Unfolding the codes of short-term feed appetence in farm and companion animals. A comparative oronasal nutrient sensing biology review

Roura, Eugeni; Humphrey, Brooke; Tedó, Gemma; Ipharraguerre, I.R.

doi:10.4141/cjas08014

Cited by 61 publications

(49 citation statements)

References 193 publications

(323 reference statements)

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“…Nevertheless, the T1R family shows a high degree of conservation across vertebrate evolution and its gene repertoire is practically constant in size across most vertebrates, except for the loss of the T1R2 gene in the sweet-insensitive chicken, its pseudogenization in cats (Li et al, 2005), the lack of T1R1 in panda bears (Li et al, 2010), and the absence of all T1R genes in the tongueless western clawed frog. This probably reflects the universal importance of sweet and umami tastes and the relative constancy in number and type of these tastants in most vertebrate species (Shi and Zhang, 2006;Roura et al, 2008). In contrast, orthologous T2R sequences are highly divergent and the T2R gene repertoire varies greatly among species, from only three functional genes in the chicken up to 49 in the frog, indicating that T2R gene families expanded after the separation of each lineage and that high variability exists in the number and type of bitter compounds detected by different species (Shi and Zhang, 2006;Oike et al, 2007).…”

Section: Taste Receptorsmentioning

confidence: 98%

“…Adapted from Marui et al, 1983 (© Springer International Publishing. Reproduced by permission of Springer International Publishing. Permission to reuse must be obtained from the rightsholder) (a, c, d) and broadly tuned L-amino acid sensor that is activated by most of the 20 standard AAs (depending on the species), but not their D-enantiomer forms, with responses being enhanced by purine 5 0 ribonucleotides (Li et al, 2002;Nelson et al, 2002;Roura et al, 2008). Another attractive taste modality, responding to several classes of sweet compounds (in mammals these include natural sugars, artificial sweeteners, D-amino acids, and sweet proteins) as fundamental sources of metabolic energy, is mediated by the T1R2/T1R3 receptor complex (Nelson et al, 2001;Li et al, 2002).…”

Section: Taste Receptorsmentioning

confidence: 99%

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The Physiology of Taste in Fish: Potential Implications for Feeding Stimulation and Gut Chemical Sensing

Morais¹

2016

Reviews in Fisheries Science & Aquaculture

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Recent advances in understanding the molecular basis of taste physiology in fish could open new opportunities to optimize feeding performance in aquaculture. This is particularly relevant at a time when alternative ingredients are being increasingly used, often reducing the digestibility and acceptability of fish diets, even if they are nutritionally balanced. The molecular characterization of fish taste receptors T1Rs and T2Rs revealed common taste discrimination mechanisms among vertebrates. In addition, data so far appear to indicate that taste signaling elements are conserved from fish to mammals. Nevertheless, fundamental differences between ligand specificities of taste receptors, and the presence of multiple T1R2s in fish species, underlines evolutionary adaptations of the T1R2 receptor to sense metabolically important nutrients, with a shift from sugars in mammals to amino acids in teleosts. This fits well with electrophysiological and behavioral studies on ligand specificities and taste preferences in several fish species. On the other hand, synergistic responses between different attractants could result from additive effects of independent receptor sites and response mechanisms, and this knowledge can be of practical interest to specifically design stimulant mixtures to modulate feed intake in aquaculture. Mammalian taste receptors and signaling elements have also been identified in the gastrointestinal tract, where they trigger multiple endocrine and neuronal pathways regulating digestion, nutrient absorption, feeding, and metabolism. Evidence for the existence of these receptors and signaling pathways in fish guts have recently been uncovered, suggesting that sensory properties of the diet might also have functional effects beyond oral taste sensations and palatability.

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Section: Taste Receptorsmentioning

confidence: 98%

Section: Taste Receptorsmentioning

confidence: 99%

The Physiology of Taste in Fish: Potential Implications for Feeding Stimulation and Gut Chemical Sensing

Morais¹

2016

Reviews in Fisheries Science & Aquaculture

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“…Sensory neurons of the trigeminal nerve are part of the pain pathway and are involved in the detection of noxious stimuli such as low or high temperatures and pungent substances (e.g. acids, spices) (Roura et al, 2008). Transmembrane ion channel receptors of the transient receptor potential (TRP) family seem to be responsible for the detection of high (TRPVs) and low (TRPMs) temperatures and pungency or noxious cold (TRPAs) (e.g.…”

mentioning

confidence: 99%

Effect of dose of thymol and supplemental flavours or camphor on palatability in a choice feedings study with piglets

Michiels¹,

Missotten²,

Ovyn³

et al. 2012

CZECH J ANIM SCI

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Thymol’s antimicrobial properties urged researchers to study its effect on animal performance and intestinal health in pigs. However, thymol has the characteristic sharp odor of thyme and a bitter, aromatic, and sometimes burning sensation which may elicit feeding aversions. The objectives in the current study were: (1) to determine the effect of dose of thymol and camphor on palatability and (2) to test the hypothesis that supplemental flavours or camphor, the latter as a known Transient Receptor Potential A1 blocker, could mitigate feed avoidance caused by thymol. Two analogous choice-feeding trials were conducted. Feed intake of the test diet was expressed as proportion of the total intake and tested by means of a one-sample Student’s t-test against a set value of 50%. The preference for feed supplemented with 125, 500, 1250 and 2000 mg/kg thymol was 53.7 ± 6.0% (P > 0.05), 47.5 ± 5.1% (P > 0.05), 36.8 ± 4.9% (P = 0.022), and 3.9 ± 7.9% (P = 0.005) respectively. When feed containing 2000 mg/kg thymol with either flavour A (containing intense sweeteners) or flavour B (containing the same intense sweeteners and a caramel aroma) was opposed against a control diet, the relative intake of the test diets was 19.9 ± 5.8% and 14.0 ± 4.9% (both P < 0.05) respectively. When animals were offered one of these test diets and a reference diet with 2000 mg/kg thymol, animals exhibited a preference for the feed with 2000 mg/kg thymol + flavour A, but not for the feed with 2000 mg/kg thymol + flavour B. Thus, supplemental flavours containing intense sweeteners partially overcame feed avoidance caused by thymol which was less pronounced when the caramel aroma was present. Exposure to camphor (50 and 200 mg/kg) did not improve feed preference for a diet containing 1250 mg/kg thymol. Thymol’s bitter taste might be largely responsible for the recorded feed refusal at high inclusion rates.    

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“…Taste receptors of pigs can differentiate between the five taste sensations of sweet, salty, bitter, sour, and umami (savory) (Bachmanov and Beauchamp 2007;Roura et al 2008), giving them the ability to differentiate molecules within food items. Sweet and umami taste categories often represent sugars and proteins that are known to trigger gustatory preferences in pigs, while bitter compounds, which may signal rotten or rancid food items, are often rejected .…”

Section: Physiological Senses Driving Motivationmentioning

confidence: 99%

Attractants for wild pigs: current use, availability, needs, and future potential

et al. 2017

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Populations of wild pigs (Sus scrofa) are burgeoning around the globe, and they are currently the target of extensive research and management efforts. Wild pigs are a highly successful invasive species that cause extensive damage to agriculture and native plant and animal communities. Lethal control is the most common management strategy used to reduce wild pig populations and their damage, and many lethal strategies rely on luring wild pigs to a specific location. Most commonly, a food commodity such as corn or maize (Zea mays) is used for attracting wild pigs to a site, but baiting with food is sometimes prohibited under wildlife laws, and visitation can be variable due to availability of alternative foods, level of harassment by humans, and acceptance of novel food source, devices, and activity. Wild pigs are highly adaptable with refined senses that enable them to interact with their environment and conspecifics in a complex manner. Wild and domestic pigs share keen senses, though differences exist due to suppressed stimuli, evolutionary gains and losses, or other factors related to needs for survival and fitness. Wild pigs routinely rely on acute olfaction to locate food, detect predators, and communicate with conspecifics. A pig's sense of taste is also considered to be refined and more acute than that of humans. An abundance of evaluations regarding various attractants for wild pigs has been conducted over the last several decades; yet, a scarcity of conclusive results on which attractants to use when and where still exists. As such, we undertook a comprehensive review of available information on potential attractants that could be used to aid management strategies of wild pigs such as hunting/shooting, trapping, pharmaceutical delivery, or density estimation. To complete this review, we assimilated and synthesized the most relevant literature, provide recommendations, and identify attractant evaluation needs for the enhancement of the global management of wild pigs.

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Unfolding the codes of short-term feed appetence in farm and companion animals. A comparative oronasal nutrient sensing biology review

Cited by 61 publications

References 193 publications

The Physiology of Taste in Fish: Potential Implications for Feeding Stimulation and Gut Chemical Sensing

The Physiology of Taste in Fish: Potential Implications for Feeding Stimulation and Gut Chemical Sensing

Effect of dose of thymol and supplemental flavours or camphor on palatability in a choice feedings study with piglets

Attractants for wild pigs: current use, availability, needs, and future potential

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