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Metabolism of 25-hydroxyvitamin D3 in kidney homogenates of chicks supplemented with vitamin D3
BIOCHEMICAL
Vol. 85, No. 2, 1978
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
November 29,1978
Pages
601-607
METABOLISM OF 25-HYDROXYVITAMIN D3 IN KIDNEY HOMOGENATES OF CHICKS SUPPLEMENTED WITH VITAMIN D3 YOSHIKO TAKASAKI,
NOBORU HORIUCHI,
and TATSUO SUDA*
Department of Biochemistry, Showa University l-5-8, Hatanodai, Shinagawa-ku, Tokyo 142, Received
October
Dental Japan
School,
4,1978
Kidney homogenates from chicks fed a vitamin D-deficient diet Summary: for 10 days and supplemented with 6.5 nmol of vitamin D3 48 hr prior to sacrifice metabolized [3H]-25-hydroxyvitamin D3 (25-OH-D31 to 24,25-dihy--in vitro droxyvitamin D3 [24,25-(OH)2-D3] and 3 other metabolites (peaks A, C and E). When the homogenates were incubated with purified L3H]-24,25-(OH)2-D3, 3 simiOn high pressure liquid lar metabolites (peaks A', C' and E') were produced. chromatography, peaks A, C and E migrated to exactly the same respective pOSitions as peaks A', C' and E'. Kidney homogenates from D-deficient chicks failed to produce these metabolites from [3H]-2%OH-D3 or L3H]-24,25-(OH)2-D3. These results strongly suggest that the new metabolites reported here are synthesized via 24,25-(OH)2-D3 in the kidney of chicks supplemented with vitamin D3. INTRODUCTION It
is now well
hydroxyvitamin
established
D3 (25-OH-D3)
la,25-dihydroxyvitamin 25-(OH)2-D3] this
(1).
has not been the ly-
selective More
phosphate,
or during
kidney
--in vitro
of these
vitamin
situation
(3H]-25-OH-D3
thought
in
to 25-
the kidney
in
the
levels
form,
of plasma
has been were
since
calcium
of 24,25-(OH)2-D3, circumstances
to
D3 (24,
to be an active
when animals
D depletion,
however,
associated
investigated
with extensive-
in need of calcium
and more 24,25-(OH)2-D3
or
was produced
(2-6).
of investigating
homogenates
* To whom all Abbreviations dihydroxyvitamin
was produced
metabolized
or 24,25-dihydroxyvitamin
significance
metabolites
first
and subsequently
change
The physiological
la,25-(OH)2-D3
In the course that
The biological
formation
in the opposite
has been
a remarkable
established.
D3 is
in the liver,
la,25-(OHj2-D3 induces
and phosphate
vitamin
D3 [lu,25~-(OH)~-D~]
(1).
metabolite
that
from chicks to 3 other
renal
24-hydroxylase
supplemented metabolites
with besides
activity, vitamin
D3
we found metabolize
24,25-(OHj2-D3.
The
correspondence should be addressed. used: 25-OH-D3, 25-hydroxyvitamin D3; la,25-(OH)2-D3, 24,25-dihydroxyvitamin D3. D3; 24,25-(OHj2-D3,
la,25-
0006-291X/78/0852-0601$01.00/0 601
Copyright All rights
0 1978 by Academic Press. Inc. of reproduction in any form reserved
Vol. 85, No. 2, 1978
present
report
OH-D3 via
BIOCHEMICAL
describes
that
24,25-(OH)2-D3
in
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
these
new metabolites
the kidney
of chicks
MATERIALS Animals: One-day-old White days on a vitamin D-deficient calcium and 0.45% phosphorus. 6.5 nmol of vitamin D3 48 hr minced with removed, rinsed, 0.2 M sucrose containing 15 5 mM sodium succinate.
are
synthesized
supplemented
from 25-
with
vitamin
D3.
AND METHODS
Leghorn cockerel chicks were maintained for 10 purified soy protein diet (7) containing 3% Most of the animals were orally predosed with prior to sacrifice. The kidneys were quickly a garlic press, and homogenized in 4 volumes of mM Tris-Cl (pH 7.4), 2 mM MgC12, 0.4 mM NADP, and
Incubation: The homogenates (1.5 ml) were incubated in 20 ml-Erlenmeyer flasks with 10 pmol (0.1 uCi) of either [26,27-3H]-25-OH-D3 (Radiochemical Centre, Amersham) or [26,27-3H]-24,25-(OH)2-D3. The iucubation was carried out at 37OC for 5-60 min under 100% oxygen. The reactions were terminated by the addition of 9 ml of methanol-chloroform (2:l v/v). Extraction was performed as reported by Gray et al. (8). Chromatography: Chromatography of the extracts was carried out on a 1 x 30 cm column of Sephadex LH-20 (10 g) using a solvent of 65% chloroform - 35% hexane High pressure liquid chromatography(HPLC) according to Holick and DeLuca (9). was performed on a Waters HPLC system (Model 440) equipped with a Zorbax-Sil column (2.1 mm x 25 cm, Du Pant) . The solvent system was either 0.67% or 2% Thirtymethanol in dichloromethane according to Ikekawa and Koizumi (13). Determifour 0.25 ml fractions were collected at a flow rate of 0.5 ml/min. nation of radioactivity was carried out with a Packard liquid scintillation counter (Model 3255) as previously reported (10). Preparation of [26,27-3~1-24,25-(OH)~-~~i Kidney homogenates of chicks predosed intravenously with 312.5 pmol of la-hydroxyvitamin D3 24 hr prior to sacrifice were incubated with r3H]-25-OH-D3 at 37OC for 20 min. [3~]-24,25(OH)2-D3 was purified on the Sephadex LH-20 and HPLC column described above. Crystalline vitamin D3 was purchased from Tokyo Chemical Industry, and 25OH-D3 from Phillips-Dupher Co., Amsterdam. Crystalline la,25-(OH)2-D3 and 24R,25-(OH)2-D3 were gifts from Dr. M. R. Uskokovie, Hoffman-La Roche Inc., New Jersey. la-hydroxyvitamin D3 was a gift from Dr. I. Matsunaga, Chugai Pharmaceutical Co., Tokyo. RESULTS AND DISCUSSION Administration
of 6.5
ly suppressed
renal
tivity
I).
In the course
that
the
ity,
(Table we found
from Sephadex
LH-20
The heterogeneity
25-OH-D3-la-hydroxylase
columns of the
by Garabedian
OH-D3 and the
24,25-(OHj2-D3
were
individually
and the
were
both
heterogeneous fraction
applied
fractions
(11)
fractions
on Sephadex
to HPIC column,
602
the
LH-20 former
by HPLC.
LH-20
(12).
activ-
isolated
when purified
Sephadex
ac-
24-hydroxylase
and Gray et al. from
complete-
24-hydroxylase
renal
24,25-(OH)2-D3
24,25-(OHj2-D3 et al. --
chicks
and enhanced
of investigating
25-OH-D3
been reported
(a))
D3 to D-deficient
nmol of vitamin
column
When the
columns
(Fig
was separated
has
251. into
~~-
Failure
100% N2*** 24,25-(OHj2-D3
Boiled** 24,25-(OH),-0,
24,25-(OHj2-D3
Control 25-OH-D3
___...
24,25-(OH),-D3
Control 25-OH-D3
Substrate
Incubation*
I.
of
-.---.
0 0
0 0
0
0
0
0
15.4 13.9
0
22.2
15.9
0
39.6
0 ~- ___.-_._.
Trace -15.8
0
Trace
24.8
0
%
0
0
0
0
47.6
45.2
25.8
23.3
0
0
0
0
Peak
new metabolites
25-OH-D3
the
17.6
%
A
of
0
Peak
synthesis
%
C
91.7
92.0
98.5
97.7
27.3
25.9
23.1
9.5
89.6
87.2
0
0
24,25-(OHj2-D3
by kidney
%
were
homogenates
The 25-OH-D3 and the 24,25-(OH)2-D3 fractions from Sephadex LH-20 columns Figures in Table I are expressed as percentage of the sum of the radioactivity on HPLC. * All incubations were performed for 60 min. l * boiled homogenates for 5 min at 100°C prior to incubation. *** incubated for 60 min under 100% N2.
6.5
0
nmol
Predose of D3
Table
%
E
separately recovered
0
0
0
0
8.8
8.4
8.0
5.1
Trace
Trace
0
0
Peak
from
in
%
to HPLC columns. l-34 fractions
8.3 applied each
8.0 0
1.5
0
2.3
2.4
5.1
5.0
6.7
3.2
5.4
12.0
8.8
Others
0
%
chicks.
0
0
0
0
0
0
0
63.2
73.6
la,25-(OH)2-D3
D-deficient
Vol. 85, No. 2, 1978
BIOCHEMICAL
AND BIOPHYSICAL
4 (b) t
25-OH-D3 Fraction
.-;;E 3
RESEARCH COMMUNICATIONS
s .-z3
24,25-(OH)>-D,
4 2
e
24.25~(OH),-03 Fract!on
,
‘: 0
2-
; e
Fraction
. 25-OH-D, Fractmn
l-
Number
( 3rd)
Fig 1. Sephadex LH-20 chromatographic profiles of extracts of kidney homogenates from chicks orally dosed with 6.5 nmol of vitamin D3. The reaction conditions are described under MATERIALS AND METHODS. The columns containing 10 g of Sephadex LH-20 were eluted with chloroform : n-hexane (65:35, v/v) and 3 ml fractions were collected. Panel (a) represents a chromatographic profile of the extracts when the homogenates were incubated for 60 min with 10 pmol (0.1 PCi) of [3H]-25-OH-D3 and panel (b) with 10 pmol (0.1 UCi) of 13H]-24,25(OH) 2-D3.
2 peaks: with
authentic
3 peaks: tic
an unknown
peak referred
25-OH-D3
2 unidentified
24R,25-(OH)2-D3
that
from
metabolites
of vitamin in this
radioactive 1.
might
was referred
3 peaks:
failed
were
2 unidentified
reported
that
2.
was
by Gray et al.
604
produced
new metabolites
(12).
[3H]-24,25-(OH)2-D3, on Sephadex
LH-20
not
fraction and peak
which
produce
25-OH-D3
to exactly
the
was also D' which
a columns
peak was homogeneous, did
similar
Thus,
Peak A' migrated
C' and E',
However,
(12).
fraction
The homogenates
resemble
administration
purified
radioactive
authen-
whereas
by Gray et al.
25-OH-D3
with
into
here,
from
with
separated
(12).
of lc~,25-(OH]~-D~
those
coincided
coincided
them
The 24,25-(OHj2-D3 peaks
latter
to produce
the
cc)).
B which
new metabolites
reported
incubated
in the
to as peak A'.
as peak A on HPLC.
Some of these
to those
be different
(Fig
On HPLC the
administration
HPLC showed
[3H]-24,25-(OH)2-D3 tion
prior
peak appeared (b)).
(b)).
recently
D3 or 25-OH-D3 study
(a)).
A, and peak
C and E, and peak D which
r3H]-25-OH-D,
When the homogenates
(Fig
2.
those
demonstrated
2.
peaks (Fig
chromatographically they
(Fig
to as peak
from
same posi-
separated
coincided
into with
BIOCHEMICAL
Vol. 85, No. 2, 1978
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
i.
10
5 Time
( mln
15
10
5
Time
1
15
(min)
Fig 2. HPLC profiles of the 25-OH-D3 and the 24,25-(OH)2-D3 fractions colHPLC Panels (a) and (c) represent lected from the Sephadex LH-20 columns. (tubes 6-13) shown on Fig 1. (al and (b), profiles of the 25-OH-D3 fraction respectively. Panels (b) and (d) indicate those of the 24,25-(OH)2-D3 fraction (tubes 16-35) on Fig 1. (a) and (b), respectively. Before applying to 500 pmol of authentic 25-OH-D3 (in panels (a) and (c)) or 24R, HPLC columns, The columns 25-(OH)2-D3 (in panels (b) and (d)) were added to each extract. were eluted with a solvent of either 0.67% methanol (in panels (a) and (c)) or 2% methanol (in panels (b) and (d)) in dichloromethane.
authentic
24R,25-(OH12-D3
exactly were
(Fig
the same respective preheated
at 100°C
and E' were
produced,
matically.
Production
under
100% nitrogen Figure
D3 and peaks D3 for in 5-10
5-60
2.
positions for
5 min,
indicating
(Table
3 indicates
as peaks neither
that
of these
On HPLC peaks
(a)).
metabolites
time
Amounts
min and decreased
C and E gradually
increased
A, C and E nor
metabolites
are
was also
suppressed
peaks
A',
synthesized
C' enzy-
completely
I). course
of change
A, C and E when the homogenates min.
to
When the homogenates
C and E.
peaks
these
C' and E' migrated
of 24,25-(OHj2-D3 thereafter. during
in
the amounts-of
were produced
On the other the incubation
605
incubated
with
attained hand,
period
24,25-(OHJ2F3H]-25-OH-
a maximal
amounts of 60 min.
level
of peaks
A,
When the
Vol. 85, No. 2, 1978
BIOCHEMICAL
0
AND BIOPHYSICAL
30
15 Incubation
Time
RESEARCH COMMUNICATIONS
45 ( min
60
)
proFig 3. Time course of change in the amounts of the 25-OH-D3 metabolites duced by kidney homogenates from chicks dosed with 6.5 nmol of vitamin D3. Incubations were carried out with 10 pmol (0.1 uCi) of [3H]-25-OH-D3 as described under MATERIALS AND METHODS. Results are expressed as percentage of the radioactivity recovered as peak A (--A- ), peak C (-0 ), and peak E (--&-). The vertical bar 24,25-(OH),-D3 ( -), indicates standard error of the mean of 3-4 experiments.
homogenates major
were
incubated
metabolite
relatively
was peak
minor
failed
ones
to produce The results
(peaks
behaviors fied
with
reported
here
D-deficient the time
course
A, C and E fits Biological in view under
of the investigation
Second,
25-OH-D3
from
peaks
or 24,25-(OHj2-D3
of change
in the
these amounts
in the kidney
metabolites
(Table
I).
Third, kidney
of chicks
from puri-
A, C and E migrate
Fourth,
chicks
chromatographic
are produced
C' and E'.
produced
were
of 25-OH-D3
C' and E' with
on HPLC peaks A',
and E (or E')
the metabolites
A',
the
from D-deficient
24,25-(OH)2-D3
24,25-(OHj2-D3.
to produce
to exactly
the homogenates homogenates
from 25-OH-D3. of 24,25-(OH),-D3
from
Finally, and peaks
the above hypothesis.
significance control
25-OH-D3 that
as peaks
fail
with
A (or A')
A, C and E, respectively,
positions
chicks
First,
D3.
to peaks
the same respective
indicate via
[3H]-24,25-(OH)2-D3,
homogenates
from
synthesized
or
and peaks
Kidney
metabolites
[3H]-24,25-(OH)2-D3.
do not produce
I).
these
vitamin
similar
13H]-25-OH-D3
C (or C'),
(Table
A, C and E) are
supplemented
with
of
mechanism in our
these
metabolites
of 25-OH-D3
laboratory.
606
is metabolism,
of considerable which
is
interest currently
Vol. 85, No. 2, 1978
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
REFERENCES 1.
DeLuca,
H. F.,
2.
Boyle, I. T., Gray, USA 68, 2131-2134.
3.
Tanaka, 574.
4.
Horiuchi, N., Suda, (1974) FEBS Letters
5.
Tanaka,
Y.,
6.
Hughes, Baylink,
M. R., Brumbaugh, P. F., Haussler, D. J. (1975) Science 190, 578-580.
-7.
Gmdahl, J., Biochemistry
8.
Gray, R. W., Gmdahl, J. L., Ghazarian, J. Biol. Chem. 247, 7528-7532.
9.
Holick,
Y.,
and Schnoes, R. W.,
and DeLuca, T., 43,
and DeLuca,
and DeLuca,
H. F.
H. F.
and DeLuca,
S.,
Ezawa,
(1974)
Suda,
H. F.
11.
Garabedian, M., Bailly Du Bois, Balsan, S. (1978) Endocrinology
12.
Gray, R. W., Caldas, A. E., Weber, Biochem. Biophys, Res. Commun. 82,
13.
Ikekawa,
Proc.
M. R., Y.,
Y.,
607
J. Chrmatogr.
154,
Wergedal,
Sci.
566-
J. E.,
and DeLuca,
Res.
12,
Pezant,
J. L., and Ghazarian, 121-128.
N. (1976)
Acad.
E.
1198-1200.
Ogata, E., Ezawa, I., Biophys. 171, 540-548.
M., Corvol, M. T., 102, 1262-1268.
Nat.
631-666.
and Ogata,
and DeLuca,
J. Lipid
e,
Biophys.
Sano. 183,
J. G.,
N., Suda, T., Sasaki, S., E. (1975) Arch. Biochem.
(1971)
I.,
Tanaka,
(1971)
Rev. Biochem.
Biochem.
Science
T.,
Horiuchi, Shimazawa,
and Koizumi,
H. F. Arch.
10.
N.,
Ann.
(1973)
Sasaki, 353-356.
Holick, M. F., lo, 2935-2940.
M. F.,
H. K. (1976)
-119,
H. F.
H. F.
and (1971)
(1972)
460-465. SanO, Y., E.,
and
J. G. (1978) 227-232.
and
Vol. 85, No. 2, 1978
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
November 29,1978
Pages
601-607
METABOLISM OF 25-HYDROXYVITAMIN D3 IN KIDNEY HOMOGENATES OF CHICKS SUPPLEMENTED WITH VITAMIN D3 YOSHIKO TAKASAKI,
NOBORU HORIUCHI,
and TATSUO SUDA*
Department of Biochemistry, Showa University l-5-8, Hatanodai, Shinagawa-ku, Tokyo 142, Received
October
Dental Japan
School,
4,1978
Kidney homogenates from chicks fed a vitamin D-deficient diet Summary: for 10 days and supplemented with 6.5 nmol of vitamin D3 48 hr prior to sacrifice metabolized [3H]-25-hydroxyvitamin D3 (25-OH-D31 to 24,25-dihy--in vitro droxyvitamin D3 [24,25-(OH)2-D3] and 3 other metabolites (peaks A, C and E). When the homogenates were incubated with purified L3H]-24,25-(OH)2-D3, 3 simiOn high pressure liquid lar metabolites (peaks A', C' and E') were produced. chromatography, peaks A, C and E migrated to exactly the same respective pOSitions as peaks A', C' and E'. Kidney homogenates from D-deficient chicks failed to produce these metabolites from [3H]-2%OH-D3 or L3H]-24,25-(OH)2-D3. These results strongly suggest that the new metabolites reported here are synthesized via 24,25-(OH)2-D3 in the kidney of chicks supplemented with vitamin D3. INTRODUCTION It
is now well
hydroxyvitamin
established
D3 (25-OH-D3)
la,25-dihydroxyvitamin 25-(OH)2-D3] this
(1).
has not been the ly-
selective More
phosphate,
or during
kidney
--in vitro
of these
vitamin
situation
(3H]-25-OH-D3
thought
in
to 25-
the kidney
in
the
levels
form,
of plasma
has been were
since
calcium
of 24,25-(OH)2-D3, circumstances
to
D3 (24,
to be an active
when animals
D depletion,
however,
associated
investigated
with extensive-
in need of calcium
and more 24,25-(OH)2-D3
or
was produced
(2-6).
of investigating
homogenates
* To whom all Abbreviations dihydroxyvitamin
was produced
metabolized
or 24,25-dihydroxyvitamin
significance
metabolites
first
and subsequently
change
The physiological
la,25-(OH)2-D3
In the course that
The biological
formation
in the opposite
has been
a remarkable
established.
D3 is
in the liver,
la,25-(OHj2-D3 induces
and phosphate
vitamin
D3 [lu,25~-(OH)~-D~]
(1).
metabolite
that
from chicks to 3 other
renal
24-hydroxylase
supplemented metabolites
with besides
activity, vitamin
D3
we found metabolize
24,25-(OHj2-D3.
The
correspondence should be addressed. used: 25-OH-D3, 25-hydroxyvitamin D3; la,25-(OH)2-D3, 24,25-dihydroxyvitamin D3. D3; 24,25-(OHj2-D3,
la,25-
0006-291X/78/0852-0601$01.00/0 601
Copyright All rights
0 1978 by Academic Press. Inc. of reproduction in any form reserved
Vol. 85, No. 2, 1978
present
report
OH-D3 via
BIOCHEMICAL
describes
that
24,25-(OH)2-D3
in
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
these
new metabolites
the kidney
of chicks
MATERIALS Animals: One-day-old White days on a vitamin D-deficient calcium and 0.45% phosphorus. 6.5 nmol of vitamin D3 48 hr minced with removed, rinsed, 0.2 M sucrose containing 15 5 mM sodium succinate.
are
synthesized
supplemented
from 25-
with
vitamin
D3.
AND METHODS
Leghorn cockerel chicks were maintained for 10 purified soy protein diet (7) containing 3% Most of the animals were orally predosed with prior to sacrifice. The kidneys were quickly a garlic press, and homogenized in 4 volumes of mM Tris-Cl (pH 7.4), 2 mM MgC12, 0.4 mM NADP, and
Incubation: The homogenates (1.5 ml) were incubated in 20 ml-Erlenmeyer flasks with 10 pmol (0.1 uCi) of either [26,27-3H]-25-OH-D3 (Radiochemical Centre, Amersham) or [26,27-3H]-24,25-(OH)2-D3. The iucubation was carried out at 37OC for 5-60 min under 100% oxygen. The reactions were terminated by the addition of 9 ml of methanol-chloroform (2:l v/v). Extraction was performed as reported by Gray et al. (8). Chromatography: Chromatography of the extracts was carried out on a 1 x 30 cm column of Sephadex LH-20 (10 g) using a solvent of 65% chloroform - 35% hexane High pressure liquid chromatography(HPLC) according to Holick and DeLuca (9). was performed on a Waters HPLC system (Model 440) equipped with a Zorbax-Sil column (2.1 mm x 25 cm, Du Pant) . The solvent system was either 0.67% or 2% Thirtymethanol in dichloromethane according to Ikekawa and Koizumi (13). Determifour 0.25 ml fractions were collected at a flow rate of 0.5 ml/min. nation of radioactivity was carried out with a Packard liquid scintillation counter (Model 3255) as previously reported (10). Preparation of [26,27-3~1-24,25-(OH)~-~~i Kidney homogenates of chicks predosed intravenously with 312.5 pmol of la-hydroxyvitamin D3 24 hr prior to sacrifice were incubated with r3H]-25-OH-D3 at 37OC for 20 min. [3~]-24,25(OH)2-D3 was purified on the Sephadex LH-20 and HPLC column described above. Crystalline vitamin D3 was purchased from Tokyo Chemical Industry, and 25OH-D3 from Phillips-Dupher Co., Amsterdam. Crystalline la,25-(OH)2-D3 and 24R,25-(OH)2-D3 were gifts from Dr. M. R. Uskokovie, Hoffman-La Roche Inc., New Jersey. la-hydroxyvitamin D3 was a gift from Dr. I. Matsunaga, Chugai Pharmaceutical Co., Tokyo. RESULTS AND DISCUSSION Administration
of 6.5
ly suppressed
renal
tivity
I).
In the course
that
the
ity,
(Table we found
from Sephadex
LH-20
The heterogeneity
25-OH-D3-la-hydroxylase
columns of the
by Garabedian
OH-D3 and the
24,25-(OHj2-D3
were
individually
and the
were
both
heterogeneous fraction
applied
fractions
(11)
fractions
on Sephadex
to HPIC column,
602
the
LH-20 former
by HPLC.
LH-20
(12).
activ-
isolated
when purified
Sephadex
ac-
24-hydroxylase
and Gray et al. from
complete-
24-hydroxylase
renal
24,25-(OH)2-D3
24,25-(OHj2-D3 et al. --
chicks
and enhanced
of investigating
25-OH-D3
been reported
(a))
D3 to D-deficient
nmol of vitamin
column
When the
columns
(Fig
was separated
has
251. into
~~-
Failure
100% N2*** 24,25-(OHj2-D3
Boiled** 24,25-(OH),-0,
24,25-(OHj2-D3
Control 25-OH-D3
___...
24,25-(OH),-D3
Control 25-OH-D3
Substrate
Incubation*
I.
of
-.---.
0 0
0 0
0
0
0
0
15.4 13.9
0
22.2
15.9
0
39.6
0 ~- ___.-_._.
Trace -15.8
0
Trace
24.8
0
%
0
0
0
0
47.6
45.2
25.8
23.3
0
0
0
0
Peak
new metabolites
25-OH-D3
the
17.6
%
A
of
0
Peak
synthesis
%
C
91.7
92.0
98.5
97.7
27.3
25.9
23.1
9.5
89.6
87.2
0
0
24,25-(OHj2-D3
by kidney
%
were
homogenates
The 25-OH-D3 and the 24,25-(OH)2-D3 fractions from Sephadex LH-20 columns Figures in Table I are expressed as percentage of the sum of the radioactivity on HPLC. * All incubations were performed for 60 min. l * boiled homogenates for 5 min at 100°C prior to incubation. *** incubated for 60 min under 100% N2.
6.5
0
nmol
Predose of D3
Table
%
E
separately recovered
0
0
0
0
8.8
8.4
8.0
5.1
Trace
Trace
0
0
Peak
from
in
%
to HPLC columns. l-34 fractions
8.3 applied each
8.0 0
1.5
0
2.3
2.4
5.1
5.0
6.7
3.2
5.4
12.0
8.8
Others
0
%
chicks.
0
0
0
0
0
0
0
63.2
73.6
la,25-(OH)2-D3
D-deficient
Vol. 85, No. 2, 1978
BIOCHEMICAL
AND BIOPHYSICAL
4 (b) t
25-OH-D3 Fraction
.-;;E 3
RESEARCH COMMUNICATIONS
s .-z3
24,25-(OH)>-D,
4 2
e
24.25~(OH),-03 Fract!on
,
‘: 0
2-
; e
Fraction
. 25-OH-D, Fractmn
l-
Number
( 3rd)
Fig 1. Sephadex LH-20 chromatographic profiles of extracts of kidney homogenates from chicks orally dosed with 6.5 nmol of vitamin D3. The reaction conditions are described under MATERIALS AND METHODS. The columns containing 10 g of Sephadex LH-20 were eluted with chloroform : n-hexane (65:35, v/v) and 3 ml fractions were collected. Panel (a) represents a chromatographic profile of the extracts when the homogenates were incubated for 60 min with 10 pmol (0.1 PCi) of [3H]-25-OH-D3 and panel (b) with 10 pmol (0.1 UCi) of 13H]-24,25(OH) 2-D3.
2 peaks: with
authentic
3 peaks: tic
an unknown
peak referred
25-OH-D3
2 unidentified
24R,25-(OH)2-D3
that
from
metabolites
of vitamin in this
radioactive 1.
might
was referred
3 peaks:
failed
were
2 unidentified
reported
that
2.
was
by Gray et al.
604
produced
new metabolites
(12).
[3H]-24,25-(OH)2-D3, on Sephadex
LH-20
not
fraction and peak
which
produce
25-OH-D3
to exactly
the
was also D' which
a columns
peak was homogeneous, did
similar
Thus,
Peak A' migrated
C' and E',
However,
(12).
fraction
The homogenates
resemble
administration
purified
radioactive
authen-
whereas
by Gray et al.
25-OH-D3
with
into
here,
from
with
separated
(12).
of lc~,25-(OH]~-D~
those
coincided
coincided
them
The 24,25-(OHj2-D3 peaks
latter
to produce
the
cc)).
B which
new metabolites
reported
incubated
in the
to as peak A'.
as peak A on HPLC.
Some of these
to those
be different
(Fig
On HPLC the
administration
HPLC showed
[3H]-24,25-(OH)2-D3 tion
prior
peak appeared (b)).
(b)).
recently
D3 or 25-OH-D3 study
(a)).
A, and peak
C and E, and peak D which
r3H]-25-OH-D,
When the homogenates
(Fig
2.
those
demonstrated
2.
peaks (Fig
chromatographically they
(Fig
to as peak
from
same posi-
separated
coincided
into with
BIOCHEMICAL
Vol. 85, No. 2, 1978
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
i.
10
5 Time
( mln
15
10
5
Time
1
15
(min)
Fig 2. HPLC profiles of the 25-OH-D3 and the 24,25-(OH)2-D3 fractions colHPLC Panels (a) and (c) represent lected from the Sephadex LH-20 columns. (tubes 6-13) shown on Fig 1. (al and (b), profiles of the 25-OH-D3 fraction respectively. Panels (b) and (d) indicate those of the 24,25-(OH)2-D3 fraction (tubes 16-35) on Fig 1. (a) and (b), respectively. Before applying to 500 pmol of authentic 25-OH-D3 (in panels (a) and (c)) or 24R, HPLC columns, The columns 25-(OH)2-D3 (in panels (b) and (d)) were added to each extract. were eluted with a solvent of either 0.67% methanol (in panels (a) and (c)) or 2% methanol (in panels (b) and (d)) in dichloromethane.
authentic
24R,25-(OH12-D3
exactly were
(Fig
the same respective preheated
at 100°C
and E' were
produced,
matically.
Production
under
100% nitrogen Figure
D3 and peaks D3 for in 5-10
5-60
2.
positions for
5 min,
indicating
(Table
3 indicates
as peaks neither
that
of these
On HPLC peaks
(a)).
metabolites
time
Amounts
min and decreased
C and E gradually
increased
A, C and E nor
metabolites
are
was also
suppressed
peaks
A',
synthesized
C' enzy-
completely
I). course
of change
A, C and E when the homogenates min.
to
When the homogenates
C and E.
peaks
these
C' and E' migrated
of 24,25-(OHj2-D3 thereafter. during
in
the amounts-of
were produced
On the other the incubation
605
incubated
with
attained hand,
period
24,25-(OHJ2F3H]-25-OH-
a maximal
amounts of 60 min.
level
of peaks
A,
When the
Vol. 85, No. 2, 1978
BIOCHEMICAL
0
AND BIOPHYSICAL
30
15 Incubation
Time
RESEARCH COMMUNICATIONS
45 ( min
60
)
proFig 3. Time course of change in the amounts of the 25-OH-D3 metabolites duced by kidney homogenates from chicks dosed with 6.5 nmol of vitamin D3. Incubations were carried out with 10 pmol (0.1 uCi) of [3H]-25-OH-D3 as described under MATERIALS AND METHODS. Results are expressed as percentage of the radioactivity recovered as peak A (--A- ), peak C (-0 ), and peak E (--&-). The vertical bar 24,25-(OH),-D3 ( -), indicates standard error of the mean of 3-4 experiments.
homogenates major
were
incubated
metabolite
relatively
was peak
minor
failed
ones
to produce The results
(peaks
behaviors fied
with
reported
here
D-deficient the time
course
A, C and E fits Biological in view under
of the investigation
Second,
25-OH-D3
from
peaks
or 24,25-(OHj2-D3
of change
in the
these amounts
in the kidney
metabolites
(Table
I).
Third, kidney
of chicks
from puri-
A, C and E migrate
Fourth,
chicks
chromatographic
are produced
C' and E'.
produced
were
of 25-OH-D3
C' and E' with
on HPLC peaks A',
and E (or E')
the metabolites
A',
the
from D-deficient
24,25-(OH)2-D3
24,25-(OHj2-D3.
to produce
to exactly
the homogenates homogenates
from 25-OH-D3. of 24,25-(OH),-D3
from
Finally, and peaks
the above hypothesis.
significance control
25-OH-D3 that
as peaks
fail
with
A (or A')
A, C and E, respectively,
positions
chicks
First,
D3.
to peaks
the same respective
indicate via
[3H]-24,25-(OH)2-D3,
homogenates
from
synthesized
or
and peaks
Kidney
metabolites
[3H]-24,25-(OH)2-D3.
do not produce
I).
these
vitamin
similar
13H]-25-OH-D3
C (or C'),
(Table
A, C and E) are
supplemented
with
of
mechanism in our
these
metabolites
of 25-OH-D3
laboratory.
606
is metabolism,
of considerable which
is
interest currently
Vol. 85, No. 2, 1978
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
REFERENCES 1.
DeLuca,
H. F.,
2.
Boyle, I. T., Gray, USA 68, 2131-2134.
3.
Tanaka, 574.
4.
Horiuchi, N., Suda, (1974) FEBS Letters
5.
Tanaka,
Y.,
6.
Hughes, Baylink,
M. R., Brumbaugh, P. F., Haussler, D. J. (1975) Science 190, 578-580.
-7.
Gmdahl, J., Biochemistry
8.
Gray, R. W., Gmdahl, J. L., Ghazarian, J. Biol. Chem. 247, 7528-7532.
9.
Holick,
Y.,
and Schnoes, R. W.,
and DeLuca, T., 43,
and DeLuca,
and DeLuca,
H. F.
H. F.
and DeLuca,
S.,
Ezawa,
(1974)
Suda,
H. F.
11.
Garabedian, M., Bailly Du Bois, Balsan, S. (1978) Endocrinology
12.
Gray, R. W., Caldas, A. E., Weber, Biochem. Biophys, Res. Commun. 82,
13.
Ikekawa,
Proc.
M. R., Y.,
Y.,
607
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154,
Wergedal,
Sci.
566-
J. E.,
and DeLuca,
Res.
12,
Pezant,
J. L., and Ghazarian, 121-128.
N. (1976)
Acad.
E.
1198-1200.
Ogata, E., Ezawa, I., Biophys. 171, 540-548.
M., Corvol, M. T., 102, 1262-1268.
Nat.
631-666.
and Ogata,
and DeLuca,
J. Lipid
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Biophys.
Sano. 183,
J. G.,
N., Suda, T., Sasaki, S., E. (1975) Arch. Biochem.
(1971)
I.,
Tanaka,
(1971)
Rev. Biochem.
Biochem.
Science
T.,
Horiuchi, Shimazawa,
and Koizumi,
H. F. Arch.
10.
N.,
Ann.
(1973)
Sasaki, 353-356.
Holick, M. F., lo, 2935-2940.
M. F.,
H. K. (1976)
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H. F.
H. F.
and (1971)
(1972)
460-465. SanO, Y., E.,
and
J. G. (1978) 227-232.
and