UV tolerance of Lactococcus lactis 936-type phages - Staff of the Department of Food Science

UV tolerance of Lactococcus lactis 936-type phages: Impact of wavelength, matrix, and pH

Research output: Contribution to journal › Journal article › Research › peer-review

Standard

UV tolerance of Lactococcus lactis 936-type phages : Impact of wavelength, matrix, and pH. / Vitzilaiou, Eirini; Liang, Yuxin; Castro-Mejía, Josué L.; Franz, Charles M.A.P.; Neve, Horst; Vogensen, Finn Kvist; Knøchel, Susanne.

In: International Journal of Food Microbiology, Vol. 378, 109824, 2022.

Research output: Contribution to journal › Journal article › Research › peer-review

Harvard

Vitzilaiou, E, Liang, Y, Castro-Mejía, JL, Franz, CMAP, Neve, H, Vogensen, FK & Knøchel, S 2022, 'UV tolerance of Lactococcus lactis 936-type phages: Impact of wavelength, matrix, and pH', International Journal of Food Microbiology, vol. 378, 109824. https://doi.org/10.1016/j.ijfoodmicro.2022.109824

APA

Vitzilaiou, E., Liang, Y., Castro-Mejía, J. L., Franz, C. M. A. P., Neve, H., Vogensen, F. K., & Knøchel, S. (2022). UV tolerance of Lactococcus lactis 936-type phages: Impact of wavelength, matrix, and pH. International Journal of Food Microbiology, 378, [109824]. https://doi.org/10.1016/j.ijfoodmicro.2022.109824

Vancouver

Vitzilaiou E, Liang Y, Castro-Mejía JL, Franz CMAP, Neve H, Vogensen FK et al. UV tolerance of Lactococcus lactis 936-type phages: Impact of wavelength, matrix, and pH. International Journal of Food Microbiology. 2022;378. 109824. https://doi.org/10.1016/j.ijfoodmicro.2022.109824

Author

Vitzilaiou, Eirini ; Liang, Yuxin ; Castro-Mejía, Josué L. ; Franz, Charles M.A.P. ; Neve, Horst ; Vogensen, Finn Kvist ; Knøchel, Susanne. / UV tolerance of Lactococcus lactis 936-type phages : Impact of wavelength, matrix, and pH. In: International Journal of Food Microbiology. 2022 ; Vol. 378.

Bibtex

@article{8b0bbe60ecb24a00aa2c46179c76a475,

title = "UV tolerance of Lactococcus lactis 936-type phages: Impact of wavelength, matrix, and pH",

abstract = "Ultraviolet C (UVC) radiation is a widely used technology for the disinfection of surfaces, air flows, water and other liquids. Although extensive research has been conducted on the UV tolerance of bacteriophages used as surrogates for waterborne viruses, limited information is available on phages relevant to food processing. Phages of dairy starters may reach high numbers in dairy facilities and cause fermentation failure with great economic losses for the dairy industry. Here, the UV tolerance of virulent phages, belonging to the 936-group (Skunavirus) of Lactococcus lactis subsp. diacetylactis F7/2, was assessed, employing both host infectivity loss and qPCR assays. A highly heat-tolerant phage (P680) and a less heat-tolerant phage (P008) were exposed to UV radiation at 265 nm (UVC), 285 nm (UVB) and 365 nm (UVA), respectively, in an aqueous suspension, using UV Light-Emitting-Diodes (LEDs) in a static set-up. UVC at 265 nm achieved the highest total inactivation, leading to a 4 log10 reduction of the phage titer at a UV dose of 327 and 164 mJ/cm2 for P680 and P008, respectively. UVB at 285 nm achieved similar inactivation levels, while UVA at 365 nm did not cause major reductions. Phages were also suspended in yoghurt serum of pH 5.5 and pH 7.0 and exposed to UVC radiation at 265 nm. The heat-tolerant phage P680 was more UV tolerant for all wavelengths, matrices and pH values tested. A higher aggregation degree together with less DNA damage was observed for both phages at pH 5.5, especially for phage P680, indicating a UV light-shielding effect. Interestingly, there were indications of some phage survivors exhibiting higher UV tolerance on re-exposure, pointing out a need for further investigation. Our results show that UV LEDs emitting at 265 nm and 285 nm are efficient in reducing the phage population significantly, but also underline that 936-type phages are relatively UV resistant. A further understanding of the main factors influencing UV efficiency could enable future use of the UV technology as an alternative or complement to thermal treatment for phage inactivation.",

keywords = "Dairy bacteriophages, LEDs, Light-shielding, Non-thermal treatment, Tailing, UVA, UVB, UVC inactivation",

author = "Eirini Vitzilaiou and Yuxin Liang and Castro-Mej{\'i}a, {Josu{\'e} L.} and Franz, {Charles M.A.P.} and Horst Neve and Vogensen, {Finn Kvist} and Susanne Kn{\o}chel",

note = "Publisher Copyright: {\textcopyright} 2022 The Authors",

year = "2022",

doi = "10.1016/j.ijfoodmicro.2022.109824",

language = "English",

volume = "378",

journal = "International Journal of Food Microbiology",

issn = "0168-1605",

publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - UV tolerance of Lactococcus lactis 936-type phages

T2 - Impact of wavelength, matrix, and pH

AU - Vitzilaiou, Eirini

AU - Liang, Yuxin

AU - Castro-Mejía, Josué L.

AU - Franz, Charles M.A.P.

AU - Neve, Horst

AU - Vogensen, Finn Kvist

AU - Knøchel, Susanne

PY - 2022

Y1 - 2022

N2 - Ultraviolet C (UVC) radiation is a widely used technology for the disinfection of surfaces, air flows, water and other liquids. Although extensive research has been conducted on the UV tolerance of bacteriophages used as surrogates for waterborne viruses, limited information is available on phages relevant to food processing. Phages of dairy starters may reach high numbers in dairy facilities and cause fermentation failure with great economic losses for the dairy industry. Here, the UV tolerance of virulent phages, belonging to the 936-group (Skunavirus) of Lactococcus lactis subsp. diacetylactis F7/2, was assessed, employing both host infectivity loss and qPCR assays. A highly heat-tolerant phage (P680) and a less heat-tolerant phage (P008) were exposed to UV radiation at 265 nm (UVC), 285 nm (UVB) and 365 nm (UVA), respectively, in an aqueous suspension, using UV Light-Emitting-Diodes (LEDs) in a static set-up. UVC at 265 nm achieved the highest total inactivation, leading to a 4 log10 reduction of the phage titer at a UV dose of 327 and 164 mJ/cm2 for P680 and P008, respectively. UVB at 285 nm achieved similar inactivation levels, while UVA at 365 nm did not cause major reductions. Phages were also suspended in yoghurt serum of pH 5.5 and pH 7.0 and exposed to UVC radiation at 265 nm. The heat-tolerant phage P680 was more UV tolerant for all wavelengths, matrices and pH values tested. A higher aggregation degree together with less DNA damage was observed for both phages at pH 5.5, especially for phage P680, indicating a UV light-shielding effect. Interestingly, there were indications of some phage survivors exhibiting higher UV tolerance on re-exposure, pointing out a need for further investigation. Our results show that UV LEDs emitting at 265 nm and 285 nm are efficient in reducing the phage population significantly, but also underline that 936-type phages are relatively UV resistant. A further understanding of the main factors influencing UV efficiency could enable future use of the UV technology as an alternative or complement to thermal treatment for phage inactivation.

AB - Ultraviolet C (UVC) radiation is a widely used technology for the disinfection of surfaces, air flows, water and other liquids. Although extensive research has been conducted on the UV tolerance of bacteriophages used as surrogates for waterborne viruses, limited information is available on phages relevant to food processing. Phages of dairy starters may reach high numbers in dairy facilities and cause fermentation failure with great economic losses for the dairy industry. Here, the UV tolerance of virulent phages, belonging to the 936-group (Skunavirus) of Lactococcus lactis subsp. diacetylactis F7/2, was assessed, employing both host infectivity loss and qPCR assays. A highly heat-tolerant phage (P680) and a less heat-tolerant phage (P008) were exposed to UV radiation at 265 nm (UVC), 285 nm (UVB) and 365 nm (UVA), respectively, in an aqueous suspension, using UV Light-Emitting-Diodes (LEDs) in a static set-up. UVC at 265 nm achieved the highest total inactivation, leading to a 4 log10 reduction of the phage titer at a UV dose of 327 and 164 mJ/cm2 for P680 and P008, respectively. UVB at 285 nm achieved similar inactivation levels, while UVA at 365 nm did not cause major reductions. Phages were also suspended in yoghurt serum of pH 5.5 and pH 7.0 and exposed to UVC radiation at 265 nm. The heat-tolerant phage P680 was more UV tolerant for all wavelengths, matrices and pH values tested. A higher aggregation degree together with less DNA damage was observed for both phages at pH 5.5, especially for phage P680, indicating a UV light-shielding effect. Interestingly, there were indications of some phage survivors exhibiting higher UV tolerance on re-exposure, pointing out a need for further investigation. Our results show that UV LEDs emitting at 265 nm and 285 nm are efficient in reducing the phage population significantly, but also underline that 936-type phages are relatively UV resistant. A further understanding of the main factors influencing UV efficiency could enable future use of the UV technology as an alternative or complement to thermal treatment for phage inactivation.

KW - Dairy bacteriophages

KW - LEDs

KW - Light-shielding

KW - Non-thermal treatment

KW - Tailing

KW - UVA, UVB, UVC inactivation

U2 - 10.1016/j.ijfoodmicro.2022.109824

DO - 10.1016/j.ijfoodmicro.2022.109824

M3 - Journal article

C2 - 35797894

AN - SCOPUS:85133496227

VL - 378

JO - International Journal of Food Microbiology

JF - International Journal of Food Microbiology

SN - 0168-1605

M1 - 109824

ER -

ID: 316400474