Complementary lateral hypothalamic populations resist hunger pressure to balance nutritional and social needs
Animals continuously weigh hunger and thirst against competing needs, such as social contact and mating, according to state and opportunity. Yet neuronal mechanisms of sensing and ranking nutritional needs remain poorly understood. Here, combining calcium imaging in freely behaving mice, optogenetic...
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| Published in | Cell metabolism Vol. 35; no. 3; pp. 456 - 471.e6 |
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| Main Authors | , , , |
| Format | Journal Article |
| Language | English |
| Published |
United States
Elsevier Inc
07.03.2023
Cell Press |
| Subjects | |
| Online Access | Get full text |
| ISSN | 1550-4131 1932-7420 1932-7420 |
| DOI | 10.1016/j.cmet.2023.02.008 |
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| Abstract | Animals continuously weigh hunger and thirst against competing needs, such as social contact and mating, according to state and opportunity. Yet neuronal mechanisms of sensing and ranking nutritional needs remain poorly understood. Here, combining calcium imaging in freely behaving mice, optogenetics, and chemogenetics, we show that two neuronal populations of the lateral hypothalamus (LH) guide increasingly hungry animals through behavioral choices between nutritional and social rewards. While increased food consumption was marked by increasing inhibition of a leptin receptor-expressing (LepRLH) subpopulation at a fast timescale, LepRLH neurons limited feeding or drinking and promoted social interaction despite hunger or thirst. Conversely, neurotensin-expressing LH neurons preferentially encoded water despite hunger pressure and promoted water seeking, while relegating social needs. Thus, hunger and thirst gate both LH populations in a complementary manner to enable the flexible fulfillment of multiple essential needs.
[Display omitted]
•Food-elicited inhibition of LepRLH neurons facilitates food intake•Activation of LepRLH cells limits feeding rebound post-acute food restriction•LepRLH neurons limit nutritional needs in favor of sex-specific social interaction•NtsLH neurons relegate hunger and social interaction to promote drinking
Animals continuously weigh hunger and thirst against competing needs, such as social contact and mating, according to state and opportunity. Here, Petzold et al. show that leptin receptor-expressing and neurotensin-expressing neurons in the lateral hypothalamus resist immediate nutritional needs and flexibly prioritize competing needs despite hunger or thirst. |
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| AbstractList | Animals continuously weigh hunger and thirst against competing needs, such as social contact and mating, according to state and opportunity. Yet neuronal mechanisms of sensing and ranking nutritional needs remain poorly understood. Here, combining calcium imaging in freely behaving mice, optogenetics, and chemogenetics, we show that two neuronal populations of the lateral hypothalamus (LH) guide increasingly hungry animals through behavioral choices between nutritional and social rewards. While increased food consumption was marked by increasing inhibition of a leptin receptor-expressing (LepRLH) subpopulation at a fast timescale, LepRLH neurons limited feeding or drinking and promoted social interaction despite hunger or thirst. Conversely, neurotensin-expressing LH neurons preferentially encoded water despite hunger pressure and promoted water seeking, while relegating social needs. Thus, hunger and thirst gate both LH populations in a complementary manner to enable the flexible fulfillment of multiple essential needs.Animals continuously weigh hunger and thirst against competing needs, such as social contact and mating, according to state and opportunity. Yet neuronal mechanisms of sensing and ranking nutritional needs remain poorly understood. Here, combining calcium imaging in freely behaving mice, optogenetics, and chemogenetics, we show that two neuronal populations of the lateral hypothalamus (LH) guide increasingly hungry animals through behavioral choices between nutritional and social rewards. While increased food consumption was marked by increasing inhibition of a leptin receptor-expressing (LepRLH) subpopulation at a fast timescale, LepRLH neurons limited feeding or drinking and promoted social interaction despite hunger or thirst. Conversely, neurotensin-expressing LH neurons preferentially encoded water despite hunger pressure and promoted water seeking, while relegating social needs. Thus, hunger and thirst gate both LH populations in a complementary manner to enable the flexible fulfillment of multiple essential needs. Animals continuously weigh hunger and thirst against competing needs, such as social contact and mating, according to state and opportunity. Yet neuronal mechanisms of sensing and ranking nutritional needs remain poorly understood. Here, combining calcium imaging in freely behaving mice, optogenetics, and chemogenetics, we show that two neuronal populations of the lateral hypothalamus (LH) guide increasingly hungry animals through behavioral choices between nutritional and social rewards. While increased food consumption was marked by increasing inhibition of a leptin receptor-expressing (LepR ) subpopulation at a fast timescale, LepR neurons limited feeding or drinking and promoted social interaction despite hunger or thirst. Conversely, neurotensin-expressing LH neurons preferentially encoded water despite hunger pressure and promoted water seeking, while relegating social needs. Thus, hunger and thirst gate both LH populations in a complementary manner to enable the flexible fulfillment of multiple essential needs. Animals continuously weigh hunger and thirst against competing needs, such as social contact and mating, according to state and opportunity. Yet neuronal mechanisms of sensing and ranking nutritional needs remain poorly understood. Here, combining calcium imaging in freely behaving mice, optogenetics, and chemogenetics, we show that two neuronal populations of the lateral hypothalamus (LH) guide increasingly hungry animals through behavioral choices between nutritional and social rewards. While increased food consumption was marked by increasing inhibition of a leptin receptor-expressing (LepR LH ) subpopulation at a fast timescale, LepR LH neurons limited feeding or drinking and promoted social interaction despite hunger or thirst. Conversely, neurotensin-expressing LH neurons preferentially encoded water despite hunger pressure and promoted water seeking, while relegating social needs. Thus, hunger and thirst gate both LH populations in a complementary manner to enable the flexible fulfillment of multiple essential needs. • Food-elicited inhibition of LepR LH neurons facilitates food intake • Activation of LepR LH cells limits feeding rebound post-acute food restriction • LepR LH neurons limit nutritional needs in favor of sex-specific social interaction • Nts LH neurons relegate hunger and social interaction to promote drinking Animals continuously weigh hunger and thirst against competing needs, such as social contact and mating, according to state and opportunity. Here, Petzold et al. show that leptin receptor-expressing and neurotensin-expressing neurons in the lateral hypothalamus resist immediate nutritional needs and flexibly prioritize competing needs despite hunger or thirst. Animals continuously weigh hunger and thirst against competing needs, such as social contact and mating, according to state and opportunity. Yet neuronal mechanisms of sensing and ranking nutritional needs remain poorly understood. Here, combining calcium imaging in freely behaving mice, optogenetics, and chemogenetics, we show that two neuronal populations of the lateral hypothalamus (LH) guide increasingly hungry animals through behavioral choices between nutritional and social rewards. While increased food consumption was marked by increasing inhibition of a leptin receptor-expressing (LepRLH) subpopulation at a fast timescale, LepRLH neurons limited feeding or drinking and promoted social interaction despite hunger or thirst. Conversely, neurotensin-expressing LH neurons preferentially encoded water despite hunger pressure and promoted water seeking, while relegating social needs. Thus, hunger and thirst gate both LH populations in a complementary manner to enable the flexible fulfillment of multiple essential needs. [Display omitted] •Food-elicited inhibition of LepRLH neurons facilitates food intake•Activation of LepRLH cells limits feeding rebound post-acute food restriction•LepRLH neurons limit nutritional needs in favor of sex-specific social interaction•NtsLH neurons relegate hunger and social interaction to promote drinking Animals continuously weigh hunger and thirst against competing needs, such as social contact and mating, according to state and opportunity. Here, Petzold et al. show that leptin receptor-expressing and neurotensin-expressing neurons in the lateral hypothalamus resist immediate nutritional needs and flexibly prioritize competing needs despite hunger or thirst. |
| Author | van den Munkhof, Hanna Elin Figge-Schlensok, Rebecca Petzold, Anne Korotkova, Tatiana |
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| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/36827985$$D View this record in MEDLINE/PubMed |
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| Keywords | neurotensin innate behaviors optogenetics chemogenetics feeding social interaction in vivo calcium imaging leptin behaving mice |
| Language | English |
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| SubjectTerms | Animals behaving mice calcium imaging chemogenetics feeding Hunger - physiology Hypothalamic Area, Lateral - physiology in vivo innate behaviors leptin Mice Neurons - physiology Neurotensin optogenetics social interaction |
| Title | Complementary lateral hypothalamic populations resist hunger pressure to balance nutritional and social needs |
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