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Kinetics of Human Epidermal Cell Proliferation: Diurnal Variation*
Vol. 50, No. 6
THE JOURNAL 05' INVESTIGATIVE DERMATOLOGY
Copyright
Printed in U.S.A.
1968 by The Williams & Wilkins Co.
KINETICS OF HUMAN EPIDERMAL CELL PROLIFERATION: DIURNAL VARIATION* GUINTER KAHN, M.D.,t GERALD D. WEINSTEIN, M.D. AND PHILLIP FROST, M.D.
being over 50 years old. The patients had been hospitalized for physical rehabilitation because
In studies of animal epithelial tissues in Which mitoses Were counted at different times of day, the time of maximal and minimal activity has varied greatly depending upon the species and
of orthopedic problems. Only one patient (JF) had a systemic illness, mild diabetes, under eoatrol. The biopsy specimens were processed for autoradiog-
experimental conditions. Most investigators raphy with 6 micron histologic sections and ex-
have concluded that mitotie activity is greatest posed to photographic emulsion for 3—4 weeks. When an animal is at relative rest. These stud- Autoradiographs were analyzed by projecting their images magnified 175 times onto paper and ies are summarized in Table I.
tracing the perimeter of the epidermis. The length of the basal cell layer was measured and from this the number of basal cells in a section was deter-
In previous studies of diurnal variation of proliferative activity in human tissues, mitoses were counted. Autoradiographie methods,
mined as follows:
Which utilize tritiated thymidine as a marker for cells synthesizing DNA in preparation for mitosis, may also be employed to measure the proliferative activity of a cell population (1, 2). With this technic cellular proliferation can be analyzed more easily and with greater accuracy since there are more cells in DNA synthesis than in mitosis at a given moment and since labeled cells are easier to identify than mitoses. The present study was performed to determine whether diurnal variation of epidermal cell proliferation is present in human epidermis by tritiated thymidine labeling experiments. It would be important to be aware of such diurnal variations in view of the many
number of basal cells in a section
studies on cellular kinetics now being performed using tritiated thymidine teehnies.
= basal cell layer length width of average basal cell Areas of epidermal thickening associated with hair follicles and sweat gland ducts were not included in the measurements. Using smaller areas of epidermis under higher
magnification the width of an average basal cell was calculated as follows:
average basal cell width
=
One-tenth ml (5 microcuries) of thymidine-1H 1.9 C/mM) was injected intradermally into each of 4 areas of normal lumbar skin. The thymidioe-1H was injected at 0600, 1200, 1800, and 2400 hours into 7 men and 2 women. Injection sites
cell layer length number of basal cells
The labeling index, i.e. the percentage of basal cells labeled by thymidine-5H thirty minutes after injection, was thea determined: labeling index number of labeled cells X 100% total number of cells in the basal layer
MATERIAL5 AND METHODS
(sp act =
basal
The variability and reproducibility of the experimental technic were tested by performing duplicate or triplicate injections and biopsies at
were marked and 30 minutes later 4 mm punch the same time in five patients. biopsy specimens were taken. The average age of RE 5TJLTS the patients was 61, seven of the nine subjects
This work was supported by research grants
from the National Institutes of Health (CA10292) and the Hartford Foundation. Accepted for publication December 23, 1967.
The labeling index for each patient at different hours is presented in Table II. An average of 146 labeled cells were counted at each time in each patient. When the data from each
* From the Department of Dermatology, University of Miami School of Medicine, Miami, patient were plotted on a graph, no pattern of diurnal variation among the different subFlorida, 33136. t Present address: Division of Dermatology, jects was apparent. However, there was eviUniv. of Colorado Medical Center, Denver, dence for a slight increase in the rate of cell Colorado. 459
460
THE JOURNAL OF INVESTIGATIVE DERMATOLOGY
TABLE I Diurnal variation of mitotic activity System
Tissue
Age
Kittens (6)
Newborn
Mice
Not stated Lymphatic
White mice (6)
28 Days
Lymphatic
Rat)o9f Ref
Time oi1maximum
Time oçminimum
2230—0230
1030
2.1:1
3
1100
0300
2.5:1
4
1200
2000—2400
3.0:1
15
2.0:1
16
Epidermis, lumbar area
White mice (48)
1—7 Days
Abdomen
2000
1200
Human (males) (13)
8 Days
Epidermis, prepuce
2100
1000
Human (males) (57)
6—11 Days
Epidermis, prepuce
2200
0500—1000
3.6:1
10
Human (males) (14)
Infant
Epidermis, prepuce
2100
1000
2.0:1
11
Epidermis, abdomen
0800
2000
3.5:1
17
3.2:1
6
Albino rats (males) 28 Days
9
(98)
Male mice
2—4 mo.
Epidermis, ear, back; 0600 epithelia of esoph- and 1400 agus, duodenum, epididymis
Epidermis, shoulder
Human (males) (12)
20 years
Hairless mice (48)
Not stated Epidermis, back
1000
and (two max- 2000 ima)
(two mmima)
3.2:1
2400—0300
1000—1300
6.0:1
18
2400
1400
4.7:1
5
Numbers in parentheses indicate number of subjects in each study.
proliferation at midnight when the data were
(3, 4) and has since been observed in many
analyzed in the following manner: The mean of the four labeling indices for each subject was
other animals. As seen in Table I there has been no consistency in the time when maximum and
calculated and the percent variation at each minimum mitotic activity occurs. Important different hour from the individual's mean was determinants of proliferative activity to be determined (Fig. 1). These data were examined statistically by Wilcoxon's Signed-Ranks Test, which revealed that at 2400 hours (midnight) there was a small but significant increase in la-
considered include age, sex, physical condition, environment, metabolic rate, intracellular car-
bohydrate levels, and the proximity of other animals (5—8). Physical activity of the animal
beling indices above the individual's means is reported to result in lower mitotic counts (p < 0.05). No significant differences were (6). The diurnal variation of physical activity found at the other hours. in most species must, therefore, also be conIn the experiments designed to test the re- sidered. Cooper and Broders et al. have shown liability of each value, it was found that the that newborn infants (whose activity and enaverage variance in each patient was less than vironment are presumably uniform over 24 hours) have a definite cireadian rhythm of epi15% (Tab. III). dermal cell mitoses (9—11). Scheving conDISCUsSION
firmed this finding in the shoulder skin of adult
Diurnal variation of epidermal mitotic ac- males (18). These studies therefore indicate tivity was originally noted in kittens and mice that there is at least a two fold increase in the
461
DIURNAL VARIATIONS
TABLE II Labeling index at different hours (% basal cells labeled) Tritiated thymidine injected intradermally at the times stated. Biopsies for autoradiographic proces-.
sing taken 30 minutes after each injection (see text). The labeling index at different times of day is shown. No consistent pattern of diurnal variation in labeling indices is apparent. Note: The data as presented are not corrected for the thickness of the histologic sections used for autoradiography. Multiplying all the labeling indices by 1.4, the correction factor under these conditions, will give the absolute values for the number of cells labeled (21, 22). 0600
(Midnight) 2400
Patient
S of labeled cells counted per specimen
2 3
4 5 6 7 8 9
% cells labeled
S of labeled cells counted
(Noon) 1200
% of cells labeled
126 123 129 121 136 88 274
3.8 2.7 3.8 2.8 3.6
62 185 170 110
1.8 3.1
3.5
100 182
144
3.6 5.8
2.3 4.0 2.3
4.8
230
97
% of cells labeled
5' of labeled cells counted
5.1 2.2 3.2 2.7 3.5 2.3 5.4 2.7 3.9
243 104 156 169 129 64 209 162 188
3.0
3.8
Average
3.6 3.8
S of labeled cells counted
1800
% of cells labeled
3.4 2.8 2.4 2.4 3.4 2.4 3.6 3.8 6.4
144 123 93 120 97 41 184 194 256
3.5
3.4
Std. Dev.
TABLE III
aa;
I
+50 0 +40 +30 E +20 0 IS Li a
'C
a; C
a; C a; .0 0 -J
+ 10
0 —
0
I S
-I-
I
I
I
S
•
—20
0 —30 C 0 —40 a
The labeling index and number of labeled cells
counted per section in duplicate and triplicate
$
.
Labeling index at 1800 hours (% basal cells labeled)
I
•
-I•
specimens at the same time of day. Biopsy Si Patient
per
S
I• B C
I I
2400 (MIDNIGHT)
I
0600
t
(200
I
800
cells labeled
D E
56 55 149 119 89
1.9 1.4 5.3 4.7 2.4
Biposy S3
Sof
Sot
% of
section
A
a -50
Sot
labeled cells counted
Biopsy 52
labeled labeled % of cells % of cells cc counted labeled counted labeled per per section section
76 71 223 108 66
2.3 1.6 5.3 3.5 2.6
86 76 86
— —
2.5 1.6 4.1 — —
TIME of BIOPSY
FIG. 1. Each point represents the variation at that time from the mean of an individual's labeling indices. The bar is the average of the values at each time. This average is slightly greater at midnight than at other times.
Autoradiographic methods with tritiated thymidine have been utilized in animals to investigate cell proliferation kinetics. In one study of mouse esophagus, stomach, tongue, and abdom-
inal skin, a maximum number of cells in-
mitotic count at night (Table I). This increase corporated thymidine-'H at about 1730 hours. can be due to a greater rate of cell proliferation However, kidney tubule and jejunum showed no diurnal variation of labeling indices (12). A. or to a longer duration of the mitotic event.
462
THE JOURNAL OF INVESTIGATIVE DERMATOLOGY
recent study on rat corneol epithelium indi-
H. J. M., F. A. Davis Company, Philadelphia,
cated that diurnal variation of labeling indices
2. Weinstein, C. D. and Van Scott, E. J.: Turnover time of human normal and psoriatic epidermis by autoradiographic analysis. J. Invest. Derm., 45: 257, 1965. 3. Fortuyn von Leyden, C. E. D.: Observations on periodic nuclear division in the cat. Proc.
is present (13) ; in another study on rat lens cpithclium, no variation was found (14).
The number of cells synthesizing DNA can be considered a measure of cell proliferation assuming the duraton of the DNA synthesis period remains constant throughout a 24 hour period. If the DNA synthesis period itself has diurnal variations, it would affect the rate of cell proliferation as measured by a labeling index. Indeed, in recent reports of studies performed on mouse and salamander epidermis it is suggested that the length of the DNA syn-
thesis period may vary over a 24 hour period (19, 20). However, no information is available yet on such a variation of DNA synthesis in human tissues. A similar situation also obtains in studies utilizing mitotic counts without information concerning mitotic duration. Even-
sen has, in fact, presented evidence that diurnal variations of mitotic counts arc mainly due to variation of mitotic duration and not mitotic rate (5).
This is the first reported study of diurnal
1963.
Akad. Wet. Amsterdam, 19:
38, 1917.
4. Fortuyn von Leyden,C. F. D.: Day and night period in nuclear division. Proc. Akad. Wet. Amsterdam, 29: 979, 1926.
5. Evensen, A.: Epidermal kinetics. Bull. Wld. Hlth. Org., 28: 513, 1963.
6. Bullough, W. S.: Mitotic activity in the adult
male mouse. Proc. of Roy. Soc. London, Bi35: 212, 1948.
7. Bullough, W. S.: The energy relations of mi-
totic activity. Biol. Rev., 27: 133, 1952. 8. Holberg, F.: Temporal coordination of physiological function. Cold Spring Harbor Symp. Quant. Biol., 25: 289, 1960.
9. Cooper, Z. K. and Schiff, A.: Mitotic rhythm in human epidermis. Proc. Soc. Exp. Biol. and Med., 39: 323, 1938.
10. Cooper, Z. K.: Mitotic rhythm in human epidermis. J. Invest. Derm., 2: 289, 1939. 11. Broclers, A. C.: Rhythmicity of mitosis in the epidermis of human beings. Proc. Staff. Meet. Mayo Clinic, 14: 423, 1939.
12. Pilgrim, C., Erb, W. and Maurer, W.: Diurnal
fluctuations in the numbers of DNA synthesizing nuclei in various mouse tissues. Nature, 199: 863, 1963.
13. Scheving, L. E. and Pauly, J. E.: Circadian variation of epidermal cell proliferative activphase relationships of thymidine-'H uptake, labeled nuclei, grain counts, and cell division ity in humans in which labeling indices arc emrate in rat corneal epithelium. J. Cell. Biol., ployed as an indicator of cell proliferation. The 32: 677, 1967. results indicate that there is only a slight in- 14. von Sallman, L. and Crimes, P.: Effect of age on cell division, 3H-thymidine incorporation, crease in the number of cells proliferating at and diurnal rhythm in the lens epithelium night. This increase is substantially less than of rats. Invest. Ophth., 5: 560, 1966. that found in studies in which at least two fold 15. Ortiz Picon, J. M.: TJber zellteilungsfrequenz und zellteilungsrhythms in der epidermis der differences were found when mitotic counts mnus. Zeit. f. Zellforsch. u. mikr. Anat., 19:
were used as a measure of proliferative ac-
488, 1934.
tivity (5). Further information about the dura- 16. Carleton, A.: A rhythmical periodicity in the mitotic division of animal cells. J. Anat., 68: tion of DNA synthesis is still required to com251, 1934. pletely evaluate these results. SUMMARY
Human cpidermal cell proliferation was stud-
ied for the presence of diurnal variations by
17. Blumenfeld, C. M.: Periodic mitotic activity in the epidermis of the albino rat. Science, 90: 446, 1939.
18. Sche'ing, L. E.: Mitotic activity in the human epidermis. Anat. Rec., 135: 7, 1959.
19. Scheving, L. E. and Chiakulas, J. J.: Twentyf our-hour periodicity in the uptake of tntiated thymidine and its relation to mitotic rate in urodele larval epidermis. Exp. Cell
thymidinc labeling indices. The technic utilized tritiated thymidine injected intradermally and Res., 39: 161, 1965. autoradiographic analysis of sequential biopsy 20. Pilgrim, C. H. and W. Maurcr: Autoradingraphischc untersuchung uber die konstanz specimens. Only a slight increase in the averder DNS-verdopplungs-dauer bei zellarten age labeling index was noted at midnight as von maus und ratte durch doppelmarkierung compared to previously reported several fold mit 8H-und 14C-thymidin. Exp. Cell Res., 37: 183, 1965. differences in mitotic counts. 21. Weinstein, C. and Frost, P.: Abnormal cell proliferation in psoriasis. J. Invest. Dcrm., REFERENCES 1. Wimber, D. E.: Methods for studying cell proliferation with emphasis on DIN A labels. Cell
Proliferation. Eds., Lamerton, L. F. and Fry,
50: 254, 1968.
22. Iversen, 0. II. and Evensen, A.: Experimental
skin carcinngenesis in mice. Acta Path. Micro. Scand. Suppl., 156: 97, 1962.
THE JOURNAL OF INVESTIGATIVE DERMATOLOGY
94
linolenic acid extract. Arch. This pdf is a scanned copy UV of irradiated a printed document.
24. Wynn, C. H. and Iqbal, M.: Isolation of rat
skin lysosomes and a comparison with liver Path., 80: 91, 1965. and spleen lysosomes. Biochem. J., 98: lOP, 37. Nicolaides, N.: Lipids, membranes, and the 1966.
human epidermis, p. 511, The Epidermis
Eds., Montagna, W. and Lobitz, W. C. Acascopic localization of acid phosphatase in demic Press, New York. human epidermis. J. Invest. Derm., 46: 431, 38. Wills, E. D. and Wilkinson, A. E.: Release of 1966. enzymes from lysosomes by irradiation and 26. Rowden, C.: Ultrastructural studies of kerathe relation of lipid peroxide formation to tinized epithelia of the mouse. I. Combined enzyme release. Biochem. J., 99: 657, 1966. electron microscope and cytochemical study 39. Lane, N. I. and Novikoff, A. B.: Effects of of lysosomes in mouse epidermis and esoarginine deprivation, ultraviolet radiation and X-radiation on cultured KB cells. J. phageal epithelium. J. Invest. Derm., 49: 181, 25. Olson, R. L. and Nordquist, R. E.: Ultramicro-
No warranty is given about the accuracy of the copy.
Users should refer to the original published dermal cells. Nature, 216: 1031, 1967. version of1965. the material. vest. Derm., 45: 448, 28. Hall, J. H., Smith, J. G., Jr. and Burnett, S. 41. Daniels, F., Jr. and Johnson, B. E.: In prepa1967.
Cell Biol., 27: 603, 1965.
27. Prose, P. H., Sedlis, E. and Bigelow, M.: The 40. Fukuyama, K., Epstein, W. L. and Epstein, demonstration of lysosomes in the diseased J. H.: Effect of ultraviolet light on RNA skin of infants with infantile eczema. J. Inand protein synthesis in differentiated epi-
C.: The lysosome in contact dermatitis: A ration. histochemical study. J. Invest. Derm., 49: 42. Ito, M.: Histochemical investigations of Unna's oxygen and reduction areas by means of 590, 1967. 29. Pearse, A. C. E.: p. 882, Histochemistry Theoultraviolet irradiation, Studies on Melanin, retical and Applied, 2nd ed., Churchill, London, 1960.
30. Pearse, A. C. E.: p. 910, Histacheini.stry Thearetscal and Applied, 2nd ed., Churchill, London, 1960.
31. Daniels, F., Jr., Brophy, D. and Lobitz, W. C.: Histochemical responses of human skin fol-
lowing ultraviolet irradiation. J. Invest. Derm.,37: 351, 1961.
32. Bitensky, L.: The demonstration of lysosomes by the controlled temperature freezing section method. Quart. J. Micr. Sci., 103: 205, 1952.
33. Diengdoh, J. V.: The demonstration of lysosomes in mouse skin. Quart. J. Micr. Sci., 105: 73, 1964.
34. Jarret, A., Spearman, R. I. C. and Hardy, J. A.:
Tohoku, J. Exp. Med., 65: Supplement V, 10, 1957.
43. Bitcnsky, L.: Lysosomes in normal and pathological cells, pp. 362—375, Lysasames Eds., de Reuck, A. V. S. and Cameron, M. Churchill, London, 1953.
44. Janoff, A. and Zweifach, B. W.: Production of inflammatory changes in the microcirculation by cationic proteins extracted from lysosomes. J. Exp. Med., 120: 747, 1964.
45. Herion, J. C., Spitznagel, J. K., Walker, R. I. and Zeya, H. I.: Pyrogenicity of granulocyte lysosomes. Amer. J. Physiol., 211: 693, 1966.
46. Baden, H. P. and Pearlman, C.: The effect of ultraviolet light on protein and nucleic acid synthesis in the epidermis. J. Invest. Derm.,
Histochemistry of keratinization. Brit. J. 43: 71, 1964. Derm., 71: 277, 1959. 35. De Duve, C. and Wattiaux, R.: Functions of 47. Bullough, W. S. and Laurence, E. B.: Mitotic control by internal secretion: the role of lysosomes. Ann. Rev. Physiol., 28: 435, 1966. the chalone-adrenalin complex. Exp. Cell. 36. Waravdekar, V. S., Saclaw, L. D., Jones, W. A. and Kuhns, J. C.: Skin changes induced by
Res., 33: 176, 1964.
THE JOURNAL 05' INVESTIGATIVE DERMATOLOGY
Copyright
Printed in U.S.A.
1968 by The Williams & Wilkins Co.
KINETICS OF HUMAN EPIDERMAL CELL PROLIFERATION: DIURNAL VARIATION* GUINTER KAHN, M.D.,t GERALD D. WEINSTEIN, M.D. AND PHILLIP FROST, M.D.
being over 50 years old. The patients had been hospitalized for physical rehabilitation because
In studies of animal epithelial tissues in Which mitoses Were counted at different times of day, the time of maximal and minimal activity has varied greatly depending upon the species and
of orthopedic problems. Only one patient (JF) had a systemic illness, mild diabetes, under eoatrol. The biopsy specimens were processed for autoradiog-
experimental conditions. Most investigators raphy with 6 micron histologic sections and ex-
have concluded that mitotie activity is greatest posed to photographic emulsion for 3—4 weeks. When an animal is at relative rest. These stud- Autoradiographs were analyzed by projecting their images magnified 175 times onto paper and ies are summarized in Table I.
tracing the perimeter of the epidermis. The length of the basal cell layer was measured and from this the number of basal cells in a section was deter-
In previous studies of diurnal variation of proliferative activity in human tissues, mitoses were counted. Autoradiographie methods,
mined as follows:
Which utilize tritiated thymidine as a marker for cells synthesizing DNA in preparation for mitosis, may also be employed to measure the proliferative activity of a cell population (1, 2). With this technic cellular proliferation can be analyzed more easily and with greater accuracy since there are more cells in DNA synthesis than in mitosis at a given moment and since labeled cells are easier to identify than mitoses. The present study was performed to determine whether diurnal variation of epidermal cell proliferation is present in human epidermis by tritiated thymidine labeling experiments. It would be important to be aware of such diurnal variations in view of the many
number of basal cells in a section
studies on cellular kinetics now being performed using tritiated thymidine teehnies.
= basal cell layer length width of average basal cell Areas of epidermal thickening associated with hair follicles and sweat gland ducts were not included in the measurements. Using smaller areas of epidermis under higher
magnification the width of an average basal cell was calculated as follows:
average basal cell width
=
One-tenth ml (5 microcuries) of thymidine-1H 1.9 C/mM) was injected intradermally into each of 4 areas of normal lumbar skin. The thymidioe-1H was injected at 0600, 1200, 1800, and 2400 hours into 7 men and 2 women. Injection sites
cell layer length number of basal cells
The labeling index, i.e. the percentage of basal cells labeled by thymidine-5H thirty minutes after injection, was thea determined: labeling index number of labeled cells X 100% total number of cells in the basal layer
MATERIAL5 AND METHODS
(sp act =
basal
The variability and reproducibility of the experimental technic were tested by performing duplicate or triplicate injections and biopsies at
were marked and 30 minutes later 4 mm punch the same time in five patients. biopsy specimens were taken. The average age of RE 5TJLTS the patients was 61, seven of the nine subjects
This work was supported by research grants
from the National Institutes of Health (CA10292) and the Hartford Foundation. Accepted for publication December 23, 1967.
The labeling index for each patient at different hours is presented in Table II. An average of 146 labeled cells were counted at each time in each patient. When the data from each
* From the Department of Dermatology, University of Miami School of Medicine, Miami, patient were plotted on a graph, no pattern of diurnal variation among the different subFlorida, 33136. t Present address: Division of Dermatology, jects was apparent. However, there was eviUniv. of Colorado Medical Center, Denver, dence for a slight increase in the rate of cell Colorado. 459
460
THE JOURNAL OF INVESTIGATIVE DERMATOLOGY
TABLE I Diurnal variation of mitotic activity System
Tissue
Age
Kittens (6)
Newborn
Mice
Not stated Lymphatic
White mice (6)
28 Days
Lymphatic
Rat)o9f Ref
Time oi1maximum
Time oçminimum
2230—0230
1030
2.1:1
3
1100
0300
2.5:1
4
1200
2000—2400
3.0:1
15
2.0:1
16
Epidermis, lumbar area
White mice (48)
1—7 Days
Abdomen
2000
1200
Human (males) (13)
8 Days
Epidermis, prepuce
2100
1000
Human (males) (57)
6—11 Days
Epidermis, prepuce
2200
0500—1000
3.6:1
10
Human (males) (14)
Infant
Epidermis, prepuce
2100
1000
2.0:1
11
Epidermis, abdomen
0800
2000
3.5:1
17
3.2:1
6
Albino rats (males) 28 Days
9
(98)
Male mice
2—4 mo.
Epidermis, ear, back; 0600 epithelia of esoph- and 1400 agus, duodenum, epididymis
Epidermis, shoulder
Human (males) (12)
20 years
Hairless mice (48)
Not stated Epidermis, back
1000
and (two max- 2000 ima)
(two mmima)
3.2:1
2400—0300
1000—1300
6.0:1
18
2400
1400
4.7:1
5
Numbers in parentheses indicate number of subjects in each study.
proliferation at midnight when the data were
(3, 4) and has since been observed in many
analyzed in the following manner: The mean of the four labeling indices for each subject was
other animals. As seen in Table I there has been no consistency in the time when maximum and
calculated and the percent variation at each minimum mitotic activity occurs. Important different hour from the individual's mean was determinants of proliferative activity to be determined (Fig. 1). These data were examined statistically by Wilcoxon's Signed-Ranks Test, which revealed that at 2400 hours (midnight) there was a small but significant increase in la-
considered include age, sex, physical condition, environment, metabolic rate, intracellular car-
bohydrate levels, and the proximity of other animals (5—8). Physical activity of the animal
beling indices above the individual's means is reported to result in lower mitotic counts (p < 0.05). No significant differences were (6). The diurnal variation of physical activity found at the other hours. in most species must, therefore, also be conIn the experiments designed to test the re- sidered. Cooper and Broders et al. have shown liability of each value, it was found that the that newborn infants (whose activity and enaverage variance in each patient was less than vironment are presumably uniform over 24 hours) have a definite cireadian rhythm of epi15% (Tab. III). dermal cell mitoses (9—11). Scheving conDISCUsSION
firmed this finding in the shoulder skin of adult
Diurnal variation of epidermal mitotic ac- males (18). These studies therefore indicate tivity was originally noted in kittens and mice that there is at least a two fold increase in the
461
DIURNAL VARIATIONS
TABLE II Labeling index at different hours (% basal cells labeled) Tritiated thymidine injected intradermally at the times stated. Biopsies for autoradiographic proces-.
sing taken 30 minutes after each injection (see text). The labeling index at different times of day is shown. No consistent pattern of diurnal variation in labeling indices is apparent. Note: The data as presented are not corrected for the thickness of the histologic sections used for autoradiography. Multiplying all the labeling indices by 1.4, the correction factor under these conditions, will give the absolute values for the number of cells labeled (21, 22). 0600
(Midnight) 2400
Patient
S of labeled cells counted per specimen
2 3
4 5 6 7 8 9
% cells labeled
S of labeled cells counted
(Noon) 1200
% of cells labeled
126 123 129 121 136 88 274
3.8 2.7 3.8 2.8 3.6
62 185 170 110
1.8 3.1
3.5
100 182
144
3.6 5.8
2.3 4.0 2.3
4.8
230
97
% of cells labeled
5' of labeled cells counted
5.1 2.2 3.2 2.7 3.5 2.3 5.4 2.7 3.9
243 104 156 169 129 64 209 162 188
3.0
3.8
Average
3.6 3.8
S of labeled cells counted
1800
% of cells labeled
3.4 2.8 2.4 2.4 3.4 2.4 3.6 3.8 6.4
144 123 93 120 97 41 184 194 256
3.5
3.4
Std. Dev.
TABLE III
aa;
I
+50 0 +40 +30 E +20 0 IS Li a
'C
a; C
a; C a; .0 0 -J
+ 10
0 —
0
I S
-I-
I
I
I
S
•
—20
0 —30 C 0 —40 a
The labeling index and number of labeled cells
counted per section in duplicate and triplicate
$
.
Labeling index at 1800 hours (% basal cells labeled)
I
•
-I•
specimens at the same time of day. Biopsy Si Patient
per
S
I• B C
I I
2400 (MIDNIGHT)
I
0600
t
(200
I
800
cells labeled
D E
56 55 149 119 89
1.9 1.4 5.3 4.7 2.4
Biposy S3
Sof
Sot
% of
section
A
a -50
Sot
labeled cells counted
Biopsy 52
labeled labeled % of cells % of cells cc counted labeled counted labeled per per section section
76 71 223 108 66
2.3 1.6 5.3 3.5 2.6
86 76 86
— —
2.5 1.6 4.1 — —
TIME of BIOPSY
FIG. 1. Each point represents the variation at that time from the mean of an individual's labeling indices. The bar is the average of the values at each time. This average is slightly greater at midnight than at other times.
Autoradiographic methods with tritiated thymidine have been utilized in animals to investigate cell proliferation kinetics. In one study of mouse esophagus, stomach, tongue, and abdom-
inal skin, a maximum number of cells in-
mitotic count at night (Table I). This increase corporated thymidine-'H at about 1730 hours. can be due to a greater rate of cell proliferation However, kidney tubule and jejunum showed no diurnal variation of labeling indices (12). A. or to a longer duration of the mitotic event.
462
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recent study on rat corneol epithelium indi-
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cated that diurnal variation of labeling indices
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is present (13) ; in another study on rat lens cpithclium, no variation was found (14).
The number of cells synthesizing DNA can be considered a measure of cell proliferation assuming the duraton of the DNA synthesis period remains constant throughout a 24 hour period. If the DNA synthesis period itself has diurnal variations, it would affect the rate of cell proliferation as measured by a labeling index. Indeed, in recent reports of studies performed on mouse and salamander epidermis it is suggested that the length of the DNA syn-
thesis period may vary over a 24 hour period (19, 20). However, no information is available yet on such a variation of DNA synthesis in human tissues. A similar situation also obtains in studies utilizing mitotic counts without information concerning mitotic duration. Even-
sen has, in fact, presented evidence that diurnal variations of mitotic counts arc mainly due to variation of mitotic duration and not mitotic rate (5).
This is the first reported study of diurnal
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