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Sproul AA, Lambourne LT, Jean-Jacques D J, Kornberg HL
Genetic control of manno(fructo)kinase activity in Escherichia coli.
Proc Natl Acad Sci U S A. 2001; 98: 15257-9
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Mutants of Escherichia coli unable to use fructose by means of the phosphoenolpyruvate/glycose phosphotransferase system mutate further to permit growth on that ketose by derepression of a manno(fructo)kinase (Mak(+) phenotype) present in only trace amounts in the parent organisms (Mak-o phenotype). The mak gene was located at min 8.8 on the E. coli linkage map as an ORF designated yajF, of hitherto unknown function; it specifies a deduced polypeptide of 344 aa. The derepression of Mak activity was associated with a single base change at position 71 (codon 24) of the gene, where GCC (alanine) in Mak-o has been changed to GAC (aspartate) in Mak(+). By cloning selected portions of the total 1,032-bp mak gene into a plasmid that also carried a temperature-sensitive promoter, we showed that the mutation resided in a 117-bp region that does not specify sequences necessary for Mak activity but was located 46 bp upstream of a 915-bp portion that does. Mak(+) and Mak-o strains differ greatly in the heat stability of the enzyme: at 61 degrees C, mak-o cloned into a mak-o recipient loses 50% of its activity in approximately 6 min, whereas it takes over 30 min to achieve a similar reduction in the activity of mak(+) cloned into a mak-o strain. However, the Mak activity of the cloned fragment specifying the enzyme without the regulatory region lost activity with a half-life of 29 min irrespective of whether it was derived from a mak(+) or a mak-o donor, which indicates that the A24D mutation contributes to the high enzyme activity of Mak(+) mutants by serving to protect Mak from denaturation.

Boos W, Shuman H
Maltose/maltodextrin system of Escherichia coli: transport, metabolism, and regulation.
Microbiol Mol Biol Rev. 1998; 62: 204-29
Display abstract
The maltose system of Escherichia coli offers an unusually rich set of enzymes, transporters, and regulators as objects of study. This system is responsible for the uptake and metabolism of glucose polymers (maltodextrins), which must be a preferred class of nutrients for E. coli in both mammalian hosts and in the environment. Because the metabolism of glucose polymers must be coordinated with both the anabolic and catabolic uses of glucose and glycogen, an intricate set of regulatory mechanisms controls the expression of mal genes, the activity of the maltose transporter, and the activities of the maltose/maltodextrin catabolic enzymes. The ease of isolating many of the mal gene products has contributed greatly to the understanding of the structures and functions of several classes of proteins. Not only was the outer membrane maltoporin, LamB, or the phage lambda receptor, the first virus receptor to be isolated, but also its three-dimensional structure, together with extensive knowledge of functional sites for ligand binding as well as for phage lambda binding, has led to a relatively complete description of this sugar-specific aqueous channel. The periplasmic maltose binding protein (MBP) has been studied with respect to its role in both maltose transport and maltose taxis. Again, the combination of structural and functional information has led to a significant understanding of how this soluble receptor participates in signaling the presence of sugar to the chemosensory apparatus as well as how it participates in sugar transport. The maltose transporter belongs to the ATP binding cassette family, and although its structure is not yet known at atomic resolution, there is some insight into the structures of several functional sites, including those that are involved in interactions with MBP and recognition of substrates and ATP. A particularly astonishing discovery is the direct participation of the transporter in transcriptional control of the mal regulon. The MalT protein activates transcription at all mal promoters. A subset also requires the cyclic AMP receptor protein for transcription. The MalT protein requires maltotriose and ATP as ligands for binding to a dodecanucleotide MalT box that appears in multiple copies upstream of all mal promoters. Recent data indicate that the ATP binding cassette transporter subunit MalK can directly inhibit MalT when the transporter is inactive due to the absence of substrate. Despite this wealth of knowledge, there are still basic issues that require clarification concerning the mechanism of MalT-mediated activation, repression by the transporter, biosynthesis and assembly of the outer membrane and inner membrane transporter proteins, and interrelationships between the mal enzymes and those of glucose and glycogen metabolism.

Peist R, Schneider-Fresenius C, Boos W
The MalT-dependent and malZ-encoded maltodextrin glucosidase of Escherichia coli can be converted into a dextrinyltransferase by a single mutation.
J Biol Chem. 1996; 271: 10681-9
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malZ is a member of the mal regulon. It is controlled by MatT, the transcriptional activator of the maltose system. MalZ has been purified and identified as an enzyme hydrolyzing maltotriose and longer maltodextrins to glucose and maltose. MalZ is dispensable for growth on maltose or maltodextrins. Mutants lacking amylomaltase (encoded by malQ), the major maltose utilizing enzyme, cannot grow on maltose, maltotriose, or maltotetraose, despite the fact that they contain an effective transport system and MalZ. From such a malQ mutant a pseudorevertant was isolated that was able to grow on maltose. The suppressor mutation was mapped in malZ. The mutant gene was cloned. It contained a Trp to Cys exchange at position 292 of the deduced protein sequence. Surprisingly, the purified mutant enzyme was still unable to hydrolyze maltose as was the wild type enzyme, while both were able to release glucose from maltodextrins. However, the mutant enzyme had gained the ability to transfer dextrinyl moieties to glucose, maltose, and other maltodextrins. Thus, it had gained an activity associated with amylomaltase. It was the MalZ292-associated transferase reaction that allowed the utilization of maltose. In addition, we discovered that mutant and wild type enzyme alike were highly active as gamma-cyclodextrinases.

Bohringer J, Fischer D, Mosler G, Hengge-Aronis R
UDP-glucose is a potential intracellular signal molecule in the control of expression of sigma S and sigma S-dependent genes in Escherichia coli.
J Bacteriol. 1995; 177: 413-22
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The sigma S subunit of RNA polymerase is the master regulator of a regulatory network that controls stationary-phase induction as well as osmotic regulation of many genes in Escherichia coli. In an attempt to identify additional regulatory components in this network, we have isolated Tn10 insertion mutations that in trans alter the expression of osmY and other sigma S-dependent genes. One of these mutations conferred glucose sensitivity and was localized in pgi (encoding phosphoglucose isomerase). pgi::Tn10 strains exhibit increased basal levels of expression of osmY and otsBA in exponentially growing cells and reduced osmotic inducibility of these genes. A similar phenotype was also observed for pgm and galU mutants, which are deficient in phosphoglucomutase and UDP-glucose pyrophosphorylase, respectively. This indicates that the observed effects on gene expression are related to the lack of UDP-glucose (or a derivative thereof), which is common to all three mutants. Mutants deficient in UDP-galactose epimerase (galE mutants) and trehalose-6-phosphate synthase (otsA mutants) do not exhibit such an effect on gene expression, and an mdoA mutant that is deficient in the first step of the synthesis of membrane-derived oligosaccharides, shows only a partial increase in the expression of osmY. We therefore propose that the cellular content of UDP-glucose serves as an internal signal that controls expression of osmY and other sigma S-dependent genes. In addition, we demonstrate that pgi, pgm, and galU mutants contain increased levels of sigma S during steady-state growth, indicating that UDP-glucose interferes with the expression of sigma S itself.

Hashimoto W, Suzuki H, Nohara S, Tachi H, Yamamoto K, Kumagai H
Subunit association of gamma-glutamyltranspeptidase of Escherichia coli K-12.
J Biochem. 1995; 118: 1216-23
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gamma-Glutamyltranspeptidase [EC 2.3.2.2] of Escherichia coli K-12 consists of one large subunit and one small subunit, which can be separated from each other by high-performance liquid chromatography. Using ion spray mass spectrometry, the masses of the large and the small subunit were determined to be 39,207 and 20,015, respectively. The large subunit exhibited no gamma-glutamyltranspeptidase activity and the small subunit had little enzymatic activity, but a mixture of the two subunits showed partial recovery of the enzymatic activity. The results of native-polyacrylamide gel electrophoresis suggested that they could partially recombine, and that the recombined dimer exhibited enzymatic activity. The gene of gamma-glutamyltranspeptidase encoded a signal peptide, and the large and small subunits in a single open reading frame in that order. Two kinds of plasmid were constructed encoding the signal peptide and either the large or the small subunit. A gamma-glutamyltranspeptidase-less mutant of E. coli K-12 was transformed with each plasmid or with both of them. The strain harboring the plasmid encoding each subunit produced a small amount of the corresponding subunit protein in the periplasmic space but exhibited no enzymatic activity. The strain transformed with both plasmids together exhibited the enzymatic activity, but its specific activity was approximately 3% of that of a strain harboring a plasmid encoding the intact structural gene. These results indicate that a portion of the separated large and small subunits can be reconstituted in vitro and exhibit the enzymatic activity, and that the expressed large and small subunits independently are able to associate in vivo and be folded into an active structure, though the specific activity of the associated subunits was much lower than that of native enzyme. This suggests that the synthesis of gamma-glutamyltranspeptidase in a single precursor polypeptide and subsequent processing are more effective to construct the intact structure of gamma-glutamyltranspeptidase than the association of the separated large and small subunits.

Kohl L, Callens M, Wierenga RK, Opperdoes FR, Michels PA
Triose-phosphate isomerase of Leishmania mexicana mexicana. Cloning and characterization of the gene, overexpression in Escherichia coli and analysis of the protein.
Eur J Biochem. 1994; 220: 331-8
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The gene of triose-phosphate isomerase in Leishmania mexicana has been cloned and characterized. The gene encodes a polypeptide of 251 amino acids, with a calculated molecular mass of 27,561 Da and a net charge of +2. Only one gene could be detected, although the enzyme is present in two different compartments of the cell, in microbody-like organelles called glycosomes and in the cytosol. The primary structure of the enzyme has many features in common with that of triose-phosphate isomerase in the related organism Trypanosoma brucei. Their sequences are 68% identical. The residues constituting the subunit interface are highly conserved between the enzyme of L. mexicana and T. brucei, but are mostly different from those in the enzyme of other organisms. One major substitution was detected in the interface region of the L. mexicana protein: a glutamate was found at position 66, instead of glutamine in all other available 20 sequences. The glutamine is thought to be important for the stability of the dimeric enzyme. L. mexicana triose-phosphate isomerase has been overexpressed in Escherichia coli. Growth conditions were established to obtain high levels of soluble and active protein. The enzyme has been purified to near homogeneity. It appears a stable dimeric protein with a specific activity of 5500 units/mg protein, a subunit mass of 28 kDa and an isoelectric point of 9.0. The enzyme has also been partially purified from glycosomes of cultured L. mexicana promastigotes. Some kinetic properties of the recombinant protein have been compared with those of the promastigote enzyme and with the values previously reported for the T. brucei enzyme. The kinetics of the different enzyme preparations were very similar. For the recombinant enzyme the following values were measured: with glyceraldehyde 3-phosphate as substrate Km = 0.30 +/- 0.05 mM and kcat = 2.5 x 10(5) min-1; with dihydroxyacetone phosphate as substrate Km = 1.3 +/- 0.3 mM and kcat = 2.8 x 10(4) min-1.

Decker K, Peist R, Reidl J, Kossmann M, Brand B, Boos W
Maltose and maltotriose can be formed endogenously in Escherichia coli from glucose and glucose-1-phosphate independently of enzymes of the maltose system.
J Bacteriol. 1993; 175: 5655-65
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The maltose system in Escherichia coli consists of cell envelope-associated proteins and enzymes that catalyze the uptake and utilization of maltose and alpha,1-4-linked maltodextrins. The presence of these sugars in the growth medium induces the maltose system (exogenous induction), even though only maltotriose has been identified in vitro as an inducer (O. Raibaud and E. Richet, J. Bacteriol., 169:3059-3061, 1987). Induction is dependent on MalT, the positive regulator protein of the system. In the presence of exogenous glucose, the maltose system is normally repressed because of catabolite repression and inducer exclusion brought about by the phosphotransferase-mediated vectorial phosphorylation of glucose. In contrast, the increase of free, unphosphorylated glucose in the cell induces the maltose system. A ptsG ptsM glk mutant which cannot grow on glucose can accumulate [14C]glucose via galactose permeases. In this strain, internal glucose is polymerized to maltose, maltotriose, and maltodextrins in which only the reducing glucose residue is labeled. This polymerization does not require maltose enzymes, since it still occurs in malT mutants. Formation of maltodextrins from external glucose as well as induction of the maltose system is absent in a mutant lacking phosphoglucomutase, and induction by external glucose could be regained by the addition of glucose-1-phosphate entering the cells via a constitutive glucose phosphate transport system. malQ mutants, which lack amylomaltase, are constitutive for the expression of the maltose genes. This constitutive nature is due to the formation of maltose and maltodextrins from the degradation of glycogen.

Yoshimoto T et al.
Cloning and sequencing of the 7 alpha-hydroxysteroid dehydrogenase gene from Escherichia coli HB101 and characterization of the expressed enzyme.
J Bacteriol. 1991; 173: 2173-9
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The 7 alpha-hydroxysteroid dehydrogenase (EC 1.1.1.159) gene from Escherichia coli HB101 was cloned and expressed in E. coli DH1. The hybrid plasmid pSD1, with a 2.8-kbp insert of chromosomal DNA at the BamHI site of pBR322, was subcloned into pUC19 to construct plasmid pSD3. The entire nucleotide sequence of an inserted PstI-BamHI fragment of plasmid pSD3 was determined by the dideoxy chain-termination method. Within this sequence, the mature enzyme protein-encoding sequence was found to start at a GTG initiation codon and to comprise 765 bp, as judged by comparison with the protein sequence. The deduced amino acid sequence of the enzyme indicated that the molecular weight is 26,778. The transformant of E. coli DH1 harboring pSD3 with a 1.8-kbp fragment showed about 200-fold-higher enzyme activity than the host. The enzyme was purified by a single chromatography step on DEAE-Toyopearl and obtained as crystals, with an activity yield of 39%. The purified enzyme was homogeneous, as judged by sodium dodecyl sulfate gel electrophoresis. The enzyme was most active at pH 8.5 and stable between pH 8 and 9. The enzyme was NAD+ dependent and had a pI of 4.3. The molecular mass was estimated to be 120 kDa by the gel filtration method and 28 kDa by electrophoresis, indicating that the enzyme exists in a tetrameric form.

Dardonville B, Raibaud O
Characterization of malT mutants that constitutively activate the maltose regulon of Escherichia coli.
J Bacteriol. 1990; 172: 1846-52
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The expression of the maltose regulon of Escherichia coli is controlled by a transcriptional activator, the product of the malT gene, and is induced by the presence of maltose or maltodextrins in the growth medium. We isolated eight mutants with mutations in malT which lead to constitutive expression of the regulon. The nucleotide sequences of the mutated genes revealed that the eight mutations are clustered in two small regions in the first one-third of the malT gene. Two mutated MalT proteins (corresponding to a mutation in each cluster) were purified and examined for in vitro activation of the MalT-dependent malPp promoter. Whereas wild-type MalT activity was absolutely dependent upon the presence of maltotriose, even at high protein concentrations, both mutated proteins were partially active in the absence of this sugar. Indeed, while the activity of the mutated proteins was still increased by maltotriose at low protein concentrations, the proteins were fully active in the absence of maltotriose at high protein concentrations. Both proteins exhibited a fivefold-higher affinity for maltotriose than the wild-type protein did.

Peri KG, Goldie H, Waygood EB
Cloning and characterization of the N-acetylglucosamine operon of Escherichia coli.
Biochem Cell Biol. 1990; 68: 123-37
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Three enzymes are required for N-acetylglucosamine (NAG) utilization in Escherichia coli: enzyme IInag (gene nagE), N-acetylglucosamine-6-phosphate deacetylase (gene nagA), and glucosamine-6-phosphate isomerase (gene nagB). The three genes are located near 16 min on the E. coli chromosome. A strain of E. coli, KPN9, incapable of utilizing N-acetylglucosamine, was used to screen a genomic library of E. coli for a complementing recombinant colicin E1 plasmid that allowed for growth on N-acetylglucosamine. Plasmid pLC5-21 was found to contain all three known nag genes on a 5.7-kilobase (5.7-kb) fragment of DNA. The products of these nag genes were identified by complementation of E. coli strains with mutations in nagA, nagB, and nagE. The gene products from the 5.7-kb fragment were identified by [35S]methionine-labelled maxicells and autoradiography of sodium dodecyl sulphate-polyacrylamide electrophoresis gels. The gene products had the following relative masses (Mrs: nagE, 62,000; nagA, 45,000; nagB, 29,000. In addition, another product of Mr 44,000 was detected. The genes have been sequenced to reveal an additional open reading frame (nagC), a putative catabolite activator protein binding site that may control nagB and nagE, putative rho-independent terminator sites for nagB and nagE, and sequence homologies for RNA polymerase binding sites preceding each of the open reading frames, except for nagA. The calculated molecular weight (MWs) of the gene products derived from the sequence are as follows: nagA, 40,954; nagB, 29,657; nagC, 44,664; nagE, 68,356. No role is known for nagC, although a number of regulatory roles appear to be plausible. No obvious transcriptional termination site distal to nagC was found and another open reading frame begins after nagC. This gene, nagD, was isolated separately from pLC5-21, and the sequence revealed a protein with a calculated MW of 27,181. The nagD gene is followed by repetitive extragenic palindromic sequences. The nag genes appear to be organized in an operon: nagD nagC nagA nagB nagE.

Burne RA, Schilling K, Bowen WH, Yasbin RE
Expression, purification, and characterization of an exo-beta-D-fructosidase of Streptococcus mutans.
J Bacteriol. 1987; 169: 4507-17
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A genetic library of Streptococcus mutans GS-5, constructed in an Escherichia coli plasmid vector, was screened for cells which could utilize sucrose as the sole carbon and energy source. The recombinant plasmid pFRU1, containing a 4.2-kilobase pair insert of S. mutans DNA, was shown to confer this phenotype. Further characterization of the gene product encoded by pFRU1 revealed that the enzyme was a beta-D-fructosidase with the highest specificity for the beta (2----6)-linked fructan polymer levan. The enzyme could also hydrolyze inulin [beta (2----1)-linked fructan], sucrose, and raffinose with 34, 21, and 12%, respectively, of the activity observed for levan. The gene (designated fruA) appeared to be expressed under its own control in E. coli, as judged by the lack of influence on gene product activity of induction or repression of the beta-galactosidase promoter adjacent to the insertion site on the cloning vector. The protein was purified to homogeneity, as judged by silver staining of purified protein in denaturing and reducing conditions in polyacrylamide gels, from sonic lysate of E. coli, as well as from culture supernatants of S. mutans GS-5 grown in a chemostat at low dilution rate with fructose as the sole carbohydrate source. Both purified proteins had an apparent molecular mass of 140,000 daltons in sodium dodecyl sulfate-polyacrylamide gel electrophoresis, were immunologically related and comigrated in sodium dodecyl sulfate-polyacrylamide gel electrophoresis as determined by Western blotting with antisera raised against the cloned gene product, and were identical in all physical and biochemical properties tested. The pH optimum of the enzyme acting on fructan polymers was 5.5, with a significant amount of activity remaining at pH 4.0. The optimum pH for sucrose degradation was broader and lower, with a peak at approximately 4.5. Enzyme activity was inhibited almost completely by Hg2+ and Ag2+, inhibited partially by Cu2+, not inhibited by fluoride ion or Tris, and slightly stimulated by Mn2+ and Co2+. Fructan polymers were attacked exohydrolytically by the enzyme, fructose being the only product released. With sufficient time, both levan and inulin were degraded to completion, with no evidence of product inhibition.

Yamada M, Saier MH Jr
Physical and genetic characterization of the glucitol operon in Escherichia coli.
J Bacteriol. 1987; 169: 2990-4
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The glucitol (gut) operon has been identified in the colony bank of Clark and Carbon (A. Sancar and W. D. Rupp, Proc. Natl. Acad. Sci. USA 76:3144-3148, 1979). We subcloned the gut operon by using paCYC184, pACYC177, and pBR322. The operon, which is encoded in a 3.3-kilobase nucleotide fragment, consists of the gutC, gutA, gutB, and gutD genes. The repressor of the gut operon seemed to be encoded in the region downstream from the operon. The gene products of the gut operon were identified by using maxicells. The apparent molecular weights of the glucitol-specific enzyme II (product of the gutA gene), enzyme III (product of the gutB gene), and glucitol-6-phosphate dehydrogenase (product of the gutD gene) were about 46,000, 13,500, and 27,000, respectively, as estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis.

Shanley MS, Neidle EL, Parales RE, Ornston LN
Cloning and expression of Acinetobacter calcoaceticus catBCDE genes in Pseudomonas putida and Escherichia coli.
J Bacteriol. 1986; 165: 557-63
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This report describes the isolation and preliminary characterization of a 5.0-kilobase-pair (kbp) EcoRI DNA restriction fragment carrying the catBCDE genes from Acinetobacter calcoaceticus. The respective genes encode enzymes that catalyze four consecutive reactions in the catechol branch of the beta-ketoadipate pathway: catB, muconate lactonizing enzyme (EC 5.5.1.1); catC, muconolactone isomerase (EC 5.3.3.4); catD, beta-ketoadipate enol-lactone hydrolase (EC 3.1.1.24); and catE, beta-ketoadipate succinyl-coenzyme A transferase (EC 2.8.3.6). In A. calcoaceticus, pcaDE genes encode products with the same enzyme activities as those encoded by the respective catDE genes. In Pseudomonas putida, the requirements for both catDE and pcaDE genes are met by a single set of genes, designated pcaDE. A P. putida mutant with a dysfunctional pcaE gene was used to select a recombinant pKT230 plasmid carrying the 5.0-kbp EcoRI restriction fragment containing the A. calcoaceticus catE structural gene. The recombinant plasmid, pAN1, complemented P. putida mutants with lesions in catB, catC, pcaD, and pcaE genes; the complemented activities were expressed constitutively in the recombinant P. putida strains. After introduction into Escherichia coli, the pAN1 plasmid expressed the activities constitutively but at much lower levels that those found in the P. putida transformants or in fully induced cultures of A. calcoaceticus or P. putida. When placed under the control of a lac promoter on a recombinant pUC13 plasmid in E. coli, the A. calcoaceticus restriction fragment expressed catBCDE activities at levels severalfold higher than those found in fully induced cultures of A. calcoaceticus. Thus there is no translational barrier to expression of the A. calcoaceticus genes at high levels in E. coli. The genetic origin of the cloned catBCDE genes was demonstrated by the fact that the 5.0-kbp EcoRI restriction fragment hybridized with a corresponding fragment from wild-type A. calcoaceticus DNA. This fragment was missing in DNA from an A. calcoaceticus mutant in which the cat genes had been removed by deletion. The properties of the cloned fragment demonstrate physical linkage of the catBCDE genes and suggest that they are coordinately transcribed.

Black PN, Kianian SF, DiRusso CC, Nunn WD
Long-chain fatty acid transport in Escherichia coli. Cloning, mapping, and expression of the fadL gene.
J Biol Chem. 1985; 260: 1780-9
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Transport of long-chain fatty acids across the inner membrane of Escherichia coli K-12 requires a functional fadL gene (Maloy, S. R., Ginsburgh, C. L., Simons, R. W., and Nunn, W. D. (1981) J. Biol. Chem. 256, 3735-3742). Mutants defective in the fadL gene lack a 33,000-dalton inner membrane protein as evaluated using two-dimensional pI/sodium dodecyl sulfate (SDS) polyacrylamide gel electrophoresis (Ginsburgh, C. L., Black, P. N., and Nunn, W. D. (1984) J. Biol. Chem. 259, 8437-8443). In an effort to determine whether the fadL gene is the structural gene for this 33,000-dalton protein, we have cloned, mapped, and analyzed the expression of the fadL gene. The fadL gene has been localized on a 2.8-kilobase EcoRV fragment of E. coli genomic DNA. Plasmids containing this gene (i) complement all fadL mutants, (ii) increase the long-chain fatty acid transport activity of fadL strains harboring them by 2- to 3-fold, and (iii) direct the synthesis of a membrane protein which has the same molecular weight and isoelectric point as that described by Ginsburgh et al. This is a heat-modifiable protein which has an apparent molecular weight of 43,000 daltons when solubilized at 100 degrees C in the presence of SDS and 33,000 daltons when solubilized at 50 degrees C in the presence of SDS.

Goldman RC, Kohlbrenner WE
Molecular cloning of the structural gene coding for CTP:CMP-3-deoxy-manno-octulosonate cytidylyltransferase from Escherichia coli K-12.
J Bacteriol. 1985; 163: 256-61
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The kdsB gene from Escherichia coli K-12, which encodes CTP:CMP-3-deoxy-manno-octulosonate cytidylyltransferase (CMP-KDO synthetase), was cloned into pBR322 as an 8-kilobase PstI fragment. Selection of this cloned segment was facilitated by using Salmonella typhimurium SL5283, which is deficient in three restriction enzyme systems and thus allows efficient cloning of E. coli DNA in S. typhimurium. The temperature-sensitive kdsB gene from S. typhimurium HD2 was transduced into strain SL5283 after the insertion of transposon Tn10 near the kdsB allele. Tetracycline-sensitive variants of strain SL5283 were then derived and used to select clones of the E. coli K-12 gene, inserted into the PstI site of pBR322, by complementation of the temperature-sensitive lesion in kdsB. One plasmid, pRG-1, complemented the kdsB temperature-sensitive allele and had the following characteristics: (i) it coded for several polypeptides by coupled transcription-translation in vitro, including one polypeptide which comigrated with CMP-KDO synthetase during polyacrylamide gel electrophoresis in sodium dodecyl sulfate; (ii) it overproduced CMP-KDO synthetase activity 20- to 40-fold depending on strain and growth conditions; and (iii) it coded for activity of CMP-KDO synthetase which, when purified to homogeneity, had the same molecular weight and kinetic characteristics as CMP-KDO synthetase of chromosomal origin.

Bondaryk RP, Paulus H
Cloning and structure of the gene for the subunits of aspartokinase II from Bacillus subtilis.
J Biol Chem. 1985; 260: 585-91
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A library of Bacillus subtilis DNA in lambda Charon 4A (Ferrari, E., Henner, D.J., and Hoch, J.A. (1981) J. Bacteriol. 146, 430-432) was screened by an immunological procedure for DNA sequences encoding aspartokinase II of B. subtilis, an enzyme composed of two nonidentical subunits arranged in an alpha 2 beta 2 structure (Moir, D., and Paulus, H. (1977a) J. Biol. Chem. 252, 4648-4654). A recombinant bacteriophage was identified that harbored an 18-kilobase B. subtilis DNA fragment containing the coding sequences for both aspartokinase subunits. The coding sequence for aspartokinase II was subcloned into bacterial plasmids. In response to transformation with the recombinant plasmids, Escherichia coli produced two polypeptides immunologically related to B. subtilis aspartokinase II with molecular weights (43,000 and 17,000) indistinguishable from those found in enzyme produced in B. subtilis. Peptide mapping by partial proteolysis confirmed the identity of the polypeptides produced by the transformed E. coli cells with the B. subtilis aspartokinase II subunits. The size of the cloned B. subtilis DNA fragment could be reduced to 2.9 kilobases by cleavage with PstI restriction endonuclease without affecting its ability to direct the synthesis of complete aspartokinase II subunits, irrespective of its orientation in the plasmid vector. Further subdivision by cleavage with BamHI restriction endonuclease resulted in the production of truncated aspartokinase subunits, each shortened by the same extent. This suggested that a single DNA sequence encoded both aspartokinase subunits and provided an explanation for the earlier observation that the smaller beta subunit of aspartokinase II was highly homologous or identical with the carboxyl-terminal portion of the alpha subunit (Moir, D., and Paulus, H. (1977b) J. Biol. Chem. 252, 4655-4661). A map of the gene for B. subtilis aspartokinase II is proposed in which the coding sequence for the smaller beta subunit overlaps in the same reading frame the promoter-distal portion of the coding sequence for the alpha subunit.

Hatfield D, Hofnung M, Schwartz M
Nonsense mutations in the maltose A region of the genetic map of Escherichia coli.
J Bacteriol. 1969; 100: 1311-5
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The isolation of one amber mutation in malQ, one ochre mutation in malP, and seven amber mutations in malT is reported. A study of their phenotypic expressions in the presence of the amber suppressor su(III) and the ochre suppressor su(c) suggests that (i) malQ is the structural gene for amylomaltase; (ii) malQ and the structural gene for maltodextrin phosphorylase, malP, belong to the same operon; (iii) the malT product, which promotes the expression of the malP-malQ operon, is a protein synthesized in limiting amounts by the wild-type strain.