Santiago B. Plurad

Insulin-like Growth Factor I Reverses Experimental Diabetic Autonomic Neuropathy

Recent studies have suggested a role for neurotrophic substances in the pathogenesis and treatment of diabetic neuropathy. In this study, the effect of insulin-like growth factor I (IGF-I) on diabetic sympathetic autonomic neuropathy was examined in an experimental streptozotocin-induced diabetic rat model. Two months of IGF-I treatment of chronically diabetic rats with established neuroaxonal dystrophy (the neuropathological hallmark of the disease) involving the superior mesenteric ganglion and ileal mesenteric nerves resulted in nearly complete normalization of the frequency of neuroaxonal dystrophy in both sites without altering the severity of diabetes. Treatment with low-dose insulin (to control for the transient glucose-lowering effects of IGF-I) failed to affect the frequency of ganglionic or mesenteric nerve neuroaxonal dystrophy or the severity of diabetes. The striking improvement in the severity of diabetic autonomic neuropathy shown with IGF-I treatment in these studies and the fidelity of the rat model to findings in diabetic human sympathetic ganglia provide promise for the development of new clinical therapeutic strategies.

Ultrastructural and Biochemical Characterization of Autonomic Neuropathy in Rats with Chronic Streptozotocin Diabetes

Alterations in the extrinsic innervation of the alimentary tract and in various sympathetic autonomic ganglia were examined using quantitative ultrastructural and biochemical methods in streptozotocin diabetic rats maintained without treatment for 9–15 months. Ileal mesenteric nerves of 13–15 month diabetics showed the characteristic alterations of neuroaxonal dystrophy qualitatively similar to changes seen in this system in animals which were diabetic for shorter durations. Dystrophic axonopathy was not accompanied by significant axonal loss or atrophy. Dystrophic axons, presumably involving presynaptic elements, also were increased in frequency in the superior mesenteric ganglia, but not in the superior cervical ganglia, of animals diabetic for various durations. In addition, the superior mesenteric ganglia of diabetic animals contained an increased number of postsynaptic dendritic processes which were dilated by unusual tubular profiles. These ganglionic alterations were not accompanied by changes in the activity of the presynaptic cholinergic marker enzyme, choline acetyltransferase. The activity of the noradrenergic marker enzyme, dopamine-beta-hydroxylase, was unaltered in diabetic superior mesenteric ganglia compared to controls, but showed a 30–40% decrease in diabetic superior cervical ganglia, in which site it was unaccompanied by neuronal loss, atrophy, or ultrastructural alterations.

Axonal cytoskeletal pathology in aged and diabetic human sympathetic autonomic ganglia.

Prevertebral sympathetic ganglia develop markedly enlarged argyrophilic neurites as a function of age, gender and diabetes. Immunolocalization studies demonstrate their preferential labeling with antisera to highly phosphorylated 200 kDa neurofilament (NF-H) epitopes, NPY, peripherin and synapsin I, but not to hypophosphorylated NF-M and NF-H or MAP-2. The immunophenotype of dystrophic neurites in conjunction with the results of histochemical and ultrastructural studies are consistent with the terminal axonal and/or synaptic origin of neuritic dystrophy in the sympathetic ganglia of aged and diabetic human subjects.

Dystrophic Axonal Swellings Develop as a Function of Age and Diabetes in Human Dorsal Root Ganglia

Neuroaxonal dystrophy, characterized by swollen axon terminals and, to a lesser degree, enlarged initial segments of axons or perikaryal projections, develops in human dorsal root sensory ganglia as a function of aging and diabetes. Lesions are typically located within the satellite cell capsule and are intimately applied to sensory neuronal perikarya, which are compressed and distorted but are otherwise normal. Swollen axons contain large numbers of neurofilaments that are immunoreactive with antisera to highly phosphorylated neurofilament epitopes but fail to stain with antisera directed against hypophosphorylated neurofilament epitopes. Other dystrophic swellings contain collections of tubulovesicular profiles admixed with neurotrasnsmitter granules. Neuroaxonal dystrophy involves subpopulations of intraganglionic axons and apparent terminals, notably those containing CGRP, while apparently sparing others, including noradrenergic sympathetic axons. Diabetic subjects develop lesions prematurely and in greater numbers than in aged subjects. Individual dystrophic axons in diabetics and aged human subjects are identical in their light microscopic, immunohistochemical and ultrastructural appearance, suggesting the possibility of shared pathogenetic mechanisms.

The Effect of Pancreatic Islet Transplantation and Insulin Therapy on Experimental Diabetic Autonomic Neuropathy

Rats with chronic streptozotocin (SZ) diabetes develop dilatation of the alimentary tract, loss of fecal consistency, and autonomic neuropathy involving unmyelinated axons of the extrinsic innervation of the small bowel. Diabetic autonomic neuropathy involving the ileal mesenteric nerves is characterized by modest to marked dilatation of axons by distinctive subcellular organelles identical to those described in experimental and clinical axonal dystrophies. Axonopathy is confined to the alimentary tract; examination of myelinated and unmyelinated axons of the sciatic (midthigh level) and distal somatic nerves of the tail of diabetic animals with prominent ileal axonopathy failed to demonstrate significant numbers of dystrophic axons. The prevention or reversal of diabetic autonomic neuropathy by a variety of experimental manipulations clearly indicates that the lesions we have demonstrated in chronically SZ-induced diabetic animals were produced by diabetes and were not the result of a direct neurotoxic effect of the diabetogenic agent streptozotocin. Animals did not develop axonopathy after simultaneous administration of SZ and nicotinamide, a procedure which prevents pancreatic beta-cell necrosis and induction of diabetes while exposing the nervous system to a possible neurotoxic agent. Selected animals that were given SZ, became diabetic, and subsequently received daily insulin therapy or pancreatic islet transplantation also did not develop axonopathy. Transplantation of pancreatic islets 6 mo after induction of diabetes, a time at which mesenteric axonopathy was well developed, quickly reestablished normoglycemia, and within 3 mo resulted in nearly complete resolution of the neuropathy. Mild chronic diabetes maintained for 5–6 mo failed to produce significant levels of axonopathy. Diabetes-induced alteration in the gross appearance and weight of portions of the digestive tract and stool consistency were completely or partially prevented by institution of diabetic control.

Retrograde axonal transport of 125I-nerve growth factor in rat ileal mesenteric nerves. Effect of streptozocin diabetes.

The retrograde axonal transport of intravenously (i.v.) administered 125I-nerve growth factor (125I-NGF) was examined in mesenteric nerves innervating the small bowel of rats with streptozocin (STZ) diabetes using methods described in detail in the companion article. The accumulation of 125I-NGF distal to a ligature on the ileal mesenteric nerves of diabetic animals was 30-40% less than in control animals. The inhibition of accumulation of 125I-NGF in diabetic animals was greater at a ligature tied 2 h after i.v. administration than at a ligature tied after 14 h, which suggests that the diabetic animals may have a lag in initiation of NGF transport in the terminal axon or retardation of transport at some site along the axon. The 125I-NGF transport defect was observed as early as 3 days after the induction of diabetes, a time before the development of structural axonal lesions, and did not worsen at later times when dystrophic axonopathy is present. Both the ileal mesenteric nerves, which eventually develop dystrophic axonopathy in experimental diabetes, and the jejunal mesenteric nerves, which never develop comparable structural alterations, showed similar 125I-NGF transport deficits, suggesting that the existence of the transport abnormality does not predict the eventual development of dystrophic axonal lesions. Autoradiographic localization of 125I-NGF in the ileal mesenteric nerves of animals that had been diabetic for 11-13 mo demonstrated decreased amounts of 125I-NGF in transit in unligated paravascular nerve fascicles. There was, however, no evidence for focal retardation of transported 125I-NGF at the sites of dystrophic axonal lesions.

Effects of Aldose Reductase Inhibitor Sorbinil on Neuroaxonal Dystrophy and Levels of myo-inositol and Sorbitol in Sympathetic Autonomic Ganglia of Streptozocin-Induced Diabetic Rats

Biochemical and ultrastructural effects of the aldose reductase inhibitor sorbinil were examined in two experimental rat models of chronic diabetic neuropathy: rats with streptozocin-induced diabetes (STZ-D) and rats fed a galactose-enriched diet. The frequency of neuroaxonal dystrophy in the superior mesenteric sympathetic ganglia of rats with untreated 8-mo STZ-D increased sevenfold compared with that in age-matched controls. Animals chronically maintained on a diet containing 50% galactose, however, did not develop neuroaxonal dystrophy in excess of that found in untreated age-matched control rats. Institution of sorbinil therapy at the time of induction of STZ-D decreased, but did not completely normalize, the frequency of neuroaxonal dystrophy without altering the severity of diabetes; this finding is based on measurements of plasma glucose, body weight, food consumption, 24-h urine volume, and levels of glycosylated hemoglobin. Sorbitol levels in the superior cervical sympathetic ganglia (SCG) of untreated 8-mo-diabetic animals increased three- to fourfold compared with levels in controls. The increase in sorbitol content of diabetic SCG was completely prevented by early institution of dietary sorbinil therapy. The myo-inositol content of 8-mo-diabetic SCG was modestly decreased compared with controls. Sorbinil administration improved but did not completely normalize diabetic SCG myo-inositol. The sorbitol content of the SCG, superior mesenteric and celiac sympathetic ganglia, and a major trunk of the superior mesenteric nerve xof short-term (2.5-mo)-diabetic rats increased comparably, but only the diabetic SCG showed a decrease in myo-inositol.

Ultrastructural Appearance of Intentionally Frustrated Axonal Regeneration in Rat Sciatic Nerve

The ultrastructural appearance of axons regenerating after crush injury was examined in rat sciatic nerves in which proximodistal growth was interrupted (frustrated regeneration) by placement of a tight ligature 1 cm distal to the original crush injury, and in nerves lacking a distal tie (unimpeded regeneration). Examination of unimpeded regenerating axons four and seven days after injury showed minute axonal sprouts as well as scattered dilated (2–10 μm) axonal profiles containing large numbers of anastomosing tubulovesicular elements and vacuoles. These dilated profiles were consistent with the appearance of growth cones, the motile tips of regenerating axons, as described in various in vivo and in vitro systems. The ultrastructural appearance of regenerating axons accumulating proximal to a frustrating tie was a function of time after arrival at the ligature. At the earliest time examined (one week) large numbers of axonal profiles accumulated at the ligature which were qualitatively similar to growth cones seen in unimpeded regeneration, although slightly larger in diameter. With time, the uniform population of growth cones proximal to the frustrating ligature was replaced by dilated axons containing large numbers of neurofilaments, dense collections of heterogeneous membranous organelles, or delicate to coarse tubulovesicular elements admixed with a variety of subcellular organelles. Rare examples of axonal dystrophy were demonstrated after chronic frustration of regeneration; however, they represented only a small percentage (less than 1%) of frustrated axons. Frustrated regeneration was accompanied by scattered examples of demyelination/remyelination of large axons proximal to the ligature as well as transperineurial growth of axons as microfascicles to escape the site of ligation.

Effects of Sorbinil, Dietary myo-Inositol Supplementation, and Insulin on Resolution of Neuroaxonal Dystrophy in Mesenteric Nerves of Streptozocin-Induced Diabetic Rats

Previous studies indicate that experimental diabetic autonomic neuropathy can be largely prevented by initiating therapy at the onset of diabetes. More clinically relevant, however, is the ability of therapy to reverse established neuropathy produced by long-standing diabetes. We have examined the effect of selected therapies on established neuroaxonal dystrophy (NAD) in ileal mesenteric nerves, a rat model of diabetic autonomic neuropathy. Groups of 3-mo-old rats were made diabetic with streptozocin (STZ-D) and allowed to survive untreated for 5 mo, at which time they were begun on sorbinil, dietary myo-inositol, and daily insulin therapies or left untreated for an additional 2 or 4 mo. Ultrastructural evidence of NAD was demonstrated in ileal mesenteric nerves of rats with untreated 5-mo STZ-D and increased with the duration of diabetes. No lesions were demonstrated in control rats of any age. myo-inositol or sorbinil administration failed to alter the severity of diabetes as measured by its metabolic indices. Institution of sorbinil or insulin treatment at 5 mo of diabetes prevented the increase in, but did not normalize, NAD at 7 or 9 mo. Dietary myo-inositol failed to significantly reverse established NAD or prevent its initial development. Morphometric examination of ileal mesenteric nerves demonstrated a decrease in the number of axons comprising each diabetic Schwann cell unit, suggestive of chronic cycles of axonal degeneration and regeneration. This parameter, clearly abnormal by 5 mo of diabetes, was not normalized by 2 or 4 mo of insulin, sorbinil, or myo-inositol treatment. These observations indicate that treatment with insulin or an aldose reductase inhibitor, but not myo-inositol, initiated after the development of structural axonopathy significantly inhibited progression of NAD for the duration of treatment. (ABSTRACT TRUNCATED AT 250 WORDS)

Effect of sorbitol dehydrogenase inhibition on experimental diabetic autonomic neuropathy

The polyol pathway and its dependent biochemical pathways are thought to play a role in the pathogenesis of diabetic neuropathy. We have developed an animal model of diabetic autonomic neuropathy characterized by neuroaxonal dystrophy involving ileal mesenteric nerves and prevertebral sympathetic superior mesenteric ganglia (SMG) in chronic streptozocin-diabetic rats. Our previous studies have shown a salutary effect of aldose reductase inhibitors on experimental autonomic neuropathy, suggesting a role for the polyol pathway in its pathogenesis. In the current studies we have examined the effect of the sorbitol dehydrogenase inhibitor (SDI) CP-166,572, which interrupts the conversion of sorbitol to fructose (and reactions dependent on the second step of the polyol pathway) resulting in markedly increased levels of sorbitol in peripheral nerve. Fourteen weeks of treatment with CP-166,572 resulted in a dramatically increased frequency of neuroaxonal dystrophy in ileal mesenteric nerves and SMG. Although lesions developed prematurely and in greater numbers in SDI-treated diabetics than untreated diabetics did, their anatomic distribution and ultrastructural appearance were identical to that previously reported in long-term untreated diabetics. CP-166,572 treatment did not produce neuroaxonal dystrophy in control animals despite the fact that sciatic nerve sorbitol levels were markedly increased, reaching the same levels as untreated diabetic animals. Treatment of diabetic rats for 14 weeks with the aldose reductase inhibitor zopolrestat resulted in a significant decrease in the frequency of neuroaxonal dystrophy compared with untreated diabetics.