We demonstrate that a Drosophila Golgi protein, Gorab, is present not only in the trans-Golgi but also in the centriole cartwheel where, complexed to Sas6, it is required for centriole duplication. In addition to centriole defects, flies lacking Gorab are uncoordinated due to defects in sensory cilia, which lose their nine-fold symmetry. We demonstrate the separation of centriole and Golgi functions of Drosophila Gorab in two ways: first, we have created Gorab variants that are unable to localize to trans-Golgi but can still rescue the centriole and cilia defects of gorab null flies; second, we show that expression of C-terminally tagged Gorab disrupts Golgi functions in cytokinesis of male meiosis, a dominant phenotype overcome by mutations preventing Golgi targeting. Our findings suggest that during animal evolution, a Golgi protein has arisen with a second, apparently independent, role in centriole duplication.D.M.G. is grateful for a Wellcome Investigator Award, which supported this work. The study was initiated with support from Cancer Research UK

A Efimov

A Rodrigues-Martins

AC Groth

AK Gillingham

BG Lambrus

BT Emmer

C Stoetzel

CJC Tang

CS Fong

D Frescas

D Izquierdo

D Kitazawa

David M. Glover

F Port

F Riedel

G Goshima

G Kohlmaier

George Tzolovsky

Giuliano Callaini

H Kim

HC Hennies

J Bischof

J Dobbelaere

J Egerer

J Fu

J Ripoche

JA Follit

Jennifer Chao-Chu

JG Heuer

JL Burman

JR Broekhuis

JV Chen

K Raj

L Zhong

Levente Kovacs

M Al-Dosari

M Gottardo

M Hilbert

M Hiraki

M Ohta

M Wong

Marco Gottardo

Maria Giovanna Riparbelli

Nikola S. Dzhindzhev

NS Dzhindzhev

O Papoulas

P Gönczy

P Strnad

PP D’Avino

R Basto

RM Rios

S Blachon

S Rivero

S Sechi

Sandra Schneider

TI Schmidt

WJ Wang

Y Di

Y Liu

YC Lin

Z Lipinszki

English

Kovacs, Levente

Chao-Chu, Jennifer

Schneider, Sandra

Gottardo, Marco

Tzolovsky, George

Dzhindzhev, Nikola S

Riparbelli, Maria Giovanna

Callaini, Giuliano

Glover, David M

Apollo (Cambridge)

Gorab is a Golgi protein required for structure and duplication of Drosophila centrioles.

We demonstrate that a Drosophila Golgi protein, Gorab, is present not only in the trans-Golgi but also in the centriole cartwheel where, complexed to Sas6, it is required for centriole duplication. In addition to centriole defects, flies lacking Gorab are uncoordinated due to defects in sensory cilia, which lose their nine-fold symmetry. We demonstrate the separation of centriole and Golgi functions of Drosophila Gorab in two ways: first, we have created Gorab variants that are unable to localize to trans-Golgi but can still rescue the centriole and cilia defects of gorab null flies; second, we show that expression of C-terminally tagged Gorab disrupts Golgi functions in cytokinesis of male meiosis, a dominant phenotype overcome by mutations preventing Golgi targeting. Our findings suggest that during animal evolution, a Golgi protein has arisen with a second, apparently independent, role in centriole duplication

Dzhindzhev, Nikola S.

Glover, David M.

Caltech Authors - Main

Articles
https://doi.org/10.1038/s41588-018-0149-1
Gorab is a Golgi protein required for structure and 
duplication of Drosophila centrioles
Levente Kovacs   1, Jennifer Chao-Chu   1,3,6, Sandra Schneider1,6, Marco Gottardo2,4,  
George Tzolovsky1,5, Nikola S. Dzhindzhev1, Maria Giovanna Riparbelli2, Giuliano Callaini2  
and David M. Glover   1*
1University of Cambridge, Cambridge, UK. 2University of Siena, Siena, Italy. 3Present address: The University of Hong Kong, Hong Kong, China.  
4Present address: Alexander von Humboldt Foundation Fellow, Center for Molecular Medicine and Institute for Biochemistry of the University of Cologne, 
Cologne, Germany. 5Present address: Carl Zeiss Microscopy Ltd, ZEISS Group, Cambridge, UK. 6These authors contributed equally: Jennifer Chao-Chu, 
Sandra Schneider. *e-mail: dmg25@cam.ac.uk
SUPPLEMENTARY INFORMATION
In the format provided by the authors and unedited.
NaTuRe GeNeTiCS | www.nature.com/naturegenetics
© 2018 Nature America Inc., part of Springer Nature. All rights reserved.
 
 
 
 
 
Supplementary Figure 1 
Localization of Gorab in mitotic cells 
(a) D-Mel2 cells in metaphase were immunostained to reveal Gorab, dPLP (centrosome), and Golgin245 (trans-Golgi). Arrowheads 
indicate centrosomes. Experiment repeated 3 times with similar results.Main scale bar, 5 µm; inset scale bar, 0.5 µm.(b) Wing discs 
from larvae expressing N-terminally GFP-tagged Gorab were immunostained for dPLP (red) and Golgin245 (grey). Dashed lines 
highlight an interphase (left) and a mitotic cell (right). Arrowheads indicate centrosomes of mitotic cells. Experiement repeated 3 times 
with similar results.Main scale bar,5 µm.Inset scale bar,0.5µm.(c) Brains from larvae expressing N-terminally GFP-tagged Gorab 
immunostained for dPLP (red) and Golgin245 (grey). Dashed lines highlight an interphase (left) and a mitotic cell (right). Arrowheads 
indicate centrosomes of a mitotic neuroblast. Experiment repeated with similar result. Main scale bar,5 µm, Inset scale bar, 1µm. (d) 
Fluorescent micrographs of control and Gorab depleted D-Mel2 cells stained by DAPI (blue) and anti-Gorab (green) to demonstrate the 
specificity of Gorab antibody. Cells subjected to 4 times 4 days siRNA treatment with control or Gorab specific siRNAs followed by 
fixation in methanol and immunostaning. Experiment independently repeated twice with similar results. Scale bar: 10 µm. 
 
 
 
Supplementary Figure 2 
Gorab interaction with Sas6 
Autoradiograms of GST-tagged Gorab’s interaction with the 
35
S-Methionine-labelled Sas6 protein fragments schematically illustrated in 
Fig2B. The length of the Sas6 fragments are indicated. Experiments were repeated twice by different investigators with similar results. 
 
 
 
Supplementary Figure 3 
Sas6 interaction with Gorab 
(a)Autoradiogram of GST-Sas6 interaction with 
35
S-Methionine-labelled Gorab protein fragments, schematically illustrated in Fig5B. The 
experiments were repeated once by a different investigator with similar result. (b) Sas6 and Gorab interaction in vivo. D-Mel2 cells were 
transiently transfected with myc-tagged Sas6 and GFP-tagged wild type or ΔSID Gorab. Samples were subjected to GFP-trap 
immunoprecipitation and western blot using anti-myc and anti-GFP antibodies. Experiments were repeated once by a different 
investigator with similar result. Anti-alpha tubulin is loading control. 
 
 
 
 
Supplementary Figure 4 
Localization of V266P mutant Gorab to basal bodies. 
Ciliated neurons from femoral chordotonal organs of flies expressing GFP-gorab
V266P
 in a gorab
1
 mutant background immunostained 
with dPLP to reveal basal bodies and with phalloidin to visualize actin in scolopale rods. Experiment was repeated once with similar 
result. Arrowheads, GFP-Gorab at basal bodies. Scale bar, 10 µm.  
 
 
 
Supplementary Figure 5 
C-terminally GFP-tagged wild-type Gorab rescues gorab
1
 mutant phenotypes 
(a) Fertility of wild type, gorab
1
mutant and rescued females. Wild type C-terminally GFP tagged gorab cDNA was expressed under the 
control of the ubiqutin promoter in gorab
1
 to rescue (Ubq-gorab
wt-
GFP, gorab
1
). Individual females were mated with wild type males and 
allowed to lay eggs at 25 
o
C for 6 days.Data points represent the number of progeny of individual females. Means ± s.e.m are shown 
for  n=15 females per genotype. p values of two tailed unpaired t-tests are shown. p value in blue indicates significant difference (99% 
confidence interval). Experiment repeated once with similar result.(b) Climbing ability of wild type, gorab
1
mutant and rescued flies. Wild 
type C-terminally GFP tagged gorab cDNA was expressed under the control of the ubiqutin promoter in gorab
1
 to give rescue (Ubq-
gorab
wt-
GFP, gorab
1
). Flies were raised at 29 
o
C and subjected to a climbing assay. Each data point represents the percentage of flies 
from a group of 15 flies. Means ± s.e.m are shown for N=3 independent experiments, n= 15 flies/genotype were investigated in each 
experiment. p values of two tailed unpaired t-tests are shown. p value in blue indicates significant difference (99% confidence interval). 
 
 
 
 
 
Supplementary Figure 6 
Centrosomal localization of human GORAB 
(a) Centrosomal localization of wild type and A220P mutant GORAB. U-2 OS cells transiently transfected with constructs constitutively 
expressing N terminally GFP-tagged wild type (left panel) or A220P mutant human GORAB. Pericentrin (PCNT, red) stains 
centrosomes, Golgin-97 (grey) highlights trans-Golgi. Main scale bar,2 µm. Inset scale bar, 0.2 µm. Experiments repeated twice with 
similar results.(b)GORAB localization inside the centrioles.3D-SIM micrographs of U-2 OS centrosomes immunostained for Pericentrin 
(blue), SAS6 (red) and GORAB (green). Centrosomes of top (upper panel) and side view (lower panel) are not identical. Experiments 
repeated twice with similar results. Asterisk, site of procentriole formation where SAS6 is recruited. Arrowheads indicate SAS6, which is 
initially recruited to the proximal lumen of the cartwheel-less mother centriole and which moves to the site of procentriole formation
45
. 
Scale bar, 200 nm. (c) Synergistic effect of SAS6 and GORAB on loss of centrosomes. U-2OS
p53DD
cells subjected to 3 times 72h 
siRNA treatments against the indicated genes. Fixed cells were immunostained with a combination of CENP-J and gamma-Tubulin 
antibodies to reveal centrioles and centrosomes..Each data point represent the percentage of cells with the given centrosome number 
from an independent experiment (n=100 cells). Means ± s.e.m are shown for N=4 independent experiments (n=100 cells/experiment)p 
values of two tailed unpaired t-tests are shown(99% confidence interval). (d)Representative images of U-2OS cells subjected to siRNAs 
against GFP (control) or GORAB and treated with a combination of 4 µM aphidicolin and 1.5 mM hydroxyurea (A/HU). Anti-gamma-
tubulin immunostaning reveals centrosomes (red) and DAPI staining (blue) reveals nuclei. Experiment repeated twice with similar 
results. Scale bar, 5 µm. (e) Quantification of centrosome numbers in U-2OS cell shown on d. Each data point represents the 
percentage of cells with a given number from an independent experiment (n=100 cells). Mean ± s.e.m are shown for N=3 independent 
experiments (n=100 cells/experiment).p values of two tailed unpaired t-tests are shown (99% confidence interval). (f) Anti-Gorab 
Western blot on GORAB depleted U-2 OS
p53DD
 cell lysates. Cells were subjected to3 siRNA treatments, each for 72h, with control or 
GORAB specific siRNAs to check the specificity of the GORAB antibody (Atlas, #HPA027250). Subsequent Coomassie staining of the 
membrane (CBB) proves a loading control. Experiment independently repeated once with similar results.(g) Fluorescent micrographs of 
control and GORAB-depleted U-2 OS
p53DD
 cells stained with DAPI (blue) and anti-GORAB (green) to demonstrate the specificity of 
GORAB antibody (Atlas, #HPA027250). Cells were subjected to3 siRNA treatments, each for 72h, with control or GORAB specific 
siRNAs followed by fixation in 4% formaldehyde and immunostaning. Experiment independently repeated once with similar results. 
Scale bar,5 µm. 
 


Gorab is a Golgi protein required for structure and duplication of Drosophila centrioles

Gorab is a Golgi protein required for structure and duplication of Drosophila centrioles.

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