Diabetes, blood lipids, lipoproteins, and change of environment: Restudy of the “new immigrant Yemenites” in Israel

Diabetes,

Blood Lipids, Lipoproteins, and Change of Environment: Restudy of the “New Immigrant Yemenites” in Israel A. M. Cohen,

Restudy of 306 “new immigrant

J.

B. Cohen,

Fidel,

Yemenite”

Jews, an

ethnic group in which, upon their arrival in Israel, no diabetes

was detected,

immigration, higher

plasma

prevalence ance”)

to

of diabetes

male/female status-in

males

resulted

older

age

The

intoler-

and

9.7%

in increased

group

while only.

ratio was affected

underweight,

in males,

levels.

as “glucose

(13.2%

their

of diabetes and

in all age groups,

the

diabetic the

prevalent

(defined

in females

it affected

25 yr after

incidence

lipoprotein-lipid

11.8%

Obesity

prevalence males

and

of diabetes

rose

females).

revealed,

an increased

in

The

by weight

diabetes

was

in the overweight,

more

the rate of

diabetes in females equaled that of males. In nondiabetics

(those

with

neither

the

glucose

response

normal

glucose

tolerance

deteriorated

with

aging.

tolerance),

nor

the

Most

had a delayed insulin response.

However,

of nondiabetics

had insulin

and diabetics

insulin

diabetics about 50% response

peak at 60 min and similar insulin levels. It appears that in newly discovered population shortage

adult-onset

there is no shortage

diabetics in this

cholesterol

and triglycerides

the levels (TG)

were

TG. cholesterol,

higher when

tics, especially

and LDL-cholesterol

compared

in the group

Hyperlipoproteinemia

was

cholesterol

significantly

levels

hundred

and six Yemeni(es,

of overweight

ago and are living in six agricultural

diagnosed

males.

in 27.7%

of

In diabetics, the

diabetics.

I

N A SURVEY of Yemenite Jews carried out shortly after their arrival in Israel, it was found that the prevalence of diabetes was extremely low among “new immigrant Yemen-

About

65%75’%

in the study.

born in Yemen, immigrated of the settlers

willing and were examined.

to Israel 25 yr

settlements*

(Table

in each settlement

1).

were

Cases known to be diabetic or to

suffer from vascular disease were not included in the study. The subjects came to the examination blood was collected

determination

1 mg/ml

and in

studies, after which

following an overnight in heparin

disodium

i g glucose/kg

for glucose

EDTA

for lipid

body weight was given

and blood drawn after 30, 60, and 120 min in heparinized tubes for glucose and

insulin

determination.

history was taken and a physical examination Glucose analyzer

From the Diabetic Unit and the Isotope Laboratory for Endocrine Research and the Sh~mshon Family Mediea~ Center. &pat Holim Beit-Shemesh, ~epartrnent.~ of Inrernal Medicine A and B, Hadassah University Hospita! and Hebrew University. Hadassah Medical School. Jerusalem, Israel. Received for publication October I I, 1977. Supported by the United States-Israel &national Science Foundation Research Grant No. 804 and in part by the NIH Research Grant No. I ROI-AM-20733-01. Address reprint requests to Dr. A. M. Cohen, Head of Diabetic Unit, Hadassah Medical organization. Jerusalem, Israel. o I979 by Crune & Stratton, Inc. 0026-0495/79/2807.0002$02.00/0

182 maies and I24

females, aged 30 yr and over, are included

fast. Venous

716

METHODS

These Yemenites,

ratio was found to be reduced,

so in overweight

Three

AND

to those of nondiabe-

diabetics and 11 .O% of nondiabetics. HDL/LDL

MATERIALS

were

higher than levels upon their arrival. In diabetics. the plasma

ites.” whereas it was as high among old settled Yemenite Jews as among immigrants from Western countries.’ It has also been found that the rate of mortality from coronary artery disease among the “new ij~migrant Yemenites” was low in the first decade after their arrival in Israel but has increased during the following decade.’ During the last 2 yr, 18 yr after the first survey, we have reexamined the “new immigrant Yemenites” in Yemenite agricultural settlements around Jerusalem with the objective of finding out possible changes in the prevalence of diabetes compared with those of the initial survey and the plasma lipids and lipoproteins levels in nondiabetic and newly discovered diabetic Yemenites.

of insulin, but rather

of insulin action. in nondiabetics,

of plasma

A. Furst, and S. Eisenberg

was

determined

using

a

and insulin was determined

radioimmunoassay

using the Amersham

glucose tolerance test (CKiTT)

A

medical

made.

Beckman

glucose

by double-antibody Insulin Kit. An oral

was considered diabetic when

the blood glucose following the load was 2 I90 mg/ 100 ml at 60 min and 2 140 mgflO0

ml at 120 min. It was considered

normal when the blood glucose was G- I60 mg/ 100 m1 at 60 min and < 120 mg/ 100 ml at 120 min. Borderline cases were those with

blood glucose

values

between

189

and

160

mg/ 100 ml at 60 min and between I39 and I20 mg/ 100 ml at 120 min. Plasma lipids were studied in 289 subjects 116 females).

(169 males

For plasma lipid and lipoprotein

*The settlements are Bekoa. Givat-Yearim,

and

determina-

Ora. Shtulim,

Tarom. and Tzelafon.

Metabolism, Vol. 28, No. 7 (July), 1979

717

DIABETES. BLOOD LIPIDS, AND ENVIRONMENT

Table 1. Prevalence

of Diabetes

Underweight Borderline Examined

Age Groups Total

Overweight Diabetic

Number Age Group

in the Different

Borderline

Diabetic

Number N

%

N

%

Examined

Borderlnne

Diabetic

Number N

%

N

96

Examined

N

%

N

%

Males 30-44

35

1

2.9

2

6.7

26

2

7.7

2

7.7

61

3

4.9

4

6.6

45-55

21

3

14.3

3

14.3

24

3

12.5

3

12.5

45

6

13.3

6

13.3

55c

42

4

9.5

6

14.3

34

6

17.6

8

23.5

76

10

13.2

14

18.4

All ages

98

8

8.2

11

12.2

84

11

13.1

13

15.5

182

19

10.4

24

1 3.2

30-44

22

1

4.6

0

0

31

2

6.5

2

6.5

53

3

5.7

2

3.8

45-55

13

1

7.7

0

0

27

4

14.8

4

14.8

40

5

12.5

5

1 2.5

Females

55-c

13

2

15.4

1

7.7

18

4

22.2

5

27.6

31

6

19.5

6

19.5

All ages

48

4

8.3

1

2.1

76

10

13.2

11

14.5

124

14

11.3

12

9.7

306

33

10.8

36

1.8

Total for Males and Females Effect of obesity on prevalence of diabetes, for males x2 = 2.3520,

tion, plasma was separated within a few hours. The presence of a chylomicron layer was recorded by inspection of plasma stored at 4OC for 24 hr. Plasma lipid levels were determined by the autoanalyzer technique.3,4 HDL-cholesterol level was determined following he~rin-uncle precipitation of VLDL and LDL.* Paper electrophoresis of lipoproteins was performed as described by Lees and Hatch.6,’ LDL-cholesterol levels were calculated from the measured values of plasma cholesterol, plasma triglyceride, and HDL-cholesterol as described by Friedenwald et al.* The calculated LDL-cholesterol level was shown previously to reflect very accurately the true LDL-cholesterol level in an Israeli population examined by us in the Hadassah University Hospital.’ Hyperlipoproteinemia was defined by plasma and lipoprotein lipid levels following the WHO panel recommendations,“’ and using the cut-off criteria suggested by Fredrickson et al.” Accordingly, type IIA was diagnosed in subjects with LDL-cholesterol above 200 mg/lOO ml and normal plasma TG levels; type. IIB in subjects with elevations of both plasma TC and LDL-cholesterol levels; and type IV in subjects with plasma TG above 200 ml/ 100 ml and normal LDL-cholesterol. The more rare forms of hyperlipoproteinemia (types I, III, and V) were not encountered in the present study. According

to the ponderal

index (PI)-height

p NS kff = 1). for females x2 = 4.357 11 P c 0.02 (df = 1).

RESULTS

The percent of diabetic and borderline cases in the different age groups are shown in Table I. Of the total population, 11.8% were diabetic (13.2%

dq--

the subjects were subdivided into overweight and underweight groups. The “weighted average” PI for this population, assuming that all of them were at 100% normal relative weight,12 was 12.83 for males and 12.69 for females. Therefore, a similar PI was taken for both males and females as a cut-off point. In order to focus attention on the more overweight subjects, the cut-off point of 12.4 was chosen. Subjects with a PI of 12.4 and over were considered underweight, whereas those with a PI under 12.4 were considered overweight. The median PI for the total population was 12.488 + 0.550 for males and 12.179 r 0.388 for females. The insulin response curves were classified both in the diabetics and nondiabetics (according to the time of their maximal response-at 30, 60, or 120 min) as well as flat curves. Statistical evaluations were carried out using the Student t test and x*.‘~

Types of insulin and glucose response in underFig. 1. weight (PI > 12.4) and overweight (PI < 12.4) diabetic and nondiabetic Yemenites. Maximal insulin response at 30 min.

COHEN ET AL.

718

Types of insulin and glucose response in underFig. 2. weight (PI > 12.4) and overweight (PI < 12.4) diabetic and nondiabetic Yemenites. Maximal insulin response at 60 min.

Fig. 3. Types of insulin and glucose response in underweight (PI > 12.4) and overweight (PI < 12.4) diabetic and nondiabetic Yemenites. Maximal insulin response at 120 min.

of males and 9.7% of females) and 10.8% borderline cases (10.4% of males and 11.3% of females). The prevalence of diabetes increased with age in all age groups. Obesity resulted in an increase in the percent of diabetes in all the age groups for females, whereas in the male, obesity resulted in an increase of diabetes in the age group 55 + yr only. The effect of obesity on the prevalence of diabetes was not significant for males, but was significant for females, x2 = 4.35711, p < 0.05 (df = 1). The absolute blood glucose and plasma insulin

values at 0, 30, 60, and 120 min following the glucose load of the different types of insulin response curves with peaks at 30, 60, and 120 min are presented in Figs. l-3. The percent of the insulin response curves with peak at 30, 60, and 120 min as well as the flat curve in the nondiabetic and diabetic subjects is presented in Table 2. The change in insulin between the fasting level and that at 30, 60, and 120 min following the load in the different types of curves are presented in Table 3. In underweight nondiabetic subjects, about 39% of the cases had a

Table 2. Types of Insulin Response Following Oral Glucose Tolerance (%I Underweight

Overweight

Resqonsa Peaks

Response Peaks

Number Examined

Number 30 min

60 min

120 Ill,”

Flat

Examined

30 min

60 ml”

120 Ill,”

Flat

122

39.0

48.4

7.4

115

28.0

48.0

20.0

4.3

Borderline

12

8.3

50.0

25.0

16.7

21

0.0

42.9

47.6

9.5

Diabetic

12

8.3

50.0

25.0

16.7

24

8.3

50.0

33.3

8.3

Nondiabetic

Total

146

5.0

160

Nondiabetic

3

9.0

2

v. underweight,

vs. Nondiabetic,

SOverweiQht

tDiabetic

1.3

+ 2.0

t

f 3.7

t 3.1

+ 1.9

“corrected”

“corrected”

lZ G, + Ci= + GBO+ G,,i,.

6.0

3

NCXldiabetic

Diabetic

Flat

7.4

13.0

6

9.0

1.2

+ 2.27

8.0

9.4 f

12.8

Non *abetic

6

59

1

Fasting

Diabetic

120 min

Diabetic

Nondiabetic

60 min

Diabetic

47

With Peek

30 min

NUVlbW

Examined

Insulin Curve

5.8

28.0

29.8

34.6

35.5

17

0

k 3

+ 11.2

t

A 1.5

12.6

+ 1.5

+ 12.7

f

f 3.6

t 2.2

8.5

1 .o i- 2.0

0.4

48.0

54.5

4.7

8.6

8.0

120 ml”

of comparisons)

r 10.4

t 3.3

10

21 i. 2.7t

60 min

From Fasting Level

p x 4-number

+ 1.7

* 3

+ 7.0

f 5.2

+ 5.4

+ 2.6

p < 0.05.

p (“exact”

3.0

5.8

14.0

13.2

23.0

25.0

12.5

34 + 3.2f

30 min

lncnsse

Underweight

Table 3. Plasma Insulin Levels (Mean au/ml

<: 0.05.

1179

413

744

444

781

445

423

2 225t

* 23

* 53t

f 9

f 40’.

* 9.1

803

_+ 10.5$

min

GlUCOSEl*

O-120

Number

6.0 19.0

2

10.2

11.3

1.9

1.0

1.3

3

f 2.2t

+_ 2.0

f 2.8

f

12 *

11 t

152

12 f 2.5

Fasting

3

5

23

9

55

2

30

Examined

f 8.6

f 6.2$

5.0

+ 1.2

1.0 f 2.0

33.4

31.9

28 -t 4.0

38 2 3.7

93 f 21t

* 13.7

t 7.4

10

7.0

+ 0.4

1.3 -r 3.0

57.4

40.2

60 t

53 f 5.7$

67 i Ott

28 k 6.4

60 min

+ 3.0$

t 48$

zt 6.8

t f

12

11.4

6.0

t 2.3

1.7 ). 2.9

71.2

64.8

36 f: 5.7t

20.7

102.0

22.4

120 min

lncressa From Fasting Level

55 * S.lt.

30 min

Overweight

‘_ SE1 in Diabetics and Nondiabetics Following Oral Glucose Load

Glucose+

886

334

784

459

783

* 52t

+ 42

+ 40t

r 15

zt 44t

2 10

* 94t

885

484

+ 15

448

O-120min

COHEN ET AL.

720

maximum insulin response at 30 min, whereas in the diabetic subjects only 8.3% of the cases had a peak at 30 min. At 60 min, 48.4% of the nondiabetics and 50% of the diabetics had a peak. Of the diabetic subjects, 16.7% had a flat curve, versus 7.4% in the nondiabetic subjects. In the overweight category, 28% of the nondiabetic subjects and 8.3% of the diabetics had a maximum response curve at 30 min whereas 48% of the nondiabetics and 50% of the diabetics had a delayed response with peak at 60 min. There is no significant difference in the extent of insulin response of the nondiabetic and the diabetic in the corresponding types of curves (as multiple comparisons were made, the “exact” p was multiplied by 4, which is the number of comparisons in each instance) except for the 30-min peak curve of the underweight group (Table 3) and the 60-min values of the 30-min peak of the overweight group as well as the

different age groups vary inconsistently with age. In the several cases where the insulin values are lower in the older age group, the difference is not significant. In a large proportion of the overweight group, especially in males, the insulin values following the glucose load are significantly higher when compared to the corresponding underweight groups. Table 6 shows the ratio of the increase of blood glucose level from fasting levels to the corresponding increase of insulin values from fasting levels at 30, 60, and 120 min after the glucose load in the different types of insulin response curves. It is evident that the higher glucose insulin ratio in the diabetics at the different periods and in all types of insulin response curves are attributable to undue hyperglycemia, since insulin increments at these times were not different from those present in the normal glucose tolerance. The correlation index of plasma triglyceride. plasma cholesterol, and LDL- and HDL-cholesterol levels as related to age and sex in nondiabetic subjects is shown in Fig. 4. In both males and females the regression analysis (r) for the increase of total cholesterol and of LDL-cholesterol levels, with age, was signi~~nt, whereas for the TG level it was not significant. The regression analysis for the increase of‘ HDLcholesterol level, with age, was signihcant for females, but not for males. Mean plasma triglyceride, plasma cholesterol, LDLand HDL-cholesterol levels and HDL/LDL ratio are shown in Table 7. The mean plasma triglyceride was higher in overweight males and females as compared to underweight, but significant only in overweight nondiabeti~ males. Plasma cholesterol levels were in general higher in overweight as

120-min values of the 618min peak of the overweight group. The fasting insulin in the diabetics was not significantly different from that of the nondiabetics in the underweight group. In the overweight group, the fasting insulin of the diabetics was higher in the flat curves. Table 4 details the absolute blood glucose levels following OGTT in the underweight and overweight nondiabetic subjects in the different age groups. No difference due to aging was noted in the blood glucose values at 60 and 120 min following glucose load. It appears that females have lower blood glucose values than males, but the difference is not statistically significant. Table 5 details the insulin response following OGTT in the nondiabetic underweight and overweight subjects of the different age groups. It is apparent that the plasma insulin levels in the

Table 4. Glucose Tolerance Test in Nondiabetics of the Different Age Groups (Mean mg/lOO ml t SE) Overweight

Underweight

Ttme Followng

Tsme Following Glucose Load Exammed

0 in,”

Glucose Load

Numbw

Number Age Group

60 mm

120 min

Examined

0 min

60 mu?

120 ml”

30-44 MElie

32

86 + 1.5

110 i 2.9

86 t 2.4

22

86 I

1.8

118 t 3.7

94

Female

21

81 i- 2.0

110

t 3.2

90 f 3.5

27

86 ? 2.2

115 t 4.1

34 ? 3.1

+ 3.3

45-55 MaI@

15

87 t 2.3

125 t 4.4

65 f 3.8

18

86k22

131 12.2

92

f 3.6

FCllWle

12

87

116

c 6.7

86 + 5.3

19

83 ? 2.7

118

+ 4.5

95

r 3.5

Male

32

67 i 2.3

121 _i 2.9

82 + 3.1

20

so i 3.4

122

+ 4.9

95 f 4.3

Fi?m&e

10

64

117

87 f 5.0

9

85 t 2.5

I12

+ 6.6

96

i

1.9

55t

r 4.0

t 3.9

r42

Number

32

10

55+

15.0

11.9

t 3.6

i; 1.7

i 2.3

t 0.7’

t 1.2

t 1.2

39.0

23.0

30.0

29.0

27.2

+ 4.8

+ 3.4

+ 4.2

* 3.2

lr 6.0

i: 4.4

30 min

35.7

overweight, “corrected” p < 0.05.

12

*Underweight

21

30-44

45-55

Females

12.6

9.4

15

55+

9.8

32

12.6

Fasting

45-55

vs.

Examined

30-44

M&5

Ase GWJP

(Mean flu/ml

37.8

28.2

25.6

34.2

26.0

25.9

i 8.0

f 7.4

+ 3.0

k 4.2

-c 6.2

2 4.3

60 min

-

4.8

17.5

9.8

11.1

8.5

12.7

1.9

x 5.1

* 6.6

i

+ 2.0

+ 5.0

t 2.2

120 ml”

;t SE) in Nondiabetics

increase From Fasting Level

Underweight

Table 5. Plasma Insulin Response

9

19

27

20

18

22

Exammed

Number

in Different

11.4

9.9

10.7

15.9

17.0

12.9 1.4

1.3 + 1.7

f

i- 1.2

+ 5.8

+ 2.4t

i

Fasting

48.9

29.4

34.0

37.8

48.0

50.0

i

11.0

zt 8.0

r 4.8

i: 7.8

+ 7.2

+ 5.6

30 min

Overweight

32.3

25.0

34.8

38.0

56.2

46.4

* 8.0

2 5.2

t 4.4

+ 5.6

zt 8.0’

f. 4.9*

60 min

Increase From Fasting Level

Age Groups Following Oral Glucose Load

35.3

14.5

26.7

25.0

24.6

33.3

f 9.0.

A 3.9

f 3.9’

+ 10.0

e 6.3

* 6.7’

120 min

COHEN ET AL.

722

Table 6. Glucose/Insulin Time Following Glucose

Insulin response-peak

+ SE) in Nondiabetic,

Borderline,

and Diabetic Glucose Tolerance

Underweight

Load

(mini

Ratios (Mean

NondiabetIc at

Tests

Overweight

Borderline

Diabetic

Baderline

NondiabetIc

Diabetic

30 min

30

1.52

+ 0.17

3.94

5.06

1.14

t

1.40

18.9

t

10.8

60

1.52

+ 0.20

3.7

8.50

1.50

t: 0.47

30.4

i

12

? 0.94

3.8

9.33

0.20

+ 0.30

27.0

f; 6

120

-0.60

I?

48

insulin response-peak 30 60 120

+ 0.34

8.50

+z 3.9

24.5

r 2.12

2.76

-f 0.54

2.40

+ 0.6

5.7

i

4.60

r 2.8

8.5

f 0.92

1.04

* 0.22

1.40

t 0.3

2.9

f 0.6

+ 1.00

4.00

r

1.0

t 0.62

1.44

+ 0.72

3.5

59 at

1.6

6

+ 7.7

-0.7

6

55

9

r

1.1 1.0

12

120 min 4.87

60

PO.8

120

2

+ 0.23

30

”

32

1.54 -0.82

response-peak

1

2.25

n Insulin

1

at 60 min

-0.24 6

* 2.98

2.50

i: 0.80

47.0

+ 17.0

4.03

z+ 1.66

3.65

+ 0.73

4.80

t 8.74

+ 2.7

4.50

+ 2.6

11.6

c 4.8

1.48

i 0.44

3.30

+ 0.80

4.15

+ 0.82

zt 0.3

2.00

+ 1.2

3.08

+ 0.7 1

0.80

+ 0.1

0.88

3

3

compared to underweight subjects, but these differences were not statistically significant. Mean LDL-cholesterol was variable among the groups, and significantly higher in overweight diabetic males. Plasma HDL-cholesterol levels were in general lower in overweight subjects, but significant changes were noted only in nondiabetic males. Significant increases of mean blood lipid levels from nondiabetic through borderline and

23

_t 0.16 10

._

t 0.8 2

diabetic subjects were noted in the following measurements and categories: with plasma TG (underweight diabetic males and overweight diabetic females), plasma cholesterol (underweight diabetic males and overweight diabetic males), and plasma LDL-cholesterol (overweight diabetic males). The HDL/LDL cholesterol ratio was lower in overweight than in underweight subjects, significantly so only in the case of diabetics.

FEMALES

AGE ormfs~

3.1

n-c

yemenltes.

11

Diabetic

18.0

tp -c0.05,

-C 0.05,

13

Diabetic

lp

177

13

212

207

186

211

188

179

12.9.

+ 11.6’

+ 14.6

+ 4.4

t

k 16.0

+ 2.9

Plasma

3 5.0 18.0 7.3*t

t

140 133 I

1.3t

36 k 3.6

39 + 2.7

39 f

49 + 7.0

112 it 6.3

114

0.353

41 + 6.5

+ 0.038

t 0.02 + 0.06 + 0.005’t

0.372

0.289

r 0.050

+ 0.057

0.327

0.370

0.462

47 ? 1.9

126 rt. 13.7

HDL

113 * 3.5

LDL

HDL/LDL

Lipid Levels of Nondiabetic,

Cholesterol (mg/dl)

overweight vs. underweight of the respective group.

diabetic vs. nondiabetic within the PI group.

+ 36

f 31.0

136 f 8.0t

164

51

Nondiatwtic

128 + 9.5.

115 *

96 zt 5.3

(m&II

TG

Plasma

Borderline

Overweight

9

72

Examined

Bwderline

Nondiabetwz

Undwweight

Subiects

Number

Male

Table 7. Plasma and Lipoprotein

11

11

46

1

4

43

Examined

Number

Borderline,

f 6.5

135

+ 14.0.

117 + 17.0

101

103

81 + 12.0

SO f 3.6

(mg/dl)

TG

PlaSma

and Diabetic

183

199

227

194

183

11.3

+ 7.5

r 10.3

A 5.0

199

f

f 4.1

12.2

f 5.3

133

f

134

+ 10.4

138 f 9.6

137

122

124 f 4.8

LDL

Cholesterol

t SE)

Female

(Mean

Plasma

Subjects

0.341 0.275

47 f 2.3 35 a 3.7

42 + 1.6

0.328

0.387 45

0.368 44 t 3.3

k 0.514.

k 0.003

-r 0.019

0.338

f 0.057

k 0.022

HM/LDL

43 f 2.4

HDL

hng/dl)

E

P

724

COHEN ET AL.

Table 8. Incidence of Hyperlipoproteinemia Diabetic,

(%I Among

Nondiabetic.

Borderline

and Diabetic Subjects

Subject

Examned

IIA

IIB

219

2.3 15)’

0.9 (21

LipoproteinType

Number

Nondiabetic

IV

7.7 (17)

Borderline

31

6.4 (2)

3.2 (1)

12.9 (4)

Diabetic

36

11.1 (41

2.8 (1)

13.9 (5)

67

9.0 (6)

3.0 (2)

13.4 (9) .-I__

esting to note that in diabetic subjects with hyperlipoproteinemia, the HDL/LDL cholesterol ratio was lower than in nondiabetics with comparable lipoprotein profiles. These differences are significant for type 1la and I lb. DISCUSSION

Diabetic IBorderline ‘Number

in parentheses represents number of subjects with

specified lipoprotein type. x2 nondiabettc vs. diabetic = 9.5472.

p c 0.05 (df -= 1).

x2 Nondlabetvz vs. borderline = 5.3424,

p. NS Idf = 1).

The incidence of hyperlipoproteinemia in nondiabetic, borderline, and diabetic subjects is shown in Table 8. it is evident that in diabetic subjects, all three types of hyperlipoproteinemia were more common than in nondiabetic subjects. We are aware of the small number of cases of diabetics, but we still calculated the x?: nondiabetic versus diabetic = 9.5472, p -: 0.05 (df = I ). Mean plasma lipid and lipoprotein levels of subjects with normal lipoprotein profile and the three types of hyperlipoproteinemia encountered in the study population are shown in Table 9. As expected, LDL-cholesterol levels were elevated in subjects with types Ila and Ilb and TG was elevated in types Ilb and IV when comparing hyperlipoproteinemic subjects to those with normal lipoprotein pattern, either in the nondiabetic, borderline, or diabetic subjects. It is inter-

Table 9. Plasma and Lipoprotein

of Diabetes

Our diagnostic

criteria for diabetes meliitus based on both a I-hr value of 190 mg/IOO ml and a 2-hr value of 140 mg/ 100 ml glucose following an oral glucose load satisfy the commonly used criteria.14.‘” This abnormal glucose tolerance test indicates “chemical and not necessarily “clinical diadiabetes” betes”.” The percent of maturity-onset diabetes in the examined population is 11.X% (I 3.3% in males and 9.7% in females). These results arc not different from those observed in other studies outside Israel.” ” The present results confirm our previous observations’ that on changing the environment, this population, in which almost no diabetes was detected 20 yr ago. now has a prevalence of diabetes comparable to other affluent communities. The incidence of maturity-onset diabetes increased with age and was higher in individuals who were overweight. In spite of the small number of cases, WC calculated the x’. which is significant for overweight females, but not for males. This is in accordance with the known fact

Lipid Level Among Subjects With Normal Lipoprotein Hyperlipoproteinemia

Llpoproteln Pattern

Prevalence

(Mean

Cholesterol

TG

Plasma

Profile and With

i SE1 lmgidl)

LOL

HDL

--_-HDL/LDL

NondiabetIc 88 t 2.7

175 f 2.0

114 t 1.9

IIA (5)

Normal (195)’

101 1? 11.1

274 i- 3.1

232 -t 10.0

IIB (2)

242 I 4.5

317 -t 16.5

243 f 11.5

IV (17)

273 + 15.6

205 i 6.7

102 + 7.1

44 1- 1.0 44.6

0.386

f 0.008

f 3.2

0.257

-r 0.027

36 * 0.5

0.176

? 0.1

0.340

f 0.023

0.362

i 0.035

35.2

+ 2.1

Borderline Normal 124) IIA 121 flB (1) IV (4) Diabetic

89 + 6.7 131 -r 27 203 461 + 129

177 i 7.0

116 ?r 5.7

42 5 3.6

289 + 11.5

221 * 4.0

41 +6

289 244 ?: 43

214

35

0.1829

i 0.03

0.1636

108 r 20

59 t- 13

0.458

Normal (26)

116 +8t

187 t 6.0

122 15.7

41 -c 3.3

0.3515

IIA (4)

122 * 34

301 + 23.7

226 + 12.6

35 t 0.5

0.182

IIB (1)

250

284

IV 151

310 ” 66.9

209 rt 18.2

*Number in parentheses represents number of subjects. tNondiabetic vs. diabetic p --c0.05.

219 131 k 8

29 36 i; 5.3

t 0.10 2 0.037 + 0.004t

0.132 0.2666

.k 0.028

DIABETES, BLOOD LIPIDS, AND ENVIRONMENT

that obesity significantly alters glucose tolerance.*’ It is noteworthy that in this population the effect of obesity on the prevalence of diabetes was more pronounced in females than in males. While the effect of overweight versus underweight on the increase in the prevalence of diabetes in males was observed in the older age group only, in females its expression was significant and evident in the younger age groups as well. It remains to be seen whether obesity is the primary cause for the increased prevalence of diabetes or if it accompanies diabetes as part of the metabolic changes that have occurred in this population on changing their environment, since in males there was a pronounced increase in the prevalence of diabetes in the underweight group as well. The prevalence of maturity-onset diabetes in males was higher than in females in the underweight group, whereas in the overweight group the prevalence in females almost equaled that of males. This higher diabetic male/female ratio was also observed in our previous survey among the old settled Yemenites’ and in other populations.“-24 The role of obesity in the change of this ratio observed in the present study may explain the changing sex incidence of diabetes that was observed in recent decades in the “developed countries” where an increase of diabetes among females was found in all age groups.‘~ “-*’ Several authors reported an initially delayed insulin response to hyperglycemia as a common feature to all forms of maturity-onset diabetes mellitus from prediabetes,28,29 the mildest forrns30 and the clinical overt disease.“-33 However, other investigators have reported identical or greater insulin response to intravenous or oral glucose in diabetic subjects, obese or nonobese, than in nondiabetics of comparable age, height, and weight.“, 34-36 We have therefore classified, both in the nondiabetics and diabetics, the insulin response curves according to the time of the maximal peak. It is apparent that in maturity-onset diabetics 91.7% of the underweight and 91.7% of the overweight have delayed insulin responses. It is noteworthy that among the nondiabetics, 53.4% of the underweight and 68% of the overweight also have delayed insulin responses with peaks at 60 or 120 min following the glucose load. However, the extent of the insulin responses of the diabetics, at all times, in the

725

corresponding types of insulin curves are not significantly different from the nondiabetics except for the cases with the 30-min maximal responses. The higher glucose/insulin ratio in the diabetics at the different periods of time, except for the flat curve responses, is attributable to undue hyperglycemia, since insulin increments at those times were not different from those present in the normal glucose tolerance. In conformity with other studies,37.3X our results indicate no significant difference in the fasting insulin levels between maturity-onset diabetics and nondiabetics in the underweight group. In the overweight group the fasting insulin level of diabetics with a flat curve are higher than the respective nondiabetic groups, as reported by Karam et al.39 Thus, in the early stages of adult-onset diabetes the fasting insulin and the insulin response is not different from that of the nondiabetic controls. It has been reported by some40.4’ that with advancing age there is deterioration of the mean glucose tolerance. However, our results are in accordance with other observers’B,4’,J’ who did not find any deterioration of glucose tolerance with age in nondiabetic individuals (i.e., those with normal glucose tolerance). Insulin release following glucose stimulation was also reported by some authors44,45 to deteriorate with age. Our results in the nondiabetics do not show any consistent pattern of change in the insulin response with advancing age, in conformity with the reports of other investigators 42.46 48 In the diabetic glucose tolerance curves, the ratio of glucose insulin increment from fasting level at 30, 60, and 120 min are higher than in the nondiabetic. This is attributable to undue hyperglycemia, since insulin increments at these times equaled those present in normal glucose tolerance, both in underweight and overweight subjects, except for the flat curves. It appears that in order to explain this fact one has to resort to “insulin resistance” or imply that the insulin molecule itself is structurally not intact. Obesity is frequently cited as a cause of insulin ineffectiveness, but this ineffectiveness was also evident in our nonobese diabetics. The maturity-onset diabetes mellitus, even in its early stages, is often defined as undue hyperglycemia resulting from a shortage of insulin. Our results cannot support this view. They

726

COHEN ET AL.

suggest rather that there is a shortage of insulin action. flood Lipids in ~o~diub~tic ~ubj~et~

Plasma cholesterol and LDL-cholesterol levels were significantly lower in the nondiabetic Yemenite settler described here compared to the non-Yemenites reported recently by Eisenberg’ and Klorfajn et a1.49(Table lo), whereas HDLcholesterol and plasma TG levels did not differ. However, the non-Yemenites were not screened for impairment of glucose tolerance and represented an urban population. The plasma cholesterol level in the non-diabetic Yemenite settlers now living in Israel for 25 yr is higher than levels found soon after their arrival in Israel, as reported by Toor et aL5’ and Brunner and Lobl.5’ In our nondiabetic population, the regression analysis did reveal a significant increase of total cholesterol and LDL-cholestero1 levels with age, whereas there was no such trend for an increase of plasma TG levels. This is in conformity with several authors52353who reported an increase of the blood cholesterol level with age in both males and females. Other investigators report no change with age.49.s4Obesity resulted in significant increases of plasma TG levels and decreased HDL-cholesterol levels in males but not females. Blood Lipids in diabetic Subjects

Plasma TG was increased in the diabetics, both male and female. The LDL-cholesterol was increased in males while no consistent trend was noted in the HDL-cholesterol levels. Higher prevalence of hyperli~mia among diabetic subjects as compared to nondiabetics was reported by several investigators.55--59Simi-

larly, in this unique Yemenite population in Israel, the incidence of hyperlipoproteinemia among the diabetics was more than twice that of nondia~ti~s, 27.7% and 1.096, respectively, whereas the per cent of subjects with different types of hyperlipoproteinemia was similar to that reported by other investigators.56-59These observations, together with those already discussed herein, indicate that in the Yemenite population an increase of plasma Iipid levels occurred during the 25 yr following immigration to Israel, most probably due to the changing environmental conditions. However, the expression of diabetes in this unique population, at least as related to the plasma lipid and lipoprotein levels, was similar to that of other non-Yemenite diabetic populations. The present study is the first investigation in Israel in which plasma HDL-cholesterol levels were determined in diabetic and nondiabetic subjects of one ethnic group living under similar environmental conditions. Clinical and epidemiologic studies show a consistent negative correlation between absolute plasma HDL concentration and coronary risk.60-62It has been postulated6’ that the “protective” effect of HDL may relate to the role of HDL in the removal of cholesterol from peripheral tissues.63.64Carew et alS6j suggest that raised HDL concentrations may limit the uptake by smooth muscle of the arterial wall of LDL, a lipoprotein that contributes to the initiation and progression of atherogenie lesions. The decisive factor in coronary risk is the relative HDL/LDL ratio at any given LDL concentration.b’.62 Our data (Table 7) suggests that in the underweight man and woman, HDLjLDL ratio is not affected by diabetes, while diabetes in the overweight male and female results in a decreased HDL/LDL ratio.

Table 10. Plasma Lipids and Cholesterol Levels in Yemenites and Non-Yemenites With Normal Lipoprotein Profile (Mean f SE) Cholesterol (mg/d~) Group

Nondiabetic Yemenites

NUmbar

Plasma TG

Examswd

fmgid4

219

105 + 2.7’

185 r 2.0

121 * 1.9

43 * 1.0

65

104 t 4.1

208 + 4.lt

139 + 2.q

44 + 2.1

386

112 + 2.6

227 * 2.1t

-

-

Plasma

LDL

HDL

Non-Yemenites (Eisenberg? Non-Yemenites (Klorfajn et al.“)

lt

= mean + SE.

tp < 0.01 Yemenites vs. non-Yemenites.

727

DIABETES, BLOOD LIPIDS, AND ENVIRONMENT

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728

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COHEN ET AL.

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