ABSTRACT
Determinations have been made of the desoxyribonuclease (DNase) activity of various embryonic stages and adult tissues of a sea-urchin, a frog, and the domestic fowl. Special attention has been paid to the pH optimum and the magnesium requirement of the enzymes. Of the three species investigated only the sea-urchin exhibited DNase activity during early embryonic development. This activity was essentially the same as that of crystalline bovine pancreatic DNase, although it is doubtful that the two enzymes are identical. The possible correlation of this enzyme with the amount of preformed desoxyribonucleotides in the egg is discussed.
At later stages of development, all three species contain an enzyme which is similar to DNase II of mammalian origin. The possibility that the difference in enzyme activity between embryonic and mature tissue is due to the presence of inhibitors has been ruled out. The data obtained in this study and that of other workers suggests that the adult DNase may play a role in the processes of cell destruction and cell turnover in adult metazoans.
INTRODUCTION
RECENT work has pointed to DNA as either the genetic material of the cell or one of its most essential components. As yet the biological role of the desoxyribonucleases (DNases), the only enzymes known to attack polymerized DNA, has not been established. The distribution of these enzymes throughout the animal and plant kingdoms appears to be widespread, and it is now recognized that they fall into at least two general classes (Schmidt, 1955). If these enzymes are involved in chromosome reduplication or in the genetic or developmental controls which may be attributed to nuclear DNA, it might be expected that the pattern of enzyme activity in rapidly growing, undifferentiated tissue and adult differentiated tissues would differ. For these reasons it was decided to investigate the type of DNase activity found in a developing embryonic system as compared to the activity of adult organs of the same species.
The animals studied in this manner were the west coast sea-urchin, Strongylo-centrotus purpuratus; the frog, Rana pipiens; and the domestic fowl, Gallus domesticus. These species were chosen since they represented three different types of development according to classic embryological standards. In addition these are embryonic systems where the quantitative changes in DNA and desoxyribonucleotides have been established by previous workers (Hoff-Jorgensen & Zeuthen, 1952; Hoff-Jorgensen, 1954). Any differences in either the level or type of DNase present might then be correlated with both the amount of stored desoxyribonucleotides present and the type of morphogenetic changes which are occurring. It has thus been possible to show a definite difference between adult and early embryonic tissue for all three species studied, and also a difference in the embryonic pattern of DNase which may be associated with the level of stored desoxyribonucleotides in the developing ova.
MATERIAL AND METHODS
All material to be assayed for DNase activity was homogenized immediately after collection or frozen and stored at - 15° C. Homogenization was carried out in a Potter homogenizer, with the exception of the eggs and embryos of the sea-urchin. These were homogenized in a ‘Microblender’ consisting of a 15 ml. glass vial containing a set of small brass blades which were electrically driven at about 5,000 r.p.m.
Strongylocentrotus purpuratus
The eggs and sperm of the sea-urchin were collected and fertilization carried out in the manner described by Mazia (1949). Unless the eggs showed 90-100 per cent, fertilization they were not used. This criterion was also applied when only non-fertilized eggs were collected. Mass cultures were grown in an aerated 5-1. Ehrlenmeyer flask rotated at about 20 r.p.m. in a room maintained at 14° C. Quantities of the embryo suspension containing between six and ten million eggs were transferred to 50-ml. centrifuge tubes. The eggs were concentrated by lowspeed centrifugation, and almost all the debris and micro-organisms present could be removed with the supernatant sea-water. Repeated centrifuging, utilizing only two centrifuge tubes, was employed in order to minimize any loss which might occur in transferring the packed embryos to the ‘Microblender’.
Rana pipiens
The method of Rugh (1934) was used to obtain the eggs and embryos of this species. Only those clutches which showed less than 10-15 per cent, abnormal development were utilized for DNase determinations. At the desired stage of development 100 embryos were removed from the culture dishes and frozen and stored at - 15° C. Eggs and embryos from a single clutch of eggs were used for each set of determinations. Before homogenization the embryos were only partially thawed, so that they could be transferred to the glass vessel of the homogenizer.
Gallus domesticus
Fertilized hens’ eggs were obtained from the Division of Poultry Husbandry of the University of California at Berkeley. The eggs were refrigerated after collection, and placed in a 39° C. incubator when it was desired to initiate further development. Eggs were removed at appropriate intervals, the embryos dissected out, and examined microscopically to make certain they were at the developmental stage desired. The embryos were then washed twice with 0 85 per cent, saline to remove any adhering yolk, and homogenized in the manner previously described.
DNase determinations
High polymer DNA was prepared from salmon testes by the method of Bernstein (1953). This procedure yielded a preparation which was white, fibrous, hygroscopic, and dissolved readily in water to give a clear viscous solution.
The substrate normally employed contained 0·15 per cent. DNA, and was either 0·024 molar with respect to magnesium chloride, or 0·03 molar with respect to sodium citrate. When the substrate was buffered at a pH below 6·0, a 0·1 molar acetate buffer was used. For those determinations carried out at a pH above 6·0, a 0·2 molar phosphate buffer was used.
The reaction mixture used for the determinations of DNase activity in the seaurchin eggs and embryos consisted of 10 ml. of the substrate solution and 1·0 ml. of the enzyme sample. The enzyme activity of this material was such that 1·0 ml. of homogenate containing from 300,000 to 500,000 eggs or embryos was sufficient to measure the depolymerization of 15 mg. of DNA, and the enzyme activity was proportional to the quantity of embryonic material in the homogenate. For the analysis of adult tissues of this species, 1·0 ml. of homogenate containing from 2·0 to 6·0 mg. of protein fulfilled the requirements that the DNase activity should be proportional to the amount of enzyme used.
For most of the determinations the protamine precipitation method of Barton (1948) was used. The homogenate and buffered substrate were incubated with shaking at 27° C. At zero time (i.e. upon addition of the homogenate to substrate), and at desired intervals during the course of the reaction, the amount of protamine-soluble DNA present in a 2·0-ml. sample was determined spectro-photometrically.
The amount of DNA liberated in low polymer form for any period during the course of the reaction was calculated as the difference between the zero time value and the value after the given period of incubation. For a comparison of the activity at different stages of development, the activity was expressed as milligrammes of low polymer DNA liberated per hour per embryo. When it was desired to make a comparison of the activity in embryonic and adult tissues, or between two types of adult tissues, the activity was expressed as milligrammes of low polymer DNA liberated per hour per milligramme of protein of the homogenate. The rate of depolymerization was determined for each measurement, and the calculation of activity was made from values obtained from that portion of the curve which was linear.
Viscometric determinations
Although the viscometric method of DNase assay may be subject to a number of limitations, it can be used to detect small amounts of activity which might not be revealed by the other methods in use. When the protamine precipitation method revealed no activity in the embryonic stages of the frog and chick, the viscometric method was used to verify the results.
The procedure used for the viscosity measurements was similar to that of Laskowski & Seidell (1945). Measurements were made with an Ostwald viscometer at 27° C. The substrate was a 0·11 per cent, solution of DNA which was 0·024 molar with respect to magnesium, or 0·03 molar with respect to citrate. It was buffered with 0·2 molar phosphate for determinations at pH 6·0 or above, and with 0·1 molar acetate for determinations below 6·0. Both the homogenate and substrate were allowed to attain a temperature of 27° C. before being added to the viscometer. Five millilitres of substrate and 3 ml. of homogenate containing 0·4 to 1·3 mg. of protein per millilitre were used for each determination. A measurement was made immediately after mixing the homogenate and substrate and at approximately 5-minute intervals thereafter. When the reaction had proceeded for over 30 minutes, measurements were taken at less frequent intervals until the viscosity had attained a constant value.
For certain stages of the chick embryo, where there seemed to be an increase of activity as development proceeded, reaction velocity constants were calculated. These were calculated from the formula K = 1/t log(n0/n1) in which n0 is the relative viscosity at zero time and m is the relative viscosity at time t.
Protein determination
The concentration of protein in the homogenates was determined according to the method of Lowry et al. (1951). A calibration curve for known concentrations of crystalline bovine albumin was used as the standard.
RESULTS
Embryonic tissues
Of the three species studied, only the sea-urchin exhibited any appreciable activity during the early stages of embryogenesis. Not only was the amount of DNase activity per embryo constant throughout development, but also the characteristics of the enzyme showed no changes. Those stages investigated included unfertilized eggs, fertilized eggs just prior to the first cleavage, 4- and 16-cell stages, early blastulae, free-swimming blastulae, gastrulae prisms, and plutei.
Homogenates were tested for activity in the pH range of 5-7 with reaction mixtures containing magnesium and those from which the magnesium had been removed by the addition of citrate. All stages tested showed no activity when magnesium was absent from the reaction mixture. In Text-fig. 1 it can be seen that the pH optimum for the DNase activity of unfertilized egg is between 6·6 and 6·8. The pH activity curves for the other stages are essentially the same.
The fact that this DNase activity is magnesium activated and has a pH optimum of about 6-8 places it in the DNase I category (Cunningham & Laskowski, 1953).
Table 1 shows the amount of activity of this magnesium-activated enzyme which is present in the eggs and embryos. The difference in activity of the various stages is of the same order of magnitude as the difference obtained between different determinations on the same stage of development. The values given here are the mean values for from 2 to 4 determinations on different cultures of embryos. These data are in agreement with those obtained for Arbacia (Mazia, 1949), where it was also found that the level of activity remained constant throughout development. Although no difference in developmental pattern of the enzyme was expected between such closely related species, it was felt that an analysis at more frequent intervals after fertilization might show changes in activity not indicated by the study on Arbacia. However, the results obtained from these determinations do not indicate any changes in the level of activity which might be correlated with mitotic activity or changes in DNA metabolism.
DNase activity of eggs and embryos, expressed as mg. × 10−7 of low polymer DNA liberated per hour per egg or embryo

Recent work has shown that in many forms an RNA inhibitor is present, which masks the true level of DNase activity of the organism (Roth, 1954; Kozloff, 1953 a, b). It seemed possible that such an inhibitor might regulate differences in the in vivo level of DNase activity during development and that these differences would not be detectable by the methods used. The DNase of Arbacia is in the soluble portion of the homogenate of unfertilized eggs and, as development proceeds, becomes progressively localized on the sedimentable portion. This appearance of the DNase of later stages in a sedimentable form suggested that it becomes associated with the particulate matter of the cytoplasm, which is rich in RNA. Such a close association with cytoplasmic RNA might mask a potentially higher activity at later stages of development. For these reasons it seemed worthwhile to study the effect of RNase pretreatment of the homogenates on the level of activity of the various developmental stages.
Homogenates were incubated for 30 minutes at 27° C. with a 0·2 per cent, solution of crystalline RNase (Worthington Biochemical Corporation), and buffered at pH 6·0 before they were added to the substrate. The activity of these homogenates was compared to those of untreated homogenates of equal concentration. Text-fig. 2 shows representative results of one of such a series of determinations made on the different developmental stages. It is apparent that there is no significant difference in activity between the RNase digested and the untreated homogenates. At present there is no evidence to support any contention that the constancy of DNase activity throughout the embryonic development of this species is an artifact of the method of assay.
Unlike the sea-urchin, the eggs and embryos of the frog exhibited no DNase activity. Using the protamine precipitation method, no appreciable activity of an enzyme corresponding to DNase I or II could be detected in any of the embryonic stages from unfertilized eggs to free-swimming tadpoles. With the viscometric method of DNase assay, which is more sensitive than the protamine method, no activity of either acid or neutral DNase could be detected in stages up to and including Shumway stage 25 (Shumway, 1940). Here, too, homogenates were tested for activity in the pH range of from 4 to 7, both in the presence and absence of magnesium. Although not amenable to quantitative interpretation, the viscometric method is the most sensitive method now available for detecting DNase activity. The complete absence of these enzymes cannot be proved conclusively, but it seems reasonable to assume that they are not present in any functionally significant amounts unless they can be detected by this method. Pretreatment of the homogenates by methods known to destroy the usual inhibitors of DNase did not result in any active enzyme preparations. This included digestion of the homogenate with RNase and the dilute acid treatment described by Cunningham & Laskowski (1953) for the removal of inhibitors from calfkidney preparations.
It is somewhat difficult to explain the discrepancy between these results and those obtained by Finamore (1955). He reports changes in the level of DNase activity during the early development of Rana pipiens. The increase in ultraviolet absorption which he obtained for those stages which had maximum activity was rather low, especially when compared to the values for RNase activity in the same material. Since he did not indicate if measurements had been made of the amount of ultra-violet absorbing material released by incubation of the homogenates alone, there is no way of distinguishing what proportion of the optical density was actually due to the products released by DNase action. Even if one accepts Finamore’s data as given, the difference between his results and those of this investigation becomes merely a question of whether there is no DNase activity or extremely low activity in the early developmental stages of the frog.
Allfrey & Mirsky (1952) had previously demonstrated the presence of DNase II activity in the organs of the 15-day chick embryo, the 8-day chick, and adult chickens. They did not report the presence of any DNase I in this material. Their work did not indicate whether this enzyme was present throughout development or appeared only at later stages. The determination of DNase activity in early Stages of chick embryogenesis was undertaken in order to answer this question and also to determine whether DNase I might be present in earlier stages.
When the protamine method was used, assays for DNase I and II did not show any activity in the 24-, 48-, 72-, and 96-hour chick embryo and in yolk isolated from 24-hour embryos. Viscometric assays also did not reveal any activity in stages prior to the 96-hour chick. At this stage of development a small amount of DNase II could be detected. In Text-fig. 3 it can be seen that the DNase activity at this stage is only just within the range of detectability even when viscometric methods are used.
No activity of the DNase I type could be detected at this stage of development or later when the activity of the DNase II increased.
The progressive increase of DNase II from the 4th to the 10th day of incubation is shown in Table 2. This activity is expressed as the velocity constant per amount of embryo in the added homogenate. For all of these determinations the protein concentration of the added homogenate was in the range of 1·0 to 2·0 mg. / ml. This was achieved by decreasing the number of embryos homogenized and increasing the total volume of homogenate as the age of the embryo increased. The advantage of this procedure over that of keeping the number of embryos homogenized constant for each stage tested was that it avoided the possibility of spurious differences in the rate of viscosity decrease between homogenates of different embryonic stages due to differences in total protein content.
The velocity constants were calculated from several measurements taken during the period of linear viscosity decrease. The values given in Table 2 are the mean of from 2 to 4 determinations on different homogenates. The deviation from the mean for the activity values calculated in this manner was never greater than 015 × 10 −2. It is obvious that the amount of enzyme per embryo increases progressively after the 4th day of incubation; although the percentage increase cannot be calculated with any degree of accuracy. The presence of any DNase II prior to 96 hours of incubation seems improbable, since more embryonic material was present in the homogenates of early stages than in those where activity was demonstrable. This is due to the fact that all homogenates assayed had equivalent protein concentrations.
Adult tissues
Analysis of the only two tissues of the adult sea-urchin which could be removed in an intact state, gut and ovary, revealed the presence of a DNase whose properties differed from that found in the eggs and embryos of this species. The activity is only partially inhibited by concentrations of citrate which completely inhibit embryonic DNase. In addition there is essentially no activity at the pH where the embryonic enzyme exhibits maximum activity. Text-fig. 4 shows the pH optimum and the effect of citrate on this adult enzyme in gut homogenates. The effect of various inhibitors and activators of crystalline DNase on the DNase activity of this homogenate is shown in Table 3.
Effect of inhibitors and activators on adult DNase. Enzyme activity is expressed as milligrammes per millilitre of low polymer DNA liberated per hour

Those compounds which remove magnesium from the medium, such as citrate and versene, only reduce the activity by less than one-half, whereas the same agents completely inhibit DNase I. Manganese, which activates most DNase I preparations to practically the same extent as magnesium, inhibits this activity to an even greater extent than does fluoride.
The shifting of the pH optimum from 5·1 to 5·5 in the presence of magnesium and the fact that this enzyme is active in the absence of magnesium both tend to suggest that the apparent magnesium activation may not be due to any effect on the enzyme itself. The activation is probably due to the effect of the magnesium on the substrate. Tamm, Shapiro, & Chargaff (1952) have shown that magnesium will cause a further degradation or depolymerization of partially digested DNA. It is probable that this enzyme of adult tissues only partially depolymerizes the substrate, and in the presence of magnesium it is further degraded.
The fact that magnesium does not inhibit adult DNase activity keeps this enzyme from rigidly fulfilling the DNase II qualifications. However, its characteristics more closely resemble this type of activity than those of DNase I. On the basis of the characterization of the two types of DNase found in mammalian tissues, it would seem valid to conclude that the DNase found in the gut and ovaries of the adult sea-urchin is due to an enzyme which is separate and distinct from that found in the eggs and embryos. In the gut homogenates no activity was found which was similar to that found in the embryos.
In homogenates of ovaries from which practically all the mature eggs had been shed and only immature oocytes remained, both types of activity were present. Text-fig. 5 shows the results of determinations for both types of activity in the same ovarian homogenates. Although embryonic DNase is present, the adult type predominated.
The data presented in Table 4 show that the amount of activity of both enzymes, calculated on the basis of the protein content of the tissues, is lower in the ovary than in those tissues where only one type of activity is present. The embryonic DNase is only 13 per cent, of that found in mature fertilized eggs. It seems probable that the embryonic DNase activity in this tissue is due to the presence of oocytes and the few mature eggs which might still remain in the ovary.
Unless inhibitors are present it can be concluded that embryonic cells contain only one type of DNase, while differentiated adult cells exhibit only activity of another type. The fact that the ovary exhibited both types could exclude the possibility of the presence of inhibitors. However, the low levels of activity found in this tissue might be explained by partial inhibition of both enzymes. To test the possibility of inhibitors masking the presence of adult DNase in embryonic tissue and embryonic DNase in differentiated cells, homogenates of the gut were mixed with homogenates of unfertilized eggs or embryos and both types of activity determined. These activities were compared to that of adult and embryonic tissue alone. Text-fig. 6 shows the results of such an experiment. It is obvious that neither tissue exerts an inhibitory effect.
From these experiments it can be concluded that the adult sea-urchin contains a DNase which is not present in either the eggs or any of the developmental stages up to and including the pluteus larva. It is probable that this enzyme first makes its appearance sometime during the metamorphosis of the pluteus larva to an adult sea-urchin. The absence or extremely low level of the embryonic enzyme in adult tissue suggests that during or after metamorphosis of the pluteus larva this enzyme is either destroyed or converted to another type.
Homogenates of various adult organs of the frog exhibited DNase activity in the pH range of 4 to 5. Although magnesium did not completely inhibit this activity, it was higher in reaction mixtures from which the magnesium had been removed by the addition of citrate. Text-fig. 7 shows the pH optimum for the DNase activity found in homogenates of adult frog-liver. The optimum was essentially the same for other adult tissues tested. Above pH 6 no appreciable activity could be detected either in the presence or absence of magnesium. The effect of the addition to the reaction mixture of some of the usual inhibitors and activators is shown in Table 5. The source of the enzyme tested here was a homogenate of adult stomach mucosa. The activity of the enzyme was inhibited by the presence of magnesium or those substances which did not completely remove magnesium from the medium. The enzyme activity found in these adult frogtissues shows the same characteristics as that described for DNase II in bovine tissues.
Effect of inhibitors and activators on frog DNase II. Enzyme activity is expressed as milligrammes per millilitre of low polymer DNA liberated per hour per mg. of protein of homogenate

The relative amounts of this DNase II in various adult frog-tissues is shown in Table 6. The distribution of activity in the adult frog is similar to that obtained for several mammals by Allfrey & Mirsky (1952). Although ovarian eggs showed no DNase II activity, the activity found in ovaries collected after the breeding season is higher than that found in an organ such as the lung. Most probably this enzyme is present only in the somatic cells of the ovary. Therefore, the level of activity in the actual ovarian tissue might be of the same order of magnitude as that of the liver or kidney. The possibility still existed that the presence of an inhibitor in embryonic tissue might be masking the presence of DNase II in the eggs and embryos. This was ruled out by testing the effects of embryonic tissues on the activity of adult lung homogenates. This tissue was chosen, since its low level of activity should make it an exceedingly sensitive test system for the presence of inhibitors. Lung homogenates were mixed with homogenates of unfertilized eggs or early cleavage stages and the rate of depolymerization measured. Text-fig. 8 shows the results of such a determination.
DNase activity of adult frog-tissues, expressed as milligrammes per millilitre of low polymer DNA liberated per hour per mg. of protein of homogenate. The values listed are each the average of three determinations whose mean deviation was never larger than 0·10×10−2

The absence of DNase II in the eggs and embryos of the frog and its presence in every adult organ tested suggested that it first made its appearance during metamorphosis. To determine during which period of metamorphosis this occurred, tadpoles were collected at different intervals after hatching, homogenized, and tested for DNase activity by the viscometric method. The first appreciable amount of DNase that could be detected was in tadpoles that had been raised for 50 days after they attained Shumway Stage 25. These tadpoles, measured from the head to the tip of the tail, ranged from 40 to 50 mm. in length. They had completely formed eyes. Limb-buds were present, but none of the limbs had yet emerged. A homogenate of two such embryos, having a protein concentration of 1·2 mg./ml., depolymerized the substrate during the first 18 minutes of the reaction with a velocity constant equal to 1·88 × 10−2. An adult frogkidney homogenate having a protein concentration of 0·50 mg./ml. and acting on the same concentration of substrate, had a velocity constant of2·73×10−2. From even this sort of crude comparison it is obvious that the DNase activity increases to a large extent from the time it makes its first appearance until the frog reaches maturity.
DISCUSSION
Of the three species studied, only the sea-urchin exhibited any DNase activity during the early portion of embryogenesis, when most of the cell-division and differentiation occurs. There seems to be little doubt that this activity is due to an enzyme which is separate and distinct from that found in the other two species and the adult tissues of the sea-urchin. The disappearance of this enzyme in the adult would tend to support the contention that this enzyme probably has an essential role in either the maintenance, division, or differentiation of embryonic cells. The fact that the amount of enzyme does not change during development, even at periods when cell-division and differentiation are at their maximal level, neither supports nor disproves this contention. However, the question then arises as to why this enzyme or any DNase cannot be found in equivalent embryonic stages of the chick or frog.
There appears to be a fundamental difference in chemical composition of the egg of the sea-urchin as compared to the egg of the frog or chick, which might explain this difference in DNase activity. The quantity of yolk and yolk-like material is much greater in the eggs of the latter two species than in that of the sea-urchin, and the amount of stored desoxyribonucleotides seems to parallel the quantity of yolk present. Therefore, the presence or absence of DNase in early embryonic stages might well be dependent on the amount of de novo DNA synthesis required of the developing embryo. Hoff-Jorgensen has shown that the sea-urchin contains only enough preformed DNA or desoxyribonucleotides to carry it to the 16-cell stage, while the frog has enough for development to late blastulae or a 5,000-cell stage, and the chick enough for the formation of 5 × 107 cells.
The distribution of DNase II and the period of development at which it first appears is essentially similar for all three species studied. The increase of activity of this enzyme during late development, as well as the period when it first emerges, establishes its appearance as a result of differentiation or maturity rather than as one of their causes. In both the frog and the sea-urchin the enzyme first makes its appearance during metamorphosis. In the chick it appears on the 4th day of incubation, and the chick at this time cannot be considered to be any less advanced embryogenically than a metamorphosing sea-urchin or frog tadpole. The heart has already differentiated into its component parts, the digestive tract has become subdivided, the pancreas and internal mesenteries have been formed, and most of the structures of the adult eye are present.
Although there is a clear association of DNase II with adult differentiated tissue, no one has set forth a satisfactory explanation of how this enzyme is involved in either the growth or maintenance of these adult tissues and organs. Allfrey & Mirsky (1952) correlate the amount of enzymes present in adult tissues with the tissue’s ability to proliferate or regenerate. On the basis of this observation and the rate of glycine-N15 incorporation into the nuclear DNA of these tissues, they postulate that DNase II is related to the overall desoxyribonucleotide metabolism, which is higher in those tissues capable of proliferation or regeneration. The role which Allfrey & Mirsky postulate for the function of DNase II does not account for its absence in embryonic tissue or its low activity in differentiated organs during periods of most rapid growth.
From the data obtained by the authors mentioned above, the results of this study, and the work of Brody (1953) it seems quite possible that this enzyme may be more closely associated with the destruction and removal of dead or nonfunctional cells than with the synthesis or overall desoxyribonucleotide metabolism of the tissues in question. The amount of this enzyme in any specific organ seems to increase with the age of the organ (Allfrey & Mirsky, 1952). The degree of destruction or degeneration of the cells of many organs and tissues may also increase with age. This is exemplified by the decrease in the number of cells and fibres in the ganglia and spinal nerves of man (Gardner, 1940); the loss of glomeruli in rat kidney (Aratki, 1926); and the decrease in epidermal cell-layers of the human head and face with advancing age (Ejiri, 1937). The high enzyme activity of mammalian spleen from many sources and the blood-destroying function of this organ also tends to support such a hypothesis. The spleen has from 2 to 5 times the activity of the liver and intestinal mucosa which are among the richest sources of this enzyme (Allfrey & Mirsky, 1952).
Brody (1953) has found that the DNase activity of the 10-weeks’ old human placenta is approximately ten times greater than that of a full-term placenta. The amount of DNase, calculated with the DNA content of the tissue as a basis of reference, remains constant during the 10th and 12th weeks of pregnancy and then progressively diminishes, reaching the minimum value at the 40th week. This decrease in DNase activity cannot be attributed to a cessation of growth, since the area of the uterus which the placenta occupies increases by about 16 per cent, from the 10th to the 20th week, while the enzyme activity drops by more than one-half. However, it is during these first 10 weeks of pregnancy that the formation and growth of the placenta is dependent upon invasion and cell destruction as well as cellular growth and division. Since the cytolytic processes accompanying placental growth, such as invasion of the endometrium and the disappearance of the chorionic villi in the region of the decidua capsularis, all come to a halt at about the 10th week of pregnancy, this too can serve as an example of a relationship existing between the level of DNase activity and the amount of cell destruction occurring in a given tissue or organ.
The absence of DNase II in the early embryo might also be explained in part by the amount of cell death and degeneration associated with the embryonic development of these species. Metamorphosis in the sea-urchin results in such drastic changes in both the organ systems present and the overall appearance of the animal that it is difficult to imagine this occurring without a relatively large degree of degeneration or removal of many of the original larval structures. Though there may be cell death and degeneration occurring during development prior to metamorphosis, there is little or no evidence for this in the literature.
In the case of the frog and chick there is evidence of cell death and degeneration in embryonic stages prior to those at which DNase II first makes its appearance. Glucksman’s review (1951) lists the incidence and localization of cell degenerations during normal vertebrate ontogeny. The first instances of cell destruction cited for Rana is that of degeneration in ganglia of branchial nerves during metamorphosis. It is possible that embryonic cell degeneration does occur earlier than this, as Glucksman lists the degeneration of yolk endoderm cells during gastrulation of another amphibian. However, the paucity of such information in the literature does suggest that the greatest degree of such degeneration OCCUrs during metamorphosis, the period of development when this enzyme activity could first be detected. There are numerous observations of histolysis and cell degeneration in the developing chick embryo prior to the 4th day of incubation (Glucksman, 1951). Though there appears to be more sites of cell degeneration during subsequent development of the chick embryo, it is impossible to state definitively that this process is more pronounced in later stages where the DNase II content increases.
Leblond & Walker (1956) have recently focused attention on the extent of cell destruction and renewal which occurs in the animal body. Their work indicates a much lower order of magnitude for the turnover time of many cell populations than hitherto accepted. Destructive enzymes such as DNase II may be of the highest significance in the maintenance of these renewal processes and the normal economy of the animal body.
ACKNOWLEDGEMENTS
The author wishes to thank Dr. Daniel Mazia for his advice and encouragement in this investigation and Dr. William E. Berg for his aid with certain aspects of the experimental procedure. This paper is condensed from a Ph.D. thesis presented to the University of California.