Although genetic and biochemical evidence has established that GroES is required for the full function of the molecular chaperone, GroEL, little is known about the molecular details of their interaction. GroES enhances the cooperativity of ATP binding and hydrolysis by GroEL (refs 4, 5) and is necessary for release and folding of several GroEL substrates. Here we report that native GroES has a highly mobile and accessible polypeptide loop whose mobility and accessibility are lost upon formation of the GroES/GroEL complex. In addition, lesions present in eight independently isolated mutant groES alleles map in the mobile loop. Studies with synthetic peptides suggest that the loop binds in a hairpin conformation at a site on GroEL that is distinct from the substrate-binding site. Flexibility may be required in the mobile loops on the GroES seven-mer to allow them to bind simultaneously to sites on seven GroEL subunits, which may themselves be able to adopt different arrangements, and thus to modulate allosterically GroEL/substrate affinity.
In Rhodobacter sphaeroides 2.4.1, the cellular requirements for 5-aminolevulinic acid (ALA) are in part regulated by the level of ALA synthase activity, which is encoded by the hemA and hemT genes. Under standard growth conditions, only the hemA gene is transcribed, and the level of ALA synthase activity varies in response to oxygen tension. The presence of an FNR consensus sequence upstream of hemA suggested that oxygen regulation of hemA expression could be mediated, in part, through a homolog of the fnr gene. Two independent studies, one detailed here, identified a region of the R. sphaeroides 2.4.1 genome containing extensive homology to the fix region of the symbiotic nitrogen-fixing bacteria Rhizobium meliloti and Bradyrhizobium japonicum. Within this region that maps to 443 kbp on chromosome I, we have identified an fnr homolog (fnrL), as well as a gene that codes for an anaerobic coproporphyrinogen III oxidase, the second such gene identified in this organism. We also present an analysis of the role of fnrL in the physiology of R. sphaeroides 2.4.1 through the construction and characterization of fnrL-null strains. Our results further show that fnrL is essential for both photosynthetic and anaerobic-dark growth with dimethyl sulfoxide. Analysis of hemA expression, with hemA::lacZ transcriptional fusions, suggests that FnrL is an activator of hemA under anaerobic conditions. On the other hand, the open reading frame immediately upstream of hemA appears to be an activator of hemA transcription regardless of either the presence or the absence of oxygen or FnrL. Given the lack of hemT expression under these conditions, we consider FnrL regulation of hemA expression to be a major factor in bringing about changes in the level of ALA synthase activity in response to changes in oxygen tension.
The means by which oxygen intervenes in gene expression has been examined in considerable detail in the metabolically versatile bacterium Rhodobacter sphaeroides. Three regulatory systems are now known in this organism, which are used singly and in combination to modulate genes in response to changing oxygen availability. The outcome of these regulatory events is that the molecular machinery is present for the cell to obtain energy by means that are best suited to prevailing conditions, while at the same time maintaining cellular redox balance. Here, we explore the dangers associated with molecular oxygen relative to the various metabolisms used by R. sphaeroides, and then present the most recent findings regarding the features and operation of each of the three regulatory systems which collectively mediate oxygen control in this organism.
Rhodobacter sphaeroides 2.4.1 has the ability to synthesize a variety of tetrapyrroles, reflecting the metabolic versatility of this organism and making it capable of aerobic, anaerobic, photosynthetic, and diazotrophic growth. The hemA and hemT genes encode isozymes that catalyze the formation of 5-aminolevulinic acid, the first step in the biosynthesis of all tetrapyrroles present in R. sphaeroides 2.4.1. As part of our studies of the regulation and expression of these genes, we developed a genetic selection that uses transposon mutagenesis to identify loci affecting the aerobic expression of the hemA gene. In developing this selection, we found that sequences constituting an open reading frame immediately upstream of hemA positively affect hemA transcription. Using a transposon-based selection for increased hemA expression in the absence of the upstream open reading frame, we isolated three independent mutants. We have determined that the transposon insertions in these strains map to three different loci located on chromosome I. One of the transposition sites mapped in the vicinity of the recently identified R. sphaeroides 2.4.1 homolog of the anaerobic regulatory gene fnr. By marker rescue and DNA sequence analysis, we found that the transposition site was located between the first two genes of the cco operon in R. sphaeroides 2.4.1, which encodes a cytochrome c terminal oxidase. Examination of the phenotype of the mutant strain revealed that, in addition to increased aerobic expression of hemA, the transposition event also conferred an oxygen-insensitive development of the photosynthetic membranes. We propose that the insertion of the transposon in cells grown in the presence of high oxygen levels has led to the generation of a cellular redox state resembling either reduced oxygen or anaerobiosis, thereby resulting in increased expression of hemA, as well as the accumulation of spectral complex formation. Several models are presented to explain these findings.Rhodobacter sphaeroides 2.4.1, by virtue of its metabolic versatility, would be expected to possess a diversity of regulatory circuits and mechanisms of gene control that enable it to rapidly adapt to changing environmental conditions. A snapshot of the metabolic versatility inherent to this organism is the presence of the four major physiologically active tetrapyrroles, i.e., hemes, bacteriochlorophylls (Bchls), vitamin B 12 , and siroheme, which aptly illustrates the variety of growth conditions to which this organism is capable of adapting. Underlying the presence of these important metabolites is the tetrapyrrole biosynthesis pathway which displays a variety of regulatory features, notably oxygen and light control (see reference 20).The first step in the tetrapyrrole pathway in R. sphaeroides 2.4.1 is the condensation of succinyl-coenzyme A and glycine to 5-aminolevulinic acid (ALA), catalyzed by the enzyme ALA synthase (succinyl-coenzyme A:glycine C-succinyl transferase [decarboxylating] [EC 2.3.1.37]). Unlike all other prokaryotic organisms in wh...
ThegroES and groEL genes ofEscherichia coli have been shown previously to belong to a single operon under heat shock regulation. Both proteins have been universally conserved in nature, as judged by the presence of similar proteins throughout evolution. The GroEL protein has been shown to bind promiscuously to many unfolded proteins, thus preventing their aggregation. ATP hydrolysis by GroEL results in the release of the bound polypeptides, a process that often requires the action of GroES. In an effort to understand GroEL and GroES structure and function, we have determined the nucleotide changes of nine mutant alleles ofgroEL. All of these mutant alleles were isolated because they block bacteriophage A growth. Our sequencing results demonstrate that (i) many of these alleles are identical, in spite of the fact that they were independently isolated, and (ii) most of the different alleles are clustered in the same region of the gene. One of the mutant alleles was shown to possess two nucleotide alterations in the groEL coding phase, one of which is located in a putative ATP-binding domain. The two nucleotide changes were separated by genetic engineering, and each individual change was shown to exert an effect on bacteriophage growth. But, using genetic analyses, we demonstrate that the restriction on bacterial growth at elevated temperatures is conferred only by the mutation within the putative ATP-binding domain. We have cloned the mutant alleles on multicopy plasmids and overexpressed their products. By testing for the ability of bacteriophage either to propagate or to form colonies at 430C, we have been able to divide the mutant proteins into those with no activity and those with residual activity under the various conditions tested.In studies initiated to investigate the role of host-contributed functions in the growth and replication of bacteriophage X, three classes of mutants, termed gro for essential for bacteriophage growth, were isolated (reviewed in reference 11). The groN (now referred to as nus) and groP (now referred to as dnaB, dnaK, dnaJ, and grpE) classes represent the more obvious types of host functions that would be logically implicated by the selection screen used to identify them in that they are involved in transcription or replication of the bacteriophage genome (11,14). Somewhat less obvious is the third class of mutants, groE, that affect X development at the viral particle assembly step (reviewed in reference 33). This class of mutants has also been isolated as tabB (6), mop (30), and hdh (27) mutants, in which the genes were identified through mutations that block X (13, 29) or T4 (6, 27, 30) bacteriophage growth.Mutations of the groE class were found to map to one or the other of two genes forming an operon located at 94 min on the Escherichia coli genetic map. The first gene, groES, codes for a 10,368-Mr protein and the second, groEL, codes for a 57,259-Mr protein. Mutations in either groES orgroEL generally display the same phenotypes, which include the impairment of the growth of ...
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