LuxR-type DNA-binding HTH domain

In molecular biology, the LuxR-type DNA-binding HTH domain is a DNA-binding, helix-turn-helix (HTH) domain of about 65 amino acids. It is present in transcription regulators of the LuxR/FixJ family of response regulators. The domain is named after Vibrio fischeri luxR, a transcriptional activator for quorum-sensing control of luminescence. LuxR-type HTH domain proteins occur in a variety of organisms. The DNA-binding HTH domain is usually located in the C-terminal region of the protein; the N-terminal region often containing an autoinducer-binding domain or a response regulatory domain. Most luxR-type regulators act as transcription activators, but some can be repressors or have a dual role for different sites. LuxR-type HTH regulators control a wide variety of activities in various biological processes.

Bacterial regulatory proteins, luxR family
solution structure of the dna-binding domain of the erwinia amylovora rcsb protein
Identifiers
Symbol	GerE
Pfam	PF00196
Pfam clan	CL0123
InterPro	IPR000792
PROSITE	PDOC00542
SCOP2	1rnl / SCOPe / SUPFAM
Available protein structures: Pfam   structures / ECOD   PDB RCSB PDB; PDBe; PDBj PDBsum structure summary

The luxR-type, DNA-binding HTH domain forms a four-helical bundle structure. The HTH motif comprises the second and third helices, known as the scaffold and recognition helix, respectively. The HTH binds DNA in the major groove, where the N-terminal part of the recognition helix makes most of the DNA contacts. The fourth helix is involved in dimerisation of gerE and traR. Signalling events by one of the four activation mechanisms described below lead to multimerisation of the regulator. The regulators bind DNA as multimers.^[1][2][3]

LuxR-type HTH proteins can be activated by one of four different mechanisms:

1. Regulators which belong to a two-component sensory transduction system where the protein is activated by its phosphorylation, generally on an aspartate residue, by a transmembrane kinase.^[4][5] Some proteins that belong to this category are:

• Rhizobiaceae fixJ (global regulator inducing expression of nitrogen-fixation genes in microaerobiosis)
• Escherichia coli and Salmonella typhimurium uhpA (activates hexose phosphate transport gene uhpT)
• E. coli narL and narP (activate nitrate reductase operon)
• Enterobacteria rcsB (regulation of exopolysaccharide biosynthesis in enteric and plant pathogenesis)
• Bordetella pertussis bvgA (virulence factor)
• Bacillus subtilis comA (involved in expression of late-expressing competence genes)

2. Regulators which are activated, or in very rare cases repressed, when bound to N-acyl homoserine lactones, which are used as quorum sensing molecules in a variety of Gram-negative bacteria:^[6]

• Vibrio fischeri luxR (activates bioluminescence operon)
• Agrobacterium tumefaciens traR (regulation of Ti plasmid transfer)
• Erwinia carotovora carR (control of carbapenem antibiotics biosynthesis)
• E. carotovora expR (virulence factor for soft rot disease; activates plant tissue macerating enzyme genes)
• Pseudomonas aeruginosa lasR (activates elastase gene lasB)
• Erwinia chrysanthemi echR and Erwinia stewartii esaR
• Pseudomonas chlororaphis phzR (positive regulator of phenazine antibiotic production)
• Pseudomonas aeruginosa rhlR (activates rhlAB operon and lasB gene)
• Acinetobacter baumannii abaR (activates operon for production of surfactant-like lipopeptide acinetin-505)^[7][8]

3. Autonomous effector domain regulators, without a regulatory domain, represented by gerE.^[1]

• B. subtilis gerE (transcription activator and repressor for the regulation of spore formation)

4. Multiple ligand-binding regulators, exemplified by malT.^[9]

• E. coli malT (activates maltose operon; MalT binds ATP and maltotriose)

References

1. Ducros VM, Lewis RJ, Verma CS, Dodson EJ, Leonard G, Turkenburg JP, Murshudov GN, Wilkinson AJ, Brannigan JA (March 2001). "Crystal structure of GerE, the ultimate transcriptional regulator of spore formation in Bacillus subtilis". J. Mol. Biol. 306 (4): 759–71. doi:10.1006/jmbi.2001.4443. PMID 11243786.
2. Pristovsek P, Sengupta K, Lohr F, Schafer B, von Trebra MW, Ruterjans H, Bernhard F (May 2003). "Structural analysis of the DNA-binding domain of the Erwinia amylovora RcsB protein and its interaction with the RcsAB box". J. Biol. Chem. 278 (20): 17752–9. doi:10.1074/jbc.M301328200. PMID 12740396.
3. Zhang RG, Pappas T, Brace JL, Miller PC, Oulmassov T, Molyneaux JM, Anderson JC, Bashkin JK, Winans SC, Joachimiak A (June 2002). "Structure of a bacterial quorum-sensing transcription factor complexed with pheromone and DNA". Nature. 417 (6892): 971–4. doi:10.1038/nature00833. PMID 12087407. S2CID 4420408.
4. Maris AE, Sawaya MR, Kaczor-Grzeskowiak M, Jarvis MR, Bearson SM, Kopka ML, Schroder I, Gunsalus RP, Dickerson RE (October 2002). "Dimerization allows DNA target site recognition by the NarL response regulator". Nat. Struct. Biol. 9 (10): 771–8. doi:10.1038/nsb845. PMID 12352954. S2CID 20574350.
5. Birck C, Malfois M, Svergun D, Samama J (August 2002). "Insights into signal transduction revealed by the low resolution structure of the FixJ response regulator". J. Mol. Biol. 321 (3): 447–57. doi:10.1016/S0022-2836(02)00651-4. PMID 12162958.
6. Pappas KM, Weingart CL, Winans SC (August 2004). "Chemical communication in proteobacteria: biochemical and structural studies of signal synthases and receptors required for intercellular signalling". Mol. Microbiol. 53 (3): 755–69. doi:10.1111/j.1365-2958.2004.04212.x. PMID 15255890.
7. Niu C, Clemmer KM, Bonomo RA, Rather PN. Isolation and characterization of an autoinducer synthase from Acinetobacter baumannii. J Bacteriol. 2008;190(9):3386–3392. doi:10.1128/JB.01929-07
8. Pérez-Varela M, Tierney ARP, Kim JS, Vazquez-Torres A, Rather P. Characterization of RelA in Acinetobacter baumannii [published online ahead of print, 2020 Mar 30]. J Bacteriol. 2020;JB.00045-20. doi:10.1128/JB.00045-20
9. Schlegel A, Bohm A, Lee SJ, Peist R, Decker K, Boos W (May 2002). "Network regulation of the Escherichia coli maltose system". J. Mol. Microbiol. Biotechnol. 4 (3): 301–7. PMID 11931562.

This article incorporates text from the public domain Pfam and InterPro: IPR000792