The amount of alcohol consumed correlates with the values of different laboratory parameters. Although one of the most frequently used markers of alcohol consumption is the erythrocyte mean cell volume (MCV), the extent of the increase of MCV varies from one individual to another.1 This cannot be explained only by inaccuracies in measuring alcohol intake by interviews or questionnaires. The major enzymes responsible for alcohol metabolism are alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ALDH). Among the ADH and ALDH genes, the polymorphisms of ADH2 and ALDH2 are thought to contribute to individual differences in the elimination rates of alcohol and acetaldehyde, respectively.2 In this study, we examined the relations between the polymorphisms of these genes and the levels of MCV in drinkers.

The subjects were 133 male workers aged 25 to 59 years (average, 46 years) who drank more than 300 g alcohol per week (average, 375 g). Informed consent was obtained from all subjects. DNA was extracted from peripheral blood leukocytes. The ADH2genotype was determined by polymerase chain reaction and subsequent digestion with MaeIII according to the method of Xu et al.3 The ALDH2 genotype was determined based on amplified product length polymorphism analysis using 3 oligonucleotide primers according to the method described by Aoshima et al.4 For statistical analysis, the Tukey multiple comparison test was used to assess significant differences between group means. Analysis of covariance was used to estimate the means of variables adjusted for the confounding variables.

In the 133 men, the frequencies ofALDH21/21, ALDH21/22, andALDH22/22 genotypes were 78.9%, 20.3%, and 0.8%, respectively. The frequency of theALDH21/21 genotype was higher, and the frequencies of the ALDH21/22 andALDH22/22 genotypes were lower, compared with those in Japanese subjects, including drinkers and nondrinkers.5 This is probably because we examined only heavy drinkers. When the subjects were divided into theALDH21/21, ALDH21/22, andALDH22/22 groups, theALDH21/22 group had significantly higher MCVs than the ALDH21/21 group (Table 1). No difference in hemoglobin level between the 2 groups was observed. Similar results were obtained after correction for age, body-mass index, smoking, alcohol consumption, and ADH genotype. Because theALDH22/22 genotype was observed in only one subject, we could not compare this group with the other 2 groups. In contrast, when the subjects were divided into theADH21/21, ADH21/22, andADH22/22 groups, no difference in the MCVs and hemoglobin concentration was observed among the 3 groups. Multiple regression analysis revealed that MCV was positively associated with the ALDH genotype (P = .0001), the amount of smoking (P = .0208), and age (P = .0237), but negatively associated with the body-mass index (P = .0374). There was no association between MCV and the amount of consumption or the ADH genotype.

Table 1.

Peripheral blood data of the subjects distributed according to their ADH2 and ALDH2 genotypes

ALDH2genotypesADH2 genotypes
21/2121/2221/2121/2222/22
n 105 27 29 42 62 
Not adjusted      
 Erythrocyte count, 1012/L 4.82  (0.03) 4.64  (0.08) 4.72  (0.07) 4.83  (0.04) 4.79  (0.05)  
 Hemoglobin level, g/L 150  (1) 150  (2) 148  (2) 151  (1) 150  (1) 
 Hematocrit, fraction of 1.00 0.472  (0.003) 0.467  (0.005) 0.464  (0.005) 0.474  (0.004) 0.472  (0.004) 
 MCV, fL 97.9  (0.4) 101.1  (1.0) 98.6  (0.7) 98.4  (0.6) 98.7  (0.6)  
 Leukocyte count, 109/L 5.97  (0.16) 5.94  (0.23) 5.98  (0.30) 5.82  (0.20) 6.03  (0.21) 
Adjusted      
 Erythrocyte count, 1012/L 4.82  (0.03) 4.64  (0.06) 4.72  (0.06) 4.82  (0.05) 4.79  (0.04) 
 Hemoglobin level, g/L 150  (1) 150  (2) 148  (2) 151  (1) 150  (1)  
 Hematocrit, fraction of 1.00 0.472  (0.003) 0.468  (0.005) 0.464  (0.005) 0.475  (0.004) 0.471  (0.004)  
 MCV, fL 97.9  (0.4) 101.3  (0.8) 98.4  (0.8) 98.5  (0.6) 98.7  (0.5)  
 Leukocyte count, 109/L 5.95  (0.13) 6.00  (0.27) 5.91  (0.26) 5.93  (0.21) 5.99  (0.18) 
ALDH2genotypesADH2 genotypes
21/2121/2221/2121/2222/22
n 105 27 29 42 62 
Not adjusted      
 Erythrocyte count, 1012/L 4.82  (0.03) 4.64  (0.08) 4.72  (0.07) 4.83  (0.04) 4.79  (0.05)  
 Hemoglobin level, g/L 150  (1) 150  (2) 148  (2) 151  (1) 150  (1) 
 Hematocrit, fraction of 1.00 0.472  (0.003) 0.467  (0.005) 0.464  (0.005) 0.474  (0.004) 0.472  (0.004) 
 MCV, fL 97.9  (0.4) 101.1  (1.0) 98.6  (0.7) 98.4  (0.6) 98.7  (0.6)  
 Leukocyte count, 109/L 5.97  (0.16) 5.94  (0.23) 5.98  (0.30) 5.82  (0.20) 6.03  (0.21) 
Adjusted      
 Erythrocyte count, 1012/L 4.82  (0.03) 4.64  (0.06) 4.72  (0.06) 4.82  (0.05) 4.79  (0.04) 
 Hemoglobin level, g/L 150  (1) 150  (2) 148  (2) 151  (1) 150  (1)  
 Hematocrit, fraction of 1.00 0.472  (0.003) 0.468  (0.005) 0.464  (0.005) 0.475  (0.004) 0.471  (0.004)  
 MCV, fL 97.9  (0.4) 101.3  (0.8) 98.4  (0.8) 98.5  (0.6) 98.7  (0.5)  
 Leukocyte count, 109/L 5.95  (0.13) 6.00  (0.27) 5.91  (0.26) 5.93  (0.21) 5.99  (0.18) 

All values are the mean (SE).

*

Adjusted for age, body-mass index, smoking, alcohol consumption, and ADH genotype or ALDH genotype. Because the ALDH22/22 genotype was observed in only one subject, theALDH22/22 genotype group was omitted from the table.

P < .05 between 21/21 and 21/22.

P < .001 between 21/21 and 21/22.

The present study indicated that the extent of the increase of MCV in alcohol drinkers depended on the individual ALDHgenotype. Although drinkers are well known to show macrocytosis, the cause of their macrocytosis is not clear. Because the ALDH2genotype is largely responsible for blood levels of acetaldehyde after alcohol consumption, the macrocytosis observed in drinkers might be caused by increased blood levels of acetaldehyde.

Supported in part by grants from the Health Science Center Foundation, the Smoking Research Foundation, and the Clinical Pathology Research Foundation of Japan

1
Conigrave
KM
Saunders
JB
Whitfield
JB
Diagnostic tests for alcohol consumption.
Alcohol Alcoholism.
30
1995
13
26
2
Bosron
WF
Li
T-K
Genetic polymorphism of human liver alcohol and aldehyde dehydrogenases, and their relationship to alcohol metabolism and alcoholism.
Hepatol.
6
1986
502
510
3
Xu
Y
Carr
LG
Bosron
WF
Li
T-K
Edenberg
HJ
Genotyping of human alcohol dehydrogenases at the ADH2 and ADH3 loci following DNA sequence amplification.
Genomics.
2
1988
209
214
4
Aoshima
T
Umetsu
K
Yuasa
I
Watanabe
G
Suzuki
T
Simultaneous genotyping of alcohol dehydrogenase 2 (ADH2) and aldehyde dehydrogenase 2 (ALDH2) loci by amplified product length polymorphism (APLP) analysis.
Electrophoresis.
19
1998
659
660
5
Suzuki
Y
Muramatsu
T
Taniyama
M
et al
Mitochondrial aldehyde dehydrogenase in diabetes associated with mitochondrial tRNALeu (UUR) mutation at position 3243.
Diabetes Care.
19
1996
1423
1425
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