 |
|||||
|
|||||
|
|||||
|
|||||
|
|||||
Previous Article | Next Article
Volume 16, Number 23, Issue of December 1, 1996 pp. 7513-7525
Copyright ©1996 Society for NeuroscienceExpression of Presenilin 1 and 2 (PS1 and PS2) in Human and Murine Tissues
Michael K. Lee1, 4, Hilda H. Slunt1, 4, Lee J. Martin1, 2, 4, Gopal Thinakaran1, 4, Grace Kim1, 4, Samuel E. Gandy5, Mary Seeger5, Edward Koo6, Donald L. Price1, 2, 3, 4, and Sangram S. Sisodia1, 2, 4 Departments of 1 Pathology, 2 Neuroscience, and 3 Neurology, and the 4 Neuropathology Laboratory, The Johns Hopkins University School of Medicine, Baltimore, Maryland 21205, 5 Departments of Neurology and Neuroscience, Cornell University Medical College, New York, New York 10021, and 6 Center for Neurological Diseases, Brigham and Women's Hospital, Harvard Medical School, Boston, Massachusetts 02115
ABSTRACT
Mutations in genes encoding related proteins, termed presenilin 1 (PS1) and presenilin 2 (PS2), are linked to the majority of cases with early-onset familial Alzheimer's disease (FAD). To clarify potential function(s) of presenilins and relationships of presenilin expression to pathogenesis of AD, we examined the expression of PS1 and PS2 mRNA and PS1 protein in human and mouse. Semi-quantitative PCR of reverse-transcribed RNA (RT-PCR) analysis revealed that PS1 and PS2 mRNA are expressed ubiquitously and at comparable levels in most human and mouse tissues, including adult brain. However, PS1 mRNA is expressed at significantly higher levels in developing brain. In situ hybridization studies of mouse embryos revealed widespread expression of PS1 mRNA with a neural expression pattern that, in part, overlaps that reported for mRNA encoding specific Notch homologs. In situ hybridization analysis in adult mouse brain revealed that PS1 and PS2 mRNAs are enriched in neurons of the hippocampal formation and entorhinal cortex. Although PS1 and PS2 mRNA are expressed most prominently in neurons, lower but significant levels of PS1 and PS2 transcripts are also detected in white matter glial cells. Moreover, cultured neurons and astrocytes express PS1 and PS2 mRNAs. Using PS1-specific antibodies in immunoblot analysis, we demonstrate that PS1 accumulates as ~28 kDa N-terminal and ~18 kDa C-terminal fragments in brain. Immunocytochemical studies of mouse brain reveal that PS1 protein accumulates in a variety of neuronal populations with enrichment in somatodendritic and neuropil compartments.
Key words: Alzheimer's disease; presenilins; development; mRNA expression; protein accumulation; immunocytochemistry
INTRODUCTION
Alzheimer's disease (AD), the most common progressive type of dementia occurring in adult life, is characterized neuropathologically by the presence of numerous senile plaques and neurofibrillary tangles in cerebral cortex and hippocampus (Wisniewski and Terry, 1973
). AD is a genetically heterogeneous disorder (St. George-Hyslop et al., 1992
Presenilins 1 and 2 are transmembrane proteins (Rogaev et al., 1995
Previous studies demonstrated that both PS1 and PS2 are expressed ubiquitously in a variety of human tissues and brain regions (Rogaev et al., 1995
To clarify potential function(s) of presenilins and relationships of presenilin expression in the pathogenesis of AD, we examined the expression of PS1 and PS2 mRNA and PS1 protein in human and mouse. Our semi-quantitative RT-PCR studies reveal that PS1 and PS2 mRNAs are expressed at similar levels in most tissues, with minor exceptions. In situ hybridization analysis of mouse embryos at various developmental stages and adult mouse brain indicate that PS1 and PS2 transcripts are widely expressed. In brain, PS1 and PS2 mRNAs are expressed at highest levels in neurons, with somewhat lower levels in glial cells. Immunoblot analysis using two anti-PS1 antibodies raised against nonoverlapping epitopes revealed that PS1 accumulates as proteolytically processed fragments in brain and systemic tissues. Finally, we performed immunocytochemical investigations to identify the cellular and subcellular distributions of PS1 in mouse brain. We document that PS1 is expressed in somatodendritic and neuropil compartments of neurons in the neocortex and hippocampal formation.
MATERIALS AND METHODS
PS1 and PS2 mRNA analysis. Total RNA was isolated by homogenization of selected tissue in 4 M guanidium thiocyanate and centrifugation of the lysates over a 5.7 M cesium chloride cushion (Chirgwin et al., 1979
The levels of PS1 and PS2 mRNA in mouse and human brain, peripheral tissues, and developmental stages were assayed by PCR of reverse-transcribed RNA (RT-PCR; Chelly et al., 1988 -(A/G)ACGG(G/T)CAGCT(A/C)ATCTACAC-3
In situ hybridization. Mouse PS1 cDNA corresponding to nucleotides 1758-1945 of mouse PS1 mRNA (Sherrington et al., 1995
Sections (10 µm) cut from either fresh-frozen or paraffin-embedded tissues were mounted onto slides and reacted with either sense or antisense probes (1 ng/slide, ~106 cpm/ng). Sections were hybridized overnight at 55°C in a buffer containing 50% formamide, 10% dextran sulfate, 0.3 M NaCl, 20 mM Tris, pH 7.5, 10 mM DTT, 5 mM EDTA, 1× Denhardt's solution and 0.4 mg/ml yeast tRNA, and 1 ng/slide of labeled probe (~2 × 106 cpm/ng). Slides were washed as follows: 5× SSC (1× SSC = 0.15 M NaCl and 0.015 M sodium citrate) and 1 mM DTT at 55°C for 20 min; 50% formamide, 2× SSC, and 1 mM DTT at 60°C for 30 min; 10 mM Tris, pH 7.5, 0.5 M NaCl, and 5 mM EDTA (TNE buffer) at 37°C three times for 10 min each; TNE buffer containing 20 µg/ml RNase A at 37°C for 45 min; TNE buffer at 37°C for 15 min; 50% formamide, 2× SSC, and 1 mM DTT at 60°C for 30 min; 2× SSC at 37°C for 20 min; and 0.1× SSC at 37°C for 20 min. After dehydration, slides were dipped into Kodak emulsion NTB-2 from 3 d to 3 weeks and developed in Kodak D-19. The sections were counterstained lightly with hematoxylin and eosin and coverslipped with Permount.
Primary neuronal and glial cultures. Primary neuronal and glial cultures from mouse neocortex were obtained as described by Hertz et al. (1985)
The glial culture, enriched in astrocytes, was established from cortices of 2-d-old mouse pups. The cortices were removed asceptically into HBSS, minced into ~1 mm pieces, and treated with trypsin as above. Cells were dissociated and plated on plastic tissue culture dishes at 2 × 105 cells/cm2 in DMEM containing 10% fetal calf serum. Total cellular RNA from 7 d neuronal and glial cultures was isolated with Trizol reagent (Life Technologies).
Immunoblot analysis of PS1 protein. Tissue and cell homogenates were prepared in TNE buffer (10 mM Tris-HCl, pH 7.4, 150 mM NaCl, and 5 mM EDTA) containing protease inhibitors (5 mM PMSF, 10 µg/ml aprotinin, 10 µg/ml leupeptin, and 10 µg/ml pepstatin) and detergents (1% SDS, 0.25% deoxycholate, and 0.25% NP-40). Protein concentrations of each homogenate were determined by bichichonic acid protein assay (Pierce, Rockford, IL). The homogenates were diluted further with the Laemmli sample buffer (Laemmli, 1970).
Protein in the above homogenates was fractioned by SDS-PAGE (Laemmli, 1970) and transferred to nitrocellulose filter membranes (Towbin et al., 1979 PS1Loop, a rabbit polyclonal antibody generated against amino acids 263-407 of PS1 (the "loop" region between putative transmembrane domains 6 and 7; Sherrington et al., 1995
-tubulin mouse monoclonal antibody (TuJ1; Lee et al., 1990
Immunocytochemistry. Mice were perfused intra-aortically with PBS followed by 4% paraformaldehyde. Brains were cryoprotected in 30% sucrose. Sections were cut (40 µm) on a sliding microtome and processed immunocytochemically by using the peroxidase/antiperoxidase method with diaminobenzidine as chromogen (Martin et al., 1991
RESULTS
Levels of PS1 and PS2 mRNAs in human and murine tissues
Earlier Northern blotting studies revealed that, although PS1 and PS2 transcripts are expressed in a variety of human tissues, PS1 mRNA seemed to be over-represented considerably, relative to PS2 mRNA (Rogaev et al., 1995
Fig. 1. Quantitative PCR amplification of PS1 and PS2 cDNAs from human brain and mouse spinal cord. A, EtBr-stained gel of PflMI/NcoI double-digested PCR products from human fetal brain and adult mouse spinal cord cDNA after 22, 24, 26, 28, and 30 cycles of amplification. Also shown are PCR products obtained by using PS1 and PS2 cDNA as templates. The marker DNA fragments are indicated in bp. B, Autoradiogram of the gel shown in A. C, D, Semilog plots of radioactivity (density) versus cycle number for the human (C) and mouse (D) PS1 and PS2 fragments shown in B. The linear regression equation for each plot is shown in the inset.
[View Larger Version of this Image (49K GIF file)]
Using optimized RT-PCR conditions (100 ng of reverse-transcribed RNA and 26 cycles), we examined the relative levels of PS1 and PS2 mRNAs in human fetal tissues. Our studies, consistent with earlier RNA blot studies (Rogaev et al., 1995 
Fig. 2. RT-PCR analysis of PS1 and PS2 mRNA in human and mouse tissues. A, EtBr-stained gel of PflMI/NcoI double-digested PCR product generated by RT-PCR amplification of RNAs from human fetal tissues (adrenal, kidney, liver, lung, skeletal muscle, and spleen), brains from fetus and adults [cortex from a fetus (f-Ctx), a 19 yr old (Ctx-19), a 66 yr old (Ctx-66), and a 75 yr old (Ctx-75)], cortical white matter (WM-1 and WM-2), and cortical gray matter (GM-1 and GM-2). B, EtBr-stained gel of PflMI/NcoI double-digested PCR products generated by RT-PCR amplification of RNAs from mouse embryos [embryonic days 8.5 (E8.5), 10.5 (E10.5), 12.5 (E12.5), and 14.5 (E14.5)], brain [neonatal cortex (P1 Ctx) and adult cortex (Ad Ctx)], and adult tissues [heart, kidney, liver, lung, small intestine (Sm Int), spleen, and testis]. C, D, Autoradiogram of the gels shown in A and B, respectively. The ratio of PS1 to PS2 cDNA products, averaged from two independent PCR reactions, is shown at the bottom. The amount of template (reverse-transcribed RNA) was equated for its actin mRNA content (data not shown).
[View Larger Version of this Image (55K GIF file)]
Analysis of PS1 and PS2 mRNA levels in human cortex from a late second trimester fetus, 19 yr old, 66 yr old, and 75 yr old reveals that the relative expression levels of PS1 and PS2 mRNAs change significantly as a function of age. In fetal cortex, the expression level of PS1 mRNA is approximately fivefold higher than that of PS2 mRNA, consistent with studies shown in Figure 1, A and C. However, in young adult and aged brain, PS1 and PS2 mRNAs are expressed at similar levels. Finally, analysis of cortical gray and white matter from a 21 yr old (Fig. 2A,C, lanes GM-1, WM-1) or an 80 yr old (Fig. 2A,C, lanes GM-2, WM-2) revealed that PS1 mRNA is enriched in the white matter, as compared with PS2 mRNA, suggesting that glial cells (mostly oligodendrocytes) selectively express more PS1 mRNA than PS2 mRNA. This observation is consistent with earlier Northern blot studies that showed high levels of PS1 mRNA expression in corpus collosum (Rogaev et al., 1995
Both PS1 and PS2 mRNAs also are expressed widely in adult mouse tissues (Fig. 2B,D). PS1 mRNA levels are significantly higher than PS2 mRNA in small intestine and in testis, whereas PS2 mRNA is four times more abundant than PS1 mRNA in liver. In the remaining adult mouse tissues, PS1 and PS2 mRNAs accumulate to comparable levels. However, during mouse embryonic development, PS1 mRNA expression occurs at earlier developmental stages, with subsequent increases in the relative level of PS2 mRNA (Fig. 2B,D). In day 8.5 and 10.5 whole-mouse embryos, PS1 mRNA levels are approximately twice that of PS2 mRNA. By day 12.5, both PS1 and PS2 transcripts are expressed at equivalent levels, and PS2 mRNA may be expressed at slightly higher levels in 14.5 d embryos. In the cortex of newborn mice, PS1 is expressed at approximately three times the level of PS2 mRNA. Consistent with the results obtained using postnatal human brain (Fig. 2A,C), the level of PS2 mRNA is similar to the level of PS1 mRNA in adult mouse cortex.
These studies demonstrate that, although both PS1 and PS2 transcripts are expressed in many tissues, the relative levels of PS1/PS2 mRNAs are variable between tissues and during brain development. Specifically, the level of PS2 mRNA increases relative to PS1 mRNA during postnatal development of both human and mouse brain, suggesting that the expression of PS1 and PS2 transcripts is regulated differentially during brain maturation. Clearly, analysis of total RNA samples fails to score differences in mRNA accumulation within specific cell types/substructures; hence, our studies are only a first approximation. Nevertheless, although the structural conservation and relatively ubiquitous expression pattern of PS1 and PS2 mRNAs suggest some degree of functional redundancy, differences in relative levels of expression suggest that the biological roles of PS1 and PS2 may differ during development and in adult tissues. Distribution of PS1 and PS2 transcripts in mouse embryos
The high degree of homology between presenilins and sel-12, a C. elegans protein that mediates cell-fate decisions elicited by Notch/lin-12, has led to the suggestion that PS1/PS2 may function in Notch signaling pathway(s) in mammals. To determine whether PS1 transcripts are expressed in a distinctive pattern overlapping that known for Notch mRNA during development, we examined the expression of PS1 mRNA in mouse embryos by in situ hybridization analysis.
In 10 and 12 d mouse embryos, PS1 mRNA is expressed throughout the neuraxis and developing organs and at comparable levels (Fig. 3A,B,E,F). Notably, in the neuroepithelium, PS1 mRNA is expressed at nearly indistinguishable levels in cells within the ventricular and the marginal zones and may have slightly higher levels of expression in terminally differentiated neurons located in ventral horn and dorsal root ganglia (Fig. 3C,D). These observations contrast with several reports demonstrating that the highest levels of Notch mRNA expression in the neuroepithelium are in cells located within the ventricular zone (Reaume et al., 1992 
Fig. 3. In situ localization of PS1 mRNA in mouse embryos. Paraffin-embedded sections of mouse embryos were processed for in situ hybridization by PS1-specific riboprobes. The silver grains over the sections, representing specific hybridization, were visualized by dark-field microscopy. The sections hybridized with antisense and control sense probes were photographed and reproduced using identical conditions. A, B, PS1 mRNA expression in E10 mouse embryos. Sections from E10 mouse embryos probed with antisense (A) and sense (B) mouse PS1 riboprobes reveal the presence of PS1 mRNA throughout the embryo. A, Aorta; C, spinal cord; H, heart; M, mesencephalon; O, optic vesicle; S, somite; ST, septum transversum; T, telencephalon. C, D, Detailed view of the spinal neural tube from sections shown in A and B. The antisense-probed section (C) shows higher grain density throughout the neural epithelium, as compared with the section probed with sense probe (D). DRG, Dorsal root ganglion; M, marginal zone; V, ventricular zone; VH, ventral horn. E, F, Sagittal sections of E12.5 mouse embryo hybridized with antisense (E) and sense (F) mouse PS1 riboprobe show PS1 mRNA expression throughout the nervous system and peripheral tissues. B, Brachial arch; C, spinal cord; H, heart; HB, hindbrain; L, liver; M, mesencephalon; T, telencephalon. G, H, Sections of E16.5 mouse embryo show high levels of PS1 mRNA expression in epithelial cells of small intestine (G) and skin (H). Scale bars: C, D, 150 µm; G, H, 300 µm.
[View Larger Version of this Image (192K GIF file)]
Comparison of PS1 and PS2 mRNA expression with APP mRNA expression in adult mouse brain
Although earlier reports show that both PS1 and PS2 mRNAs are expressed in a variety of brain regions (Rogaev et al., 1995
Consistent with several earlier reports, our analysis of coronal sections through mouse brain at the level of medial dorsal hippocampus revealed that APP mRNA is expressed widely at high levels in most brain regions (Fig. 4A). Adjacent sections hybridized with 33P-labeled RNA probes complementary to PS1 or PS2 mRNA show that presenilin transcripts also are expressed in a variety of brain regions (Fig. 4C,E). Consecutive sections hybridized with sense RNA probes did not show significant hybridization (Fig. 4B,D,F), demonstrating the specificity of the antisense RNA probes. Neurons seem to express PS1 transcripts at the highest levels (Fig. 5A); PS1 mRNA expression is also evident in oligodendrocytes and astrocytes in white matter tracts, although at somewhat lower levels (Fig. 5C). The expression of PS1 or PS2 mRNAs in glial cells in the neuropil could not be determined conclusively using in situ hybridization because of the paucity of the cytoplasm in these cells. Nevertheless, expression of presenilin mRNA and protein has been confirmed in primary cultures of purified astrocytes (see below, Fig. 9). 
Fig. 4. Expression of APP, PS1, and PS2 transcripts in mouse brain. Coronal sections of adult mouse brain at the level of dorsal hippocampus hybridized with antisense riboprobes specific for APP (A), PS1 (C), and PS2 (E). Adjacent sections were hybridized with sense probe (B, D, F) to show the specificity of antisense probes. The silver grains associated with specific transcripts were visualized with dark-field microscopy. The antisense and respective sense control sections were photographed and reproduced under identical conditions. A, B, APP mRNA is highly expressed in most brain regions, with particularly high levels in hippocampal CA fields (CA1, CA2) and primary olfactory cortex (POC). The APP sections were exposed to emulsion for 3 d. PS1 (C, D) and PS2 (E, F) mRNA are widely distributed, but the distribution of cells expressing high (Figure legend continues) levels of each transcript is restricted. The PS1 and PS2 sections were exposed on emulsion for 3 weeks. Longer exposure times were required for photography of sections hybridized with PS2 probes (E, F) because of lower signal levels of the section shown in E. The longer exposure times under dark-field illumination led to higher levels of nonspecific signal associated with the white matter tracts in both antisense (E) and sense (F)-probed sections. CA1, CA2, D, Hippocampal CA-fields and dentate gyrus; POC, primary olfactory cortex; Th, thalamus; a, b, c, lateral, medial, and cortical amygdala; d, arcuate nucleus; e, subthalamic nucleus; f, zona inserta; g, corpus callosum; h, habenulae.
[View Larger Version of this Image (105K GIF file)]
Fig. 5. Neuronal and glial expression of PS1 mRNA in brain. A, B, Bright-field image of CA2 region of hippocampus from sections hybridized with antisense (A) or sense (B) PS1 riboprobes. High levels of PS1 mRNA-associated silver grains are most evident in pyramidal neurons. C, D, Corpus callosum from brain sections hybridized with antisense (C) or sense (D) riboprobes shows expression of PS1 mRNA in glial cells of white matter tracts. The silver grains were visualized by differential interference contrast microscopy and are shown as white dots. All of the sections were lightly counterstained with hematoxylin/eosin. Scale bars: A, B, 75 µm; C, D, 150 µm.
[View Larger Version of this Image (131K GIF file)]
Fig. 9. Expression of PS1 and PS2 in mouse neurons and glia in culture. A, EtBr-stained gels of PS1 and PS2 products amplified from mouse neuronal or glial RNA. PS1 was distinguished from PS2 by digestion with PflMI. Lane 1, PS1 plasmid; lane 2, PS2 plasmid; lane 3, mouse neocortex; lane 4, primary neuronal culture; lane 5, primary glial culture. Marker fragments (M) are indicated in bps. B, Immunoblot analysis of total SDS-extracts (50 µg) from mouse cortex (Ctx), cultured neurons (N), and cultured glia (G) using Ab14 and
[View Larger Version of this Image (72K GIF file)]
Despite the widely distributed expression pattern of PS1, PS2, and APP transcripts, not all neuronal populations express all of these transcripts at high levels. In general, APP mRNA is abundant in most neurons, as previously reported (Bendotti et al., 1988
Coronal sections through the caudate at the level anterior to hippocampus and sections through caudal hippocampus at the level of entorhinal cortex and substantia nigra show high levels of APP mRNA expression in all cortical and subcortical regions (Fig. 6A,D), including neurons in the thalamus, lateral amygdyla, and substantia nigra as well as cortical and hippocampal neurons. Examination of PS1 and PS2 mRNA in adjacent sections shows that, in addition to cells in the hippocampus, presenilin transcripts are expressed prominently in neurons of subiculum and entorhinal cortex (Fig. 6E,F). However, unlike APP mRNA, presenilin mRNA expression in nigral neurons and in the lateral amygdala was unremarkable (Fig. 6D-F). With the possible exception of the caudate putamen, the general distribution of PS2 mRNA is similar to that observed for PS1 mRNA (Fig. 6B,C). 
Fig. 6. Distribution of APP, PS1, and PS2 mRNA expression at the level of caudate and entorhinal cortex. A-C, Coronal sections through the caudate putamen at the level anterior to hippocampus hybridized with antisense riboprobes specific for APP (A), PS1 (B), or PS2 (C) mRNA. In lateral amygdyla, APP mRNA is expressed at high levels relative to PS1 and PS2 transcripts. Also note that, whereas the level of PS1 mRNA in caudate putamen is qualitatively similar to other cortical regions in this section, PS2 mRNA is much more prominent in the CP relative to neighboring cortical regions. CP, Caudate putamen; HT, hypothalamus; LA, lateral amygdyla, POC, primary olfactory cortex; Th, thalamus. D-F, Coronal section through caudal hippocampus at the level of entorhinal cortex (EC) and substantia nigra (SN) hybridized with antisense riboprobes specific for APP (D), PS1 (E), and PS2 (F). All three transcripts are distributed throughout this coronal section with significant expression of APP, PS1, and PS2 mRNAs in hippocampus, entorhinal cortex, and amygdyla. APP mRNA level is very high in SN neurons, whereas PS1 and PS2 mRNAs are expressed at similar levels in SN and regions adjacent to it. A, Amygdyla; CA1, CA3, the CA-fields of hippocampus; D, dentate gyrus; M, mamillary body.
[View Larger Version of this Image (128K GIF file)]
Finally, analysis of PS1 and PS2 transcripts in the cerebellum shows high levels of presenilin expression in granule cells, Purkinje cells, and neurons in the pons (Fig. 7). Grains over smaller nuclei located in the Purkinje cell layer suggest that PS1 and PS2 mRNAs also may be expressed in Bergmann glia or other supporting cells (Fig. 7). In contrast to the general expression pattern seen with PS1/PS2, the highest level of APP expression in cerebellum is limited to the Purkinje cells and the deep cerebellar nuclei (Sola et al., 1993 
Fig. 7. Expression of PS1 and PS2 mRNAs in cerebellum. A, C, Dark-field microscopy images of sagittal section through cerebellum and pons hybridized with antisense riboprobe for PS1 (A) and PS2 (B). B, D, High power view of cerebellar cortex showing PS1 (B) and PS2 (D) mRNA-associated silver grains over granule cell layer (gcl) and Purkinje cells (arrows) in Purkinje cell layer (pcl). Note that grains in pcl are not restricted to Purkinje cells, and the cells in the molecular layer (ml) also show specific hybridization. Scale bar, B, D, 75 µm.
[View Larger Version of this Image (171K GIF file)]
Accumulation of proteolytically processed PS1 derivatives in mouse brain and tissues
To complement our analysis of PS1 mRNA expression, we examined the expression of PS1 protein by immunoblot analysis. We detected PS1 protein in whole SDS-soluble extracts of mouse brain regions and selected non-neural tissues by using a rabbit polyclonal antibody, Ab14, generated against the N-terminal 25 amino acids of PS1 and a rabbit polyclonal antibody,
Immunoblot analysis of mouse brain regions, cranial nerves, and peripheral tissues reveals that PS1 accumulates as two principal fragments (Fig. 8). Notably, although the Ab14-reactive ~28 kDa N-terminal fragment resolves as a doublet with possibly a third minor species, only a single C-terminal fragment is detected in most non-neural tissues. The apparent heterogeneity of the N-terminal fragment suggests that PS1 may be subject to tissue-specific post-translational modifications or, alternatively, be encoded by alternatively spliced transcripts. In support of the latter idea, alternatively spliced human PS1 mRNA has been identified in lymphoblasts, liver, spleen, and kidney (Rogaev et al., 1995 
Fig. 8. Accumulation of processed PS1 fragments in mouse tissues. SDS-soluble extracts from mouse neural (olfactory bulb, lane 1; caudate putamen, lane 2; thalamus, lane 3; neocortex, lane 4; hippocampus, lane 5; cerebellum, lane 6; brain stem, lane 7; optic nerve, lane 8) and non-neural (heart, lane 9; kidney, lane 10; liver, lane 11; lung, lane 12; small intestine, lane 13; spleen, lane 14) tissues were immunoblotted and probed with PS1-specific Ab14 (A) or
[View Larger Version of this Image (58K GIF file)]
Our semi-quantitative analysis of total levels of PS1 in mouse neocortex revealed that the PS1 accumulates to <0.001% of total brain protein (Thinakaran et al., 1996 Expression of PS1 and PS2 in cultured mouse neurons and glia
To confirm the cellular specificities of PS1 and PS2 expression in neural tissues, we examined the expression of PS1 and PS2 mRNAs in primary cultures of mouse cortical neurons and glia by using optimized RT-PCR conditions (Fig. 9A). Our studies clearly show that cultured mouse neurons and glia express similar levels of PS1 and PS2 mRNA (Fig. 9A). To examine the relative levels and the nature of the accumulated PS1 protein SDS-extracts prepared from neurons and glia, we performed immunoblotting with the two anti-PS1 antibodies described above (Fig. 8). Immunoblot analysis demonstrated that both neurons and glia accumulate similar levels of N-terminal and C-terminal fragments (Fig. 9B). To establish the purity of neuronal and glial cultures, we subjected extracts from each culture to immunoblot analysis with antibodies specific for neuron-specificImmunocytochemical localization of PS1 in mouse brain
To date, only a single report has attempted to localize PS1 in brain (Moussaoui et al., 1996
Fig. 10. Immunohistochemical localization of PS1 in mouse brain. A,
[View Larger Version of this Image (183K GIF file)]
DISCUSSION
To address the potential functional role(s) of presenilins during development and to provide a conceptual framework that relates presenilin expression and selective neuronal vulnerability in AD, we examined the expression of presenilins 1 and 2 during embryonic development and in mature brain. The present studies provide new information concerning the expression of presenilin transcripts and protein, the potential biological function(s) of PS, and the roles of PS in the pathogenesis of AD.
First, and in contrast with earlier Northern blotting studies concluding that PS2 mRNA is expressed at low levels relative to PS1 mRNA, our quantitative RT-PCR studies revealed that, although both PS1 and PS2 transcripts are expressed in many tissues, the relative levels of PS1/PS2 expression can vary significantly between tissues and during brain development. Thus, although the structural conservation and relatively ubiquitous expression pattern of PS1 and PS2 mRNAs suggest some degree of functional redundancy, differences in relative levels of expression suggest that PS1 and PS2 may play different biological roles in tissue- or development-specific processes.
Second, in view of the demonstration that sel-12, a C. elegans homolog of presenilins, mediates developmental cell-fate decisions elicited by lin-12 (Levitan and Greenwald, 1995
Third, our in situ hybridization analysis of adult mouse brain reveals that both PS1 and PS2 transcripts are expressed in a variety of neuronal populations. Moreover, prominent expression of presenilin transcripts in neurons supports the view that mutations in presenilin genes cause FAD by directly compromising neuronal function. However, in view of significant levels of presenilin mRNA expression in glial cells, pathogenic mechanisms involving glial cells cannot be excluded. Most notable is our finding that neuronal populations known to be at risk in AD coexpress high levels of APP and presenilin transcripts. For example, neurons in the hippocampal CA-fields, neurons of the medial and cortical amygdala, and neocortical neurons express presenilins and APP transcripts at high levels. In contrast, neurons in regions less prone to AD-associated pathology express these transcripts at more variable levels. For example, granule cells in the dentate gyrus and cerebellum express high levels of presenilins mRNA but lower levels of APP mRNA; in contrast, neurons in lateral amygdala and substantia nigra express high levels of APP mRNA but low levels of presenilin transcripts. Thus, our demonstration of high-level presenilin mRNA expression in neurons known to be at risk in AD further supports the view, proposed earlier by Kovacs et al. (1996)
Fourth, our studies are the first to examine the expression and distribution of PS1 by using two highly specific antibodies generated against independent epitopes of PS1. We document that PS1 protein accumulates as two proteolytically processed fragments in all tissues examined, similar to our earlier description of PS1 derivatives in human, primate, and rodent brain and brains of transgenic mice expressing human PS1 (Thinakaran et al., 1996
Finally, our immunocytochemical studies of mouse brain provide strong evidence for the ubiquitous and prominent accumulation of PS1 polypeptides in neurons. PS1-IR in neurons is localized primarily to somatodendritic compartments, but strong neuropil PS1-IR is also evident. The neuropil-specific PS1-IR may correspond to PS1 within axon terminals, a view supported by our demonstration of prominent PS1-IR in the stratum lucidum of CA3, an area enriched in mossy fiber terminals. Alternatively, neuropil-IR may correspond to distal dendrites or to glial processes. In this regard, and despite our demonstration that low levels of PS1 protein accumulate in cranial nerves (Fig. 8A,B), PS1 mRNA expression in glial cells (Figs. 5B, 9B), and PS1 protein accumulation in cultured glial cells (Fig. 9B), we rarely detected PS1-IR in glial cell bodies in the neuropil. However, in view of findings that certain glial proteins (e.g., glial glutamate transporters; Rothstein et al., 1994
FOOTNOTES
Received Aug. 13, 1996; revised Sept. 11, 1996; accepted Sept. 16, 1996.
This work was supported by National Institutes of Health Grants AG05146 and NS20471 and by grants from the Adler Foundation and the Develbiss Fund. S.S.S. is the recipient of an Alzheimer's Association Zenith Award. We thank Cornelia Von Koch [Johns Hopkins Medical Institutes (JHMI), Baltimore, MD] for providing mouse embryos, Donna Suresch for technical help with tissue sections, and Dr. Juan Troncoso (JHMI) for helpful discussions.
Correspondence should be addressed to Dr. Sangram S. Sisodia, The Johns Hopkins University School of Medicine, Neuropathology Laboratory, 558 Ross Research Building, 720 Rutland Avenue, Baltimore, MD 21205-2196.
REFERENCES
- (1995) The structure of the presenilin 1 (S182) gene and identification of six novel mutations in early onset AD families. Nat Genet 11:219-222. [Web of Science][Medline]
- Bendotti C, Forloni GL, Morgan RA, O'Hara BF, Oster-Granite ML, Reeves RH, Gearhart JD, Coyle JT (1988) Neuroanatomical localization and quantification of amyloid precursor protein mRNA by in situ hybridization in the brains of normal, aneuploid, and lesioned mice. Proc Natl Acad Sci USA 85:3628-3632 .
[Abstract/Free Full Text] - Boteva K, Vitek M, Mitsuda H, de Silva H, Xu P-T, Small G, Gilbert JR (1996) Mutation analysis of presenilin 1 gene in Alzheimer's disease. Lancet 347:130-131 . [Web of Science][Medline]
- Campion D, Flaman JM, Brice A, Hannequin D, Dubois B, Martin C, Moreau V, Charbonnier F, Didierjean O, Tardieu S, Penet C, Puel M, Pasquier F, Ledoze F, Bellis G, Calenda A, Heilig R, Martinez M, Mallet J, Bellis M, Clergetdarpoux F, Agid Y, Frebourg T (1995) Mutations of the presenilin 1 gene in families with early-onset Alzheimer's disease. Hum Mol Genet 4:2373-2377 .
[Abstract/Free Full Text] - Chapman J, Asherov A, Wang N, Treves TA, Korczyn AD, Goldfarb LG (1995) Familial Alzheimer's disease associated with S182 codon 286 mutation. Lancet 346:1040 . [Web of Science][Medline]
- Chelly J, Kaplan JC, Maire P, Gautron S, Kahn A (1988) Transcription of the dystrophin gene in human muscle and non-muscle tissues. Nature 333:958-960.
- Chirgwin JM, Przybyla AE, MacDonald RJ, Rutter WJ (1979) Isolation of biologically active ribonucleic acid from sources enriched in ribonuclease. Biochemistry 18:5294-5299 . [Medline]
- Golde TE, Estus SE, Usiak M, Yunkin LH, Younkin SG (1990) Expression of
- Hertz L, Juurlink H, Szuchet S, Walz W (1985) Cell and tissue cultures. In: Neuromethods 1 (Boulton, AA, Baker, GB, eds) , p. 117. Clifton, NJ: Humana.
- Hyman BT, Wenniger JJ, Tanzi RE (1993) Nonisotopic in situ hybridization of amyloid beta protein precursor in Alzheimer's disease: expression in neurofibrillary tangle-bearing neurons and in the microenvironment surrounding senile plaques. Mol Brain Res 18:253-258 . [Medline]
- Kovacs DM, Fausett HJ, Page KJ, Kim T-W, Moir RD, Merriam DE, Hollister RD, Hallmark OG, Mancini R, Felsenstein KM, Hyman BT, Tanzi RE, Wasco W (1996) Alzheimer-associated presenilins 1 and 2: neuronal expression in brain and localization to intracellular membranes in mammalian cells. Nat Med 2:224-229 . [Web of Science][Medline]
- Laemmlie UK (1970) Cleavage of structural proteins during the assembly of the head of bacteriophage T4. Nature 227:680-685. [Medline]
- Lardelli M, Dahlstrand J, Lendahl U (1994) The novel notch homologue mouse Notch 3 lacks specific epidermal growth factor-repeats and is expressed in proliferating neuroepithelium. Mech Dev 46:123-136 . [Web of Science][Medline]
- Lee MK, Tuttle JB, Rebhun LI, Cleveland DW, Frankfurter AF (1990) Expression and post-translational modification of a neuron-specific beta-tubulin isotope during chick embryogenesis. Cell Motil Cytoskeleton 17:118-132 . [Web of Science][Medline]
- Lemere CA, Lopera F, Kosik KS, Ossa J, Saido TC, Ruiz A, Martinez A, Madrigol L, Hincapie L, Arango JC, Selkoe DJ, Arango JC (1996) Immunocytochemical characterization of plaques, tangles, and vascular amyloid in the brains of 2 FAD patients with an identified PS1 mutation. Neurobiol Aging [Suppl] 17:S17.
- Levitan D, Greenwald I (1995) Facilitation of lin-12-mediated signalling by sel-12, a Caenorhabditis elegans S182 Alzheimer's disease gene. Nature 377:351-354 . [Medline]
- Levy-Lahad E, Wijsman EM, Nemens E, Anderson L, Goddard KAB, Weber JL, Bird TD, Schellenberg GD (1995a) A familial Alzheimer's disease locus on chromosome 1. Science 269:970-973 .
[Abstract/Free Full Text] - Levy-Lahad E, Wasco W, Poorkaj P, Romano DM, Oshima J, Pettingell WH, Yu C-E, Jondro PD, Schmidt SD, Wang K, Crowley AC, Fu Y-H, Guenette SY, Galas D, Nemens E, Wijsman EM, Bird TD, Schellenberg GD, Tanzi RE (1995b) Candidate gene for the chromosome 1 familial Alzheimer's disease locus. Science 269:973-977 .
[Abstract/Free Full Text] - L'Hernault SW, Arduengo PM (1992) Mutation of a putative sperm membrane protein in Caenorhabditis elegans prevents sperm differentiation but not its associated meiotic divisions. J Cell Biol 119:55-68.
[Abstract/Free Full Text] - Lindsell CE, Shawber CJ, Boulter J, Weinmaster G (1995) Jagged: a mammalian ligand that activates Notch 1. Cell 80:909-917 . [Web of Science][Medline]
- Martin LJ, Sisodia SS, Koo EH, Cork LC, Dellovade TL, Weidmann A, Beyreuther K, Masters C, Price DL (1991) Amyloid precursor protein in aged nonhuman primates. Proc Natl Acad Sci USA 88:1461-1465 .
[Abstract/Free Full Text] - Moussaoui S, Czech C, Pradier L, Blanchard V, Boniei B, Gohin M, Imperato A, Revah F (1996) Immunohistochemical analysis of presenilin-1 expression in the mouse brain. FEBS Lett 383:219-222. [Web of Science][Medline]
- Neve RL, Finch EA, Dawes LR (1988) Expression of the Alzheimer amyloid precursor gene transcripts in the human brain. Neuron 1:667-677.
- Pereztur J, Froelich S, Prihar G, Crook R, Baker M, Duff K, Wragg M, Busfield F, Lendon C, Clark RF, Roques P, Fuldner RA, Johnston J, Cowburn R, Forsell C, Axelman K, Lilius L, Houlden H, Karran E, Roberts GW, Rossor M, Adams MD, Hardy J, Goate A, Lannfelt L, Hutton M (1995) A mutation in Alzheimer's disease destroying a splice acceptor site in the presenilin-1 gene. NeuroReport 7:297-301. [Web of Science][Medline]
- Reaume AG, Conlon RA, Zirngibl R, Yamaguchi TP, Rossant J (1992) Expression analysis of a Notch homologue in the mouse embryo. Dev Biol 154:377-387 . [Web of Science][Medline]
- Rogaev EI, Sherrington R, Rogaeva EA, Levesque G, Ikeda M, Liang Y, Chi H, Lin C, Holman K, Tsuda T, Mar L, Sorbi S, Nacmias B, Piacentini S, Amaducci L, Chumakov I, Cohen D, Lannfelt L, Fraser PE, Rommens JM, St. George-Hyslop PH (1995) Familial Alzheimer's disease in kindreds with missense mutations in a gene on chromosome 1 related to the Alzheimer's disease type 3 gene. Nature 376:775-778 . [Medline]
- Rothstein JD, Martin L, Levey A, Dykes-Hoberg M, Jin L, Wu D, Nash N, Kuncl R (1994) Localization of neuronal and glial glutamate transporters. Neuron 13:713-725 . [Web of Science][Medline]
- Sahara N, Yahagi Y, Takagi H, Kondo T, Okochi M, Usami M, Shirasawa T, Mori H (1996) Identification and characterization of presenilin I-467, I-463, and I374. FEBS Lett 381:7-11 . [Web of Science][Medline]
- Schellenberg GD (1995) Genetic dissection of Alzheimer disease, a heterogeneous disorder. Proc Natl Acad Sci USA 92:8552-8559 .
[Abstract/Free Full Text] - Scheuner D, Eckman C, Jensen M, Song X, Citron M, Suzuki N, Bird TD, Hardy J, Hutton M, Kukull W, Larson E, Levy-Lahad E, Viitanen M, Peskind E, Poorkaj P, Schellenberg G, Tanzi R, Wasco W, Lannfelt L, Selkoe D, Younkin S (1996) The amyloid
- Selkoe DJ (1995) Missense on the membrane. Nature 375:734 . [Medline]
- Sherrington R, Rogaev EI, Liang Y, Rogaeva EA, Levesque G, Ikeda M, Chi H, Lin C, Li G, Holman K, Tsuda T, Mar L, Foncin J-F, Bruni AC, Montesi MP, Sorbi S, Rainero I, Pinessi L, Nee L, Chumakov I, Pollen D, Brookes A, Sanseau P, Polinsky RJ, Wasco W, Da Silva HAR, Haines JL, Pericak-Vance MA, Tanzi RE, Roses AD, Fraser PE, Rommens JM, St. George-Hyslop PH (1995) Cloning of a gene bearing missense mutations in early-onset familial Alzheimer's disease. Nature 375:754-760 . [Medline]
- Sisodia SS, Koo EH, Hoffman PH, Perry G, Price DL (1993) Identification and transport of full-length amyloid precursor proteins in rat peripheral nervous system. J Neurosci 13:3136-3142 . [Abstract]
- Slunt HH, Thinakaran G, Von Koch C, Lo ACY, Tanzi RE, Sisodia SS (1994) Expression of a ubiquitous, cross-reactive homologue of the mouse
[Abstract/Free Full Text] - Slunt HH, Thinakaran G, Lee MK, Sisodia SS (1995) Nucleotide sequence of the chromosome 14-encoded S182 cDNA and revised secondary structure prediction. Amyloid. Int J Exp Clin Invest 2:188-190.
- Sola C, Mengod G, Ghetti D, Palacios JM, Triarhou LC (1993) Regional distribution of the alternatively spliced isoforms of
- Spillantini MG, Hunt SP, Ulrich J, Goedert M (1989) Expression and cellular localization of amyloid
- St. George-Hyslop PH, Haines J, Rogaev E, Mortilla M, Vaula G, Pericak-Vance M, Foncin J-F, Montesi M, Bruni A, Sorbi S, Rainero I, Pinessi L, Pollen D, Polinsky R, Nee L, Kennedy J, Macciardi F, Rogaeva E, Liang Y, Alexandrova N, Lukiw W, Schlumpf K, Tanzi R, Tsuda T, Farrer L, Cantu J-M, Duara R, Amaducci L, Bergamini L, Gusella J, Roses A, Crapper McLachlan D (1992) Genetic evidence for a novel familial Alzheimer's disease locus on chromosome 14. Nat Genet 2:330-334. [Web of Science][Medline]
- Suzuki T, Nishiyama K, Murayama S, Yamamoto A, Sato S, Kanazawa I, Sakaki Y (1996) Regional and cellular presenilin 1 gene expression in human and rat tissues. Biochem Biophys Res Commun 219:708-713 . [Web of Science][Medline]
- Tanzi RE, Wenniger JJ, Hyman BT (1993) Cellular specificity and regional distribution of amyloid
- Thinakaran G, Borchelt DR, Lee MK, Slunt H, Spitzer L, Kim G, Ratovitsky T, Davenport F, Norstedt C, Seeger M, Hardy J, Levey A, Gandy SE, Jenkins NA, Copeland NG, Price DL, Sisodia SS (1996) Endoproteolysis of presenilin 1 and accumulation of processed derivatives in vivo. Neuron 17:181-190 . [Web of Science][Medline]
- Towbin H, Staehlin T, Gordon J (1979) Electrophoretic transfer of proteins from polyacrylamide gels to nitrocellulose sheets: procedure and some applications. Proc Natl Acad Sci USA 76:4350-4354 .
[Abstract/Free Full Text] - Wasco W, Pettingell WP, Jondro PD, Schmidt SD, Gurubhagavatula S, Rodes L, DiBlasi T, Romano DM, Guenette SY, Kovacs DM, Growdon JH, Tanzi RE (1995) Familial Alzheimer's chromosome 14 mutations. Nat Med 1:848 . [Web of Science][Medline]
- Weinmaster G, Roberts VJ, Lemke G (1992) Notch 2: a second mammalian Notch gene. Development 116:931-941 . [Abstract]
- Williams R, Lendahl U, Lardelli M (1995) Complementary and combinatorial pattern of Notch gene family expression during early mouse development. Mech Dev 53:357-368 . [Web of Science][Medline]
- Wisniewski HM, Terry RD (1973) Reexamination of the pathogenesis of the senile plaque. In: Progress in neuropathology, Vol 2 (Zimmerman, HM, eds) , p. 1. New York: Grune and Stratton.
Copyright ©1996 Society for Neuroscience 0270-6474/1996/167513-13$05.00/0
This article has been cited by other articles:
H. L. Chai and S. Miura
Accurate Determination of Carboxyl-Terminal Fragment of Presenilin 1 in Various Tissues from Rat and Cell Lines
J. Biochem., July 1, 2009; 146(1): 141 - 148.
[Abstract] [Full Text] [PDF]
J. Ouellet, S. Li, and R. Roy
Notch signalling is required for both dauer maintenance and recovery in C. elegans
Development, August 1, 2008; 135(15): 2583 - 2592.
[Abstract] [Full Text] [PDF]
M.-X. Silveyra, G. Evin, M.-F. Montenegro, C. J. Vidal, S. Martinez, J. G. Culvenor, and J. Saez-Valero
Presenilin 1 Interacts with Acetylcholinesterase and Alters Its Enzymatic Activity and Glycosylation
Mol. Cell. Biol., May 1, 2008; 28(9): 2908 - 2919.
[Abstract] [Full Text] [PDF]
M. Wines-Samuelson and J. Shen
Presenilins in the Developing, Adult, and Aging Cerebral Cortex
Neuroscientist, October 1, 2005; 11(5): 441 - 451.
[Abstract] [PDF]
W. Li, C. Lesuisse, Y. Xu, J. C. Troncoso, D. L. Price, and M. K. Lee
Stabilization of {alpha}-Synuclein Protein with Aging and Familial Parkinson's Disease-Linked A53T Mutation
J. Neurosci., August 18, 2004; 24(33): 7400 - 7409.
[Abstract] [Full Text] [PDF]
Z. Zou, B. Chung, T. Nguyen, S. Mentone, B. Thomson, and D. Biemesderfer
Linking Receptor-mediated Endocytosis and Cell Signaling: EVIDENCE FOR REGULATED INTRAMEMBRANE PROTEOLYSIS OF MEGALIN IN PROXIMAL TUBULE
J. Biol. Chem., August 13, 2004; 279(33): 34302 - 34310.
[Abstract] [Full Text] [PDF]
A. Louvi, S. S. Sisodia, and E. A. Grove
Presenilin 1 in migration and morphogenesis in the central nervous system
Development, July 1, 2004; 131(13): 3093 - 3105.
[Abstract] [Full Text] [PDF]
X.-X. Yan, T. Li, C. M. Rominger, S. R. Prakash, P. C. Wong, R. E. Olson, R. Zaczek, and Y.-W. Li
Binding Sites of {gamma}-Secretase Inhibitors in Rodent Brain: Distribution, Postnatal Development, and Effect of Deafferentation
J. Neurosci., March 24, 2004; 24(12): 2942 - 2952.
[Abstract] [Full Text] [PDF]
C. Lilliehook, O. Bozdagi, J. Yao, M. Gomez-Ramirez, N. F. Zaidi, W. Wasco, S. Gandy, A. C. Santucci, V. Haroutunian, G. W. Huntley, et al.
Altered A{beta} Formation and Long-Term Potentiation in a Calsenilin Knock-Out
J. Neurosci., October 8, 2003; 23(27): 9097 - 9106.
[Abstract] [Full Text] [PDF]
J. Li, G. J. Fici, C.-A. Mao, R. L. Myers, R. Shuang, G. P. Donoho, A. M. Pauley, C. S. Himes, W. Qin, I. Kola, et al.
Positive and Negative Regulation of the {gamma}-Secretase Activity by Nicastrin in a Murine Model
J. Biol. Chem., August 29, 2003; 278(35): 33445 - 33449.
[Abstract] [Full Text] [PDF]
M.-T. Lai, E. Chen, M.-C. Crouthamel, J. DiMuzio-Mower, M. Xu, Q. Huang, E. Price, R. B. Register, X.-P. Shi, D. B. Donoviel, et al.
Presenilin-1 and Presenilin-2 Exhibit Distinct yet Overlapping {gamma}-Secretase Activities
J. Biol. Chem., June 13, 2003; 278(25): 22475 - 22481.
[Abstract] [Full Text] [PDF]
M. K. Lee, W. Stirling, Y. Xu, X. Xu, D. Qui, A. S. Mandir, T. M. Dawson, N. G. Copeland, N. A. Jenkins, and D. L. Price
Human alpha -synuclein-harboring familial Parkinson's disease-linked Ala-53 right-arrow Thr mutation causes neurodegenerative disease with alpha -synuclein aggregation in transgenic mice
PNAS, June 25, 2002; 99(13): 8968 - 8973.
[Abstract] [Full Text] [PDF]
C. Lesuisse, G. Xu, J. Anderson, M. Wong, J. Jankowsky, G. Holtz, V. Gonzalez, P. C. Y. Wong, D. L. Price, F. Tang, et al.
Hyper-expression of human apolipoprotein E4 in astroglia and neurons does not enhance amyloid deposition in transgenic mice
Hum. Mol. Genet., October 1, 2001; 10(22): 2525 - 2537.
[Abstract] [Full Text] [PDF]
C. H. Faux, A. M. Turnley, R. Epa, R. Cappai, and P. F. Bartlett
Interactions between Fibroblast Growth Factors and Notch Regulate Neuronal Differentiation
J. Neurosci., August 1, 2001; 21(15): 5587 - 5596.
[Abstract] [Full Text] [PDF]
R. Kopan and A. Goate
A common enzyme connects Notch signaling and Alzheimer's disease
Genes & Dev., November 15, 2000; 14(22): 2799 - 2806.
[Full Text]
S.-J. JEONG, H.-S. KIM, K.-A CHANG, D.-H. GEUM, C. H. PARK, J.-H. SEO, J.-C. RAH, J. H. LEE, S. H. CHOI, S. G. LEE, et al.
Subcellular localization of presenilins during mouse preimplantation development
FASEB J, November 1, 2000; 14(14): 2171 - 2176.
[Abstract] [Full Text]
J. Theuns and C. Van Broeckhoven
Transcriptional regulation of Alzheimer's disease genes: implications for susceptibility
Hum. Mol. Genet., October 1, 2000; 9(16): 2383 - 2394.
[Abstract] [Full Text] [PDF]
Y Guo, S. Zhang, N Sokol, L Cooley, and G. Boulianne
Physical and genetic interaction of filamin with presenilin in Drosophila
J. Cell Sci., January 10, 2000; 113(19): 3499 - 3508.
[Abstract] [PDF]
D. B. Donoviel, A.-K. Hadjantonakis, M. Ikeda, H. Zheng, P. S. G. Hyslop, and A. Bernstein
Mice lacking both presenilin genes exhibitearlyembryonic patterningdefects
Genes & Dev., November 1, 1999; 13(21): 2801 - 2810.
[Abstract] [Full Text]
A. Herreman, D. Hartmann, W. Annaert, P. Saftig, K. Craessaerts, L. Serneels, L. Umans, V. Schrijvers, F. Checler, H. Vanderstichele, et al.
Presenilin 2 deficiency causes a mild pulmonary phenotype and no changes in amyloid precursor protein processing but enhances the embryonic lethal phenotype of presenilin 1 deficiency
PNAS, October 12, 1999; 96(21): 11872 - 11877.
[Abstract] [Full Text] [PDF]
H. Steiner, K. Duff, A. Capell, H. Romig, M. G. Grim, S. Lincoln, J. Hardy, X. Yu, M. Picciano, K. Fechteler, et al.
A Loss of Function Mutation of Presenilin-2 Interferes with Amyloid beta -Peptide Production and Notch Signaling
J. Biol. Chem., October 1, 1999; 274(40): 28669 - 28673.
[Abstract] [Full Text] [PDF]
M. Pastorcic and H. K. Das
An Upstream Element Containing an ETS Binding Site Is Crucial for Transcription of the Human Presenilin-1 Gene
J. Biol. Chem., August 20, 1999; 274(34): 24297 - 24307.
[Abstract] [Full Text] [PDF]
A. L. Schwarzman, N. Singh, M. Tsiper, L. Gregori, A. Dranovsky, M. P. Vitek, C. G. Glabe, P. H. St. George-Hyslop, and D. Goldgaber
Endogenous presenilin 1 redistributes to the surface of lamellipodia upon adhesion of Jurkat cells to a collagen matrix
PNAS, July 6, 1999; 96(14): 7932 - 7937.
[Abstract] [Full Text] [PDF]
B. Stahl, A. Diehlmann, and T. C. Sudhof
Direct Interaction of Alzheimer's Disease-related Presenilin 1 with Armadillo Protein p0071
J. Biol. Chem., April 2, 1999; 274(14): 9141 - 9148.
[Abstract] [Full Text] [PDF]
C.-S. Hong, L. Caromile, Y. Nomata, H. Mori, D. E. Bredesen, and E. H. Koo
Contrasting Role of Presenilin-1 and Presenilin-2 in Neuronal Differentiation In Vitro
J. Neurosci., January 15, 1999; 19(2): 637 - 643.
[Abstract] [Full Text] [PDF]
D. L. Price, S. S. Sisodia, and D. R. Borchelt
Genetic Neurodegenerative Diseases: The Human Illness and Transgenic Models
Science, November 6, 1998; 282(5391): 1079 - 1083.
[Abstract] [Full Text]
Q. Guo, N. Robinson, and M. P. Mattson
Secreted beta -Amyloid Precursor Protein Counteracts the Proapoptotic Action of Mutant Presenilin-1 by Activation of NF-kappa B and Stabilization of Calcium Homeostasis
J. Biol. Chem., May 15, 1998; 273(20): 12341 - 12351.
[Abstract] [Full Text] [PDF]
W. Zhang, S. W. Han, D. W. McKeel, A. Goate, and J. Y. Wu
Interaction of Presenilins with the Filamin Family of Actin-Binding Proteins
J. Neurosci., February 1, 1998; 18(3): 914 - 922.
[Abstract] [Full Text] [PDF]
G. Thinakaran, C. L. Harris, T. Ratovitski, F. Davenport, H. H. Slunt, D. L. Price, D. R. Borchelt, and S. S. Sisodia
Evidence That Levels of Presenilins (PS1 and PS2) Are Coordinately Regulated by Competition for Limiting Cellular Factors
J. Biol. Chem., November 7, 1997; 272(45): 28415 - 28422.
[Abstract] [Full Text] [PDF]
S. Janicki and M. J. Monteiro
Increased Apoptosis Arising from Increased Expression of the Alzheimer's Disease-associated Presenilin-2 Mutation (N141I)
J. Cell Biol., October 20, 1997; 139(2): 485 - 495.
[Abstract] [Full Text] [PDF]
H. Loetscher, U. Deuschle, M. Brockhaus, D. Reinhardt, P. Nelboeck, J. Mous, J. Grunberg, C. Haass, and H. Jacobsen
Presenilins Are Processed by Caspase-type Proteases
J. Biol. Chem., August 15, 1997; 272(33): 20655 - 20659.
[Abstract] [Full Text] [PDF]
J. Busciglio, H. Hartmann, A. Lorenzo, C. Wong, K. Baumann, B. Sommer, M. Staufenbiel, and B. A. Yankner
Neuronal Localization of Presenilin-1 and Association with Amyloid Plaques and Neurofibrillary Tangles in Alzheimer's Disease
J. Neurosci., July 1, 1997; 17(13): 5101 - 5107.
[Abstract] [Full Text] [PDF]
H. Hartmann, J. Busciglio, K.-H. Baumann, M. Staufenbiel, and B. A. Yankner
Developmental Regulation of Presenilin-1 Processing in the Brain Suggests a Role in Neuronal Differentiation
J. Biol. Chem., June 6, 1997; 272(23): 14505 - 14508.
[Abstract] [Full Text] [PDF]
T.-W. Kim, W. H. Pettingell, O. G. Hallmark, R. D. Moir, W. Wasco, and R. E. Tanzi
Endoproteolytic Cleavage and Proteasomal Degradation of Presenilin 2in Transfected Cells
J. Biol. Chem., April 25, 1997; 272(17): 11006 - 11010.
[Abstract] [Full Text] [PDF]
D.L. Price, D.R. Borchelt, P.C. Wong, C.A. Pardo, G. Thinakaran, M.K. Lee, D.W. Cleveland, and S.S. Sisodia
Neurodegenerative Diseases and Model Systems
Cold Spring Harb Symp Quant Biol, January 1, 1996; 61(0): 725 - 738.
[Abstract] [PDF]
N. Mitsuda, N. Ohkubo, M. Tamatani, Y.-D. Lee, M. Taniguchi, K. Namikawa, H. Kiyama, A. Yamaguchi, N. Sato, K. Sakata, et al.
Activated cAMP-response Element-binding Protein Regulates Neuronal Expression of Presenilin-1
J. Biol. Chem., March 23, 2001; 276(13): 9688 - 9698.
[Abstract] [Full Text] [PDF]
This Article Abstract 
Full Text (PDF) Submit an eLetter Alert me when this article is cited Alert me when eLetters are posted Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in Web of Science Similar articles in PubMed Alert me to new issues of the journal Download to citation manager 
Citing Articles Citing Articles via HighWire Citing Articles via Web of Science (175) Citing Articles via Google Scholar Google Scholar Articles by Lee, M. K. Articles by Sisodia, S. S. Search for Related Content PubMed PubMed Citation Articles by Lee, M. K. Articles by Sisodia, S. S.
ABSTRACT
|
|
|
|
 |
|