Independent phenotypic plasticity axes define distinct obesity sub-types

Chih-Hsiang Yang; Luca Fagnocchi; Stefanos Apostle; Vanessa Wegert; Salvador Casaní-Galdón; Kathrin Landgraf; Ilaria Panzeri; Erez Dror; Steffen Heyne; Till Wörpel; Darrell P Chandler; Di Lu; Tao Yang; Elizabeth Gibbons; Rita Guerreiro; Jose Bras; Martin Thomasen; Louise G Grunnet; Allan A Vaag; Linn Gillberg; Elin Grundberg; Ana Conesa; Antje Körner; J Andrew Pospisilik; PERMUTE

doi:10.1038/s42255-022-00629-2

Independent phenotypic plasticity axes define distinct obesity sub-types

Chih-Hsiang Yang, Luca Fagnocchi, Stefanos Apostle, Vanessa Wegert, Salvador Casaní-Galdón, Kathrin Landgraf, Ilaria Panzeri, Erez Dror, Steffen Heyne, Till Wörpel, Darrell P Chandler, Di Lu, Tao Yang, Elizabeth Gibbons, Rita Guerreiro, Jose Bras, Martin Thomasen, Louise G Grunnet, Allan A Vaag, Linn GillbergElin Grundberg, Ana Conesa, Antje Körner, J Andrew Pospisilik^*, PERMUTE

^*Corresponding author for this work

Steno Diabetes Center Copenhagen

28 Citations (Scopus)

Abstract

Studies in genetically 'identical' individuals indicate that as much as 50% of complex trait variation cannot be traced to genetics or to the environment. The mechanisms that generate this 'unexplained' phenotypic variation (UPV) remain largely unknown. Here, we identify neuronatin (NNAT) as a conserved factor that buffers against UPV. We find that Nnat deficiency in isogenic mice triggers the emergence of a bi-stable polyphenism, where littermates emerge into adulthood either 'normal' or 'overgrown'. Mechanistically, this is mediated by an insulin-dependent overgrowth that arises from histone deacetylase (HDAC)-dependent β-cell hyperproliferation. A multi-dimensional analysis of monozygotic twin discordance reveals the existence of two patterns of human UPV, one of which (Type B) phenocopies the NNAT-buffered polyphenism identified in mice. Specifically, Type-B monozygotic co-twins exhibit coordinated increases in fat and lean mass across the body; decreased NNAT expression; increased HDAC-responsive gene signatures; and clinical outcomes linked to insulinemia. Critically, the Type-B UPV signature stratifies both childhood and adult cohorts into four metabolic states, including two phenotypically and molecularly distinct types of obesity.

Original language	English
Journal	Nature metabolism
Volume	4
Issue number	9
Pages (from-to)	1150-1165
Number of pages	16
ISSN	2522-5812
DOIs	https://doi.org/10.1038/s42255-022-00629-2
Publication status	Published - Sept 2022

Keywords

Adaptation, Physiological
Adult
Animals
Child
Histone Deacetylases
Humans
Insulin
Membrane Proteins/metabolism
Mice
Nerve Tissue Proteins/genetics
Obesity/genetics

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Yang, C.-H., Fagnocchi, L., Apostle, S., Wegert, V., Casaní-Galdón, S., Landgraf, K., Panzeri, I., Dror, E., Heyne, S., Wörpel, T., Chandler, D. P., Lu, D., Yang, T., Gibbons, E., Guerreiro, R., Bras, J., Thomasen, M., Grunnet, L. G., Vaag, A. A., ... PERMUTE (2022). Independent phenotypic plasticity axes define distinct obesity sub-types. Nature metabolism, 4(9), 1150-1165. https://doi.org/10.1038/s42255-022-00629-2

Yang, C-H, Fagnocchi, L, Apostle, S, Wegert, V, Casaní-Galdón, S, Landgraf, K, Panzeri, I, Dror, E, Heyne, S, Wörpel, T, Chandler, DP, Lu, D, Yang, T, Gibbons, E, Guerreiro, R, Bras, J, Thomasen, M , Grunnet, LG , Vaag, AA, Gillberg, L, Grundberg, E, Conesa, A, Körner, A, Pospisilik, JA & PERMUTE 2022, 'Independent phenotypic plasticity axes define distinct obesity sub-types', Nature metabolism, vol. 4, no. 9, pp. 1150-1165. https://doi.org/10.1038/s42255-022-00629-2

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title = "Independent phenotypic plasticity axes define distinct obesity sub-types",

abstract = "Studies in genetically 'identical' individuals indicate that as much as 50\% of complex trait variation cannot be traced to genetics or to the environment. The mechanisms that generate this 'unexplained' phenotypic variation (UPV) remain largely unknown. Here, we identify neuronatin (NNAT) as a conserved factor that buffers against UPV. We find that Nnat deficiency in isogenic mice triggers the emergence of a bi-stable polyphenism, where littermates emerge into adulthood either 'normal' or 'overgrown'. Mechanistically, this is mediated by an insulin-dependent overgrowth that arises from histone deacetylase (HDAC)-dependent β-cell hyperproliferation. A multi-dimensional analysis of monozygotic twin discordance reveals the existence of two patterns of human UPV, one of which (Type B) phenocopies the NNAT-buffered polyphenism identified in mice. Specifically, Type-B monozygotic co-twins exhibit coordinated increases in fat and lean mass across the body; decreased NNAT expression; increased HDAC-responsive gene signatures; and clinical outcomes linked to insulinemia. Critically, the Type-B UPV signature stratifies both childhood and adult cohorts into four metabolic states, including two phenotypically and molecularly distinct types of obesity.",

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doi = "10.1038/s42255-022-00629-2",

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T1 - Independent phenotypic plasticity axes define distinct obesity sub-types

AU - Yang, Chih-Hsiang

AU - Fagnocchi, Luca

AU - Apostle, Stefanos

AU - Wegert, Vanessa

AU - Casaní-Galdón, Salvador

AU - Landgraf, Kathrin

AU - Panzeri, Ilaria

AU - Dror, Erez

AU - Heyne, Steffen

AU - Wörpel, Till

AU - Chandler, Darrell P

AU - Lu, Di

AU - Yang, Tao

AU - Gibbons, Elizabeth

AU - Guerreiro, Rita

AU - Bras, Jose

AU - Thomasen, Martin

AU - Grunnet, Louise G

AU - Vaag, Allan A

AU - Gillberg, Linn

AU - Grundberg, Elin

AU - Conesa, Ana

AU - Körner, Antje

AU - Pospisilik, J Andrew

AU - PERMUTE

PY - 2022/9

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N2 - Studies in genetically 'identical' individuals indicate that as much as 50% of complex trait variation cannot be traced to genetics or to the environment. The mechanisms that generate this 'unexplained' phenotypic variation (UPV) remain largely unknown. Here, we identify neuronatin (NNAT) as a conserved factor that buffers against UPV. We find that Nnat deficiency in isogenic mice triggers the emergence of a bi-stable polyphenism, where littermates emerge into adulthood either 'normal' or 'overgrown'. Mechanistically, this is mediated by an insulin-dependent overgrowth that arises from histone deacetylase (HDAC)-dependent β-cell hyperproliferation. A multi-dimensional analysis of monozygotic twin discordance reveals the existence of two patterns of human UPV, one of which (Type B) phenocopies the NNAT-buffered polyphenism identified in mice. Specifically, Type-B monozygotic co-twins exhibit coordinated increases in fat and lean mass across the body; decreased NNAT expression; increased HDAC-responsive gene signatures; and clinical outcomes linked to insulinemia. Critically, the Type-B UPV signature stratifies both childhood and adult cohorts into four metabolic states, including two phenotypically and molecularly distinct types of obesity.

AB - Studies in genetically 'identical' individuals indicate that as much as 50% of complex trait variation cannot be traced to genetics or to the environment. The mechanisms that generate this 'unexplained' phenotypic variation (UPV) remain largely unknown. Here, we identify neuronatin (NNAT) as a conserved factor that buffers against UPV. We find that Nnat deficiency in isogenic mice triggers the emergence of a bi-stable polyphenism, where littermates emerge into adulthood either 'normal' or 'overgrown'. Mechanistically, this is mediated by an insulin-dependent overgrowth that arises from histone deacetylase (HDAC)-dependent β-cell hyperproliferation. A multi-dimensional analysis of monozygotic twin discordance reveals the existence of two patterns of human UPV, one of which (Type B) phenocopies the NNAT-buffered polyphenism identified in mice. Specifically, Type-B monozygotic co-twins exhibit coordinated increases in fat and lean mass across the body; decreased NNAT expression; increased HDAC-responsive gene signatures; and clinical outcomes linked to insulinemia. Critically, the Type-B UPV signature stratifies both childhood and adult cohorts into four metabolic states, including two phenotypically and molecularly distinct types of obesity.

KW - Adaptation, Physiological

KW - Adult

KW - Animals

KW - Child

KW - Histone Deacetylases

KW - Humans

KW - Insulin

KW - Membrane Proteins/metabolism

KW - Mice

KW - Nerve Tissue Proteins/genetics

KW - Obesity/genetics

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DO - 10.1038/s42255-022-00629-2

M3 - Journal article

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SN - 2522-5812

VL - 4

SP - 1150

EP - 1165

JO - Nature metabolism

JF - Nature metabolism

IS - 9

ER -

Independent phenotypic plasticity axes define distinct obesity sub-types

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