Species differences in activation of TRPA1 by resin additive-related chemicals relevant to indoor air quality.

Transient Receptor Potential Ankyrin 1 (TRPA1), which is expressed in the airways, has causative and exacerbating roles in respiratory diseases. TRPA1 is known as a target of sick building syndrome-related air pollutants, such as formaldehyde. Thus, an in vitro TRPA1 activation assay would be useful for predicting the potential risk of air pollution. In this study, we used human TRPA1 (hTRPA1)- and mouse TRPA1 (mTRPA1)-expressing cell lines to measure TRPA1 activation by the emerging indoor air pollutants 2-ethyl-1-hexanol (2-EH), a mixture of 2,2,4-trimethyl-1,3-pentanediol 1- and 3-monoisobutyrate (Texanol), and 2,2,4-trimethyl-1,3-pentanediol diisobutyrate (TXIB). The results indicated that 2-EH activated both hTRPA1 and mTRPA1 in a concentration-dependent manner, whereas TXIB did not activate hTRPA1 or mTRPA1. Texanol also activated hTRPA1 in a concentration-dependent manner. In contrast, a bell-shaped concentration-dependent curve was observed for mouse TRPA1 activation by Texanol, indicating inhibitory effects at a higher concentration range, which was also reported for menthol, a typical TRPA1 modulator. To further elucidate the mechanism underlying the species difference in TRPA1 activation by Texanol, V875G and G878V mutations were introduced into hTRPA1 and mTRPA1, respectively, which were reported to be key mutations for the inhibitory effect of menthol. These mutations switched the inhibitory effects of Texanol; thus, hTRPA1/V875G, but not mTRPA1/G878V, was inhibited at higher concentrations of Texanol. These results indicate that Texanol shares an interaction site with menthol. Overall, these findings suggest that careful interpretation is necessary when extrapolating rodent TRPA1-dependent toxicological effects to humans, especially with respect to the risk assessment of indoor air pollutants.

Global Trends and Hotspots of Transient Receptor Potential Melastatin 8 Research from 2002 to 2021: A Bibliometric Analysis.

Background: Transient receptor potential channels are the major temperature and nociceptive receptors in the human body and transient receptor potential melastatin 8 (TRPM8) is the cold-sensitive and non-selective cation channel. In our study, we performed a bibliometric analysis of TRPM8 from 2002 to 2021 to summarize the current research status and potential research direction in the future. Methods: The TRPM8-related publications were selected from the Web of Science Core Collection SCI-EXPANDED database from 2002 to 2021. The publication details, such as authors, titles, and author keywords, were used for bibliometric analysis and network visualization to present the current state of TRPM8 research. Results: A total of 1035 articles met the inclusion criteria. The number of TRPM8-related articles has grown rapidly over the past two decades. The USA has the largest number of publications, citations, and international collaborations. The TRPM8-related articles are mainly published and cited in neurological journals, such as the Journal of Neuroscience (41 publications and 2171 local citations). Prevarskaya N. has the most publications (26), and Patapoutian A. has been cited the most (1414 local citations). The popular disciplines in TRPM8 research include Neurosciences and Neurology, Pharmacology and Pharmacy, Biochemistry, and Molecular Biology. Research hotspots are mainly TRP channel, calcium, prostate cancer, proliferation, pain, cold, nociception, and inflammation. Conclusion: Our bibliometric analysis demonstrates that the number of TRPM8 studies has increased from 2002 to 2021. The global research trends and hotspots include the activation mechanism of TRPM8 in neurons, the role of TRPM8 in neuronal and non-neuronal diseases, and therapeutic target research.

Species-Specific Activation of Transient Receptor Potential Ankyrin 1 by Phthalic Acid Monoesters.

Phthalic acid (PA) diesters are widely used in consumer products, as plasticizers, and are ubiquitous environmental pollutants. There is a growing concern about their adjuvant effect on allergic diseases. Although its precise mechanism remains unknown, possible involvement of transient receptor potential ankyrin 1 (TRPA1) has been suggested. Hence, in this study, the activation of human and mouse TRPA1s by a series of PA di- and monoesters was investigated using a heterologous expression system in vitro. Consequently, it was found that monoesters activated human TRPA1, where EC50 values were in the order of mono-hexyl > mono-heptyl > mono-n-octyl > mono-2-ethylhexyl > mono-isononyl and mono-isodecyl esters. Significant species differences in TRPA1 activation by PA monoesters were also discovered; PA monoesters activated human TRPA1 but not mouse TRPA1 in a concentration-dependent manner up to 50 µM. These findings suggest that PA esters may exert TRPA1-dependent adverse effects on humans, which have never been demonstrated in experimental animals.

Nociceptive Pathway in the Cockroach Periplaneta americana.

Detecting and avoiding environmental threats such as those with a potential for injury is of crucial importance for an animal's survival. In this work, we examine the nociceptive pathway in an insect, the cockroach Periplaneta americana, from detection of noxious stimuli to nocifensive behavior. We show that noxious stimuli applied to the cuticle of cockroaches evoke responses in sensory axons that are distinct from tactile sensory axons in the sensory afferent nerve. We also reveal differences in the evoked response of post-synaptic projection interneurons in the nerve cord to tactile versus noxious stimuli. Noxious stimuli are encoded in the cockroach nerve cord by fibers of diameter different from that of tactile and wind sensitive fibers with a slower conduction velocity of 2-3 m/s. Furthermore, recording from the neck-connectives show that the nociceptive information reaches the head ganglia. Removing the head ganglia results in a drastic decrease in the nocifensive response indicating that the head ganglia and the nerve cord are both involved in processing noxious stimuli.

Heat and noxious chemical sensor, chicken TRPA1, as a target of bird repellents and identification of its structural determinants by multispecies functional comparison.

Nociceptive receptors enable animals to sense tissue-damaging stimuli, thus playing crucial roles in survival. Due to evolutionary diversification, responses of nociceptive receptors to specific stimuli can vary among species. Multispecies functional comparisons of nociceptive receptors help elucidate their evolutionary process and molecular basis for activation. The transient receptor potential ankyrin 1 (TRPA1) ion channel serves as a nociceptive receptor for chemical and thermal stimuli that is heat-activated in reptiles and frogs while potentially cold-activated in rodents. Here, we characterized channel properties of avian TRPA1 in chicken. Chicken TRPA1 was activated by noxious chemicals that also activate TRPA1 in other vertebrates. Regarding thermal sensitivity, chicken TRPA1 was activated by heat stimulation, but not cold, thus thermal sensitivity of avian TRPA1 does not coincide with rodent TRPA1, although both are homeotherms. Furthermore, in chicken sensory neurons, TRPA1 was highly coexpressed with TRPV1, another nociceptive heat and chemical receptor, similar to mammals and frogs. These results suggest that TRPA1 acted as a noxious chemical and heat receptor, and was coexpressed with TRPV1 in the ancestral terrestrial vertebrate. The acquisition of TRPV1 as a novel heat receptor in the ancestral terrestrial vertebrate is likely to have affected the functional evolution of TRPA1 regarding thermal sensitivity and led to the diversification among diverse vertebrate species. Additionally, we found for the first time that chicken TRPA1 is activated by methyl anthranilate (MA) and its structurally related chemicals used as nonlethal bird repellents. MA-induced responses were abolished by a TRPA1 antagonist in somatosensory neurons, indicating that TRPA1 acts as a MA receptor in chicken. Furthermore, TRPA1 responses to MA varied among five diverse vertebrate species. Utilizing species diversity and mutagenesis experiments, three amino acids were identified as critical residues for MA-induced activation of chicken TRPA1.