Differential Expression of Multiple Transglutaminases in Human Brain

The transglutaminase (TGase) family of enzymes, of which seven different members are known in the human genome, participate in many biological processes involving cross-linking proteins into large macromolecular assemblies. The TGase 2 enzyme is known to be present in neuronal tissues and may play a role in neuronal degenerative diseases such as Alzheimer's disease (AD) by aberrantly cross-linking proteins. In this paper, we demonstrate by reverse transcriptase-polymerase chain reaction and immunological methods with specific antibodies that in fact three members, the TGase 1, TGase 2, and TGase 3 enzymes, and are differentially expressed in various regions of normal human brain tissues. Interestingly, the TGase 1 and 3 enzymes and their proteolytically processed forms are involved in terminal differentiation programs of epithelial cell development and barrier function. In addition, we found that the levels of expression and activity of the TGase 1 and 2 enzymes were both increased in the cortex and cerebellum of AD patients. Furthermore, whereas normal brain tissues contain ≈1 residue of cross-link/10,000 residues, AD patient cortex and cerebellum tissues contain 30–50 residues of cross-link/10,000 residues. Together, these findings suggest that multiple TGase enzymes are involved in normal neuronal structure and function, but their elevated expression and cross-linking activity may also contribute to neuronal degenerative disease.

A number of reports have described the presence of TGase activity in regional and subcellular tissue locations and the presence of TGase substrates in the nervous system (17)(18)(19)(20)(21). In the peripheral nervous system, TGase activity was reported in sympathetic postganglionic motor neurons (18) and activity was increased in sheath cells in the distal portion of peripheral nerves following nerve injury (22). However, the nature of the TGase enzyme was not characterized. In the adult human central nervous system, only the TGase 2 enzyme has been identified by immunohistochemical studies (19). In neurons of both the peripheral and central nervous systems, several different bands of TGase were observed (21). Interestingly, in one set of experiments, about half of the TGase activity of mammalian brain homogenates was measured in the soluble (cytosolic) fraction, and the remainder was presumably associated with the membrane fraction (17). Furthermore, TGase activities with different biochemical characteristics were reported in sympathetic postganglionic motorneurons of the rat peripheral nervous system (23) and in the adult human central nervous system (24) although the nature of the TGase(s) was not identified.
One possible explanation for these various findings is that there may be multiple different TGases in the neuronal system. In this study, examination of TGase expression in human brain tissue has revealed expression of not only TGase 2 but also of TGases 1 and 3 which are commonly found in stratified squamous epithelia (24). The functional role of TGases in the normal brain is not yet clear, but reports have documented that TGases may be involved in senile plaque formation in Alzheimer's disease (AD) (24, 26 -29). We extend an earlier report (29) to show that the levels of both TGases 1 and 2 are changed and increased in various parts of the brain in AD disease concomitant with significant levels of isopeptide cross-link formed by these enzymes.

MATERIALS AND METHODS
Tissue Preparation-Normal human brain tissue segments (autopsy samples of healthy male subjects dead by accidents) from cerebral cortex, amygdala, and corpus callosum were obtained from Chungnam National University Hospital, Korea. For comparative studies of TGase expression between normal and AD brain tissues, several tissue specimens of frontal lobe and cerebellum of normal age matched (80 -81 years old, post-mortem time 10.5-12.7 h) individuals, and of AD patients (64 -71 years old, post-mortem time 9.4 -11.7 h), were obtained from Dr. Daniel Brady, National Institute of Aging.
The frozen brain specimens were homogenized using a Teflon pestle * The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. with 0.1 M Tris acetate (pH 7.5), 1 mM EDTA, containing protease inhibitors (5 g/ml leupeptin, 5 g/ml aprotinin, 50 g/ml calpain inhibitor I, 100 g/ml bestatin, and 1 mM phenylmethylsulfonyl fluoride). The homogenates were centrifuged at 10,000 ϫ g for 30 min at 4°C. The supernatant was used for the soluble (cytosolic) fraction. The pellet containing the membrane fraction was extracted with the same buffer as above containing 1% Triton X-100 for 10 min at room temperature, and pelleted again. This procedure released the membranebound TGase activity into the supernatant. No further TGase activity could be detected following a second treatment and centrifugation. Both the cytosolic and membrane-bound fractions were used for TGase activity assays and immunoslot blotting assays with TGase 1, 2, and 3 antibodies. To prepare total RNA for RT-PCR, control and AD brain tissues were homogenized directly in a glass tube using a Polytron homogenizer by adding TRIZOL reagent (100 mg/ml) (Life Technologies, Inc., Gaithersburg, MD) using the manufacturer's instructions.
Immunohistochemical Labeling-Immunohistochemical staining of normal brain tissue was performed with avidin/biotin complex (ABC) using the Vectastatin elite kit (Vector Laboratories, Burlingame, CA). Formalin-fixed, paraffin-embedded tissue blocks were selected for immunohistochemical staining as follows: after 3-4-m sections were deparaffinized in xylene, hydrated in descending grades of ethanol, then washed in distilled water, the sections were placed in glass jars filled with Tris-HCl (pH 7.6) buffer and processed 10 min at room temperature. They were then treated with 0.6% hydrogen peroxide for 15 min, and incubated sequentially, first with the antibodies against TGases 1, 2, or 3 for 60 min, second with biotinylated link antibody for 30 min, and finally with streptavidin labeled with peroxidase for 30 min. A Mayer hematoxylin counterstain was used to localize nuclei. Immunohistochemical staining of AD brain tissues was performed with frozen sections (10 m) of AD and age-matched normal control cerebel-lae by established methods (34). Monoclonal antibodies of anti-neurofilament heavy chain 160 kDa and anti-glial fibrillary acidic protein were purchased from Roche Molecular Biochemicals, Indianapolis, IN. The three specific affinity purified TGase antibodies used were: 1) polyclonal anti-human TGase 1 made in goats (25) (dilution 1:200); 2) polyclonal anti-human TGase 2 made in rabbits (dilution 1:400); and 3) polyclonal anti-human TGase 3 made in rabbits (dilution 1:200). In addition, specific polyclonal antibodies were elicited against bacterially expressed forms of the C-terminal regions of human TGase 2 (residues 523-687) and human TGase 3 (residues 470 -692). The specificities were confirmed by immunoprecipitation and Western blotting (data not shown). Human TGase 1, 2, and 3 proteins expressed in bacteria (35,36,38) were used to block the action of the TGase antibodies as negative controls.
Immunoslot Blotting-To obtain ranges suitable for accurate quantitation by the PhosphorImager, the cytosolic and membrane-bound fractions of neuronal tissue extracts were serially diluted in the range of 25 g to 1.5 g, and were applied into slot chambers followed by twice washing with Tris-buffered saline. Western blotting was performed as established previously (37). The concentrations of antibodies were 5 g/ml for primary antibodies and 0.1 g/ml for secondary antibodies. The blots were then developed by an enhanced chemiluminescence method (Pierce), and exposed for quantitation.
Isolation and Quantitation of Isopeptide Cross-link-Several frozen tissue sections (20 m thickness) were extracted in a solution containing 2% (w/v) SDS and 1% dithiothreitol and boiled vigorously for 10 min. Insoluble proteins were sedimented at 13,500 ϫ g for 5 min. These pellets were extracted three more times (38,39). Samples were then subjected to total enzymic hydrolysis to release the intact N ⑀ -(␥-glutamyl)lysine isopeptide cross-link, which was resolved and quantitated by amino acid analysis (38). As the amount in normal brain tissues was very low, in some experiments, we digested the entire tissue section instead.

RESULTS
We have examined the distribution of mRNA and expressed protein of the several known TGase gene products in four different tissue regions of human brain: amygdala, cerebellum, corpus callosum, and cortex.
Identification of TGase 1, 2, and 3 mRNAs in Normal Human Brain by RT-PCR-We used specific PCR primer sets to test for the presence of mRNAs for each of the seven known human TGase enzymes in these tissues. Human ␤-actin was employed as a control (Fig. 1). After 35 cycles of RT-PCR, we obtained PCR products for only the TGase 1 (361 base pairs), TGase 2 (310 base pairs), and TGase 3 (225 base pairs) mRNA tran-FIG. 1. Differential expression of TGase 1, 2, and 3 mRNAs in normal human brain. RT-PCR of TGase 1, 2, and 3 showed different expression levels in the three different parts of brain. TGase 1 was abundant in corpus callosum, TGase 2 was ubiquitous, and TGase 3 was expressed highly in amygdala. The results of RT-PCR showed the amount of product per 0.1 g of mRNA after 35 cycles except ␤-actin, 25 cycles. The products were run on 2% agarose gel and stained with ethidium bromide. Product size is shown on the right as base pairs. These data are representative of tissues from eight normal individuals. scripts ( Fig. 1): TGase 4, band 4.2, factor XIIIa, and TGase X mRNAs were not detected (data not shown). Interestingly, the amount of the three TGase transcripts varied in the different parts of the brain: the expression of TGase 1 was five times higher in the corpus callosum and cerebellum (data not shown) than in the other parts tested; the expression of TGase 3 was more than 10 times higher in the amygdala; but expression of TGase 2 was essentially the same in all tissues tested (Fig. 1). We were unable to confirm an earlier report of factor XIIIa expression in brain tissues (2).
Immunohistochemical Localization of TGase 1, 2, and 3 Enzymes in Normal Adult Human Brain-We performed immunohistochemical staining of the four different parts of normal adult human brain including amygdala (Fig. 2, A-C), cerebral cortex ( Fig. 2, D, E, F, J, K, and L), corpus callosum (Fig. 2, G-I), and cerebellum (data not shown) with specific antibodies for the TGase 1 (Fig. 2, A, D, and G), 2 ( Fig. 2, B, E, and H), and 3 ( Fig. 2, C, F, and I) enzymes. Staining of the tissue sections with preimmune sera showed no cross-reactivity (Fig. 2L for TGase 1). In the amygdala, TGase 3 was highly expressed in the cytoplasm of pyramidal cells (Fig. 2C), whereas a much weaker diffuse staining was seen in the pyramidal cells by TGases 1 (Fig. 2A) and 2 (Fig. 2B). In the cerebral cortex and cerebellum (data not shown), TGases 1 and 2 stained the cytoplasm and dendritic processes of pyramidal cells in the gray matter (Fig. 2, D and E), but TGase 3 was not detectable (Fig.  2F). In the corpus callosum, staining for TGase 1 (Fig. 2G) was notably stronger than for TGases 2 and 3 (Fig. 2, H and I), although the staining of TGases 2 and 3 was somewhat stronger in the corpus callosum than the cerebral cortex (Fig. 2, H  and I). In controls in cortex tissue, we used a specific antibody for the intermediate filament glial fibrillary acidic protein, which stained only glial cells (Fig. 2J), and an antibody for the intermediate filament neurofilament heavy chain, which stained only axons (Fig. 2K). Although these data indicate that TGase expression in neuronal cells is restricted to the cell bodies, we cannot rigorously exclude the possibility of expression and localization in the axons. Similarly, our data show that TGase expression is very low or undetectable in glial cells and astrocytes, although one earlier report has described the presence of TGase 2 in cultured rat astrocytes (40). Together, these observations correlate well with the RT-PCR data of Fig.   FIG. 2. Immunohistochemical study of TGase 1, 2, and 3 enzymes in the normal human brain with specific antibodies. The series of sections of normal human brain were: amygdala 1, and afford robust evidence for the expression of these three members of the TGase enzyme family in human brain tissues.
Elevated Expression of Especially TGase 1 in AD Brain Tissues-Next, we studied TGase expression in cerebellum and cerebral cortex tissues from normal and AD patients. Semiquantitative RT-PCR was used to estimate the amounts of mRNAs for these TGases: in order to ensure a linear relationship between the amount of PCR product and amount of total RNA, we used 20 cycles for ␤-actin and TGase 2, 27 cycles for TGase 1, and 35 cycles for TGase 3. The amounts were standardized with respect to the amount of ␤-actin mRNA. In both normal tissues, the amount of TGase 2 mRNA was severalfold higher than for TGase 1, but the amount for TGase 3 was too low to be statistically significant (Fig. 3). Notably, there was a 70% increase in the amount of TGase 1 mRNA in the cerebellum of six AD patients tested, but it was unchanged in the cortex of eight patients, including the same six. Likewise, there was a 65-75% increase in the amount of TGase 2 mRNA in both tissues of AD patients. These results for TGase 2 are generally similar to those of Johnson (29).
We then examined the subcellular localization of the TGase activity, since the foregoing data lack the resolution to determine whether the TGases are cytosolic or membrane-bound. Fig. 4 shows that about 20% of the total enzymic activity in control cortex and cerebellum resided in the membrane fraction, and was increased about 2-fold in the cerebellum tissue of the AD patients. The majority of the TGase activity resided in the cytosolic fraction, and was increased about 3-fold in the cerebellum of AD patients. Both sets of data are consistent with Fig. 3.
To confirm the identity of these activities, we performed Western slot blotting experiments using specific anti-TGase 1 and 2 antibodies in cortex (Fig. 5A) and cerebellum (Fig. 5B) tissues of post-mortem time-matched normal and AD individuals. Total data from three matched pairs (cortex) or five pairs (cerebellum) were quantitated by scanning densitometry and are summarized in Table I. (Comparable data for the TGase 3 enzyme were not possible because the expression levels were too low.) First, we were unable to detect measurable amounts of TGase 2 antigen in the membrane fractions in either tissue. Second, in the cortex, TGase 1 levels of both the membrane and cytosolic fractions were increased manyfold in AD in comparison to normal controls, whereas TGase 2 levels were increased only about 2-fold in the cytosolic fraction. Third, while there were only modest increases of TGase 1 and 2 levels in the cytosolic fraction of the cerebellum of AD tissues, there was a 10-fold increase of TGase 1 in the membrane fraction. We FIG. 4. TGase activity in the normal and AD brain tissues. The TGase activity in the membrane fraction was about 20% of the total, and was due to the TGase 1 enzyme, whereas the 80% of activity in the cytosol was due to both the TGase 1 and 2 enzymes (see Fig. 5 and Table  I). Both the cytosolic and membrane-bound TGase activities from AD cerebellum tissue were about 2.5-fold increased over the matched normal control. These data are the averages Ϯ S.D. from seven normal individuals as well as tissues from the same six AD patients. Ct, normal brain; AD, Alzheimer's disease brain.
FIG. 5. The relative amounts of TGase 1 and 2 enzymes and their distribution. Slot Western blotting was performed with the serial diluted samples (25 to 1.5 g) of cytosolic and membrane fractions from cortex (A) and cerebellum (B). There were only trace amounts of the TGase 2 enzyme in the membrane fraction. There was about 5-fold more TGase 1 in the membrane fraction, and about 2-fold more TGase 2, in the cortex compared with the cerebellum. TGase 2 was increased about two times both in A and B. The data shown are representative of one normal and one AD patient. Ct, normal brain; AD, Alzheimer's disease brain.

FIG. 3. Elevated expression of TGases in AD brain cortex and cerebellum tissues.
RT-PCR products were quantitated by Phospho-rImager analyses following [ 32 P]dCTP labeling. TGase 1 was increased about 70% in the cerebellum of AD. TGase 2 was increased 65-75% in both the cortex and cerebellum of AD. TGase 3 levels were too low to be quantifiable. These data are the averages Ϯ S.D. from eight normal individuals as well as tissues from the same six AD patients. Ct, normal brain; AD, Alzheimer's disease brain.
cannot rigorously exclude the possibility that these differences, especially the TGase 1 levels in AD tissue, are due to delays in postmortem sample processing, but this seems unlikely since the samples were carefully matched.
Immunohistochemical staining of cerebellum tissue using anti-TGase 1 (Fig. 6, A and B) and anti-TGase 2 (Fig. 6, C and  D) antibodies consistently showed that TGase 1 and 2 were more strongly positive in cerebellum and cortex (not shown) tissues of AD patients (Fig. 6, B and D) than in the normal controls (Fig. 6, A and C). Interestingly, TGase 1 showed cell peripheral and cytoplasmic staining while TGase 2 showed generalized cytoplasmic staining. In addition, TGase 1 staining in AD tissue showed unusual protein tangles (UT), and TGase 2 showed unusual protein fibrils (UF). Similar data were obtained in several other tissue samples.
Isolation of Isopeptide Cross-link from High Molecular Weight Proteins Recovered from AD Tissues-Finally, we wanted to know whether the increased expression of TGases and TGase activities contributed to the formation of crosslinked protein material. Isopeptide cross-link amounts were measured in two ways. First, total enzymic digestion of intact tissue sections revealed Ϸ1 residue of cross-link/10,000 residues in normal cerebellum or cortex tissues sections, but much larger amounts in tissue sections from AD patients. To quantitate this more accurately, tissue sections were exhaustively boiled in buffer containing SDS and reducing reagents. Whereas we were able to isolate only traces of insoluble proteins from cerebellum and cortex tissues of normal individuals (yields Ͻ1 g/mg of total protein), we recovered 35 Ϯ 15 and 75 Ϯ 20 g/mg of insoluble proteins from these two tissues of AD specimens, respectively. Following total enzymic hydrolysis these insoluble proteins contained 2 residues of cross-link/ 10,000 residues in normal tissues, but 30 and 50 residues/ 10,000, respectively, in the two AD tissues. By way of analogy, we have found 80 -100 residues/10,000 residues in skin specimens (38,39).

Multiplicity of TGase Activity in the Nervous System-The
purpose of the present experiments has been to identify the enzyme(s) which are responsible for the TGase activity in brain. We have provided robust evidence for the presence of multiple functional TGases in brain tissues. Of these, the TGase 2 enzyme was the most abundant (Fig. 5), as expected from several earlier studies, but significant amounts of the TGase 1 and lesser amounts of the TGase 3 enzyme are also present. Furthermore, we have provided evidence of differential expression of these TGase enzymes in different regions of the brain (Figs. 1-5).
The TGase 1 and 3 Enzymes-These two enzymes are abundantly expressed in terminally differentiating stratified squamous epithelia in response to elevated Ca 2ϩ levels, and play important roles in barrier function by cross-linking structural proteins. Major aspects of their biochemical properties and substrate proclivities are now well understood (12)(13)(14)(15)(16). The Ϸ77-kDa TGase 3 enzyme is typically located in the cytosol but is proteolytically processed during Ca 2ϩ -induced terminal differentiation into a functional 50/27-kDa complex (33,41). Most of the TGase 1 in epithelial cells exists as a Ϸ100-kDa membrane-bound protein of very low specific activity, but during terminal differentiation, some may be activated by proteolytic processing into a 67/33/10-kDa form of very high specific activity, and some intact low specific activity or higher specific activity processed forms are released into the cytosol (37,42). Thus cytosolic or membrane fractions of epithelial cells may hold large amounts of TGase 1 protein of either low or high activity depending on the degree of proteolytic activation. In contrast, however, the TGase 2 enzyme is destroyed by proteolysis (reviewed in Refs. 1-4). Thus proteolytic activation of TGase 1 can cause major changes in total TGase activity in

TABLE I
Both transglutaminases 1 and 2 are increased in AD brain tissues These data are the averages Ϯ S.D. from eight normal individuals as well as tissues from the same six AD patients and on a range of x-ray film exposures after the enhanced chemiluminescence reaction. 0 means that it could not be detected. C, normal tissue; AD, tissue from Alzheimer patient; membrane, means membrane fraction. TGase 1  TGase 2  TGase 1  TGase 2 Cytosol

Frontal cortex Cerebellum
cells. With this background, it is to be expected that substantial increases in total TGase activity could occur in normal or abnormal neuronal cells as a result of proteolytic activation of TGases 1 and/or 3. Complexity of Brain TGases-Previous reports have described the complexity of brain TGases in terms of molecular size (67-100 kDa) (21,43) and biochemical properties (17,24), Furthermore, there is evidence that TGase activities reside in cytosolic and/or membrane compartments (22), and that membrane-associated brain TGases contain latent activity which can be activated with thiol reagents, thrombin, proteases, and physical agents (high salt, glycerol etc.) (21,43). In another study, a significant degree of cross-linking of endogenous protein substrates occurred in synaptic membranes (44). There is evidence from studies of isolated superior cervical and nodose ganglia that intracellular TGase activities can be induced and rapidly activated by treatments including varatridine, high extracellular potassium (45), and acetylcholine (46). These agents result directly in an influx of Ca 2ϩ . Such induction and rapid activation phenomena may occur by both protein synthesisdependent and -independent mechanisms. Thus while unambiguous evidence has existed for some time on the presence of the TGase 2 enzyme (17,21,28,29), it is somewhat difficult to reconcile these reported complexities with the known properties of the TGase 2 enzyme. Our new data reveal that there is significant TGase 1 and 3 activity in brain tissues. Indeed, many of the known properties of the cytosolic and membraneassociated forms of the TGase 1 and 3 enzymes and their activation in vivo concord well with these various reports on the complexity of TGases in brain tissues.
A recent report has documented the presence of a novel cytosolic TGase 2-like enzyme in cultured rat astrocytes (40) but we could not identify its mRNA in adult human brain tissues (data not shown). Furthermore, in contrast to our present work, previous studies have documented the presence of the factor XIIIa enzyme in brain tissues (2), but we think this may be due to contamination from residual blood in the specimens tested.
Distribution of TGases 1, 2, and 3 in Normal Adult Human Brain-We found that the mRNA and protein for TGase 2 were abundantly expressed in each of the four tissue types studied here. This is to be expected from many published reports and since it is an essential housekeeping protein involved both in GTP-mediated receptor binding (47) and cross-linking when intracellular Ca 2ϩ levels rise (1, 2). The TGase 3 enzyme was expressed to a minor extent in all tissues tested, but more significantly in the amygdala (Fig. 2). Substantial expression of TGase 1 mRNA was observed in normal cerebellum and corpus callosum where it represented 20 -25% of the total (Fig. 3). Unlike epithelial tissues where most TGase 1 is membrane bound, however, we found in these brain tissues that only about 20% of the total TGase activity was associated with membranes from the cortex and cerebellum (Fig. 4), all of which was due to the TGase 1 protein (Fig. 5). Thus up to 80% of the TGase 1 enzyme was present in the cytosolic fraction. Because of its relatively low activity levels (41) (Fig. 4), this means that much of it remained in its intact low specific activity (unprocessed) form. Accordingly, future studies should focus on the biochemical properties of the TGase 1 enzyme and its complex processed forms in brain tissues.
To address the issue as to whether the TGase 1, 2, and 3 enzymes are in fact functional in brain tissues, we isolated and quantitated the isopeptide cross-link formed by these enzymes. Using total tissue sections, we recovered only traces of the cross-link from normal cortex and cerebellum (Ϸ1 residue/ 10,000 residues). This amount is similar to that found in a variety of normal tissues such as liver and muscle (1)(2)(3)(4). However, further work will be necessary to identify the natural substrates of the TGases in normal brain tissues.
Analysis of TGase Expression and Function in AD-However, in AD cortex and cerebellum tissues, we found 30 -50-fold larger amounts of the cross-link, and reflecting this large increase, we were able to isolate highly insoluble proteins following exhaustive extraction in SDS-dithiothreitol solutions. To the best of our knowledge, this is the first report of the direct isolation of the cross-link from AD patient material. Proteins cross-linked to this extent in in vitro assays form large insoluble macromolecular aggregates (1), and insoluble aggregates formed in natural processes such as apoptosis are toxic for cells (4,6,48). By extrapolation therefore, it is to be expected that such insoluble protein inclusions could contribute to progressive neurodegenerative disease.
Accordingly, in view of the foregoing discussion, a new set of questions arises as to how these enzymes become problematic in AD disease. In this regard, it is known that expression of proteases including calpains are increased abnormally in AD disease (49 -51). Although the detailed molecular events involved in proteolytic activation of TGases 1 or 3 in epithelia are not yet known, we have observed in calcium-dependent differentiation of normal human epidermal keratinocytes that calpain may process TGase 1 into the high specific activity forms and that calpain inhibitors interfere with this process (52). Thus the marked increases of TGase activity in both the cytosol and membrane fractions of especially the cerebellum tissue observed here (Fig. 4), raise the possibility that the TGase 1 (and 3) enzymes may be proteolytically activated abnormally in AD disease. However, it is less clear why similar changes were not also observed in cortex tissue (Fig. 4), although the simplest explanation at this time is that there are variable degrees of proteolytic activation. Finally, amyloid deposits, neurofibrillary tangles, and accumulations of insoluble paired helical filaments are also features of amygdala tissue in AD disease (53), but we were unable to acquire this tissue to explore the potential role of the TGase 3 enzyme.
Generally similar data for the TGase 2 enzyme in normal and AD brain tissues have been reported earlier (29). However, in contrast to our study, they noted modest increases of TGase 2 protein and activity in the cortex but little change in the cerebellum between normal and AD patients. As they examined only the cytosolic fraction, such differences in the two studies may be due in part to the presence of significant amounts of TGase 1 enzyme activity in the cytosolic fraction as well. Another possibility is that minor variations in the postmortem time of the tissues collected may potentially result in proteolytic activation of the cytosolic TGase 1 enzyme but loss of some TGase 2 enzyme.
Conclusion-A recent report has suggested that the primary cause of Huntington's disease may be TGase-induced crosslinking/polymerization of the protein Huntingtin which has an abnormally expanded polyglutamine tract (54), and furthermore, this polymerization could be inhibited by the TGase inhibitors. These data suggest that TGases may be involved in the downstream events of neuronal degenerative diseases such as Huntington's disease and AD. In this study, we have demonstrated that not only the TGase 2 but also the TGases 1 and 3 enzymes are present and differentially expressed in normal adult human brain tissues. Furthermore, we show that the TGase 1 and 2 enzymes are significantly up-regulated in AD disease. Moreover, the direct isolation and quantitation of the isopeptide cross-link from insoluble protein inclusions from AD tissues affords a robust causal relationship between aberrantly increased TGase activity and disease. Further studies of these