptide from a $\text{S.}\text{aureus}$ digest of subunit 2 was isolated and sequenced. It had the following amino acid sequence: His-Try¹-Asp-Val-Ala-Ser-Lys-Val-Gln-Glu, whereby Tyr¹ is the modified amino acid residue. This sequence shows homology to other sequences obtained from maize, beef heart, and $\text{E.}\text{coli}$ F₁-ATPases.     

Studies on compartmentation of S-adenosyl-L-methionine in Saccharomyces cerevisiae and isolated rat hapatocytes

The existence of metabolically distinct pools of $\text{S-}\text{adenosyl-L-methionine}$ in Saccharomyces cerevisiae and isolated rat hepatocytes was investigated. Utilizing a relatively long labeling period with [methyl-¹⁴C]methionine, a metabolically ‘stable’ pool was labeled. A subsequent short labeling with [methyl-³H]methionine selectively labeled a putative metabolically ‘labile’ pool. The existence of these distinguishable pools was ascertained by following the ³H and ¹⁴C label disappearance in $\text{S-}\text{adenosyl-L-methionine}$ during the chase-period in label-free media containing cycloleycine to prevent futher synthesis of $\text{S-}\text{adenosyl-L-methionine}$. In both yeast and hepatocytes, the ${}^3\text{H}{}^{14}\text{C}$ ratio in $\text{S-}\text{adenosyl-L-methionine}$ decreased sharply. The individual ³H and ¹⁴C decrease in $\text{S-}\text{adenosyl-L-methionine}$ showed $\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ values of 3 and 8 min for yeast and 4 and 18 min for hepatocytes. The results strongly indicate that at least two metabolically distinct $\text{S-}\text{adenosyl-L-methionine}$ pools actually do exist in both systems. Subcellular fractionation revealed that the ‘labile’ pool exist in the cytosol for both yeast and hepatocytes while the ‘stable’ pool exists in the vacuolar and the mitochondrial fraction for the yeast and hepatocytes respectively. The $\text{S-}\text{adenosyl-L-methionine}$ pools were also studied in normal yeast under anaerobic chase condition and petite mutant yeast. Sharply contrasting with aerobically chased normal yeast, both showed closely parallel ³H and ¹⁴C decreases in $\text{S-}\text{adenosyl-L-methionine}$.