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The cholesterol content of HDL2 and HDL3 subfractions of high density lipoproteins in different normocholesterolemic populations
Clrnrcu
Chimrco A&J,
319
142 (1984) 319-324
Elscvier
(‘(‘A
02967
The cholesterol content of HDL, and HDL, subfractions of high density lipoproteins in different normocholesterolemic populations D. Neel,
P. Beaudry,
I.ohorzrtorr~ de Btochrmre.
D. Erlich,
Il~pitol
Smut
E. Turpin,
Y. Goussault
Louis. .? place L/u Dr Fournrer
-
and C. Dreux
*
7547.5 Ports C&le.r IO (Fruttc~e)
(Received December 23, 19X3: revision June 12th. 1984)
Summary Two normocholesterolemic populations, selected for either high triglyceridemia or low HDL cholesterol content, both known to have increased artery disease risks, were studied
for their cholesterol
subfractions
were isolated
both populations,
content
total HDL
cholesterol
cholesterol
content
were decreased
percentage
of total
HDL
significantly
diminished
in HDL,
by a precipitation
and HDL,
method.
showed
values were similar and HDL,
when compared
cholesterol,
subfractions.
The results
the HDL,
only in female subjects
with a control
cholesterol
These that, in
and HDL,
population.
subfraction
for both populations
In
appeared
studied.
Introduction If the low density lipoprotein of coronary between
heart
diseases,
(LDL)
cholesterol
it has been
shown
these diseases and high density lipoprotein
[l]. HDL
are not homogeneous,
ultracentrifugation.
but comprise
The main ones are HDL,
importance
of the
emphasized
[2-31.
HDL, The
subfraction
existing
is directly related to the incidence that
an inverse
(HDL)
correlation
cholesterol
exists
concentration
several subfractions,
characterized
and HDL,.
evidence
in the protective
ultracentrifugal
methods
Recently role
of HDL
by
for the
has
for the quantitation
been of
HDL, and HDL, are often unsuitable for handling a large number of samples; so some workers have described a simpler method of separating HDL, and HDL, by a precipitation method [4]. * To whom correspondence should be addressed. 0009-8981/84/$03.00
0 1984 Elsevier Science Publishers B.V
Methods
Apoprotein addition
B containing
USP/ml)
and
heparin
100 ~1 of MnC‘t,t
0.046 mmol/ml, min at 4’c‘ and The
lipoprotein5
of 80 ~1 of sodium
precipitated
from
(sodium
salt,
2 ml ~)f herum
Sigma
to a final concentration
from
and
part
the heparin wax taken
manganese for
precipitation
immediate
an
assay
to stand
the
and
for 45
MJ;I\ \epar;ited ol‘
b>
I 5000
grade
of 184 IlSt),,~ml
respecti\,ely. After mixing. the sample wa\ allowed then centrifuged at 1500 X (y for 30 min at 4OC‘.
aupernatant
the precipitate
mot/t
were solution
from
cholesterol
tttll.
(11DLC‘). Scprrratron oj I-lDLa, und HDL; One
hundred
tubes
1600
x g
were
allowed
.subfruc~tion.s(41
of 1.21% dextran
’ supernatant,
heparin/Mn’ The
microlitres
giving to stand
for
for 30 min. The supernalants
The cholesterol (<‘HOD-PAP.
concentrations
sulphate
a final dextran 30 min
at room
added
to
I
temperalure.
ml
ol
the
of 0.1 19,
concentration then
spun
at
were separated.
were determined
Boehringer-Mannheim,
were
sulphate
FRG)
by a cholesterol
in the presence
enzymatic
of disodium
mmol/l. to eliminate positive interference by the precipitating The value for the HDL, cholesterol (HDL,C) was ohtaincd
reagents. by subtracting
method EDTA,
8
HILL 1
from total HDt> cholesterol. Total HDL and H IIL 3 cholesterol for the appropriate dilutions. enzymatic method values were obtained by using a gtycerolipase
cholesterol (HDL,C) values were corrected Triglycerides (Merck,
Darmstadt,
We sampled subjects
with
normal
hypertrigtyceridemic 21
mate
FRG).
42 female
and
HDL subjects
22 male
cholesterol with
normal
normochotesteroter~lic-normotrigtyccridcl~lic as controls: 12 female and
values,
values
normocholesterolemic-normotrigtyceridemic where the content (LHDLC)
of total
cholesterol:
subjects + VLDL)
(LDL cholesterol cholesterol ratio was higher than 4 [6]. All these subjects were between 1X and X0 years old with a mean groups exhibited a similar distribution. The hypertrigtyceridemic chosen from gtyceridemia.
among The
normocholesterolemic one5 whatever the origin normnchotesterolemic-normotrig1yceridemic-I,~iDL~~
30 malt
I9 female
and
with low’ HDL chotesterot/HDL ;II 45. The three SUbJech were of the hypertrisubjects
321
represent a population with increased artery disease risks and already described [6]. The frequent values observed in our clinical laboratory for normal healthy subjects were: triglycerides: 0.45-1.5 mmol/l. cholesterol: 4.1-6.2 mmol/l, HDL cholesterol: 1.1-2.05 mmol/l.
We compared the results using the Kolmogorov-Snlirnov test which is one of the most convenient for such a population in which the Gaussian distributiol~ was not proved. Therefore the means and SD were given only for information. Results
As shown in Table I, the hypertriglyceridemic subjects were chosen to have normal values of total blood serum cholesterol and the subjects with low HDL cholesterol (LHDLC) to have normal triglyceride values and normal total blood serum cholesterol values; the subjects with low or high total blood serum cholesterol were eliminated. So the two populations were identical considering whole cholesterol content. The hypertrigly~er~demic subjects exhibited a decrease of the total HDLC and HLD,C and HDL,C. This decrease was significant in both subpopulations of male and female subjects. The same results were found in the LHDL C subjects (Table II). The comparison of the hypertriglyceridemic population with the LHDL C population showed that these two populations appeared identical for total HDLC’, HDL,C and HDL,C for both male and female subjects.
C‘ontrol
0.76 + 0.28 2.01 + 0.49 ks 57 (S) ,’ -=c0.01
Hypertriglyceridcmic normocholeaterolemic
5.11 * 0.69 5.14iO.64 ks 0.64 (NS)
0.81 + 0.32 2.07 i 0.66 k.\ 53.33 (Sj ,’ < 0.01
5.21 IO.54 5.21 t O.hO k\ 0.72 (NS)
Normcltriglvce~idcmic nortnclcholcsterolemi~ with low HDL cholestcrol content (LHDLC) ks = vai~e obtained
0.X6 _c0.26 k> 1.46 tNS)
4.90 i 0.58 ks 2.83 (f-3
rrom the K.S. test: S = significant;
1.11 to.26 ks 14.02 (S) p < 0.05
NS = n~n-~ig~ifi~~~nt
5.20 + 0.55 k.\O7 INSi
Table 111 shows the variations of HDL?C’ expressed in percentage of total I iDI_, : it appeared significantly decressed in female aubpopulatinns of the two popul:~t~on~ studied.
Control H!pcrtriglycer1dcrnic LHDLC
(low HDL cholesterol)
Total HDL
HDL,
1.52 i 0.23 0 97 i 0.23 * ks42.G (S) I’ -C 0.01 0.95 + 0.15 * kx 52.3X (S) ,’ i 0.01
0 22 i 0. I1 0 1 I I 0.0’) * ks 14.31 (S) I’ C 0.05 0. lo t 0.w * k\ 14.5X (S) ,’ ( 0.05
** ks = 0.77 (NS)
1.53 + 0.30 0.96 r 0.23 * k> 32.4Y (S) ,I < 0.01 0.96 t 0.13
** ks = 2.Yl
* ks 3X.XX (S) I’ < 0.01
(NS)
0.22 i_O.ih 0.0’) -f 0.0x * ka 9.53 (S) ,’ i 0.05 0.10 t 0.08 * ks 6.74 (S) 1’ C 0.05
171 to77 0.X6 / 0 73 * k,\ 2303 (S) ,I . Ol)l 0 X6 + 0 13 * kx7S.71 (S) /> c ti.oi
** ki = 1.37 (NS)
** lx\ 1 45 (NS)
ks = value obtained from the K.S. tot: S = Ggniflwnt: NS = non >lgnificant: * = comparison with normal bubyx’t value; ** = wtnpar~xm of h\ipertrigl~c~ridctnic and LDHC’ zuhyxt.
TABLE
III
HDL, cholesterol subjects
expressed
in percent
of total
HDL
cholesterol;
statistical
comparison
with normal __I_
Females (% HDL,) Control Hypertriglycetidemic
LHDLC
ks = value obtained
14.42 rt 6.79 10.33 + 7.86 ks 6.58 (S) p c. 0.05 10.02 f. 9.48 ks 10.07 (S) p < 0.05 from the KS. test; S = significant;
Males (5%HDL,) 13.X2&9.19 IO.53 * 9.79 ks 5.23 (NS) 10.28 f 8.02 ks 3.50 (NS) NS = non significant.
--
323 TABLE
IV
Statistical
comparisons
Subjects
between
males and females for HDL. Total HDL
HDL,
and HDL,
cholesterol
HDL,
HDL,
Control
ks 2.24
ks 5.41
ks 1.36
Hypertriglyceridemic
(NS) ks 0.86
(N’S) ks 1.16
(NS) ks 0.501
(NS) ks 4.10
WS) ks 0.30
(NS) ks 1.34
(NS)
(NS)
(NS)
Hypocholesterolemic HDL ks = value obtained
values.
from the KS. test; NS = non significant.
In Table IV, the total HDLC and the cholesterol content of HDL, and HDL, subfractions in male and female subjects are compared. In control subjects, the results indicated no difference between male and female subjects; however, some authors have shown that total HDL cholesterol was higher in female subjects, particularly before the menopause [7]. This discrepancy could be explained in our study by the presence of post-menopausal women and by the absence of subjects with low HDL cholesterol often found among male subjects. As regards total HDL C, HDL,C and HDL,C, no difference between male and female subjects was observed either in hypertriglyceridemic population or in LHDLC samples. Discussion
The precipitation procedure used here for HDL,, HDL, fractionation was described by Gidez et al in 1979 [4]. For SR Kahn et al [8], this procedure is valid in that the subclasses of HDL obtained are analogous to those obtained by ultracentrifugation. For Simpson et al [9] there is a higher value of HDL,C as measured by the precipitation procedure than by zonal ultracentrifugation. Nevertheless, this precipitation method is a simpler method for handling a large number of samples despite the inherent variability of precipitation methods and the probably low precision of HDL,C values, which had a low cholesterol content and were determined by difference between total HDLC and HDL,C. The two populations studied are known to have some increased ischaemic artery disease risks, though they are both normocholesterolemic [5,6]. In 1978, Schaefer showed that HDL cholesterol levels are inversely correlated with serum or VLDL triglyceride levels [lo]. In our study, we confirmed, for the hypertriglyceridemic patients, a HDL cholesterol decrease observed for both HDL, and HDL, subfractions, possibly explaining the higher incidence of ischaemic artery diseases in this population. The decrease of HDL,C, in the populations studied appeared more important than that of HDL,C when the results are expressed in percentage of total HDLC, but it was only significant according to the Kolmogorov-Smirnov test, in female subjects (Table III). However the HDL,C was about 50% decreased in male or female subjects, whereas it was only 35% decreased in HDL,C fractions, Alau-
povic
]I I] suggested
that
provided
the biochemical
particles,
and
that.
or in VLDL content both
on
cfficiencv
the
Here
such
subpopulations
where
particles
cholesterol,
the same
should of
the
and
results increase
an
be considered
serum
found.
in VLDL
the triglyceride
could
population.
L>w
f l1)l.C
of
w;15 oh4cr\ ccl in which is hncm 11 c<)n(cnt
the lack of ape
01
C’-containing
non r-call\ he \uggcsted.
like. for instance.
in this
of tripl\c~cride
decrease
;I decrease subfraction
As regards
were
t 1111
in t 11)1 ) )
a decrease the
to
in the \\hc)le
decrca\c
of
tIDl.:
the apo A, or A ,, were probablv also implicated. It would hc intrrcstinp now the apolipoprotein content of HDL, and HDL, subfractions in thcae
to study
two normocholesterolemic valuea.
However.
the
and
(mainI\
mechanism\
explain
p,~rt~c~lc~
Vl.DL
E in HDL
removal
could
subjects.
between
and not only in the HDL,
in HDL
mechanisms C content
of the
part of apo C lipoproteins.
C samples.
lipoprotein Other
of HDL
the main
relationship
C and ape
;I hypothesis
~~I‘ Ili)l.
lipoproteina
E contatning
of ape
in the hyprrtriglyceridemic
LHDL
apo
apt)
for the inverse
the distribution
[12].
contain
to
C‘ and
basis
depends
metabolism
apcj
populations,
but are phvsiologicallv
which
different
had the same
with
respect
1cholealcrol
HDL,-HDI.
to their
lipid
mctahnlism.
References
3 Miller
NE.
Hammett
F. Saltlsst.
Ilpoprotelns
to plasma
4 Ci~dez LI. Miller
GJ.
Burst&n
procedure-correlation HDL
with
methodology
5 Carlsaon
MA.
Bottiger
J. Chanu
chez da 7 Kraus
5uJets KM,
on high X Kahn
Undgren
SR,
Actn
Ahfrlat Stand
HS. 1982;
.O Schaefer
Risks
factors
206:
351~360.
Med
J. Bradley
Lipids
1979:
RS. Niththyananthan
14:
publ.
1744.
IIDL
h\
suhclasw\
197’):
In:
Uppcl
JI\c;I~
a prcuplt,itlc,n ti. a.
Kepclrt
01
111 the
Stochholm
1661.
for myocardial
Y, Dreux
artq
coron;~r\
Infarction
C. C‘hole~terol\
HDL
ct LDL
+ \‘I I)1
19X2: 10: 1646. DD,
Ramcharan
I 13
11 X.
R, Seed
procedure:
of plasma
def~nrd
J I-YXI: 1: 1741
ultracentrlfugation. NIH
E. Gousaault Presse
FT. Wlngerd
Ballantyne
FC.
M. Wynn
comparison
with
S. Effect?,
c>f cbtrc~gc‘ns and
V. Analy\~a
of high
preparative
ultracentrlfuge.
dcnvt\
propc‘rtlns lipoproteina
Clin.
C‘him.
CJ.
Morgan
polyanionic
t1C;. Sheperd
precipitation
J. High
and
rate
density
ronal
lipoprotein
whflac-
ultr;~crntrifug;~tion.
C’lin
10: 2040-2043.
EJ.
Anderson
DW.
of plasma
high
Alaupvvic
P. David
Rubinstrin
Interrelationship I2 Nikkyla
Packard
by differential
regulation
Invat
RE. 1979:
D. Turpin
by a precipitation
ah measured
C‘hem
1
LE.
Br Med
lYX2; l-20: 49. 5.5.
Y Slmpaon (Ion:,
Anelys~s
32X, no. 7’). Usdew:
hpoprotelns.
Elk&s
t1A.
and analytical
normolipidt-miques.
density
wbclasse~
M. bder
Med
B. Nerl
of :cnglographicall\
and apollpopr~,teins.
preparative
Workshop
prospective study. Acta 6 Rouff?;
S. et al. Relation
suhfractwns
EA.
between Metabolic
197X: 8: 111-113.
Brewer
drnslty VLDL regulation
Jr
HB.
lipoproteins memoral and
HDL.
Lrvj
RI.
Danner
concentrations. lecture.
The
Can
J Biochrm
of plasma
high
hiochernud
density
Blackweldcr
KN.
Lancet
197X: 2: 3Yl and
clInical
W.C‘.
Met;itx,lic
7Y2. ugniflcance
of the
19X1: 59: 565.-579. lipoproteins
conccntr;~tIon\.
Eur
.I (‘lln
Chimrco A&J,
319
142 (1984) 319-324
Elscvier
(‘(‘A
02967
The cholesterol content of HDL, and HDL, subfractions of high density lipoproteins in different normocholesterolemic populations D. Neel,
P. Beaudry,
I.ohorzrtorr~ de Btochrmre.
D. Erlich,
Il~pitol
Smut
E. Turpin,
Y. Goussault
Louis. .? place L/u Dr Fournrer
-
and C. Dreux
*
7547.5 Ports C&le.r IO (Fruttc~e)
(Received December 23, 19X3: revision June 12th. 1984)
Summary Two normocholesterolemic populations, selected for either high triglyceridemia or low HDL cholesterol content, both known to have increased artery disease risks, were studied
for their cholesterol
subfractions
were isolated
both populations,
content
total HDL
cholesterol
cholesterol
content
were decreased
percentage
of total
HDL
significantly
diminished
in HDL,
by a precipitation
and HDL,
method.
showed
values were similar and HDL,
when compared
cholesterol,
subfractions.
The results
the HDL,
only in female subjects
with a control
cholesterol
These that, in
and HDL,
population.
subfraction
for both populations
In
appeared
studied.
Introduction If the low density lipoprotein of coronary between
heart
diseases,
(LDL)
cholesterol
it has been
shown
these diseases and high density lipoprotein
[l]. HDL
are not homogeneous,
ultracentrifugation.
but comprise
The main ones are HDL,
importance
of the
emphasized
[2-31.
HDL, The
subfraction
existing
is directly related to the incidence that
an inverse
(HDL)
correlation
cholesterol
exists
concentration
several subfractions,
characterized
and HDL,.
evidence
in the protective
ultracentrifugal
methods
Recently role
of HDL
by
for the
has
for the quantitation
been of
HDL, and HDL, are often unsuitable for handling a large number of samples; so some workers have described a simpler method of separating HDL, and HDL, by a precipitation method [4]. * To whom correspondence should be addressed. 0009-8981/84/$03.00
0 1984 Elsevier Science Publishers B.V
Methods
Apoprotein addition
B containing
USP/ml)
and
heparin
100 ~1 of MnC‘t,t
0.046 mmol/ml, min at 4’c‘ and The
lipoprotein5
of 80 ~1 of sodium
precipitated
from
(sodium
salt,
2 ml ~)f herum
Sigma
to a final concentration
from
and
part
the heparin wax taken
manganese for
precipitation
immediate
an
assay
to stand
the
and
for 45
MJ;I\ \epar;ited ol‘
b>
I 5000
grade
of 184 IlSt),,~ml
respecti\,ely. After mixing. the sample wa\ allowed then centrifuged at 1500 X (y for 30 min at 4OC‘.
aupernatant
the precipitate
mot/t
were solution
from
cholesterol
tttll.
(11DLC‘). Scprrratron oj I-lDLa, und HDL; One
hundred
tubes
1600
x g
were
allowed
.subfruc~tion.s(41
of 1.21% dextran
’ supernatant,
heparin/Mn’ The
microlitres
giving to stand
for
for 30 min. The supernalants
The cholesterol (<‘HOD-PAP.
concentrations
sulphate
a final dextran 30 min
at room
added
to
I
temperalure.
ml
ol
the
of 0.1 19,
concentration then
spun
at
were separated.
were determined
Boehringer-Mannheim,
were
sulphate
FRG)
by a cholesterol
in the presence
enzymatic
of disodium
mmol/l. to eliminate positive interference by the precipitating The value for the HDL, cholesterol (HDL,C) was ohtaincd
reagents. by subtracting
method EDTA,
8
HILL 1
from total HDt> cholesterol. Total HDL and H IIL 3 cholesterol for the appropriate dilutions. enzymatic method values were obtained by using a gtycerolipase
cholesterol (HDL,C) values were corrected Triglycerides (Merck,
Darmstadt,
We sampled subjects
with
normal
hypertrigtyceridemic 21
mate
FRG).
42 female
and
HDL subjects
22 male
cholesterol with
normal
normochotesteroter~lic-normotrigtyccridcl~lic as controls: 12 female and
values,
values
normocholesterolemic-normotrigtyceridemic where the content (LHDLC)
of total
cholesterol:
subjects + VLDL)
(LDL cholesterol cholesterol ratio was higher than 4 [6]. All these subjects were between 1X and X0 years old with a mean groups exhibited a similar distribution. The hypertrigtyceridemic chosen from gtyceridemia.
among The
normocholesterolemic one5 whatever the origin normnchotesterolemic-normotrig1yceridemic-I,~iDL~~
30 malt
I9 female
and
with low’ HDL chotesterot/HDL ;II 45. The three SUbJech were of the hypertrisubjects
321
represent a population with increased artery disease risks and already described [6]. The frequent values observed in our clinical laboratory for normal healthy subjects were: triglycerides: 0.45-1.5 mmol/l. cholesterol: 4.1-6.2 mmol/l, HDL cholesterol: 1.1-2.05 mmol/l.
We compared the results using the Kolmogorov-Snlirnov test which is one of the most convenient for such a population in which the Gaussian distributiol~ was not proved. Therefore the means and SD were given only for information. Results
As shown in Table I, the hypertriglyceridemic subjects were chosen to have normal values of total blood serum cholesterol and the subjects with low HDL cholesterol (LHDLC) to have normal triglyceride values and normal total blood serum cholesterol values; the subjects with low or high total blood serum cholesterol were eliminated. So the two populations were identical considering whole cholesterol content. The hypertrigly~er~demic subjects exhibited a decrease of the total HDLC and HLD,C and HDL,C. This decrease was significant in both subpopulations of male and female subjects. The same results were found in the LHDL C subjects (Table II). The comparison of the hypertriglyceridemic population with the LHDL C population showed that these two populations appeared identical for total HDLC’, HDL,C and HDL,C for both male and female subjects.
C‘ontrol
0.76 + 0.28 2.01 + 0.49 ks 57 (S) ,’ -=c0.01
Hypertriglyceridcmic normocholeaterolemic
5.11 * 0.69 5.14iO.64 ks 0.64 (NS)
0.81 + 0.32 2.07 i 0.66 k.\ 53.33 (Sj ,’ < 0.01
5.21 IO.54 5.21 t O.hO k\ 0.72 (NS)
Normcltriglvce~idcmic nortnclcholcsterolemi~ with low HDL cholestcrol content (LHDLC) ks = vai~e obtained
0.X6 _c0.26 k> 1.46 tNS)
4.90 i 0.58 ks 2.83 (f-3
rrom the K.S. test: S = significant;
1.11 to.26 ks 14.02 (S) p < 0.05
NS = n~n-~ig~ifi~~~nt
5.20 + 0.55 k.\O7 INSi
Table 111 shows the variations of HDL?C’ expressed in percentage of total I iDI_, : it appeared significantly decressed in female aubpopulatinns of the two popul:~t~on~ studied.
Control H!pcrtriglycer1dcrnic LHDLC
(low HDL cholesterol)
Total HDL
HDL,
1.52 i 0.23 0 97 i 0.23 * ks42.G (S) I’ -C 0.01 0.95 + 0.15 * kx 52.3X (S) ,’ i 0.01
0 22 i 0. I1 0 1 I I 0.0’) * ks 14.31 (S) I’ C 0.05 0. lo t 0.w * k\ 14.5X (S) ,’ ( 0.05
** ks = 0.77 (NS)
1.53 + 0.30 0.96 r 0.23 * k> 32.4Y (S) ,I < 0.01 0.96 t 0.13
** ks = 2.Yl
* ks 3X.XX (S) I’ < 0.01
(NS)
0.22 i_O.ih 0.0’) -f 0.0x * ka 9.53 (S) ,’ i 0.05 0.10 t 0.08 * ks 6.74 (S) 1’ C 0.05
171 to77 0.X6 / 0 73 * k,\ 2303 (S) ,I . Ol)l 0 X6 + 0 13 * kx7S.71 (S) /> c ti.oi
** ki = 1.37 (NS)
** lx\ 1 45 (NS)
ks = value obtained from the K.S. tot: S = Ggniflwnt: NS = non >lgnificant: * = comparison with normal bubyx’t value; ** = wtnpar~xm of h\ipertrigl~c~ridctnic and LDHC’ zuhyxt.
TABLE
III
HDL, cholesterol subjects
expressed
in percent
of total
HDL
cholesterol;
statistical
comparison
with normal __I_
Females (% HDL,) Control Hypertriglycetidemic
LHDLC
ks = value obtained
14.42 rt 6.79 10.33 + 7.86 ks 6.58 (S) p c. 0.05 10.02 f. 9.48 ks 10.07 (S) p < 0.05 from the KS. test; S = significant;
Males (5%HDL,) 13.X2&9.19 IO.53 * 9.79 ks 5.23 (NS) 10.28 f 8.02 ks 3.50 (NS) NS = non significant.
--
323 TABLE
IV
Statistical
comparisons
Subjects
between
males and females for HDL. Total HDL
HDL,
and HDL,
cholesterol
HDL,
HDL,
Control
ks 2.24
ks 5.41
ks 1.36
Hypertriglyceridemic
(NS) ks 0.86
(N’S) ks 1.16
(NS) ks 0.501
(NS) ks 4.10
WS) ks 0.30
(NS) ks 1.34
(NS)
(NS)
(NS)
Hypocholesterolemic HDL ks = value obtained
values.
from the KS. test; NS = non significant.
In Table IV, the total HDLC and the cholesterol content of HDL, and HDL, subfractions in male and female subjects are compared. In control subjects, the results indicated no difference between male and female subjects; however, some authors have shown that total HDL cholesterol was higher in female subjects, particularly before the menopause [7]. This discrepancy could be explained in our study by the presence of post-menopausal women and by the absence of subjects with low HDL cholesterol often found among male subjects. As regards total HDL C, HDL,C and HDL,C, no difference between male and female subjects was observed either in hypertriglyceridemic population or in LHDLC samples. Discussion
The precipitation procedure used here for HDL,, HDL, fractionation was described by Gidez et al in 1979 [4]. For SR Kahn et al [8], this procedure is valid in that the subclasses of HDL obtained are analogous to those obtained by ultracentrifugation. For Simpson et al [9] there is a higher value of HDL,C as measured by the precipitation procedure than by zonal ultracentrifugation. Nevertheless, this precipitation method is a simpler method for handling a large number of samples despite the inherent variability of precipitation methods and the probably low precision of HDL,C values, which had a low cholesterol content and were determined by difference between total HDLC and HDL,C. The two populations studied are known to have some increased ischaemic artery disease risks, though they are both normocholesterolemic [5,6]. In 1978, Schaefer showed that HDL cholesterol levels are inversely correlated with serum or VLDL triglyceride levels [lo]. In our study, we confirmed, for the hypertriglyceridemic patients, a HDL cholesterol decrease observed for both HDL, and HDL, subfractions, possibly explaining the higher incidence of ischaemic artery diseases in this population. The decrease of HDL,C, in the populations studied appeared more important than that of HDL,C when the results are expressed in percentage of total HDLC, but it was only significant according to the Kolmogorov-Smirnov test, in female subjects (Table III). However the HDL,C was about 50% decreased in male or female subjects, whereas it was only 35% decreased in HDL,C fractions, Alau-
povic
]I I] suggested
that
provided
the biochemical
particles,
and
that.
or in VLDL content both
on
cfficiencv
the
Here
such
subpopulations
where
particles
cholesterol,
the same
should of
the
and
results increase
an
be considered
serum
found.
in VLDL
the triglyceride
could
population.
L>w
f l1)l.C
of
w;15 oh4cr\ ccl in which is hncm 11 c<)n(cnt
the lack of ape
01
C’-containing
non r-call\ he \uggcsted.
like. for instance.
in this
of tripl\c~cride
decrease
;I decrease subfraction
As regards
were
t 1111
in t 11)1 ) )
a decrease the
to
in the \\hc)le
decrca\c
of
tIDl.:
the apo A, or A ,, were probablv also implicated. It would hc intrrcstinp now the apolipoprotein content of HDL, and HDL, subfractions in thcae
to study
two normocholesterolemic valuea.
However.
the
and
(mainI\
mechanism\
explain
p,~rt~c~lc~
Vl.DL
E in HDL
removal
could
subjects.
between
and not only in the HDL,
in HDL
mechanisms C content
of the
part of apo C lipoproteins.
C samples.
lipoprotein Other
of HDL
the main
relationship
C and ape
;I hypothesis
~~I‘ Ili)l.
lipoproteina
E contatning
of ape
in the hyprrtriglyceridemic
LHDL
apo
apt)
for the inverse
the distribution
[12].
contain
to
C‘ and
basis
depends
metabolism
apcj
populations,
but are phvsiologicallv
which
different
had the same
with
respect
1cholealcrol
HDL,-HDI.
to their
lipid
mctahnlism.
References
3 Miller
NE.
Hammett
F. Saltlsst.
Ilpoprotelns
to plasma
4 Ci~dez LI. Miller
GJ.
Burst&n
procedure-correlation HDL
with
methodology
5 Carlsaon
MA.
Bottiger
J. Chanu
chez da 7 Kraus
5uJets KM,
on high X Kahn
Undgren
SR,
Actn
Ahfrlat Stand
HS. 1982;
.O Schaefer
Risks
factors
206:
351~360.
Med
J. Bradley
Lipids
1979:
RS. Niththyananthan
14:
publ.
1744.
IIDL
h\
suhclasw\
197’):
In:
Uppcl
JI\c;I~
a prcuplt,itlc,n ti. a.
Kepclrt
01
111 the
Stochholm
1661.
for myocardial
Y, Dreux
artq
coron;~r\
Infarction
C. C‘hole~terol\
HDL
ct LDL
+ \‘I I)1
19X2: 10: 1646. DD,
Ramcharan
I 13
11 X.
R, Seed
procedure:
of plasma
def~nrd
J I-YXI: 1: 1741
ultracentrlfugation. NIH
E. Gousaault Presse
FT. Wlngerd
Ballantyne
FC.
M. Wynn
comparison
with
S. Effect?,
c>f cbtrc~gc‘ns and
V. Analy\~a
of high
preparative
ultracentrlfuge.
dcnvt\
propc‘rtlns lipoproteina
Clin.
C‘him.
CJ.
Morgan
polyanionic
t1C;. Sheperd
precipitation
J. High
and
rate
density
ronal
lipoprotein
whflac-
ultr;~crntrifug;~tion.
C’lin
10: 2040-2043.
EJ.
Anderson
DW.
of plasma
high
Alaupvvic
P. David
Rubinstrin
Interrelationship I2 Nikkyla
Packard
by differential
regulation
Invat
RE. 1979:
D. Turpin
by a precipitation
ah measured
C‘hem
1
LE.
Br Med
lYX2; l-20: 49. 5.5.
Y Slmpaon (Ion:,
Anelys~s
32X, no. 7’). Usdew:
hpoprotelns.
Elk&s
t1A.
and analytical
normolipidt-miques.
density
wbclasse~
M. bder
Med
B. Nerl
of :cnglographicall\
and apollpopr~,teins.
preparative
Workshop
prospective study. Acta 6 Rouff?;
S. et al. Relation
suhfractwns
EA.
between Metabolic
197X: 8: 111-113.
Brewer
drnslty VLDL regulation
Jr
HB.
lipoproteins memoral and
HDL.
Lrvj
RI.
Danner
concentrations. lecture.
The
Can
J Biochrm
of plasma
high
hiochernud
density
Blackweldcr
KN.
Lancet
197X: 2: 3Yl and
clInical
W.C‘.
Met;itx,lic
7Y2. ugniflcance
of the
19X1: 59: 565.-579. lipoproteins
conccntr;~tIon\.
Eur
.I (‘lln