UCCE Livestock Antimicrobial Stewardship

Lessons Learnt

 

A Natural Solution for California's Herds: African Catfish Peptides

California's cattle producers and agricultural communities are all too familiar with the rising challenge of antibiotic resistance, making common bacterial infections harder to treat in livestock. But imagine a future where we could tackle these infections with a natural, powerful alternative. Our research points to just that: antimicrobial peptides (AMPs) found in African catfish.

We're really excited about these peptides because African catfish thrive in pathogen-rich freshwater, naturally producing these robust immune compounds in their skin mucus as a defense. This natural origin makes them highly appealing alternatives to synthetic drugs.

Predicted Safety and Potent Action

One of the most compelling aspects of these AMPs is their predicted safety for mammals. Our initial computer analyses suggest that various catfish AMPs are generally recognized as safe (GRAS). We predict they'll be absorbed in the human intestine without causing liver, brain, or heart toxicity. Furthermore, lab tests on a promising peptide, NACAP-II, confirmed it was non-hemolytic, meaning it didn't damage rabbit red blood cells—a strong indicator of its potential safety for mammalian cells.

Beyond safety, these peptides demonstrate effectiveness against problematic bacteria. One study revealed NACAP-II's strong activity against Extended-Spectrum Beta-Lactamase (ESBL)-producing Escherichia coli—a critical concern for both animal and human health due to its resistance to many common antibiotics. Another peptide, ACAP-IV, also showed antibacterial activity against E. coli and Staphylococcus aureus. We believe these AMPs work by directly disrupting bacterial cell membranes, a mechanism that makes it harder for bacteria to develop resistance compared to how they resist traditional antibiotics.

 

The Path Forward

While these findings are very promising, we want to emphasize that this research is still in its early, laboratory stages. A key challenge we've identified is that some of these peptides have a high molecular weight, which might hinder their absorption if given orally. This means our future work will need to explore advanced delivery methods, potentially involving nanotechnology, or modify the peptides for better absorption and accumulation where they're needed most. Ultimately, more studies are essential to confirm their effectiveness and safety in living animals, such as cattle, and to develop strategies for large-scale production.

 

From Our Lab to Your Farm: Smarter Strategies for Antimicrobial Resistance

As fellow researchers who have been studying antimicrobial resistance (AMR) in California dairy cattle, we want to share some important insights from our recent work. Our studies highlight that while we don't focus on new types of drugs to replace antibiotics, the most critical "alternative" is actually smarter, more targeted management and a deep understanding of pathogen behavior on your farm. This approach aims to reduce the need for antibiotics or minimize the development and spread of resistance when antibiotics are necessary.

Identification, Synthesis, and In Vitro Activities of Antimicrobial Peptide from African Catfish against the Extended-Spectrum Beta-Lactamase (ESBL)-Producing Escherichia coli

 

 

 

Tackling Resistant Salmonella in Cull Cows

First, we've found that Salmonella in cull dairy cows, which contribute to the ground beef supply, often carries resistance to important antimicrobials like tetracyclines, ampicillin, and even ceftriaxone—a drug critical for human medicine. This is definitely a concern for public health. Our research shows that certain cow-level factors, such as prior antimicrobial treatment or culling due to lameness, are associated with higher odds of isolating resistant Salmonella. Conversely, culling a cow due to low milk production was associated with lower odds of resistance.

 

At the herd level, factors like the number of milking cows and monthly culling rates can also influence the presence of resistant Salmonella. This suggests that improving timely culling decisions—removing cows with mild disease problems before they escalate and require extensive antimicrobial therapy—could be an economical way to reduce the selection pressure for AMR. We also need to investigate specific reasons for culling, especially lameness, to understand its link to resistance.

 

Unpacking Mastitis: The Importance of Specificity

Second, regarding mastitis, we've extensively characterized Coagulase-negative Staphylococcus (CNS) species, which are the most common cause of intra-mammary infections (IMI). Historically, these have often been grouped into one class for convenience, or sometimes left untreated. However, our findings reveal a diverse range of different CNS species circulating on US dairies, with Staphylococcus chromogenes and Staphylococcus haemolyticus being the most prevalent. We've seen evidence of persistent subclinical infections, especially with S. chromogenes and S. simulans, where identical strains were isolated from the same udder quarter over consecutive sampling stages.

 

Our message here is that a better understanding of these specific CNS species and their genetic diversity is crucial for improved management and treatment outcomes. Instead of blanket approaches, identifying the predominant species on your farm can guide species-specific control strategies, including targeted treatment decisions to eliminate persistent infections and improvements in milking practices like teat dipping. This precise identification, perhaps through rapid and low-cost diagnostic tests, is a key step to managing mastitis effectively while minimizing broad-spectrum antibiotic use. The low number of clinical mastitis cases from CNS suggests they mainly cause subclinical chronic infections, reinforcing the need for targeted strategies.

 

Calves and Antibiotic Use: A Clear Connection

Finally, our work with pre-weaned dairy calves shows a direct link between antibiotic use and the rise of resistance. We observed that administering ceftiofur as a systemic injection or feeding neomycin-supplemented milk replacer to calves leads to an increased concentration of resistant Enterobacteriaceae in their feces. The peak of ceftiofur resistance occurred around three to four days after treatment, with levels decreasing to below pre-treatment levels by seven to eight days post-treatment. Similarly, neomycin resistance increased during administration and then decreased once the antibiotic was discontinued.

 

This clearly illustrates that AMR is acquired during treatment and can be lost when antimicrobial pressure is removed. This finding strongly supports the importance of prudent antimicrobial stewardship. While antibiotics are sometimes necessary, minimizing their use, especially extra-label use or prophylactic feeding where not strictly justified, can help preserve their effectiveness for when they are truly needed. Initial resistance observed in calves might also be linked to residual antibiotics in colostrum or environmental bacteria ingested by the calves.

 

The Real "Alternatives" are Smart Choices

In summary, the "alternatives" we emphasize aren't necessarily new medications, but rather strategic management decisions. This includes timely culling, species-specific diagnostics for mastitis, and responsible, prudent use of antibiotics in calves, all aimed at reducing the overall selection pressure for antimicrobial resistance on your dairy.

 

What specific management practices are you currently implementing to address antibiotic resistance on your farm?

 

Based on

  1. Molecular epidemiology of coagulase-negative Staphylococcus species isolated at different lactation stages from dairy cattle in the United States
  2. Association between herd management practices and antimicrobial resistance in Salmonella spp. from cull dairy cattle in Central California
  3. Estimating the Rates of Acquisition and loss of Resistance of Enterobacteriaceae to Antimicrobial Drugs in Pre-Weaned Dairy Calves

Our Research: Guiding California Dairies in the Fight Against Antimicrobial Resistance

As California dairy owners and farmers, our research provides crucial insights into managing antimicrobial resistance (AMR) on our operations. We want to emphasize the importance of judicious antibiotic use and strong stewardship practices to maintain herd health and preserve the effectiveness of these vital medicines.

Understanding Resistance Patterns in Your Herd

Our findings reveal important patterns of antimicrobial resistance in common bacteria (Escherichia coli and Enterococcus/Streptococcus spp.) found in the fecal samples of adult dairy cows across California. We observed very low resistance to several drugs commonly given to adult dairy cows, such as cephalosporins and penicillins. This tells us that these particular drugs remain effective when used appropriately.

However, we detected higher rates of AMR to drugs that aren't approved for use in lactating dairy cattle over months of age, including florfenicol, tildipirosin, tilmicosin, and tiamulin. The high resistance to florfenicol, for instance—a drug typically used in beef cattle or non-lactating dairy cattle and calves—might be linked to co-selection with other resistance genes or how resistance spreads between bacteria. These results truly underscore the importance of sticking to labeled drug uses and understanding how resistance can develop even to drugs not directly used in adult lactating cows.

Regional Differences and Management Impacts

We also identified significant differences in AMR across California's dairy regions and seasons. For instance, E. coli isolates from Northern California showed lower resistance to certain antibiotics like ceftiofur compared to the Northern San Joaquin Valley and Greater Southern California. We believe this difference is related to regional variations in management practices and how antibiotics are used, especially for mastitis prevention and treatment. It's noteworthy that some dairies in Northern California didn't use antibiotics for mastitis treatment or prevention, which contributed to lower AMR in those areas. This really suggests that management practices that reduce the overall need for antibiotic treatments can play a significant role in bringing down AMR. The seasonal variations we observed, with higher resistance often seen in winter for E. coli isolates, could be attributed to weather conditions that favor bacterial growth and increase disease, potentially leading to more antibiotic use.

The Dynamics of Antibiotic Treatment and Resistance

Our in-depth study on the dynamics of ceftiofur resistance further highlights the impact of antibiotic treatments. We found that while systemic ceftiofur treatment leads to a rapid increase in resistant Enterobacteriaceae, these levels typically return to pre-treatment baselines within a few days. However, populations of sensitive bacteria can remain suppressed for a longer period. We even observed a cyclical re-emergence of resistance, though at diminishing levels, possibly due to complex interactions within the gut bacteria. These dynamics are critical for us to consider for future AMR surveillance and when designing treatment strategies.

The Path Forward: Stewardship and Smart Choices

In summary, our research emphasizes that while we weren't focused on entirely new non-antibiotic products, the most important "alternative" approach to combating AMR on our dairies is through robust antibiotic stewardship and judicious use. This means making informed decisions in consultation with your veterinarians, selecting antibiotics based on known resistance patterns, adhering strictly to approved drug labels and treatment protocols, and, crucially, implementing best management practices that reduce the incidence of diseases requiring antibiotic intervention in the first place. By doing so, we can help ensure that the antibiotics we rely on for animal health remain effective for generations to come.

 

 

Primary Image
Photo: University of Florida, Institute of Food & Agricultural Sciences
UC Master Gardeners of Santa Clara County: Page

Chayote

Chayote, a member of the cucurbit family (along with cucumber, melons, and squash), is a perennial vine which produces edible vegetables used in cooking and used raw in salads and salsas. Plant seed or sprouted fruit in May to September, possibly April or October.
View Page
Primary Image
A pile of tomatoes in a variety of colors and sizes
UC Master Gardeners of Santa Clara County: Page

Tomatoes

Transplant in May to June, possibly April depending on weather and local conditions. For best results, wait until daytime temperatures are regularly over 70°F. If growing your own seedlings, start the seeds 6 weeks before you want to plant.
View Page
Primary Image
Yellow Onions (Photo: Evett Kilmartin)
UC Master Gardeners of Santa Clara County: Page

Onion Handout

Biennial monocot with prominent bulb, hollow cylindrical leaves, and an odor when bruised. Roots shallow, 12 to 18 inches. Has been used for food since very early times; it was eaten in Egypt before 3000 B.C. Also used as flavoring in nearly every current world culture. Botanically, there are three groups…
View Page
Primary Image
Cucumber tasting at Nine Palms Ranch (Photo: Barbara Williams-Sheng)
UC Master Gardeners of Santa Clara County: Page

Nine Palms Cucumber Trial, 2008

Fourteen varieties of cucumbers were compared for flavor and production. Stallion White and Japanese Climbing ranked top in flavor. Marketmore 76 was top in production.
View Page
Primary Image
Lettuces Black Seeded Simpson and Carmona, by Karen Schaffer
UC Master Gardeners of Santa Clara County: Page

Growing Lettuce Year Round

Lettuce is generally considered a cool weather plant, grown in early spring or fall, although it can be grown in the warm season in most of the SF Bay Area by choosing varieties adapted to warmer weather. Check seed catalogs for summer lettuces.
View Page
Primary Image
Growing Blueberries in SCC 2024
UC Master Gardeners of Santa Clara County: Page

Blueberries

When/how to plant: Late fall through winter, using 2 to 3 year old plants. Blueberries require acidic soil; a soil test will help determine how much to acidify your soil. Be sure the soil has a pH between 4.5 and 6.5. If it’s a clay soil, use organic matter to amend the soil, preferably peat moss. Oregon…
View Page
Primary Image
Five parsnips
UC Master Gardeners of Santa Clara County: Page

Parsnip

Parsnips are a root vegetable in the Apiaceae family, also called Umbelliferae, which also includes carrots. Cultural requirements are very similar.
View Page
Primary Image
Snow pea pods
UC Master Gardeners of Santa Clara County: Page

Peas

Peas are a cool season vegetable in Santa Clara County. There are three types of fresh peas: Shelling peas, where the tough pod is removed before eating. Snow peas, which have edible pods and are harvested flat, while the peas inside are small and immature. Sugar snap peas, which have edible pods and are…
View Page
Primary Image
carrots
UC Master Gardeners of Santa Clara County: Page

Carrots in the Home Garden — 2004

The carrot study consisted of growing 14 varieties of carrots in three different soil textures and compositions. There were several objectives for the study: Determine the best germination method for planting seeds.
View Page
Primary Image
All 11 varieties that produced, on 9/7/07
UC Master Gardeners of Santa Clara County: Page

Long Bean Trial — 2007

We compared 12 varieties of long beans, Vigna unguiculata, to determine which ones have the best production and the best flavor for growing here in Santa Clara County. Chinese Green Noodle was the most productive variety by far and was the favorite in the first tasting for its very tender, mild pods. Chinese…
View Page