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A genetic study of inositol trisphosphate involvement in phototransduction using Drosophila mutants
Vol.
132,
October
BIOCHEMICAL
No. 2, 1985 30,
AND
BIOPHYSICAL
COMMUNICATIONS
RESEARCH
Pages
1985
513-519
A GENETIC STUDY OF INOSITOL TRISPHOSPHATE INVOLVEMENT IN PHOTOTRANSDUCTION USING DROSOPHILA MUTANTS Hiroko
Inouel
, Tohru
1 Department School
of Physiology, of Medicine,
2 Department University Received
July
23,
Yoshioka'
and Yoehiki
Hotta*
Yokohama City University, Yokohama, 232 Japan
of Physics, of Tokyo,
Faculty of Science, Tokyo 113, Japan
1985
Phoephatidylinositol 4,5-biephoephate phosphodiesterase activity was visual found to be almost absent in the compound eyes of Drosophila mutant, norpA (no receptor potentials A). We compared the enzyme activities among independently isolated norpA alleles, each having a different degree of the vision defect. A close correlation was found between the size of receptor potentials (electroretinogrsm), phototactic behavior and the enzyme activity. The correlation exists not only among in a single, temperature-dependent allele under alleles, but also kept at 18'c different temperature; the enzyme activity of flies (phototactic) was about five times higher than that of the ones kept at 28'~ (blind). These results suggest that hydrolysis of phoephatidylinositol 4,5-bisphosphate is involved in phototransduction process in 0 1985 Academic Press, Inc. Drosophila eyes.
It
has
involved
as In
cl,*).
been
proposed
a second order mutants
bisphoephate
(PtdInsP2) mutant
potentials, rhabdomere
the rhabdomere a
reduced
fracture
both almost
of the
electronmicroscopy
Abbreviations: phosphatidylinositol; DG, diacylglycerol;
trisphoephate invertebrate
in the hypothesis,
any defects
(no
of the most
number
inositol
(InsP3) phototransduction
we examined in
is
if
Drosophila
phosphatidylinoeitol
4,5-
hydrolysis.
norpA
are
this
have
although (4)
messenger
to test
transduction
The
that
receptor
potentials
morphology
(3)
normal. extreme
and rhodopsin
has
allele
We also
receptor of
described was found
of norpA% particles
no
content
We have previously
intramembraneoue (3).
A)
revealed
demonstrated
that
that
to
by the
the
have
freezenorpA
InsP inoeitol trisphosphate; PtdIns, P&InsP *, phosphatidylinoeitol 4,5-bisphosphate; ERG, electroretinogram 0006-291X/85 513
AN
Copyright 0 1985 rights qf reproduction
$1.50
by Academic Press, Inc. in any form reserved.
Vol.
132,
No. 2, 1985
mutants
harbor
inositol
(PtdIns)
BIOCHEMICAL
deficits
We report defective close
(6)
in
in the correlations
behavioral including
in the
metabolism;
phosphodiesterase
defects
AND
extremely
this
paper
norpA
mutant
that
between the
PtdInsP2
the mutant
phosphatidyl-
of
and PtdIns
(5)
eyes.
phosphodiesterase
enzyme deficit
a temperature-sensitive
COMMUNICATIONS
the
(DC) kinase
low in
degrees
RESEARCH
to
eyes of Drosophila.
Materials Materials: of Canton-S
enzyme related
diacylglycerol
being
and
BIOPHYSICAL
activity
Furthermore, electrophysiological
among
the
mutant
is
we show and alleles
strain.
and Methods
As a normal strain, an inbred (CS) was used, from which all
Drosophila melanogaster strain the mutants used were derived. norpA- JMll , norpA= and norpA-. KO50
The alleles of norpA gene used were KO50 norpAis a temperature-sensitive allele and can produce receptor potentials when it is kept at lower temperature (less than 25'C), while it lacks the photoresponse at higher temperature (more than 28’C) (7). A mutant, sine oculis (without compound eyes) were also used to test -whether the enzyme is localized in the eyes. 32 P-labelled Preparation of 32 P-labelled PtdInsP : PtdInsP2 was -32 P labelled Drosophila -------El extracted from y the method described by Hauser and El berg (8) with a slight modification. Flies were fed for 24 hours $9 P labelled inorganic phosphate (0.1 mCi/O.5 ml of 1% sucrose). WhP labelled flies were homogenized by microhomogenizer and mixed with to extract phospholipids other than chloroform/methanol (l:l, v/v) The mixture was centrifuged chloroform/methanol/ PtdInsP . and v/v) was added to the precipitate. concentgated IX1 (200:100:0.75, 0.2 volume of 1 N HCl was added to the After the centrifugation, supernatant and the lower phase was washed with chloroform/methanol/l N Extracted phospholipids were separated by thin Hcl (3:48:47, v/v). layer chromatography on a silica gel plate (Art. 5631, Merck), developed chloroform/acetone/methanol/acetic acid/water (40:17:15:12:8, with were impregnated in 1% potassium oxalate solution v/v). The Yaates before use. P-labelled phospholipids were detected by autoradiography and the corresponding area of PtdInsP was scraped off and eluted with as described by chloroform/methanol/water/HCl (145:24$:115:1, v/v) Irvine et al. (9). This eluate was added with 0.25 volume of chloroform and the same volume of 1N HCl. The lower phase was taken and was neutralized with Tris.
Assay of PtdInsP2 phosphodiesterase: PtdInsP2 phosphodiesterase was assayedwith a react containing 50 mM Tris HCl (pH 7.01, 0.5 9n mixture f P PtdInsP2 (about 10,000 cpm) and head homogenate mM EDTA and 0.2 mM (0.17 mg protein) in a final volume of 0.1 ml. Concentration of the substrate was adjusted by adding non-radioactive PtdInsP2 extracted from bovine brain kindly supplied by Dr. Hayashi of Kobe University. Incubation was carried out for 5 min at room temperature (22.C) and the was terminated by adding 0.1 ml of 10% trichloroacetic acid reaction After centrifugation, followed by an addition of serum albumin. supernatant was washed with diethyl ether and neutralized with 1 N NaOH. They were then loaded on Dowex 1x8 column (formate form) and separated 514
Vol.
132,
BIOCHEMICAL
No. 2, 1985
AND
BIOPHYSICAL
as described by Downes and Michell (10). was taken and radioactivity was counted.
RESEARCH
An aliquot
COMMUNICATIONS
of each
fraction
Electroretinogram (ERG) measurement: ERG was obtained by placing one electrode on a compound eye and a reference electrode inside the body The cornea1 electrode was a fine cotton wick, kept moist with (11). 0.9% NaCl in a capillary tube. The reference electrode was a glass pipette with 30-50 um tip, filled with 0.9% NaCl. This electrode was inserted dorsally through soft thoracic-abdominal junction. Assay of phototactic behavior: For the assay of phototactic behavior, about one hundred flies were placed in two 6 cm-long, transparent plastic tubes connected mouth to mouth. Flies were tapped to one end, and the tube was placed 3 cm away and perpendicular to a 15 Wfluorescent lamp. Flies were left undisturbed under the condition until their spatial distribution became quasi-stable (about one minute). The phototactic index is calculated as number of flies in the lighter half Phototactic Index = log number of flies in the darker half The index is about 1.0 + 0.2 for normal strain under the condition The near-zero phototactic index indicates absence of described above. If flies phototaxis. are positively or negatively phototactic, the phototactic index becomes positive or negative, respectively.
Results PtdInsP2
phosphodiesterase
Fig.
1
products iS
of
anion
shows
[32P]PtdInsP2
extremely
reduced
intermediate
peak
also
in Fig
observed Although
the
homogenate, highly of
we
localized
--sine
oculis
could
demonstrate
within
the
(a mutant
the
with
eyes while
the marked alleles
A similar
is
the
evident
32 P-labelled
that
while
reduction
enzyme activities
compound
norpA
It
of
an InaP
norpA-
in InsP2
JMll
peak
showed
production
is
1.
isolated
Therefore,
chromatography
hydrolysis.
height.
in comparison
activity,
exchange
in the case of norpA=,
activity
enzyme
activity
indicate
that
compound
PtdInsP2
eyes.
without
eyes)
that
of normal
from
freeze-dried
isolated reductions that
were measured
the
brain
with
enzyme. 515
head
contains
only
fly.
10%
of
Secondly,
flies
is
the head homogenate
(6) not
eyes of norpA
enzyme manually
contained
(data
of the enzyme activity compound
whole
phosphodiesterase
Firstly,
did
the
high
not
shown).
in the
several
essentially
lack
Vol. 132, No. 2, 1985
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
a
b C
12
”
Elution
volume
(ml)
Fig. 1 Separation of radioactive product hydrolyzed from [32P] PtdInsP on Dowex 1x8 column (formate form). Elution was with (a) 0.1 M fox& acid/O.2 M ammonium formate (for inorganic phosphate and inoaitol (b) 0.1 M formic acid/O.4 M ammonium formate (for monophosphate); inositol bisphosphate); (c) 0.1 M formic acid/l.0 M ammonium formate (for inositol trisphosphate). 10 ml of each solution were run through Note at constant flow (0.3 ml/min) and the fraction volume was 1 ml. that the inositol trisphosphate peak is almost absent in es, but X411 small peak is present in norpA=. A; e-, 0: normal, EE5 l ;norpA--.
ERG, phototactic
two
index ---2
b, behavioral
In Fig
2a,
norpA
alleles
extreme
On
receptor
small
the
is
in Fig
in
parallel
other
2c.
and
It with
with
those
no receptor
hand,
activities
phosphodiesterase summarized
have
potentials
phosphodiesterase
and electrophysiological
are compared norpA%,
allele,
phototactic.
and PtdInsP
normal
of
potentials
a milder
partially
allele
fly.
the
mutants
Is clear
that
degree
behavioral
The
The
described of the
and
of the
and entirely JMll of norpA-
phototactic.
of
the
syndromes
most nonshows
PtdInsP2
above
are
enzyme deficiency
electrophysiological
abnormalities. PtdInsP, We allele,
phosphodiesterase
activity
-of temperature-sensitive
the enzyme activity of a assayed KO50 This mutant produces norpA-. 516
temperature-sensitive receptor
potentials
mutant
E norpA
and
is
Vol.
132,
No. 2, 1985
BIOCHEMICAL
(a)
AND
( I 1
ERG
BIOPHYSICAL
RESEARCH
( II 1
( 111 1
COMMUNICATIONS
L-----b
(b)
Fig 2 Electropbysiological, behavioral and biochemical abnormalities of norpA mutants; Index and (c) relative (a) ERG, (b) phototactic phosphodieaterase activity for PtdInaP2. I, II and III represent normal, norpA= and-=, respectively. Note close correlations between the electrophysiological, behavioral PtdIneP2 and phosphodiesterase defects among the alleles. The values of the enzyme expressed as nmol/mg protein/5 min for normal, activity g&l-land norpA= are 39.6 + 5.7 (n=lD), 3.2 + 0.6 (n=4) and 1.0 + 0.6 (n=6), respectively. The error bare in the figure represents S.D. For details of experimental conditions, 886 Materials and Methods.
phototactic when
when it
shifted
to
essentially
no
temperature wa8 also
norpA=
28-c.
shown
norpA-
KO50 (Table
at
On the
difference
was altered
The effect the
is raised
while
18-C,
other
hand,
in ERG nor from
18
it
becomes
28
‘C.
blind
strain
showed
the normal
in phototaxis
'C to
entirely
when
The blindness
the
breeding
of norpA=
to be temperature-independent. of temperature head homogenate 1).
The
on the PtdInsP2 was compared enzyme
activity 517
hydrolyzing with was
that
of
markedly
activities
of
normal
and
reduced
in
Vol.
132,
No.
2, 1985
BIOCHEMICAL
AND
Table Phosphatidylinoaitol
BIOPHYSICAL
RESEARCH
1
4,5-bisphosphate
phosphodiesterase
Breeding
Temperature
18-c normal
COMMUNICATIONS
28-C
37.8 + 6.6
(5)
41.3 + 4.7
(6)
nor-&=
4.1 + 1.1
(4)
0.9 + 0.3
(5)
m=
1.3 + 0.1
(3)
0.8 + 0.1
(3) The the
The assay conditions are described in the legend of Fig. 1. is expressed as nmol/mg protein/5 min. Values are activity means + S.D. Number of experiments is give in the parenthesis.
KO50
IlorpA-
when it
activity
was found
breeding
raised
at
norpA- KO50
the
of
change
is
in the
temperature
On the
28-c.
kept
at 18'~
enzyme activity
other
was
hand,
the
significantly
of normal
and
enzyme
high.
No
norpA=,
when
was altered.
Discussion In
the
activity
present
is
study,
localized
correlation
is
in the
present
abnormality
that
exists
single,
correlation
temperature.
was observed The the
metabolism of
compound
eyes of fly
among norpA
not
only
the
messenger possibility
primary in
in
defect
the eye.
mutant
will the
that
nor
of such a close
If
this
shed light signal the
norpA
is
the
gene
effect in the
function 518
alleles
case,
and showed
also
in a
different
enzyme activity
strain. a
near
possibility the
the more detailed
PtdInsP2 analysis
of InsP
However, is
but
suggests in or
close
activity
under
norpA%
is
a
We also
on the
on the hypothesis
transduction.
enzyme
norpA-, KO50
mutants
and
mutants.
correlation
of norpA
heads,
among mutant
allele,
in the normal
phosphodiesterase
of the
Such a temperature
neither
presence
PtdInsP2
the reduction
temperature-sensitive
breeding
that
that
between
electrophysiological this
we found
essential
as a second 3 we cannot exclude a for
the
general
Vol.
132,
No. 2, 1985
phospholipid since
BIOCHEMICAL
metabolism
the mutant
has abnormalities
PtdIns
phosphodiesterase
the
experiment
of InsP
or
by chemical
BIOPHYSICAL
in the membrane,
and
mutant
AND
3
injection analysis
especially
in other (5,6).
Direct into
RESEARCH
in PtdIns
enzymes,
turnover,
such as DG kinase
evidence
will
the photoreceptor
of intracellular
COMMUNICATIONS
InsP
be given
cells 3
in the
of
norpA
compound
eyes of Drosophila.
Acknowledgment form
This work was supported by Grants-in-Aid No. the Ministry of Education, Science and Culture
58124027 and 59123006 of Japan.
References 1.
Fein, A., Payne, R., Corson, D. W., Berridge, M. J. and Irvine, R. F. (1984) Nature 311, 157-160. A. J., Tarver, A. P., 2. Brown, J. E., Rubin, L. J., Ghalayini, Irvine, R. F., Berridge, M. J. and Anderson, R. E. (1984) Nature 311, 160-163. K. and Hotta, Y. (1982) The Structure of The Eye ted. 3. Hirosawa, Hollyfield, J. G.) pp. 45-53, Elsevier Biomedical, New York. Genetic Approach to the Nervous 4. Pak, W. L. (1979) Neurogenetics: System (ed. Breakefield, X. 0.) pp. 67-99, Elsevier, North-Holland. T., Inoue, H. and Hotta, Y. (1984) Biochem. Biophys. 5. Yoshioka, Res. Commun. 119, 389-395. T., Inoue, H. and Hotta, Y. J. Biochem. (Tokyo) (1985) 6. Yoshioka, 97, 1251-1254. Y. and Benzer, S. Proc. Natl. Acad. Sci. U. S. A. (1970) 7. Hotta, 67, 1156-1163. 8. Hauser, G. and Eichberg, J. Biochim. Biophys. Acta (1973) 326, 201-209. R. F., Letcher, A. J. and Dawson, R. M. C. (1984) Biochem. 9. Irvine, J. 218, 177-185. 10. Downes, C. P. and Michell, R. H. (1981) Biochem. J. 198, 133-140. 11. Hotta, Y. and Benzeer, S. (1969) Nature 222, 354-356.
519
by
132,
October
BIOCHEMICAL
No. 2, 1985 30,
AND
BIOPHYSICAL
COMMUNICATIONS
RESEARCH
Pages
1985
513-519
A GENETIC STUDY OF INOSITOL TRISPHOSPHATE INVOLVEMENT IN PHOTOTRANSDUCTION USING DROSOPHILA MUTANTS Hiroko
Inouel
, Tohru
1 Department School
of Physiology, of Medicine,
2 Department University Received
July
23,
Yoshioka'
and Yoehiki
Hotta*
Yokohama City University, Yokohama, 232 Japan
of Physics, of Tokyo,
Faculty of Science, Tokyo 113, Japan
1985
Phoephatidylinositol 4,5-biephoephate phosphodiesterase activity was visual found to be almost absent in the compound eyes of Drosophila mutant, norpA (no receptor potentials A). We compared the enzyme activities among independently isolated norpA alleles, each having a different degree of the vision defect. A close correlation was found between the size of receptor potentials (electroretinogrsm), phototactic behavior and the enzyme activity. The correlation exists not only among in a single, temperature-dependent allele under alleles, but also kept at 18'c different temperature; the enzyme activity of flies (phototactic) was about five times higher than that of the ones kept at 28'~ (blind). These results suggest that hydrolysis of phoephatidylinositol 4,5-bisphosphate is involved in phototransduction process in 0 1985 Academic Press, Inc. Drosophila eyes.
It
has
involved
as In
cl,*).
been
proposed
a second order mutants
bisphoephate
(PtdInsP2) mutant
potentials, rhabdomere
the rhabdomere a
reduced
fracture
both almost
of the
electronmicroscopy
Abbreviations: phosphatidylinositol; DG, diacylglycerol;
trisphoephate invertebrate
in the hypothesis,
any defects
(no
of the most
number
inositol
(InsP3) phototransduction
we examined in
is
if
Drosophila
phosphatidylinoeitol
4,5-
hydrolysis.
norpA
are
this
have
although (4)
messenger
to test
transduction
The
that
receptor
potentials
morphology
(3)
normal. extreme
and rhodopsin
has
allele
We also
receptor of
described was found
of norpA% particles
no
content
We have previously
intramembraneoue (3).
A)
revealed
demonstrated
that
that
to
by the
the
have
freezenorpA
InsP inoeitol trisphosphate; PtdIns, P&InsP *, phosphatidylinoeitol 4,5-bisphosphate; ERG, electroretinogram 0006-291X/85 513
AN
Copyright 0 1985 rights qf reproduction
$1.50
by Academic Press, Inc. in any form reserved.
Vol.
132,
No. 2, 1985
mutants
harbor
inositol
(PtdIns)
BIOCHEMICAL
deficits
We report defective close
(6)
in
in the correlations
behavioral including
in the
metabolism;
phosphodiesterase
defects
AND
extremely
this
paper
norpA
mutant
that
between the
PtdInsP2
the mutant
phosphatidyl-
of
and PtdIns
(5)
eyes.
phosphodiesterase
enzyme deficit
a temperature-sensitive
COMMUNICATIONS
the
(DC) kinase
low in
degrees
RESEARCH
to
eyes of Drosophila.
Materials Materials: of Canton-S
enzyme related
diacylglycerol
being
and
BIOPHYSICAL
activity
Furthermore, electrophysiological
among
the
mutant
is
we show and alleles
strain.
and Methods
As a normal strain, an inbred (CS) was used, from which all
Drosophila melanogaster strain the mutants used were derived. norpA- JMll , norpA= and norpA-. KO50
The alleles of norpA gene used were KO50 norpAis a temperature-sensitive allele and can produce receptor potentials when it is kept at lower temperature (less than 25'C), while it lacks the photoresponse at higher temperature (more than 28’C) (7). A mutant, sine oculis (without compound eyes) were also used to test -whether the enzyme is localized in the eyes. 32 P-labelled Preparation of 32 P-labelled PtdInsP : PtdInsP2 was -32 P labelled Drosophila -------El extracted from y the method described by Hauser and El berg (8) with a slight modification. Flies were fed for 24 hours $9 P labelled inorganic phosphate (0.1 mCi/O.5 ml of 1% sucrose). WhP labelled flies were homogenized by microhomogenizer and mixed with to extract phospholipids other than chloroform/methanol (l:l, v/v) The mixture was centrifuged chloroform/methanol/ PtdInsP . and v/v) was added to the precipitate. concentgated IX1 (200:100:0.75, 0.2 volume of 1 N HCl was added to the After the centrifugation, supernatant and the lower phase was washed with chloroform/methanol/l N Extracted phospholipids were separated by thin Hcl (3:48:47, v/v). layer chromatography on a silica gel plate (Art. 5631, Merck), developed chloroform/acetone/methanol/acetic acid/water (40:17:15:12:8, with were impregnated in 1% potassium oxalate solution v/v). The Yaates before use. P-labelled phospholipids were detected by autoradiography and the corresponding area of PtdInsP was scraped off and eluted with as described by chloroform/methanol/water/HCl (145:24$:115:1, v/v) Irvine et al. (9). This eluate was added with 0.25 volume of chloroform and the same volume of 1N HCl. The lower phase was taken and was neutralized with Tris.
Assay of PtdInsP2 phosphodiesterase: PtdInsP2 phosphodiesterase was assayedwith a react containing 50 mM Tris HCl (pH 7.01, 0.5 9n mixture f P PtdInsP2 (about 10,000 cpm) and head homogenate mM EDTA and 0.2 mM (0.17 mg protein) in a final volume of 0.1 ml. Concentration of the substrate was adjusted by adding non-radioactive PtdInsP2 extracted from bovine brain kindly supplied by Dr. Hayashi of Kobe University. Incubation was carried out for 5 min at room temperature (22.C) and the was terminated by adding 0.1 ml of 10% trichloroacetic acid reaction After centrifugation, followed by an addition of serum albumin. supernatant was washed with diethyl ether and neutralized with 1 N NaOH. They were then loaded on Dowex 1x8 column (formate form) and separated 514
Vol.
132,
BIOCHEMICAL
No. 2, 1985
AND
BIOPHYSICAL
as described by Downes and Michell (10). was taken and radioactivity was counted.
RESEARCH
An aliquot
COMMUNICATIONS
of each
fraction
Electroretinogram (ERG) measurement: ERG was obtained by placing one electrode on a compound eye and a reference electrode inside the body The cornea1 electrode was a fine cotton wick, kept moist with (11). 0.9% NaCl in a capillary tube. The reference electrode was a glass pipette with 30-50 um tip, filled with 0.9% NaCl. This electrode was inserted dorsally through soft thoracic-abdominal junction. Assay of phototactic behavior: For the assay of phototactic behavior, about one hundred flies were placed in two 6 cm-long, transparent plastic tubes connected mouth to mouth. Flies were tapped to one end, and the tube was placed 3 cm away and perpendicular to a 15 Wfluorescent lamp. Flies were left undisturbed under the condition until their spatial distribution became quasi-stable (about one minute). The phototactic index is calculated as number of flies in the lighter half Phototactic Index = log number of flies in the darker half The index is about 1.0 + 0.2 for normal strain under the condition The near-zero phototactic index indicates absence of described above. If flies phototaxis. are positively or negatively phototactic, the phototactic index becomes positive or negative, respectively.
Results PtdInsP2
phosphodiesterase
Fig.
1
products iS
of
anion
shows
[32P]PtdInsP2
extremely
reduced
intermediate
peak
also
in Fig
observed Although
the
homogenate, highly of
we
localized
--sine
oculis
could
demonstrate
within
the
(a mutant
the
with
eyes while
the marked alleles
A similar
is
the
evident
32 P-labelled
that
while
reduction
enzyme activities
compound
norpA
It
of
an InaP
norpA-
in InsP2
JMll
peak
showed
production
is
1.
isolated
Therefore,
chromatography
hydrolysis.
height.
in comparison
activity,
exchange
in the case of norpA=,
activity
enzyme
activity
indicate
that
compound
PtdInsP2
eyes.
without
eyes)
that
of normal
from
freeze-dried
isolated reductions that
were measured
the
brain
with
enzyme. 515
head
contains
only
fly.
10%
of
Secondly,
flies
is
the head homogenate
(6) not
eyes of norpA
enzyme manually
contained
(data
of the enzyme activity compound
whole
phosphodiesterase
Firstly,
did
the
high
not
shown).
in the
several
essentially
lack
Vol. 132, No. 2, 1985
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
a
b C
12
”
Elution
volume
(ml)
Fig. 1 Separation of radioactive product hydrolyzed from [32P] PtdInsP on Dowex 1x8 column (formate form). Elution was with (a) 0.1 M fox& acid/O.2 M ammonium formate (for inorganic phosphate and inoaitol (b) 0.1 M formic acid/O.4 M ammonium formate (for monophosphate); inositol bisphosphate); (c) 0.1 M formic acid/l.0 M ammonium formate (for inositol trisphosphate). 10 ml of each solution were run through Note at constant flow (0.3 ml/min) and the fraction volume was 1 ml. that the inositol trisphosphate peak is almost absent in es, but X411 small peak is present in norpA=. A; e-, 0: normal, EE5 l ;norpA--.
ERG, phototactic
two
index ---2
b, behavioral
In Fig
2a,
norpA
alleles
extreme
On
receptor
small
the
is
in Fig
in
parallel
other
2c.
and
It with
with
those
no receptor
hand,
activities
phosphodiesterase summarized
have
potentials
phosphodiesterase
and electrophysiological
are compared norpA%,
allele,
phototactic.
and PtdInsP
normal
of
potentials
a milder
partially
allele
fly.
the
mutants
Is clear
that
degree
behavioral
The
The
described of the
and
of the
and entirely JMll of norpA-
phototactic.
of
the
syndromes
most nonshows
PtdInsP2
above
are
enzyme deficiency
electrophysiological
abnormalities. PtdInsP, We allele,
phosphodiesterase
activity
-of temperature-sensitive
the enzyme activity of a assayed KO50 This mutant produces norpA-. 516
temperature-sensitive receptor
potentials
mutant
E norpA
and
is
Vol.
132,
No. 2, 1985
BIOCHEMICAL
(a)
AND
( I 1
ERG
BIOPHYSICAL
RESEARCH
( II 1
( 111 1
COMMUNICATIONS
L-----b
(b)
Fig 2 Electropbysiological, behavioral and biochemical abnormalities of norpA mutants; Index and (c) relative (a) ERG, (b) phototactic phosphodieaterase activity for PtdInaP2. I, II and III represent normal, norpA= and-=, respectively. Note close correlations between the electrophysiological, behavioral PtdIneP2 and phosphodiesterase defects among the alleles. The values of the enzyme expressed as nmol/mg protein/5 min for normal, activity g&l-land norpA= are 39.6 + 5.7 (n=lD), 3.2 + 0.6 (n=4) and 1.0 + 0.6 (n=6), respectively. The error bare in the figure represents S.D. For details of experimental conditions, 886 Materials and Methods.
phototactic when
when it
shifted
to
essentially
no
temperature wa8 also
norpA=
28-c.
shown
norpA-
KO50 (Table
at
On the
difference
was altered
The effect the
is raised
while
18-C,
other
hand,
in ERG nor from
18
it
becomes
28
‘C.
blind
strain
showed
the normal
in phototaxis
'C to
entirely
when
The blindness
the
breeding
of norpA=
to be temperature-independent. of temperature head homogenate 1).
The
on the PtdInsP2 was compared enzyme
activity 517
hydrolyzing with was
that
of
markedly
activities
of
normal
and
reduced
in
Vol.
132,
No.
2, 1985
BIOCHEMICAL
AND
Table Phosphatidylinoaitol
BIOPHYSICAL
RESEARCH
1
4,5-bisphosphate
phosphodiesterase
Breeding
Temperature
18-c normal
COMMUNICATIONS
28-C
37.8 + 6.6
(5)
41.3 + 4.7
(6)
nor-&=
4.1 + 1.1
(4)
0.9 + 0.3
(5)
m=
1.3 + 0.1
(3)
0.8 + 0.1
(3) The the
The assay conditions are described in the legend of Fig. 1. is expressed as nmol/mg protein/5 min. Values are activity means + S.D. Number of experiments is give in the parenthesis.
KO50
IlorpA-
when it
activity
was found
breeding
raised
at
norpA- KO50
the
of
change
is
in the
temperature
On the
28-c.
kept
at 18'~
enzyme activity
other
was
hand,
the
significantly
of normal
and
enzyme
high.
No
norpA=,
when
was altered.
Discussion In
the
activity
present
is
study,
localized
correlation
is
in the
present
abnormality
that
exists
single,
correlation
temperature.
was observed The the
metabolism of
compound
eyes of fly
among norpA
not
only
the
messenger possibility
primary in
in
defect
the eye.
mutant
will the
that
nor
of such a close
If
this
shed light signal the
norpA
is
the
gene
effect in the
function 518
alleles
case,
and showed
also
in a
different
enzyme activity
strain. a
near
possibility the
the more detailed
PtdInsP2 analysis
of InsP
However, is
but
suggests in or
close
activity
under
norpA%
is
a
We also
on the
on the hypothesis
transduction.
enzyme
norpA-, KO50
mutants
and
mutants.
correlation
of norpA
heads,
among mutant
allele,
in the normal
phosphodiesterase
of the
Such a temperature
neither
presence
PtdInsP2
the reduction
temperature-sensitive
breeding
that
that
between
electrophysiological this
we found
essential
as a second 3 we cannot exclude a for
the
general
Vol.
132,
No. 2, 1985
phospholipid since
BIOCHEMICAL
metabolism
the mutant
has abnormalities
PtdIns
phosphodiesterase
the
experiment
of InsP
or
by chemical
BIOPHYSICAL
in the membrane,
and
mutant
AND
3
injection analysis
especially
in other (5,6).
Direct into
RESEARCH
in PtdIns
enzymes,
turnover,
such as DG kinase
evidence
will
the photoreceptor
of intracellular
COMMUNICATIONS
InsP
be given
cells 3
in the
of
norpA
compound
eyes of Drosophila.
Acknowledgment form
This work was supported by Grants-in-Aid No. the Ministry of Education, Science and Culture
58124027 and 59123006 of Japan.
References 1.
Fein, A., Payne, R., Corson, D. W., Berridge, M. J. and Irvine, R. F. (1984) Nature 311, 157-160. A. J., Tarver, A. P., 2. Brown, J. E., Rubin, L. J., Ghalayini, Irvine, R. F., Berridge, M. J. and Anderson, R. E. (1984) Nature 311, 160-163. K. and Hotta, Y. (1982) The Structure of The Eye ted. 3. Hirosawa, Hollyfield, J. G.) pp. 45-53, Elsevier Biomedical, New York. Genetic Approach to the Nervous 4. Pak, W. L. (1979) Neurogenetics: System (ed. Breakefield, X. 0.) pp. 67-99, Elsevier, North-Holland. T., Inoue, H. and Hotta, Y. (1984) Biochem. Biophys. 5. Yoshioka, Res. Commun. 119, 389-395. T., Inoue, H. and Hotta, Y. J. Biochem. (Tokyo) (1985) 6. Yoshioka, 97, 1251-1254. Y. and Benzer, S. Proc. Natl. Acad. Sci. U. S. A. (1970) 7. Hotta, 67, 1156-1163. 8. Hauser, G. and Eichberg, J. Biochim. Biophys. Acta (1973) 326, 201-209. R. F., Letcher, A. J. and Dawson, R. M. C. (1984) Biochem. 9. Irvine, J. 218, 177-185. 10. Downes, C. P. and Michell, R. H. (1981) Biochem. J. 198, 133-140. 11. Hotta, Y. and Benzeer, S. (1969) Nature 222, 354-356.
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