ACTIVITY OF ALKALINE PHOSPHATASE IN THE MAJOR SALIVARY GLANDS OF MICE AT VARIOUS AGES OF POSTNATAL LIFE, AND DURING PREGNANCY AND LACTATION

present study was aimed to determine the time of appearence of alkaline phosphatase (AP) activity in murine MSGs, as well as enzyme activity changes in the parenchyma and the capillary endothelial bed of murine MSGs during various periods of postnatal life, and during pregnancy and lactation. However, to our knowledge no reports are available on the distribution of AP activity in murine MSGs during postnatal glandular parenchyma differentiation, or during pregnancy and lactation. Summary: Activity of alkaline phosphatase in the major salivary glands of male and female mice at various ages of postnatal life, and in females during pregnancy and lactation was studied histochemically. Enzyme activity was not detected on the day of birth, but was found in the terminal tubules of all major salivary glands during the first postnatal week. Alkaline phosphatase activity was increasing gradually with age and a definitive enzymatic pattern was observed by the age of 6 weeks. No difference in enzyme activity was found among the major salivary glands of young adult and old animals. The parenchyma of fully differentiated submandibular glands showed clear sexually dimorphic patterns of alkaline phosphatase activity. During pregnancy, a significant increase of alkaline phosphatase activity was detected in submandibular gland. From gestation day 15 to the end of pregnancy, enzymic pattern of granular convoluted tubules of pregnant females was the same as in the adult males. Histochemical masculinization of the submandibular gland during pregnancy suggests that besides androgens also progesterone exerts masculinization of the murine submandibular salivary gland.


Introduction
The major salivary glands (MSGs) of mouse are the submandibular, sublingual and parotid glands. The submandibular gland (SMG) is situated on both sides of the midline on the floor of the oral cavity; the sublingual gland (SLG) closely adjoins at the anterolateral surface of the submandibular gland; the parotid gland (PG) lies dorsolaterally behind the ear (Fig.1). In mice, major salivary glands are not fully developed at birth and continue to differentiate during several postnatal weeks. The parenchyma of the salivary glands in newborn mice is composed of rudimentary secretory units known as terminal tubules (TTs) (30).The fully differentiated parenchyma of the rodent major salivary glands comprises morphological units composed of acini (Ac), intercalated ducts (IDs), striated ducts (SDs), and excretory ducts (14,25). In addition, the SMG of mice contains granular convoluted tubules (GCTs) representing secretory structures between the intercalated and striated ducts -they differentiate from the upper parts of the SDs postnatally (25,30) (Fig. 2). The SMG of mice is an androgen-dependent organ (8) showing sexual dimorphism in adult animals (1,7,14,17,23,28). This sex dimorphism is morphologically characterized by three features: 1) larger and more frequent GCTs in males, 2) fe-wer SDs in males, 3) granular IDs in females. The cells of mouse GCTs contain a lot of biologically active polypeptides, much more in males than in females (2).
The present study was aimed to determine the time of appearence of alkaline phosphatase (AP) activity in murine MSGs, as well as enzyme activity changes in the parenchyma and the capillary endothelial bed of murine MSGs during various periods of postnatal life, and during pregnancy and lactation. However, to our knowledge no reports are available on the distribution of AP activity in murine MSGs during postnatal glandular parenchyma differentiation, or during pregnancy and lactation.
AP is also known as an excellent marker of capillary endothelial cells (CECs) (19,27), usually in the arterial part of the capillary bed (19). Membrane localization of this phosphatase strongly suggests its function in membrane active transport, but the mechanism is not known as yet (5). Analysis of AP in mice with defective vitamin B-6 metabolism suggests involvement of AP in vitamin B-6 metabolism in the central nervous system (32), however, its biological and physiological roles in other tissues remain unknown.

Experimental animals
Sixty ICR mice, 20 males and 40 females, were used in this study. Experimental mice were assigned to six groups of 10 animals each (5 males and 5 females in groups N, P, Y, O; 10 females in groups G, L), and classified as follows: group N: early postnatal period (newborn males and females aged 0-7days; the day of birth was counted as day zero) group P: prepubescent and pubescent period (prepubescent males and females aged 1-3 weeks; pubescent males and females aged 4-6 weeks) group Y: young adult period (males and females aged 7-20 weeks) group O: old adult period (males and females aged 24-26 months) group G: pregnancy (5-day-, 10-day-, 15-day-, 21-day-pregnant females; 21st day of gestation = birth of offspring) group L: lactation (5-day-, 10-day-, 15-day-lactating females; 21st day of lactation = day of weaning) Histochemistry SMG, SLG and PG were removed bilaterally in each animal and rapidly frozen. For light microscopy, cryostat sections (20 µm) were used. Histochemical detection of AP was carried out by the simultaneous coupling method of Burstone, 1962 (4); the succedaneous enzymatic method in the combination AP/ AChE (acetylcholinesterase) was sometime used. Parallel detection of AP and AChE (direct-colouring thiocholine method of Karnovsky and Roots, 1964) (21) in the same section was used for better topical orientation in histochemical sections and for complex mapping of the capillary bed.

Results
Histochemical patterns of AP activity in the SMG, SLG and PG of mice of both sexes at various ages of postnatal life, and in the MSGs of female mice during pregnancy and lactation are shown in Table 1.
AP activity in MSGs during the early postnatal period (group N) (Fig. 3, 4) On day zero, all components of the gland parenchyma and likewise the CECs were entirely unreactive for AP. On day 2, apical cell membranes of TTs in the SMG and SLG began to react weakly positive. On day 4, first signs of AP activity were seen in the TTs of PG and in IDs of SMG. AP activity was slowly increasing during the next days of the 1st week. Slight AP activity in the CECs of the arterial part of the capillary bed of all MSGs was detected between day 1 and day 7. No sex difference in enzyme activity pattern was seen in the glands during the early postnatal period. 66 SLG PG SMG AP activity in MSGs during the prepubescent and pubescent period (group P) (Fig. 5) AP activity in TTs and IDs was gradually decreasing to disappear around week 3. However, enzyme activity in the region of developing Ac appeared during the 2nd postnatal week. In all MSGs reaction product outlined basal parts of acini. AP activity in Ac was gradually increasing with age (more rapidly in SMG). No sexual differences in AP activity in SMG of prepubescent (2-3-week-old) animals were observed, but histochemical sexual differences in SMG of pubescent mice (from the 4th week of age on) were seen. During the 4th week, the male SMG Ac displayed rapidly increasing activity, while AP activity in female Ac increased very slowly. The first signs of AP activity in male SMG GCTs were detected during the course of the 4th postnatal week. However, female GCTs stayed enzyme negative at the same time. Between the 4th and 6th postnatal weeks enzyme activity in male GCTs was gradually increasing. During this period, female GCTs displayed none or only sporadic, very slight AP positivity. No enzymic sex differences were seen in SLG and PG. A definitive enzymic pattern was observed in the glands of animals aged six weeks. AP activity in the CECs during the first six postnatal weeks increased also. When histochemically examined by the succedaneous 67 Tab. 1: Histochemical patterns of AP activity in the major salivary glands in several groups        Strong AP reaction is seen in numerous granular convoluted tubules (T). The enzymic pattern is the same as in adult male SMG (see Fig. 6). 150x.

GROUP N GROUP P GROUP Y GROUP O GROUP G GROUP L
T T T T T T enzymatic methods for AP and AChE, the arterial segment of capillary bed revealed the AP activity in contrast with the AChE-stained venous segment of the capillary bed. The middle part of the capillary bed between those segments displayed activity of both enzymes.
AP activity in MSGs during young and old adult periods (groups Y, O) (Fig. 6, 7, 8) No difference was found in AP activity of the parenchyma of MSGs between young adult (group Y) and old animals (group O), and no enzymic sex differences were detected between AP activity of the SLG and PG. The parenchyma of the SMG demonstrated a more intense reaction than the parenchyma of the SLG or PG. AP activity of fully matured SMG showed clear signs of histochemical sexual dimorphism. Strong enzymic reaction was found in the basal cell membranes of male GCTs, but none (or only sporadic trace reaction) in the female GCTs. Moreover, the GCTs were more frequent and larger in the male than in the female animals. AP activity in the basal cell region of mature SMG Ac was also more intense in males than in the females. Arterial parts of the capillary bed displayed strong AP activity without gland and sex differences. (Fig. 9) In the SLG and PG of pregnant females, the enzymic pattern was the same as in adult males or adult non-pregnant females (groups Y, O). However, dramatic histochemical changes were detected in SMG during the course of pregnancy. On the 5th day of gestation, slight AP activity was seen in the basal cell membranes of all GCTs. From gestation day 15 throughout the end of pregnancy till the 21pregnancy day (birth of offspring), enzyme activity of GCTs reached a maximum. At this time the enzymic pattern of pregnant GCTs was the same as in adult male GCTs.

AP activity in MSGs during pregnancy (group G)
AP activity in MSGs during lactation (group L) (Fig. 10) During lactation, AP activity of GCTs significantly decreased and the SMG of lactating females gradually lost its "masculine" enzymic pattern. However, between lactating day 5 and 15, the GCTs retained some AP activity. At the 10th lactating day, the AP activity of GCT was intermediate between that seen in pregnant females (or adult males) and non-pregnant adult females, whereas on the 21st lactating day (day of weaning) the gland already displayed a "female" type of AP activity (with histochemically negative or only a few positive GCTs).

Discussion
The histochemical demonstration of alkaline phosphatase in the parenchyma of salivary glands of various mammals has been reported by a number of authors (1,13,14,18). Andrews and Bulock (1) reported strong AP activity in the male granular convoluted tubules of murine SMG. Hill and Bourne (14) described a slight AP reaction in some acinar cells of MSGs of mice. Garrett and Harrison (13) noted AP activity in the myoepitelial-cell plasma membranes adjacent to the secretory acini of the MSGs of cats and also in nonmucous acini of the SLG of dogs. Leeson (18) demonstrated AP activity in the myoepithelial cells of rat salivary glands.
The present study describes the light microscopic localization and intensity of AP activity in MSGs of laboratory mice during postnatal gland differentiation, and during pregnancy and lactation. A survey of literature has noted no reports on AP distribution in developing murine salivary glands, or in the glands during pregancy and lactation as yet. Our investigation also documents that AP is a good marker for developing and mature Ac, male GCTs, as well as the arterial part of the capillary bed of MSGs.
We have shown that AP activity in MSGs was undetectable histochemically on the day of birth, appeared in the TTs and SMG IDs during the 1st postnatal week, and then gradually decreased in these structures to disappear at the end of the 3rd week. However, we showed that during the 2nd week, AP activity appeared in region of developing Ac of all three investigated glands. From the 2nd to 6th week of age, AP activity of basal parts of Ac slowly increases in the SLG and PG.
The postnatal development of AP activity in murine SMG can be divided into two phases. In the 1st phase in 2-3-week-old prepubescent animals, the enzymic pattern in developing male SMG is the same as in females. In the 2nd phase in 4-6-week-old pubescent animals, the enzymic pattern is sexually different, the female glands exhibit generally less activity than male ones. In fully differentiated SMG of adult young or old animals this histochemical sexual dimorphism is more pronounced than in SMG of adolescent animals. The enzyme reaction is strong in adult male Ac and GCTs, whereas the reaction is only slight in female Ac, and negative (or sporadically very weakly positive) in female GCTs. It has been known for more than five decades that the SMG of laboratory mice (Mus musculus) exhibits morphological sex dimorphism (17). Number of studies has demonstrated differences between male and female SMG in mice (1,7,14,23). We have shown that sexual differences in intensity and localization of AP activity in adolescent, young and old adult mice exist too.This finding confirms an androgenic dependence of GCTs and indicates a high metabolic activity of male GCTs (which are massive producers of biologically active peptides) (2) and probably plays a different biologic role in males and females. Corresponding to our observations, Andrews and Bullock (1) described strong AP activity in the male GCTs but none in female GCTs of SMG of adult mice. On the other hand, Hill and Bourne (14) found no histochemical sexual differences of AP activity in adult murine SMG.
We have observed that the SMG of mice shows histochemical "masculinization" during pregnancy. This SMG masculinization is characterized by numerous, large and histochemically strongly positive GCTs of pregnant fema-les. The maximum of this masculinization occurs between pregnancy day 15 and day 21 (birth of offspring). During lactation, AP activity of GCTs is gradually decreasing and on lactating day 21 (the day of weaning), GCTs already displays the "female" type of AP activity. Although Desclin (11) reports that progesterone has no masculinizing effect on the morphology of murine female SMG, other authors have shown that progesterone stimulates the SMG (26,31). The SMG of mice is a typical androgen target organ and contains receptors for androgens that can be characterized and quantified (33). Studies in Tfm/y mice also show that SMG of these animals is insensitive to progestagens, suggesting that progesterone acts via androgenic receptors. Progesterone could interact directly with the receptors for androgen, or after its biotransformation into steroid C 19 (26). In fact, progesterone can be converted into 5-alpha-dihydrotestosterone in some androgen target organs such as the SMG of mice, showing that the masculinization effect of progesterone takes place after conversion into androgens (20). While the concentration of progesterone in blood starts to decrease from the 17th day of pregnancy, progestin is very high in the rat SMG till delivery (22).This hormone retention in the glandular tissue could enable the histochemical masculinization of SMG till the 21st day of pregnancy, which our study seems to support.
In the MSGs, AP appears as a good marker of the CECs. Enzyme activity of CECs develops during the first postnatal weeks. In a complex delineation of the capillary bed (with the aid of AP and AChE in the same section), AP maps out the arterial parts of capillaries, whereas AChE depicts the venous part of the capillary bed (the middle part displays activity of both enzymes).This finding documents a heterogeneity of CECs of the capillary bed in murine MSGs.

Conclusion
1) A complex topo-histochemic picture of AP activity in murine MSGs during various periods of postnatal life (in newborn, prepubescent, pubescent, young adult and old animals of both sexes), as well as during pregnancy and lactation is presented. In our study, AP appears as a good marker of developing and mature Ac, male GCTs and CECs. 2) AP activity is absent on the day of birth in the parenchyma of all MSGs and appears during the 1st postnatal week in TTs, transitional structures of gland parenchyma. During week 2, AP activity in basal region of developing Ac of all three glands is recognized. During the 4th postnatal week the first signs of AP activity in male GCTs are revealed. 3) AP activity in basal parts of Ac and male GCTs gradually increases with postnatal differentiation of the glandular parenchyma. Definitive enzymic pattern is present in the MSGs at the end of the 6th week of age. There is no difference in enzymic activity between young adult and old animal glands. The parenchyma of SMG demonstra-tes a more intense AP reaction than the parenchyma of SLG and PG. 4) Distinct sexual differences of AP activity are observed in the SMG. Histochemical sexual dimorphism is not obvious until 3 weeks of age. In adolescent animals (from the 4th week on) a clear histochemical sex dimorphism is evident but is not yet as pronounced as in the mature SMG of adult mice. AP activity in basal parts of Ac is more intense in adult males than in females. GCTs of fully differentiated SMG of adult males are strongly positive, whereas GCTs of adult females are negative or only sporadically very weakly positive. This finding confirms an androgenic dependence of GCTs (primarily known from histological studies) and indicates a high metabolic activity of male GCTs. 5) "Masculinization" of female SMG occurs during pregnancy (with a maximum from the 15th day of gestation till delivery) with the development of numerous, large, histochemically strongly positive GCTs. Progesterone produced during pregnancy apparently stimulates the transformation of the "female" type of GCTs into a metabolically highly AP positive "male" type. This histochemical "masculinization"of GCTs gradually decreases after delivery, and at the end of lactation the gland again assumes the "female" type of activity (with histochemically negative or only sporadically very weakly positive GCTs).This histochemical masculinization of the SMG during pregnancy indicates that not only androgens but also progesterone exerts masculinization of this gland. 6) AP appears as a good marker of the arterial parts of capillaries in the MSGs.