Stecab Publishing
Article section
Molecular Detection and Phylogenetic Analysis of Klebsiella aerogenes in Diabetic Foot Ulcers in Iraq
Authors
-
Rajaa Ali Habeeb
Department of Pathological Analyses, College of Science, University of Al-Qadisiyah, Al-Qadisiyah, Iraq
Abstract
Klebsiella aerogenes is a nosocomial bacterium which recognized increasingly as a significant contributor to the complexity and recalcitrance of diabetic foot ulcers. The study looks at molecular phylogenetic profiling of K. aerogenes in diabetic foot ulcers and estimating the relationship of infection to some related risk factors. Swab samples were collected from foot ulcer of an overall 143 diabetic patients at Al-Qadisiyah province, and subjected to molecular examination using the conventional PCR assay. Then, some positive K. aerogenes isolates were sent for sequencing, and the received data were submitted to the NCBI-GenBank database, and then analysed phylogenetically using the MEGA-11 software. Information related to age and sex of study patients as well as type of diabetes and glycemic control had been recorded as risk factors. Totally, there were 13.29% positive foot ulcers to K. aerogenes infection. Sequencing data and pahylogenetic analysis of 10 study K. aerogenes isolates revealed the presence of similarity (*) at range of 99.25-99.86% and substitution / mutation at range of 0.0001-0.0014% with the global GenBank-BLAST K. aerogenes isolates / strains; in particular Polish K. aerogenes strain (ID: OM250432.1). For risk factors, positive K. aerogenes infection was observed significantly in patients aged 30-50 (11.86%) and >50 (14.63%) years more than <30 (0%) years; males (14.66%) more than females (7.41%); type 2 diabetes (14.17%) more than type 1 (6.25%); and glycemic uncontrolled (17.07%) more than glycemic controlled (8.2%) patients. Subsequently, the risk of K. aerogenes infection was elevated significantly in patients aged >50 years more than 30-50 years and <30 years; males more than females; type 2 diabetes more than type 1; and glycemic uncontrolled more than controlled patients. This might represent the first Iraqi molecular phylogenetic study implicates K. aerogenes in diabetic foot ulcers indicating the need for moreover studies. Also, the nuanced interplay between bacterial virulence factors, host immune responses and the development of antimicrobial resistance necessitates a re-evaluation of current diagnostic and therapeutic paradigms for diabetic foot ulcers.
Keywords:
Diabetes Mellitus Enterobacteriaceae Iraq Phylogenetic Analysis Polymerase Chain Reaction (PCR)
Article information
Journal
Journal of Medical Science, Biology, and Chemistry
Volume (Issue)
2(2), (2025)
Pages
159-168
Published
Copyright
Copyright (c) 2025 Rajaa Ali Habeeb (Author)
Open access
This work is licensed under a Creative Commons Attribution 4.0 International License.
How to Cite
References
Abd Khader, K., & Raad, A. (2025). The Prevalence of Pseudomonas aeruginosa and antibiotic resistance in diabetic foot ulcer patients in ErbilIraq. The Medical Journal of Tikrit University, 31(1), 7-13.
Aifari, S. A. G. (2025). A Molecular Investigation for Staphylococcus aureus in Diabetic Foot Ulcers. International Journal of Medical and Health Research, 3(1), 22-32.
Akinci, B., Yener, S., Yesil, S., Yapar, N., Kucukyavas, Y., & Bayraktar, F. (2011). Acute phase reactants predict the risk of amputation in diabetic foot infection. Journal of the American Podiatric Medical Association, 101(1), 1-6.
Al-Ethafa, L. F., Almialy, A. J., Gharban, H. A., Essa, I. A. M., & Al-Eqabi, S. R. (2025). First molecular phylogenetic and serological insights into Listeria monocytogenes infection in aborted ewes in Iraq: A cross-border comparative analysis.
Alkhudhairy, M. K., & Al-Shammari, M. M. M. (2020). Prevalence of metallo-β-lactamase–producing Pseudomonas aeruginosa isolated from diabetic foot infections in Iraq. New microbes and new infections, 35, 100661.
Almatroudi, A. (2025). Biofilm resilience: Molecular mechanisms driving antibiotic resistance in clinical contexts. Biology, 14(2), 165.
Al-Shaeli, S. J. J., Ethaeb, A. M., & Al-Zaidi, E. A. N. (2022a). Serological and histological evaluation of the effect of honeybee venom on pancreas and liver in diabetic mice. Archives of Razi Institute, 77(3), 1125.
Al-Shaeli, S. J., Hussen, T. J., & Ethaeb, A. M. (2022b). Effect of honey bee venom on the histological changes of testes and hormonal disturbance in diabetic mice. Veterinary World, 15(9), 2357.
Al-Shaeli, S. J., Almialy, A. J., Ethaeb, A. M., & Gharban, H. A. (2025). Molecular, Histopathological, and Immunohistochemical Investigation of Peste des Petits Ruminants in Clinically Suspected Sheep in Wasit Province, Iraq. Veterinary Medicine International, 2025(1), 2702787.
Álvarez-Marín, R., Lepe, J. A., Gasch-Blasi, O., Rodríguez-Martínez, J. M., Calvo-Montes, J., Lara-Contreras, R., & Spanish Network for Research in Infectious Diseases. (2021). Clinical characteristics and outcome of bacteraemia caused by Enterobacter cloacae and Klebsiella aerogenes: more similarities than differences. Journal of Global Antimicrobial Resistance, 25, 351-358.
Boyko, E. J., Ahroni, J. H., Smith, D. G., & Davignon, D. (1996). Increased mortality associated with diabetic foot ulcer. Diabetic medicine, 13(11), 967-972.
Chang, M., & Nguyen, T. T. (2021). Strategy for treatment of infected diabetic foot ulcers. Accounts of chemical research, 54(5), 1080-1093.
Chen, L., Sun, S., Gao, Y., & Ran, X. (2023). Global mortality of diabetic foot ulcer: a systematic review and meta‐analysis of observational studies. Diabetes, Obesity and Metabolism, 25(1), 36-45.
Cooke, E. M., Pool, R., Brayson, J. C., Edmondson, A. S., Munro, M. E., & Shinebaum, R. (1979). Further studies on the sources of Klebsiella aerogenes in hospital patients. Epidemiology and Infection, 83(3), 391-395.
Costa, R. H. R., Cardoso, N. A., Procópio, R. J., Navarro, T. P., Dardik, A., & de Loiola Cisneros, L. (2017). Diabetic foot ulcer carries high amputation and mortality rates, particularly in the presence of advanced age, peripheral artery disease and anemia. Diabetes and Metabolic Syndrome: Clinical Research and Reviews, 11, S583-S587.
Dong, N., Yang, X., Chan, E. W. C., Zhang, R., & Chen, S. (2022). Klebsiella species: taxonomy, hypervirulence and multidrug resistance. EBioMedicine, 79.
Dutta, A., Bhansali, A., & Rastogi, A. (2023). Early and intensive glycemic control for diabetic foot ulcer healing: a prospective observational nested cohort study. The International Journal of Lower Extremity Wounds, 22(3), 578-587.
Erhunmwunse, R. U., Ogbodo, E. C., & Muoneke, G. I. (2025). Complications Associated with Type 2 Diabetes Mellitus, Pathophysiology, Diagnosis and Management: A Concise Review of Current Literature. Saudi J Biomed Res, 10(7), 201-244.
Gandhi, S. K., Waschbusch, M., Michael, M., Zhang, M., Li, X., Juhaeri, J., & Wu, C. (2020). Age-and sex-specific incidence of non-traumatic lower limb amputation in patients with type 2 diabetes mellitus in a US claims database. Diabetes Research and Clinical Practice, 169, 108452.
Glushakova, А. М., Kachalkin, А. V., Prokof’eva, T. V., & Lysak, L. V. (2022). Enterobacteriaceae in soils and atmospheric dust aerosol accumulations of Moscow city. Current Research in Microbial Sciences, 3, 100124.
Guedes, M., Gathara, D., López-Hernández, I., Pérez-Crespo, P. M. M., Pérez-Rodríguez, M. T., Sousa, A., & Rodríguez-Baño, J. (2024). Differences in clinical outcomes of bloodstream infections caused by Klebsiella aerogenes, Klebsiella pneumoniae and Enterobacter cloacae: a multicentre cohort study. Annals of Clinical Microbiology and Antimicrobials, 23(1), 42.
Habeeb, T. A., Shaebth, L. J., & Abdulameer, N. A. (2021). Isolation of Bacteria from Diabetic Foot Patients in Hospital of Al-Dewaniyah City, Iraq. Annals of the Romanian Society for Cell Biology, 25(5), 187-192.
Hangaard, S., Rasmussen, A., Almdal, T., Nielsen, A. A., Nielsen, K. E., Siersma, V., & Holstein, P. (2019). Standard complication screening information can be used for risk assessment for first time foot ulcer among patients with type 1 and type 2 diabetes. Diabetes research and clinical practice, 151, 177-186.
Hussein, S. Z., & Saleh, G. M. (2024). Molecular Detection of Virulence Factors Genes for Staphylococcus aureus in Diabetic Foot Ulcers in Iraq. Ibn AL-Haitham Journal For Pure and Applied Sciences, 37(3), 98-105.
Ibraheim, H. K., Madhi, K. S., Jasim, A. S., & Gharban, H. A. (2024). Molecular identification of Klebsiella species from pneumonic goats, Iraq. Open Veterinary Journal, 14(11), 2980.
Jaber, D., Younes, N., Khalil, E., Albsoul-Younes, A., Zawiah, M., & Al-Bakri, A. G. (2025). Studying microbial ecology of diabetic foot infections: significance of PCR analysis for prudent antimicrobial stewardship. The International Journal of Lower Extremity Wounds, 24(2), 497-505.
Lane, K. L., Abusamaan, M. S., Voss, B. F., Thurber, E. G., Al-Hajri, N., Gopakumar, S., & Mathioudakis, N. N. (2020). Glycemic control and diabetic foot ulcer outcomes: A systematic review and meta-analysis of observational studies. Journal of Diabetes and its Complications, 34(10), 107638.
Lin, C. W., Hsu, L. A., Chen, C. C., Yeh, J. T., Sun, J. H., Lin, C. H., & Huang, Y. Y. (2010). C-reactive protein as an outcome predictor for percutaneous transluminal angioplasty in diabetic patients with peripheral arterial disease and infected foot ulcers. Diabetes research and clinical practice, 90(2), 167-172.
Liu, X., Xu, Q., Yang, X., Heng, H., Yang, C., Yang, G., & Chen, S. (2025). Capsular polysaccharide enables Klebsiella pneumoniae to evade phagocytosis by blocking host-bacteria interactions. MBio, 16(3), e03838-24.
Madhi, K. S., Jasim, A. S., Nasear, H. A., Ibraheim, H. K., and Gharban, H. A. (2024). Phylogenetic analysis of Klebsiella pneumoniae isolates of respiratory tract infections in humans and sheep. Open Veterinary Journal, 14(9), 2325.
Matar, T. A., & Saleh, N. I. (2024). Detection of Multidrug Resistant Bacterial Infections Isolated from Patients with Diabetics Foot Ulcers in Iraq. Central Asian Journal of Medical and Natural Science, 5(4), 410-418.
Mezil, S. A., & Abed, B. A. (2021). Complication of diabetes mellitus. Annals of the Romanian Society for Cell Biology, 25(3), 1546-1556.
Morgado, S., Fonseca, É., Freitas, F., Caldart, R., and Vicente, A. C. (2024). In-depth analysis of Klebsiella aerogenes resistome, virulome and plasmidome worldwide. Scientific Reports, 14(1), 6538.
Mustamu, A. C., Samaran, E., & Bistara, D. N. (2024). Impact of Poor Glycemic Control and Vascular Complications on Diabetic Foot Ulcer Recurrence. Integrative Biomedical Research, 8(8), 1-14.
Orji, F. A., Nwachukwu, N. C., & Udora, E. C. (2009). Bacteriological evaluation of diabetic ulcers in Nigeria. African Journal of Diabetes Medicine, 15(11), 19-21.
Oyibo, S. O., Jude, E. B., Tarawneh, I., Nguyen, H. C., Armstrong, D. G., Harkless, L. B., & Boulton, A. J. M. (2001). The effects of ulcer size and site, patient’s age, sex and type and duration of diabetes on the outcome of diabetic foot ulcers. Diabetic Medicine, 18(2), 133-138.
Price, D. J. E., & Sleigh, J. D. (1970). Control of infection due to Klebsiella aerogenes in a neurosurgical unit by withdrawal of all antibiotics. The Lancet, 296(7685), 1213-1215.
Rajagopalan, S. (2005). Serious infections in elderly patients with diabetes mellitus. Clinical infectious diseases, 40(7), 990-996.
Rong, Q., Ling, C., Lu, D., Zhang, C., Zhao, H., Zhong, K., & Qin, X. (2022). Sb (III) resistance mechanism and oxidation characteristics of Klebsiella aerogenes X. Chemosphere, 293, 133453.
Rong, Q., Lu, D., Zhong, K., Yang, S., Li, Z., & Zhang, C. (2024). Mechanism of antimony oxidation and adsorption using immobilized Klebsiella aerogenes HC10 in soil. Science of The Total Environment, 956, 177404.
Rossi, F., Santonicola, S., Amadoro, C., Marino, L., & Colavita, G. (2023). Recent records on bacterial opportunistic infections via the dietary route. Microorganisms, 12(1), 69.
Russo, A., Fusco, P., Morrone, H. L., Trecarichi, E. M., & Torti, C. (2023). New advances in management and treatment of multidrug-resistant Klebsiella pneumoniae. Expert Review of Anti-infective Therapy, 21(1), 41-55.
Sayiner, Z. A., Can, F. I., & Akarsu, E. (2019). Patients’ clinical charecteristics and predictors for diabetic foot amputation. Primary care diabetes, 13(3), 247-251.
Schofield, H., Haycocks, S., Robinson, A., Edmonds, M., Anderson, S. G., & Heald, A. H. (2021). Mortality in 98 type 1 diabetes mellitus and type 2 diabetes mellitus: Foot ulcer location is an independent risk determinant. Diabetic Medicine, 38(10), e14568.
Tabur, S., Eren, M. A., Çelik, Y., Dağ, O. F., Sabuncu, T., Sayiner, Z. A., & Savas, E. (2015). The major predictors of amputation and length of stay in diabetic patients with acute foot ulceration. Wiener Klinische Wochenschrift, 127(1), 45-50.
Turkei, M. R., & Al-Dulaimi, T. H. (2024). Identification of bacterial species isolated from diabetic foot ulcer in Iraq. Microbial Biosystems, 9(2), 115-120.
Wesevich, A., Sutton, G., Ruffin, F., Park, L. P., Fouts, D. E., Fowler Jr, V. G., & Thaden, J. T. (2020). Newly named Klebsiella aerogenes (formerly Enterobacter aerogenes) is associated with poor clinical outcomes relative to other Enterobacter species in patients with bloodstream infection. Journal of clinical microbiology, 58(9), 10-1128.
Xiang, J., Wang, S., He, Y., Xu, L., Zhang, S., & Tang, Z. (2019). Reasonable glycemic control would help wound healing during the treatment of diabetic foot ulcers. Diabetes Therapy, 10(1), 95-105.
Yachmaneni Jr, A., Jajoo, S., Mahakalkar, C., Kshirsagar, S., & Dhole, S. (2023). A comprehensive review of the vascular consequences of diabetes in the lower extremities: current approaches to management and evaluation of clinical outcomes. Cureus, 15(10).
Zakir, M., Ahuja, N., Surksha, M. A., Sachdev, R., Kalariya, Y., Nasir, M., & Ali, M. (2023). Cardiovascular complications of diabetes: from microvascular to macrovascular pathways. Cureus, 15(9).
Journal information
Call for Papers
Author's Guidelines
Manuscript Template
References Guideline
Join in Editorial Team
