Water scarcity has been a challenge in Nigeria for decades, but beyond the issue of availability, there is a sinister threat that doesn't make headlines: antibiotic-resistant bacteria silently circulating through water. As with many parts of Africa, Kaduna state has its issues with adequate potable water for the population of around 9 million people. Where the municipal pipe-borne water is inadequate or unavailable, individuals depend on water from hand-dug wells, boreholes, streams and commercially available treated water sealed in polythene sachets, popularly known in local parlance as "pure water".
In previous years, the research on antibiotic- resistant bacteria in Nigeria focused majorly on bacteria isolated from clinical settings. This research however, which was carried out between 2014 and 2015, focused on detecting antibiotic resistant Salmonella enterica from various sources of drinking water in Kaduna state. This organism is well known to include serovars that cause diseases such as typhoid fever (which is endemic in Nigeria) and salmonellosis. The symptoms of these diseases can include fever and gastroenteritis, organ failure, shock and death.
The Quest for Answers
As part of her Ph.D research, Dr. Olajoke Alalade under the guidance of her supervisors from Ahmadu Bello University, Zaria collected 500 water samples from diverse sources: packaged water in sachets, municipal treated tap water, wells, boreholes, and streams across six different local government areas across Kaduna State. They were specifically hunting for Salmonella enterica and more importantly, they wanted to know if these bacteria were resistant to the antibiotics we rely on to treat infections. Those that showed resistance were assayed for the presence of some genes responsible for the resistance.
What They Found
Only six samples contained Salmonella enterica, giving an isolation rate of 1.2 %. This may seem low, but it is significant because this bacteria should not be present in water used for drinking. The sources of water where these resistant bacteria were obtained was troubling. Five isolates came from hand-dug wells and boreholes, which are common water sources for many rural and urban families. Most alarming, was finding resistant Salmonella in treated municipal water, the very supply that should be safest after undergoing purification processes. This discovery suggested that either the treatment was inadequate or the ageing distribution pipes had a source of post-treatment contamination.
Four isolates were resistant to multiple antibiotics, showing particular resistance to tetracycline, which is an affordable, widely available antibiotic used across Nigeria. Two-thirds of the isolates were resistant to this drug, along with nalidixic acid and sulfamethoxazole-trimethoprim, which are all front-line antibiotics that are available for purchase over the counter.
The Genetic Evidence
What makes this study particularly significant is that the researchers also found the genetic back up that explained the resistance. Two of the bacterial isolates harbored genes tetA and sul1. These carry genetic information that enable bacteria resist the actions of tetracycline and sulfamethoxazole- trimethoprim. The tetA gene gives bacteria a pump system that pushes tetracycline out of their cells before it can kill them, while the sul1 gene allows bacteria to continue essential functions even when sulfonamide antibiotics try to interfere. What makes this particularly worrying, is that these genes can be horizontally transferred to other bacteria. They can be copied and shared between bacteria, spreading resistance like a viral video on social media.
Why This Matters to You
You might wonder why findings from 2014-2015 in Nigeria matter today. The answer lies in understanding how antibiotic resistance works and spreads. When bacteria in water sources carry resistance genes, they can end up in the food chain through various pathways. For instance, when contaminated water is used for irrigation and animal husbandry, they ultimately end up in our bodies when we eat such food. This creates a vicious cycle where resistance spreads across environmental, animal, and human health domains. There are other implications such as higher treatment costs for ill individuals, longer hospital stays, increased chance of mortality, and greater economic burden on families.
The One Health Connection
This research exemplifies the "One Health" approach, which recognizes that human, animal, and environmental health are connected inextricably. The same antibiotics used carelessly in human medicine, animal farming, and even agriculture create selection pressure that allows resistant bacteria to thrive everywhere.
In Kaduna State, some communities' water sources contained bacteria susceptible to all antibiotics, while others harbored multi-drug resistant strains. These differences likely reflect local patterns of antibiotic use, sanitation infrastructure quality, and environmental contamination levels.
Practical Solutions
The researchers propose several actionable solutions that communities can implement. They include boiling drinking water since Salmonella is heat-sensitive, protection of water sources such as the proper construction of wells far away from latrines, and improved sanitation. Open defecation must be discouraged as it is a major way such bacteria get into water bodies and antibiotic stewardship must also be taken seriously. The populace must be educated on the use of antibiotics only on professional advice, and completing the course of treatment as these help reduce spread of resistance among bacteria. Water sources should also be tested periodically for contamination and resistant bacteria.
Looking Forward
While this data is now a decade old, it provides crucial baseline information. The presence of resistance genes in 2014-2015 means these genes were already circulating in environmental reservoirs long before many current interventions began. The researchers call for urgent follow-up surveillance to assess whether resistance patterns have intensified and whether any interventions implemented over the past decade have made a difference. This historical data becomes invaluable for tracking trends and evaluating the effectiveness of public health measures.
The Bigger Picture
This study from Kaduna State is a microcosm of a global crisis. The World Health Organization projects nearly 2 million deaths annually from bacterial antibiotic resistance by 2050. Water sources serve as both reservoirs and highways for resistance genes, making environmental monitoring essential to any comprehensive response strategy. Addressing antibiotic resistance requires coordinated action across healthcare, agriculture, environmental management, and public education. The genes detected in these water samples are warnings we cannot afford to ignore.