Millicent Masters

Why Is Carbonic Anhydrase Essential to Escherichia coli

The can (previously yadF) gene of Escherichia coli encodes a beta-class carbonic anhydrase (CA), an enzyme which interconverts CO(2) and bicarbonate. Various essential metabolic processes require either CO(2) or bicarbonate and, although carbon dioxide and bicarbonate spontaneously equilibrate in solution, the low concentration of CO(2) in air and its rapid diffusion from the cell mean that insufficient bicarbonate is spontaneously made in vivo to meet metabolic and biosynthetic needs. We calculate that demand for bicarbonate is 10(3)- to 10(4)-fold greater than would be provided by uncatalyzed intracellular hydration and that enzymatic conversion of CO(2) to bicarbonate is therefore necessary for growth. We find that can expression is ordinarily required for growth in air. It is dispensable if the atmospheric partial pressure of CO(2) is high or during anaerobic growth in a closed vessel at low pH, where copious CO(2) is generated endogenously. CynT, the single E. coli Can paralog, can, when induced with azide, replace Can; also, the gamma-CA from Methanosarcina thermophila can at least partially replace it. Expression studies showed that can transcription does not appear to respond to carbon dioxide concentration or to be autoregulated. However, can expression is influenced by growth rate and the growth cycle; it is expressed best in slow-growing cultures and at higher culture densities. Expression can vary over a 10-fold range during the growth cycle and is also elevated during starvation or heat stress.

GroE is vital for cell-wall synthesis.

Chaperone proteins help other proteins to fold. GroEL, the Escherichia coli form of the ubiquitous Cpn60 chaperonins, has a multimeric barrel-shaped structure with a central cavity, within which almost any protein can fold in vitro. But what does GroE (GroEL plus its co-chaperone GroES) fold in the cell? Why is it needed for cell survival? We report here the first definite identification of an essential, GroE-dependent E. coli protein, dihydropicolinate synthase (DapA), without which cell-wall synthesis fails.

PcnB is required for the rapid degradation of RNAI, the antisense RNA that controls the copy number of ColE1-related plasmids

The replication of CoIE1‐related plasmids is controlled by an unstable antisense RNA, RNAI, which can interfere with the successful processing of the RNAII primer of replication. We show here that a host protein, PcnB, supports replication by promoting the decay of RNAI. In bacterial strains deleted for pcnB a stable, active form of RNAI, RNAI*, which appears to be identical to the product of 5′‐end processing by RNAse E, accumulates. This leads to a reduction in plasmid copy number. We show, using a GST‐ PcnB fusion protein, that PcnB does not interfere with RNAI/RNAII binding in vitro. The fusion protein, like PcnB, has polyadenylating activity and is able to polyadenylate RNAI (and also another antisense RNA, CopA) in vitro.

The Escherichia coli metD Locus Encodes an ABC Transporter Which Includes Abc (MetN), YaeE (MetI), and YaeC (MetQ)

We report that the genes abc, yaeC, and yaeE comprise metD, an Escherichia coli locus encoding a DL-methionine uptake system. MetD is an ABC transporter with Abc the ATPase, YaeE the permease, and YaeC the likely substrate binding protein. Expression of these genes is regulated by L-methionine and MetJ, a common repressor of the methionine regulon. We propose to rename abc, yaeE, and yaeC as metN, metI, and metQ, respectively.

Tools for Characterization of Escherichia coli Genes of Unknown Function

Despite the power of sequencing and of emerging high-throughput technologies to collect data rapidly, the definitive functional characterization of unknown genes still requires biochemical and genetic analysis in case-by-case studies. This often involves the deletion of target genes and phenotypic characterization of the deletants. We describe here modifications of an existing deletion method which facilitates the deletion process and enables convenient analysis of the expression properties of the target gene by replacing it with an FRT-lacZ-aph-P(lac)-FRT cassette. The lacZ gene specifically reports the activity of the deleted gene and therefore allows the determination of the conditions under which it is actively expressed. The aph gene, encoding resistance to kanamycin, provides a selectable means of transducing a deleted locus between strains so that the deletion can be combined with other relevant mutations. The lac promoter helps to overcome possible polar effects on downstream genes within an operon. Because the cassette is flanked by two directly repeated FRT sites, the cassette can be excised by the Flp recombinase provided in trans. Removing the cassette leaves an in-frame deletion with a short scar which should not interfere with downstream expression. Replacements of yacF, yacG, yacH, yacK (cueO), yacL, ruvA, ruvB, yabB, and yabC made with the cassette were used to verify its properties.

The lytB Gene of Escherichia coli Is Essential and Specifies a Product Needed for Isoprenoid Biosynthesis

LytB and GcpE, because they are codistributed with other pathway enzymes, have been predicted to catalyze unknown steps in the nonmevalonate pathway for isoprenoid biosynthesis. We constructed a conditional Escherichia coli lytB mutant and found that LytB is essential for survival and that depletion of LytB results in cell lysis, which is consistent with a role for this protein in isoprenoid biosynthesis. Alcohols which can be converted to pathway intermediates beyond the hypothesized LytB step(s) support limited growth of E. coli lytB mutants. An informatic analysis of protein structure suggested that GcpE is a globular protein of the TIM barrel class and that LytB is also a globular protein. Possible biochemical roles for LytB and GcpE are suggested.

The strongly conserved carboxyl-terminus glycine-methionine motif of the Escherichia coli GroEL chaperonin is dispensable

The universally distributed heat‐shock proteins (HSPs) are divided into classes based on molecular weight and sequence conservation. The members of at least two of these classes, the HSP60s and the HSP70S, have chaperone activity. Most HSP60s and many HSP70s feature a striking motif at or near the carboxyl terminus which consists of a string of repeated glycine and methionine residues. We have altered the groEL gene (encoding the essential Escherichia coli HSP60 chaperonin) so that the protein produced lacks its 16 final (including nine gly, and five met) residues. This truncated product behaves like the intact protein in several in vitro tests, the only discernible difference between the two proteins being in the rate at which ATP is hydrolysed. GroELtr can substitute for GroEL in vivo although cells dependent for survival on the truncated protein survive slightly less well during the stationary phase of growth. Elevated levels of the wild‐type protein can suppress a number of temperature‐sensitive mutations; the truncated protein lacks this ability.

A DNA fragment containing the groE genes can suppress mutations in the Escherichia coli dnaA gene

SummaryAn 8.2 kb fragment of E. coli chromosomal DNA, when cloned in increased copy number, suppresses the dnaA46 mutation, and an abundant protein of about 68 kd (60 kd when measured by us), encoded by the fragment, is essential for the suppression (Takeda and Hirota 1982). Mapping experiments show that the fragment originates from the 94 min region of the chromosome. It encodes several proteins but only one abundant polypeptide of the correct size, the product of the groEL gene. Suppression by the fragment is allele specific; those mutations which map to the centre of the gene are suppressed. Other initiation mutants including dnaA203, dnaA204, dnaA508, dnaAam, dnaC, dnaP and dnaB252 are not suppressed. Most suppressed strains are cold-sensitive suggesting an interaction between the mutant proteins (or their genes) and the suppressing protein or proteins.

Regulation of plasmid R1 replication: PcnB and RNase E expedite the decay of the antisense RNA, CopA

The replication frequency of plasmid R1 is controlled by an unstable antisense RNA, CopA, which, by binding to its complementary target, blocks translation of the replication rate‐limiting protein RepA. Since the degree of inhibition is directly correlated with the intracellular concentration of CopA, factors affecting CopA turnover can also alter plasmid copy number. We show here that PcnB (PAP I — a poly(A)polymerase of Escherichia coli ) is such a factor. Previous studies have shown that the copy number of ColE1 is decreased in pcnB mutant strains because the stability of the RNase E processed form of RNAI, the antisense RNA regulator of ColE1 replication, is increased. We find that, analogously, the twofold reduction in R1 copy number caused by a pcnB lesion is associated with a corresponding increase in the stability of the RNase E‐generated 3′ cleavage product of CopA. These results suggest that CopA decay is initiated by RNase E cleavage and that PcnB is involved in the subsequent rapid decay of the 3′ CopA stem‐loop segment. We also find that, as predicted, under conditions in which CopA synthesis is unaffected, pcnB mutation reduces RepA translation and increases CopA stability to the same extent.

Expression of the Escherichia coli pcnB gene is translationally limited using an inefficient start codon: a second chromosomal example of translation initiated at AUU

Expression of the gene pcnB, encoding the dispensable Escherichia coli poly(A) polymerase (PAPI), which is toxic when overproduced, was investigated. Its promoter was identified and found to be moderately strong when used to express a β‐galactosidase reporter. Expression levels were not affected by increasing or decreasing PcnB concentration. Translation of pcnB was found to initiate from the non‐canonical initiation codon AUU. The only other coli gene reported to use AUU as initiation codon is infC, which encodes the initiation factor IF‐3. AUU, in common with other rarely used initiation codons, is discriminated against by IF‐3, resulting in the aborting of most AUU‐promoted initiation events. This enables AUU to form part of an autoregulatory circuit controlling IF‐3 production. We show that InfC discrimination reduces PcnB production fivefold. This is the first instance of this mechanism being used to limit severely the production of a potentially toxic product.