Tissue phosphatase changes following triamcinolone associated with cleft palate in rats.

One theory of the development of cleft palate in rats involves the action of lysosomal enzymes secreted by epithelial cells at the time of fusion of the palatal shelves. To test this theory we studied the biochemistry of the palates of fetal rats daily between days 14 and 19 (from 3 days before to 3 days after palate closure). Triamcinolone was administered once im on gestation day 14 to Wistar rats; 0.5 mg/kg body weight produced approximately 50% cleft palates. Pooled control palatal tissue was compared with pooled experimental tissue; that from fetuses with clefts being pooled separately from those not affected. Acid phosphatase and beta-glucuronidase were assayed. Concentration vs. time curves for both enzymes were very similar. Prior to the time of palate closure both enzymes were present in low concentration. Between days 16 and 17, the normal time of closure, there was an abrupt increased in enzyme concentration, with experimental tissue showing a significant elevation over control tissue on days 17 and 18. Alkaline phosphatase was also present in small amounts before closure and significantly higher in control tissue on day 17. Protein was depressed in palates having clefts on day 17; thus the ratio of enzyme activities to protein synthesis was significantly elevated at a critical time. Unaffected experimental palates had a normal ratio. These results suggest imbalanced acid phosphatase, beta-glucuronidase, and alkaline phosphatase activity compared with protein synthesis at the time of palate closure following triamcinolone in rats.     

Glutamine synthetase activity in the developing secondary palate and induction by dexamethasone

Glutamine synthetase (EC 6.3.1.2) (GS) and glutamyltransferase (EC 2.3.2.1) (GT) specific activity were examined in developing A/Jax and C57BL/6J (C57) mouse fetal secondary palates. In addition, the induction of palatal GS was also examined after maternal injection of dexamethasone. Palatal GT activity was uniformly higher in A/J than C57 palates with both strains showing highest activity late on day 13 of gestation and a drop in activity by early day 14. In contrast, A/J palatal GS activity peaked transiently late on day 13, dropped by early day 14 and remained lower throughout the remaining period of palatal development. Palatal GS activity in C57 mouse fetuses, although failing to show a discrete transient peak of activity, remained at a constant elevated level from early day 13 to late day 14 and did not decrease until day 15 of gestation. These elevated levels of palatal GS and GT activity correspond to the gestation period of maximal palatal glycoconjugate biosynthesis. Thus, palatal GS activity may play an important regulatory role in the synthesis of these macromolecules. A/J and C57BL/6J mice exhibit different susceptibilities to glucocorticoid-induced cleft palate. However, maternal administration of a non-teratogenic dose of dexamethasone on either late day 12 or late day 13 resulted in a dramatic stimulation of both A/J and C57 fetal palatal GS but not GT activity when assay 18 h later. A/J palatal tissue responded to dexamethasone with greater induction of palatal GS activity than enzyme activity in C57 palates. Palatal GS, sensitive to glucocorticoid stimulation, may thus be an important link in expressing hormonal control of normal palatal differentiation.     

Palatal length in cleft palate as a predictor of speech outcome

In an attempt to predict which patients might benefit from primary posterior pharyngeal flaps done at the time of palatal repair, palatal length was assessed before palatal repair and the patient was placed in one of four categories. Patients with longer palates preoperatively had statistically better speech outcomes than patients with shorter palates. Statistical significance was found for most speech parameters. Information on presurgical palatal length can be useful in predicting which patients might profit from primary "pharyngoplasties."     

Medial epithelial seam cell migration during palatal fusion

The mammalian secondary palate forms from two shelves of mesenchyme sheathed in a single-layered epithelium. These shelves meet during embryogenesis to form the midline epithelial seam (MES). Failure of MES degradation prevents mesenchymal confluence and results in a cleft palate. Previous studies indicated that MES cells undergo features of epithelial-to-mesenchymal transition (EMT) and may become migratory as part of the fusion mechanism. To detect MES cell movement over the course of fusion, we imaged the midline of fusing embryonic ephrin-B2/GFP mouse palates in real time using two-photon microscopy. These mice express an ephrin-B2-driven green fluorescent protein (GFP) that labels the palatal epithelium nuclei and persists in those cells through the time window necessary for fusion. We observed collective migration of MES cells toward the oral surface of the palatal shelf over 48 hr of imaging, and we confirmed histologically that the imaged palates had fused by the end of the imaged period. We previously reported that ephrin reverse signaling in the MES is required for palatal fusion. We therefore added recombinant EphA4/Fc protein to block this signaling in imaged palates. The blockage inhibited fusion, as expected, but did not change the observed migration of GFP-labeled cells. Thus, we uncoupled migration and fusion. Our data reveal that palatal MES cells undergo a collective, unidirectional movement during palatal fusion and that ephrin reverse signaling, though required for fusion, controls aspects of the fusion mechanism independent of migration.     

Sprouty2 controls proliferation of palate mesenchymal cells via fibroblast growth factor signaling

Cleft palate is one of the most common craniofacial deformities. The fibroblast growth factor (FGF) plays a central role in reciprocal interactions between adjacent tissues during palatal development, and the FGF signaling pathway has been shown to be inhibited by members of the Sprouty protein family. In this study, we report the incidence of cleft palate, possibly caused by failure of palatal shelf elevation, in Sprouty2-deficient (KO) mice. Sprouty2-deficient palates fused completely in palatal organ culture. However, palate mesenchymal cell proliferation estimated by Ki-67 staining was increased in Sprouty2 KO mice compared with WT mice. Sprouty2-null palates expressed higher levels of FGF target genes, such as Msx1, Etv5, and Ptx1 than WT controls. Furthermore, proliferation and the extracellular signal-regulated kinase (Erk) activation in response to FGF was enhanced in palate mesenchymal cells transfected with Sprouty2 small interfering RNA. These results suggest that Sprouty2 regulates palate mesenchymal cell proliferation via FGF signaling and is involved in palatal shelf elevation.     

从甲状腺肥大细胞探讨胎儿器官肥大细胞的差异

研究肥大细胞在人胎儿甲状腺发育中数量、分布及组化性质的改变,以探讨胎儿器官发育中肥大细胞的差异。取45例不同胎龄的人胎甲状腺石蜡切片做甲苯胺蓝染色和阿尔辛蓝－－藏红染色,并测定肥大细胞的临界电解质浓度值及进行硫酸小蘖硷荧光染色。结果显示：3月龄胎儿甲状腺内开始出现肥大细胞,数量极少,主要分布在被膜及小叶间结缔组织内,甲苯胺蓝染色肥大细胞颗粒呈淡紫蓝色,阿尔辛蓝－－藏红染色呈蓝色,临界电解质浓度值较低,硫酸小蘖硷染色未见显黄色荧乐的肥大细胞,从3月龄到足月随着胎龄增长,肥大细胞数量缓慢增多,8月龄时肥大细胞经甲苯胺蓝染色,其颗粒呈紫红色,阿尔辛蓝－－藏红染色出现少量含红色和红蓝混合染色颗粒的肥大细胞,临界电解质浓度值偏高,可见少量显黄色荧光的肥大细胞,结果表明：在人胎儿3月龄时甲状腺发育中开始出现肥大细胞,但随胎儿发育肥大细胞的组化性质改变不明显。     

Susceptibility of mice to phenytoin-induced cleft palate correlated with inhibition of fetal palatal RNA and protein synthesis (41255)

Phenytoin administered to pregnant mice during the critical embryonic period of palatal differentiation produced 50% cleft palates in the Ajax (A/J) strain compared to 1.6% clefts in the C57BL/6 (B6) strain of mice. Furthermore, a single maternal injection of phenytoin produced a significantly greater and more persistent decrease in fetal palatal RNA and protein synthesis in the sensitive A/J strain compared to that in the insensitive B6 strain of mice. Thus, these differential effects of phenytoin on RNA and protein synthesis are associated with the differential susceptibility to the teratogenic action of phenytoin in the two strains.     

Effects of epidermal growth factor (EGF), transforming growth factor-alpha (TGFalpha), and 2,3,7,8-tetrachlorodibenzo-p-dioxin on fusion of embryonic palates in serum-free organ culture using wild-type, EGF knockout, and TGFalpha knockout mouse strains

BACKGROUND: 2,3,7,8-Tetrachlorodibenzo-p-dioxin (TCDD) is teratogenic in mice, producing cleft palate (CP). TCDD exposure disrupts expression of epidermal growth factor (EGF) receptor, EGF, and transforming growth factor-alpha (TGFalpha) in the palate and affects proliferation and differentiation of medial epithelial cells. EGF knockout embryos are less susceptible to the induction of CP by TCDD. This study used palate organ culture to examine the hypothesis that EGF enables a response to TCDD. METHODS: The midfacial tissues from wild-type (WT), EGF knockout, C57BL/6J, and TGFalpha knockout embryos were placed in organ culture on gestational day (GD) 12. Palatal explants were cultured for 4 days in serum-free Bigger's (BGJ) medium with 0.1% dimethyl sulfoxide (DMSO) or 1 x 10(-8) M TCDD with or without 2 ng of EGF/ml, 1 or 2 ng of TGFalpha/ml. Effects on palatal fusion were evaluated on day 4 of culture. EGF levels in explants and medium were determined using Luminex technology. RESULTS: In serum-free, control medium, palates from all of the strains fused. EGF knockout palates cultured with TCDD (no EGF) fused, but those cultured with TCDD + 2 ng of EGF/ml failed to fuse (p < 0.05 vs. control or TCDD without EGF). TGFalpha knockout palates failed to fuse when cultured with TCDD + 2 ng of TGFalpha/ml. EGF levels increased in tissue and accumulated in the medium after 24 hr of culture. CONCLUSIONS: This study demonstrated that providing EGF to the palates of EGF knockout mice restored the response to TCDD. These studies support the hypothesis that the mechanism for induction of CP by TCDD is mediated via the EGFR pathway.     

Medial edge epithelial cell fate during palatal fusion

To explain the disappearance of medial edge epithelial (MEE) cells during palatal fusion, programmed cell death, epithelial-mesenchymal transformation, and migration of these cells to the oral and nasal epithelia have been proposed. However, MEE cell death has not always been accepted as a mechanism involved in midline epithelial seam disappearance. Similarly, labeling of MEE cells with vital lipophilic markers has not led to a clear conclusion as to whether MEE cells migrate, transform into mesenchyme, or both. To clarify these controversies, we first utilized TUNEL techniques to detect apoptosis in mouse palates at the fusion stage and concomitantly analyzed the presence of macrophages by immunochemistry and confocal microscopy. Second, we in vitro infected the MEE with the replication-defective helper-free retroviral vector CXL, which carries the Escherichia coli lacZ gene, and analyzed beta-galactosidase activity in cells after fusion to follow their fate. Our results demonstrate that MEE cells die and transform into mesenchyme during palatal fusion and that dead cells are phagocytosed by macrophages. In addition, we have investigated the effects of the absence of transforming growth factor beta(3) (TGF-beta(3)) during palatal fusion. Using environmental scanning electron microscopy and TUNEL labeling we compared the MEE of the clefted TGF-beta(3) null and wild-type mice. We show that MEE cell death in TGF-beta(3) null palates is greatly reduced at the time of fusion, revealing that TGF-beta(3) has an important role as an inducer of apoptosis during palatal fusion. Likewise, the bulging cells observed on the MEE surface of wild-type mice prior to palatal shelf contact are very rare in the TGF-beta(3) null mutants. We hypothesize that these protruding cells are critical for palatal adhesion, being morphological evidence of increased cell motility/migration.     

Alteration of medial-edge epithelium cell adhesion in two Tgf-beta3 null mouse strains

Abstract Although palatal shelf adhesion is a crucial event during palate development, little work has been carried out to determine which molecules are responsible for this process. Furthermore, whether altered palatal shelf adhesion causes the cleft palate presented by Tgf -β₃ null mutant mice has not yet been clarified. Here, we study the presence/distribution of some extracellular matrix and cell adhesion molecules at the time of the contact of palatal shelves in both wild-type and Tgf -β₃ null mutant palates of two strains of mice (C57/BL/6J (C57), and MF1) that develop cleft palates of different severity. We have performed immunohistochemistry with antibodies against collagens IV and IX, laminin, fibronectin, the α₅- and β₁-integrins, and ICAM-1; in situ hybridization with a Nectin-1 riboprobe; and palatal shelf cultures treated or untreated with TGF-β₃ or neutralizing antibodies against fibronectin or the α₅-integrin. Our results show the location of these molecules in the wild-type mouse medial edge epithelium (MEE) of both strains at the time of the contact of palatal shelves; the heavier (C57) and milder (MF1) alteration of their presence in the Tgf -β₃ null mutants; the importance of TGF-β₃ to restore their normal pattern of expression; and the crucial role of fibronectin and the α₅-integrin in palatal shelf adhesion. We thus provide insight into the molecular bases of this important process and the cleft palate presented by Tgf -β₃ null mutant mice.     

Overexpression of Smad2 in Tgf-beta3-null mutant mice rescues cleft palate

Transforming growth factor (TGF)-beta3 is an important contributor to the regulation of medial edge epithelium (MEE) disappearance during palatal fusion. SMAD2 phosphorylation in the MEE has been shown to be directly regulated by TGF-beta3. No phospho-SMAD2 was identified in the MEE in Tgf-beta3-null mutant mice (Tgf-beta3-/-), which was correlated with the persistence of the MEE and failure of palatal fusion. In the present study, the cleft palate phenotype in Tgf-beta3-/- mice was rescued by overexpression of a Smad2 transgene in Keratin 14-synthesizing MEE cells following mating Tgf-beta3 heterozygous mice with Keratin 14 promoter directed Smad2 transgenic mice (K14-Smad2). Success of the rescue could be attributed to the elevated phospho-SMAD2 level in the MEE, demonstrated by two indirect evidences. The rescued palatal fusion in Tgf-beta3-/-/K14-Smad2 mice, however, never proceeded to the junction of primary and secondary palates and the most posterior border of the soft palate, despite phospho-SMAD2 expression in these regions at the same level as in the middle portion of the secondary palate. The K14-Smad2 transgene was unable to restore all the functional outcomes of TGF-beta3. This may indicate an anterior-posterior patterning in the palatal shelves with respect to TGF-beta3 signaling and the mechanism of secondary palatal fusion.     

Genetic aspects of the effects of methylmercury in mice: the incidence of cleft palate and concentrations of adenosine 3':5' cyclic monophosphate in tongue and palatal shelf

Concentrations of adenosine 3':5' cyclic monophosphate (cAMP) were measured in the tongues and palates of 14.5-day-old fetuses from control and methylmercury-treated mothers of four inbred lines of mice which represent the four possible combinations of two H-2 alleles and two residual genetic backgrounds. The incidence of cleft palate in fetuses from control and methylmercury-treated mothers was also examined. The H-2 alleles significantly affected the degree of reduction of cAMP concentration in palates seen in fetuses from mothers treated with methylmercury. Neither the H-2 allele nor the residual genetic background played a role in the effect of methylmercury on cAMP concentrations in fetal tongues. The magnitude of increase in the incidence of cleft palate with methylmercury treatment was approximately the same for all lines. Thus, methylmercury-induced cleft palate may not be mediated by the reduction of cAMP. Finally, fetuses with cleft lip had increased palatal cAMP levels, whether or not they were from control or methylmercury treated mothers.     

TCDD exposure of human embryonic palatal shelves in organ culture alters the differentiation of medial epithelial cells

The highly toxic, polychlorinated aromatic compound 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) occurs as a contaminant throughout the environment. Epidemiology studies of populations accidentally exposed to TCDD have failed to identify TCDD as a human teratogen, but these studies are limited by the small numbers of exposed pregnancies and imprecise estimates of exposure. TCDD is highly teratogenic in mice, inducing cleft palate and hydronephrosis. TCDD exposure in vivo of embryonic mice alters the differentiation and expression of growth factors in the medial epithelial palatal cells. These alterations also occur in rat and mouse palates exposed to TCDD in organ culture. In the present study, human embryonic palatal shelves were cultured in the rodent organ culture system. In order to achieve in vitro the developmental stage at which fusion would normally occur, GD 52 shelves were cultured for 4 days, GD 53 shelves were cultured for 3 days, and GD 54 shelves were cultured for 3 days. Three of four palatal shelves exposed to 5 x 10(-11) M TCDD were identical to their homologous controls (right shelf cultured with control medium; left shelf cultured with TCDD-containing medium). TCDD at 1 x 10(-7) M produced cytotoxicity detected by transmission electron microscopy (TEM). Exposure to 1 x 10(-8) M TCDD resulted in continued incorporation of thymidine ([3H]-TdR detected autoradiographically) by palatal medial cells, failure of the medial peridermal cells to degenerate as observed by scanning electron microscopy (SEM), and differentiation into a stratified, squamous epithelium. These alterations are identical to those induced by TCDD in vitro in rat and mouse palatal cells. The main difference between these species is the level of TCDD required to elicit the responses. Cultured mouse palates respond to 5 x 10(-11) M TCDD with altered medial cell differentiation, and 1 x 10(-10) M TCDD is cytotoxic. The rat shelves respond with altered differentiation at 1 x 10(-8) M and cytotoxicity at 1 x 10(-7) M. All the human shelves respond at 1 x 10(-8) M TCDD with altered differentiation, 1 out of 4 responded at 5 x 10(-11) M, and cytotoxicity occurred at 1 x 10(-7) M. The present data suggest human embryonic palates are less sensitive than those of the C57BL/6N mouse, and that exposure to high levels of TCDD would be required to elicit altered differentiation in the palatal shelf.     

Roles of collagen and periostin expression by cranial neural crest cells during soft palate development

The tissue in the palatal region can be divided into the hard and the soft palates, each having a specialized function such as occlusion, speech, or swallowing. Therefore, an understanding of the mechanism of palatogenesis in relation to the function of each region is important. However, in comparison with the hard palate, there is still a lack of information about the mechanisms of soft palate development. In this study, the authors investigated the contribution of cranial neural crest (CNC) cells to development of both hard and soft palates. They also demonstrated a unique pattern of periostin expression during soft palate development, which was closely related to that of collagen type I (Col I) in palatine aponeurosis. Furthermore, organ culture analysis showed that exogenous transforming growth factor-β (TGF-β) induced the expression of both periostin and Col I. These novel patterns of expression in the extracellular matrix (ECM) induced by CNC cells suggest that these cells may help to determine the character of both the hard and soft palates through ECM induction. TGF-β signaling appears to be one of the mediators of Col I and periostin expression in the formation of functional structures during soft palate development.     

Rescue of an in vitro palate nonfusion model using interposed embryonic mesenchyme

The authors previously established an in vitro palate nonfusion model on the basis of a spatial separation between prefusion embryonic day 13.5 mouse palates (term gestation, 19.5 days). They found that an interpalatal separation distance of 0.48 mm or greater would consistently result in nonfusion after 4 days in organ culture. In the present study, they interposed embryonic palatal mesenchymal tissue between embryonic day 13.5 mouse palatal shelves with interpalatal separation distances greater than 0.48 mm in an attempt to "rescue" this in vitro palate nonfusion phenotype. Because no medial epithelial bilayer (i.e., medial epithelial seam) could potentially form, palatal fusion in vitro was defined as intershelf mesenchymal continuity with resolution of the medial edge epithelia bilaterally. Forty-two (n = 42) palatal shelf pairs from embryonic day 13.5 CD-1 mouse embryos were isolated and placed on cell culture inserts at precisely graded distances (0, 0.67, and 0.95 mm). Positive controls consisted of shelves placed in contact (n = 6). Negative controls consisted of shelves placed at interpalatal separation distances of 0.67 mm (n = 6) and 0.95 mm (n = 7) with no interposed mesenchyme. Experimental groups consisted of embryonic day 13.5 palatal shelves separated by 0.67 mm (n = 11) and 0.95 mm (n = 12) with interposed lateral palatal mesenchyme isolated at the time of palatal shelf harvest. Specimens were cultured for 4 days (n = 19) or 10 days (n = 23), harvested, and evaluated histologically. All positive controls at 4 and 10 days in culture showed complete histologic palatal fusion. All negative controls at 4 days and 10 days in culture remained unfused. Five of six palatal shelves separated at 0.67 mm interpalatal separation distance with interposed mesenchyme were fused at 4 days, and all five were fused at 10 days. At an interpalatal separation distance of 0.95 mm with interposed mesenchyme (n = 12), no palates (zero of four) were fused at 4 days, but seven of eight were fused at 10 days. These data suggest that nonfused palatal shelves can be "rescued" with an interposed graft of endogenous embryonic mesenchyme to induce fusion in vitro.     

Use of the radial forearm flap for deep,central, midfacial defects

Six cases that required soft-tissue replacement in the central midface are presented. The greatest number of flaps were used for large defects in patients with cleft palates who had undergone multiple previous operations. Several were for palatal defects attributable to cocaine abuse, and one was used for lining in a nasal reconstruction. There were no flap losses and, on the basis of these experiences, it is concluded that this is an excellent method for providing soft tissue in these difficult situations.     

Tooth induction and temporal patterning in palatal epithelium of fetal mice

The present study examined the effect of aging on epithelium and on its ability to respond to an inductive stimulus provided by murine dental papillae. In fetal CD-1 mice, 15- to 17-day molar mesenchyme was combined with 15- to 19-day epithelium from the secondary palates. Enamel organs were separated from the dental papillae, and palatal epithelium was peeled away from its underlying mesenchyme after treatment with 1% trypsin. Recombinants of epithelium and papillae were initially cultured on a solidified complex medium for 24 hr followed by an additional 10-14 days of intraocular explanation. Control specimens consisted of isolated molar papillae. Nineteen of 88 isochronal, heterotypic recombinations formed teeth. None of the 46 heterochronal, heterotypic grafts of 18- and 19-day palatal epithelium combined with 15- to 17-day molar papillae-produced teeth. Instead, keratin-filled epithelial cysts and bone spicules were formed. Isolated control molar papillae often formed bone in the intraocular sites but did not form teeth or contain epithelium. These results show that palatal epithelium is first restricted to its developmental pathway at 18 days of gestation. Younger epithelium can convert to functional ameloblasts that secrete enamel protein. In addition to the change in gene expression, normal tooth morphology is attained. The loss of competence of the palatal epithelium at 18 days gestation coincided with the acquisition of stratum corneum and the attainment of the fully differentiated state. The oral surface of palatal epithelium appears to be determined histogenically and morphogenically at 18 days of gestation in mice.     

Maternal phenytoin administration affects DNA and protein synthesis in embryonic primary palates

Recent studies have shown that phenytoin (Dilantin) administration to pregnant A/J mice on day 10 causes reduced growth in embryonic primary palates. The current investigation concentrates on biochemical and autoradiographic changes toward the end of primary palate formation (gestational day 11), which coincides with the developmental period used for the previously conducted morphological studies. On gestational day 10, one group of pregnant A/J mice was injected intraperitoneally (IP) with 60 mg/kg phenytoin and the other group with vehicle. Twenty-three hours after phenytoin administration, all animals were injected (IP) with either [3H]-thymidine or [3H]-leucine. After one hour of incorporation, animals were sacrificed, embryos removed and placed in ice-cold Eagle's minimum essential medium containing 0.02% NaN3 for biochemical assay or fixed immediately in Bouin's solution for autoradiography. For biochemical analyses, palates and limb buds were removed, homogenized, TCA precipitated, lyophilized, and acid hydrolyzed. Examination of the data revealed that DNA synthesis in control palates was 3.8-fold greater than in primary palates from embryos of phenytoin-treated mothers. Results were similar for limb buds from control embryos and from embryos of phenytoin-treated mothers. Experiments utilizing [3H]-leucine indicated that protein synthesis was 2.6-fold greater in primary palates from phenytoin-treated mothers than in control primary palates. Similar results were obtained for protein synthesis in limb-bud tissue from controls and embryos of phenytoin-treated mothers. Autoradiographic data supported the biochemical findings. DNA synthesis in primary palates from embryos of phenytoin-treated mothers decreased 3-fold; protein synthesis increased 2.2-fold compared with control primary palates.(ABSTRACT TRUNCATED AT 250 WORDS)     

Decreased tissue guanylate cyclase activity in glycosuric Djungarian hamsters (Phodopus sungorus) that is correctable with insulin

Twelve hyperglycemic, glycosuric, and ketonuric Djungarian hamsters with average blood glucose concentrations of 295+-32 mg/dl were compared to twelve non-glycosuric, but ketonuric Djungarian hamsters with average blood glucose concentrations of 88+-11 mg/dl with regards to their cyclic nucleotide metabolism. The glycosuric Djungarian hamsters had decreased guanylate cyclase (E.C.4.6.1.2.) activity in vitro and cyclic GMP levels in vivo in liver, lung, kidney, colon, heart, spleen, and pancreas that was approximately 50% of the guanylate cyclase activity in these same tissues of non-glycosuric Djungarian hamsters. The decreased tissue guanylate cyclase activity and cyclic GMP levels in the glycosuric animals could be restored to the level of non-glycosuric Djungarian hamsters with 100 U regular insulin, but not with 50 or 10 U of regular insulin. Fifty and 100 U of regular insulin also increased the level of guanylate cyclase activity in the non-glycosuric (control) animals. There was no change in adenylate cyclase (E.C.4.6.1.1.) activity but there were increased cyclic AMP levels in the glycosuric when compared to the non-glycosuric Djungarian hamsters that were correctable with 100 U of insulin. We conclude that guanylate cyclase activity is decreased in the peripheral tissues of glycosuric Djungarian hamsters as compared to non-glycosuric Djungarian hamsters and that insulin modulates this enzyme.