Copper is an essential transition metal for living organisms but it is detrimental in excess. The metalloregulatory protein copper‐sensing operon repressor (CsoR) in bacteria has evolved to prevent cytoplasmic copper toxicity. Cu(I)‐binding to tetrameric CsoRs mediates transcriptional derepression of copper resistance genes but the mechanism is unknown. A phylogenetic analysis of 227 DUF156 protein members including biochemically or structurally characterized CsoR/RcnR repressors reveals that Geobacillus thermodenitrificans (Gt) CsoR characterized here is representative of CsoRs from pathogenic bacilli Listeria monocytogenes and Bacillus anthracis. The 2.56 Å structure of Cu(I)‐bound Gt CsoR reveals that Cu(I) binding induces a kink in the α2‐helix between two conserved copper‐ligating residues and folds an N‐terminal tail (residues 12‐19) over the Cu(I) binding site. NMR studies of Gt CsoR reveal that this tail is flexible in the apo‐state with these dynamics quenched upon Cu(I) binding. Small angle X‐ray scattering (SAXS) experiments on an N‐terminally truncated Gt CsoR (∆2‐10) reveal that the Cu(I)‐bound tetramer is hydrodynamically more compact than is the apo‐state. A mutational analysis of residues critical to N‐terminal tail folding reveals that these residues function to stabilize the apoprotein‐DNA complex and/or control the extent of allosteric negative regulation of DNA binding by Cu(I), but to varying degrees. The mechanism of Cu(I)‐mediated allosteric switching in CsoRs is discussed. Grant Funding Source: Supported by NIH grant GM042569
The ubiquitous Cation Diffusion Facilitator proteins (CDF) play a key role in maintaining the cellular homeostasis of essential metal ions. Previous neighbor-joining phylogenetic analysis classified CDF proteins into three substrate-defined groups: Zn(2+), Fe(2+)/Zn(2+) and Mn(2+). These studies were unable to discern substrate-defined clades for Ni(2+), Co(2+), Cd(2+) and Cu(2+) transporters, despite their existence in this family. In this study we improved the accuracy of this previous functional classification using a phylogenomic approach based on a thorough maximum-likelihood phylogeny and the inclusion of recently characterized CDF transporters. The inference of CDF protein function predicted novel clades for Zn(2+), Fe(2+), Cd(2+) and Mn(2+). The Ni(2+)/Co(2+) and Co(2+) substrate specificities of two clades containing uncharacterized proteins were defined through the functional characterization of nepA and cepA metal inducible genes which independently conferred Ni(2+) and Co(2+) resistances to Rhizobium etli CFN42 and increased, respectively, Ni(2+)/Co(2+) and Co(2+) resistances to Escherichia coli. Neither NepA nor CepA confer Zn(2+), Fe(2+) and Mn(2+) resistances. The ability of NepA to confer Ni(2+)/Co(2+) resistance is dependent on clade-specific residues Asn(88) and Arg(197) whose mutations produce a non-functional protein.
Manganese (Mn(2+)) plays a key role in important cellular functions such as oxidative stress response and bacterial virulence. The mechanisms of Mn(2+) homeostasis are not fully understood, there are few data regarding the functional and taxonomic diversity of Mn(2+) exporters. Our recent phylogeny of the cation diffusion facilitator (CDF) family of transporters classified the bacterial Mn(2+)-CDF transporters characterized to date, Streptococcus pneumoniae MntE and Deinococcus radiodurans DR1236, into two monophyletic groups. DR1236 was shown to belong to the highly-diverse metal specificity clade VI, together with TtCzrB, a Zn(2+)/Cd(2+) transporter from Thermus thermophilus, the Fe(2+) transporter Sll1263 from Synechocystis sp and eight uncharacterized homologs whose potential Mn(2+)/Zn(2+)/Cd(2+)/Fe(2+) specificities could not be accurately inferred because only eleven proteins were grouped in this clade. A new phylogeny inferred from the alignment of 197 clade VI homologs revealed three novel subfamilies of uncharacterized proteins. Remarkably, one of them contained 91 uncharacterized α-proteobacteria transporters (46% of the protein data set) grouped into a single subfamily. The Mn(2+)/Fe(2+) specificity of this subfamily was proposed through the functional characterization of the Rhizobium etli RHE_CH03072 gene. This gene was upregulated by Mn(2+), Zn(2+), Cd(2+) and Fe(2+) but conferred only Mn(2+) resistance to R. etli. The expression of the RHE_CH03072 gene in an E. coli mntP/zitB/zntA mutant did not relieve either Zn(2+) or Mn(2+) stress but slightly increased its Fe(2+) resistance. These results indicate that the RHE_CH03072 gene, now designated as emfA, encodes for a bacterial Mn(2+)/Fe(2+) resistance CDF protein, having orthologs in more than 60 α-proteobacterial species.
Cadmium is an environmental pollutant and significant health hazard that is similar to the physiological metal zinc. In Caenorhabditis elegans, high zinc homeostasis is regulated by the high zinc activated nuclear receptor (HIZR-1) transcription factor. To define relationships between the responses to high zinc and cadmium, we analyzed transcription. Many genes were activated by both high zinc and cadmium, and hizr-1 was necessary for activation of a subset of these genes; in addition, many genes activated by cadmium did not require hizr-1, indicating there are at least two mechanisms of cadmium-regulated transcription. Cadmium directly bound HIZR-1, promoted nuclear accumulation of HIZR-1 in intestinal cells, and activated HIZR-1–mediated transcription via the high zinc activation (HZA) enhancer. Thus, cadmium binding promotes HIZR-1 activity, indicating that cadmium acts as a zinc mimetic to hijack the high zinc response. To elucidate the relationships between high zinc and cadmium detoxification, we analyzed genes that function in three pathways: the pcs-1/phytochelatin pathway strongly promoted cadmium resistance but not high zinc resistance, the hizr-1/HZA pathway strongly promoted high zinc resistance but not cadmium resistance, and the mek-1/sek-1/kinase signaling pathway promoted resistance to high zinc and cadmium. These studies identify resistance pathways that are specific for high zinc and cadmium, as well as a shared pathway.
Copper (Cu) is an essential micronutrient for all aerobic forms of life. Its oxidation states (Cu+/Cu2+) make this metal an important cofactor of enzymes catalyzing redox reactions in essential biological processes. In gram‐negative bacteria, Cu uptake is an unexplored component of a finely regulated trafficking network, mediated by protein–protein interactions that deliver Cu to target proteins and efflux surplus metal to avoid toxicity. Rhizobium etli CFN42 is a facultative symbiotic diazotroph that must ensure its appropriate Cu supply for living either free in the soil or as an intracellular symbiont of leguminous plants. In crop fields, rhizobia have to contend with copper‐based fungicides. A detailed deletion analysis of the pRet42e (505 kb) plasmid from an R. etli mutant with enhanced CuCl2 tolerance led us to the identification of the ropAe gene, predicted to encode an outer membrane protein (OMP) with a β–barrel channel structure that may be involved in Cu transport. In support of this hypothesis, the functional characterization of ropAe revealed that: (I) gene disruption increased copper tolerance of the mutant, and its complementation with the wild‐type gene restored its wild‐type copper sensitivity; (II) the ropAe gene maintains a low basal transcription level in copper overload, but is upregulated when copper is scarce; (III) disruption of ropAe in an actP (copA) mutant background, defective in copper efflux, partially reduced its copper sensitivity phenotype. Finally, BLASTP comparisons and a maximum likelihood phylogenetic analysis highlight the diversification of four RopA paralogs in members of the Rhizobiaceae family. Orthologs of RopAe are highly conserved in the Rhizobiales order, poorly conserved in other alpha proteobacteria and phylogenetically unrelated to characterized porins involved in Cu or Mn uptake.
The ubiquitous cytoplasmic membrane copper transporting P1B‐1 and P1B‐3‐type ATPases pump out Cu+ and Cu2+, respectively, to prevent cytoplasmic accumulation and avoid toxicity. The presence of five copies of Cu‐ATPases in the symbiotic nitrogen‐fixing bacteria Sinorhizobium meliloti is remarkable; it is the largest number of Cu+‐transporters in a bacterial genome reported to date. Since the prevalence of multiple Cu‐ATPases in members of the Rhizobiales order is unknown, we performed an in silico analysis to understand the occurrence, diversity and evolution of Cu+‐ATPases in members of the Rhizobiales order. Multiple copies of Cu‐ATPase coding genes (2–8) were detected in 45 of the 53 analyzed genomes. The diversity inferred from a maximum‐likelihood (ML) phylogenetic analysis classified Cu‐ATPases into four monophyletic groups. Each group contained additional subtypes, based on the presence of conserved motifs. This novel phylogeny redefines the current classification, where they are divided into two subtypes (P1B‐1 and P1B‐3). Horizontal gene transfer (HGT) as well as the evolutionary dynamic of plasmid‐borne genes may have played an important role in the functional diversification of Cu‐ATPases. Homologous cytoplasmic and periplasmic Cu+‐chaperones, CopZ, and CusF, that integrate a CopZ‐CopA‐CusF tripartite efflux system in gamma‐proteobacteria and archeae, were found in 19 of the 53 surveyed genomes of the Rhizobiales. This result strongly suggests a high divergence of CopZ and CusF homologs, or the existence of unexplored proteins involved in cellular copper transport.
Nitrogen-fixing bacteria collectively called rhizobia are adapted to live in polyphenol-rich environments. The mechanisms that allow these bacteria to overcome toxic concentrations of plant polyphenols have not been clearly elucidated. We used a crude extract of polyphenols released from the seed coat of the black bean to simulate a polyphenol-rich environment and analyze the response of the bean-nodulating strain Rhizobium etli CFN42. Our results showed that the viability of the wild type as well as that of derivative strains cured of plasmids p42a, p42b, p42c, and p42d or lacking 200 kb of plasmid p42e was not affected in this environment. In contrast, survival of the mutant lacking plasmid p42f was severely diminished. Complementation analysis revealed that the katG gene located on this plasmid, encoding the only catalase present in this bacterium, restored full resistance to testa polyphenols. Our results indicate that oxidation of polyphenols due to interaction with bacterial cells results in the production of a high quantity of H 2 O 2 , whose removal by the katG-encoded catalase plays a key role for cell survival in a polyphenol-rich environment.Flavonoids are a widespread group of polyphenolic compounds in the plant kingdom. Their basic chemical structure consists of two benzene (A and B) rings linked through a heterocyclic pyran or pyrone (C) ring. Substitutions in the C ring give rise to anthocyanidins, flavanols, flavonols, flavones, flavanones, chalcones, and isoflavonoids. Many are esterified at hydroxyl groups with different sugars, commonly glucose, galactose, or rhamnose, to produce glycosides. They are distributed throughout the plant, including in the fruit and seeds.Several groups of bacteria are adapted to live in environments rich in polyphenols, such as the gastrointestinal tracts of ruminants or the rhizosphere, the soil region surrounding the plant root (6, 45). Nitrogen-fixing bacteria belonging to the genera Rhizobium, Sinorhizobium, Mesorhizobium, Bradyrhizobium, and Azorhizobium (collectively called rhizobia) live surrounded by a wide variety of organic substances released by germinating seeds and plant roots, including polyphenolic compounds. Some of the flavonoids exuded by legume seeds and roots induce transcription of rhizobial nodulation (nod, noe, and nol) genes, which allow these bacteria to establish a symbiotic association with their host plant (9, 27). In addition, flavonoids enhance the growth rates of bacterial cells and promote bacterial movement toward the plant (12,22,42). Since root exudation is a highly dynamic process influenced by multiple biotic and abiotic factors, it is very likely that under field growth conditions, rhizobia are constantly exposed to large amounts and wide varieties of polyphenols in addition to the specific nod gene-inducing flavonoids (5). For instance, the presence of multiple microorganisms, including plant pathogens, may influence the quality and quantity of flavonoids produced by the roots (43, 47). It has also been shown that diverse envi...
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