References

1. T. Hülsen, E.M. Barry, Y. Lu, D. Puyol, D.J. Batstone, Low temperature treatment of domestic wastewater by purple phototrophic bacteria: performance, activity, and community, Water Res., 100 (2016) 537–545.
2. R.A. MacLeod, P.H. Calcott, Cold Shock and Freezing Damage to Microbes, In The Survival of Vegetative Microbes, The 26th Symposium of the Society for General Microbiology, Cambridge University Press, Cambridge, United Kingdom, 1976.
3. N. Beales, Adaptation of microorganisms to cold temperatures, weak acid preservatives, low pH, and osmotic stress: a review, Compr. Rev. Food Sci. Food Saf., 3 (2004) 1–20.
4. M. Henze, Wastewater Treatment: Biological and Chemical Processes, Springer Science & Business Media, 2002.
5. J.H. Hwang, J.A. Oleszkiewicz, Effect of cold-temperature shock on nitrification, Water Environ. Res., 79 (2007) 964–968.
6. W. Ahmed, X. Tian, R. Delatolla, Nitrifying moving bed biofilm reactor: performance at low temperatures and response to coldshock, Chemosphere, 229 (2019) 295–302.
7. B. Young, R. Delatolla, K. Kennedy, E. Laflamme, A. Stintzi, Low temperature MBBR nitrification: microbiome analysis, Water Res., 111 (2017) 224–233.
8. W. Ahmed, R. Delatolla, Microbial response of nitrifying biofilms to cold-shock, Environ. Sci. Water Res., 6 (2020) 3428–3439.
9. C. Wu, Z. Chen, X. Liu, Y. Peng, Nitrification–denitrification via nitrite in SBR using real-time control strategy when treating domestic wastewater, Biochem. Eng. J., 36 (2007) 87–92.
10. W.E. Federation, APH Association, Standard Methods for the Examination of Water and Wastewater, 21st ed., American Public Health Association (APHA), Washington, D.C., USA, 2005.
11. A. Klindworth, E. Pruesse, T. Schweer, J. Peplies, C. Quast, M. Horn, F.O. Glöckner, Evaluation of general 16S ribosomal RNA gene PCR primers for classical and next-generation sequencing-based diversity studies, Nucleic Acids Res., 41 (2013) e1, doi: 10.1093/nar/gks808.
12. E. Bolyen, J.R. Rideout, M.R. Dillon, N.A. Bokulich, C.C. Abnet, G.A. Al-Ghalith, H. Alexander, E.J. Alm, M. Arumugam, F. Asnicar, Y. Bai, J.E. Bisanz, K. Bittinger, A. Brejnrod, C.J. Brislawn, C. Titus Brown, B.J. Callahan, A.M. Caraballo- Rodríguez, J. Chase, E.K. Cope, R. Da Silva, C. Diener, P.C. Dorrestein, G.M. Douglas, D.M. Durall, C. Duvallet, C.F. Edwardson, M. Ernst, M. Estaki, J. Fouquier, J.M. Gauglitz, S.M. Gibbons, D.L. Gibson, A. Gonzalez, K. Gorlick, J. Guo, B. Hillmann, S. Holmes, H. Holste, C. Huttenhower, G.A. Huttley, S. Janssen, A.K. Jarmusch, L. Jiang, B.D. Kaehler, K.B. Kang, C.R. Keefe, P. Keim, S.T. Kelley, D. Knights, I. Koester, T. Kosciolek, J. Kreps, M.G.I. Langille, J. Lee, R. Ley, Y.-X. Liu, E. Loftfield, C. Lozupone, M. Maher, C. Marotz, B.D. Martin, D. McDonald, L.J. McIver, A.V. Melnik, J.L. Metcalf, S.C. Morgan, J.T. Morton, A.T. Naimey,
    J.A. Navas-Molina, L.F. Nothias, S.B. Orchanian, T. Pearson, S.L. Peoples, D. Petras, M.L. Preuss, E. Pruesse, L.B. Rasmussen, A. Rivers, M.S. Robeson II, P. Rosenthal, N. Segata, M. Shaffer, A. Shiffer, R. Sinha, S.J. Song, J.R. Spear, A.D. Swafford, L.R. Thompson, P.J. Torres, P. Trinh, A. Tripathi, P.J. Turnbaugh, S. Ul-Hasan,
    J.J.J. van der Hooft, F. Vargas, Y. Vázquez-Baeza, E. Vogtmann, M. von Hippel, W. Walters, Y. Wan, M. Wang, J. Warren, K.C. Weber, C.H.D. Williamson, A.D. Willis, Z.Z. Xu, J.R. Zaneveld, Y. Zhang, Q. Zhu, R. Knight, J. Gregory Caporaso, Reproducible, interactive, scalable and extensible microbiome data science using QIIME 2, Nat. Biotechnol., 37 (2019) 852–857.
13. M. Martin, Cutadapt removes adapter sequences from highthroughput sequencing reads, EMBnet. J., 17 (2011) 10–12.
14. R.C. Edgar, Search and clustering orders of magnitude faster than BLAST, Bioinformatics (Oxford, England), 26 (2010) 2460–2461.
15. C. Quast, E. Pruesse, P. Yilmaz, J. Gerken, T. Schweer, P. Yarza, J. Peplies, F.O. Glöckner, The SILVA ribosomal RNA gene database project: improved data processing and web-based tools, Nucl. Acids Res., 41 (2013) D590–D596.
16. M.K.H. Winkler, J.P. Bassin, R. Kleerebezem, D.Y. Sorokin, M. van Loosdrecht, Unravelling the reasons for disproportion in the ratio of AOB and NOB in aerobic granular sludge, Appl. Microbiol. Biotechnol., 94 (2012) 1657–1666.
17. A. Gnida, J. Wiszniowski, E. Felis, J. Sikora, J. Surmacz-Górska, J.K. Miksch, The effect of temperature on the efficiency of industrial wastewater nitrification and its (geno)toxicity, Arch. Environ. Prot., 42 (2016) 27–34.
18. C. Barria, M. Malecki, C.M. Arraiano, Bacterial adaptation to cold, Microbiology, 159 (2013) 2437–2443.
19. S. Phadtare, K. Severinov, RNA remodeling and gene regulation by cold shock proteins, RNA Biol., 7 (2010) 788–795.
20. M. Chen, Y. Chen, Sh. Dong, S. Lan, H. Zhou, Z. Tan, X. Li, Mixed nitrifying bacteria culture under different temperature dropping strategies: nitrification performance, activity, and community, Chemosphere, 195 (2018) 800–809.
21. S. Zhu, S. Chen, The impact of temperature on nitrification rate in fixed film biofilters, Aquacult. Eng., 26 (2002) 221–237.
22. R. Salvetti, A. Azzellino, R. Canziani, L. Bonomo, Effects of temperature on tertiary nitrification in moving-bed biofilm reactors, Water Res., 40 (2006) 2981–2993.
23. M. Żubrowska-Sudoł, Moving bed technology as an alternative solution for reducing bioreactor volume, Environ. Prot. Eng., 38 (2012) 5–22.
24. Y. Shao, Y. Shi, A. Mohammed, Y. Liu, Wastewater ammonia removal using an integrated fixed-film activated sludgesequencing batch biofilm reactor (IFAS-SBR): comparison of suspended flocs and attached biofilm, Int. Biodeterior. Biodegrad., 116 (2017) 38–47.