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A Polarographic Study on the Effects of Ultraviolet Light on Scales, Epidermis, Dermis and Serum*
A POLAROGRAPHIC STUDY ON THE EFFECTS OF ULTRAVIOLET LIGHT ON SCALES, EPIDERMIS, DERMIS AND SERUM* RYOHEI OGURA, M.D., PH.D., JOHN M. KNOX, M.D. AND MASAKAZLT KUSTJHARA, M.D.
When the skin is irradiated by ultraviolet nic. Scale, separated epidermis, dermis and light a number of different effects are known to serum were examined before and after irradiaoccur; however, the mechanism of action of tion to look for possible changes in the protein ultraviolet on the skin is not adequately under- wave pattern on the polarogram. stood. Several hypotheses have been advanced, MATERIALS AND METHODS yet very little is actually known. When a moleNormal skin specimens were obtained from the cule absorbs a photon of ultraviolet light it is either raised to a higher energy level or is dis- abdomen of autopsy material. Subcutaneous fat was trimmed from the dermis immediately upon associated. Molecules may dissipate this energy removal. Later the epidermis was separated from by fluorescence, collision with another molecule, the dermis by Baumberger's ammonium method or a reaction with other molecules at collision (4). After washing with cold ether three times at (1). Possibly other as yet unrecognized pathways room temperature, the defatted epidermis was are equally important. Proteins are known to allowed to stand for several minutes in a small
beaker immersed in dry ice and acetone. Following
absorb ultraviolet in the erythema producing
this procedure the material was lyophilized by
spectra and changes in proteins may be directly or indirectly responsible for one or more of the
the usual technic. The lyophilized epidermis was
refrigerated in a tightly sealed container under one atmosphere of nitrogen. The separated dermis was also lyophilized but instead of being pulverized it was scraped with a sharp scalpel. Psoriatic scales were collected from hospitalized patients.
harmful effects of ultraviolet irradiation. Included among the adverse effects of ultraviolet are sunburn, degeneration of connective tissue, carcinogenesis, and photosensitivity phenomena. Since ultraviolet wavelengths are absorbed by thin layers of material such as a sheet of paper it has long been thought that all or almost all
These scales were prepared and preserved as
described in a previous publication (5). The serum
used in these studies was obtained from horse blood. Samples of the above described solid materials
of the erythema producing wavelengths are were spread over the surface of a Petri dish and absorbed by superficial layers of the epidermis
irradiated at room temperature with a hot quartz
diffusible substance which produces vaso dila-
irradiated material was polarographed immedi-
(stratum corneum primarily) and that ultra- mercury vapor ultraviolet light source* at a disof 25 cm. The serum formed a layer about 1 violet erythema is caused by the release of a tance cm. thick in a Petri dish (diameter 2.8 cm.). The
tation and inflammation (2). The pathway ately after irradiation. Nonirradiated control whereby this substance is released and the samples were similarly studied. chemical nature of this agent have not been identified. Kirby-Smith, et al (3), have shown that only a small percentage of ultraviolet light in the erythema producing range (up to 10% with untanned skin) passes through the epidermis and penetrates into the dermis. However, a small percentage of a large amount can be significant.
Polarographic Procedure (6)
Following irradiation study samples were
immediately homogenized in a cold saline solution (immersed in ice water to prevent degeneration by the heat of grinding). Thirty mg. of epidermis were homogenized in 2 ml. of saline, 50 mg. of dermis in 3 ml., and 15 mg. of scale in 2 ml. The homogenate
was kept in the ice bath until it was pipetted
vessel. In this presentation the effects of ultraviolet into a polarographic 1. Brdicka's Total Protein Reaction irradiation on epidermal and dermal protein A sample of 0.1 g. of pepsin was dissolved in
100 ml. of 0.05 N HC1, and 5 ml. of the resulting
were studied by employing a polarographic tech-
solution was heated on a water bath to 40° C.
* From the Department of Medical Chemistry, Kurume University School of Medicine, Kurume, Japan, and the Departments of Dermatology and
The 0.2 ml. of serum or 0.5 ml. of skin homogenate being analyzed, was added and heated at the same
temperature for 30 minutes. The heated solution
Biochemistry, Baylor University College of Medicine, Houston, Texas. Received for publication March 14, 1962.
* Acme 37
Mercury Lamp, Japan 200 watts
38
THE JOURNAL OF INVESTIGATIVE DERMATOLOGY
TABLE 1 Water evaporation by irradiation
5.0 ml. (Petri dish)
Serum
25.0 cm.
Distance Room Temperature
23.8°C. Weight of Serum
Time of Irradiation
Temperature
Loss of Weight
of Serum
After Irrad.
Before Irrad.
0
15 minutes 30 minutes
45 minutes 60 minutes
24.2 27.0
28.0
28.2
28.8
—
—
5.097 g 5.102
5.052 g
—0.045 g
5.052
—0.050
5.068
5.024
5.055 5.062
4.992 4.999
5.063
4.995
5.062
4.988
5.067
4.994
5.061
4.987
5.064
5.002
5.059
4.990
—0.044 —0.063 —0.063 —0.068 —0.074 —0.073 —0.074 —0.062 —0.069
5.063
5.007
—0.056
(0.2 ml.) was diluted with 10 ml. of cobaltous solution (0.001 M CoC12, 0.1 N NH4CI, 0.1 N NH3) and
polarographed* from —1.0 volt against the saturated calomel electrode. 2. Brdicka's Filtrate Reaction To the serum or skin homogenate 0.1 N KOH
was added (in the amount specified below) at room temperature. After allowing the solution to stand for 45 minutes 20% sulfosalicylic acid was added and the solution was shaken vigorously in order to obtain a homogenous mixture. After 10 minutes, the precipitated proteins were separated
— —0.88% —0.98% —0.87% —1.25% —1.24% —1.34% —1.46% —1.44% —1.46% —1.22% —1.36% —1.11%
irradiation was 24° C. and following irradiation was 28° C. On solid skin samples it is not necessary to consider water evaporation; however, on serum
it is necessary to determine whether water evapo-
ration has taken place. Table 1 illustrates that
the loss of water from serum was approximately 0.9 to 1.5% and not great enough to significantly alter results. RESULTS
The catalytic protein wave of irradiated serum was increased when compared to the The filtrate (0.5 ml.—1.0 ml.) was added to 5 ml. protein wave of control serum. This was true of cobaltic solution (0.001 M Co(NH3)eCls, 0.1 N NH4C1, 1 N NH3), and after mixing, polaro- when serum was irradiated directly and also graphed from —0.8 volt against the saturated after precipitation with sulfosalicylic acid (see calomel electrode. Table 2). Sixty minutes of irradiation gave a from solution by filtering through filter paper.
lower value than 15 minutes in the total protein KOH
20%
2
0.1 N
Serum Epidermis 30 mg/2m1
Dermis
IN
Filtrate
for o Sulfosali- Polarcylic Acid ography
0.5 ml 1.0 — — 1.0 ml — 0.1 0.4
1.0 0.5 ml 1.0 0.5 ml
1.0 ml — 0.1 0.4 1.0
0.7 ml
reaction, but the highest value in the filtrate reaction.
For scale, the catalytic wave in both reactions was decreased by ultraviolet irradiation and it appears that the height is lowered gradually with increasing amounts of ultraviolet irradiation. However, with statistical calculation
(a = 5%), there is no significant difference between the three irradiation times in the total protein reaction, but 30 minutes gave a significantly lower value than 15 minutes in the filSamples were irradiated in open air at room trate reaction. The results are given in Table 3. temperature. The temperature of serum before Table 4 shows the height of the protein wave * for epidermis before and after irradiation. There Yanagimoto Polarograph, Japan, PA 102 50 mg/3m! Scale 0.5 ml — 0.1 — l5mg/2m1
2.0
1.0 ml
39
ULTRAVIOLET EFFECT ON SCALES, EPIDERMIS, DERMIS AND SERUM
TABLE 2 Height
of the protein wave following ultraviolet irradiation of serum Total Protein Reaction
Specimen No.
Filtrate Reaction Irradiation Time
Irradiation Time(Min.)
Control
Control
mm
15
30
45
60
mm
15
30
45
60
1
74
78
75
75
75
39
46
50
47
52
2
74
77
81
81
77
70
74
70
76
79
3 4
59
63
66
59
63
68
61
61 54
61
63
63
64
61
66
56
70
71
54
59
63 55
66 58
70
71
73 71
63 54
68
6 7
62 62 65 72
59
5
67 66 66
55
57
59
60
62
Mean
57
66.4
63
67 72 72
70.9
(Average Deviation from Control)
73
70.4
70.0
1.06
1.07
68.9
55.6
60.1
1.04
1.05
61.0
61.1
1.09
1.11
1.11
—
64.1
1.16
0.2 eA:0.06 ,A
Sensitivity:
Parallel capacitance: 600 MF:400 eF
TABLE 3 Height of the protein wave following ultraviolet irradiation of scale Total Protein Reaction Specimen No.
Filtrate Reaction
Irradiation Time (Mm)
Irradiation Time
Control
1
60 mm
2
48 42 55 52 55
3 4
5 6
Mean
52.0
Deviation (Average from Control)
Control 15
30
60
90
98 90 89
89 86 87
108
102
90
88 88 83 93 87
98
91
15
30
60
54 44
55 41
100
38 52
39 51 44
51 40 41
42 43 50
105 107
48 51
51
47.8
46.8
0.92
44.5
0.90
Sensitivity:
mm
91
100.2
94.5
0.86
0.95
88.3
0.89
100 84 99 90.8
0.91
0.04 pA:0.06 MA
Parallel capacitance: 200 pF:200 MF
was no significant change in either the total Analysis of the data revealed that there were no protein reaction or the filtrate reaction.
significant differences between the control and 15 minutes, or between the 30 and 60 minute dermis are presented in Table 5. With the total value. The filtrate reaction was not appreciably protein reaction, the height of the protein wave altered by ultraviolet irradiation. The above data was studied by an analysis of at 30 and 60 minutes was lowered by irradiation.
Results obtained following irradiation of
40
THE JOURNAL OF INVESTIGATIVE DERMATOLOGY
TABLE 4 Height of the protein wave following ultraviolet irradiation of epidermis Filtrate Reaction
Total Protein Reaction
Irradiation Time
Irradiation Time (Mm)
Specimen No.
Control
Control 15
30
60
31
35
38 44 53 53
38 41
54 54
1
34mm
2
35
3
41
34 37 45
4 5
55
56
52
55
Mean
45.4
43.4
Derivation (Average from Control)
44.4
43.8
1.05
15
30
60
86mm
87
88
84
75
65
90
68
66 70
73
72
81
88
88
84
83
98
93
85
78.6
1.04
1.02
1.01
83.0
81.4
81.8
1.06
1.03
0.04 MA:0.06 MF Sensitivity: Parallel Capacitance: 200 rF:200 viF
TABLE 5 Height of the protein wave following ultraviolet irradiation of dermis Filtrate Reaction
Total Protein Reaction
Irradiation Time
Irradiation Time (Mm)
Specimen No.
Control
1
2
3
4 5 Mean
30 31 35 34 36
Control
mm
33.2
Deviation from Control)
15
30
60
40 30 29 36 41
20 26 23 33 35
22 26
27.4
35.2
(Average
1.07
30
60
100 110 114 110
107
110 123 108
114 102
105 120 113 105
98
95
90
99
104 mm
21
29 35
26.6
0.82
-
15
108.6
1.058
0.82
117
106.0
0.98
0.98
108.4
1.00
0.04 ,A:0.06 rA Sensitivity: Parallel Capacitance: 200 MF:200 ,F
variants technic to determine its statistical
DISCUSSION
significance (a = 5%). Figures 1 and 2 graphically illustrate this data with deviations from the control for the total protein reaction being plotted on Figure 1 and deviations for the filtrate reaction being shown in Figure 2.
typical double wave on the polarograph. Brdicka, who has extensively studied normal and patho-
Complex compounds such as proteins give a
logic sara with the polarograph, concludes that in the total protein reaction alterations may be
ULTRAVIOLET EFFECT ON SCALES, EPIDERMIS, DERMIS AND SERUM
41
Deviation
1.10
07
1 •
Serum
1 •
00
Time of Irradiation 45
30
60
0.90
Scale
0.
111/ No Statistically
significant Difference from Control
FIG. 1
present in constituents containing the cystine
Both Stricks (7) and Wenig and Jirovec (8)
group. With the filtrate reaction, important found that the catalytic double wave height for changes have been found to occur in mucoproteins containing hexosamine and polysaccharide. Brdicka has demonstrated significant differences between serum from patients with cancer, other pathological states, and normal sera. The most specific changes were thought to occur in the filtrate reaction (6).
serum was increased following ultraviolet light
irradiation. In this study irradiated serum revealed changes similar to those reported by these authors. The height of the curve was decreased with scale in both the total protein and filtrate reaction, and decreased with dermis in only the total protein reaction. Interestingly,
42
THE JOURNAL OF INVESTIGATIVE DERMATOLOGY
1.20
Serum
1.10
Time of Irradiation
1.00 Dermis
Scale
0.90
No Statistically significant Difference from Control
FIG. 2
liberated on denaturation and the change in the epidermis even after 60 minutes of con- structure of the denatured protein molecule tinuous irradiation. However, it must be em- becomes evident from the change in shape of the phasized that this is an in vitro study and that catalytic double wave. The effect of ultraviolet radiation upon prooniy powdered samples were irradiated. Disulfide or sulfhydryl groups are liberated teins was investigated polarographically by when a protein molecule is denatured. In most Wenig and Jirovec (8) and these authors rethere were no statistically significant changes in
cases the polarographic examination of protein ported an increase in both of the double protein solutions during the denaturation process shows waves. Greater increase was found in the second an increase in the catalytic protein waves. Po- wave and the ratio of the two reached a maximum larographically active groups are apparently after a certain period of irradiation. The protein
ULTRAVIOLET EFFECT ON SCALES, EPIDERMIS, DERMIS AND SERUM
started to precipitate after this maximum had been reached and at this point both waves then
43
SUMMARY
1. The effect of ultraviolet irradiation on the
decreased although the ratio remained the same. According to Schmidt (9) the effect of ultraviolet light on protein solutions increases as the concentration of the protein is decreased. Undiluted
protein of powdered scale, epidermis, and dermis and on serum protein was studied by employing a polarographic technic.
bumins have been found to be effected more by
3. Epidermis manifested noteworthy stability;
2. Scales, serum and dermis showed striking serum did not show an irradiation effect. Al- alterations.
irradiation than globulins. The presence or no significant changes were found following absence of oxygen does not appear to alter the intensive ultraviolet irradiation. effect of ultraviolet irradiation on albumin solu4. It is possible that although only a small tions, as determined by the polarograph (10). percentage of the ultraviolet from sunlight X-rays do not produce similar polarographic reaches the dermis, it is in this area that the changes for Heeren and Seuberling (11) ir- most significant biological changes occur. radiated protein solutions with 100,000 r. and REFERENCES detected no appreciable effect on the height or 1. BLUM, H. F.: Photodynamic Action and shape of the catalytic waves. This result is Diseases Caused by Light. American Publishing Corporation, 1941. somewhat surprising since ultraviolet and x-rays 2. BLUM, H. F.: Carcinogenesis by Ultraviolet are quite similar in their biological action. Light: An Essay in Quantitative Biology,
Magnus (12) placed psoriatic scales and scales from patients with chronic dermatitis in a boiling water bath for ten minutes. The mean sulfhydryl values for psoriatic scale was reduced to half by boiling; whereas, the sulfhydryl values in chronic
dermatitis were found to be increased threefold. Ultraviolet irradiation of normal human epidermis causes an immediate increase in sulfhydryl concentration; however, this is followed by a return to normal range in 24 hours and later by a decrease in sulfhydryl. Values return to normal levels within 15 days (13).
The effect of heat on protein is generally recognized as producing two types of change; either denaturation or a recoiling of the protein molecule. The findings in this experiment indicate that ultraviolet may also be capable of producing denaturation or a recoiling of protein molecules within the skin.
pp. 156—164, Princeton, N. J., Princeton University
3.
Press, 1959.
KIRBY-SMITH, J. S., BLUM, H. F. AND GRADY,
H. G.: Penetration of Ultraviolet Radiation into Skin as a Factor in Carcinogcnesis. J.
4.
Nat. Cancer Inst., 2: 403—412, 1942. DRY, E. \T: Methods for the separation of Epidermis from Dermis and Some Physi-
BAUMBRRGRR, J. P., SUNTzRFF, V. AND Cow-
ologic and Chemical Properties of Isolated
Epidermis. J. Nat. Cancer Inst., 2: 413— 423,
1941—1942.
5. OOURA, R., Kxox, J. M. AND GRIFFIN, A. C.: An Evaluation of Methods for Determining the Sulfhydryl and Disulfidc Concentration in the Stratum Corncum. 4. Invest. Derm., 35: 125—129, 1960.
M. AND ZUMAN, P.: Polarography in Medicine, Biochemistry and Pharmacy.
6. BRRzINA,
New York, Intersciencc Publ., 1958.
7. Snucics, W., IN
LINGANE, J.
KOLTHOFF, I. M. AND
J.: Polarography. v2, p. 859,
New York, Interscience Publ., 1952.
8. WENIG, K. AND JiRovxc, 0.: fiber die polarographische Reaktion dcr mit ultraviolcttcm Licht bestrahlten Eiwesstoffe. Biochcm.
Z., 295: 405—413, 1938. It will be important to determine whether or 9. SCHMIDT, H. W.: Polarographische Untcrsuchungen uber Bezichungen der Ultranot normal kcratin manifests alterations similar violett-Strahlenwirkung zur Konzentration to those shown by psoriatic scales. Powdered von Eiweisslosungen. Biochem. Z., 306: 167—176, 1940. epidermis manifested noteworthy stability since 10. FIALA, S.: fiber die Oxydations-und Dcno significant changes were found following naturierungswirkung der UV-Strahlen auf EiweisskOrpcr. Biochem. Z., 318: 67—76, intensive ultraviolet irradiation; whereas, the 1947. dermis manifested a rather striking alteration in 11. Hzxw, J. G. AND SRUBRRLING, 0.: Beitrag zur unterschiedlichen Wirkung von Ultrathe total protein reaction after thirty minutes violett-und Rontgcnstrahlen auf Eiweissof irradiation. It is possible that although only korper. Strahlentherapie., 67: 130—135, 1940. a small percentage of the ultraviolet from sun- 12. MAGNU5, I. A.: Observations on the Thiol Content of Abnormal Stratum Corneum in light reaches the dermis, it is in this area that Psoriasis and Other Conditions. Brit. J. l)erm., 68: 243—251, 1956. most of the biological changes of significance 13. OOURA, R., KU5UHARA, M. AND KNOX, J. M.: actually occur. Data is being prepared for publication.
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.
When the skin is irradiated by ultraviolet nic. Scale, separated epidermis, dermis and light a number of different effects are known to serum were examined before and after irradiaoccur; however, the mechanism of action of tion to look for possible changes in the protein ultraviolet on the skin is not adequately under- wave pattern on the polarogram. stood. Several hypotheses have been advanced, MATERIALS AND METHODS yet very little is actually known. When a moleNormal skin specimens were obtained from the cule absorbs a photon of ultraviolet light it is either raised to a higher energy level or is dis- abdomen of autopsy material. Subcutaneous fat was trimmed from the dermis immediately upon associated. Molecules may dissipate this energy removal. Later the epidermis was separated from by fluorescence, collision with another molecule, the dermis by Baumberger's ammonium method or a reaction with other molecules at collision (4). After washing with cold ether three times at (1). Possibly other as yet unrecognized pathways room temperature, the defatted epidermis was are equally important. Proteins are known to allowed to stand for several minutes in a small
beaker immersed in dry ice and acetone. Following
absorb ultraviolet in the erythema producing
this procedure the material was lyophilized by
spectra and changes in proteins may be directly or indirectly responsible for one or more of the
the usual technic. The lyophilized epidermis was
refrigerated in a tightly sealed container under one atmosphere of nitrogen. The separated dermis was also lyophilized but instead of being pulverized it was scraped with a sharp scalpel. Psoriatic scales were collected from hospitalized patients.
harmful effects of ultraviolet irradiation. Included among the adverse effects of ultraviolet are sunburn, degeneration of connective tissue, carcinogenesis, and photosensitivity phenomena. Since ultraviolet wavelengths are absorbed by thin layers of material such as a sheet of paper it has long been thought that all or almost all
These scales were prepared and preserved as
described in a previous publication (5). The serum
used in these studies was obtained from horse blood. Samples of the above described solid materials
of the erythema producing wavelengths are were spread over the surface of a Petri dish and absorbed by superficial layers of the epidermis
irradiated at room temperature with a hot quartz
diffusible substance which produces vaso dila-
irradiated material was polarographed immedi-
(stratum corneum primarily) and that ultra- mercury vapor ultraviolet light source* at a disof 25 cm. The serum formed a layer about 1 violet erythema is caused by the release of a tance cm. thick in a Petri dish (diameter 2.8 cm.). The
tation and inflammation (2). The pathway ately after irradiation. Nonirradiated control whereby this substance is released and the samples were similarly studied. chemical nature of this agent have not been identified. Kirby-Smith, et al (3), have shown that only a small percentage of ultraviolet light in the erythema producing range (up to 10% with untanned skin) passes through the epidermis and penetrates into the dermis. However, a small percentage of a large amount can be significant.
Polarographic Procedure (6)
Following irradiation study samples were
immediately homogenized in a cold saline solution (immersed in ice water to prevent degeneration by the heat of grinding). Thirty mg. of epidermis were homogenized in 2 ml. of saline, 50 mg. of dermis in 3 ml., and 15 mg. of scale in 2 ml. The homogenate
was kept in the ice bath until it was pipetted
vessel. In this presentation the effects of ultraviolet into a polarographic 1. Brdicka's Total Protein Reaction irradiation on epidermal and dermal protein A sample of 0.1 g. of pepsin was dissolved in
100 ml. of 0.05 N HC1, and 5 ml. of the resulting
were studied by employing a polarographic tech-
solution was heated on a water bath to 40° C.
* From the Department of Medical Chemistry, Kurume University School of Medicine, Kurume, Japan, and the Departments of Dermatology and
The 0.2 ml. of serum or 0.5 ml. of skin homogenate being analyzed, was added and heated at the same
temperature for 30 minutes. The heated solution
Biochemistry, Baylor University College of Medicine, Houston, Texas. Received for publication March 14, 1962.
* Acme 37
Mercury Lamp, Japan 200 watts
38
THE JOURNAL OF INVESTIGATIVE DERMATOLOGY
TABLE 1 Water evaporation by irradiation
5.0 ml. (Petri dish)
Serum
25.0 cm.
Distance Room Temperature
23.8°C. Weight of Serum
Time of Irradiation
Temperature
Loss of Weight
of Serum
After Irrad.
Before Irrad.
0
15 minutes 30 minutes
45 minutes 60 minutes
24.2 27.0
28.0
28.2
28.8
—
—
5.097 g 5.102
5.052 g
—0.045 g
5.052
—0.050
5.068
5.024
5.055 5.062
4.992 4.999
5.063
4.995
5.062
4.988
5.067
4.994
5.061
4.987
5.064
5.002
5.059
4.990
—0.044 —0.063 —0.063 —0.068 —0.074 —0.073 —0.074 —0.062 —0.069
5.063
5.007
—0.056
(0.2 ml.) was diluted with 10 ml. of cobaltous solution (0.001 M CoC12, 0.1 N NH4CI, 0.1 N NH3) and
polarographed* from —1.0 volt against the saturated calomel electrode. 2. Brdicka's Filtrate Reaction To the serum or skin homogenate 0.1 N KOH
was added (in the amount specified below) at room temperature. After allowing the solution to stand for 45 minutes 20% sulfosalicylic acid was added and the solution was shaken vigorously in order to obtain a homogenous mixture. After 10 minutes, the precipitated proteins were separated
— —0.88% —0.98% —0.87% —1.25% —1.24% —1.34% —1.46% —1.44% —1.46% —1.22% —1.36% —1.11%
irradiation was 24° C. and following irradiation was 28° C. On solid skin samples it is not necessary to consider water evaporation; however, on serum
it is necessary to determine whether water evapo-
ration has taken place. Table 1 illustrates that
the loss of water from serum was approximately 0.9 to 1.5% and not great enough to significantly alter results. RESULTS
The catalytic protein wave of irradiated serum was increased when compared to the The filtrate (0.5 ml.—1.0 ml.) was added to 5 ml. protein wave of control serum. This was true of cobaltic solution (0.001 M Co(NH3)eCls, 0.1 N NH4C1, 1 N NH3), and after mixing, polaro- when serum was irradiated directly and also graphed from —0.8 volt against the saturated after precipitation with sulfosalicylic acid (see calomel electrode. Table 2). Sixty minutes of irradiation gave a from solution by filtering through filter paper.
lower value than 15 minutes in the total protein KOH
20%
2
0.1 N
Serum Epidermis 30 mg/2m1
Dermis
IN
Filtrate
for o Sulfosali- Polarcylic Acid ography
0.5 ml 1.0 — — 1.0 ml — 0.1 0.4
1.0 0.5 ml 1.0 0.5 ml
1.0 ml — 0.1 0.4 1.0
0.7 ml
reaction, but the highest value in the filtrate reaction.
For scale, the catalytic wave in both reactions was decreased by ultraviolet irradiation and it appears that the height is lowered gradually with increasing amounts of ultraviolet irradiation. However, with statistical calculation
(a = 5%), there is no significant difference between the three irradiation times in the total protein reaction, but 30 minutes gave a significantly lower value than 15 minutes in the filSamples were irradiated in open air at room trate reaction. The results are given in Table 3. temperature. The temperature of serum before Table 4 shows the height of the protein wave * for epidermis before and after irradiation. There Yanagimoto Polarograph, Japan, PA 102 50 mg/3m! Scale 0.5 ml — 0.1 — l5mg/2m1
2.0
1.0 ml
39
ULTRAVIOLET EFFECT ON SCALES, EPIDERMIS, DERMIS AND SERUM
TABLE 2 Height
of the protein wave following ultraviolet irradiation of serum Total Protein Reaction
Specimen No.
Filtrate Reaction Irradiation Time
Irradiation Time(Min.)
Control
Control
mm
15
30
45
60
mm
15
30
45
60
1
74
78
75
75
75
39
46
50
47
52
2
74
77
81
81
77
70
74
70
76
79
3 4
59
63
66
59
63
68
61
61 54
61
63
63
64
61
66
56
70
71
54
59
63 55
66 58
70
71
73 71
63 54
68
6 7
62 62 65 72
59
5
67 66 66
55
57
59
60
62
Mean
57
66.4
63
67 72 72
70.9
(Average Deviation from Control)
73
70.4
70.0
1.06
1.07
68.9
55.6
60.1
1.04
1.05
61.0
61.1
1.09
1.11
1.11
—
64.1
1.16
0.2 eA:0.06 ,A
Sensitivity:
Parallel capacitance: 600 MF:400 eF
TABLE 3 Height of the protein wave following ultraviolet irradiation of scale Total Protein Reaction Specimen No.
Filtrate Reaction
Irradiation Time (Mm)
Irradiation Time
Control
1
60 mm
2
48 42 55 52 55
3 4
5 6
Mean
52.0
Deviation (Average from Control)
Control 15
30
60
90
98 90 89
89 86 87
108
102
90
88 88 83 93 87
98
91
15
30
60
54 44
55 41
100
38 52
39 51 44
51 40 41
42 43 50
105 107
48 51
51
47.8
46.8
0.92
44.5
0.90
Sensitivity:
mm
91
100.2
94.5
0.86
0.95
88.3
0.89
100 84 99 90.8
0.91
0.04 pA:0.06 MA
Parallel capacitance: 200 pF:200 MF
was no significant change in either the total Analysis of the data revealed that there were no protein reaction or the filtrate reaction.
significant differences between the control and 15 minutes, or between the 30 and 60 minute dermis are presented in Table 5. With the total value. The filtrate reaction was not appreciably protein reaction, the height of the protein wave altered by ultraviolet irradiation. The above data was studied by an analysis of at 30 and 60 minutes was lowered by irradiation.
Results obtained following irradiation of
40
THE JOURNAL OF INVESTIGATIVE DERMATOLOGY
TABLE 4 Height of the protein wave following ultraviolet irradiation of epidermis Filtrate Reaction
Total Protein Reaction
Irradiation Time
Irradiation Time (Mm)
Specimen No.
Control
Control 15
30
60
31
35
38 44 53 53
38 41
54 54
1
34mm
2
35
3
41
34 37 45
4 5
55
56
52
55
Mean
45.4
43.4
Derivation (Average from Control)
44.4
43.8
1.05
15
30
60
86mm
87
88
84
75
65
90
68
66 70
73
72
81
88
88
84
83
98
93
85
78.6
1.04
1.02
1.01
83.0
81.4
81.8
1.06
1.03
0.04 MA:0.06 MF Sensitivity: Parallel Capacitance: 200 rF:200 viF
TABLE 5 Height of the protein wave following ultraviolet irradiation of dermis Filtrate Reaction
Total Protein Reaction
Irradiation Time
Irradiation Time (Mm)
Specimen No.
Control
1
2
3
4 5 Mean
30 31 35 34 36
Control
mm
33.2
Deviation from Control)
15
30
60
40 30 29 36 41
20 26 23 33 35
22 26
27.4
35.2
(Average
1.07
30
60
100 110 114 110
107
110 123 108
114 102
105 120 113 105
98
95
90
99
104 mm
21
29 35
26.6
0.82
-
15
108.6
1.058
0.82
117
106.0
0.98
0.98
108.4
1.00
0.04 ,A:0.06 rA Sensitivity: Parallel Capacitance: 200 MF:200 ,F
variants technic to determine its statistical
DISCUSSION
significance (a = 5%). Figures 1 and 2 graphically illustrate this data with deviations from the control for the total protein reaction being plotted on Figure 1 and deviations for the filtrate reaction being shown in Figure 2.
typical double wave on the polarograph. Brdicka, who has extensively studied normal and patho-
Complex compounds such as proteins give a
logic sara with the polarograph, concludes that in the total protein reaction alterations may be
ULTRAVIOLET EFFECT ON SCALES, EPIDERMIS, DERMIS AND SERUM
41
Deviation
1.10
07
1 •
Serum
1 •
00
Time of Irradiation 45
30
60
0.90
Scale
0.
111/ No Statistically
significant Difference from Control
FIG. 1
present in constituents containing the cystine
Both Stricks (7) and Wenig and Jirovec (8)
group. With the filtrate reaction, important found that the catalytic double wave height for changes have been found to occur in mucoproteins containing hexosamine and polysaccharide. Brdicka has demonstrated significant differences between serum from patients with cancer, other pathological states, and normal sera. The most specific changes were thought to occur in the filtrate reaction (6).
serum was increased following ultraviolet light
irradiation. In this study irradiated serum revealed changes similar to those reported by these authors. The height of the curve was decreased with scale in both the total protein and filtrate reaction, and decreased with dermis in only the total protein reaction. Interestingly,
42
THE JOURNAL OF INVESTIGATIVE DERMATOLOGY
1.20
Serum
1.10
Time of Irradiation
1.00 Dermis
Scale
0.90
No Statistically significant Difference from Control
FIG. 2
liberated on denaturation and the change in the epidermis even after 60 minutes of con- structure of the denatured protein molecule tinuous irradiation. However, it must be em- becomes evident from the change in shape of the phasized that this is an in vitro study and that catalytic double wave. The effect of ultraviolet radiation upon prooniy powdered samples were irradiated. Disulfide or sulfhydryl groups are liberated teins was investigated polarographically by when a protein molecule is denatured. In most Wenig and Jirovec (8) and these authors rethere were no statistically significant changes in
cases the polarographic examination of protein ported an increase in both of the double protein solutions during the denaturation process shows waves. Greater increase was found in the second an increase in the catalytic protein waves. Po- wave and the ratio of the two reached a maximum larographically active groups are apparently after a certain period of irradiation. The protein
ULTRAVIOLET EFFECT ON SCALES, EPIDERMIS, DERMIS AND SERUM
started to precipitate after this maximum had been reached and at this point both waves then
43
SUMMARY
1. The effect of ultraviolet irradiation on the
decreased although the ratio remained the same. According to Schmidt (9) the effect of ultraviolet light on protein solutions increases as the concentration of the protein is decreased. Undiluted
protein of powdered scale, epidermis, and dermis and on serum protein was studied by employing a polarographic technic.
bumins have been found to be effected more by
3. Epidermis manifested noteworthy stability;
2. Scales, serum and dermis showed striking serum did not show an irradiation effect. Al- alterations.
irradiation than globulins. The presence or no significant changes were found following absence of oxygen does not appear to alter the intensive ultraviolet irradiation. effect of ultraviolet irradiation on albumin solu4. It is possible that although only a small tions, as determined by the polarograph (10). percentage of the ultraviolet from sunlight X-rays do not produce similar polarographic reaches the dermis, it is in this area that the changes for Heeren and Seuberling (11) ir- most significant biological changes occur. radiated protein solutions with 100,000 r. and REFERENCES detected no appreciable effect on the height or 1. BLUM, H. F.: Photodynamic Action and shape of the catalytic waves. This result is Diseases Caused by Light. American Publishing Corporation, 1941. somewhat surprising since ultraviolet and x-rays 2. BLUM, H. F.: Carcinogenesis by Ultraviolet are quite similar in their biological action. Light: An Essay in Quantitative Biology,
Magnus (12) placed psoriatic scales and scales from patients with chronic dermatitis in a boiling water bath for ten minutes. The mean sulfhydryl values for psoriatic scale was reduced to half by boiling; whereas, the sulfhydryl values in chronic
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The effect of heat on protein is generally recognized as producing two types of change; either denaturation or a recoiling of the protein molecule. The findings in this experiment indicate that ultraviolet may also be capable of producing denaturation or a recoiling of protein molecules within the skin.
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THE JOURNAL OF INVESTIGATIVE DERMATOLOGY
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