Overproduction of perlecan core protein in cultured cells and transgenic mice.

Heparan sulphate proteoglycan (HSPG) and amyloid P component are the only macromolecules consistently associated with all varieties of amyloid, irrespective of the type of amyloid protein, suggesting that HSPG may play a pathogenetic role in amyloid formation through a common mechanism. In the case of Alzheimer's disease (AD), HSPG, such as perlecan, co-accumulates with amyloid-beta protein (Abeta), a main constituent of amyloid plaques, and paired helical filaments (PHFs). Additionally, in vitro, HSPG accelerates both Abeta fibril and PHF formation and protects Abeta from degradation. Therefore, this study first established lines of P19 mouse embryonic carcinoma cells stably carrying an expression vector encoding the complete perlecan core protein (approximately 400 kD). In the cell lysates, overexpressed perlecan was identified as an approximately 400 kD protein without glycosaminoglycan side-chains, while in the media, secreted perlecan was mostly glycosylated, suggesting that the secretion and glycosylation of perlecan are coupled. Next, transgenic mice were produced using the same expression vector. Marked perlecan overexpression occurred in the cytoplasm of multiple tissues including the brain, heart, kidney, and pancreas, without a discernible increase of perlecan in extracellular matrices. The transgenic mice up to 18 months of age did not develop amyloid or AD-like pathology in the brain or elsewhere, based on histochemical and immunohistochemical analyses. Thus, overproduction of perlecan core protein is insufficient to lead to amyloidosis and AD-like pathology.

Laminin inhibition of beta-amyloid protein (Abeta) fibrillogenesis and identification of an Abeta binding site localized to the globular domain repeats on the laminin a chain.

beta-Amyloid protein (Abeta) is a major component of neuritic plaques and cerebrovascular amyloid deposits in the brains of patients with Alzheimer's disease (AD). Inhibitors of Abeta fibrillogenesis are currently sought as potential future therapeutics for AD and related disorders. In the present study, the basement membrane protein laminin was found to bind Abeta 1-40 with a single dissociation constant, K(d) = 2.7 x 10(-9) M, and serve as a potent inhibitor of Abeta fibril formation. 25 microM of Abeta 1-40 was incubated at 37 degrees C for 1 week in the presence of 100 nM of laminin or other basement membrane components, including perlecan, type IV collagen, and fibronectin to determine their effects on Abeta fibril formation as evaluated by thioflavin T fluorometry. Of all the basement membrane components tested, laminin demonstrated the greatest inhibitory effect on Abeta-amyloid fibril formation, causing a ninefold inhibition at 1 and 3 days and a 21-fold inhibition at 1 week. The inhibitory effects of laminin on Abeta fibrillogenesis occurred in a dose-dependent manner and were still effective at lower concentrations. The inhibitory effects of laminin on Abeta 1-40 fibril formation was confirmed by negative stain electron microscopy, whereby laminin caused an almost complete inhibition of Abeta fibril formation and assembly by 3 days, resulting in the appearance of primarily amorphous nonfibrillar material. Laminin also caused partial disassembly of preformed Abeta-amyloid fibrils following 4 days of coincubation. Laminin was not effective as an inhibitor of islet amyloid polypeptide fibril formation, suggesting that laminin's amyloid inhibitory effects were Abeta-specific. To identify a potential Abeta-binding site(s) on laminin, laminin was first digested with V8, trypsin, or elastase. An Abeta-binding elastase digestion product of approximately 120-130 kDa was found. In addition, a approximately 55 kDa fragment derived from V8 and elastase-digested laminin interacted with biotinylated Abeta 1-40. Amino acid sequencing of the approximately 55 kDa fragment identified a conformationally dependent Abeta-binding site within laminin localized to the globular repeats on the laminin A chain. These studies demonstrate that laminin not only binds Abeta with relatively high affinity but is a potent inhibitor of Abeta-amyloid fibril formation. In addition, further identification of an Abeta-binding domain within the globular repeats on the laminin A chain may lead to the design of new therapeutics for the inhibition of Abeta fibrillogenesis.

The sulfate moieties of glycosaminoglycans are critical for the enhancement of beta-amyloid protein fibril formation.

Our previous studies have demonstrated that perlecan and perlecan-derived glycosaminoglycans (GAGs) not only bind beta-amyloid protein (Abeta) 1-40 and 1-42, but are also potent enhancers of Abeta fibril formation and stabilize amyloid fibrils once formed. However, it was not determined which moieties in perlecan heparan sulfate GAG chains may be responsible for the observed effects and whether other GAGs were also capable of a similar enhancement of Abeta fibril formation as observed with perlecan GAGs. In the present study, thioflavin T fluorometry (over a 1-week period) was used to extend our previous studies and to test the hypothesis that the sulfate moiety is critical for the enhancing effects of heparin/heparan sulfate GAGs on Abeta 1-40 fibrillogenesis. This hypothesis was confirmed when removal of all sulfates from heparin (i.e., completely desulfated N-acetylated heparin) led to a complete loss in the enhancement of Abeta fibrillogenesis as demonstrated in both thioflavin T fluorometry and Congo red staining studies. On the other hand, removal of O-sulfate from heparin (i.e., completely desulfated N-sulfated heparin), and to a lesser extent N-sulfate (i.e., N-desulfated N-acetylated heparin), resulted in only a partial loss of the enhancement of Abeta 1-40 fibril formation. These studies indicate that the sulfate moieties of GAGs are critical for enhancement of Abeta amyloid fibril formation. In addition, other sulfated molecules such as chondroitin-4-sulfate, dermatan sulfate, dextran sulfate, and pentosan polysulfate all significantly enhanced (greater than twofold by 3 days) Abeta amyloid fibril formation. These latter findings indicate that deposition and accumulation of other GAGs at sites of Abeta amyloid deposition in Alzheimer's disease brain may also participate in the enhancement of Abeta amyloidosis.

Sulfate content and specific glycosaminoglycan backbone of perlecan are critical for perlecan's enhancement of islet amyloid polypeptide (amylin) fibril formation.

Islet amyloidosis is characterized by the deposition and accumulation of amylin in pancreatic beta-cells and is observed in 90% of patients with type 2 diabetes. Previous studies have also revealed the presence of the specific heparan sulfate proteoglycan, perlecan, colocalized to islet amyloid deposits, similar to perlecan's known involvement with other amyloid proteins. In the present study, perlecan purified from the Engelbreth-Holm-Swarm (EHS) tumor was used to define perlecan's interactions with amylin (i.e., islet amyloid polypeptide) and its effects on amylin fibril formation. Using a solid phase-binding immunoassay, human amylin, but not rat amylin, bound immobilized EHS perlecan with a single dissociation constant (Kd) = 2.75 x 10(-6) mol/l. The binding of human amylin to perlecan was similarly observed using perlecan heparan sulfate glycosaminoglycans (GAGs), and was completely abolished by 10 micromol/l heparin. Using thioflavin T fluorometry, Congo red staining, and electron microscopy methodology, intact perlecan was found to enhance amylin fibril formation in a dosage-dependent manner, with the majority of these effects attributed to the heparan sulfate GAG chains of perlecan. Other sulfated GAGs and related macromolecules were also effective in the enhancement of amylin fibril formation in the order of heparin > heparan sulfate > chondroitin-4-sulfate = dermatan sulfate = dextran sulfate > pentosan polysulfate, implicating the importance of the specific GAG/carbohydrate backbone. The sulfate content of heparin/heparan sulfate was also important for the enhancement of amylin fibril formation in the order of heparin > N-desulfated N-acetylated heparin > completely desulfated N-sulfated heparin > completely desulfated N-acetylated heparin. These studies suggest that the enhancement effects of perlecan on amylin fibril formation are mediated primarily by both specific GAG chain backbone and GAG sulfate content, and implicate perlecan as an important macromolecule that is likely involved in the pathogenesis of islet amyloidosis.

Perlecan binds to the beta-amyloid proteins (A beta) of Alzheimer's disease, accelerates A beta fibril formation, and maintains A beta fibril stability.

Perlecan is a specific heparan sulfate proteoglycan that accumulates in the fibrillar beta-amyloid (A beta) deposits of Alzheimer's disease. Perlecan purified from the Engelbreth-Holm-Swarm tumor was used to define perlecan's interactions with A beta and its effects on A beta fibril formation. Using a solid-phase binding immunoassay, freshly solubilized full-length A beta peptides bound immobilized perlecan at two sites, representing both high-affinity [K(D) = approximately 5.8 x 10(-11) M for A beta (1-40); K(D) = approximately 6.5 x 10(-12) M for A beta (1-42)] and lower-affinity [K(D) = 3.5 x 10(-8) M for A beta (1-40); K(D) = 4.3 x 10(-8) M for A beta (1-42)] interactions. An increase in the binding capacity of A beta (1-40) to perlecan correlated with an increase in A beta amyloid fibril formation during a 1-week incubation period. The high-capacity binding of A beta (1-40) to perlecan was similarly observed using perlecan heparan sulfate glycosaminoglycans and was completely abolished by heparin, but not by chondroitin-4-sulfate. Using a thioflavin T fluorometry assay, perlecan accelerated the rate of A beta (1-40) amyloid fibril formation, causing a significant increase in A beta fibril assembly over a 2-week incubation period at 1 h (2.8-fold increase), 1 day (3.6-fold increase), and 3 days (2.8-fold increase) in comparison with A beta (1-40) alone. Perlecan also initially accelerated the formation of A beta (1-42) fibrils within 1 h and maintained significantly higher levels of A beta (1-42) thioflavin T fluorescence throughout a 2-week experimental period in comparison with A beta (1-42) alone, suggesting perlecan's ability to maintain amyloid fibril stability. Perlecan's effects on A beta (1-40) fibril formation and maintenance of A beta (1-42) fibril stability occurred in a dose-dependent manner and was also mediated primarily by perlecan's glycosaminoglycan chains. Perlecan was the most effective enhancer and accelerator of A beta fibril formation when compared directly with other amyloid plaque components, including apolipoprotein E, alpha1-antichymotrypsin, P component, C1q, and C3. This study, therefore, demonstrates that perlecan not only binds to the predominant isoforms of A beta, but also accelerates A beta fibril formation and stabilizes amyloid fibrils once formed, confirming pivotal roles for perlecan in the pathogenesis of A beta amyloidosis in Alzheimer's disease.

Localization of perlecan (or a perlecan-related macromolecule) to isolated microglia in vitro and to microglia/macrophages following infusion of beta-amyloid protein into rodent hippocampus.

The origin of the heparan sulfate proteoglycan (PG), perlecan, in beta-amyloid protein (A beta)-containing amyloid deposits in Alzheimer's disease (AD) brain is not known. In the present investigation we used indirect immunofluorescence, SDS-PAGE, and Western blotting with a specific perlecan core protein antibody to identify possible cell candidates of perlecan production in both primary cell cultures and in a rat infusion model. Double and triple-labeled indirect immunofluorescence was performed on dissociated primary rat septal cultures using antibodies for specific identification of cell types and for perlecan core protein. In mixed cultures of both embryonic day 18 (containing neurons and glia) and postnatal day 2-3 (devoid of neurons), microglia identified by labeling with OX-42 or anti-ED1 were the only cell type also double labeled with an affinity-purified polyclonal antibody against perlecan core protein. Similar immunolabeling of microglia with the anti-perlecan antibody was also observed in purified cultures of post-natal rat microglia. Analyses of PGs from cultured postnatal rat microglia by Western blotting using a polyclonal antibody against perlecan core protein revealed an approximately 400 kDa band in cell layer, which was intensified following heparitinase/heparinase digestion, suggestive of perlecan core protein. Other lower Mr bands were also found implicating either degradation of the 400 kDa core protein or the presence of separate and distinct gene products immunologically related to perlecan. Reverse transcription followed by polymerase chain reaction using human perlecan domain I specific primers demonstrated perlecan mRNA in cultured human microglia derived from postmortem normal aged and AD brain. Following a 1-week continuous infusion of A beta (1-40) into rodent hippocampus, immunoperoxidase immunocytochemistry and double-labeled immunofluorescent studies revealed perlecan accumulation primarily localized to microglia/macrophages within the A beta infusion site. These studies have identified microglia/macrophages as one potential source of perlecan (or a perlecan-related macromolecule) which may be important for the ongoing accumulation of both perlecan and A beta in the amyloid deposits of AD.

Detection and quantitation of perlecan mRNA levels in Alzheimer's disease and normal aged hippocampus by competitive reverse transcription-polymerase chain reaction.

Our previous studies have implicated perlecan, a specific heparan sulfate proteoglycan, in the pathogenesis of fibrillar beta-amyloid protein (A beta) accumulation and persistence in Alzheimer's disease (AD) brain. In the present investigation, we determined if perlecan mRNA was present in rodent and human brain tissue and whether perlecan persistence in A beta amyloid deposits in AD hippocampus may be partly due to increased perlecan expression and/or decreased perlecan degradation. To detect and to quantify low-abundance perlecan mRNA in rodent and postmortem human brain tissue, regions of perlecan domain I (503 and 366 bp) containing the unique heparan sulfate glycosaminoglycan attachment sites were analyzed by reverse transcription (RT) and polymerase chain reaction (PCR). Perlecan mRNA was detected in rodent brain, kidney, and liver and in human AD and normal aged frontal cortex. Different-size transcripts of perlecan domain I were found, suggesting the existence of alternatively spliced variants of perlecan or closely related gene products. Quantitative competitive RT-PCR using a mutant perlecan domain I internal standard was used to determine perlecan mRNA levels in total RNA isolated from the hippocampus of 10 AD (mean +/- SEM duration of illness, 11.3 +/- 1.4 years) and 10 normal aged controls. No significant difference in perlecan mRNA levels from the hippocampus of AD (1.12 +/- 0.29 amol/500 ng of total RNA) versus normal aged controls (1.09 +/- 0.30 amol/500 ng of total RNA) was found, indicating that perlecan expression remained at steady-state levels. These results therefore suggest that perlecan persistence in A beta-amyloid deposits in late-stage AD may be primarily due to decreased perlecan degradation and removal.

Novel purification and detailed characterization of perlecan isolated from the Engelbreth-Holm-Swarm tumor for use in an animal model of fibrillar A beta amyloid persistence in brain.

Co-infusion of the specific heparan sulfate proteoglycan (HSPG), perlecan, and beta-amyloid protein (A beta) into rodent hippocampus leads to a consistent animal model to study the effects of fibrillar A beta amyloid in brain [Snow, A.D. et al. (1994) Neuron 12, 219-234]. In the present study, we describe our rapid novel method of perlecan isolation. The isolation method does not require cesium chloride centrifugation and exploits a newly discovered aggregating property of a approximately 220 kDa PG observed during gel filtration chromatography, which allowed it to be affectively separated from non-aggregating perlecan. Fifty or 100 g of EHS tumor were routinely extracted using 4 M guanidine-HCl, followed by anion-exchange and gel filtration chromatography. SDS-PAGE (before and after digestion with heparitinase/heparinase or nitrous acid) followed by staining with silver demonstrated no other contaminating proteins in the perlecan preparations. Western blots using a specific perlecan core protein antibody (HK-102) following heparitinase digestion showed a characteristic doublet at 400 and 360 kDa indicative of intact perlecan core protein. Absence of contamination by other basement membrane components produced by the EHS tumor was confirmed by absence of immunoreactive bands on Western blots using antibodies against laminin, fibronectin, or type IV collagen. One week continuous co-infusion of perlecan obtained from this methodology, with A beta (1-40) into rodent hippocampus, led to deposition of fibrillar A beta amyloid in 100% (10 of 10) of animals. The detailed protocol for isolation and characterization of perlecan from EHS tumor ensures perlecan of the highest quality, and maximizes the potential effects of A beta amyloid deposition/persistence in brain using the animal model. High quality perlecan obtained from this novel isolation method will also allow future studies utilizing in vitro assays to determine the potential interactions of this specific HSPG with other macromolecules.

Identification in immunolocalization of a new class of proteoglycan (keratan sulfate) to the neuritic plaques of Alzheimer's disease.

Previous studies have demonstrated three distinct classes of proteoglycans (PGs)/glycosaminoglycans (GAGs) localized to the characteristic lesions (i.e., neuritic plaques, cerebrovascular amyloid deposits, and neurofibrillary tangles) of Alzheimer's disease (AD). These include heparan sulfate (i.e., perlecan), dermatan sulfate (i.e., decorin), and chondroitin sulfate PGs/GAGs. In the present study, two different antibodies demonstrated the presence of a new class of PG (i.e., keratan sulfate) in the neuritic plaques of AD. Asynaptic vesicle keratan sulfate PG (known as SV2PG) was detected by the monoclonal antibodies, anti-SV2 and anti-SV4, which recognize the keratan sulfate core protein and GAG chains, of the SV2PG antigen, respectively. Both antibodies immunolocalized SV2PG primarily to synapses and to dystrophic neurites within neuritic plaques of AD and normal aged brain. The SV2PG was not immunolocalized to diffuse plaques, cerebrovascular amyloid deposits, or neurofibrillary tangles in AD or normal aged brain. SV2PG immunoreactivity in AD brain was similar in distribution to synaptophysin and showed apparent reduced immunoreactiviy+in AD cortex in comparison to age-matched controls. In conjunction with previous studies, these results now suggest that within the neuritic plaques of AD, there are at least four different classes of PGs present. Although heparan sulfate PGs are still the only class of PG immunolocalized to amyloid fibrils within the neuritic plaques of AD, the specific immunolocalization of keratan sulfate, dermatan sulfate, and chondroitin sulfate containing PGs to the periphery of plaques, suggests that these particular PGs/GAGs may also play distinct and important roles in neuritic plaque pathogenesis.

Differential binding of vascular cell-derived proteoglycans (perlecan, biglycan, decorin, and versican) to the beta-amyloid protein of Alzheimer's disease.

Previous studies have demonstrated the immunolocalization of perlecan, a specific heparan sulfate proteoglycan, to the beta-amyloid protein (A beta)-containing amyloid deposits within the walls of blood vessels (i.e., congophilic angiopathy) in Alzheimer's disease (AD) brain. In the present investigation, the differential binding of previously characterized endothelial cell (EC)- and smooth muscle cell (SMC)-derived PGs to A beta was examined to determine whether the accumulation of A beta in cerebrovascular amyloid deposits may be due to its interactions with perlecan. Pretreatment of AA amyloidotic splenic and liver tissue sections with synthetic A beta (1-28) produced strong immunoreactivity with A beta antibodies at tissue sites enriched in perlecan which was partially removed by pretreatment with heparitinase, but not by chondroitin ABC lyase. [35S]-Sulfate labeled proteoglycans (PGs) derived from cultured ECs and SMCs bound to affinity columns containing A beta (1-28) or (1-40), with virtually no binding to A beta (40-1) (reverse peptide), beta-amyloid precursor protein (410-429), or bovine serum albumin. Characterization of EC and SMC PGs bound to A beta (1-28) revealed strong binding by perlecan, weak binding by decorin and biglycan, two dermatan sulfate proteoglycans, and lack of binding by versican/PG-M, a large chondroitin sulfate proteoglycan. Binding of 125I-labeled perlecan to A beta (1-28) was strongly inhibited by isolated perlecan and to a lesser extent by heparin, but not by chondroitin-6-sulfate or unsulfated dextran sulfate. Heparitinase treatment decreased, but did not eliminate the binding of 125I-labeled perlecan to A beta (1-28). Scatchard analysis of the interaction of A beta (1-28)- and EC-derived perlecan in solid-phase assays indicated high-affinity (Kd = 8.3 x 10(-11) M) and lower-affinity (Kd = 4.2 x 10(-8) M) binding sites, with approximately 1 mol of perlecan binding 1.8 mol of A beta. A significant decrease in binding of EC-derived perlecan to A beta (1-28) was observed when a sequence within the putative heparin-binding motif of A beta (His13His14Gln15Lys16) was replaced by the uncharged peptide sequence, Gly13Gly14Gln15Gly16, indicating a perlecan binding site on A beta near the postulated alpha-secretase site (at Lys-16). Overall, the results indicate that specific vascular cell-derived PGs differentially interact with A beta, and that the interactions of highest affinity occur between A beta and binding sites on both the core protein and glycosaminoglycan chains of perlecan.(ABSTRACT TRUNCATED AT 400 WORDS)

Conformation and fibrillogenesis of Alzheimer A beta peptides with selected substitution of charged residues.

A key pathological feature of Alzheimer's disease (AD) is the formation and accumulation of amyloid fibers within the neurophil as senile plaques and in the walls of cerebral and meningeal blood vessels. The major component is the 39 to 42 residue amyloid beta protein (A beta), which is an internal proteolytic fragment of the membrane-associated amyloid precursor protein. Aggregation of A beta into amyloid fibers that could be cytotoxic may be a factor in the AD-related neuronal loss. To understand the steps and molecular interactions involved in the transition from a soluble to fibrous form of A beta, and to test molecular models that postulate ion pairing between beta-strands, we have synthetized four peptides having substitutions in specific, charged residues. These included an A beta fragment, residues 11 to 25, and having histidine-to-aspartate replacements at positions 13 (H13D) and 14 (H14D), an aspartate-to-lysine at position 23 (D23K) and a 28-mer full-length extracellular domain where the positive charge cluster at His13-His14-Gln15-Lys16 was replaced by an uncharged Gly13-Gly14-Gln15-Gly16 (GGQG). Fourier-transform infrared spectroscopy and fiber X-ray diffraction determined that the H13D and H14D substitutions had negligible effect on beta-sheet formation, suggesting that these residues are not critical for the intramolecular interactions necessary for folding in the beta-conformation. However, negative-stain electron microscopy revealed that the loss of the His13 or His14 resulted in only protofilament formation, suggesting that these residues are involved in amyloid fibril assembly. By contrast, the D23K substitution virtually eliminated folding into a beta-sheet conformation, with appreciable secondary structure being detected only following extended incubation times. The complete absence of the centrally charged region GGQG arrested amyloid assembly at the protofilament stage and also reduced the stability of the beta-conformation, suggesting a contribution of Lys16 in maintaining secondary structure. While it has been conclusively demonstrated by previous investigations that amyloid formation is dependent to a large extent on hydrophobically driven interactions, our results indicate that charge-charge interactions function in concert with non-ionic interactions to stabilize the beta-sheet conformation and assembly of AD amyloid fibers.

Characterization of proteoglycans synthesized by murine embryonal carcinoma cells (P19) reveals increased expression of perlecan (heparan sulfate proteoglycan) during neuronal differentiation.

Proteoglycans (PGs) incorporated into cell layer and secreted into media were characterized during retinoic acid-induced neuronal differentiation of cultured P19 murine embryonal carcinoma cells. Heparan sulfate significantly increased (P < 0.01) in cell layer following neuronal differentiation of P19 cells by 3.9-fold. CL-4B gel chromatography revealed the major PGs present in cell layer of stem cells eluted as a broad peak with a Kav = 0.65, and was susceptible to chondroitin ABC lyase. The chondroitin ABC lyase resistant material eluted as a broad peak between Kav = 0.40 and Kav = 0.60, and was only partially digested with heparitinase/heparinase (with resistant material eluting at Kav = 0.70). Therefore, the cell layer of stem cells contained primarily chondroitin sulfate/dermatan sulfate (CS/DS) PGs, with lesser amounts of heparan sulfate proteoglycans (HSPGs). This was confirmed by SDS-PAGE. The CS/DS PGs in the cell layer of stem cells had an apparent M(r) of approximately > 200 kDa, and the HSPGs had an apparent M(r) of approximately 140-230 kDa. In contrast, the major PGs in the cell layer of neurons consisted primarily of HSPGs, with only a minor proportion of CS/DS PGs. Furthermore, both gel filtration chromatography and SDS-PAGE analysis revealed a larger HSPG in the cell layer of neurons (Kav = 0.3-0.6 on CL-4B following chondroitin ABC lyase digestion; M(r) 170 kDa- > 400 kDa on SDS-PAGE) in comparison to stem cells (Kav = 0.4-0.6 on CL-4B following chondroitin ABC lyase digestion; M(r) 140-230 kDa on SDS-PAGE). Likewise, the major PGs secreted into media of stem cells consisted almost exclusively of CS/DS PGs, with lesser amounts of HSPGs, whereas an increase in HSPGs in the media of neurons was apparent. Western, Northern, and immunocytochemical analysis demonstrated that mRNA transcript and protein levels for a specific HSPG (i.e., perlecan) markedly increased in cell layer following P19 neuronal differentiation. Perlecan core protein was identified by Western blot analysis using specific monoclonal and polyclonal antibodies, as a large HSPG with a core protein of apparent M(r) approximately 370-400 kDa, and was observed primarily in extracts from neurons. Northern blot analysis with a cDNA to perlecan revealed a significant (P < 0.01) 12.7-fold increase in expression of perlecan in neurons (day 9) in comparison to stem cells. The increase in perlecan message during P19 neuronal differentiation was concomitant with a significant (P < 0.01) 26.3-fold increase in message for beta-amyloid precursor protein (beta PP).(ABSTRACT TRUNCATED AT 400 WORDS)

Age-related deposition of glia-associated fibrillar material in brains of C57BL/6 mice.

With advancing age, clusters of unusual granules appear in the brains of C57BL/6 (B6) mice. At the light, confocal laser and electron microscopic levels, the granules represent aggregations of fibrillar material often associated with astrocytes. The fibrillar material is largely free of normal organelles and has been located within astrocytic somata and processes, although in many cases the material is found in the neuropil and is surrounded by a discontinuous membrane. The deposits occur predominantly in hippocampus, but also in piriform cortex, cerebellum and less frequently in some other brain regions. They become evident about six months of age and increase markedly in both number and size thereafter. Incidence of the deposits varies greatly among inbred mouse strains. At six to 12 months of age, granules are abundant in male and female B6, and are absent in BALB/c, CBA, DBA/2 and A mice. In hybrid strains with a B6 background the deposits are also present and thus appear to manifest dominant genetic heritability. Similar granular structures have been described in adult brains of the senescence accelerated mouse and have been noted, albeit very rarely, in aged mice from other strains. While immunostaining of the granules with several polyclonal antisera was found by preabsorption with antigens to be non-specific, immunolabeling with monoclonal antibodies to heparan sulfate proteoglycan core protein and to laminin suggest these or related molecules as components of the fibrillar material. The presence of glycosaminoglycans is supported by staining with periodic acid-Schiff and Gomori's methenamine silver methods. The functional significance of the murine deposits is not yet clear. The deposits do not represent senile plaques with beta-amyloid deposition, but they might mimic the deposition of extracellular matrix molecules that is hypothesized to be a precursor condition for plaque formation and cerebral amyloidosis. Furthermore, the genetic differences in the incidence of the fibrillar deposits has potential to model aspects of familial neurodegenerative diseases.

Heparan sulfate proteoglycan in diffuse plaques of hippocampus but not of cerebellum in Alzheimer's disease brain.

Previous studies have shown the basement membrane form of heparan sulfate proteoglycan (HSPG) known as perlecan, co-localized to beta-amyloid protein (A beta)-containing amyloid deposits in brains of patients with Alzheimer's disease (AD) and Down's syndrome. Although HSPG was localized to diffuse A beta plaques in hippocampus, amygdala, and neocortex, it is not known whether they are present in diffuse A beta plaques in cerebellum. In the present study, Alcian blue staining and immunocytochemical techniques were used to determine whether highly sulfated glycosaminoglycans (GAGs) and/or HSPG (perlecan) were also present in diffuse A beta plaques of cerebellum. Tissues from cases of AD were examined for the co-localization of highly sulfated GAGs, HSPGs, and A beta in diffuse plaques in cerebellum in comparison with hippocampus. Consecutive serial sections of AD brain tissue were stained or immunostained with 1) the modified Bielschowsky stain; 2) a polyclonal antibody directed against synthetic A beta (1-40); 3) Congo red; 4) Alcian blue (pH 5.7) with varying concentrations of magnesium chloride for identification of sulfated and highly sulfated GAGs; and 5) polyclonal and monoclonal antibodies recognizing either the core protein or a specific GAG epitope on perlecan. All cases (7 of 7) of AD contained diffuse A beta plaques in the cerebellum as identified by positive Bielschowsky staining and A beta immunoreactivity. None of these cases demonstrated positive Alcian blue staining (at 0.3 and 0.7 mol/L MgCl2), HSPG, or HS GAG immunoreactivity in the same diffuse cerebellar plaques on adjacent serial sections. However, Alcian blue staining, HSPG, and/or HS GAG immunoreactivity were observed in blood vessel walls, choroid plexus, and within Purkinje cells, suggesting that the techniques used were reliable and specific. In cerebellum, all plaques containing amyloid cores that were Congo red-positive were also positive for highly sulfated GAGs (by Alcian blue staining at 0.7 mol/L MgCl2) and HSPG (both core protein and GAG chain) immunoreactivity. Even though HSPG immunoreactivity was not present in cerebellar diffuse plaques, all cases (4 of 4) examined demonstrated HSPG (both core protein and GAG chain) immunoreactivity in diffuse A beta plaques in hippocampus. Therefore, by Alcian blue staining and immunocytochemical methods, highly sulfated GAGs and HSPGs are not present in A beta diffuse plaques in cerebellum. Since previous studies indicate that the cerebellum contains relatively few amyloid-containing plaques in comparison with diffuse plaques, these studies suggest that HSPG may be an essential component needed for amyloid formation and/or persistence in brain as observed in cortical areas.(ABSTRACT TRUNCATED AT 400 WORDS)

An important role of heparan sulfate proteoglycan (Perlecan) in a model system for the deposition and persistence of fibrillar A beta-amyloid in rat brain.

A consistent rat model for the study of the consequences of congophilic and fibrillar A beta-amyloid in brain has been developed. One hundred percent of animals receiving infusions of synthetic beta-amyloid protein (A beta 1-40) plus a specific heparan sulfate proteoglycan (HSPG) for 1 week or 7 weeks (following 2 week infusions) demonstrated Congo red and thioflavin S-positive deposits adjacent to the infusion site. Extracellular amyloid fibrils were identified by electron microscopy and were immunogold decorated with A beta antibody. Significant increases in Congo red staining were observed in animals infused with A beta plus HSPG versus those infused with only A beta. Infusion of A beta alone was variable with respect to congophilic amyloid persistence, which occurred in 50% of animals and only when endogenous HSPGs accumulated at A beta deposition sites. By 7 weeks, only animals infused with A beta plus HSPG demonstrated compaction of the Congo red material from amorphous, wispy deposits (at 1 week) to stellate deposits resembling a Maltese cross. These spherical amyloid deposits were very similar to Congo red-stained amyloid plaques in human Alzheimer's disease brain, and in vitro data suggest that they were probably formed in vivo following interactions with endogenous brain components.

Increased expression of beta-amyloid protein precursor and microtubule-associated protein tau during the differentiation of murine embryonal carcinoma cells.

Expression of the genes encoding the beta/A4 amyloid protein precursor (APP) and microtubule-associated protein tau was studied in an embryonal carcinoma cell line (P19) that differentiates in vitro into cholinergic neurons after treatment with retinoic acid. Expression of APP increased 34- (mRNA) and 50-fold (protein) during neuronal differentiation; APP-695 accounted for most of this increase. These remarkable increases in APP expression coincided with a proliferation of neuronal processes and with an increase in content of tau mRNA. Moreover, subsequent decreases in the levels of APP and tau mRNA coincided with the onset of the degeneration of the neuronal processes. Immunocytochemical staining suggested that greater than 85% of the P19-derived neurons are cholinergic and that APP is present in the neuronal processes and cell bodies. These results suggest that APP may play an important role in construction of neuronal networks and neuronal differentiation and also indicate that this embryonal carcinoma cell line provides an ideal model system to investigate biological functions of APP and the roles of APP and tau protein in development of Alzheimer's disease in cholinergic neurons.

Peripheral distribution of dermatan sulfate proteoglycans (decorin) in amyloid-containing plaques and their presence in neurofibrillary tangles of Alzheimer's disease.

We used a polyclonal antibody and a mixture of three monoclonal antibodies (MAb), all recognizing the protein core of the small dermatan sulfate proteoglycan (DSPG) (known as PG-II or decorin) derived from human skin fibroblasts, to immunolocalize this molecule in the characteristic lesions in Alzheimer's brain. All antibodies demonstrated positive decorin immunostaining in both the amyloid deposits of neuritic plaques (NPs) and the filamentous structures within neurofibrillary tangles (NFTs). Unlike heparan sulfate proteoglycans (HSPGs), which tend to be evenly distributed throughout NPs containing amyloid fibrils, decorin was primarily localized to the periphery of the spherically shaped amyloid plaques and to the edges of amyloid fibril bundles within the plaque periphery. Decorin was also immunolocalized to the paired helical and straight filaments within NFTs and to collagen fibrils surrounding blood vessels. The unusual distribution of decorin confined to the periphery of amyloid plaques in AD brain suggests that this particular PG may play an important role in the development of the amyloid plaque.