γ‐Secretase Inhibition Induces Muscle Hypertrophy in a Notch‐Independent Mechanism

A wide variety of cellular processes and signaling events are regulated by the proteolytic enzyme γ‐secretase. Notch‐1 is one of the substrates of γ‐secretase and its role in the regulation of muscle differentiation has been well described. Importantly, besides Notch‐1, a number of proteins have been identified to undergo proteolysis by γ‐secretase. To date, the specific role of γ‐secretase during embryonic skeletal muscle differentiation has not been studied. Therefore, we address this question through the analysis of in vitro grown chick myogenic cells during the formation of multinucleated myotubes. The γ‐secretase inhibitor DAPT (N‐N[‐(3,5‐Difluorophenacetyl‐l ‐alanyl)]‐S‐328 phenylglycine‐t‐butyl‐ester) induces muscle hypertrophy. Knockdown of Notch‐1 using siRNA specific to chick shows no significant effect in myotube size, suggesting that γ‐secretase‐dependent effects on muscle hypertrophy in chick myogenic cells are Notch‐1‐independent. We also investigate the effects of γ‐secretase inhibition in the whole proteomic profile of chick myogenic cells. We identified 276 differentially expressed proteins from Label‐free proteomic approach. Data overview of interaction network obtained from STRING show that after γ‐secretase inhibition cells exhibited imbalance in protein metabolism, cytoskeleton/adhesion, and Sonic Hedgehog signaling. The collection of these results provides new insights into the role of γ‐secretase in skeletal muscle hypertrophy.     

Role of γ‐glutamyltranspeptidase in the pathogenesis of Helicobacter pylori infection

γ‐Glutamyltranspeptidase and asparaginase have been shown to play important roles in Helicobacter pylori colonization and cell death induced by H. pylori infection. In this study, the association of γ‐glutamyltranspeptidase and asparaginase was elucidated by comparing activities of both deamidases in H. pylori strains from patients with chronic gastritis, gastric and duodenal ulcers, and gastric cancer. γ‐Glutamyltranspeptidase activities in H. pylori strains from patients with gastric cancer were significantly higher than in those from patients with chronic gastritis or gastric ulcers. There was a wide range of asparaginase activities in H. pylori strains from patients with gastric cancer and these were not significantly than those from patients with other diseases. To identify the contributions of γ‐glutamyltranspeptidase and asparaginase to gastric cell inflammation, human gastric epithelial cells (AGS line) were infected with H. pylori wild‐type and knockout strains and inflammatory responses evaluated by induction of interleukin‐8 (IL‐8). IL‐8 response was significantly decreased by knockout of the γ‐glutamyltranspeptidase‐encoding gene but not by knockout of the asparaginase‐encoding gene. Additionally, IL‐8 induction by infection with the H. pylori wild‐type strain was significantly decreased by adding glutamine during infection. These findings indicate that IL‐8 induction caused by γ‐glutamyltranspeptidase activity in H. pylori is mainly attributable to depletion of glutamine. These data suggest that γ‐glutamyltranspeptidase plays a significant role in the chronic inflammation caused by H. pylori infection.     

Suppression,disaggregation, and modulation of γ‐Synuclein fibrillation pathway by green tea polyphenol EGCG

Oligomerization of γ‐Synuclein is known to have implications for both neurodegeneration and cancer. Although it is known to co‐exist with the fibrillar deposits of α‐Synuclein (Lewy bodies), a hallmark in Parkinson's disease (PD), the effect of potential therapeutic modulators on the fibrillation pathway of γ‐Syn remains unexplored. By a combined use of various biophysical tools and cytotoxicity assays we demonstrate that the flavonoid epigallocatechin‐3‐gallate (EGCG) significantly suppresses γ‐Syn fibrillation by affecting its nucleation and binds with the unstructured, nucleus forming oligomers of γ‐Syn to modulate the pathway to form α‐helical containing higher‐order oligomers (~158 kDa and ~ 670 kDa) that are SDS‐resistant and conformationally restrained in nature. Seeding studies reveal that these oligomers although “on‐pathway” in nature, are kinetically retarded and rate‐limiting species that slows down fibril elongation. We observe that EGCG also disaggregates the protofibrils and mature γ‐Syn fibrils into similar SDS‐resistant oligomers. Steady‐state and time‐resolved fluorescence spectroscopy and isothermal titration calorimetry (ITC) reveal a weak non‐covalent interaction between EGCG and γ‐Syn with the dissociation constant in the mM range (K_d ~ 2–10 mM). Interestingly, while EGCG‐generated oligomers completely rescue the breast cancer (MCF‐7) cells from γ‐Syn toxicity, it reduces the viability of neuroblastoma (SH‐SY5Y) cells. However, the disaggregated oligomers of γ‐Syn are more toxic than the disaggregated fibrils for MCF‐7cells. These findings throw light on EGCG‐mediated modulation of γ‐Syn fibrillation and suggest that investigation on the effects of such modulators on γ‐Syn fibrillation is critical in identifying effective therapeutic strategies using small molecule modulators of synucleopathies.     

The stress response neuropeptide CRF increases amyloid‐β production by regulating γ‐secretase activity

The biological underpinnings linking stress to Alzheimer's disease (AD) risk are poorly understood. We investigated how corticotrophin releasing factor (CRF), a critical stress response mediator, influences amyloid‐β (Aβ) production. In cells, CRF treatment increases Aβ production and triggers CRF receptor 1 (CRFR1) and γ‐secretase internalization. Co‐immunoprecipitation studies establish that γ‐secretase associates with CRFR1; this is mediated by β‐arrestin binding motifs. Additionally, CRFR1 and γ‐secretase co‐localize in lipid raft fractions, with increased γ‐secretase accumulation upon CRF treatment. CRF treatment also increases γ‐secretase activity in vitro, revealing a second, receptor‐independent mechanism of action. CRF is the first endogenous neuropeptide that can be shown to directly modulate γ‐secretase activity. Unexpectedly, CRFR1 antagonists also increased Aβ. These data collectively link CRF to increased Aβ through γ‐secretase and provide mechanistic insight into how stress may increase AD risk. They also suggest that direct targeting of CRF might be necessary to effectively modulate this pathway for therapeutic benefit in AD, as CRFR1 antagonists increase Aβ and in some cases preferentially increase Aβ42 via complex effects on γ‐secretase.     

Vibrational and chiroptical spectroscopic characterization of γ‐turn model cyclic tetrapeptides containing two β‐Ala residues

The optical spectroscopic characterization of γ‐turns in solution is uncertain and their distinction from β‐turns is often difficult. This work reports systematic ECD and vibrational circular dichroism (VCD) spectroscopic studies on γ‐turn model cyclic tetrapeptides cyclo(Ala‐β‐Ala‐Pro‐β‐Ala) ( 1 ), cyclo(Pro‐β‐Ala‐Pro‐β‐Ala) ( 2 ) and cyclo(Ala‐β‐Ala‐Ala‐β‐Ala) ( 3 ). Conformational analysis performed at the 6‐31G(d)/B3LYP level of theory using an adequate PCM solvent model predicted one predominant conformer for 1‐3 , featuring two inverse γ‐turns. The ECD spectra in ACN of 1 and 2 are characterized by a negative n→π* band near 230 nm and a positive π→π* band below 200 nm with a long wavelength shoulder. The ECD spectra in TFE of 1‐3 show similar spectra with blue‐shifted bands. The VCD spectra in ACN‐d₃ of 1 and 2 show a +/?/+/? amide I sign pattern resulting from four uncoupled vibrations in the case of 1 and a sequence of two positive couplets in the case of 2 . A ?/+/+/? amide I VCD pattern was measured for 3 in TFE‐d₂. All three peptides give a positive couplet or couplet‐like feature (+/?) in the amide II region. VCD spectroscopy, in agreement with theoretical calculations revealed that low frequency amide I vibrations (at ～1630 cm^?1 or below) are indicative of a C₇ H‐bonded inverse γ‐turns with Pro in position 2, while γ‐turns encompassing Ala absorb at higher frequency (above 1645 cm^?1). Chirality, 2010. © 2010 Wiley‐Liss, Inc.     

γ‐Tubulin Ring Complexes and EB1 play antagonistic roles in microtubule dynamics and spindle positioning

γ‐Tubulin is critical for microtubule (MT) assembly and organization. In metazoa, this protein acts in multiprotein complexes called γ‐Tubulin Ring Complexes (γ‐TuRCs). While the subunits that constitute γ‐Tubulin Small Complexes (γ‐TuSCs), the core of the MT nucleation machinery, are essential, mutation of γ‐TuRC‐specific proteins in Drosophila causes sterility and morphological abnormalities via hitherto unidentified mechanisms. Here, we demonstrate a role of γ‐TuRCs in controlling spindle orientation independent of MT nucleation activity, both in cultured cells and in vivo, and examine a potential function for γ‐TuRCs on astral MTs. γ‐TuRCs locate along the length of astral MTs, and depletion of γ‐TuRC‐specific proteins increases MT dynamics and causes the plus‐end tracking protein EB1 to redistribute along MTs. Moreover, suppression of MT dynamics through drug treatment or EB1 down‐regulation rescues spindle orientation defects induced by γ‐TuRC depletion. Therefore, we propose a role for γ‐TuRCs in regulating spindle positioning by controlling the stability of astral MTs.     

Chromosomal integration of a synthetic expression control sequence achieves poly‐γ‐glutamate production in a Bacillus subtilis strain

Poly‐γ‐glutamate (γ‐PGA) has applications in food, medical, cosmetic, animal feed, and wastewater industries. Bacillus subtilis DB430, which possesses the γ‐PGA synthesis ywsC‐ywtAB genes in its chromosome, cannot produce γ‐PGA. An efficient synthetic expression control sequence (SECS) was introduced into the upstream region of the ywtABC genes, and this resulted in γ‐PGA‐producing B. subtilis mutant strains. Mutant B. subtilis PGA6‐2 stably produces high levels of γ‐PGA in medium A without supplementation of extra glutamic acid or ammonium chloride. The mutant B. subtilis PGA 6‐2 is not only a γ‐PGA producer, but it is also a candidate for the genetic and metabolic engineering of γ‐PGA production. © 2010 American Institute of Chemical Engineers Biotechnol. Prog., 2010     

The γ‐aminobutyric acid shunt contributes to closing the tricarboxylic acid cycle in Synechocystis sp. PCC 6803

A traditional 2‐oxoglutarate dehydrogenase complex is missing in the cyanobacterial tricarboxylic acid cycle. To determine pathways that convert 2‐oxoglutarate into succinate in the cyanobacterium Synechocystis sp. PCC 6803, a series of mutant strains, Δsll1981, Δslr0370, Δslr1022 and combinations thereof, deficient in 2‐oxoglutarate decarboxylase (Sll1981), succinate semialdehyde dehydrogenase (Slr0370), and/or in γ‐aminobutyrate metabolism (Slr1022) were constructed. Like in Pseudomonas aeruginosa, N‐acetylornithine aminotransferase, encoded by slr1022, was shown to also function as γ‐aminobutyrate aminotransferase, catalysing γ‐aminobutyrate conversion to succinic semialdehyde. As succinic semialdehyde dehydrogenase converts succinic semialdehyde to succinate, an intact γ‐aminobutyrate shunt is present in Synechocystis. The Δsll1981 strain, lacking 2‐oxoglutarate decarboxylase, exhibited a succinate level that was 60% of that in wild type. However, the succinate level in the Δslr1022 and Δslr0370 strains and the Δsll1981/Δslr1022 and Δsll1981/Δslr0370 double mutants was reduced to 20–40% of that in wild type, suggesting that the γ‐aminobutyrate shunt has a larger impact on metabolite flux to succinate than the pathway via 2‐oxoglutarate decarboxylase. ¹³C‐stable isotope analysis indicated that the γ‐aminobutyrate shunt catalysed conversion of glutamate to succinate. Independent of the 2‐oxoglutarate decarboxylase bypass, the γ‐aminobutyrate shunt is a major contributor to flux from 2‐oxoglutarate and glutamate to succinate in Synechocystis sp. PCC 6803.     

Solution properties of γ‐crystallins: Compact structure and low frictional ratio are conserved properties of diverse γ‐crystallins

γ‐crystallins are highly specialized proteins of the vertebrate eye lens where they survive without turnover under high molecular crowding while maintaining transparency. They share a tightly folded structural template but there are striking differences among species. Their amino acid compositions are unusual. Even in mammals, γ‐crystallins have high contents of sulfur‐containing methionine and cysteine, but this reaches extremes in fish γM‐crystallins with up to 15% Met. In addition, fish γM‐crystallins do not conserve the paired tryptophan residues found in each domain in mammalian γ‐crystallins and in the related β‐crystallins. To gain insight into important, evolutionarily conserved properties and functionality of γ‐crystallins, zebrafish (Danio rerio) γM2b and γM7 were compared with mouse γS and human γD. For all four proteins, far UV CD spectra showed the expected β‐sheet secondary structure. Like the mammalian proteins, γM7 was highly soluble but γM2b was much less so. The heat and denaturant stability of both fish proteins was lower than either mammalian protein. The ability of full‐length and truncated versions of human αB‐crystallin to retard aggregation of the heat denatured proteins also showed differences. However, when solution behavior was investigated by sedimentation velocity experiments, the diverse γ‐crystallins showed remarkably similar hydrodynamic properties with low frictional ratios and partial specific volumes. The solution behavior of γ‐crystallins, with highly compact structures suited for the densely packed environment of the lens, seems to be highly conserved and appears largely independent of amino acid composition.     

Protein accumulation and rumen stability of wheat γ‐gliadin fusion proteins in tobacco and alfalfa

The nutritional value of various crops can be improved by engineering plants to produce high levels of proteins. For example, because methionine deficiency limits the protein quality of Medicago Sativa (alfalfa) forage, producing alfalfa plants that accumulate high levels of a methionine‐rich protein could increase the nutritional value of that crop. We used three strategies in designing methionine‐rich recombinant proteins that could accumulate to high levels in plants and thereby serve as candidates for improving the protein quality of alfalfa forage. In tobacco, two fusion proteins, γ‐gliadin‐δ‐zein and γ‐δ‐zein, as well as δ‐zein co‐expressed with β‐zein, all formed protein bodies. However, the γ‐gliadin‐δ‐zein fusion protein accumulated to the highest level, representing up to 1.5% of total soluble protein (TSP) in one transformant. In alfalfa, γ‐gliadin‐δ‐zein accumulated to 0.2% of TSP, and in an in vitro rumen digestion assay, γ‐gliadin‐δ‐zein was more resistant to microbial degradation than Rubisco. Additionally, although it did not form protein bodies, a γ‐gliadin‐GFP fusion protein accumulated to much higher levels, 7% of TSP, than a recombinant protein comprised of an ER localization signal fused to GFP in tobacco. Based on our results, we conclude that γ‐gliadin‐δ‐zein is a potential candidate protein to use for enhancing methionine levels in plants and for improving rumen stability of forage protein. γ‐gliadin fusion proteins may provide a general platform for increasing the accumulation of recombinant proteins in transgenic plants.     

Affinity pulldown of γ‐secretase and associated proteins from human and rat brain

γ‐Secretase is a transmembrane protease complex responsible for the processing of a multitude of type 1 transmembrane proteins, including amyloid precursor protein (APP) and Notch. A functional complex is dependent on the assembly of four proteins: presenilin (PS), nicastrin, Aph‐1 and Pen‐2. Little is known about how the substrates are selected by γ‐secretase, but it has been suggested that γ‐secretase associated proteins (GSAPs) could be of importance. For instance, it was recently reported from studies in cell lines that TMP21, a transmembrane protein involved in trafficking, binds to γ‐secretase and regulates the processing of APP‐derived substrates without affecting Notch cleavage. Here, we present an efficient and selective method for purification and analysis of γ‐secretase and GSAPs. Microsomal membranes were prepared from rat or human brain and incubated with a γ‐secretase inhibitor coupled to biotin via a long linker and a S‐S bridge. After pulldown using streptavidin beads, bound proteins were eluted under reducing conditions and digested by trypsin. The tryptic peptides were subjected to LC‐MS/MS analysis, and proteins were identified by sequence data from MS/MS spectra. All of the known γ‐secretase components were identified. Interestingly, TMP21 and the PS associated protein syntaxin1 were associated to γ‐secretase in rat brain. We suggest that the present method can be used for further studies on the composition of the γ‐secretase complex.     

Microbial production of conjugated γ‐linolenic acid from γ‐linolenic acid by Lactobacillus plantarum AKU 1009a

Aims: Optimal production conditions of conjugated γ‐linolenic acid (CGLA) from γ‐linolenic acid using washed cells of Lactobacillus plantarum AKU 1009a as catalysts were investigated. Methods and Results: Washed cells of Lact. plantarum AKU 1009a exhibiting a high level of CGLA productivity were obtained by cultivation in a nutrient medium supplemented with 0·03% (w/v) α‐linolenic acid as an inducer. Under the optimal reaction conditions with 13 mg ml^?1γ‐linolenic acid as a substrate in 5 ‐ml reaction volume, the washed cells [32% (wet cells, w/v) corresponding to 46 mg ml^?1 dry cells] as the catalysts produced 8·8 mg CGLA per millilitre reaction mixture (68% molar yield) in 27 h. The produced CGLA was a mixture of two isomers, i.e., cis‐6,cis‐9,trans‐11‐octadecatrienoic acid (CGLA1, 40% of total CGLA) and cis‐6,trans‐9,trans‐11‐octadecatrienoic acid (CGLA2, 60% of total CGLA), and accounted for 66% of total fatty acid obtained. The CGLA produced was obtained as free fatty acids adsorbed mostly on the surface of the cells of Lact. plantarum AKU1009a. Conclusion: The practical process of CGLA production from γ‐linolenic acid using washed cells of Lact. plantarum AKU 1009a was successfully established. Significance and Impact of the Study: We presented the first example of microbial production of CGLA. CGLA produced by the process is valuable for evaluating their physiological and nutritional effects, and chemical characteristics.     

Aph‐1 is required to regulate Presenilin‐mediated γ‐secretase activity and cell survival in Drosophila wing development

Aph‐1 is a multipass transmembrane protein and an essential component of the Presenilin (Psn)‐mediated γ‐secretase complex. During protease assembly, Aph‐1 stabilizes the newly synthesized Psn holoprotein to facilitate generation of the active form of Psn, which is a Psn‐NTF/Psn‐CTF heterodimer produced through a Presenilinase‐initiated endoproteolytic cleavage of the Psn holoprotein. Although it is clear that loss of Aph‐1 activity leads to failure of Psn heterodimer formation, little is understood about whether Aph‐1 plays a role in regulating γ‐secretase activity in addition to assisting Psn maturation. Using various modified Psn forms that do not require endoproteolysis or have a large deletion of the cytosolic loop, we show that in Drosophila Aph‐1 is still required for γ‐secretase activity independent of its role in promoting Psn endoproteolysis. In addition, our results indicate that Aph‐1 is required to promote cell survival in the wing imaginal disc; aph‐1 mutant cells are lost either through cell death or because of a defect in cell proliferation. This function of Aph‐1 is independent of its role in regulating γ‐secretase activity, but possibly involves downregulating the activity of uncleaved Psn holoprotein. genesis 47:169–174, 2009. © 2009 Wiley‐Liss, Inc.     

Fission yeast Pcp1 links polo kinase‐mediated mitotic entry to γ‐tubulin‐dependent spindle formation

The centrosomal pericentrin‐related proteins play pivotal roles in various aspects of cell division; however their underlying mechanisms remain largely elusive. Here we show that fission‐yeast pericentrin‐like Pcp1 regulates multiple functions of the spindle pole body (SPB) through recruiting two critical factors, the γ‐tubulin complex (γ‐TuC) and polo kinase (Plo1). We isolated two pcp1 mutants (pcp1‐15 and pcp1‐18) that display similar abnormal spindles, but with remarkably different molecular defects. Both mutants exhibit defective monopolar spindle microtubules that emanate from the mother SPB. However, while pcp1‐15 fails to localise the γ‐TuC to the mitotic SPB, pcp1‐18 is specifically defective in recruiting Plo1. Consistently Pcp1 forms a complex with both γ‐TuC and Plo1 in the cell. pcp1‐18 is further defective in the mitotic‐specific reorganisation of the nuclear envelope (NE), leading to impairment of SPB insertion into the NE. Moreover pcp1‐18, but not pcp1‐15, is rescued by overproducing nuclear pore components or advancing mitotic onset. The central role for Pcp1 in orchestrating these processes provides mechanistic insight into how the centrosome regulates multiple cellular pathways.     

γ‐Tubulin complex in Trypanosoma brucei: molecular composition,subunit interdependence and requirement for axonemal central pair protein assembly

γ‐Tubulin complex constitutes a key component of the microtubule‐organizing center and nucleates microtubule assembly. This complex differs in complexity in different organisms: the budding yeast contains the γ‐tubulin small complex (γTuSC) composed of γ‐tubulin, gamma‐tubulin complex protein (GCP)2 and GCP3, whereas animals contain the γ‐tubulin ring complex (γTuRC) composed of γTuSC and three additional proteins, GCP4, GCP5 and GCP6. In Trypanosoma brucei, the composition of the γ‐tubulin complex remains elusive, and it is not known whether it also regulates assembly of the subpellicular microtubules and the spindle microtubules. Here we report that the γ‐tubulin complex in T. brucei is composed of γ‐tubulin and three GCP proteins, GCP2‐GCP4, and is primarily localized in the basal body throughout the cell cycle. Depletion of GCP2 and GCP3, but not GCP4, disrupted the axonemal central pair microtubules, but not the subpellicular microtubules and the spindle microtubules. Furthermore, we showed that the γTuSC is required for assembly of two central pair proteins and that γTuSC subunits are mutually required for stability. Together, these results identified an unusual γ‐tubulin complex in T. brucei, uncovered an essential role of γTuSC in central pair protein assembly, and demonstrated the interdependence of individual γTuSC components for maintaining a stable complex.     

Manipulation of two α‐endo‐β‐1,4‐glucanase genes,AtCel6 and GmCel7, reduces susceptibility to Heterodera glycines in soybean roots

Plant endo‐β‐1,4‐glucanases (EGases) include cell wall‐modifying enzymes that are involved in nematode‐induced growth of syncytia (feeding structures) in nematode‐infected roots. EGases in the α‐ and β‐subfamilies contain signal peptides and are secreted, whereas those in the γ‐subfamily have a membrane‐anchoring domain and are not secreted. The Arabidopsis α‐EGase At1g48930, designated as AtCel6, is known to be down‐regulated by beet cyst nematode (Heterodera schachtii) in Arabidopsis roots, whereas another α‐EGase, AtCel2, is up‐regulated. Here, we report that the ectopic expression of AtCel6 in soybean roots reduces susceptibility to both soybean cyst nematode (SCN; Heterodera glycines) and root knot nematode (Meloidogyne incognita). Suppression of GmCel7, the soybean homologue of AtCel2, in soybean roots also reduces the susceptibility to SCN. In contrast, in studies on two γ‐EGases, both ectopic expression of AtKOR2 in soybean roots and suppression of the soybean homologue of AtKOR3 had no significant effect on SCN parasitism. Our results suggest that secreted α‐EGases are likely to be more useful than membrane‐bound γ‐EGases in the development of an SCN‐resistant soybean through gene manipulation. Furthermore, this study provides evidence that Arabidopsis shares molecular events of cyst nematode parasitism with soybean, and confirms the suitability of the Arabidopsis–H. schachtii interaction as a model for the soybean–H. glycines pathosystem.     

Opposite expression of securin and γ‐H2AX regulates baicalein‐induced cancer cell death

Securin and γ‐H2AX have been shown to regulate cell survival and genomic stability. However, it is still unknown how the expression and regulation of these proteins is altered following treatment with baicalein, a natural flavonoid extracted from the Scutellaria baicalensis root. In the present study, we investigate the possible roles of securin and γ‐H2AX in baicalein‐induced cancer cell death. Baicalein reduced cell viability in a variety of human cancer cell lines, including bladder, cervical, colon, and lung cancer cells. Interestingly, baicalein treatment (40–80 µM for 24 h) markedly inhibited securin expression, while the levels of γ‐H2AX were elevated. Abnormal spindle formation and chromosomal segregation were induced by baicalein. Furthermore, wild type HCT116 cancer cells had a higher incidence of cytotoxicity and apoptosis than securin‐null HCT116 cells following treatment with baicalein. In contrast, baicalein increased the levels of γ‐H2AX to a similar extent in both cell types. Transfection with H2AX siRNA further increased baicalein‐induced cell death. Additionally, blockade of the AKT pathway by treatment with wortmannin or AKT shRNA lowered the levels of γ‐H2AX and enhanced cytotoxicity in baicalein‐treated cells. Taken together, our findings suggest that the opposing effects of baicalein on securin and γ‐H2AX levels may be involved in the regulation of cell viability and genomic stability by this compound. J. Cell. Biochem. 111: 274–283, 2010. © 2010 Wiley‐Liss, Inc.     

Neuroprotective role of γ‐enolase in microglia in a mouse model of Alzheimer's disease is regulated by cathepsin X

γ‐Enolase is a neurotrophic‐like factor promoting growth, differentiation, survival and regeneration of neurons. Its neurotrophic activity is regulated by cysteine protease cathepsin X which cleaves the C‐terminal end of the molecule. We have investigated the expression and colocalization of γ‐enolase and cathepsin X in brains of Tg2576 mice overexpressing amyloid precursor protein. In situ hybridization of γ‐enolase and cathepsin X revealed that mRNAs for both enzymes were expressed abundantly around amyloid plaques. Immunostaining demonstrated that the C‐terminally cleaved form of γ‐enolase was present in the immediate plaque vicinity, whereas the intact form, exhibiting neurotrophic activity, was observed in microglia cells in close proximity to senile plaque. The upregulation of γ‐enolase in microglial cells in response to amyloid‐β peptide (Aβ) was confirmed in mouse microglial cell line EOC 13.31 and primary microglia and medium enriched with γ‐enolase proved to be neuroprotective against Aβ toxicity; however, the effect was reversed by cathepsin X proteolytic activity. These results demonstrate an upregulation of γ‐enolase in microglia cells surrounding amyloid plaques in Tg2576 transgenic mice and demonstrate its neuroprotective role in amyloid‐β‐related neurodegeneration.