Inhibiting poly ADP-ribosylation increases fatty acid oxidation and protects against fatty liver disease

SUMMARY Binding between DIP and Dpr neuronal-recognition proteins has been proposed to regulate synaptic connections between lamina and medulla neurons in the Drosophila visual system. Each lamina neuron was previously shown to express many Dprs. Here, we demonstrate, by contrast, that their synaptic partners typically express one or two DIPs, with binding specificities matched to the lamina neuron-expressed Dprs. A deeper understanding of the molecular logic of DIP/Dpr interaction requires quantitative studies on the properties of these proteins. We thus generated a quantitative affinity-based DIP/Dpr interactome for all DIP/Dpr protein family members. This revealed a broad range of affinities and identified homophilic binding for some DIPs and some Dprs. These data, along with full-length ectodomain DIP/Dpr and DIP/DIP crystal structures, led to the identification of molecular determinants of DIP/Dpr specificity. This structural knowledge, along with a comprehensive set of quantitative binding affinities, provides new tools for functional studies in vivo.

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Interactions between the Ig-Superfamily Proteins DIP-α and Dpr6/10 Regulate Assembly of Neural Circuits

Xiao

Cosmanescu

et al. 2018

Neuron

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Drosophila Dpr (21 paralogs) and DIP proteins (11 paralogs) are cell recognition molecules of the immunoglobulin superfamily (IgSF) that form a complex protein interaction network. DIP and Dpr proteins are expressed in a synaptic layer-specific fashion in the visual system. How interactions between these proteins regulate layer-specific synaptic circuitry is not known. Here we establish that DIP-a and its interacting partners Dpr6 and Dpr10 regulate multiple processes, including arborization within layers, synapse number, layer specificity, and cell survival. We demonstrate that heterophilic binding between Dpr6/10 and DIP-a and homophilic binding between DIP-a proteins promote interactions between processes in vivo. Knockin mutants disrupting the DIP/ Dpr binding interface reveal a role for these proteins during normal development, while ectopic expression studies support an instructive role for interactions between DIPs and Dprs in circuit development. These studies support an important role for the DIP/ Dpr protein interaction network in regulating celltype-specific connectivity patterns.

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Crystal structures of Drosophila N-cadherin ectodomain regions reveal a widely used class of Ca ²⁺ -free interdomain linkers

Jin

Walker

Felsövályi

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

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Vertebrate classical cadherins mediate selective calcium-dependent cell adhesion by mechanisms now understood at the atomic level. However, structures and adhesion mechanisms of cadherins from invertebrates, which are highly divergent yet function in similar roles, remain unknown. Here we present crystal structures of three-and four-tandem extracellular cadherin (EC) domain segments from Drosophila N-cadherin (DN-cadherin), each including the predicted N-terminal EC1 domain (denoted EC1') of the mature protein. While the linker regions for the EC1'-EC2' and EC3'-EC4' pairs display binding of three Ca 2 ions similar to that of vertebrate cadherins, domains EC2' and EC3' are joined in a "kinked" orientation by a previously uncharacterized Ca 2 -free linker. Biophysical analysis demonstrates that a construct containing the predicted N-terminal nine EC domains of DN-cadherin forms homodimers with affinity similar to vertebrate classical cadherins, whereas deleting the ninth EC domain ablates dimerization. These results suggest that, unlike their vertebrate counterparts, invertebrate cadherins may utilize multiple EC domains to form intercellular adhesive bonds. Sequence analysis reveals that similar Ca 2 -free linkers are widely distributed in the ectodomains of both vertebrate and invertebrate cadherins.

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DIP/Dpr interactions and the evolutionary design of specificity in protein families

et al. 2020

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Differential binding affinities among closely related protein family members underlie many biological phenomena, including cell-cell recognition. Drosophila DIP and Dpr proteins mediate neuronal targeting in the fly through highly specific protein-protein interactions. We show here that DIPs/Dprs segregate into seven specificity subgroups defined by binding preferences between their DIP and Dpr members. We then describe a sequence-, structure- and energy-based computational approach, combined with experimental binding affinity measurements, to reveal how specificity is coded on the canonical DIP/Dpr interface. We show that binding specificity of DIP/Dpr subgroups is controlled by “negative constraints”, which interfere with binding. To achieve specificity, each subgroup utilizes a different combination of negative constraints, which are broadly distributed and cover the majority of the protein-protein interface. We discuss the structural origins of negative constraints, and potential general implications for the evolutionary origins of binding specificity in multi-protein families.

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DIP/Dpr interactions and the evolutionary design of specificity in protein families

Sergeeva

Katsamba

Cosmanescu

et al. 2020

Preprint

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AbstractDifferential binding affinities among closely related protein family members underlie many biological phenomena, including cell-cell recognition. Drosophila DIP and Dpr proteins mediate neuronal targeting in the fly through highly specific protein-protein interactions. We show here that DIPs/Dprs segregate into seven specificity subgroups defined by binding preferences between their DIP and Dpr members. We then describe a novel sequence-, structure- and energy-based computational approach, combined with experimental binding affinity measurements, to reveal how specificity is coded on the canonical DIP/Dpr interface. We show that binding specificity of DIP/Dpr subgroups is controlled by “negative constraints”, which interfere with binding. To achieve specificity, each subgroup utilizes a different combination of negative constraints, which are broadly distributed and cover the majority of the protein-protein interface. We discuss the structural origins of negative constraints, and potential general implications for the evolutionary origins of binding specificity in multi-protein families.

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Family-Wide Biophysical Analysis of Dpr-DIP Interactions

Cosmanescu

Katsamba

Sergeeva

et al. 2018

Biophysical Journal

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Crystal Structure of DIP-Alpha Ig1-3

Cosmanescu¹,

Katsamba²,

Sergeeva³

et al. 2018

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Structural and biophysical studies of the Drosophila melanogaster Dpr and DIP families

Cosmanescu¹

2018

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Filip Cosmanescu

Neuron-Subtype-Specific Expression, Interaction Affinities, and Specificity Determinants of DIP/Dpr Cell Recognition Proteins

Interactions between the Ig-Superfamily Proteins DIP-α and Dpr6/10 Regulate Assembly of Neural Circuits

Crystal structures of Drosophila N-cadherin ectodomain regions reveal a widely used class of Ca ²⁺ -free interdomain linkers

DIP/Dpr interactions and the evolutionary design of specificity in protein families

DIP/Dpr interactions and the evolutionary design of specificity in protein families

Family-Wide Biophysical Analysis of Dpr-DIP Interactions

Crystal Structure of DIP-Alpha Ig1-3

Structural and biophysical studies of the Drosophila melanogaster Dpr and DIP families

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Filip Cosmanescu

Neuron-Subtype-Specific Expression, Interaction Affinities, and Specificity Determinants of DIP/Dpr Cell Recognition Proteins

Interactions between the Ig-Superfamily Proteins DIP-α and Dpr6/10 Regulate Assembly of Neural Circuits

Crystal structures of Drosophila N-cadherin ectodomain regions reveal a widely used class of Ca 2+ -free interdomain linkers

DIP/Dpr interactions and the evolutionary design of specificity in protein families

DIP/Dpr interactions and the evolutionary design of specificity in protein families

Family-Wide Biophysical Analysis of Dpr-DIP Interactions

Crystal Structure of DIP-Alpha Ig1-3

Structural and biophysical studies of the Drosophila melanogaster Dpr and DIP families

Contact Info

Product

Resources

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Crystal structures of Drosophila N-cadherin ectodomain regions reveal a widely used class of Ca ²⁺ -free interdomain linkers