I've got you under my skin: inflammatory response to elephant seal's lice

Leonardi, María Soledad; Krmpotic, Cecilia Mariana; Barbeito, Claudio Gustavo; Soto, Florencia; Loza, Cleopatra Mara; Vera, R.; Negrete, Javier

doi:10.1111/mve.12538

Cited by 3 publications

(4 citation statements)

References 17 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Probably, these legs play a sensory role in insects where, according to the literature, eyes are absent [4,19,20]. However, the first pair of legs of L. macrorhini is robust, and the tarsal claws are modified into well-developed hooks [21]. It has been suggested that this species utilizes its claws to perforate the skin and dig into the host epidermis, in order to stay attached during elephant seal molting [21].…”

Section: Morphological Adaptationsmentioning

confidence: 99%

“…However, the first pair of legs of L. macrorhini is robust, and the tarsal claws are modified into well-developed hooks [21]. It has been suggested that this species utilizes its claws to perforate the skin and dig into the host epidermis, in order to stay attached during elephant seal molting [21]. Regarding the absence of eyes, a series of studies in different species is required to determine the presence of specific structures or pigments capable of detecting light.…”

Section: Morphological Adaptationsmentioning

confidence: 99%

“…The incapacity of N1 to survive underwater was suggested to be associated with the absence of abdominal scales [20,22,27], which are abundantly present in the tolerant instars. When seal lice emerge in seawater, they experience a reduction in oxygen availability, and a rapid and large drop in temperature (20)(21)(22)(23)(24)(25) °C difference between air and water in summer), as well as an increase in hydrostatic pressure. It has been reported that contact with seawater triggers reflex immobility (akinesis) in A. microchir and in L. macrorhini, which is immediate (in seconds) in the former and requires several minutes in the latter [23,30].…”

Section: Tolerance To Immersionmentioning

confidence: 99%

See 2 more Smart Citations

How Did Seal Lice Turn into the Only Truly Marine Insects?

Leonardi

Crespo

Soto

et al. 2021

Insects

View full text Add to dashboard Cite

Insects are the most evolutionarily and ecologically successful group of living animals, being present in almost all possible mainland habitats; however, they are virtually absent in the ocean, which constitutes more than 99% of the Earth’s biosphere. Only a few insect species can be found in the sea but they remain at the surface, in salt marshes, estuaries, or shallow waters. Remarkably, a group of 13 species manages to endure long immersion periods in the open sea, as well as deep dives, i.e., seal lice. Sucking lice (Phthiraptera: Anoplura) are ectoparasites of mammals, living while attached to the hosts’ skin, into their fur, or among their hairs. Among them, the family Echinophthiriidae is peculiar because it infests amphibious hosts, such as pinnipeds and otters, who make deep dives and spend from weeks to months in the open sea. During the evolutionary transition of pinnipeds from land to the ocean, echinophthiriid lice had to manage the gradual change to an amphibian lifestyle along with their hosts, some of which may spend more than 80% of the time submerged and performing extreme dives, some beyond 2000 m under the surface. These obligate and permanent ectoparasites have adapted to cope with hypoxia, high salinity, low temperature, and, in particular, conditions of huge hydrostatic pressures. We will discuss some of these adaptations allowing seal lice to cope with their hosts’ amphibious habits and how they can help us understand why insects are so rare in the ocean.

show abstract

Section: Morphological Adaptationsmentioning

confidence: 99%

Section: Morphological Adaptationsmentioning

confidence: 99%

Section: Tolerance To Immersionmentioning

confidence: 99%

See 1 more Smart Citation

How Did Seal Lice Turn into the Only Truly Marine Insects?

Leonardi

Crespo

Soto

et al. 2021

Insects

View full text Add to dashboard Cite

show abstract

“…The seal louse coevolved with terrestrial ancestors of seals from land into the marine environment millions of years ago 9 , 17 – 19 , hence the seal louse plays an important role as potential vector for a variety of infectious pathogens such as viruses and bacteria 20 , 21 and heartworms ( Acanthocheilonema spirocauda ) 11 , 22 – 24 . Because prevalence and intensity of ectoparasite infection are important biological indicators for predicting host health and inferring evolution 11 , 25 , 26 , precise information on seal louse infection parameters in vulnerable aquatic wildlife are crucial and of parasitological and veterinary relevance 24 , 27 .The seal louse developed biomechanical and physical adaptations for attachment and respiration in the marine environment 15 , 28 , 29 to sustain high pressure, drag forces, and hypoxemia 30 . The sampling of live lice is relevant for experiments on respiration, to investigate feeding and attachment adaptations 29 and reproductive processes in vitro.…”

Section: Introductionmentioning

confidence: 99%

High prevalence and low intensity of Echinophthirius horridus infection in seals revealed by high effort sampling

Herzog,

Siebert,

Lehnert

2024

Sci Rep

View full text Add to dashboard Cite

Seal lice (Echinophthirius horridus) are bloodsucking ectoparasites of phocid seals and vectors of pathogens like the heartworm, Acanthocheilonema spirocauda. Grey and harbour seal populations are recovering in German waters and wildlife health surveillance is crucial for wildlife conservation. A new, high effort sampling protocol for seal lice was applied for grey and harbour seals along the German North- and Baltic Sea coast. Freshly dead seals were systematically sampled within a health monitoring of stranded seals over 12 months. Prevalence, intensity and distribution patterns of seal lice were analysed. 58% of harbour seals (n = 71) and 70% of grey seals (n = 10) were infected with seal lice. A majority of harbour seals displayed mild levels of infection, while three were moderately and two were severely infected. The head was the preferred predilection site, indicating that E. horridus prefers body areas with frequent access to atmospheric oxygen. Nits and different developmental stages were recorded in all age classes in grey and harbour seals in all seasons. For the first time, copulating specimens of E. horridus were recorded on a dead harbour seal, highlighting that E. horridus reproduces throughout the year on seals of all age classes in German waters.

show abstract