N-Terminal arginylation of proteins in explants of injured sciatic nerves and embryonic brains of rats

Posttranslational modification of proteins by arginine and lysine has been demonstrated in crude extracts of vertebrate nerves and brain but not in intact cells. In the present experiments we have exploited the fact that Arg is added posttranslationally only at the N-terminus of target proteins, to demonstrate these reactions in intact cells of sciatic nerves and embryonic brains of rats. Sciatic nerves were crushed in anaesthesized rats and 2 hrs later segments of nerve, including the site of the crush, were removed and incubated in media containing [³H]Arg. Incorporation of [³H]Arg into total proteins was analyzed by acid precipitation and the presence of label at the N-terminus was determined by a modification of the Edman degradation procedure. Approximately 25% of protein bound [³H]Arg was released from the N-terminus by the Edman reaction indicating that it was added posttranslationally rather than through protein synthesis. N-terminal labeling was not detectable in nerves not crushed prior to explant and incubation. Slices of embryonic day 20 visual cortex, when incubated under similar conditions as injured sciatic nerves, also showed approximately 25% of the protein incorporated [³H]Arg at the N-terminus, while arginylation was not detectable in adult rat brain slices. Since Lys is not added posttranslationally to the N-terminus, we have attempted to observe lysylation of proteins in intact cells by using cycloheximide (Cx) to block protein synthesis without interfering with protein modification. The posttranslational incorporation of Arg/Lys into proteins was found to be insensitive to up to 2.0 mM Cx in tissue extracts (in vitro). However, in intact cells, doses as low as 10 uM Cx completely inhibited the incorporation of [³H]Arg/Lys into proteins. One uM Cx allowed for some incorporation of [³H]Arg/Lys into protein and approximately 40% of the Cx insensitive Arg was incorporated into the N-terminal. These results show that in vivo but not in vitro, Cx can block protein modification, suggesting that either in intact cells protein modification requires protein synthesis, or that Cx has effects other than as an inhibitor of protein synthesis on cells in culture, effects that it does not have on the partially purified components of the reaction.     

A role for Nogo receptor in macrophage clearance from injured peripheral nerve

We report a role for Nogo receptors (NgRs) in macrophage efflux from sites of inflammation in peripheral nerve. Increasing numbers of macrophages in crushed rat sciatic nerves express NgR1 and NgR2 on the cell surface in the first week after injury. These macrophages show reduced binding to myelin and MAG in vitro, which is reversed by NgR siRNA knockdown and by inhibiting Rho-associated kinase. Fourteen days after sciatic nerve crush, regenerating nerves with newly synthesized myelin have fewer macrophages than cut/ligated nerves that lack axons and myelin. Almost all macrophages in the cut/ligated nerves lie within the Schwann cell basal lamina, while in the crushed regenerating nerves the majority migrate out. Furthermore, crush-injured nerves of NgR1- and MAG-deficient mice and Y-27632-treated rats show impaired macrophage efflux from Schwann cell basal lamina containing myelinated axons. These data have implications for the resolution of inflammation in peripheral nerve and CNS pathologies.     

Post-translational arginylation of calreticulin: a new isospecies of calreticulin component of stress granules

Post-translational arginylation consists of the covalent union of an arginine residue to a Glu, Asp, or Cys amino acid at the N-terminal position of proteins. This reaction is catalyzed by the enzyme arginyl-tRNA protein transferase. Using mass spectrometry, we have recently demonstrated in vitro the post-translational incorporation of arginine into the calcium-binding protein calreticulin (CRT). To further study arginylated CRT we raised an antibody against the peptide (RDPAIYFK) that contains an arginine followed by the first 7 N-terminal amino acids of mature rat CRT. This antibody specifically recognizes CRT obtained from rat soluble fraction that was arginylated in vitro and also recognizes endogenous arginylated CRT from NIH 3T3 cells in culture, indicating that CRT arginylation takes place in living cells. Using this antibody we found that arginylation of CRT is Ca2+-regulated. In vitro and in NIH 3T3 cells in culture, the level of arginylated CRT increased with the addition of a Ca2+ chelator to the medium, whereas a decreased arginine incorporation into CRT was found in the presence of Ca2+. The arginylated CRT was observed in the cytosol, in contrast to the non-arginylated CRT that is in the endoplasmic reticulum. Under stress conditions, arginylated CRT was found associated to stress granules. These results suggest that CRT arginylation occurs in the cytosolic pool of mature CRT (defined by an Asp acid N-terminal) that is probably retrotranslocated from the endoplasmic reticulum.     

Org.2766 improves functional and electrophysiological aspects of regenerating sciatic nerve in the rat

The beneficial effect of short-term (8 days) melanocortin therapy on regenerating peripheral nerves is demonstrated using functional and electrophysiological tests. Following a crush lesion of the rat sciatic nerve, recovery of sensory function is monitored by assessing the responsiveness of the rat to a small electric current applied to the footsole. Recovery of motor function is assessed by means of an analysis of walking patterns. Normalization of the walking pattern reflects reinnervation of different muscle groups. The motor and H-reflex related sensory nerve conduction velocity of the regenerated nerves are longitudinally investigated in the same rats in which the recovery of motor and sensory function had been assessed previously. Functional tests show an enhanced recovery under melanocortin therapy, but in the end both saline- and melanocortin-treated rats show 100% recovery. However, when compared to the contralateral sciatic nerve, in the peptide-treated animals motor nerve conduction in the regenerated nerves has fully recovered after about 90 days following the crush lesion and the sensory conduction after about 120 days, whereas in the saline-treated rats a deficit of 20-40% in both motor and sensory conduction remains. This difference is observed even 214 days following crush.     

Synthesis of myelin,particulate, and soluble protein subfractions of rat sciatic nerve during the early stage of Wallerian degeneration: A comparison of metabolic studies using double and single isotope methods and recovery

The recovery, electrophoretic composition and synthesis of the myelin, particulate protein and soluble protein subfractions of rat sciatic nerve were compared in normal, sham-operated, and degenerating rat sciatic nerve at one, three and five days after neurotomy. Both single and double isotope methods were used to measure changes in synthesis in vitro and double isotope methods were used in vivo. The wet weights of nerves undergoing Wallerian degeneration for 5 days increased by 40 percent compared to normal and sham-operated nerves. The recovery, specific radioactivity, and synthesis of the myelin was reduced. The effect on myelin protein synthesis was similar in vitro and in vivo. The myelin loss was relatively constant in amount (30–40 g) regardless of differences in nerve sizes of young and old rats, consequently the percentage of myelin loss was inversely proportional to nerve size.The recovery of particulate protein increased, its rate of synthesis remained unchanged, and accordingly the specific radioactivity was decreased. The recovery, specific radioactivity, and the rate of synthesis of the soluble protein fraction were all elevated. The protein composition of the three fractions, as analyzed qualitatively by polyacrylamide disc gel electrophoresis, remained essentially unchanged through five days of degeneration.With regard to comparisons of the single and double isotope methods, results shows that the latter are more ideally suited to measuring changes in synthesis during the non-steady state conditions that are characteristics of rapid degeneration.     

Accumulation of apolipoproteins in the regenerating and remyelinating mammalian peripheral nerve. Identification of apolipoprotein D, apolipoprotein A-IV, apolipoprotein E, and apolipoprotein A-I

In this report, we have identified two apolipoproteins (apo), apoD and apoA-IV, that, together with the previously identified apoA-I and apoE, accumulate in the regenerating peripheral nerve. These four apolipoproteins were identified in regenerating rat sciatic nerves by their molecular weights, their isoelectric points, and their recognition by specific antibodies. Antibodies were also used to document the changing concentrations of these apolipoproteins in homogenates of regenerating sciatic nerves collected 1 day to 6 weeks after a denervating crush injury. By 3 weeks after injury, at their peak accumulation, apoA-IV and apoA-I had increased 14- and 26-fold, respectively, relative to their concentrations in the normal nerve. Apolipoproteins D and E, in contrast, increased over 500- and 250-fold, respectively, by 3 weeks. These same apolipoproteins also accumulated in the regenerating sciatic nerves of two other species, the rabbit and the marmoset monkey. Immunocytochemistry showed that apoD was produced by astrocytes and oligodendrocytes in the normal central nervous system, and by neurolemmal or fibroblastic cells in the normal peripheral nervous system. Metabolic labeling of both apoD and apoE by [35S]methionine during an in vitro incubation of regenerating rat sciatic nerve segments confirmed that these apolipoproteins are synthesized by the nerve. Neither apoA-IV nor apoA-I was metabolically labeled, however, suggesting that they enter the nerve from the plasma. The results from this study provide evidence that several different apolipoproteins from various sources may play a role in lipid transport within neural tissues.     

Tyrosination State of α-Tubulin in Regenerating Peripheral Nerve

Abstract: Certain modifications of the neuronal cytoskeleton that are associated with development also occur during regeneration of adult mammalian peripheral nerve. The aim of the present study was to examine one such modification, the tyrosination of a-tubulin. Adult rats were anaesthetized and the left or right sciatic nerve randomly selected and crushed to induce regeneration. In certain instances nerves were crushed then ligatured about the crush, to prevent regeneration. Five days later the rats were killed and the regenerating (or ligatured) and the contralateral (control) nerves were removed. Quantitative immunoblotting of nerve homogenates with antibodies that recognize tyrosinated a-tubulin and total a-tubulin revealed a significant increase (p < 0.01) in the proportion of a-tubulin that was tyrosinated in nerve pieces distal (peripheral) to a nerve crush compared with nerve pieces proximal (central) to a nerve crush and to uncrushed nerve. No such difference occurred in ligatured (crushed but nonregenerating) nerve, implying that the increase was related to the presence of regenerating fibres; nor was there any gradient in tyrosination of α-tubulin in control nerves. This effect was confirmed by cytofluorimetric scanning and fluorescence confocal laser scanning microscopy of fixed sections of control and regenerating nerve, stained with antibodies directed against tyrosinated a-tubulin. When nerves were separated into fractions containing assembled and nonassembled tubulin, a significant (p < 0.01) increase was found in the proportion of tyrosinated α-tubulin in the nonassembled tubulin fraction in nerve pieces containing regenerating fibres. This occurred in the absence of a change in the proportion of assembled and nonassembled tubulin. Measurements of tubulin:tyrosine ligase activity, by incorporation of [³H] tyrosine into endogenous nerve tubulin in vitro, indicated a decrease in tyrosine incorporation into tubulin from nerve pieces distal, compared with those proximal to a nerve crush. There was no such difference in ligatured nerves. It is proposed that the increased amount of tyrosinated a-tubulin is related to an alteration in assembly rate of microtubules required for neurite outgrowth and that the apparent decrease in the tubulin:tyrosine ligase activity in vitro reflects the increased tyrosination in vivo.     

Variable spatial magnetic field influences peripheral nerves regeneration in rats

Generator of spatial magnetic field is one of most recent achievements among the magnetostimulators. This apparatus allows to obtain the rotating magnetic field. This new method may be more effective than other widely used techniques of magnetostimulation and magnetotherapy. We investigated the influence of alternating, spatial magnetic field on the regeneration of the crushed rat sciatic nerves. Functional and morphological evaluations were used. After crush injury of the right sciatic nerve, Wistar C rats (n?=?80) were randomly divided into four groups (control and three experimental). The experimental groups (A, B, C) were exposed (20?min/day, 5?d/week, 4 weeks) to alternating spatial magnetic field of three different intensities. Sciatic Functional Index (SFI) and tensometric assessments were performed every week after nerve crush. Forty-eight hours before the sacrificing of animals, DiI (1,1’-di-octadecyl-3,3,3’,3’-tetramethyloindocarbocyanine perchlorate) was applied 5?mm distally to the crush site. Collected nerves and dorsal root ganglia (DRG) were subjected to histological and immunohistochemical staining. The survival rate of DRG neurons was estimated. Regrowth and myelination of the nerves was examined. The results of SFI and tensometric assessment showed improvement in all experimental groups as compared to control, with best outcome observed in group C, exposed to the strongest magnetic field. In addition, DRG survival rate and nerve regeneration intensity were significantly higher in the C group. Above results indicate that strong spatial alternating magnetic field exerts positive effect on peripheral nerve regeneration and its application could be taken under consideration in the therapy of injured peripheral nerves.     

Simvastatin对大鼠坐骨神经crush损伤修复作用研究

目的：探讨他汀类（statins）药物Simvastatin在大鼠坐骨神经损伤修复中的作用及可能的作用机制。方法：制作SD大鼠标准坐骨神经钳夹损伤（crush）模型后,分别予Simvastatin和溶媒对照干预2周。手术前后不同时间点进行趾展功能指数测定、神经电生理学、血脂水平、血清IL-6检测和组织学评价。结果：Simvastatin干预组与对照组比较,趾展功能指数在术后5d和8d显著增大（P〈0．05）,足趾展开速度快;2周肌肉复合动作电位幅度高,4周神经传导速度快;组织学显示有髓神经纤维数量多,髓鞘厚,排列相对整齐。各组手术前血脂水平无差异,手术后2周均有不同程度的降低,但Simvastatin干预组总胆固醇降低程度最轻,与对照组比较有显著差异（P〈0．05）;Simvastatin干预组手术后5d,血清IL-6水平明显低于对照组（P〈0．05）。结论：本研究发现,Simvastatin可能通过抑制免疫炎症反应,维持神经损伤后胆固醇的平衡,促进大鼠坐骨神经损伤的修复和再生。     

Rat sciatic nerve crush injury and recovery tracked by plantar test and immunohistochemistry analysis

An experimental crush injury to the sciatic nerve, with a crush force of 49.2 N (pressure p=1.98x10(8) Pa), was inflicted in 30 male rats (Wistar). A control group (sham), with the same number of rats, was also operated upon exactly as the experimental group but without the crush injury. We tested the sensory and motor recovery of the sciatic nerve with Hargreaves method, using an apparatus from Ugo Basile, Italy. Testing was continued for both legs of each rat, injured and uninjured, starting preoperatively (0 day), and then 1, 7, 14, 21, and 28 days postoperatively. The same experiment was run simultaneously with the sham group. The Plantar test showed recovery of the sensory and motor function of the sciatic nerve, though not complete recovery, by 28 days. An immunohistochemical experiment was run in parallel with the plantar test on L3-L6 segments of the spinal cord from where the sciatic nerve extends. We used antibodies for Myelin-associated glycoprotein (MAG), and gangliosides GD1a and GT1b on the aforesaid part of the spinal cord. The immunohistochemical methods showed changes in sensory and motor axons in the spinal cord segment L3-L6 which suggest correspondence with the results of the Plantar test, in terms of recovery of the sensory and motor function after injury of the sciatic nerve. The immunohistochemical results also show ipsilateral and contralateral changes following injury. Results of the plantar test are suggestive that the rat shows compensation for an injury in its contralateral leg.     

Low-Level Laser Irradiation Improves Functional Recovery and Nerve Regeneration in Sciatic Nerve Crush Rat Injury Model

The development of noninvasive approaches to facilitate the regeneration of post-traumatic nerve injury is important for clinical rehabilitation. In this study, we investigated the effective dose of noninvasive 808-nm low-level laser therapy (LLLT) on sciatic nerve crush rat injury model. Thirty-six male Sprague Dawley rats were divided into 6 experimental groups: a normal group with or without 808-nm LLLT at 8 J/cm² and a sciatic nerve crush injury group with or without 808-nm LLLT at 3, 8 or 15 J/cm². Rats were given consecutive transcutaneous LLLT at the crush site and sacrificed 20 days after the crush injury. Functional assessments of nerve regeneration were analyzed using the sciatic functional index (SFI) and hindlimb range of motion (ROM). Nerve regeneration was investigated by measuring the myelin sheath thickness of the sciatic nerve using transmission electron microscopy (TEM) and by analyzing the expression of growth-associated protein 43 (GAP43) in sciatic nerve using western blot and immunofluorescence staining. We found that sciatic-injured rats that were irradiated with LLLT at both 3 and 8 J/cm² had significantly improved SFI but that a significant improvement of ROM was only found in rats with LLLT at 8 J/cm². Furthermore, the myelin sheath thickness and GAP43 expression levels were significantly enhanced in sciatic nerve-crushed rats receiving 808-nm LLLT at 3 and 8 J/cm². Taken together, these results suggest that 808-nm LLLT at a low energy density (3 J/cm² and 8 J/cm²) is capable of enhancing sciatic nerve regeneration following a crush injury.     

The Protective Effects of Achyranthes bidentata Polypeptides on Rat Sciatic Nerve Crush Injury Causes Modulation of Neurotrophic Factors

Pharmacological treatment is a therapeutic approach to improving nerve regeneration and functional recovery after peripheral nerve crush injury. The objective of the present study was to investigate the effects of the polypeptides isolated from Achyranthes bidentata Blume (abbreviated as ABPP) on rat sciatic crush injury and to test the possible involvement of neurotrophic factors. After surgical crush injury, rats received daily intraperitoneal injection of 0.2 ml saline containing 2 mg ABPP, 1 μg nerve growth factor (NGF) or no additive. The results from walking track analysis, electrophysiological assessment and histological evaluation indicated that the repair outcomes by ABPP treatment were close to those by NGF treatment, but better than those by treatment with saline alone. The quantitative real-time RT-PCR was used to monitor the mRNA expression of growth associated protein in the crush nerves and the mRNA expression of NGF, brain-derived neurotrophic factor (BDNF), ciliary neurotrophic factor (CNTF), tyrosine kinase (Trk)A and TrkB in the dorsal root ganglia (DRGs) at L4–L6. The mRNA expression of these genes in the crush nerve sample and DRGs sample was higher after treatment with ABPP or NGF than after treatment with saline alone. Our findings suggest that ABPP might protect peripheral nerve against crush injury through stimulating release of neurotrophic factors and the other cytokines.     

Potentiation of angiogenesis and regeneration by G-CSF after sciatic nerve crush injury

Granulocyte colony-stimulating factor (G-CSF) demonstrates neuroprotective effects through different mechanisms, including mobilization of bone marrow cells. However, the influence of G-CSF-mediated mobilization of bone marrow-derived cells on injured sciatic nerves remains to be elucidated. The administration of G-CSF promoted a short-term functional recovery 7 days after crush injury in sciatic nerves. A double-immunofluorescence study using green fluorescent protein-chimeric mice revealed that bone marrow-derived CD34+ cells were predominantly mobilized and migrated into injured nerves after G-CSF treatment. G-CSF-mediated beneficial effects against sciatic nerve injury were associated with increased CD34+ cell deposition, vascular endothelial growth factor (VEGF) expression, and vascularization/angiogenesis as well as decreased CD68+ cell accumulation. However, cell differentiation and VEGF expression were not demonstrated in deposited cells. The results suggest that the promotion of short-term functional recovery in sciatic nerve crush injury by G-CSF involves a paracrine modulatory effect and a bone marrow-derived CD34+ cell mobilizing effect.     

Incorporation of fucose and leucine into PNS myelin proteins in nerves undergoing early Wallerian degeneration

The simultaneous incorporation of [³H]fucose and [1-¹⁴C]leucine into normal rat sciatic nerve was examined using an in vitro incubation model. A linear rate of protein precursor uptake was found in purified myelin protein over 1/2–6 hr of incubation utilizing a supplemented medium containing amino acids. This model was then used to examine myelin protein synthesis in nerves undergoing degeneration at 1–4 days following a crush injury. Data showed a statistically significant decrease in the ratio of fucose to leucine at 2, 3, and 4 days of degeneration, which was the consequence of a significant increase in leucine uptake. These results, plus substantial protein recovery in axotomized nerves, are indicative of active synthesis of proteins that purify with myelin during early Wallerian degeneration.     

Inhibition by Forskolin of Excitatory Amino Acid-Induced Accumulation of Cyclic AMP in Guinea Pig Hippocampal Slices

Left sciatic nerves of adult male Sprague-Dawley rats were crushed and allowed to recover for 0, 1, 2, 4, 7, or 14 days. At each of these times both L-5 dorsal root ganglia were injected with 100 microCi of [3H]glucosamine. Two days later, dorsal root ganglia, lumbosacral trunks, and sciatic nerves were removed bilaterally. The amounts of radiolabelled ganglioside in crushed lumbosacral trunks were consistently higher than in the controls, with the largest difference occurring within 2 days from simultaneous crush and injection to killing (specimens labelled day 0). The largest difference in the amount of radiolabelled ganglioside between crushed and control sciatic nerve (4-9 days from crush to killing) occurred later than that of lumbosacral trunk, but no significant difference occurred within the first 3 days following crush. There was only a slightly higher radioactivity in gangliosides totalled from all three anatomical specimens of crushed than in control nerves. The neutral nonganglioside lipid and acid-precipitable fraction followed patterns of synthesis and accumulation similar to those of the gangliosides. These findings indicate that after nerve crush gangliosides, glucosamine-labelled neutral nonganglioside lipids, and glycoproteins accumulate close to the proximal end of the regenerating axon. This accumulation could serve as a reservoir to increase the ganglioside concentration in the growth cone membrane.     

周围神经再生早期过程中内源性和外源性巨噬细胞数量变化的实验研究

目的：周围神经再生过程中巨噬细胞发挥了重要的作用,然而目前对于神经内内源性和外源性巨噬细胞的具体作用了解的却很少,因此本实验研究了小鼠坐骨神经损伤后早期再生过程中内源性和外源性巨噬细胞数量比例变化的情况,探索周围神经再生的规律。方法：移植CAG-EGFP转基因小鼠的全骨髓有核细胞到骨髓灭活野生型C5781／6小鼠体内建立嵌合体小鼠模型。待移植成功3个月后夹伤小鼠一侧坐骨神经,并在损伤后第2、7、14和28天取材、切片,使用巨噬细胞特异性抗体cD68进行免疫荧光染色,分析损伤神经段中内源性巨噬细胞（CD68＋／EGFP-）、外源性巨噬细胞（CD68＋／EGFP＋）的数量及其比例变化情况。结果：①夹伤骨髓移植模型小鼠坐骨神经后,参与坐骨神经损伤修复的巨噬细胞可分为两类,即内源性巨噬细胞（CD68＋／EGFP-）和外源性巨噬细胞（CD68＋／EGFP＋）;②夹伤坐骨神经后,浸润的总巨噬细胞数量从第2天开始逐渐增加,到第14天达到高峰,约为正常情况下的60倍,随后逐渐减少;③起初外、内源性巨噬细胞间的比例是1：1,差值最大出现在损伤后第14天为4：l。结论：小鼠坐骨神经夹伤后,内外源性巨噬细胞共同参与了受损神经组织远心段的修复和再生过程,损伤初期发挥作用的主要是内源性巨噬细胞,随后大量浸润的外源性巨噬细胞占主导作用。本实验首次连续观察并定量分析了神经损伤后早期内源性和外源性巨噬细胞的数量改变,证实了瓦勒氏变性过程中内源性和外源性巨噬细胞在不同阶段对巨噬细胞总量的贡献作用。     

Post-Translational Arginylation of Proteins in Cultured Cells

The aim of this study was to analyze the N-terminal post-translational incorporation of arginine into cytosolic proteins from cultured cells and the in vitro incorporation of arginine into soluble proteins of PC12 cells after serum deprivation. Arginine incorporation was measured in the presence of protein synthesis inhibitors. None of the inhibitors used affected significantly the arginylation reaction while the novo synthesis of protein was reduced by 98%. Under these conditions, we found that of the total [¹⁴C]arginine incorporated into the proteins, around 20% to 40% was incorporated into the N-terminal position of soluble proteins by a post-translational mechanism. These results suggest that this post-translational aminoacylation may be a widespread reaction in neuronal and non-neuronal cells. We also found that in PC12 cells, the in vitro post-translational arginylation was 60% higher in apoptotic cells with respect to control cells. These findings suggest that the post-translational arginylation of proteins may be involved in programmed cell death.     

What Is the Signal for the Posttranslational Arginylation of Proteins?

The N-terminal, posttranslational arginylation of proteins is ubiquitous in eukaryotic cells. Previous experiments, using purified components of the reaction incubated in the presence of exogenous substrates, have shown that only those proteins containing acidic residues at their N-terminals are arginylation substrates. However, data from experiments that used crude extracts of brain and nerve as the source of the arginylating molecules, suggest that the in vivo targets for arginylation are more complex than those demonstrated using purified components. One of the proposed functions for arginylation is as a signal for protein degradation and proteins that have undergone oxidative damage have been shown to be rapidly degraded. In the present experiments we have tested the hypothesis that the presence of an oxidatively damaged residue in a protein is a signal for its arginylation. These experiments have been performed by adding synthetic oxidized peptides to crude extracts of rat brain, incubating them with [³H]Arg and ATP and assaying for arginylated peptides using RP-HPLC. Results showed that while the oxidized A-chain of insulin was arginylated in this system, confirming previous experiments, other peptides containing oxidized residues were not. When a peptide containing Glu in the N-terminus was incubated under the same conditions it too was not a substrate for arginylation. These findings show that neither the presence of an N-terminal acidic residue nor an oxidized residue alone are sufficient to signal arginylation. Thus, another feature of the oxidized A-chain of insulin is required for arginylation. That feature remains to be identified.