Fred H. Faas

Altered fatty acid desaturation and microsomal fatty acid composition in the streptozotocin diabetic rat

Streptozotocin diabetes in the rat diminishes the synthesis of both monounsaturated and polyunsaturated fatty acids. Rat liver microsomal fatty acid composition and fatty acid desaturation were studied in the streptozotocin diabetic rat. The major alterations in fatty acid composition found in the diabetic rat were decreased proportions of palmitoleic, oleic and arachidonic acids and an increased proportion of linoleic and docosahexaeneoic acids. These findings, other than the increased docosahexaeneoic acid, probably result from the diminished liver microscomal δ9 and δ6 desaturase activities found in these animals. These changes are not due to the diminished weight gain of the diabetic animals since restricting food intake of control animals to achieve a similar weight gain failed to reproduce either the changes in fatty acid composition or the decrease in fatty acid desaturation. The increased food intake of the diabetic animal may contribute to the altered proportions of linleic and arachidonic acids since limiting food intake in diabetic animals to that of normal controls diminished the magnitude of these changes. Insulin therapy for 2 days not only reverses and overcorrects the diminished desaturase activities, but likewise reverses and overcorrects the altered fatty acid composition, with the exception of the diminished arachidonic aicd levels which are further decreased following insulin therapy. These findings strongly suggest that most of the changes in fatty acid composition in the diabetic rat are indeed caused by the diminished fatty acid desaturase activities.

Fatty Acid Desaturation in Experimental Diabetes Mellitus

Microsomal fatty acid desaturation is defective in streptozotocin-induced experimental diabetes. This defect is correctable by insulin treatment. The electron transport chain needed for microsomal fatty acid desaturation was studied in liver microsomes of streptozotocin diabetic rats, and the defect was localized to the terminal desaturase enzyme. Cytochrome b5 levels were elevated in the face of decreased fatty acid desaturation and returned to normal after 48 h of insulin treatment; 2 U of regular insulin every 6 h for 24 h repaired the fatty acid desaturation defect, while 0.5 U failed to correct the defect. Both the δ6 and δ9 desaturase defects (linoleic acid and stearoyl-CoA desaturation) required similar amounts of insulin and periods of time for correction, although these are different enzymes. This is consistent with the desaturation defect being due to a protein synthetic effect. Diabetic rats treated twice daily with injections of 4 U of NPH insulin showed a “per” repair of their desaturase defect by 48 h: δ9 desaturase activity increased eight times over control activity, while δ6 desaturase activity increased two and one-half times over control activity. This, together with the fact that δ6 desaturase activity in diabetes (64% of control) is altered less than is δ9 desaturase activity (22% of control), indicates that δ6 desaturase enzyme activity is less responsive to insulin than is δ9 desaturase enzyme activity. The physiologic significance of altered fatty acid desaturation in diabetes mellitus is unknown.

Altered microsomal phospholipid composition in the streptozotocin diabetic rat

Streptozotocin diabetes in the rat alters liver microsomal membrane fatty acid composition. The present study was undertaken to determine if such changes in fatty acid composition were due to changes in the amount of individual phosphoglycerides or to disproportionate changes in fatty acid composition in any of the individual phosphoglycerides. The diabetic animals showed a small increase in total microsomal phospholipid, which is due to a selective increase in the phosphatidylethanolamine fraction. The changes in fatty acid composition in the total lipid extract (decreased palmitoleic, oleic and arachidonic acids and increased linoleic and docosahexaenoic acids) from the diabetic animals were present in both the major phosphoglycerides, phosphatidylcholine and phosphatidylethanolamine, with very little change in fatty acid composition in the phosphatidylserine and inositol fraction. Further studies are necessary to delineate the cause of the abnormal membrane phospholipid composition in the diabetic animal.

Effects of clenbuterol on skeletal muscle mass, body composition, and recovery from surgical stress in senescent rats

Aging decreases skeletal muscle mass and strength, which may be exacerbated by age-related diseases. There is a need for therapeutic agents to prevent or restore loss of skeletal muscle in elderly subjects with muscle wasting disorders. Clenbuterol, a beta 2-adrenergic agonist, dramatically increases skeletal muscle mass in young animals and partially prevents or restores muscle loss in experimental models of muscle wasting. However, the protein anabolic and fat catabolic effects of clenbuterol have not been studied in senescent animals. To determine whether this drug has potential for preventing or repairing muscle loss in elderly subjects, we have examined its effects in young and old rats. Clenbuterol was administered by implanted osmotic minipumps to Fischer-344 rats ages 3, 12, and 23 months, at a dose of 1.5 mg/kg/24 h for 3 weeks. The weights of five hindlimb muscles and carcass protein and fat content were determined. Clenbuterol treatment increased the weight of skeletal muscles 22% to 39% in 3-month-old rats, 19% to 35% in 12-month-old rats, and 22% to 25% in 23-month-old animals. Likewise, clenbuterol increased carcass protein content 19% in 3-month-old rats, 16% in 12-month-old rats, and 24% in 23-month-old animals. Conversely, the drug reduced carcass fat content 36% in 3-month-old rats, 32% in 12-month-old rats, and 38% in 23-month-old rats. Therefore, clenbuterol had similar anabolic and catabolic effects in all age groups. In addition, clenbuterol stimulated recovery of skeletal muscle protein lost following pump implantation in senescent rats.(ABSTRACT TRUNCATED AT 250 WORDS)

Increased Phospholipid Fatty Acid Remodeling in Human and Rat Prostatic Adenocarcinoma Tissues

PURPOSE To study the mechanism of diminished arachidonic acid levels in malignant prostatic tissues. MATERIALS AND METHODS Benign and malignant prostate tissues were obtained from human radical prostatectomy specimens and from rats using Pollards Lobund/Wistar rat prostate cancer model. Fatty acid composition and a variety of enzyme activities involved in maintaining phospholipid fatty acid composition were compared in malignant and benign prostatic tissues. RESULTS Decreased arachidonic acid levels, previously reported in human prostate cancer, were present in malignant rat as well as in human tissues. There were 21% and 26% decreases of arachidonic acid levels in the rat and human malignant tissues compared with benign tissues. Fatty acid desaturase activity was undetectable. Fatty acyl-CoA hydrolase and synthetase activities were not altered in the malignant tissues. However, there was a 2-fold increase in phospholipase A2 activity and a 4- to 12-fold increase in fatty acyl-CoA lysophosphatidylcholine acyltransferase activity in malignant rat and human prostatic tissues. CONCLUSIONS These data indicate that, in malignant prostate tissues, the fatty acid remodeling mechanism is activated through the deacylation-reacylation cycle. This process may be a result of increased use of arachidonic acid for the formation of prostaglandins that may be crucial for the further development and growth of the malignant tissues.

Altered fatty acid composition in the plasma, platelets, and aorta of the streptozotocin-induced diabetic rat.

Decreased arachidonate levels have been described in various tissues of the streptozotocin-induced diabetic rat. However, reported arachidonate changes in platelets from diabetic patients have been variable. In this communication, we describe experiments that indicate that in the short-term streptozotocin diabetic rat (2 to 3 weeks), the fatty acid composition of plasma and red blood cell lipids was altered but remained unchanged in platelet and aorta phospholipids. The altered fatty acid composition of the diabetic red blood cells and plasma cholesterol esters and phospholipids was similar to that previously found in the diabetic liver. However, in long-term diabetes (6 weeks), the phospholipid fatty acid composition of the platelet and aorta became significantly altered. Thus, in the 6-week diabetic platelet, there were increases of linoleate, dihomo-gamma-linolenate, docosapentaenoate (C22:5n-3), and docosahexaenoate, and decreases of oleate, arachidonate, and docosatetraenoate. In the aorta, there were increases of linoleate, eicosapentaenoate, and docosahexaenoate, and decreases of arachidonate, docosatetraenoate, and docosapentaenoate (C22:5n-6). Results from these experiments indicate that the fatty acid composition of plasma and red blood cell lipids was altered in short-term diabetes (2 to 3 weeks), but that of platelet and aorta phospholipids was not changed until more prolonged diabetes was present. Insulin treatment of the diabetic rat increased the levels of palmitoleate and oleate and decreased the levels of linoleate in platelet and aorta lipids from insulin-treated diabetic rats, suggesting an overcorrection of diminished delta 9 and delta 6 fatty acid desaturation as compared with the nondiabetic control.(ABSTRACT TRUNCATED AT 250 WORDS)

Improved graft patency associated with altered platelet function induced by marine fatty acids in dogs

Female mongrel dogs fed a marine fish diet rich in long-chain polyenoic fatty acids had improved patency of small-diameter arterial prosthetic grafts as compared to controls. Also, in vivo platelet function as measured by bleeding times was significantly prolonged. Eicosapentaenoic acid, not found in the serum of control animals, was present in relatively high concentrations in both the serum and a platelet-rich fraction of the marine oil-fed group. Eicosapentaenoic acid, unlike arachidonic acid, does not induce platelet aggregation and this phenomonon may account for the altered platelet function demonstrated in our animals and hence the improved graft patency. These data lend further support to the role of platelets in determining the patency of vascular grafts.

Effect of experimental hyperthyroidism on protein turnover in skeletal and cardiac muscle.

Since experimental hyperthyroidism reduces skeletal muscle mass while simultaneously increasing cardiac muscle mass, the effect of hyperthyroidism on muscle protein degradation was compared in skeletal and cardiac muscle. Pulse-labeling studies using (3H) leucine and (14C) carboxyl labeled aspartate and glutamate were carried out. Hyperthyroidism caused a 25%-29% increase in protein breakdown in both sarcoplasmic and myofibrillar fractions of skeletal muscle. Increased muscle protein degradation may be a major factor in the development of skeletal muscle wasting and weakness in hyperthyroidism. In contrast, protein breakdown appeared to be reduced 22% in the sarcoplasmic fraction of hyperthyroid heart muscle and was unchanged in the myofibrillar fraction. Possible reasons for the contrasting effects of hyperthyroidism on skeletal and cardiac muscle include increased sensitivity of the hyperthyroid heart to catecholamines, increased cardiac work caused by the hemodynamic effects of hyperthyroidism, and a different direct effect of thyroid hormone at the nuclear level in cardiac as opposed to skeletal muscle.

Method of LDL Cholesterol Measurement Influences Classification of LDL Cholesterol Treatment Goals: Clinical Research Study

Background Low-density lipoprotein cholesterol (LDL-C) has been clearly associated with the risk of developing coronary heart disease. The best and most convenient method for determining LDL-C has come under increased scrutiny in recent years. We present comparisons of the Friedewald calculated LDL-C (C-LDL-C) and direct LDL-C (D-LDL-C) using 3 different homogenous assays. This highlights differences between the 2 methods of LDL-C measurement and how this affects the classification of samples into different LDL-C treatment goals as determined by the National Cholesterol Education Program Adult Treatment Panel III guidelines thus potentially affecting treatment strategies. Methods Lipid profiles of a total of 2208 clinic patients were retrieved from the Central Arkansas VA Healthcare System clinical laboratory database. Samples studied were of 1-week period during the 3 periods studied: 2000 (period 1), 2002 (period 2), and 2005 (period 3). Different homogenous assays for D-LDL-C measurement were used for each of the 3 periods. Results There is a fundamental disagreement between D-LDL-C and C-LDL-C, although Pearson correlation coefficients are 0.93, 0.97, and 0.98 for periods 1, 2, and 3, respectively. Using the model for period 1, when C-LDL-C is 70 mg/dL, the predicted D-LDL-C is 95 mg/dL (36% higher). The differences between C-LDL-C and predicted D-LDL-C progressively decrease at higher LDL-C cut points. In the assay used in period 3, there are 290 samples with D-LDL-C values between 100 and 130 mg/dL. Of these, only 182 samples show agreement with C-LDL-C values, whereas 90 samples with a D-LDL-C in the 100- to 130-mg/dL range are in the 70- to 100-mg/dL range using the C-LDL-C assay. Although the κ statistics suggests the LDL-C measures have relatively high levels of agreement, the significant generalized McNemar tests (P < 0.01) provide additional evidence of disagreement between C-LDL-C and D-LDL-C during all the 3 periods. Conclusions Our results highlight D-LDL-C measurements using 3 different assays during 3 different periods. In all assays, there is a substantial lack of agreement between D-LDL-C and C-LDL-C, which, in most cases, resulted in higher D-LDL-C values than C-LDL-C. This leads to clinically significant misclassification of patients LDL-C to a different LDL-C treatment goal, which would potentially result in more drug usage, thus exposing patients to more potential adverse effects and at a much greater cost with little evidence of benefit.

INCREASED PROSTATIC LYSOPHOSPHATIDYLCHOLINE ACYLTRANSFERASE ACTIVITY IN HUMAN PROSTATE CANCER:: A MARKER FOR MALIGNANCY

PURPOSE Phospholipase A2 and lysophosphatidylcholine acyltransferase (LAT) constitute a deacylation-reacylation cycle that incorporates arachidonic acid into the lipid membrane. In a preliminary report we found increased LAT activity in malignant prostate tissue. We measured LAT activity in prostate tissue from a large number of patients undergoing prostatectomy. MATERIALS AND METHODS Prostate tissue from 93 patients undergoing radical prostatectomy for prostate carcinoma, 14 undergoing cystoprostatectomy for bladder cancer, 55 undergoing transurethral resection for benign prostatic hyperplasia and 11 with prostate cancer undergoing transurethral resection for relief of obstructive symptoms was analyzed for LAT activity. RESULTS In radical prostatectomy specimens using oleoyl coenzyme A as substrate mean increase in LAT activity between malignant and benign portions of the same specimen was 0.68 +/- 0.12 nmol./mg. protein per minute (p <0.00001). In all radical prostatectomy specimens analyzed LAT activity was 43% higher in the malignant than benign portions (2.25 +/- 0.15 versus 1.57 +/- 0.11 nmol./mg. protein per minute, p <0.001). In the 10 benign prostate specimens obtained from cystoprostatectomy mean LAT activity was 1.12 +/- 0.18 nmol./mg. protein per minute, which was significantly lower than that of benign portions of radical prostatectomy (p <0.05). LAT activity in benign cystoprostatectomy specimens was significantly higher than that in the 50 benign transurethral resection specimens (0.54 +/- 0.05, p <0.01), possibly due to heat damage in transurethral resection specimens during collection. However, LAT activity in transurethral resection specimens from patients with known prostate cancer was similarly increased. Similar results were obtained using arachidonoyl coenzyme A. CONCLUSIONS We demonstrated increased LAT activity in malignant tissue from patients with prostate cancer. Thus, the deacylation-acylation remodeling cycle may be enhanced to provide more arachidonic acid to meet the demand for prostaglandin E2 synthesis in malignant tissue.