Structural and functional analysis of the ligand binding pocket of bitter taste receptor T2R4

Billakanti, Rohini

05 August 2014

Bitter taste is one of the five basic taste modalities, and is mediated by 25 bitter taste receptors (T2Rs) in humans. How these few receptors recognize a wide range of structurally diverse bitter compounds is not known. To address this question, structural and functional studies on T2Rs are necessary. Quinine is a natural alkaloid and one of the most intense bitter tasting compounds. Previously it was shown that quinine activates T2R4, however, whether T2R4 has only one binding site for quinine, and the amino acids on the receptor involved in binding to quinine remain to be determined. In this study, the ligand binding pocket on T2R4 for quinine was characterized using a combination of approaches. These included molecular model guided site-directed mutagenesis, characterization of the expression of the mutants by flow cytometry, and functional characterization by cell based calcium imaging. Twelve mutations were made in T2R4 and their expression and function were characterized. Results show that the ligand binding pocket of T2R4 for quinine is situated on the extracellular side, and is formed by the residues present on the transmembrane regions TM3, TM4, and extracellular loop regions ECL2 and TM6-ECL3-TM7 interface. Further, this study identified the following amino acids : A90, F91, Y155 N173, T174, Y258 and K270 to play an important role in quinine binding to T2R4. The detailed study of residues interacting with ligand will help in understanding how various ligands interact with T2Rs, and facilitate the pharmacological characterization of potent antagonists or bitter taste blockers. The characterization of novel ligands, including bitter taste blockers will help in dissecting the signaling mechanism(s) of T2Rs, and help in the development of novel therapeutic tools for the food and drug industry.

Bitter taste receptor

Structural and functional analysis

Morphological and functional characterization of the neurotransmitter GABA in adult rat taste buds

Cao, Yu

13 March 2006

No description available.

Biology, Neuroscience

taste receptor cells

GABA

paracrine

co-transmission

modulation

Functional identification and initial characterization of a fish co-receptor involved in aversive signaling

Cohen, Staci Padove

18 May 2009

Chemoreception plays an important role in predator-prey interactions and feeding dynamics. While the chemoreception of attractant or pleasant tasting compounds has been well studied, aversive chemoreceptive signaling has been difficult to investigate behaviorally in an ecological context because these interactions are species- and context- specific and deterrent compounds vary among prey. Using the coral reef system, this thesis explores on a molecular level the deterrent mechanism underlying detection by fish predators of an aversive compound, in order to gain a greater understanding of predator-prey interactions in this community. Like other organisms that are sessile or slow-moving, marine sponges have special mechanisms for defense from predation, commonly containing aversive-tasting compounds that defend these organisms from predation. To this end, we sought to identify and characterize a fish chemoreceptor that detects one or more of these compounds. We isolated a single cDNA clone encoding RAMP-like triterpene glycoside receptor (RL-TGR), a novel co-receptor involved in the signaling of triterpene glycosides. This co-receptor appears to be structurally and functionally related to receptor activity-modifying proteins (RAMPs), a family of co-receptors that physically associate with and modify the activity of G protein-coupled receptors (GPCRs). Expression in Xenopus oocytes showed that it responds to triterpene glycosides in a receptor-mediated manner and requires co-expression of a GPCR to enable signaling in oocytes; both of these receptors may be components of a larger signaling complex. A 40 bp portion of the gene is conserved across multiple fish species, but is not found in any other organism with a sequenced genome, suggesting that the expression of this receptor is limited to fish species. RL-TGR is the first identified gene encoding a co-receptor that responds to a chemical defense. This finding may lead the way for the identification of many other receptors that mediate chemical defense signaling in both marine and terrestrial environments, as this protein has the potential to represent the first of an entire family of co-receptors that respond to aversive compounds.

Chemical defense

Chemical ecology

Chemoreception

Taste receptor

Fish

Marine sponges

Chemical senses

Chemoreceptors

Taste buds

Predation (Biology)

Triterpenoid saponins

Miraculinas de citrus sinensis: modelagem molecular de estruturas e predição funcional / Miraculins of citrus sinensis: molecular modeling of structures and functional prediction

CAETANO, Érica Renata Nogueira Sá

12 July 2018

Submitted by Rosana Amâncio (rosana.amancio@ufcg.edu.br) on 2018-07-12T22:11:47Z No. of bitstreams: 1 ERICA RENATA NOGUEIRA SÁ CAETANO - DISSERTAÇÃO PPGCNBio 2016..pdf: 2506925 bytes, checksum: 2aee1b855d59914fe68902bb6ec5b3fe (MD5) / Made available in DSpace on 2018-07-12T22:11:47Z (GMT). No. of bitstreams: 1 ERICA RENATA NOGUEIRA SÁ CAETANO - DISSERTAÇÃO PPGCNBio 2016..pdf: 2506925 bytes, checksum: 2aee1b855d59914fe68902bb6ec5b3fe (MD5) Previous issue date: 2016-07-14 / CNPq / Miraculina é uma glicoproteína que possui uma incrível propriedade de converter o sabor amargo em doce. Como a miraculina não apresenta sabor algum e tem um baixo teor calórico, esta proteína pode ser usada como adoçantes direcionados para pacientes com doenças relacionadas ao consumo excessivo de açúcar. Estudos comprovaram que membros da família de proteínas miraculinas também possuem atividade de inibidor de tripsina do tipo Kunitz, atuando como agentes naturais de defesa da planta contra pragas e predadores. Diante disso, proteínas do tipo miraculina são de grande relevância para aplicações biotecnológicas. Esse estudo teve como objetivo geral realizar a caracterização estrutural e funcional comparativa de duas miraculinas de Citrus sinensis, por meio de modelagem e docking molecular. Modelos 3D foram gerados e validados para as miraculinas CsMir1 e CsMir4, tripsina de Acryrthosiphon pisum e para os receptores de sabor doce mT1R2 e T1R3 de Mus musculus. Modelos homodiméricos foram gerados para CsMir1 e CsMir4 e modelo heterodimérico foi gerado para mT1R2-T1R3. Estudos da atividade de inibidor de tripsina foram feitos para CsMir1 e CsMir4 por interação com tripsina. Para analisar a atividade de modificação de sabor doce, foi realizada a interação das miraculinas com o receptor mT1R2-T1R3. Como resultados, os modelos dos monômeros e dímeros criados foram considerados bons modelos, válidos e confiáveis, com representações muito próximas das estruturas nativas dessas proteínas. A miraculina CsMir1, na forma monomérica ligou-se a tripsina de A. pisum e na sua forma dimérica ligou-se ao receptor heterodimérico mT1R2-T1R3 através do domínio ATD da subunidade T1R2, entretanto o potencial para as atividades de inibição de proteases e de indução ou inibição a modificação de sabor amargo/azedo em doce é menor do que para a CsMir4. A miraculina CsMir4, na sua forma monomérica ligou-se a tripsina de A. pisum, possivelmente apresentando atividade de inibição de proteases. CsMir4, na sua forma dimérica, ligou-se ao receptor heterodimérico mT1R2-T1R3, através do domínio ATD da subunidade T1R2, potencialmente apresentando atividade de indução ou inibição a modificação de sabor amargo/azedo em doce em M. musculus. / Miraculins are glycoproteins that displays a remarkable property in bitter to sweet taste conversion. As miraculin does not have any taste and has a low calorie, this protein can be used as sweeteners targeted to patients with diseases related to excessive sugar consumption. Studies have shown that members of miraculins protein family also display inhibitor activity against the Kunitz trypsin, acting as natural agents of plant defense against pests and predators. In this context, miraculin proteins are of great relevance for biotechnological applications. The aim of this research was to characterize structurally and functionally two miraculins of Citrus sinensis using in silico tools. Tridimensional models were built and validated for CsMir1 and CsMir4 miraculins, Acryrthosiphon pisum trypsin and for Mus musculus mT1R2-T1R3 receptor. Homodimeric and hetrodimeric models were generated for miraculins (CsMir1, CsMir4) and mT1R2-T1R3, respectively. Molecular docking simulations were performed to investigate the trypsin inhibitory activity and taste conversion activity of CsMir1 and CsMir4. The results showed that the predicted models were reliable and presented good quality parameters. The monomeric CsMir1 miraculin bound to A. pisum trypsin, while its dimeric form bound to ATD domain of the mT1R2-T1R3, although its potential as trypsin inhibitor and bitter/sweet taste modifier were minor than that presented by its homologous CsMir4. The dimeric form of CsMir4 bound to mT1R2-T1R3 receptor in the ATD domain, which strongly suggests bitter/sweet taste modifier activity in M. musculus.

Ciências Biológicas

Kunitz Trypsin inhibitor

homology modeling

Docking

sweet taste receptor

Modelagem por homologia

Inibidor de tripsina Kunitz

Receptor de sabor doce

The relationship between single nucleotide polymorphism in taste receptor genes and body composition, energy intake, and macronutrient consumption in young adults​

Sunbul, Manal Abbas

11 May 2022

Genetic variations in taste receptor genes play a notable role in human taste perception and food preferences and intake, which may affect nutritional and health status. Understanding how genetic variations in taste receptor genes influence food perception, preferences, and intake can play an important role in designing effective interventions to improve the quality of peoples' nutrition and minimize the risk of diet-related diseases such as obesity. The objective of this study was to investigate single nucleotide polymorphisms (SNPs) of umami taste receptor gene TAS1R1 and GRM4 and sweet taste receptor gene TAS1R3 and percentage of body fat mass (BF%) among young adults. 833 young adults aged 18-31 years old were enrolled in a cross-sectional study. Umami and sweet taste receptor genotypes were determined and analyzed. A strong association was observed between the allele frequencies of sweet taste receptor gene TAS1R3 for SNPs rs307355 and rs35744813 and BMI, and between the same SNPs rs307355 and rs35744813 and BF%. In addition, the allele frequencies of SNP rs2499729 were significantly related to the likelihood of having obesity based on BMI classification. However, there was no association between the allele frequencies of the SNPs of the umami taste receptor genes; TAS1R1 for rs34160967 and BMI or BF%. The results of this study also indicated association in total energy intake and the percentage of energy from carbohydrates, protein, and fat intake between the alleles of the sweet receptor gene TAS1R3 for rs307355 and 35744813. Furthermore, a notable association was also detected in the percentage of energy from fat intake among the alleles of the umami receptors gene TAS1R1 rs34160967, and a significant relation in the percentage of energy from carbohydrates and protein intake between the different genotype polymorphisms of the umami receptor GRM4 gene for rs2499729.

Human and Clinical Nutrition

Seleção de aptâmeros que se ligam ao receptor humano para o gosto doce / Screening for aptamers that bind to the human sweet taste receptor (hT1R2/hT1R3)

Almeida, Tiago Jonas de

13 May 2014

Foi demonstrado que o gosto doce é transduzido por receptores acoplados a proteína G classe III (GPCRs), T1R2 e T1R3. Essas proteínas exibem longas extremidades amino-terminais que formam um domínio de ligação globular extracelular. Elas são expressas em células associadas ao gosto (células epiteliais que constituem os botões gustativos nas papilas gustativas), que respondem a moléculas associadas ao gosto doce. Quando T1R2 e T1R3 são co-expressas em células heterólogas, elas respondem, como heterômeros, a uma série de açúcares, alguns D-aminoácidos, edulcorantes artificiais e proteínas doces. Foi também demonstrado que o receptor humano T1R2/T1R3 para o gosto doce apresenta múltiplos sítios de ligação. Para melhor compreender a estrutura desse receptor e responder à pergunta de como um único quimiorreceptor pode ser responsivo a uma variedade de ligantes, foi utilizada a abordagem denominada evolução sistemática de ligantes por enriquecimento exponencial (SELEX) para isolar, a partir de uma biblioteca combinatória de oligonucleotídeos, aptâmeros de RNA resistentes a nuclease que se ligam ao receptor humano para o gosto doce com alta afinidade. Após um enriquecimento de doze ciclos do pool original de RNA contendo em torno de 1013 sequências diferentes (contra preparações de membrana de células HEK293T que expressam hT1R2/hT1R3) e outros ciclos de contrasseleção negativa (para eliminar moléculas de RNA que se ligam de forma inespecífica à membrana de nitrocelulose e a outras proteínas diferentes do alvo, ou seja, proteínas de membrana de células HEK293T selvagem), realizou-se a transcrição reversa do RNA seguida de amplificação por PCR e sequenciamento. Aptâmeros do ciclo 12 com sequências consenso foram selecionados, e a ligação de alguns deles com hT1R2/hT1R3 foi então avaliada. Cinco desses aptâmeros mostram claramente uma maior afinidade por células HEK293T que expressam hT1R2/hT1R3. Como segunda parte desta tese, estudamos outro receptor, denominado CD36, que, como o receptor T1R2/T1R3, é expresso na língua. Estudos indicam que ele age como receptor gustativo de gordura. Neste trabalho, verificamos que essa proteína é expressa em uma subpopulação de neurônios olfatórios presentes no epitélio olfatório, indicando que ela pode ter também uma função olfatória, ainda não caracterizada. / It has been shown that sweet taste is transduced by the Class III G Protein-Coupled Receptors (GPCRs) T1R2 and T1R3, which show long N-termini that form a globular extracellular ligand-binding domain. These receptors are expressed in the taste cells (epithelial cells that constitute the taste buds in taste papillae) that respond to sweet tastants, and when T1R2 and T1R3 are coexpressed in heterologous cells, they respond, as heteromers, to a series of sugars, some D-amino acids, artificial sweeteners and sweet proteins. It has also been demonstrated that the sweet taste receptor has multiple binding sites. In order to better understand the structure of this receptor and answer the question of how a single chemoreceptor can respond to a variety of ligands, we used the combinatorial oligonucleotide library screening approach, denominated Systematic Evolution of Ligands by Exponential Enrichment (SELEX), to isolate nuclease-resistant RNA aptamers that bind to the human sweet taste receptor with high affinity. Following a twelve round enrichment of the previous random RNA pool containing around 1013 different sequences (against membrane preparations of hT1R2/hT1R3-expressing HEK293T cells) and negative counterselection cycles (to eliminate RNA molecules that bind nonspecifically to the nitrocellulose membrane and to proteins other than the target, that is, HEK293T cells membrane proteins), the RNA was reverse-transcribed for DNA sequencing. Aptamers from cycle 12 with consensus sequences were selected, and the binding of some of them to the human sweet taste receptor was then evaluated. Five out of the aptamers clearly show greater affinity for hT1R2/hT1R3-expressing HEK293T cells than for hT1R2/hT1R3-non-expressing HEK293T cells. In this thesis we have also analyzed another receptor, denominated CD36, which is also expressed in the tongue. Studies indicate that it acts as a receptor for fat. In this work, we found that CD36 is expressed in a subset of the olfactory neurons localized in the olfactory epithelium, indicating that it may also have an as yet uncharacterized olfactory function.

Ácidos nucléicos

Aptâmeros

Aptamers

CD36

CD36

HT1R2/hT1R3

HT1R2/hT1R3

Nucleic acids

Receptor para o gosto doce

SELEX

SELEX

Sweet taste receptor

Seleção de aptâmeros que se ligam ao receptor humano para o gosto doce / Screening for aptamers that bind to the human sweet taste receptor (hT1R2/hT1R3)

Tiago Jonas de Almeida

13 May 2014

Foi demonstrado que o gosto doce é transduzido por receptores acoplados a proteína G classe III (GPCRs), T1R2 e T1R3. Essas proteínas exibem longas extremidades amino-terminais que formam um domínio de ligação globular extracelular. Elas são expressas em células associadas ao gosto (células epiteliais que constituem os botões gustativos nas papilas gustativas), que respondem a moléculas associadas ao gosto doce. Quando T1R2 e T1R3 são co-expressas em células heterólogas, elas respondem, como heterômeros, a uma série de açúcares, alguns D-aminoácidos, edulcorantes artificiais e proteínas doces. Foi também demonstrado que o receptor humano T1R2/T1R3 para o gosto doce apresenta múltiplos sítios de ligação. Para melhor compreender a estrutura desse receptor e responder à pergunta de como um único quimiorreceptor pode ser responsivo a uma variedade de ligantes, foi utilizada a abordagem denominada evolução sistemática de ligantes por enriquecimento exponencial (SELEX) para isolar, a partir de uma biblioteca combinatória de oligonucleotídeos, aptâmeros de RNA resistentes a nuclease que se ligam ao receptor humano para o gosto doce com alta afinidade. Após um enriquecimento de doze ciclos do pool original de RNA contendo em torno de 1013 sequências diferentes (contra preparações de membrana de células HEK293T que expressam hT1R2/hT1R3) e outros ciclos de contrasseleção negativa (para eliminar moléculas de RNA que se ligam de forma inespecífica à membrana de nitrocelulose e a outras proteínas diferentes do alvo, ou seja, proteínas de membrana de células HEK293T selvagem), realizou-se a transcrição reversa do RNA seguida de amplificação por PCR e sequenciamento. Aptâmeros do ciclo 12 com sequências consenso foram selecionados, e a ligação de alguns deles com hT1R2/hT1R3 foi então avaliada. Cinco desses aptâmeros mostram claramente uma maior afinidade por células HEK293T que expressam hT1R2/hT1R3. Como segunda parte desta tese, estudamos outro receptor, denominado CD36, que, como o receptor T1R2/T1R3, é expresso na língua. Estudos indicam que ele age como receptor gustativo de gordura. Neste trabalho, verificamos que essa proteína é expressa em uma subpopulação de neurônios olfatórios presentes no epitélio olfatório, indicando que ela pode ter também uma função olfatória, ainda não caracterizada. / It has been shown that sweet taste is transduced by the Class III G Protein-Coupled Receptors (GPCRs) T1R2 and T1R3, which show long N-termini that form a globular extracellular ligand-binding domain. These receptors are expressed in the taste cells (epithelial cells that constitute the taste buds in taste papillae) that respond to sweet tastants, and when T1R2 and T1R3 are coexpressed in heterologous cells, they respond, as heteromers, to a series of sugars, some D-amino acids, artificial sweeteners and sweet proteins. It has also been demonstrated that the sweet taste receptor has multiple binding sites. In order to better understand the structure of this receptor and answer the question of how a single chemoreceptor can respond to a variety of ligands, we used the combinatorial oligonucleotide library screening approach, denominated Systematic Evolution of Ligands by Exponential Enrichment (SELEX), to isolate nuclease-resistant RNA aptamers that bind to the human sweet taste receptor with high affinity. Following a twelve round enrichment of the previous random RNA pool containing around 1013 different sequences (against membrane preparations of hT1R2/hT1R3-expressing HEK293T cells) and negative counterselection cycles (to eliminate RNA molecules that bind nonspecifically to the nitrocellulose membrane and to proteins other than the target, that is, HEK293T cells membrane proteins), the RNA was reverse-transcribed for DNA sequencing. Aptamers from cycle 12 with consensus sequences were selected, and the binding of some of them to the human sweet taste receptor was then evaluated. Five out of the aptamers clearly show greater affinity for hT1R2/hT1R3-expressing HEK293T cells than for hT1R2/hT1R3-non-expressing HEK293T cells. In this thesis we have also analyzed another receptor, denominated CD36, which is also expressed in the tongue. Studies indicate that it acts as a receptor for fat. In this work, we found that CD36 is expressed in a subset of the olfactory neurons localized in the olfactory epithelium, indicating that it may also have an as yet uncharacterized olfactory function.

Ácidos nucléicos

Aptâmeros

CD36

HT1R2/hT1R3

Receptor para o gosto doce

SELEX

Aptamers

CD36

HT1R2/hT1R3

Nucleic acids

SELEX

Sweet taste receptor

Influência de polimorfismos nos genes dos receptores de sabor gorduroso, doce e amargo no consumo alimentar e no perfil metabólico de crianças e adolescentes obesos / Influence of polymorphisms in fat, sweet and bitter taste receptors genes in food intake and metabolic profile in obese children and adolescents

Pioltine, Marina Brosso

10 December 2015

INTRODUÇÃO: A obesidade infantil é um importante problema de saúde pública e apresenta impacto direto na qualidade de vida das crianças e adolescentes, bem como no desenvolvimento futuro de doenças crônicas. O padrão alimentar rico em gordura e açúcar, e com baixo aporte de fibra dietética, vitaminas e minerais é reconhecido como fator de risco para o surgimento da obesidade, no entanto os fatores que contribuem para a preferência por alimentos ricos nestes nutrientes não são bem estabelecidos. O sabor dos alimentos é reconhecido como um importante preditor das escolhas alimentares, e os polimorfismos nos genes que codificam os receptores do sabor podem explicar a variabilidade da preferência e consumo alimentar na população. OBJETIVO: Avaliar a influência de polimorfismos de genes de receptores de sabor gorduroso (CD36), doce (TAS1R2) e amargo (TAS2R38) no consumo alimentar e no perfil metabólico de crianças e adolescentes obesos. MÉTODOS: Estudo transversal com 668 crianças e adolescentes obesos e um grupo controle de 135 crianças eutróficas, de ambos os gêneros. Foi realizado o estudo molecular dos polimorfismos de nucleotídeo único (SNPs) rs1761667 e rs1527483 do CD36, rs9701796 e rs35874116 do TAS1R2, e rs1726866 e rs713598 do TAS2R38, bem como análise do consumo alimentar e perfil metabólico. RESULTADOS: Em relação ao CD36, o alelo A do rs1761667 relacionou-se com menor consumo de lipídios totais, gorduras poli e monoinsaturadas, consumo de alimentos de sabor gorduroso, ingestão de óleos vegetais e açúcares totais em obesos. O alelo A do rs1527483 associou-se com menor percentil de pressão arterial diastólica, menor massa gorda e maior massa livre de gordura em obesos. Quanto ao gene TAS1R2, a variante rs9701796 teve maior risco metabólico segundo a razão circunferência da cintura-estatura (RCE), bem como relação com maior consumo de achocolatado em pó em obesos. Já a variante rs35874116 mostrou relação com a menor ingestão de fibras dietéticas em obesos. No TAS2R38, o alelo G do rs1726866 foi associado com menor consumo de gorduras monoinsaturadas e maior consumo de açúcares totais, em obesos. O alelo G do rs713598 mostrou relação com maior consumo de carboidratos, consumo de alimentos de sabor doce, refrigerantes e menor ingestão de fibras pelos indivíduos eutróficos. CONCLUSÃO: Não houve relação entre genótipos e risco de obesidade. Os achados mostram a associação entre polimorfismos dos genes de receptores de sabor com o consumo alimentar, indicando diferenças entre obesos e magros, e alelos de proteção e de risco cardiometabólico, respectivamente dos genes CD36 e TAS1R2 / BACKGROUND: Childhood obesity is a major public health problem and it has a direct impact on the quality of life of children and adolescents, as well as the future risk for development of chronic diseases. The dietary pattern rich in fats and sugars associated to the low intake of dietary fibers, vitamins and minerals is widespread for the rise of obesity. However the factors that contribute to the preference for foods rich in these nutrients are not well established. Taste is recognized as an important predictor of food choices, and polymorphisms in genes encoding its receptors may explain the variability of taste preference and food intake on population. OBJECTIVE: To evaluate the influence of polymorphisms of fat (CD36), sweet (TAS1R2) and bitter (TAS2R38) taste receptor genes in diet and metabolic profile in obese children and adolescents. METHODS: Cross-sectional study with 668 obese children and adolescents and a control group of 135 normal-weight children. The molecular study was made for single nucleotide polymorphisms (SNPs) rs1761667 and rs1527483 of CD36, rs9701796 and rs35874116 of TAS1R2, rs1726866 and rs713598 of TAS2R38, and the analysis of food intake and metabolic profile. RESULTS: In relation to CD36, the A allele of rs1761667 was associated with lower intake of total fat, poly and monounsaturated fats, consumption of fatty flavor food, intake of vegetable oils and total sugars in obese. The A allele of rs1527483 was associated with lower percentile of diastolic blood pressure, lower fat mass and increased fat-free mass in obese. Regarding TAS1R2 gene, the variant rs9701796 was associated to increased metabolic risk according to waist-height ratio, as well as with higher consumption of chocolate powder in obese. The variant rs35874116 showed a lower intake of dietary fiber. In TAS2R38, the G allele of rs1726866 was associated with a lower intake of monounsaturated fat and a higher intake of total sugars in obese. The G allele of rs713598 was related to the higher carbohydrate intake, consumption of sweet tasting food, soda drinks and less fiber intake by normal weight children. CONCLUSION: There was no relationship between genotypes and risk of obesity. The findings show the association between polymorphisms of taste receptor genes with dietary intake, indicating differences between obese and lean children, as well as the protective and risk alleles for cardiometabolic risk in CD36 and TAS1R2, respectively

Adolescent

Adolescente

Amargo

Bitter

CD36 protein

Child

Comportamento alimentar

Consumo de alimentos

Criança

Doces

Fat taste

Feeding behavior

Food consumption

Food habits

Genótipo

Genotype

Hábitos alimentares

Nutrientes/metabolismo

Nutrients/metabolism

Obesidade pediátrica/genética

Obesidade/metabolismo

Obesity/metabolism

Paladar

Pediatric obesity/genetics

Percepção gustatória

Polimorfismo de nucleotídeo único

Polymorphism single nucleotide

Proteína CD36

Proteína humana TAS1R2

Proteína humana TAS2R38

Receptores de sabor

Sabor gorduroso

Sweet

TAS1R2 protein human

TAS2R38 protein human

Taste

Taste perception

Taste receptor

Influência de polimorfismos nos genes dos receptores de sabor gorduroso, doce e amargo no consumo alimentar e no perfil metabólico de crianças e adolescentes obesos / Influence of polymorphisms in fat, sweet and bitter taste receptors genes in food intake and metabolic profile in obese children and adolescents

Marina Brosso Pioltine

10 December 2015

INTRODUÇÃO: A obesidade infantil é um importante problema de saúde pública e apresenta impacto direto na qualidade de vida das crianças e adolescentes, bem como no desenvolvimento futuro de doenças crônicas. O padrão alimentar rico em gordura e açúcar, e com baixo aporte de fibra dietética, vitaminas e minerais é reconhecido como fator de risco para o surgimento da obesidade, no entanto os fatores que contribuem para a preferência por alimentos ricos nestes nutrientes não são bem estabelecidos. O sabor dos alimentos é reconhecido como um importante preditor das escolhas alimentares, e os polimorfismos nos genes que codificam os receptores do sabor podem explicar a variabilidade da preferência e consumo alimentar na população. OBJETIVO: Avaliar a influência de polimorfismos de genes de receptores de sabor gorduroso (CD36), doce (TAS1R2) e amargo (TAS2R38) no consumo alimentar e no perfil metabólico de crianças e adolescentes obesos. MÉTODOS: Estudo transversal com 668 crianças e adolescentes obesos e um grupo controle de 135 crianças eutróficas, de ambos os gêneros. Foi realizado o estudo molecular dos polimorfismos de nucleotídeo único (SNPs) rs1761667 e rs1527483 do CD36, rs9701796 e rs35874116 do TAS1R2, e rs1726866 e rs713598 do TAS2R38, bem como análise do consumo alimentar e perfil metabólico. RESULTADOS: Em relação ao CD36, o alelo A do rs1761667 relacionou-se com menor consumo de lipídios totais, gorduras poli e monoinsaturadas, consumo de alimentos de sabor gorduroso, ingestão de óleos vegetais e açúcares totais em obesos. O alelo A do rs1527483 associou-se com menor percentil de pressão arterial diastólica, menor massa gorda e maior massa livre de gordura em obesos. Quanto ao gene TAS1R2, a variante rs9701796 teve maior risco metabólico segundo a razão circunferência da cintura-estatura (RCE), bem como relação com maior consumo de achocolatado em pó em obesos. Já a variante rs35874116 mostrou relação com a menor ingestão de fibras dietéticas em obesos. No TAS2R38, o alelo G do rs1726866 foi associado com menor consumo de gorduras monoinsaturadas e maior consumo de açúcares totais, em obesos. O alelo G do rs713598 mostrou relação com maior consumo de carboidratos, consumo de alimentos de sabor doce, refrigerantes e menor ingestão de fibras pelos indivíduos eutróficos. CONCLUSÃO: Não houve relação entre genótipos e risco de obesidade. Os achados mostram a associação entre polimorfismos dos genes de receptores de sabor com o consumo alimentar, indicando diferenças entre obesos e magros, e alelos de proteção e de risco cardiometabólico, respectivamente dos genes CD36 e TAS1R2 / BACKGROUND: Childhood obesity is a major public health problem and it has a direct impact on the quality of life of children and adolescents, as well as the future risk for development of chronic diseases. The dietary pattern rich in fats and sugars associated to the low intake of dietary fibers, vitamins and minerals is widespread for the rise of obesity. However the factors that contribute to the preference for foods rich in these nutrients are not well established. Taste is recognized as an important predictor of food choices, and polymorphisms in genes encoding its receptors may explain the variability of taste preference and food intake on population. OBJECTIVE: To evaluate the influence of polymorphisms of fat (CD36), sweet (TAS1R2) and bitter (TAS2R38) taste receptor genes in diet and metabolic profile in obese children and adolescents. METHODS: Cross-sectional study with 668 obese children and adolescents and a control group of 135 normal-weight children. The molecular study was made for single nucleotide polymorphisms (SNPs) rs1761667 and rs1527483 of CD36, rs9701796 and rs35874116 of TAS1R2, rs1726866 and rs713598 of TAS2R38, and the analysis of food intake and metabolic profile. RESULTS: In relation to CD36, the A allele of rs1761667 was associated with lower intake of total fat, poly and monounsaturated fats, consumption of fatty flavor food, intake of vegetable oils and total sugars in obese. The A allele of rs1527483 was associated with lower percentile of diastolic blood pressure, lower fat mass and increased fat-free mass in obese. Regarding TAS1R2 gene, the variant rs9701796 was associated to increased metabolic risk according to waist-height ratio, as well as with higher consumption of chocolate powder in obese. The variant rs35874116 showed a lower intake of dietary fiber. In TAS2R38, the G allele of rs1726866 was associated with a lower intake of monounsaturated fat and a higher intake of total sugars in obese. The G allele of rs713598 was related to the higher carbohydrate intake, consumption of sweet tasting food, soda drinks and less fiber intake by normal weight children. CONCLUSION: There was no relationship between genotypes and risk of obesity. The findings show the association between polymorphisms of taste receptor genes with dietary intake, indicating differences between obese and lean children, as well as the protective and risk alleles for cardiometabolic risk in CD36 and TAS1R2, respectively

Adolescente

Amargo

Comportamento alimentar

Consumo de alimentos

Criança

Doces

Genótipo

Hábitos alimentares

Nutrientes/metabolismo

Obesidade pediátrica/genética

Obesidade/metabolismo

Paladar

Percepção gustatória

Polimorfismo de nucleotídeo único

Proteína CD36

Proteína humana TAS1R2

Proteína humana TAS2R38

Receptores de sabor

Sabor gorduroso

Adolescent

Bitter

CD36 protein

Child

Fat taste

Feeding behavior

Food consumption

Food habits

Genotype

Nutrients/metabolism

Obesity/metabolism

Pediatric obesity/genetics

Polymorphism single nucleotide

Sweet

TAS1R2 protein human

TAS2R38 protein human

Taste

Taste perception

Taste receptor