Sage Journals: Discover world-class research

Abstract

Alkaliphilic organisms are among an industrially important class of extremophile microorganisms with the ability to thrive at pH 10–11.5. Microorganisms that exhibit alkaliphilic characteristics are sources of alkali-tolerant enzymes such as proteases, starch degrading enzymes, cellulases, and metabolites such as antibiotics, enzyme inhibitors, siderophores, organic acids, and cholic acid derivatives, which have found various applications in industry for human and environmental health. Yet, multi-omics mechanisms governing adaptation to high alkalinity have been poorly studied. We undertook the present work to understand, as a case study, the alkaliphilic adaptation strategy of the novel microorganism, Bacillus marmarensis DSM 21297, to alkaline conditions using a multi-omics approach that employed transcriptomics and proteomics. As alkalinity increased, bacteria remodeled the peptidoglycan layer by changing peptide moieties along with the peptidoglycan constituents and altered the cell membrane to reduce lipid motility and proton leakiness to adjust intracellular pH. Different transporters also contributed to the maintenance of this pH homeostasis. However, unlike in most well-known alkaliphiles, not only sodium ions but also potassium ions were involved in this process. Interestingly, increased pH has triggered the expression of neither general stress proteins nor gene encoding proteins associated with heat, salt, and nutrient stresses. Only an increase in the expression of oxidative stress related genes was evident. Endospore formation, also a phenomenon closely linked to stress, was unclear. This questioned if high pH was a real stress for B. marmarensis. These new findings, corroborated using the multi-omics approach of the present case study, broaden the knowledge on the mechanisms of alkaliphilic adaptation and might also potentially offer useful departure points for further industrial applications with other microorganisms.

Get full access to this article

View all access options for this article.

References

Adler

, and Templeton

. (1967). The effect of environmental conditions on the motility of Escherichia coli. J Gen Microbiol, 46, 175–184.

Alper

, and Stephanopoulos

. (2009). Engineering for biofuels: Exploiting innate microbial capacity or importing biosynthetic potential?. Nat Rev Microbiol, 7, 715–723.

Aono

, and Horikoshi

. (1991). Carotenes produced by alkaliphilic Yellow-pigmented strains of Bacillus carotenes produced by alkaliphilic. Agric Biol Chem, 55, 2643–2645.

Aono

, and Sanada

. (1994). Hyper-autolysis of the facultative alkaliphile Bacillus sp. c-125 cells grown at neutral ph: Culture-ph dependent cross-linking of the peptide moieties of the peptidoglycan. Biosci Biotechnol Biochem, 58, 2015–2019.

Avci

, Sayar

, and Sariyar Akbulut

. (2018). An OMIC approach to elaborate the antibacterial mechanisms of different alkaloids. Phytochemistry, 149, 123–131.

Bernhardt

, Völker

, et al. (1997). Specific and general stress proteins in Bacillus subtilis—A two-dimensional protein electrophoresis study. Microbiology, 143, 999–1017.

Bootha

, and Blount

. (2012). The MscS and MscL families of mechanosensitive channels act as microbial emergency release valves. J Bacteriol, 194, 4802–4809.

Clejan

, Krulwich

, Mondrus

, and Seto-Young

. (1986). Membrane lipid composition of obligately and facultatively alkalophilic strains of Bacillus spp. J Bacteriol, 168, 334–340.

Dayer

, Fischer

, Eggen

RIL

, and Lemaire

. (2008). The peroxiredoxin and glutathione peroxidase families in Chlamydomonas reinhardtii. Genetics, 179, 41–57.

10.

de Bruijn

. (2016). Stress and Environmental Regulation of Gene Expression and Adaptation in Bacteria 2 volume set, 1st ed. New Jersey, USA: John Wiley & Sons.

11.

Denizci

, Kazan

, and Erarslan

. (2010). Bacillus marmarensis sp. nov., an alkaliphilic, protease-producing bacterium isolated from mushroom compost. Int J Syst Evol Microbiol, 60, 1590–1594.

12.

Fujinami

, and Fujisawa

. (2010). Industrial applications of alkaliphiles and their enzymes—Past, present and future. Environ Technol, 31, 845–856.

13.

Haines

. (2001). Do sterols reduce proton and sodium leaks through lipid bilayers?. Prog Lipid Res, 40, 299–324.

14.

Hauß

, Dante

, Dencher

, and Haines

. (2002). Squalane is in the midplane of the lipid bilayer: Implications for its function as a proton permeability barrier. Biochim Biophys Acta, 1556, 149–154.

15.

Hirota

, Kitada

, and Imae

. (1981). Motors of alkalophilic electrochemical NaCl (mM). FEBS Lett, 132, 278–280.

16.

Horikoshi

. (1999). Alkaliphiles: Some applications of their products for biotechnology. Microbiol Mol Biol Rev, 63, 735–750.

17.

Ito

, Guffanti

, and Zemsky

. (1997). Role of the nhaC-encoded Na⁺/H⁺ antiporter of alkaliphilic Bacillus firmus OF4. J Bacteriol, 179, 3851–3857.

18.

Ito

, Hicks

, Henkin

, et al. (2004). MotPS is the stator-force generator for motility of alkaliphilic Bacillus, and its homologue is a second functional Mot in Bacillus subtilis. Mol Microbiol, 53, 1035–1049.

19.

Jacques

, Streamer

, Rowland

, et al. (2009). Structure of the sporulation histidine kinase inhibitor Sda from Bacillus subtilis and insights into its solution state. Acta Crystallogr Sect D Biol Crystallogr, 65, 574–581.

20.

Janto

, Ahmed

, Ito

, et al. (2012). The genome of alkaliphilic Bacillus pseudofirmus OF4 reveals adaptations that support the ability to grow in an external pH range from 7.5 to 11.4. Environ Microbiol, 13, 3289–3309.

21.

Keto-Timonen

, Hietala

, Palonen

, et al. (2016). Cold shock proteins: A minireview with special emphasis on Csp-family of Enteropathogenic Yersinia. Front Microbiol, 7, 1–7.

22.

Khelaifia

, Lagier

, Bibi

, et al. (2016). Microbial culturomics to map halophilic bacterium in human gut: Genome sequence and description of Oceanobacillus jeddahense sp. nov. Omi A J Integr Biol, 20, 248–258.

23.

Krulwich

. (2006). Alkaliphilic prokaryotes. Prokaryotes, 2, 283–308.

24.

Krulwich

, and Guffanti

. (1989). The Na+ cycle of extreme alkalophiles: A secondary Na+/H+ antiporter and Na+/solute symporters. J Bioenerg Biomembr, 21, 663–667.

25.

Krulwich

, and Ito

. (2013). Alkaliphilic prokaryotes. In: The Prokaryotes: Prokaryotic Communities and Ecophysiology. Berlin, Heidelberg, Germany: Springer.

26.

Krulwich

, Ito

, and Guffanti

. (2001). The Na+ dependence of alkaliphily in Bacillus. Biochim Biophys Acta, 1505, 158–168.

27.

Langmead

, Trapnell

, Pop

, and Salzberg

. (2009). Ultrafast and memory-efficient alignment of short DNA sequences to the human genome. Genome Biol, 10, R25.

28.

Levina

. (1999). Protection of Escherichia coli cells against extreme turgor by activation of MscS and MscL mechanosensitive channels: Identification of genes required for MscS activity. EMBO J, 18, 1730–1737.

29.

Lippert

, and Galinski

. (1992). Enzyme stabilization be ectoine-type compatible solutes: Protection against heating, freezing and drying. Appl Microbiol Biotechnol, 37, 61–65.

30.

Love

, Huber

, Anders

, et al. (2014). Moderated estimation of fold change and dispersion for RNA-seq data with DESeq2. Genome Biol, 15, 550.

31.

Mandel

, Guffanti

, and Krulwichs

. (1980). Monovalent cation/proton antiporters in membrane vesicles from Bacillus alcalophilus. J Biol Chem, 255, 7391–7396.

32.

Misra

, and Kishore

. (2012). Glycine betaine: A widely reported osmolyte induces differential and selective conformational stability and enhances aggregation in some proteins in the presence of surfactants. Biopolymers, 97, 933–949.

33.

Natalia

, Jumadila

, Anggraini

, et al. (2016). Alkyl hydroperoxide reductase from Bacillus aquimaris MKSC 6.2 protects Esherichia coli from oxidative stress. J Basic Microbiol, 56, 834–837.

34.

Noack

, Dzombak

, Nakles

, et al. (2014). Comparison of alkaline industrial wastes for aqueous mineral carbon sequestration through a parallel reactivity study. Waste Manag, 34, 1815–1822.

35.

Parveen

, and Reddy

. (2017). Identification of YfiH (PgeF) as a factor contributing to the maintenance of bacterial peptidoglycan composition. Mol Microbiol, 105, 705–720.

36.

Pirih

, and Kunej

. (2017). Toward a taxonomy for multi-omics science? Terminology development for whole genome study approaches by Omics Technology and Hierarchy. Omi A J Integr Biol, 21, 1–16.

37.

Preiss

, Hicks

, Suzuki

, et al. (2015) Alkaliphilic bacteria with impact on industrial applications, concepts of early life forms, and bioenergetics of ATP synthesis. Front Bioeng Biotechnol, 3, 75.

38.

Quistgaard

, Löw

, Guettou

, and Nordlund

. (2016). Understanding transport by the major facilitator superfamily (MFS): Structures pave the way. Nat Rev Mol Cell Biol, 17, 123–132.

39.

Salton

MRJ

, and Kim

. (1996) Structure. In: Medical Microbiology, 4th ed. Baron

, ed. Galveston, TX: The University of Texas Medical Branch.

40.

Seaver

, and Imlay

. (2001). Alkyl hydroperoxide reductase is the primary scavenger of endogenous hydrogen peroxide in Escherichia coli. J Bacteriol, 183, 7173–7181.

41.

Siliakus

, van der Oost

, and Kengen

SWM

. (2017). Adaptations of archaeal and bacterial membranes to variations in temperature, pH and pressure. Extremophiles, 21, 651–670.

42.

Somerville

, Youngs

, Taylor

, et al. (2010). Feedstocks for lignocellulosic biofuels. Science, 329, 790–792.

43.

van Meer

, Voelker

, and Feigenson

. (2008). Membrane lipids: Where they are and how they behave. Nat Mol Cell Biol, 9, 112–126.

44.

Vidali

. (2001). Bioremediation—An overview. J Ind Pollut Control, 27, 161–168.

45.

Vinod Kumar

, Lall

, Vimal Raj

, et al. (2017). Overexpression of heat shock GroEL stress protein in leptospiral biofilm. Microb Pathog, 102, 8–11.

46.

Weibel

, and Whitesides

. (2006). Applications of microfluidics in chemical biology. Curr Opin Chem Biol, 10, 584–591.

47.

Wernick

, Choi

, Tat

, et al. (2013). Genome sequence of the extreme obligate alkaliphile Bacillus marmarensis strain DSM 21297. Genome Announc, 1, 967.

48.

Wernick

, Pontrelli

, Pollock

, and Liao

. (2016). Sustainable biorefining in wastewater by engineered extreme alkaliphile Bacillus marmarensis. Sci Rep, 6, 1–10.

49.

Widderich

, Hop¨pner

, Pittelkow

, et al. (2014). Biochemical properties of ectoine hydroxylases from extremophiles and their wider taxonomic distribution among microorganisms. PLoS One, 9, e93809.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

1.34 MB

0.00 MB

What Are the Multi-Omics Mechanisms for Adaptation by Microorganisms to High Alkalinity? A Transcriptomic and Proteomic Study of a Bacillus Strain with Industrial Potential

Abstract

Abstract

Get full access to this article

References

Supplementary Material