Evaluating Red Wolf Scat to Deter Coyote Access to Urban Pastureland

Depredation of domestic livestock by wildlife is a leading source of human–wildlife conflict, often requiring intervention at the local level. Historically, these interventions have resulted in the use of lethal methods to remove the offending animal. In response to increased public opposition to lethal control methods, wildlife managers have sought to identify effective nonlethal biological options to mitigate wildlife depredations. In 2018, we tested the concept of a biological deterrent using red wolf (Canis rufus) scat that had historically been spread along fence lines to prevent depredation of lambs (Ovis aries) and kid goats (Capra aegagrus hircus) at the North Carolina State University College of Veterinary Medicine 32-ha Teaching Animal Unit (TAU), North Carolina, USA. To conduct the study, we deployed paired camera traps at 3 locations where we had previously observed coyotes (C. latrans) accessing the TAU. The study was conducted over a 94-day period alternating between no scat and freshly collected scat that was placed every 3 days from adult male red wolves. The study period overlapped lambing and kidding season. In addition to coyotes, the camera traps routinely detected red foxes (Vulpes vulpes) and raccoons (Procyon lotor). The red wolf scat we placed at the access point did not deter any of the mesocarnivores from entering the pasture

Is Open Access to One Health Equivalent Across Human, Environmental, and Animal Health?

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Insights into neutralization of animal viruses gained from study of influenza virus

It has long been known that the binding of antibodies to viruses can result in a loss of infectivity, or neutralization, but little is understood of the mechanism or mechanisms of this process. This is probably because neutralization is a multifactorial phenomenon depending upon the nature of the virus itself, the particular antigenic site involved, the isotype of immunoglobulin and the ratio of virus to immunoglobulin (see below). Thus not only is it likely that neutralization of one virus will differ from another but that changing the circumstances of neutralization can change the mechanism itself. To give coherence to the topic we are concentrating this review on one virus, influenza type A which is itself well studied and reasonably well understood [1–3]. Reviews of the older literature can be found in references 4 to 7

Emerging Viruses in the Felidae: Shifting Paradigms

The domestic cat is afflicted with multiple viruses that serve as powerful models for human disease including cancers, SARS and HIV/AIDS. Cat viruses that cause these diseases have been studied for decades revealing detailed insight concerning transmission, virulence, origins and pathogenesis. Here we review recent genetic advances that have questioned traditional wisdom regarding the origins of virulent Feline infectious peritonitis (FIP) diseases, the pathogenic potential of Feline Immunodeficiency Virus (FIV) in wild non-domestic Felidae species, and the restriction of Feline Leukemia Virus (FeLV) mediated immune impairment to domestic cats rather than other Felidae species. The most recent interpretations indicate important new evolutionary conclusions implicating these deadly infectious agents in domestic and non-domestic felids