Science - USA (2020-03-13)

(Antfer) #1

even with two copies of C1 (Fig. 1C, blue), the
latter possibly attributable to the loss of sub-
unit H. The enzyme preparation had an ATP
hydrolysis rate that decreased during hydro-
lysis, consistent with the complex lacking sub-
unit H ( 24 , 26 ) (fig. S2). Further, the preparation
did not demonstrate full coupling of ATPase
activity in the V 1 region to proton transport
through the VOregion: Bafilomycin, which
blocks the VOregion, only partially inhibited
ATPase activity. This lack of coupling could
be due to free V 1 complexes that remain ac-
tive because subunit H is not present or to the
detergent-solubilized V-ATPase disassembling
during ATP hydrolysis, as seen with theManduca
sextaenzyme ( 28 ). The extent of SidK inhibi-
tion of ATP hydrolysis activity could not be
quantified because only the SidK-bound form
of the enzyme was available, although previous
work has shown that SidK inhibitsS. cerevisiae
V-ATPase by ~40% ( 19 ).
Cryo–electron microscopy (cryo-EM) of the
preparation yielded three three-dimensional


(3D) maps, corresponding to ~120°-rotations
of the rotor subcomplex between states ( 25 ).
These rotational states of the enzyme had
overall resolutions of 3.9, 4.0, and 3.9 Å (figs.
S3 and S4). Focused refinement of rotational
state 1 was able to improve the resolution to
3.8 Å for the membrane region and 3.6 Å for
the catalytic region of the complex. Together,
these maps allowed the construction of an
atomic model for most of the complex, with a
few components—including parts of subunits
E1 and G2, the soluble N-terminal domain of
subunit a1, subunit C1, and several luminal
loops in the membrane region—modeled as
backbone with truncated side chains (Fig. 1D,
table S6, and fig. S5). Similar to the yeast VO
structure ( 8 , 29 ), no density was apparent for
the loop between residues 667 and 712 in sub-
unit a1. Owing to the averaging that occurs
during cryo-EM image analysis, the minor
population of complexes in the preparation
possessing subunit G1 rather than G2 could
produce a map that shows a weighted aver-

age of both isoforms. Alternatively, images of
complexes containing subunit G1 may be ex-
cluded during 2D- and 3D-image classification
if they do not average coherently with the
major population of complexes to produce high-
resolution map features. Where the map shows
high-resolution features for subunit G, it accom-
modates subunit G2 better than G1 (fig. S6),
which is consistent with most of the V-ATPase
complexes containing subunit G2. Interpolating
between the three rotational states produced a
movie (movie S1) that shows the conforma-
tional changes in the enzyme that couple ATP
hydrolysis in the V 1 region to proton pump-
ing through the VOregion. These changes
illustrate the flexibility of the enzyme, partic-
ularly in the peripheral stalks, subunit C1,
and N-terminal domain of subunit a1.
Previous high-resolution insight into the
structure of the eukaryotic V 1 region has been
limited to cryo-EM of the intact yeast V-ATPase
at ~7-Å resolution ( 19 , 25 , 29 ) and a 6.2- to 6.7-Å
resolution crystal structure of the autoinhibited

Abbaset al.,Science 367 , 1240–1246 (2020) 13 March 2020 2of7


E1

SidK

A

B2

G2

C1

d1

D
F

ATP6AP2/PRR
ATP6AP1/Ac45

c-ring

e2
f

a1CTD

a1NTD

Native MS of dissociated G at HCD 250V

+5

G1
G2

13621 Da (acetylated)
13578 Da (acetylated)

Calculated mass
not detected
MW=13578 ± 1 Da

Measured mass

2400 2800 3200 3600 m/z

2000

0

100

Relative peak intensity (%)

4000 6000 8000 10000 12000 14000 m/z

+19

+14

+16
+11+13

V 1 subunits

V 1 region
683369 ± 144 Da
727196 ± 121 Da
639513 ± 182 Da
102984 ± 35 Da
70852 ± 21 Da
56460 ± 1 Da
43811 ± 1 Da
34682 ± 13 Da

Measured mass
0.13%
0.13%
0.14%
0.03%
0.10%
0.01%
0%
0.10%

Difference
682452 Da
726264 Da
638641 Da
102953 Da
70782 Da
56462 Da
43811 Da
34646 Da

Calculated mass
A 3 B2 3 C1 1 D 1 E1 3 F 1 G2 3 SidK 3
A 3 B2 3 C1 2 D 1 E1 3 F 1 G2 3 SidK 3
A 3 B2 3 C1 0 D 1 E1 3 F 1 G2 3 SidK 3
A 1 SidK 1
Hspa8
B2
C1
SidK

Composition

+56

+57

+54

115000

100

Relative peak intensity (%)
12000
m/z

12500 13000 13500

kDa
198
98
62
49
38
28

14

6
3

a1
A
B2
C1
d1
SidK
D/E1
c
G2
G1
F
e2/(RNAseK)

H+

ATP
ADP

H+

Lumen

Ca2+

V-ATPase

VO region
clathrin

ATP
ADP
H+

H+
neurotransmitter

transporter
receptor

Synaptic
cleft

Dendrite

Docking
and
Priming
Fusion

Recycling

Loading Uncoating

Axon terminal
Cytoplasm

A

C

B D

Fig. 1. Overall structure of brain V-ATPase.(A) Cycle of synaptic vesicle loading,
docking and priming, fusion, and recycling. (B) SDS-PAGE of rat brain V-ATPase
isolated with 3×FLAG SidK1-278and gel filtration chromatography. (C)Nativemass
spectrometry (MS) of V 1 region (left) and native mass spectrometry of dissociated
subunit G (right) at a higher-energy collisional dissociation (HCD) voltage of 250 V.


The charge state for one peak per subunit is indicated. The table shows the
measured mass for each peak (± SD of fit) and the calculated mass depending on
subunit composition (table S5). The difference between calculated and measured
massesisindicated.m/z, mass/charge ratio. (D) Composite cryo-EM map (left) and
atomic model (right) of brain V-ATPase in rotational state 1. Scale bar, 25 Å.

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