Decreased collagen production in diabetic rats.

Many of the chronic complications of diabetes mellitus involve defects in the connective tissue such as poor wound healing, diminished bone formation, and decreased linear growth. Because collagen is the major protein component of these connective tissues, we examined collagen production in diabetic rats as a probe of this generalized defect in connective tissue metabolism. Doses of streptozocin ranging from 35 to 300 mg/kg were used to induce diabetes of graded metabolic severity in rats. Parietal bone or articular cartilage was removed and incubated at 37 degrees C with 5 microCi L-[5-3H]proline for 2 h, and collagen and noncollagen protein production were quantitated after separation with purified bacterial collagenase. Within 2 wk after induction of diabetes, collagen production was significantly reduced in bone and cartilage from diabetic rats to 52% (P less than .01) and 51% (P less than .01) of control (buffer-injected) levels, respectively. In contrast, noncollagen protein production in bone and cartilage from diabetic animals was no different from in tissue from control rats. The correlation between collagen relative to total protein production (relative rate) and the degree of hyperglycemia was highly significant for both bone (r = -.77, P less than .001) and cartilage (r = -.87, P less than .001). Other factors found to correlate with altered collagen production were the duration of diabetes and the amount of weight loss. Thus, diabetes is associated with a marked decrease in collagen production, which was seen early after induction of diabetes and was specific when compared with noncollagen protein production. Cumulative effects of these marked changes in collagen production may contribute to the chronic connective tissue complications in diabetes.

Nutritional and hormonal regulation of articular collagen production in diabetic animals.

Although changes in collagen production probably play a major role in the connective tissue defects of diabetes, we do not know to what extent these changes are attributable to hormonal/metabolic versus nutritional alterations. To study collagen production as influenced separately by nutrition versus hormonal/metabolic factors, rats were given 50 mg/kg i.v. streptozocin (STZ) (mild weight-gaining diabetes) or 100 mg/kg STZ (severe weight-losing diabetes) and compared with nondiabetic food-restricted rats to match weight changes in diabetic animals. Articular cartilage was incubated with [3H]proline, and uptake of [3H]proline into both collagen and noncollagen proteins was determined with purified bacterial collagenase. Collagen decreased to 49% in mildly diabetic rats and 16% in severely diabetic rats, compared with control rats fed ad libitum and decreased to 85 and 73%, respectively, in food-restricted rats (both P less than .01 vs. diabetes). Diabetes induced a greater defect in collagen production than food restriction and a greater decrease in collagen than noncollagen protein production within each group, suggesting a specific effect on collagen. With comparable levels of metabolic severity (glucose, beta-hydroxybutyrate), diabetic animals that lost weight produced significantly less collagen than animals that gained weight, suggesting separate mechanisms. Quantitation of the impact of undernutrition on collagen production in diabetes demonstrated that approximately 31 to 32% of the defect was due to undernutrition, leaving approximately 68-69% of the defect due to the diabetic state.(ABSTRACT TRUNCATED AT 250 WORDS)

Tissue-specific regulation of basic fibroblast growth factor mRNA levels by diabetes.

Because basic fibroblast growth factor (bFGF) is recognized as an angiogenic factor and diabetes is characterized by multiple vascular complications, including diabetic microangiopathy, we examined the regulation of tissue bFGF mRNA levels by diabetes. Diabetes was induced in male Sprague-Dawley rats by injection of 125 mg/kg body wt i.v. streptozocin (STZ), with intensive insulin therapy initiated in half of the diabetic rats. Rats were killed 96 h postinjection of STZ. Tissue bFGF and insulinlike growth factor I (IGF-I) mRNA levels were measured simultaneously with a solution hybridization-RNase protection assay. bFGF mRNA levels increased from 1.7- to 2.7-fold in eye, heart, lung, and brain from diabetic compared with buffer-injected control rats. In skeletal muscle, bFGF mRNA levels decreased to 23% of control levels, whereas bFGF mRNA levels were unchanged in kidneys from diabetic versus control rats. Changes in tissue bFGF mRNA levels were partially reversed by insulin treatment in all tissues. In contrast, IGF-I mRNA levels were significantly decreased from 15 to 50% of control levels in all tissues studied except those in brain, which decreased to only 85% of control levels. These data demonstrate that bFGF mRNA levels are altered by diabetes in a tissue-specific fashion and are consistent with the hypothesis that increased production of bFGF may contribute to the development of diabetic microangiopathy in some tissues.

Differential binding of insulin to human arterial and venous endothelial cells in primary culture.

The properties of 125I-insulin binding were assessed in endothelial cells prepared from the veins and the arteries of human umbilical cords. The endothelial nature of both the natural and venous cultures were documented by the presence of characteristic endothelial features, including Weibel-Palade bodies, factor VIII antigen, and morphology. Both arterial and venous cells possessed typical receptors for insulin on the basis of specificity of binding, curvilinear Scatchard plots, affinity profiles, pH dependency, and dissociation kinetics. Arterial cells bound at least 2.5 times more insulin than did venous cells, whether studied at 4 h, 24 h, or 72 h after in vitro plating. We conclude that (1) specific receptors for insulin are present on human arterial as well as human venous endothelial cells and (2) the concentration of insulin receptors varies among endothelial cells derived from different vascular sources.

Hyperthyroidism caused by inappropriate thyrotropin hypersecretion: studies in patients with selective pituitary resistance to thyroid hormone.

We have identified the condition of thyrotropin (thyroid-stimulating hormone [TSH])-induced hyperthyroidism secondary to selective pituitary insensitivity to thyroid hormone in three patients. Each patient was clinically hyperthyroid, with elevated serum levels of thyroxine (T4) and triiodothyronine (T3) and detectable levels of serum TSH before therapy. After therapy each patient had notably elevated TSH levels at a time that peripheral levels of thyroid hormones were in the hyperthyroid range. Before and after therapy, serum levels of TSH were suppressed by therapy with liothyronine sodium and were stimulated by protirelin (thyrotropin-releasing hormone) both before and after liothyronine and dexamethasone treatment. Dexamethasone therapy decreased the levels of TSH, protirelin-stimulated TSH, and circulating T4 and T3. Serum levels of glycoprotein alpha-subunit were 0.6 to 2.4 ng/ml, values considerably lower than found in patients with TSH-secreting pituitary tumors. We suggest that the frequency of TSH-induced hyperthyroidism secondary to pituitary insensitivity to thyroid hormone may be higher than presently indicated in the medical literature.

Prediction of glucose response to weight loss in patients with non-insulin-dependent diabetes mellitus.

Although diet therapy is considered the cornerstone of therapy for obese patients with non-insulin-dependent diabetes mellitus, losing weight is often difficult, and the plasma glucose concentration does not always improve after weight loss. We looked for predictors of improvement in plasma glucose levels after weight loss in 135 obese patients with non-insulin-dependent diabetes mellitus who had lost at least 9.1 kg of body weight. After weight loss there was a bimodal distribution of plasma glucose levels, allowing us to identify patients as "responders" or "nonresponders" according to whether a random plasma glucose level was above or below 10.0 mmol/L after a 9.1-kg weight loss. Fifty-five (41%) of 135 patients were responders (after a 9.1-kg weight loss, the mean +/- SEM plasma glucose level was 7.0 +/- 0.2 mmol/L). Many responders had improved plasma glucose levels after only slight weight loss. Eighty (59%) of 135 patients were nonresponders (after a 9.1-kg weight loss, the mean +/- SEM plasma glucose level was 18.3 +/- 0.6 mmol/L). Although the responder and nonresponder groups were comparable in age, sex distribution, plasma glucose levels, and body weight at initial presentation, improvement in the plasma glucose level after weight loss could be predicted by a plasma glucose level of 10.0 mmol/L or lower after 2.3-kg (62% positive predictive value) and 4.5-kg (79% positive predictive value) weight loss. We conclude that, in contrast to conventional teaching, many patients with non-insulin-dependent diabetes mellitus will not have any improvement in plasma glucose levels after a 9.1-kg weight loss. However, a substantial minority (approximately 40%) of obese patients with non-insulin-dependent diabetes mellitus have much lower plasma glucose levels with a weight loss of 9.1 kg or less. Although the plasma glucose response to weight loss cannot be forecast by initial clinical parameters, the success or failure of diet therapy can be predicted from the plasma glucose level after a weight loss of only 2.3 to 4.5 kg. Mild or moderately obese patients with non-insulin-dependent diabetes mellitus who remain hyperglycemic after a weight loss of 2.3 to 9.1 kg are unlikely to improve with further weight loss and should be considered for treatment with insulin or oral hypoglycemic agents.

Inhibition of collagen production by diabetic rat serum: response to insulin and insulin-like growth factor-I added in vitro.

Diabetes mellitus is associated with a generalized defect in connective tissue metabolism. Since collagen is the major protein of connective tissues, we used collagen as a probe to examine the role of factors in diabetic rat serum (DRS) in the etiology of these defects. Serum and skin fibroblasts were isolated from nondiabetic rats, and serum was taken from rats 48 h after injection of 200 mg/kg streptozotocin. Within 24 h of confluency, the fibroblast medium was changed to experimental serum for 24 h, with 5 microCi [3H]proline added for the final 6 h. Collagen and noncollagen proteins were quantitated using purified collagenase. Compared to cells incubated in medium without serum, collagen fell to 58% with 0.5% DRS (P less than 0.05) and continued to decrease with increasing concentrations of DRS. Noncollagen protein decreased below levels in cells incubated in medium without serum only when concentrations of diabetic serum were 1% or greater and did not decrease further with higher concentrations of diabetic serum. Collagen was decreased to a greater degree than noncollagen protein at each concentration of DRS, such that collagen relative to total protein production was significantly reduced at 0.5% or more DRS. Addition of 10(-7)-10(-9) M insulin or insulin-like growth factor-I (0.1-1000 ng/ml) to DRS did not return collagen production to the level seen in cells incubated in medium with no added serum (basal production). After separation of serum components based on size, incubation of cells with the low mol wt fraction (less than 5000 daltons) of normal and diabetic rat serum resulted in equivalent collagen production, while incubation with the high mol wt fraction of DRS resulted in 200-fold less collagen compared to the similar fraction of normal serum. This decrease in collagen production appeared due to the presence of a high mol wt factor(s) in diabetic serum which had a direct inhibitory effect on collagen and was not due to deficiency of growth peptides. The degree and specificity of these changes in collagen production probably contribute to long term complications in diabetes through altered connective tissue metabolism.

Comparison of insulin binding to cells of fed and fasted obese patients: results in erythrocytes and monocytes.

The erythrocyte (RBC) has received recent interest as a cell model to examine insulin receptor status in humans. In the present study we have compared the insulin receptors on mature RBCs and monocytes of four hyperinsulinemic obese patients in the fed state and after a 14-day fast (less than 50 cal/day). Insulin binding in the basal (fed) state was described in RBC and monocytes due predominantly to a decrease in the receptor concentration in both cell types. After a 14-day fast, insulin binding to both RBCs and monocytes increased significantly in each patient. Maximal binding of [125I]iodoinsulin to RBCs increased by 29% (range, 20-46%), and binding to monocytes increased by 116% (range, 46-321%). In response to the fast, the concentration of insulin needed to inhibit binding by 50% decreased from 5 to 2 ng/ml in RBC and from 3 to 1 ng/ml in monocytes. Conventional and computer-fitted Scatchard analyses demonstrated no change in the receptor concentration of RBCs of any patient, whereas the receptor concentration of monocytes increased by more than 50% in two of the four patients and by 40% for the group. Thus, in response to the fast, the direction of the change in insulin binding was similar in the RBCs and monocytes, whereas the magnitude and, in certain patients, the mechanism of the binding increase differed.

Sulfated glycosaminoglycans in cultured endothelial cells from capillaries and large vessels of human and bovine origin.

The [35S]glycosaminoglycans ([35S]GAG) synthesized by capillary endothelial cells were analyzed and compared to GAG synthesized by endothelial cells cultured from 4 larger vessels. Two separate cultures of endothelial cells were established from bovine fat capillaries and from 4 larger vessels of human origin (umbilical vein) and bovine origin (pulmonary artery, pulmonary vein and aorta). After incubation with 35SO4 for 72 h, the [35S]glycosaminoglycans (GAG) composition of the media, pericellular and cellular fractions of each culture were determined by selective degradation with nitrous acid, chondroitinase ABC and chondroitinase AC. All endothelial cells produced large amounts of [35S]GAG with increased proportions of heparinoids (heparan sulfate and heparin) in the cellular and pericellular fractions. Each culture showed a distinct distribution of [35S]GAG in the media, pericellular and cellular fractions with several specific differences found among the 5 cultures. The differences in GAG content were confirmed in a second group of separate cultures from each of the 5 vessels indicating that, although having several features of GAG metabolism in common, each endothelial cell culture demonstrated a characteristic complement of synthesized, secreted and cell surface-sulfated glycosaminoglycans.

Direct inhibition of collagen production in vitro by diabetic rat serum.

Diabetes mellitus is associated with a generalized defect in connective tissue metabolism, including decreased growth, poor wound healing, and osteopenia. To determine the role of circulating factors in the etiology of these defects, we studied the effects of diabetic rat serum (DRS) on collagen, the major protein component of connective tissues. After preincubation of costal cartilage from hypophysectomized rats with experimental serum for 20 hours, [3H] proline was added for final four hours of incubation. Collagen and noncollagen protein were quantitated using purified bacterial collagenase. Compared to incubation of tissue in buffer without added serum, collagen production in cartilage incubated with 2% DRS was decreased by 23% (P less than .05), and with 4% serum by 88% (P less than .01). In contrast, serum from normal rats (NRS) increased collagen to 158% above buffer-incubated cartilage at 1.0% (P less than .02) and to 196% at 2% serum (P less than .01). Noncollagen protein production decreased below buffer only after addition of 2% or more DRS and increased above buffer after addition of 2% or more of NRS (178%, P less than .05). Addition of insulin at 10 and 100 mU/mL to DRS did not reverse defective collagen production, and addition of glucose (up to 900 mg/dL) or ketones (20 mmol/L) to NRS did not induce the changes in collagen production seen after addition of diabetic serum. Chromatographic separation of serum revealed that the inhibitory activity of DRS was in the high molecular weight fraction (less than 5000).(ABSTRACT TRUNCATED AT 250 WORDS)

Regulation of growth factor mRNA levels in the eyes of diabetic rats.

The underlying etiology of diabetic microvascular disease remains unknown. To examine the potential contribution of basic fibroblast growth factor (bFGF), which is an angiogenic factor, and insulin-like growth factor-I (IGF-I) to the development of diabetic microvascular disease, bFGF and IGF-I mRNA levels were measured in tissues of control, diabetic, and insulin-treated diabetic rats. Diabetes was induced in rats by intravenous injection of streptozotocin (STZ) 65 mg/kg, and the rats were maintained for 21 days. bFGF mRNA levels increased threefold in the eyes of diabetic versus control rats, whereas a consistent change in bFGF mRNA levels was not observed in other tissues. In contrast, IGF-I mRNA levels decreased in the eyes and other tissues, including kidney, lung, and skeletal muscle, of diabetic as compared with control rats. Insulin treatment prevented the diabetes-induced increase in bFGF and decrease in IGF-I mRNA levels. Acidic FGF (aFGF) mRNA levels were unchanged in eyes from diabetic versus control rats. In partially purified retinas, diabetes increased bFGF mRNA levels twofold as compared with levels in control retinas, whereas IGF-I mRNA levels decreased to 58% of control levels in retinas from diabetic rats. Insulin treatment again prevented the diabetes-induced increase in IGF-I mRNA levels in the retina but had no effect on the diabetes-induced increase in bFGF mRNA levels. bFGF peptide levels were minimally increased in diabetic versus control retinas.(ABSTRACT TRUNCATED AT 250 WORDS)

Reducing cardiovascular risk in diabetes. Which factors to modify first?

Up to 80% of diabetic patients die of macrovascular complications, including CAD, stroke, and peripheral vascular disease. Because of the growing numbers of diabetic patients and the increased mortality after their first cardiovascular event, it is critical to identify and treat risk factors early and aggressively in these patients. Numerous studies in patients with type 2 diabetes have shown the benefits of aggressive treatment of blood pressure and lipids to levels that 10 years ago would have seemed abnormally low. The downward changes in "normal" limits can be frustrating to primary care physicians, but advances in treatment are redefining "normal" levels required to avoid complications in this high-risk population.

Correlation between decreased collagen production in diabetic animals and in cells exposed to diabetic serum: response to insulin.

Collagen production has been shown to be decreased in costal cartilage from nondiabetic animals after incubation with diabetic rat serum. Since collagen was decreased to a similar degree in tissues from diabetic animals, we questioned whether altered collagen production in vivo could be related to altered production induced in vitro. Collagen and noncollagen protein production in articular cartilage from diabetic animals (production in vivo) was compared to protein production in dermal fibroblasts from non-diabetic rats exposed to serum from the same diabetic rats (production in vitro). Diabetes was induced by intravenous administration of 90 mg/kg of streptozotocin into male Sprague-Dawley rats. Cartilage was removed and incubated with [3H]-proline for 2 hours at 37 degrees C (in vivo), while fibroblasts were exposed to experimental serum from individual animals for 24 hours with addition of 5 microCi of [5-3H]-proline for the final 6 hours (in vitro). Collagen and noncollagen protein production were quantitated using purified bacterial collagenase. Collagen production in cartilage decreased to 46% (p less than .01) and noncollagen to 68% (p less than .05) of levels in control animals. Fibroblasts exposed to 2.5% diabetic serum decreased collagen and noncollagen protein production to levels of 30% (p less than .01) and 54% (p less than .05) of production in cells incubated in 2.5% normal rat serum. Correlation between defective collagen production in cartilage from individual rats and the effects of their own serum on collagen production in fibroblasts was significant (r = 0.84, p less than 0.001).(ABSTRACT TRUNCATED AT 250 WORDS)

A specific decrease in collagen synthesis in acutely fasted, vitamin C-supplemented, guinea pigs.

Weight loss often results from various experimental conditions including scurvy in guinea pigs, where we showed that decreased collagen synthesis was directly related to weight loss, rather than to defective proline hydroxylation (Chojkier, M., Spanheimer, R., and Peterkofsky, B. (1983) J. Clin. Invest. 72, 826-835). In the study described here, this effect was reproduced by acutely fasting normal guinea pigs receiving vitamin C, as determined by measuring collagen and non-collagen protein production after labeling tissues in vitro with [3H]proline. Collagen production (dpm/microgram of DNA) decreased soon after initiating fasting and by 96 h it had reached levels 8-12% of control values. Effects on non-collagen protein were much less severe, so that the percentage of collagen synthesis relative to total protein synthesis was 20-25% of control values after a 96-h fast. These effects were not due to changes in the specific radioactivity of free proline. Refeeding reversed the effects on non-collagen protein production within 24 h, but collagen production did not return to normal until 96 h. The effect of fasting on collagen production was independent of age, sex, ascorbate status, species of animal, and type of connective tissue and also was seen with in vivo labeling. Pulse-chase experiments and analysis of labeled and pre-existing proteins by gel electrophoresis showed no evidence of increased collagen degradation as a result of fasting. Procollagen mRNA was decreased in tissues of fasted animals as determined by cell-free translation and dot-blot hybridization with cDNA probes. In contrast, there was no decrease in translatable mRNAs for non-collagen proteins. These results suggest that loss of nutritional factors other than vitamin C lead to a rapid, specific decrease in collagen synthesis mainly through modulation of mRNA levels.

Phenytoin-induced agranulocytosis: a nonimmunologic idiosyncratic reaction?

Agranulocytosis is a rare side effect of phenytoin treatment. We describe the case of an elderly man who developed agranulocytosis 2 weeks following initiation of phenytoin treatment, on no cytotoxic drugs or any other medications except decadron. The white blood cell count was 300/mm3 with absent granulocytes. The liver enzymes were also noted to be newly elevated. Complete workup showed no evidence of infection. The patient was managed as a case of neutropenic fever and phenytoin was discontinued. A bone marrow biopsy showed absent granulocyte precursors after myelocytes, and an antigranulocyte antibody titer was negative, which suggests a direct toxic effect rather than an immunologic phenomenon. Both agranulocytosis and hepatitis were readily reversible on phenytoin cessation.

Correction of altered collagen metabolism in diabetic animals with insulin therapy.

Skeletal abnormalities commonly reported in both human and experimental diabetes include impaired linear growth and osteopenia. In the present study we examined the effect of diabetes and insulin therapy on collagen, the major protein constituent of extracellular matrix. Insulin-deficient diabetes was induced in growing rats by injection of 90 mg/kg of streptozotocin. Articular cartilage and long bone (femur) were removed, and tissues incubated with [3H]-proline in vitro for 2 hours at 37 degrees C. Uptake of [3H]-proline into both collagen and noncollagen proteins was determined using purified bacterial collagenase. In cartilage, collagen production decreased to 46% of buffer-injected control animals within one week of induction of diabetes (p less than 0.01), and remained at this level for three weeks. A similar degree of suppression was found in long bone from untreated animals, in which collagen production decreased to 58% of control (p less than 0.01). Insulin administration at the onset of diabetes prevented the expected decrease in collagen production such that after one week of therapy, collagen production in bone and cartilage was 98% and 93% of control (p +/- 0.01 vs. untreated), respectively. When insulin therapy was delayed for one week after the induction of diabetes, collagen production in articular cartilage increased from 46% to 92% and 97% of control at the end of one and two weeks of therapy (p less than 0.01 vs. untreated), respectively. Noncollagen protein production in untreated rats decreased to 49% of control in long bone and to 72% of control in articular cartilage after one week (p less than 0.01), with correction to control levels in both tissues within one week of insulin therapy.(ABSTRACT TRUNCATED AT 250 WORDS)

Regulation of collagen synthesis and mRNA levels in articular cartilage of scorbutic guinea pigs.

Previous studies suggested that decreased type I collagen synthesis in calvaria of ascorbate-deficient guinea pigs was correlated with weight loss rather than defective proline hydroxylation. The generality of this correlation was examined in articular cartilage, which synthesizes mainly type II collagen, by measuring collagen synthesis and proline hydroxylation in vitro in tissue from ascorbate-supplemented and scorbutic guinea pigs. Ascorbate concentrations in tissues were almost completely depleted after 1 week of deficiency, but proline hydroxylation remained normal until after approximately 3 weeks, when it had decreased only by 10%. At that point collagen synthesis had decreased to about 50% of the control value. There was little additional effect on proline hydroxylation but collagen synthesis decreased further to 20% of normal. Procollagen mRNA levels in cartilage, as measured by dot-blot hybridization with a type II-specific cDNA probe, were unchanged after 2 weeks of scurvy, which correlated with the lack of effect on collagen synthesis during that period. Thereafter, during the period when collagen synthesis decreased, procollagen mRNA levels decreased to 20% of control values. Refeeding ascorbate to acutely scorbutic animals led to reversal of defective proline hydroxylation within 24 h with a slower increase in collagen synthesis and mRNA levels. Collagen synthesis returned to the normal level after 4 days with no further increase, while mRNA levels continued to increase to 2.7 times the control values after 7 days. Thus the major mechanism for regulation of collagen synthesis in articular cartilage during scurvy and ascorbate repletion occurs independently of the effect on proline hydroxylation and is associated with changes in mRNA levels. The lack of precise coordination between collagen synthesis and mRNA levels during repletion, however, suggests that there may be additional regulation through post-transcriptional mechanisms.

Coordinate regulation of collagen and proteoglycan synthesis in costal cartilage of scorbutic and acutely fasted, vitamin C-supplemented guinea pigs.

The effects of ascorbic acid deficiency and acute fasting (with ascorbate supplementation) on the synthesis of collagen and proteoglycan in costal cartilages from young guinea pigs was determined by in vitro labeling of these components with radioactive proline and sulfate, respectively. Both parameters were coordinately decreased by the second week on a vitamin C-free diet, with a continued decline to 20-30% of control values by the fourth week. These effects were quite specific, since incorporation of proline into noncollagenous protein was reduced by only 30% after 4 weeks on the deficient diet. The time course of the decrease in collagen and proteoglycan synthesis paralleled the loss of body weight induced by ascorbate deficiency. Hydroxylation of proline in collagen synthesized by scorbutic costal cartilage was reduced to about 60% of normal relatively early, and remained at that level thereafter. Neither collagen nor proteoglycan synthesis was returned to normal by the addition of ascorbate (0.2 mM) to cartilage in vitro. Administration of a single dose of ascorbate to scorbutic guinea pigs increased liver ascorbate and restored proline hydroxylation to normal levels by 24 h, but failed to increase the synthesis of collagen or proteoglycan. Synthesis of both extracellular matrix components was restored to control levels after four daily doses of ascorbate. A 96-h total fast, with ascorbate supplementation, produced rates of weight loss and decreases in the synthesis of these two components similar to those produced by acute scurvy. There was a linear correlation between changes in collagen and proteoglycan synthesis and changes in body weight during acute fasting, scurvy, and its reversal. These results suggest that it is the fasting state induced by ascorbate deficiency, rather than a direct action of the vitamin in either of these two biosynthetic pathways, which is the primary regulatory factor.

L-fucose reduces collagen and noncollagen protein production in cultured cerebral microvessel endothelial cells.

L-fucose is a monosaccharide which is present in low concentrations in normal serum but is increased in diabetes, cancer, and inflammatory diseases. The contribution that abnormal L-fucose levels make to the progression of these disorders is unknown. In a previous study we showed that increased L-fucose concentration reduced proliferation and proteoglycan production by cultured cerebral microvessel endothelial cells. In the present study we show that exposing cerebral microvessel endothelial cells for 2 weeks to medium containing an increased concentration of L-fucose causes a significant decrease in collagen and to a lesser extent noncollagen protein production. The effect of L-fucose on collagen and noncollagen protein production is concentration-dependent: 1 mM L-fucose causes a significant decrease in collagen production but has no effect on noncollagen protein production; a 5 mM L-fucose concentration causes a maximum decrease in both collagen and noncollagen protein production. This defect is unrelated to the reduction in myo-inositol uptake caused by L-fucose and is not prevented by aminoguanidine. Collagen production can be improved by restoring L-fucose-conditioned cells to normal medium. Culturing cells for 2 weeks in medium containing 10 mM L-fucose resulted in a 50% decrease in collagen production, which was restored to 75% of control after cells were transferred to normal medium for 7 days. In contrast, noncollagen protein production was totally restored after 3 days in normal medium. Increasing levels of L-fucose in serum of rats also resulted in a decrease in collagen production. Collagenase digestible incorporation of L-[2,3,4,5-3H]proline into protein of the articular cartilage from rats fed a diet containing 20% L-fucose for 3 weeks was reduced by about 40% compared to rats fed a normal diet. The decrease in collagen production in L-fucose fed rats was less than the reduction that occurred in streptozotocin-induced diabetic rats. These data suggest that changes in L-fucose concentration itself may be a factor in the regulation of collagen production.

Different mechanisms decrease hepatic collagen and albumin production in fasted rats.

Weight loss is correlated with a specific decrease in collagen synthesis in extrahepatic tissues, mainly through modulation of mRNA levels. Here, we investigated the response to weight loss in the rat liver. Male rats were either fed ad libitum or fasted for 92 hr; fasted animals lost approximately 20% of their initial body weight. Following i.p. injection of [5-3H]proline, hepatic collagen was extracted and de novo collagen production was measured. There was a decrease in the specific radioactivities of purified hepatic collagen (-75%) and albumin (-70%) relative to total hepatic protein, indicating that production of both of these proteins was specifically decreased. In fasted animals, the absolute hepatic collagen production was markedly decreased (-60%), while changes in absolute hepatic protein production were small (-15%). Using hybridization with specific DNA probes, we found that fasting causes about a 70% decrease in albumin mRNA, but the quantities of hepatic procollagen alpha 1(I) and alpha 2(I) mRNAs were unchanged. These results are consistent with regulation of albumin production during fasting by modulation of mRNA levels. The inhibition of hepatic collagen production in fasted animals, however, appears to be modulated at a posttranscriptional level or may result from increased degradation. This response differs from the pretranslational regulation of collagen synthesis in extrahepatic tissues during fasting. Furthermore, our results suggest that decreased body weight could be a potentially complicating variable in studies of collagen metabolism and fibrogenesis in the liver.