Loss of Num1-mediated cortical dynein anchoring negatively impacts respiratory growth

Antoineen J. White; Clare S. Harper; Erica M. Rosario; Jonathan V. Dietz; Hannah G. Addis; Jennifer L. Fox; Oleh Khalimonchuk; Laura L. Lackner

doi:10.1242/jcs.259980

Loss of Num1-mediated cortical dynein anchoring negatively impacts respiratory growth

Antoineen J. White, Clare S. Harper, Erica M. Rosario, Jonathan V. Dietz, Hannah G. Addis, Jennifer L. Fox, Oleh Khalimonchuk, Laura L. Lackner^*

^*Corresponding author for this work

Molecular Biosciences

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

Num1 is a multifunctional protein that both tethers mitochondria to the plasma membrane and anchors dynein to the cell cortex during nuclear inheritance. Previous work has examined the impact loss of Num1-based mitochondrial tethering has on dynein function in Saccharomyces cerevisiae; here, we elucidate its impact on mitochondrial function. We find that like mitochondria, Num1 is regulated by changes in metabolic state, with the protein levels and cortical distribution of Num1 differing between fermentative and respiratory growth conditions. In cells lacking Num1, we observe a reproducible respiratory growth defect, suggesting a role for Num1 in not only maintaining mitochondrial morphology, but also function. A structure-function approach revealed that, unexpectedly, Num1-mediated cortical dynein anchoring is important for normal growth under respiratory conditions. The severe respiratory growth defect in Δnum1 cells is not specifically due to the canonical functions of dynein in nuclear migration but is dependent on the presence of dynein, as deletion of DYN1 in Δnum1 cells partially rescues respiratory growth. We hypothesize that misregulated dynein present in cells that lack Num1 negatively impacts mitochondrial function resulting in defects in respiratory growth.

Original language	English (US)
Article number	jcs259980
Journal	Journal of cell science
Volume	135
Issue number	21
DOIs	https://doi.org/10.1242/jcs.259980
State	Published - Nov 2022

Funding

We thank members of the Lackner laboratory for suggestions and critical scientific discussions. We also thank Northwestern’s Cell Biology Supergroup and the WiLa ICB for constructive feedback on the project. We are extremely grateful to Dennis Winge and Alexander Tzagoloff for providing reagents, Antoni Barrientos (U. Miami) for his help and guidance with the respirometry/polarography measurements, Jeff Moore (CU Anschutz) for the Dyn1ΔMTBD strain, and Jessica Hornick for help and advice on imaging. All microscopy was performed at the Biological Imaging Facility at Northwestern University (RRID:SCR_017767), supported by the Chemistry for Life Processes Institute, the NU Office for Research, the Department of Molecular Biosciences, and the Rice Foundation. This work was supported in part by the National Institutes of Health grants R01 GM120303 (L.L.L.), T32 GM008382 (A.J.W.), T32 GM008449 (C.S.H. and E.M.R.), R35 GM131701-01 (O.K.), P20 GM103499-20, and T32 GM107001-01A1 (J.V.D.) and the National Science Foundation Graduate Research Fellowship GRF DGE-1842165 (C.S.H.). Deposited in PMC for release after 12 months.

Keywords

Membrane contact sites
Mitochondria
Organelle positioning

ASJC Scopus subject areas

Cell Biology

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10.1242/jcs.259980

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title = "Loss of Num1-mediated cortical dynein anchoring negatively impacts respiratory growth",

abstract = "Num1 is a multifunctional protein that both tethers mitochondria to the plasma membrane and anchors dynein to the cell cortex during nuclear inheritance. Previous work has examined the impact loss of Num1-based mitochondrial tethering has on dynein function in Saccharomyces cerevisiae; here, we elucidate its impact on mitochondrial function. We find that like mitochondria, Num1 is regulated by changes in metabolic state, with the protein levels and cortical distribution of Num1 differing between fermentative and respiratory growth conditions. In cells lacking Num1, we observe a reproducible respiratory growth defect, suggesting a role for Num1 in not only maintaining mitochondrial morphology, but also function. A structure-function approach revealed that, unexpectedly, Num1-mediated cortical dynein anchoring is important for normal growth under respiratory conditions. The severe respiratory growth defect in Δnum1 cells is not specifically due to the canonical functions of dynein in nuclear migration but is dependent on the presence of dynein, as deletion of DYN1 in Δnum1 cells partially rescues respiratory growth. We hypothesize that misregulated dynein present in cells that lack Num1 negatively impacts mitochondrial function resulting in defects in respiratory growth.",

keywords = "Membrane contact sites, Mitochondria, Organelle positioning",

author = "White, {Antoineen J.} and Harper, {Clare S.} and Rosario, {Erica M.} and Dietz, {Jonathan V.} and Addis, {Hannah G.} and Fox, {Jennifer L.} and Oleh Khalimonchuk and Lackner, {Laura L.}",

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AU - Addis, Hannah G.

AU - Fox, Jennifer L.

AU - Khalimonchuk, Oleh

AU - Lackner, Laura L.

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N2 - Num1 is a multifunctional protein that both tethers mitochondria to the plasma membrane and anchors dynein to the cell cortex during nuclear inheritance. Previous work has examined the impact loss of Num1-based mitochondrial tethering has on dynein function in Saccharomyces cerevisiae; here, we elucidate its impact on mitochondrial function. We find that like mitochondria, Num1 is regulated by changes in metabolic state, with the protein levels and cortical distribution of Num1 differing between fermentative and respiratory growth conditions. In cells lacking Num1, we observe a reproducible respiratory growth defect, suggesting a role for Num1 in not only maintaining mitochondrial morphology, but also function. A structure-function approach revealed that, unexpectedly, Num1-mediated cortical dynein anchoring is important for normal growth under respiratory conditions. The severe respiratory growth defect in Δnum1 cells is not specifically due to the canonical functions of dynein in nuclear migration but is dependent on the presence of dynein, as deletion of DYN1 in Δnum1 cells partially rescues respiratory growth. We hypothesize that misregulated dynein present in cells that lack Num1 negatively impacts mitochondrial function resulting in defects in respiratory growth.

AB - Num1 is a multifunctional protein that both tethers mitochondria to the plasma membrane and anchors dynein to the cell cortex during nuclear inheritance. Previous work has examined the impact loss of Num1-based mitochondrial tethering has on dynein function in Saccharomyces cerevisiae; here, we elucidate its impact on mitochondrial function. We find that like mitochondria, Num1 is regulated by changes in metabolic state, with the protein levels and cortical distribution of Num1 differing between fermentative and respiratory growth conditions. In cells lacking Num1, we observe a reproducible respiratory growth defect, suggesting a role for Num1 in not only maintaining mitochondrial morphology, but also function. A structure-function approach revealed that, unexpectedly, Num1-mediated cortical dynein anchoring is important for normal growth under respiratory conditions. The severe respiratory growth defect in Δnum1 cells is not specifically due to the canonical functions of dynein in nuclear migration but is dependent on the presence of dynein, as deletion of DYN1 in Δnum1 cells partially rescues respiratory growth. We hypothesize that misregulated dynein present in cells that lack Num1 negatively impacts mitochondrial function resulting in defects in respiratory growth.

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Loss of Num1-mediated cortical dynein anchoring negatively impacts respiratory growth

Abstract

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