Cath Rees

Contact

• workRoom B29 Food Sciences
  Sutton Bonington Campus
  Sutton Bonington
  Leicestershire
  LE12 5RD
  UK
• work0115 951 6167
• fax0115 951 6142
• cath.rees@nottingham.ac.uk
• https://www.nottingham.ac.uk/biosciences/people/cath.rees

Biography

My focus of research is the application of molecular biology to fundamental research on micro-organisms of importance to the food industry. Specific research focuses on the food borne pathogen Listeria monocytogenes and the cattle pathogens Mycobacterium paratuberculosis (Johne's disease in cattle) and Mycobacterium bovis (bovine TB). In addition my research group specializes in the use of bacteriophage to develop rapid methods of detection of bacterial pathogens.

Expertise Summary

General area of expertise:

• Bacterial genetics and molecular biology
• Applied microbiology and the food industry
• Analysis of gene expression and use of reporter genes
• Bacteriophage

Genetics and physiology of Gram-positive food borne pathogens:

• Adaptation, survival and transmission of bacteria in the food environment with a specific focus on Listeria and Mycobacterium.
• Development of novel food preservatives

Biotechnology applications for Bacteriophage:

• Use for rapid detection of bacterial pathogens with a specific focus on Mycobacterium paratuberculosis (Johne's disease of cattle) and Mycobacterium bovis (bovine TB)
• Application of bacteriophage for diagnosis of human infections (Human TB and Crohn's disease)
• Genetic engineering of bacteriophage for detection of pathogens

Teaching Summary

I teach across a wide range of modules covering bacterial physiology, genetics, molecular microbiology, pathogenicity and biotechnology. My main teaching contributions are in the following modules:

BIOS 1027 (Module Convenor) The Physiology of Microbes

BIOS2008 (Lecturer) Analysis of Bacterial Gene Expression

BIOS2009 (Co-convenor and lecturer) Virology

BIOS3018 (Co-convenor and lecturer) Molecular Microbiology and Biotechnology

Research Summary

Listeria monocytogenes is a major cause for concern for the food industry as it causes outbreaks of food borne disease with the highest death rate. In the UK numbers of cases continue to increase and… read more

Selected Publications

• CATHERINE E.D. REES, BENJAMIN MC SWIFT and PRANABASHIS HALDAR, 2024. State-of-the-art detection of Mycobacterium tuberculosis in blood during tuberculosis infection using phage technology International Journal of Infectious Diseases. 141(April 2024), 106991
• KIM JW, BOWMAN K, NAZARETH J., LEE J, WOLTMANN GP, VERMA R, SHARIFPOUR M, SHIELD C, REES C, KAMIL A, SWIFT B and HALDAR P, 2024. PET-CT-guided characterisation of progressive, preclinical tuberculosis infection and its association with low-level circulating Mycobacterium tuberculosis DNA in household contacts in Leicester, UK: a prospective cohort study Lancet Microbe. 2(2), e119-e130
• SWIFT BMC, MEADE N, BARRON ES, BENNETT M, PEREHENIC TD, HUGHES V, STEVENSON K and REES CED, 2020. The development and use of Actiphage to detect viable mycobacteria from bovine tuberculosis and Johne’s disease-infected animals Microbial Biotechnololgy. 13(3), 738-746
• SWIFT, B.M.C, CONVERY, T. and REES, C.E.D., 2016. Evidence of Mycobacterium tuberculosis complex bacteraemia in intradermal skin test positive cattle detected using phage-RPA. Virulence. 7(7), 779-788

• View all publications

Current Research

Listeria monocytogenes is a major cause for concern for the food industry as it causes outbreaks of food borne disease with the highest death rate. In the UK numbers of cases continue to increase and factors causing this are unclear. It has the ability to grow under many of the conditions normally used to suppress the growth of bacterial pathogens (such as high salt and low temperature) and therefore manufactures are required to demonstrates an absence from high risk foods. In addition to being associated with many food ingredients (meat, fish, dairy and vegetables), it can become endemic in the food processing environment, resulting in cross-contamination of product. Focus of research looks at aspects of adaptive gene expression and cell physiology that lead to its survival in the food environment.

Bacteriophage are viruses that infect bacterial cells. These viruses have a host tropism meaning that they only infect a limited number of bacterial cell types. We have exploited this specific host interaction to develop assays to detect slow growing members of the genus Mycobacterium. These organisms take a minimum of 20 days to detect by rapid culture methods; the slowest growing organism takes up to 40 days whereas phage-based assays take just 48 h. This novel assay has been applied to a variety of samples; foods such as milk and cheese and clinical specimens such as sputum and blood. Research is being carried out to understand the impact of these new assays on the understanding of disease transmission in cattle and in improving control programes.

Past Research

Collaboration with staff in UoN Physics Dept to investigate the effect of reduced gravity on bacterial cells and the use of strong magnetic fields to separate biological material.

Future Research

Detection of bovine TB in veterinary clinical samples

• CATHERINE E.D. REES, BENJAMIN MC SWIFT and PRANABASHIS HALDAR, 2024. State-of-the-art detection of Mycobacterium tuberculosis in blood during tuberculosis infection using phage technology International Journal of Infectious Diseases. 141(April 2024), 106991
• KIM JW, BOWMAN K, NAZARETH J., LEE J, WOLTMANN GP, VERMA R, SHARIFPOUR M, SHIELD C, REES C, KAMIL A, SWIFT B and HALDAR P, 2024. PET-CT-guided characterisation of progressive, preclinical tuberculosis infection and its association with low-level circulating Mycobacterium tuberculosis DNA in household contacts in Leicester, UK: a prospective cohort study Lancet Microbe. 2(2), e119-e130
• KUBALA A, PEREHINEC TM, EVANS C, PIROVANO A, SWIFT BMC and REES CED, 2021. Development of a Method to Detect Mycobacterium paratuberculosis in the Blood of Farmed Deer Using Actiphage® Rapid. Frontiers in Veterinary Science. 8, 665697
• NWAIWU O, WONG L, LAD M, FOSTER T, MACNAUGHTAN W and REES C, 2021. Properties of the extracellular polymeric substance layer from minimally grown planktonic cells of Listeria monocytogenes Biomolecules. 11(2), 331
• SWIFT BMC, MEADE N, BARRON ES, BENNETT M, PEREHENIC TD, HUGHES V, STEVENSON K and REES CED, 2020. The development and use of Actiphage to detect viable mycobacteria from bovine tuberculosis and Johne’s disease-infected animals Microbial Biotechnololgy. 13(3), 738-746
• VERMA R, SWIFT BMC, HANDLEY-HARTILL W, LEE JK, WOLTMANN G and REES CED, 2020. A Novel, High-sensitivity, Bacteriophage-based Assay Identifies Low-level Mycobacterium tuberculosis Bacteremia in Immunocompetent Patients With Active and Incipient Tuberculosis Clinical Infectious Diseases. 70(5), 933-936.
• MOLENAAR FM, BURR PD, SWIFT BMC, REES CED and MASTERS N, 2020. Conservation challenges: the limitations of antemortem tuberculosis testing in captive Asiatic Lions (Panthera leo persica) Joural of Zoo Wildlife Medicine. 51(2), 426-432
• BLANCHARD AM, BILLENNESS R, WARREN J, GLANVILL A, RODEN W, DRINKALL E, MABONI G, ROBINSON RS, REES CED, PFARRER C and TÖTEMEYER S, 2020. Characterisation of Listeria monocytogenes isolates from cattle using a bovine caruncular epithelial cell model Heliyon. 6(7), e04476
• SWIFT BMC and REES CED, 2019. The specificity of phage testing for MAP — where might it fit into the diagnostic armoury? Livestock. 24(4),
• GERRARD ZE, SWIFT BMC, BOTSARIS G, DAVIDSON RS, HUTCHINGS MR, HUXLEY JN and REES CED, 2018. Survival of Mycobacterium avium subspecies paratuberculosis in retail pasteurised milk Food Microbiology. 74, 57-63
• NWAIWU, OGUERI, MOURA, ALEXANDRA, THOUVENOT, PIERRE, REES, CATHERINE, LECLERCQ, ALEXANDRE and LECUIT, MARC, 2017. Listeria monocytogenes, Isolated from Fresh Leaf Vegetables in Owerri City, Nigeria. Genome Announcements. 5(22),
• SAMUEL FURSE, MARTIN JAKUBEC, FRODE RISE, HUW E. WILLIAMS, CATHERINE E.D. REES and OYVIND HALSKAU, 2017. Evidence that Listeria innocua modulates its membrane's stored curvature elastic stress, but not fluidity, through the cell cycle SCIENTIFIC REPORTS. 7, 8012
• BOTSARIS, GEORGE, SWIFT, BENJAMIN M. C., SLANA, IVA, LIAPI, MARIA, CHRISTODOULOU, MARITSA, HATZITOFI, MARIA, CHRISTODOULOU, VASILIKI and REES, CATHERINE E. D., 2016. Detection of viable Mycobacterium avium subspecies paratuberculosis in powdered infant formula by phage-PCR and confirmed by culture INTERNATIONAL JOURNAL OF FOOD MICROBIOLOGY. 216, 91-94
• SWIFT, BENJAMIN M. C., HUXLEY, JONATHAN N., PLAIN, KARREN M., BEGG, DOUGLAS J., DE SILVA, KUMUDIKA, PURDIE, AURIOL C., WHITTINGTON, RICHARD J. and REES, CATHERINE E. D., 2016. Evaluation of the limitations and methods to improve rapid phage-based detection of viable Mycobacterium avium subsp paratuberculosis in the blood of experimentally infected cattle BMC VETERINARY RESEARCH. 12, 115-115
• SWIFT, B.M.C, CONVERY, T. and REES, C.E.D., 2016. Evidence of Mycobacterium tuberculosis complex bacteraemia in intradermal skin test positive cattle detected using phage-RPA. Virulence. 7(7), 779-788
• MADIHA EL AWAMIE and CATHERINE REES, 2016. Identification of the Antimicrobial Effect of Liquorice Extracts on Gram-Positive Bacteria: Determination of Minimum Inhibitory Concentration and Mechanism of Action Using a luxABCDE Reporter Strain In: International Journal of Medical, Health, Biomedical, Bioengineering and Pharmaceutical Engineering. 10. 338-346
• WARREN J, OWEN AR, GLANVILL A, FRANCIS A, MABONI G, NOVA RJ, WAPENAAR W, REES C and TÖTEMEYER S, 2015. A new bovine conjunctiva model shows that Listeria monocytogenes invasion is associated with lysozyme resistance. Veterinary microbiology. 179(1-2), 76-81
• BOTSARIS G, SWIFT BM, SLANA I, LIAPI M, CHRISTODOULOU M, HATZITOFI M, CHRISTODOULOU V and REES CE, 2015. Detection of viable Mycobacterium avium subspecies paratuberculosis in powdered infant formula by phage-PCR and confirmed by culture. International journal of food microbiology. 216, 91-4
• SWIFT BMC, GERRARD ZE, HUXLEY JN and REES CED, 2014. Factors affecting phage D29 infection: a tool to investigate different growth states of mycobacteria. PloS one. 9(9), e106690
• BOTSARIS, G., LIAPI, M., KAKOGIANNIS, C., DODD, C.E.R. and REES, C.E.D., 2013. Detection of Mycobacterium avium subsp. paratuberculosis in bulk tank milk by combined phage-PCR assay: evidence that plaque number is a good predictor of MAP International Journal of Food Microbiology. 164(1), 76-80
• SWIFT BMC, DENTON EJ, MAHENDRAN SA, HUXLEY JN and REES CED, 2013. Development of a rapid phage-based method for the detection of viable Mycobacterium avium subsp. paratuberculosis in blood within 48 h. Journal of microbiological methods. 94(3), 175-179
• SWIFT BM and REES CE, 2013. Detecting mycobacteria in cattle blood. The Veterinary record. 173(21), 522-3
• REES, CED and BOTSARIS, G, 2012. The Use of Phage for Detection, Antibiotic Sensitivity Testing and Enumeration. In: P-J CARDONA, ed., Understanding Tuberculosis - Global Experiences and Innovative Approaches to the Diagnosis Intech.. 293-306
• DIJKSTRA, C.E., LARKIN, O.J., ANTHONY, P., DAVEY, M.R., EAVES, L., REES, C.E.D. and HILL, R.J.A., 2011. Diamagnetic levitation enhances growth of liquid bacterial cultures by increasing oxygen availability Interface: Journal of the Royal Society. 8(56), 334-344
• LIAPI, M., LEONTIDES, L., KOSTOULAS, P., BOTSARIS, G., IACOVOU, Y., REES, C., GEORGIOU, K., SMITH, G.C. and NASEBY, D.C., 2011. Bayesian estimation of the true prevalence of Mycobacterium avium subsp. paratuberculosis infection in Cypriot dairy sheep and goat flocks Small Ruminant Research. 95(2-3), 174-178
• MONK AB, REES CD, BARROW P, HAGENS S and HARPER DR, 2010. Bacteriophage Applications: Where Are We Now? Letters In Applied Microbiology. 51(4), 363-9
• BOTSARIS, G., SLANA, I., LIAPI, M., DODD, C., ECONOMIDES, C., REES, C. and PAVLIK, I., 2010. Rapid detection methods for viable Mycobacterium avium subspecies paratuberculosis in milk and cheese International Journal of Food Microbiology. 141 Supplement, S87-S90
• REES, CED and GRANT, I.R., 2009. In: L. DONGYOU, ed., Molecular Detection of Foodborne Pathogens CRC Press.. 229-244
• REES, CED and MCLAUGHLIN, J., 2009. Listeriaceae. In: Bergy's Manual of Determinative Bacteriology: Topley & Wilson's Microbiology and Microbial Infections (Volume 3: Bacterial Infections). Topley & Wilson.
• STANLEY, E.C., MOLE, R.J., SMITH, R.J., GLENN, S.M., BARER, M.R, MCGOWAN, M. and REES, C.E.D, 2007. Development of a new rapid combined Phage and PCR method for detection and identification of viable Mycobacterium paratuberculosis bacteria within 48 hours Applied and Environmental Microbiology. 73(6), 1851–1857
• WHITAKER, S, HERRING, PJ, CAMPBELL, AK, HILL, PJ and REES, CED, 2007. Characterization Of A Fish Symbiont Of Photobacterium Phosphoreum With Altered Spectral Properties
• GADDIPATI, SR, PEREHINEC, TM, QAZI, SNA, REES, CED and HILL, PJ, 2007. Bivalent Fluorescent Reporters For Gene Expression Studies In Gram-Positive Bacteria
• DE SIQUEIRA, R.S., DODD, C.E. and REES, C.E., 2006. Evaluation of the natural virucidal activity of teas for use in the phage amplification assay. International Journal of Food Microbiology. 111(3), 259-262
• REES, C.E. and DODD, C.E, 2006. Phage for rapid detection and control of bacterial pathogens in food Advances in Applied Microbiology. 59, 159-186
• ATTERBURY, R. J., DILLON, E., SWIFT, C., CONNERTON, P. L., FROST, J. A., DODD, C. E. R., REES, C. E. D. and CONNERTON, I. F., 2005. Correlation of Campylobacter Bacteriophage with Reduced Presence of Hosts in Broiler Chicken Ceca Applied and Environmental Microbiology. VOL 71(NUMB 8), 4885-4887
• REES, C.E., 2005. The use of Phage as Diagnostic Systems. In: The Bacteriophages 2nd. Oxford University Press, Oxford. 699-706
• REES,C.E.D and LOESSNER,M.J, 2005. Phage for the Detection of Pathogenic Bacteria. In: , ed., Bacteriophages: Biology and Applications CRC Press, Boca Raton, Fla. 267-284
• CONNERTON, P. L., CARRILLO, C. M. L., SWIFT, C., DILLON, E., SCOTT, A., REES, C. E. D., DODD, C. E. R., FROST, J. and CONNERTON, I. F., 2004. Longitudinal Study of Campylobacter jejuni Bacteriophages and Their Hosts from Broiler Chickens Applied and Environmental Microbiology. VOL 70(PART 7), 3877-3883
• ATTERBURY, R.J., CONNERTON, P.L., DODD, C.E.R., REES, C.E.D. and CONNERTON, I.F., 2003. Isolation and characterization of Campylobacter bacteriophages from retail poultry Applied and Environmental Microbiology. 69(8), 4511-4518
• ATTERBURY, R. J., CONNERTON, P. L., DODD, C. E. R., REES, C. E. D. and CONNERTON, I. F., 2003. Application of Host-Specific Bacteriophages to the Surface of Chicken Skin Leads to a Reduction in Recovery of Campylobacter jejuni Applied and Environmental Microbiology. VOL 69(PART 10), 6302-6306
• DE SIQUEIRA, R. S., DODD, C. E. R. and REES, C. E. D., 2003. Phage amplification assay as rapid method for Salmonella detection Brazilian Journal of Microbiology. VOL 34(SUPP/1), 118-120
• QAZI, S.N.A., COUNIL, E., MORRISSEY, J., REES, C.E.D., COCKAYNE, A., WINZER, K., CHAN, W.C., WILLIAMS, P. and HILL, P.J., 2001. agr expression precedes escape of internalized Staphylococcus aureus from the host endosome Infection and Immunity. 69(11), 7074-7082
• QAZI, S. N. A., REES, C. E. D., MELLITS, K. H. and HILL, P. J., 2001. Development of gfp Vectors for Expression in Listeria monocytogenes and Other Low G+C Gram Positive Bacteria MICROBIAL ECOLOGY -NEW YORK-. VOL 41(PART 4), 301-309
• VATANYOOPAISARN, S., NAZLI, A., DODD, C. E., REES, C. E. and WAITES, W. M., 2000. Effect of Flagella on Initial Attachment of Listeria monocytogenes to Stainless Steel Applied and Environmental Microbiology. VOL 66(PART 2), 860-863
• SHARMA, N. K., REES, C. E. and DODD, C. E., 2000. Development of a Single-Reaction Multiplex PCR Toxin Typing Assay for Staphylococcus aureus Strains Applied and Environmental Microbiology. VOL 66(PART 4), 1347-1353
• SHEIKH-ZEINODDIN, M., PEREHINEC, T. M., HILL, S. E. and REES, C. E., 2000. Maillard reaction causes suppression of virulence gene expression in Listeria monocytogenes International Journal of Food Microbiology. VOL 61(NUMBER 1), 41-49