Prebiotic synthesis of nucleotides

If an RNA-only world preceded more complex forms of life, then it is essential that the process whereby the first nucleotides were made be considered. Presumably there were no enzymes and no templates to facilitate the synthesis of the first nucleotides so another form of chemical evolution must have been involved. Answers to problems of this sort were sought vigorously in the 1960s and the early 1970s but many issues were left unresolved. Progress made in the last few years has added to this early work and brings us closer to a satisfactory solution. In this article key results, old and new, and some ideas as to how further progress is likely to be made are discussed. There are reasons for optimism. Substantial progress has been made on the synthesis of purines and ribose, phosphorylation and polyphosphorylation. The outstanding problems at this juncture relate to the synthesis of ribose to the exclusion of the other aldopentoses and to the problem of linking ribose to the purine bases.

Nucleoside phosphorylation: a feasible step in the prebiotic pathway to RNA

Plausible prebiotic conditions for the phosphorylation of nucleosides by inorganic phosphate were reported by Lohrmann and Orgel in 1971. This reaction was carried out on heated dry films and promoted by urea. The major products formed were nucleoside-2:3 cyclicPs;5-NMPs and other derivatives were also formed. Minor modifications of the Lohrmann and Orgel system have resulted in the preferential formation of 5-NMPs. In this modified system a 2-fold preference for phosphorylation of the 5-OH group over the 3(2)-OH group was observed and the formation of other derivatives was minimized. The small amounts of bis compounds that were formed in this system could be quantitatively removed by selective binding to the mineral hydroxylapatite at moderate ionic strengths. It was also discovered that under hydrolytic conditions there was a 3:1 preference for removal of phosphates attached to the 3-OH group over the 5-OH group. A recycling procedure for obtaining additonal 5-NMPs from bis compounds and 3-NMPs is proposed.

Studies on the lead-catalyzed synthesis of aldopentoses

The object of this work was to find an efficient means of synthesizing ribose in a manner that could be considered prebiotic. The starting point for synthesis was an aqueous solution of formaldehyde. Heretofore the most frequently used catalyst for this purpose has been calcium hydroxide. Unfortunately this system produces a wide array of products in addition to ribose which constitutes 1% or less of the final product. Attempts were made to find more mild conditions under which the formaldehyde could be reacted. Magnesium hydroxide suspensions were used for this purpose. Formaldehyde does not yield any sugars when incubated in magnesium hydroxide suspensions alone. However, if the magnesium hydroxide suspension was supplemented with doubly charged lead salts and catalytic amounts of any intermediate in the prebiotic pentose pathway, aldopentoses accounted for 30 per cent or more of the final product. The presence of lead in the incubation mixture also accelerated a number of other reactions including the interconversion of the four common aldopentoses, ribose, arabinose, lyxose and xylose.

Binding of adenine and adenine-related compounds to the clay montmorillonite and the mineral hydroxylapatite

The first living things may have consisted of no more than RNA or RNA-like molecules bound to the surfaces of mineral particles. A key aspect of this theory is that these mineral particles have binding sites for RNA and its prebiotic precursors. The object of this study is to explore the binding properties of two of the best studied minerals, montmorillonite and hydroxylapatite, for possible precursors of RNA. The list of compounds investigated includes purines, pyrimidines, nucleosides, nucleotides, nucleotide coenzymes, diaminomaleonitrile and aminoimidazole carboxamide. Affinities for hydroxylapatite are dominated by ionic interactions between negatively charged small molecules and positively charged sites in the mineral. Binding to montmorillonite presents a more complex picture. These clay particles have a high affinity for organic ring structures which is augmented if they are positively charged. This binding probably takes place on the negatively charged faces of these sheet-like clay particles. Additional binding sites on the edges of these sheets have a moderate affinity for negatively charged molecules. Small molecules that bind to these minerals sometimes bind independently to sites on the minerals and sometimes bind cooperatively with favorable interactions between the bound molecules.

Consecutive low-usage leucine codons block translation only when near the 5' end of a message in Escherichia coli

Insertion of nine consecutive low-usage CUA leucine codons after codon 13 of a 313-codon test mRNA strongly inhibited its translation without apparent effect on translation of other mRNAs containing CUA codons. In contrast, nine consecutive high-usage CUG leucine codons at the same position had no apparent effect, and neither low- nor high-usage codons affected translation when inserted after codon 223 or 307. Additional experiments indicated that the strong positional effect of the low-usage codons could not be accounted for by differences in stability of the mRNAs or in stringency of selection of the correct tRNA. The positional effect could be explained if translation complexes are less stable near the beginning of a message: slow translation through low-usage codons early in the message may allow most translation complexes to dissociate before they read through.

Multicopy single-stranded DNAs with mismatched base pairs are mutagenic in Escherichia coli

Retrons are genetic elements that encode multicopy single-stranded DNAs called msDNAs. They are clonally distributed in Escherichia coli and retrons in different clones produce DNAs with different nucleotide sequences. msDNAs consist of an RNA molecule covalently linked to a single-stranded DNA molecule. The latter contains an inverted repeat, resulting in a stem-loop structure. In two retrons, Ec83 and Ec78, the DNA is cleaved off from the RNA. All known retrons except Ec78, have one or more mismatched base pairs in the stem-loop structure. We found that two retrons, Ec86 and Ec83, when present in high copy numbers are mutagenic. The ratios of mutation frequencies observed in Lac- indicator strains were similar to the ratios observed for a mutant defective in mismatch repair. It is known that some proteins required for mismatch repair bind to mismatched base pairs prior to carrying out repair. The similarity in the mutation frequency ratios suggested that the mutagenesis caused by msDNAs of retrons Ec86 and Ec83 might be due to sequestration of a mismatch repair protein by msDNA. Strong support for this interpretation was obtained from the finding that the msDNA produced by retron Ec78 is not mutagenic.

Clustering of low usage codons and ribosome movement

A model is presented in which the distribution of low-usage codons in a message is a major factor in determining the impact that they will have on the translation rate and distribution of ribosomes on that message. This model is based on the assumption that low-usage codons are translated more slowly than normal codons, an assumption supported by various lines of published experimental evidence. Although the parameters used to develop this model are somewhat arbitrary, the main conclusions of this paper are consistent with a wide variation in the values of those parameters. In the model, low-usage codons arranged in clusters are much more effective in blocking ribosome movement on the message than ones that are dispersed. The effective size of the cluster is limited to the dimensions of the ribosome. It has been estimated that ribosomes on a message are spaced at least 27 nucleotides or nine codons apart. A ribosome translating a cluster of nine codons in which some or all of the codons are low-usage will move more slowly than over a comparable stretch of message containing no low-usage codons. Owing to ribosome size, the ribosome immediately behind the stalled ribosome will move as slowly; it must wait for the stalled ribosome to move on before it can even begin to translate the difficult region containing the low-usage codons. When the low-usage codon cluster is at the 3' end, the message will eventually be occupied by a ribosome jam that will transmit back to the 5' end of the message. In the steady state, the slowing effect imposed by a cluster of nine low-usage codons at the 3' end of a message would be just as great as if the entire message was composed of them. If the cluster is situated in the middle of a message, the ribosomes will form a jam upstream of the cluster. The ribosome density downstream of the cluster will be considerably reduced from what it would be for the same message with no cluster. If the cluster is at the 5' end of the message, the density of ribosomes will be reduced over the entire length of the message but the overall translation rate per ribosome will be only slightly reduced. However, owing to the reduced number of ribosomes initiating, the efficiency of the message in protein synthesis will be considerably reduced.(ABSTRACT TRUNCATED AT 400 WORDS)

Effects of consecutive AGG codons on translation in Escherichia coli, demonstrated with a versatile codon test system

A system for testing the effects of specific codons on gene expression is described. Tandem test and control genes are contained in a transcription unit for bacteriophage T7 RNA polymerase in a multicopy plasmid, and nearly identical test and control mRNAs are generated from the primary transcript by RNase III cleavages. Their coding sequences, derived from T7 gene 9, are translated efficiently and have few low-usage codons of Escherichia coli. The upstream test gene contains a site for insertion of test codons, and the downstream control gene has a 45-codon deletion that allows test and control mRNAs and proteins to be separated by gel electrophoresis. Codons can be inserted among identical flanking codons after codon 13, 223, or 307 in codon test vectors pCT1, pCT2, and pCT3, respectively, the third site being six codons from the termination codon. The insertion of two to five consecutive AGG (low-usage) arginine codons selectively reduced the production of full-length test protein to extents that depended on the number of AGG codons, the site of insertion, and the amount of test mRNA. Production of aberrant proteins was also stimulated at high levels of mRNA. The effects occurred primarily at the translational level and were not produced by CGU (high-usage) arginine codons. Our results are consistent with the idea that sufficiently high levels of the AGG mRNA can cause essentially all of the tRNA(AGG) in the cell to become sequestered in translating peptidyl-tRNA(AGG) -mRNA-ribosome complexes stalled at the first of two consecutive AGG codons and that the approach of an upstream translating ribosome stimulates a stalled ribosome of frameshift, hop, or terminate translation.

Low-usage codons in Escherichia coli, yeast, fruit fly and primates

Codon usage is compared between four classes of species, with an emphasis on characterization of low-usage codons. The classes of species analyzed include the bacterium Escherichia coli (ECO), the yeast Saccharomyces cerevisiae (YSC), the fruit fly Drosophila melanogaster (DRO), and several species of primates (PRI) (taken as a group; includes eleven species for which nucleotide sequence data have been reported to GenBank, however, greater than 90% of the sequences were from Homo sapiens). The number of protein-coding sequences analyzed were 968 for ECO, 484 for YSC, 244 for DRO, and 1518 for PRI. Three methods have been used to determine low-usage codons in these species. The first and most common way of assessing codon usage is by summing the number of time codons appear in reading frames of the genome in question. The second way is to examine the distribution of usage in different genes by scoring the number of protein reading frames in which a particular codon does not appear. The third way starts with a similar notion, but instead considers combinations of codons that are missing from the maximum number of genes. These three methods give very similar results. Each species has a unique combination of eight least-used codons, but all species contain the arginine codons, CGA and CGG. The agreement between YSC and PRI is particularly striking as they share six low-usage codons. All six carry the dinucleotide sequence, CG. The eight least-used codons in PRI include all codons that contain the CG dinucleotide sequence. Low-usage codons are clearly avoided in genes encoding abundant proteins for ECO, YSC DRO. In all species, proteins containing a high percentage of low-usage codons could be characterized as cases where an excess of the protein could be detrimental. Low codon usage is relatively insensitive to gross base composition. However, dinucleotide usage can sometimes influence codon usage. This is particularly notable in the case of CG dinucleotides in PRI.

Two nearby sites bind zen protein independently

The region upstream from the zerknullt (zen) gene contains three sites that specifically bind the zen protein product of the gene. Evidence for these binding sites was obtained by the filter binding technique and the DNase footprinting technique. The filter binding technique was used to scan various segments of DNA for the presence of possible specific binding sites. Segments that were selectively retained by the filter binding technique invariably contained one or more specific binding sites according to the DNase footprinting technique. Two of the zen protein binding sites were spaced only 30 base pairs apart. These sites could be separated without any loss in their specific binding properties. It is concluded that these two sites function independently in the binding of zen protein.

Regulation of gene expression in plasmid ColE1: delayed expression of the kil gene

cea, imm, and kil are a cluster of three functionally related genes of the plasmid ColE1. The cea and kil genes are in the same inducible operon, with transcription being initiated from a promoter adjacent to the cea gene. The imm gene is located between the cea and kil genes, but it is transcribed in the opposite direction. Complementary interaction between the imm mRNA and the anti-imm sequences in the middle of the cea-kil transcript causes a pronounced delay in expression of the kil gene when the cea-kil operon is induced. A segment in the overlapping region between the cea and imm genes causes delayed expression of the kil gene in the absence of imm gene transcription. This delay effect increases the yields of colicin synthesized in induced cells.

Purification and properties of the Drosophila zen protein

The zen protein is encoded by the zerknullt gene required for normal early development in Drosophila. Like many regulatory proteins of this type, zen contains a 60 amino acid homeobox sequence. We have purified the zen protein and studied its solution behavior and its interaction with DNA. The zen protein exists as a monomer in solution with a molecular weight of about 40,000. It binds specifically to a site about 900 bases upstream from the zen gene. Within this binding site DNase protection experiments indicate that binding is confined to two regions approximately 11 and 14 bases in length that are separated by about 30 base pairs. The protein concentration dependence of the binding curve suggests that protein binding is non cooperative.

Colicin synthesis and cell death

Colicin E1 is a small plasmid, containing the cea gene for colicin, the most prominent product of the plasmid. Colicin is a 56-kilodalton bacteriocin which is especially toxic to Escherichia coli cells that do not contain the plasmid. Under normal growth conditions very low levels of the plasmid are produced as a result of cea gene repression by the host LexA protein. Conditions that lower the concentration of LexA protein result in elevated levels of colicin synthesis. The LexA protein concentration can be lowered by exposing the cells to DNA-damaging reagents such as UV light or mitomycin C. This is because DNA damage signals the host SOS response; the response leads to activation of the RecA protease which degrades the LexA protein. DNA-damaging reagents result in very high levels of colicin synthesis and subsequent death of plasmid-bearing cells. Elevated levels of colicin are also produced in mutants of E. coli that are deficient in LexA protein. We found that comparably high levels of colicin can be produced in such mutants in the absence of cell death. In lexA strains carrying a defective LexA repressor, colicin synthesis shows a strong temperature dependence. Ten to twenty times more colicin is synthesized at 42 degrees C. This sharp dependence of synthesis on temperature suggests that there are factors other than the LexA protein which regulate colicin synthesis.

Mitomycin-induced lethality of Escherichia coli cells containing the ColE1 Plasmid: involvement of the kil gene

Escherichia coli cells containing the ColE1 plasmid or related plasmids are killed by considerably lower levels of mitomycin C (MTC) than are plasmid-free cells. Since exposure to MTC induces high levels of synthesis of the plasmid-encoded colicin toxin, it was originally thought that the killing effect was due to the increased levels of colicin. This possibility was discounted when it was shown that deletion mutations in the plasmid lacking most of the colicin (cea) gene still sensitized host cells to MTC. Only when the region containing the cea gene promoter was deleted did the killing effect disappear. This led to the suggestion that transcription originating from the cea gene promoter and not the colicin protein itself was required for killing. Transcription-blocking mutations in the cea gene support this suggestion. It was proposed that there is a gene (kil) located downstream from the cea gene in the same operon that is responsible for MTC killing and colicin transport. The precise location of the kil gene in ColE1 can be predicted by piecing together published sequence information. We used available sequence data to construct a number of well-defined plasmid mutants to further examine the relevance of transcription from the cea promoter and the kil gene to drug-induced killing and colicin transport. The most informative mutant had a small insertion in the kil gene. This mutant behaved as predicted; cells containing it had a greatly lowered sensitivity to MTC and were severely inhibited in the transport of colicin.

Constancy of DNA organization of polymorphic and nonpolymorphic genes during development in Xenopus

A study was undertaken to test for the occurrence of DNA rearrangements or amplifications during embryonic development in Xenopus laevis. DNA isolated from testes and liver was digested with four restriction enzymes, separated on agarose gels, transferred to nitrocellulose, and hybridized with over 50 cloned cDNA probes generated from embryonic poly (A)+ RNA. No qualitative or quantitative differences were detectable in the DNA hybridization patterns of testes and liver DNA, suggesting that, at least during liver development, selective amplifications or rearrangements occur rarely if at all. In the course of this investigation a wide range of restriction-site polymorphisms for different genes was observed. While some genes showed little polymorphism among different animals, several genes showed considerable polymorphism, involving changes in several restriction enzyme sites. These complex polymorphisms could be the result of gene rearrangements that occur occasionally during the course of sexual reproduction rather than during development.

Analysis of ColE1 expression in vitro after chromosome fragmentation

The RNA and protein products synthesized from ColE1 DNA were observed before and after cutting the DNA with different restriction enzymes. Synthesis was carried out in the DNA-directed coupled transcription translation system. The S-30 extracts used to catalyze synthesis were prepared from a recB mutant in which the linear DNA fragments resulting from restriction enzyme cleavage were spared from the usual degradation by exonucleolytic attack. By correlating the observed in vitro synthesized products with the location of the cleavage sites in the plasmid chromosome, it was possible to identify specific gene products. The col gene catalyzes the synthesis of numerous peptides in addition to the 56-kilodalton colicin protein encoded by this gene. Most of the subsidiary products appear to arise as the result of premature termination by a mechanism(s) which remains to be determined. A unique RNA and protein were characterized as products of the imm gene. The RNA has an estimated mass of 150 kilodaltons, and the protein has an estimated mass of 13 kilodaltons. From the DNA sequence of the chromosome, it was concluded that the transcripts from the imm and col genes must crisscross each other over a region of about 75 base pairs. Such a pattern of transcription might lead to interference of transcription of one gene by the other gene. Consistent with this hypothesis, it was found that imm gene transcription increased severalfold in vitro when the chromosome was cleaved in a way that eliminated transcription originating at the col gene promoter. Surprisingly, the increase in transcription by this mechanism did not result in a significant increase in the synthesis of the imm gene-encoded protein.

Resistance of adenoviral DNA replication to aphidicolin is dependent on the 72-kilodalton DNA-binding protein

Aphidicolin is a highly specific inhibitor of DNA polymerase alpha and has been most useful for assessing the role of this enzyme in various replication processes (J. A. Huberman, Cell 23:647-648, 1981). Both nuclear DNA replication and simian virus 40 DNA replication are highly sensitive to this drug (Krokan et al., Biochemistry 18:4431-4443, 1979), whereas mitochondrial DNA synthesis is completely insensitive (Zimmerman et al., J. Biol. Chem. 255:11847-11852, 1980). Adenovirus DNA replication is sensitive to aphidicolin, but only at much higher concentrations. These patterns of sensitivity are seen both in vivo and in vitro (Krokan et al., Biochemistry 18:4431-4443, 1979). A temperature-sensitive mutant of adenovirus type 5 known as H5ts125 is able to complete but not initiate new rounds of replication at nonpermissive temperatures (P. C. van der Vliet and J. S. Sussenbach, Virology 67:415-426, 1975). When cells infected with H5ts125 were shifted from permissive (33 degrees C) to nonpermissive (41 degrees C) conditions, the residual DNA synthesis (elongation) showed a striking increase in sensitivity to aphidicolin. The temperature-sensitive mutation of H5ts125 is in the gene for the 72-kilodalton single-stranded DNA-binding protein. This demonstrated that the increased resistance to aphidicolin shown by adenovirus DNA replication was dependent on that protein. It also supports an elongation role for both DNA polymerase alpha and the 72-kilodalton single-stranded DNA-binding protein in adenovirus DNA replication. Further support for an elongation role of DNA polymerase alpha came from experiments with permissive temperature conditions and inhibiting levels of aphidicolin in which it was shown that newly initiated strands failed to elongate to completion.

Negative regulation of beta and beta' synthesis by RNA polymerase

The genes for the beta and beta' subunits of RNA polymerase, rpoB and rpoC, and the genes for the two ribosomal proteins, rplL and rplJ, are part of the beta operon. Although this operon and contains a single strong promoter, the genes of the operon are not always coordinately expressed in vivo. This has now been confirmed in vitro where the lack of coordinate expression has been shown to be correlated with the selective inhibition of rpoB and rpoC gene expression by RNa polymerase. Rifampicin, which stops the initiation of transcription, also relieves this autogenous inhibition of beta and beta' (beta beta') synthesis. The inhibitory action of RNA polymerase and its reversal by rifampicin most likely occurs at a posttranscriptional or translation level.

Inhibition of host DNA synthesis by adenovirus infection is reversed at elevated temperatures

Infection of KB cells by adenovirus normally results in a drastic reduction of host DNA synthesis at 33 to 37 degrees C. This inhibition was largely reversed by raising the temperature to 41 degrees C. Inhibition was reinstated if the temperature is lowered.

Cell-free coupled transcription-translation system for investigation of linear DNA segments

Heretofore the DNA-directed coupled transcription-translation system, most useful in gene expression analysis, has been limited to the use of circular or long linear DNAs. Linear DNAs are degraded in this system by an exonucleolytic activity that can be eliminated by making the synthetic extracts from a suitable recB mutant of Escherichia coli. Using these extracts, we have examined the gene expression of a variety of linear DNAs. In particular, the complex pattern of expression of ribosomal protein genes and RNA polymerase genes in the rpoBC-rplLJ region has been analyzed by comparing the protein products obtained when using lambda rifd18 DNA with the product obtained when using the same DNA segmented with various restriction enzymes. The results obtained confirm the conclusions of others obtained by much more elaborate in vivo techniques. It seems highly likely that this cell-free system will have extensive applications in the area of analysis of gene expression.

The replication pattern of adenovirus DNA in vivo reproduced in vitro

Temperature-sensitive mutants of adenovirus type 5 (H5ts125 and H5ts149), which are conditionally inhibited in the initiation of viral DNA synthesis, have been exploited to investigate the possibility of the initiation of replication in a cell-free system. Nuclei were isolated from human KB cells which had been infected with wild-type or mutant adenovirus. More than 90% of the DNA synthesis taking place in such nuclei was virus-specific and the pattern of drug inhibition suggested that the synthesis required DNA polymerase gamma. Nuclei prepared from cells infected with the H5ts125 temperature-sensitive mutant which have been shifted from 33 degrees C to 39.5 degrees C showed a pattern of synthesis in vitro which began at both ends of the viral genome and gradually spread through the rest of the molecule.

Differential sensitivity of gene expression in vitro to inhibitors of DNA gyrase

We have used the antibiotics coumermycin A1, novobiocin, and oxolinic acid, which are specific inhibitors of DNA gyrase, to study the coupled transcription and translation of several bacterial and plasmid genes in a DNA-directed cell-free system. The expression of different genes is reduced to different extents by inhibition of DNA gyrase activity. Among the genes tested, the lac operon, an rRNA gene, and the colicin gene of colicin E1 plasmid were found to be most sensitive, while the trp operon and some other genes in colicin E1 plasmid were relatively unaffected by the inhibitors. These results, together with earlier work on the transcription of circular DNA templates, indicate that DNA supercoiling can significantly enhance transcription from certain promoters.

Synthesis of an R plasmid protein associated with tetracycline resistance is negatively regulated

Synthesis of proteins encoded by the R222 plasmid was observed in a DNA-directed cell-free system and the products were compared to those plasmid proteins synthesized in Escherichia coli minicells. A greater number of plasmid-specified proteins was detected in the in vitro system than in the minicell, suggesting the presence of control factors for plasmid gene expression in the minicell. Synthesis of a newly detected plasmid protein (TET protein) is induced by tetracycline in minicells containing tetracycline-resistant plasmids, including R222, and this induced synthesis correlates with induced host resistance to the drug. This TET protein was synthesized in vitro from R222 DNA in the absence of tetracycline, indicating that no positive regulatory role for tetracycline is required for the protein's synthesis. TET proteon synthesis was inhibited in vitro when cell-free extracts prepared from cells containing the R222 plasmid were used.

In vitro synthesis and repression of argininosuccinase in Escherichia coli K12; partial purification of the arginine repressor

Phi80dargECBH DNA has been used to direct cell-free synthesis of argininosuccinase, the argH gene product in Escherichia coli K12. In vitro enzyme synthesis is sensitive to repression by partially purified preparations from an argR+ strain but not by corresponding preparations from an argR- strain. Using DNA-cellulose chromatography, approximately seventyfold purification of repressor has been obtained. The partially purified preparation represses argininosuccinase synthesis but has no effect on beta-galactosidase synthesis.

Effects of bacteriophage T4-induced modification of Escherichia coli RNA polymerase on gene expression in vitro

After T4 bacteriophage infection of E. coli a complex series of events take place in the bacterium, including gross inhibition of host transcription and discrete changes in the classes of the genes of T4 that are transcribed. Accompanying these changes in the pattern of transcription one finds T4-induced changes in the RNA polymerase (EC 2.7.7.6; nucleosidetriphosphate:RNA nucleotidyltransferase). The effects of modified polymerase on transcription can be advantageously analyzed in a DNA-directed cell-free system for protein synthesis. In this system gene activity is measured indirectly by the amounts and types of proteins sythesized. In the DNA-directed cell-free system this modified polymerase, like normal polymerase, transcribes T4 DNA with a high efficiency but transcribes bacteriophage lambda and host DNA very poorly. Polymerase reconstruction experiments show that modification of the alpha subunit of the RNA polymerase is sufficient for inhibition of host transcription. Host transcription is also inhibited in vitro by T4 DNA. This latter type of inhibition is presumed to involve competition between host DNA and T4 DNA for some factor essential for transcription. The T4-modified polymerase transcribes from T4 DNA many of the same genes as normal unmodified polymerase; it also shows a capability for transcribing certain "non-early" T4 genes which is enhanced in the presence of protein-containing extracts from T4-infected cells.

Effects of guanosine tetraphosphate on cell-free synthesis of Escherichia coli ribosomal RNA and other gene products

A cell-free system derived from E. coli is described in which mature-sized 16S and 23S ribosomal RNAs (rRNA) are synthesized at a high relative rate, comprising 17-25% of the total transcription. The addition of guanosine tetraphosphate (ppGpp) to this system results in up to a 5-fold selective inhibition of rRNA accumulation. This effect is exerted at the level of synthesis rather than degradation. It is concluded that ppGpp, which is produced in large amounts by E. coli during amino-acid deprivation, could mediate the decrease in rRNA synthesis that accompanies such deprivation. The expression of other genes has also been investigated. No selective reduction of transfer RNA synthesis by ppGpp is observed. The trp and lac operons are found to be stimulated at the transcriptional level by the presence of this nucleotide. It is hypothesized that ppGpp interacts with the RNA polymerase in such a manner as to alter the affinity of the enzyme for promoters in an operon-specific fashion.

Prolonged transcription in a cell-free system involving nuclei and cytoplasm

A cell-free system for nuclear-directed transcription has been developed that gives prolonged synthesis in the presence of cytoplasm. The nuclear and cytoplasmic components have been prepared from Krebs II ascites tumor cells for most experiments but further observations indicate that components prepared from other cell types may be used. After an initial 5- to 10-min period of relatively rapid RNA synthesis a linear rate ensues for 2-3 hr. In the absence of cytoplasm no net RNA synthesis occurs after the initial 10-min period. Experiments with alpha-amanitin suggest that about half of the cell-free synthesized RNA is made by RNA polymerase II, the enzyme believed to be responsible for messenger synthesis in vivo.The conditions used for RNA synthesis were derived from conditions found to be optimal for protein synthesis that proceeds linearly for 2-3 hr. It has not yet been possible to demonstrate the synthesis of protein from cell-free synthesized RNA in this system. A major problem here is that isolated nuclei, even when carefully washed, contain a great deal of translatable RNA.

Effects of guanosine tetraphosphate, guanosine pentaphosphate, and beta-gamma methylenyl-guanosine pentaphosphate on gene expression of Escherichia coli in vitro

The effects of guanosine tetraphosphate (ppGpp) and guanosine pentaphosphate (pppGpp), both produced by E. coli, were measured on the activities of several genes in a cell-free system. Gene activity is measured as gene-directed synthesis of biochemically competent protein or transfer RNA. Both ppGpp and pppGpp stimulated the activities of the ara, lac, and trp operons and inhibited the arg operon. Production of transfer-RNA(Tyr) was unaffected by moderate levels of either ppGpp or pppGpp and only slightly inhibited at higher levels of ppGpp. Since the cell-free reaction mixtures hydrolyze pppGpp to ppGpp, we performed similar studies with a hydrolysis-resistant analog of pppGpp, the beta-gamma methylenyl derivative (pcppGpp). In general, pcppGpp shows the same inhibitory potency as pppGpp for the arg operon, but lacks the stimulatory effects on the ara, lac, and trp operons. This result suggests that the stimulation of these gene activities is specific for ppGpp.Under similar conditions, pppGpp and ppGpp show a slight inhibitory effect on the messenger-directed synthesis of beta-galactosidase and no effect on the messenger-directed synthesis of MS2 viral-coat protein. These observations, together with the fact that in the same system these nucleotides affect coupled transcription and translation, lead us to surmise that the activities of pppGpp and ppGpp are exerted at the level of RNA polymerase activity.

Cell-free synthesis of rat growth hormone

Growth hormone has been synthesized in a cell-free system derived from Krebs II ascites cells, under the direction of RNA prepared from rat pituitary tumor (GC) cells. Growth hormone synthesized in the cell-free system was identified by precipitation with antiserum against growth hormone developed in baboon, followed by electrophoretic analysis of the dissolved precipitate on sodium dodecyl sulfate-polyacrylamide gels. RNA from both the membrane and the post-membrane fractions of the cytoplasm of GC cells stimulated protein synthesis in the cell-free system, but only RNA from the membrane fraction was found to direct the synthesis of growth hormone.

Detection and isolation of the repressor protein for the tryptophan operon of Escherichia coli

DNA from a transducing bacteriophage carrying a fusion of the tryptophan and lactose operons of E. coli (lambdadtrp-lac) has been used to direct cell-free synthesis of beta-galactosidase (EC 3.2.1.23). Whereas normal lac operon (lambdadlac) DNA requires adenosine-3':5'-cyclic monophosphate (cAMP) for beta-galactosidase synthesis, trp-lac DNA is unaffected by cAMP. This difference in cAMP dependence verifies the presence of a cAMP-requiring promoter in the lac operon that has been removed from the trp-lac DNA. Synthesis with trp-lac DNA is controlled by the protein product of the tryptophan repressor gene (trpR). Synthesis in extracts of trpR(-) (repressor-negative) cells is progressively reduced by increased additions of extract from trpR(+) cells. No trpR(-) product repression is seen when beta-galactosidase synthesis is programmed by normal lac DNA. This highly sensitive and specific assay has facilitated quantitation and partial purification of the trp repressor.

Purification and DNA-binding properties of the catabolite gene activator protein

A protein required for the activation of the lac operon has been extensively purified and partly characterized. This protein, called CGA protein (catabolite gene activator protein, sometimes named CAP), is a dimer with subunits of 22,000 daltons. Purified CGA protein has a substantial affinity for DNA; this affinity is greatly strengthened by cAMP and strongly inhibited by cGMP. Other studies have shown that these cyclic nucleotides compete for a binding site on CGA protein. The opposing effects of the two cyclic compounds in DNA-CGA protein binding show a parallel behavior to their effects on the expression of the lac operon. Thus cAMP, in addition to CGA protein, is required for expression of the lac operon, whereas cGMP inhibits the expression. The obvious inference is that CGA protein activates the lac operon by binding to the DNA under the influence of cAMP. Thus, CGA protein seems to be a new type of regulatory protein: a DNA-binding activator.

An adenosine 3':5'-cyclic monophosphate-binding protein that acts on the transcription process

An assay system for the in vitro transcription of the lac operon is described. A protein factor (CAP) and cyclic AMP, which are essential for the lac expression in vivo, also stimulate lac transcription in vitro.

Mechanism of activation of catabolite-sensitive genes: a positive control system

Catabolite repression is defined as the inhibition of enzyme induction by glucose or related substances. In the bacterium E. coli, the effect of glucose appears to be due to a lowering of the cyclic AMP level. A DNA-directed cell-free system for beta-galactosidase synthesis has served as a model system for studying the mechanism of action of cyclic AMP. Previously, it was reported that in this system cyclic AMP is required for normal initiation of mRNA synthesis. A protein factor which acts in conjunction with the cyclic AMP has been partially purified. This protein factor has a high affinity for cyclic AMP. These and other results presented herein lead us to the conclusion that cyclic AMP and a protein factor called the catabolite gene activator protein are part of a positive control system for activating catabolite-sensitive genes.

The stimulatory effect of cyclic adenosine 3'5'-monophosphate on DNA-directed synthesis of beta-galactosidase in a cell-free system

A cell-free system allowing for synthesis of beta-galactosidase enzymatic activity has been developed. This system requires DNA containing the beta-galactosidase gene, a cell-free extract of Escherichia coli bacteria, and the low-molecular-weight components necessary for transcription of the DNA and translation of the resulting messenger RNA. Such a system is useful for studying enzyme synthesis, as well as its regulation. The gene for beta-galactosidase is part of the lac operon whose expression is under the control of the lac repressor. In whole cells the lac repressor inhibits almost all of the gene expression for beta-galactosidase. In the cell-free system, we had previously been able to repress about half the gene expression. Adding cyclic adenosine 3'5'-monophosphate to the cell-free system improved the yield of beta-galactosidase enzymatic activity by 8 to 30 times and the efficiency of repression from 50 to 95 per cent.