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Staphylococcus aureus pigmentation is not controlled by Hfq
BMC Research Notes volume 13, Article number: 63 (2020)
The golden color of Staphylococcus aureus is due to the synthesis of carotenoid pigments. In Gram-negative bacteria, Hfq is a global posttranscriptional regulator, but its function in S. aureus remains obscure. The absence of Hfq in S. aureus was reported to correlate with production of carotenoid pigment leading to the conclusion that Hfq was a negative regulator of the yellow color. However, we reported the construction of hfq mutants in several S. aureus strains and never noticed any color change; we therefore revisited the question of Hfq implication in S. aureus pigmentation.
The absence or accumulation of Hfq does not affect S. aureus pigmentation.
Staphylococcus aureus is a major pathogen responsible for numerous diseases from minor skin infection to septicemia, affecting humans and other animals. Its name “aureus” comes from the golden color of strains that express carotenoid pigments . These pigments contribute to oxidative stress and neutrophil resistance, and virulence . The carotenoid biosynthetic operon (crtMNOPQ) leading to the synthesis of staphyloxanthin is regulated by σB [3, 4], an alternative σ factor that also controls a large number of general stress genes. σB activity depends on RsbU, its positive regulator [5, 6]. Numerous strains, including the S. aureus model NCTC8325, have rsbU mutations that prevent σB activity and crt operon expression, such that colonies are white. In addition, mutations in 37 genes were shown to result in the loss of a yellow pigmentation [5, 7].
Hfq is an RNA chaperone needed for activity of numerous regulatory RNAs in Gram-negative bacteria . However, its role in Gram-positive bacteria, with the exception of Clostridium difficile , remains enigmatic . Hfq functionality from different species is often tested by interspecies complementation tests. However, expression of hfq genes from Gram-positive bacteria S. aureus and Bacillus subtilis in Salmonella could not compensate the absence of endogenous hfq, indicating a functional difference between Gram positive and negative Hfq [11, 12].
We previously compared phenotypes of S. aureus hfq mutants with their isogenic parental strains and observed no detectable difference associated with the absence of Hfq in the tested conditions . However, our results were partly challenged by a publication reporting that carotenoid pigment production was increased in hfq-negative strains . Here we use nine different S. aureus strains to show that Hfq absence or overexpression has no effect on pigment expression.
Bacterial strains, plasmids and growth conditions
Bacterial strains, plasmids and primers used in this study are listed in Table 1. Allelic replacements of hfq+ by Δhfq::cat were either performed by ϕ11-phage mediated transduction using RN4220 hfq::cat as a donor strain or by homologous recombination using pMADΔhfq::cat [13, 15]. The Δhfq::cat deletion in SAPHB5 was verified by Southern blot and subsequent Δhfq::cat transductants were verified by PCR as described .
Engineered plasmids were constructed as described . Conditional hfq expression was obtained by cloning hfq under the xyl/tetO promoter in pRMC2  and pRMC2FLAG (Table 1). pRMC2Hfq allowing hfq conditional expression was obtained as follows: pRMC2 and PCR-amplified hfq (using primers 39/49 on HG003 DNA) were KpnI-EcoRI digested and ligated together. pRMC2FLAG was engineered for conditional expression of 3xFLAG-tagged proteins as followed: pRMC2 and pSUB11  were PCR-amplified using primers 856/918 and 858/919, respectively. The two resulting products, i.e. pRMC2 and 3xflag coding sequence, were assembled using the Gibson method . pRMC2HfqFLAG, allowing conditional expression of Hfq::3xFLAG, was obtained as follows: pRMC2FLAG and hfq HG003 were PCR-amplified using primers 918/865 and 939/940, respectively. The two resulting products were assembled using the Gibson method.
Bacteria were grown in BHI medium (BD Difco, ref: 237500) at 37 °C under vigorous agitation. BHI solid media were obtained by the addition of Bacto Agar 15 g l−1 (BD Difco, ref: 214010). For strains containing pRMC2 and derivatives, chloramphenicol (Sigma-Aldrich, ref: C0378) 5 µg ml−1 was added to media. Expression from pRMC2 and derivatives was achieved by anhydrotetracycline (aTc, Chemodex, ref: CDX-A0197-M500) 250 ng ml−1 addition to growth media.
Protein extraction, Western blotting and staphyloxanthin spectral measurement
Overnight cultures were diluted 1000 times in fresh medium. After 3 h, aTc was added. 10 min and 30 min later, cells were harvested by centrifugation (16,000g for 2 min), resuspended in 400 µl Tris HCl buffer (50 mM, pH 6.8) and lysed using a FastPrep (3 cycles of 45 s at 6.5 m s−1). Cell debris was removed by centrifugation (16,000g for 10 min). Protein concentration was determined by Bradford assays . For each sample, 3 μg of protein extract was separated on a polyacrylamide gel (Blot™ 4–12% Bis–Tris Plus, Invitrogen, ref: NW04122BOX). After electrophoresis, proteins were transferred to a polyvinylidene fluoride membrane (iBlot 2 PVDF Mini Stacks, Invitrogen ref: IB24002). For blotting and washing, an iBind™ Flex Western System (ref: SLF2000S) was used according to supplier’s instructions. Membranes were probed with the primary polyclonal ANTI-FLAG antibody produced in rabbit (Sigma, ref: F-7425) at a 1/15,000 dilution. A rabbit secondary antibody conjugated to horseradish peroxidase (Advansta, ref: R-05072-500) was used at a 1/25,000 dilution. Bioluminescent signal was detected with the WesternBright™ ECL-spray (Advansta, ref: K-12040-D50) using a digital camera (ImageQuant™ 350, GE Healthcare).
The S. aureus pigments were extracted as described . In brief, strains were grown in BHI under vigorous agitation for 24 h. Cells were harvested by centrifugation, the pellet was rinsed twice with sterile water and pigments were extracted by methanol. Absorbance between 330 and 550 nm was measured on a microplate reader (CLARIOstar BMG LABTECH).
The absence of Hfq does not alter S. aureus pigmentation
In 2010, Liu et al. reported that “deletion of hfq gene in S. aureus 8325-4 can increase the surface carotenoid pigments” . Their work was performed using an allele called Δhfq-8325 in which the hfq coding sequence was replaced by a kanamycin cassette. The hfq chromosomal deletion was constructed in strain RN4220 and then transduced into NCTC8325-4, RN6390, COL and ATCC25923 by phage ϕ11. We constructed a similar hfq deletion in RN4220, except that the hfq coding sequence was replaced by a chloramphenicol resistant gene (Δhfq::cat); this allele was transduced into RN6390, COL and Newman by ϕ11-phage mediated transduction . Note that RN4220, RN6390 and COL strains were used for both studies. As we did not notice a change of color when the Δhfq::cat allele was introduced into these strains, this information was not reported . In view of the previous report, we focused this work on the possibility that Hfq could affect S. aureus pigment expression.
NCTC8325 isolated in 1960 from a sepsis patient is the progenitor of numerous strains including NCTC8325-4 (cured of three prophages) which itself gave RN6390 and RN4220 . As these descendants were mutagenized, they carry several mutations that may affect their phenotypes. NCTC8325 has a deletion of 11 bp in rsbU and a point mutation in tcaR. The derivatives HG001 (rsbU restored), HG002 (tcaR restored), HG003 (rsbU and tcaR restored) were constructed to perform physiological studies in a non-mutagenized background . All these NCTC8325 derived strains, except HG001 and HG003 (which have a functional σB factor), give rise to white colonies (Fig. 1). In addition to those reported , we constructed Δhfq::cat derivatives in NCTC8325, NCTC8325-4, HG001, HG002 and HG003 (Table 1). In contrast to results reported in Liu et al., deletion of the hfq gene in all tested strain backgrounds had no effect on pigmentation (Fig. 1a). Note that COL, Newman are not NCTC8325 derivatives.
Spectral profiles highlighting S. aureus carotenoid production were determined as described  for three strains and their hfq derivatives after growth for 24 h in BHI. HG003 and HG003 Δhfq::cat gave equivalent profiles with three pics characteristic of carotenoid production. In contrast, NCTC8325-4 and RN1 had spectra characteristic of no or very little carotenoid production. As expected from our visual observation (Fig. 1a), the spectra of Δhfq derivatives did not differ from those of their respective parental strains (Fig. 1b).
Hfq overexpression does not alter S. aureus pigmentation
In the above-described strains, hfq is possibly poorly expressed, in which case hfq deletions would not lead to detectable phenotypes. We therefore tested the effects of an inducible Hfq expression system on pigment production. If the absence of Hfq leads to yellow colonies as proposed , the presence of Hfq could lower pigment production and lead to white colonies. To address this point, hfq was cloned under the control of the Pxyl/tetO promoter in multi-copy plasmid pRMC2  leading to pRMC2Hfq. hfq expression in strains harboring pRMC2Hfq was induced upon aTc addition to media. To confirm that Pxyl/tetO was effectively driving hfq expression, a pRMC2Hfq derivative was engineered harboring a 3xflag sequence inserted in frame at the end of the hfq open reading frame. The resulting plasmid, pRMC2HfqFLAG is a proxy for expression from pRMC2Hfq. HG003 was transformed with pRMC2, pRMC2Hfq and pRMC2HfqFLAG. The protein Hfq::3xFLAG was detected upon aTc induction by western blotting using FLAG antibodies (Fig. 2a). We inferred from this result that addition of aTc to strains harboring pRMC2Hfq lead to Hfq synthesis. The RN4220 white and HG003 yellow colors were not affected by the presence of either pRMC2, pRMC2Hfq or pRMC2HfqFLAG and remained identical upon aTc addition to growth medium (Fig. 2b).
Our results show that neither the absence, nor the accumulation of Hfq affects pigmentation of S. aureus: Hfq does not appear to regulate staphyloxanthin synthesis. Our conclusions are supported by Tarrant PhD dissertation showing an NCTC8325 hfq mutant that remained unpigmented . Of note, Pseudomonas aeruginosa reportedly induces pigment production of a non-pigmented phenotypic variant of S. aureus, however, this effect was independent of hfq transcription . In addition, color variation in USA300 strain was screened in a genome-wide transposon mutant library, and the hfq inactivation was not reported to affect S. aureus pigmentation .
While the hfq gene is absent in some Firmicutes (e.g. Lactobacillales), it is conserved in all S. aureus, suggesting that it plays a crucial function, however not related to pigment expression. The quest to find the Staphylococcal Hfq function remains open.
Our conclusion is in contradiction with Liu et al. results concerning the effect of Hfq on S. aureus pigmentation . We cannot rule out that our observation is limited to specific S. aureus strains. However, we used an NCTC8325-4 hfq derivative similar the one used in the previous study. Furthermore, the present results are strengthened by the construction of hfq mutants in numerous S. aureus backgrounds. The discrepancy between our and Liu et al. 2010  results, is a possible inadvertent selection of mutants with altered color patterns (as shown in ) in the former study.
Availability of data and materials
All data generated or analyzed during this study are included in this published article. Strains and plasmids are available from the corresponding author on reasonable request.
Polymerase chain reaction
Brain heart infusion
Marshall JH, Wilmoth GJ. Pigments of Staphylococcus aureus, a series of triterpenoid carotenoids. J Bacteriol. 1981;147(3):900–13.
Liu GY, Essex A, Buchanan JT, Datta V, Hoffman HM, Bastian JF, Fierer J, Nizet V. Staphylococcus aureus golden pigment impairs neutrophil killing and promotes virulence through its antioxidant activity. J Exp Med. 2005;202(2):209–15.
Bischoff M, Dunman P, Kormanec J, Macapagal D, Murphy E, Mounts W, Berger-Bachi B, Projan S. Microarray-based analysis of the Staphylococcus aureus sigmaB regulon. J Bacteriol. 2004;186(13):4085–99.
Pelz A, Wieland KP, Putzbach K, Hentschel P, Albert K, Gotz F. Structure and biosynthesis of staphyloxanthin from Staphylococcus aureus. J Biol Chem. 2005;280(37):32493–8.
Palma M, Cheung AL. sigma(Beta) activity in Staphylococcus aureus is controlled by RsbU and an additional factor(s) during bacterial growth. Infect Immun. 2001;69(12):7858–65.
Giachino P, Engelmann S, Bischoff M. Sigma(B) activity depends on RsbU in Staphylococcus aureus. J Bacteriol. 2001;183(6):1843–52.
Fey PD, Endres JL, Yajjala VK, Widhelm TJ, Boissy RJ, Bose JL, Bayles KW. A genetic resource for rapid and comprehensive phenotype screening of nonessential Staphylococcus aureus genes. MBio. 2013;4(1):e00537-12.
Vogel J, Luisi BF. Hfq and its constellation of RNA. Nat Rev Microbiol. 2011;9(8):578–89.
Boudry P, Gracia C, Monot M, Caillet J, Saujet L, Hajnsdorf E, Dupuy B, Martin-Verstraete I, Soutourina O. Pleiotropic role of the RNA chaperone protein Hfq in the human pathogen Clostridium difficile. J Bacteriol. 2014;196(18):3234–48.
Bouloc P, Repoila F. Fresh layers of RNA-mediated regulation in Gram-positive bacteria. Curr Opin Microbiol. 2016;30:30–5.
Rochat T, Bouloc P, Yang Q, Bossi L, Figueroa-Bossi N. Lack of interchangeability of Hfq-like proteins. Biochimie. 2012;94(7):1554–9.
Rochat T, Delumeau O, Figueroa-Bossi N, Noirot P, Bossi L, Dervyn E, Bouloc P. Tracking the elusive function of Bacillus subtilis Hfq. PLoS ONE. 2015;10(4):e0124977.
Bohn C, Rigoulay C, Bouloc P. No detectable effect of RNA-binding protein Hfq absence in Staphylococcus aureus. BMC Microbiol. 2007;7:10.
Liu Y, Wu N, Dong J, Gao Y, Zhang X, Mu C, Shao N, Yang G. Hfq is a global regulator that controls the pathogenicity of Staphylococcus aureus. PLoS ONE. 2010;5(9):e13069.
Le Lam TN, Morvan C, Liu W, Bohn C, Jaszczyszyn Y, Bouloc P. Finding sRNA-associated phenotypes by competition assays: an example with Staphylococcus aureus. Methods. 2017;117:21–7.
Rochat T, Bohn C, Morvan C, Le Lam TN, Razvi F, Pain A, Toffano-Nioche C, Ponien P, Jacq A, Jacquet E, et al. The conserved regulatory RNA RsaE down-regulates the arginine degradation pathway in Staphylococcus aureus. Nucleic Acids Res. 2018;46(17):8803–16.
Corrigan RM, Foster TJ. An improved tetracycline-inducible expression vector for Staphylococcus aureus. Plasmid. 2009;61(2):126–9.
Uzzau S, Figueroa-Bossi N, Rubino S, Bossi L. Epitope tagging of chromosomal genes in Salmonella. Proc Natl Acad Sci USA. 2001;98(26):15264–9.
Gibson DG, Young L, Chuang RY, Venter JC, Hutchison CA 3rd, Smith HO. Enzymatic assembly of DNA molecules up to several hundred kilobases. Nat Methods. 2009;6(5):343–5.
Bradford MM. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal Biochem. 1976;72:248–54.
Morikawa K, Maruyama A, Inose Y, Higashide M, Hayashi H, Ohta T. Overexpression of sigma factor, sigma(B), urges Staphylococcus aureus to thicken the cell wall and to resist beta-lactams. Biochem Biophys Res Commun. 2001;288(2):385–9.
Herbert S, Ziebandt AK, Ohlsen K, Schafer T, Hecker M, Albrecht D, Novick R, Gotz F. Repair of global regulators in Staphylococcus aureus 8325 and comparative analysis with other clinical isolates. Infect Immun. 2010;78(6):2877–89.
Tarrant EJ. The role of Hfq in S. aureus gene regulation. PhD. University of Leicester; 2013.
Antonic V, Stojadinovic A, Zhang B, Izadjoo MJ, Alavi M. Pseudomonas aeruginosa induces pigment production and enhances virulence in a white phenotypic variant of Staphylococcus aureus. Infect Drug Resist. 2013;6:175–86.
Nair D, Memmi G, Hernandez D, Bard J, Beaume M, Gill S, Francois P, Cheung AL. Whole-genome sequencing of Staphylococcus aureus strain RN4220, a key laboratory strain used in virulence research, identifies mutations that affect not only virulence factors but also the fitness of the strain. J Bacteriol. 2011;193(9):2332–5.
Novick RP, Richmond MH. Nature and interactions of the genetic elements governing penicillinase synthesis in Staphylococcus aureus. J Bacteriol. 1965;90:467–80.
Novick R. Properties of a cryptic high-frequency transducing phage in Staphylococcus aureus. Virology. 1967;33(1):155–66.
Novick RP. Molecular biology of the staphylococci. New York: VCH Publishers; 1990.
Gill SR, Fouts DE, Archer GL, Mongodin EF, Deboy RT, Ravel J, Paulsen IT, Kolonay JF, Brinkac L, Beanan M, et al. Insights on evolution of virulence and resistance from the complete genome analysis of an early methicillin-resistant Staphylococcus aureus strain and a biofilm-producing methicillin-resistant Staphylococcus epidermidis strain. J Bacteriol. 2005;187(7):2426–38.
Baba T, Bae T, Schneewind O, Takeuchi F, Hiramatsu K. Genome sequence of Staphylococcus aureus strain Newman and comparative analysis of staphylococcal genomes: polymorphism and evolution of two major pathogenicity islands. J Bacteriol. 2008;190(1):300–10.
We thank Sandy Gruss, Annick Jacq and Yan Jing for critical reading of the manuscript, helpful discussions and warm support.
This work was funded by the Agence Nationale pour la Recherche (ANR) (Grant # ANR-15-CE12-0003-01 “sRNA-Fit”) and by the Fondation pour la Recherche Médicale (FRM) (Grant # DBF20160635724 “Bactéries et champignons face aux antibiotiques et antifongiques”). WL was the recipient of fellowships from the Chinese scholarship council. PiB was the recipient of fellowships from the FRM.
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Liu, W., Boudry, P., Bohn, C. et al. Staphylococcus aureus pigmentation is not controlled by Hfq. BMC Res Notes 13, 63 (2020). https://0-doi-org.brum.beds.ac.uk/10.1186/s13104-020-4934-4
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