Research reveals that a multitude of plants, fungi, protists, bacteria, and viruses possess toxin delivery mechanisms.

These toxin delivery systems are completely similar and often rival the complexity of the venom delivery systems found in animals such as venom snakes, scorpions, and spiders.

Toxologists and other biologists have studied toxic organisms and their secretions for centuries.

Their interest is largely due to the frequently and severe consequences of human exposure.

Humans also take advantage of the potential of toxins to explore the treatment of human illnesses and illnesses.

In doing so, scientists have leveraged countless natural experiments involving interactions between toxins and target cells and tissues.

The classification of biological toxins, in particular the distinction between venom and venom, is characterized by a colorful and sometimes controversial history.

Nevertheless, with the views of consensus and the introduction of the third phase, toxic biological secretions can be divided into three groups based on their mode of delivery to other organisms.

These include poisons that are transmitted passively without a delivery mechanism (intake, inhalation, or absorption of the entire surface). Toxicity was fed to the body surface without any associated wounds (e.g., spitting, spraying, or smearing). Poison (e.g., sting, biting) carried to internal tissues through the formation of wounds.

The organisms that possess these toxins are called toxic, toxins, and/or toxic, respectively.

These distinctions provide a meaningful framework for studying the evolution of these toxins, including biochemical structures. Related structures for synthesis, storage and application. And their functional role.

Discourses on poison and poisonous animals focus exclusively on animals.

The use of venom has evolved independently in at least 104 strains within at least eight animal phylums, which emphasizes the pronounced adaptability of the trait.

But do poison distribution systems exist in other entities?

“Our findings show that we rely on poisons to solve problems such as predation, defense, and competition.

“The venomous animals have long been trying to understand the fatal secretions and the properties associated with their use, but have long fascinated biologists who have also contributed to many life-saving treatments.”

“To date, our understanding of venoms, poison delivery systems, and poisonous organisms is entirely based on animals. This represents only a small fraction of organisms that can search for meaningful tools and treatments.”

According to the study, plants inject toxins into animals through spines, thorns and stinging hairs, some of which exist with stinging ants by providing living space and food in exchange for protection.

Even bacteria and viruses have evolved mechanisms such as secretory and contractile injection systems to introduce toxins to the target through host cells and wounds.

“I have a long history of studying venom in rattlesnakes, and I began exploring the broader definition of venom over a decade ago, teaching special courses on the biology of venom,” Professor Hayes said.

“My team and I were working on a paper to define what Venom really is, so we came across non-animal examples and decided to dig deeper to identify many of the possible overlooked examples.”

This research paves the way for new discoveries, and the authors hope that experts and scientists will encourage collaboration across disciplines and explore further how Venom has evolved across diverse organisms.

“We only hurt the surface in understanding evolutionary pathways of venom dissemination, including gene duplication, co-configuration of existing genes, and natural selection,” concluded Professor Hayes.

study Published in the journal toxin.

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William K. Hayes et al. 2025. After all, it’s a small world. It is a prominent yet overlooked diversity of poisonous organisms with candidates for plants, fungi, protists, bacteria and viruses. toxin 17(3):99; doi:10.3390/toxin 17030099