Metabolic analysis of reepithelializing rabbit cornea using phosphorus-31 nuclear magnetic resonance spectroscopy

To investigate metabolic differences between the central and peripheral cornea the latter including the limbal area, corneas were dissected and examined using phosphorus-31 (31P) nuclear magnetic resonance spectroscopy. Since most 31P signals originate from the epithelium, 31P spectra of the cornea primarily represent the metabolic state of the epithelium. The spectra of the peripheral cornea showed all phosphorus resonances detected in the whole cornea; in contrast, the central cornea showed no phosphocreatine and glycerophosrylethanolamine, and only low levels of ATP. These results indicate that there is a higher metabolic activity in the peripheral epithelium, especially in the limbal area, than in the central epithelium. To evaluate the metabolic state of corneal epithelium during regeneration, we also examined corneas reepithelializing after 7 mm of central epithelial tissue had been removed by mechanical scraping. Rabbits were killed 24 and 48 h after scraping. The reepithelializing corneas clearly showed an increase in ATP, phosphocreatine, and sugar phosphates with time, although phosphorylcholine remained depressed. These findings suggest that the reepithelializing cornea has an elevated level of energy production and that it may have reached a higher steady state, thereby indicating accelerated metabolism of the epithelium during regeneration.

Disulfide linkage of biotin identifies a 106-kDa Ca2+ release channel in sarcoplasmic reticulum

Reactive disulfide reagents (RDSs) with a biotin moiety have been synthesized and found to cause Ca2+ release from sarcoplasmic reticulum (SR) vesicles. The RDSs oxidize SH sites on SR proteins via a thiol-disulfide exchange, with the formation of mixed disulfide bonds between SR proteins and biotin. Biotinylated RDSs identified a 106-kDa protein which was purified by biotin-avidin chromatography. Disulfide reducing agents, like dithiothreitol, reverse the effect of RDSs and thus promoted active re-uptake of Ca2+ and dissociated biotin from the labeled protein indicating that biotin was covalently linked to the 106-kDa protein via a disulfide bond. Several lines of evidence indicate that this protein is not Ca2+, Mg2+-ATPase and is not a proteolytic fragment or a subunit of the 400-kDa Ca2+-ryanodine receptor complex (RRC). Monoclonal antibodies against the ATPase did not cross-react with the 106-kDa protein, and polyclonal antibodies against the 106-kDa did not cross-react with either the ATPase or the 400-kDa RRC. RDSs did not label the 400-kDa RRC with biotin. Linear sucrose gradients used to purify the RRC show that the 106-kDa protein migrated throughout 5-20% linear sucrose gradients, including the high sucrose density protein fractions containing 400-kDa RRC. Protease inhibitors diisopropylfluorophosphate used to prevent proteolysis of 400-kDa proteins did not alter the migration of 106-kDa in sucrose gradients nor the patterns of biotin labeling of the 106-kDa protein. Incorporation of highly purified 106-kDa protein (free of RRC) in planar bilayers revealed cationic channels with large Na+ (gNa+ = 375 +/- 15 pS) and Ca2+ (gCa2+ = 107.7 +/- 12 pS) conductances which were activated by micromolar [Ca2+]free or millimolar [ATP] and blocked by micromolar ruthenium red or millimolar [Mg2+]. Thus, the SR contains a sulfhydryl-activated 106-kDa Ca2+ channel with apparently similar characteristics to the 400-kDa "feet" proteins.

Polyol pathway activity in streptozotocin-diabetic rat lens

We have examined polyol pathway kinetics in the lenses of rats made diabetic with streptozotocin. At up to 11 days after diabetes induction, the lenses were isolated and subjected to 'pulse-chase' studies: the lenses were incubated with [13C]glucose and lens metabolism followed by [13C]nuclear magnetic resonance (NMR) spectroscopy. Proton NMR spectroscopy was also performed to measure the hexose monophosphate shunt (HMPS) activity. The results showed that (1) the activity of aldose reductase increased initially and decreased after 11 days of diabetes; (2) the fructose pool increased initially but started to decline after 3 days; (3) the HMPS activity increased nearly 40% immediately after diabetes induction; and (4) the turnover rates of glucose, alpha-glycerophosphate (GP), lactate, sorbitol, and fructose were 80.8 +/- 2.6, 10.1 +/- 1.4, 47.7 +/- 3.7, 7.9 +/- 0.9 and 5.2 +/- 2.2 nmol hr-1 lens-1 (34 mg wet weight lens-1), respectively. Up to 35% of lactate appeared to derive from the polyol pathway. Further, GP was rapidly metabolized, although its fate is currently unknown. These results reveal a far more complex pattern of glucose metabolism in the diabetic lens than that in lenses incubated in high glucose.

Metabolic changes in the cornea of vitamin A-deficient rats

We have investigated alterations of the metabolic state in vitamin A-deficient (A-) corneas using phosphorus-31 (31P) nuclear magnetic resonance (NMR) spectroscopy. Comparing to the control, A- corneas showed a prominent rise of phosphocreatine (PCr) as well as a total loss of glycerophosphorylcholine (GPC). Further, ATP levels were lower, and sugar phosphates (SP) and inorganic phosphate (Pi) were higher than those of the control. The accumulation of PCr and Pi, and decrease of ATP indicate that the activity of creatine kinase may be altered in vitamin A deficiency. These results suggest that vitamin A may have a role in creatine kinase activation and/or induction and that its deficiency causes a decline of energy metabolism in corneal epithelium. Moreover, disappearance of GPC implies an impaired cellular membrane metabolism. When retinyl acetate was supplied to A-rats for 5 weeks, the 31P profiles of vitamin A-repleted rat corneas recovered to normal.

[Observation on muscular glycogen in spleen-deficient rats treated with a jian pi yi qi decoction]

The relationship between "Spleen" and muscles was explored by determining the amount of muscular glycogen to indicate the stored energy in muscles. The amount of muscular glycogen in normal rats was 6.34 +/- 0.20 mg/g muscles, it was much more than that in Spleen deficiency rats caused by rhubarb (4.27 +/- 0.40 mg/g muscles). In order to observe the effects of Jian Pi Yi Qi decoction on Spleen deficiency, the Spleen deficiency rats were divided into two groups, one of which was treated with Jian Pi Yi Qi decoction as experimental group, the other with distilled water as control. After one week, the amount of muscular glycogen in experimental group was 5.35 +/- 0.16 mg/g muscles and in control 4.63 +/- 0.15 mg/g muscles. It showed that the rising of the amount of muscular glycogen in experimental group was more than that in control with statistic significance but it was still lower than that in normal rats.

Aqueous/vitreous tonicity in "sugar' cataracts

We examined the aqueous/vitreous tonicity in "sugar' cataracts. Four sets of eyes and their controls were examined: diabetic human eyes, eyes from rabbits and rats fed 50% galactose for up to 1 week, and eyes from streptozotocin-diabetic rats of up to 21 days after diabetes induction. The results showed no statistically significant increase of aqueous/vitreous tonicity in the diabetic human eye and eyes from galactose-fed rats and rabbits. Diabetic rats, on the other hand, showed large tonicity increase in the vitreous, although treatment of the diabetic rats with an aldose reductase inhibitor or insulin completely normalized the tonicity. Seven days after feeding, the galactose-fed animals already showed lens opacities, while diabetic rat lenses remained clear even after 21 days after diabetes induction. These results indicate insignificant osmotic changes in the human eye. In the rat eye, the increase of lens tonicity can be offset by a concomitant increase in the vitreous tonicity. However, this phenomenon is not observed in the galactose eyes. The nature of the osmolytes in the diabetic eye is unclear, although both glucose and sorbitol have been ruled out. The presence of an osmotic regulatory mechanism in the eye is implied.