Abstract
Many changes have been described in the brains of Alzheimer’s disease (AD) patients, including loss of neurons and formation of senile plaques and neurofibrillary tangles. The molecular mechanisms underlying these pathologies are unclear. Northern blot, dot-blot, and reverse transcription-coupled PCR analyses have demonstrated altered expression levels of multiple messages in AD brain. Because not all cells are equally affected by the disease, these methods obviously cannot study the changes in relation to disease states of individual cells. We address this problem by using antisense RNA profiling of single cells. We present expression profiles of single neurons at early and late stages of AD and describe statistical tools for data analysis. With multivariate canonical analysis, we were able to distinguish the disease state on the basis of altered expression of multiple messages. To validate this approach, we compared results obtained by this approach with results obtained by in situ hybridization analysis. When the neurofilament medium subunit was used as a marker, our results from an antisense RNA profiling revealed no change in neurofilament medium subunit expression between early- and late-stage AD, consistent with findings obtained with in situ hybridization. However, our results obtained by either analysis at the single-cell level differed from the reported decrease in AD neocortex obtained by Northern blot analysis [Kittur, S., Hoh, J., Endo, H., Tourtellotte, W., Weeks, B. S., Markesbery, W. & Adler, W. (1994) J. Geriatr. Psychiatry Neurol. 7, 153–158]. Thus, the strategy of using the single-cell antisense RNA approach to identify altered gene expression in postmortem AD brain, followed by detailed in situ hybridization studies for genes of interest, is valuable in the study of the molecular mechanisms underlying AD neuropathology.
The traditional markers of Alzheimer’s disease (AD) have been the extracellular senile plaque, an aggregate of β-amyloid peptides (1, 2), and the intracellular neurofibrillary tangle, a mass of irregularly folded proteins composed mainly of hyperphosphorylated tau protein (3, 4). Although a great deal has been learned about these two lesions, our understanding of how they may fit into the pathological cascade of AD and the mechanism(s) by which they may affect the functioning of the brain is incomplete. Significantly, even within a microscopically small sample of brain, some neurons contain neurofibrillary tangles or other markers of disease, whereas other neighboring neurons appear to be normal. For this reason, we argue that even within one cell type in one region of one brain, cells representing a spectrum of disease states may be found. In addition, any small brain region will contain multiple neuronal phenotypes, glia, vascular cells, extracellular material, etc. This, then, emphasizes the importance of conducting analyses at the level of single cells.
Previous studies using single or double immunohistochemistry combined with in situ hybridization (ISH) to describe differential changes in a limited number of message levels (5, 6) led to the concept of profiles of message expression within single neurons, with these profiles changing as disease progresses in each neuron. To aid in the analysis of profiles of expression in single neurons from early- and late-stage AD brains, we applied the antisense RNA (aRNA) amplification methodology (7) to single neurons from postmortem human brain so that we could simultaneously evaluate multiple messages from a single neuron (8).
Since the development of this methodology in 1992 (7), the aRNA amplification procedure has been applied to a variety of studies, including reports on the molecular pathophysiology of tuber formation in tuberous sclerosis by using archival human brain tissues (9), molecular alterations in teratogen-induced neural tube defects in a mouse model (10, 11), differential expression of mRNAs for 16 subtypes of the glutamate receptor in rat striatal neurons (12), and molecular characterization of the dendritic growth cone in cultured primary neurons of rat hippocampus (13). In this study, we use the aRNA method to study single neurons from postmortem AD tissue and present an integrative picture of gene expression at the single cell level. To validate the results obtained with the aRNA method, we performed related ISH with a selected gene. The results in gene expression obtained by the aRNA method were consistent with the results obtained by the established ISH analysis.
MATERIALS AND METHODS
Tissue Acquisition and Processing.
Tissues containing the hippocampal formation were obtained at autopsy from presumptive control and AD brains. All the tissues were well characterized by the Clinical and Neuropathological Cores of the Rochester Alzheimer’s Disease Center. The information on the tissues used in this study is summarized in Table 1. In all the AD samples, AD was the primary disease of the patient. The age-matched “control” samples, although clinically nondemented, on subsequent neuropathological examination were assessed at Braak stage I–III (14) and were, therefore, classified as early AD for this study. For single-cell aRNA study, fresh tissues were processed immediately at autopsy as described (8). In brief, cell layers in the CA1 and subiculum were dissected, trypsinized, smeared gently on microscope slides, fixed in 70% ethanol/150 mM NaCl, and stored at −80°C until use. For ISH, fresh tissues were fixed in 4% paraformaldehyde, cryoprotected in 30% sucrose, and kept frozen at −80°C until use.
Table 1.
Case sample | Braak stage | Age, years | Gender | PMD, h | Experiment |
---|---|---|---|---|---|
95A-208 | I | 75 | M | 4 | ISH |
96A-101 | II | 80 | M | 8 | aRNA |
96A-147 | II–III | 97 | F | 6.5 | aRNA, ISH |
94A-253 | VI | 88 | F | 5.5 | ISH |
94A-258 | V | 87 | M | 3 | ISH |
95A-254 | VI | 74 | M | 6 | ISH |
96A-041 | VI | 81 | F | NA | aRNA |
96A-072 | V | 91 | F | 10 | aRNA |
97A-063 | VI | 73 | M | 6 | aRNA |
M, male; F, female; PMD, postmortem delay; NA, not available.
aRNA Profiling.
Large pyramidal neurons were isolated from tissue smears under microscopy with micropipettes. To obtain enough material from single cells for gene expression analysis, mRNA from single cells was amplified according to Eberwine et al. (7) with modifications. In brief, single cells were treated with DNase I (Life Technologies) followed by reverse transcription with SuperScript II (Life Technologies) according to manufacturer’s instructions. The second-strand cDNA was synthesized by a replacement reaction. The double-stranded cDNA was then used as a template for in vitro transcription with T7 RNA polymerase. Because the RNA made in this way is antisense, the procedure is called single-cell antisense RNA (aRNA) amplification. After initial amplification, aRNA served as a template for second-round cDNA synthesis, followed by second aRNA synthesis in the presence of [α-32P]CTP (NEN). The radiolabeled aRNA was hydrolyzed in 0.2 M sodium carbonate (pH 10.2) at 60°C for 40 min and used as a probe for reverse dot-blot hybridization analysis. One microgram of each linearized cDNA was denatured and dot-blotted on a nylon membrane (Micron Separations). For each 32P-labeled aRNA from a cell, duplicated dot blots were used for each hybridization reaction. Hybridization was performed as described (8), and the membranes were exposed to a storage phosphor screen for quantification. Hybridization intensity of each spot was detected by laser densitometric scanning (PhosphorImager model 425E, Molecular Dynamics). To normalize for the amount of plasmid DNA on each spot, membranes were stripped by incubating in hybridization solution without dextran sulfate at 65°C for 1 h and reprobed with end-labeled oligonucleotide (TAATACGACTCACTATAGGG) specific to the T7 promoter region in plasmid vectors such as pBluescript and pT7T3D.
We searched the National Center for Biotechnology Information dbEST database for 3′ cDNAs of interest and purchased them from the distributors (Genome Systems, Genetic Research, or American Type Culture Collection). [The cDNA clones used in this study (with their GenBank accession nos. in parentheses) are as follows: α1-antichymotrypsin (α1-ACT, T40002), glyceraldehyde-3-phosphate dehydrogenase (GAPDH, T71597), heat shock protein 27 (HSP27, T49404), HSP90 (T51115), neurofilament-M (NF-M, T29264), ferritin L (AA112158), ferritin H (AA111970), ras-like protein (TC25, AA112882), CDK4 (AA113040), cyclin B1 (AA113937), cyclin G1 (AA114184), cyclin E (T54121), wee1 (T63957), and αB-crystallin (AA192311).] Several cDNA clones, including cAMP-responsive element binding protein (CREB), nestin, cyclin D1, tuberin, and glutamate decarboxylase (GAD), were gifts from James Eberwine (University of Pennsylvania). Presenilin 1 cDNA was a gift from Rachael Neve (Harvard University, Boston). All of the 20 cDNA clones used in this study were sequenced to ensure the identity of cDNAs. It should be noted that if a cDNA has a region that is highly conserved among members of the gene family, cross-reactivity upon hybridization is expected.
RNA Preparation for “Spiking” Experiment.
Three λ DNA HindIII fragments of various length (0.5, 2.0, and 6.6 kb) were subcloned into a pSP64 poly(A) vector (Promega). Linearized plasmid DNA was used for in vitro transcription to generate a large quantity of artificial λ poly(A)+ RNA. The molar concentration of each λ RNA was determined by spectrophotometry at 260 nm. Total human RNA was isolated from hippocampus of a non-AD sample by using Trizol reagent (Life Technologies) and quantified. Three λ RNAs were mixed at equal amounts, diluted in a 5-fold series (1:5, 1:25, 1:125, and 1:625), and added to total human hippocampal RNA. The spiked and unspiked RNAs were taken through one cycle of amplification as described above. The radiolabeled aRNA was used for reverse dot-blot with λ plasmid DNA. For reprobing the blot, oligonucleotide probe GATTTAGGTGACACTATAG specific to the SP6 promoter in pSP64 poly(A) vector was used.
Statistical Analysis.
In these studies we sampled a number of neurons from both early- and late-stage AD brains. A total of seven cells were analyzed in duplicate from each brain. For each cell, measurements were made on a total of 20 genes. The data were normalized in two stages, first using individual vector measurements and then using the average of each marker across all cells. The resulting standardized data were analyzed statistically to determine differences between early- and late-stage AD brains.
The first level of analysis involved univariate analysis of variance (ANOVA) for each of the 20 markers. In the ANOVA model, cells were nested within brains that were classified as either early- or late-stage AD so that brain were nested within disease state. In this nested model, the comparison of early- and late-stage AD brains is essentially a t test using the brain means and having degrees of freedom equal to the number of brains minus 2, illustrating the importance of including as many brains as possible in the analysis. In addition, the ANOVA provides estimates of variability among replicate measurements, cells, and brains.
Because a large number of markers was included in these analyses, it was also important to describe the overall pattern of difference between early- and late-stage AD brains across all the markers. For this reason we also performed multivariate analysis by using a canonical discriminant analysis (15). This is essentially a data reduction technique that computes linear combinations (weighted sums) of the original variables to yield a set of canonical variables. The first canonical variable provides the maximal amount of information concerning group differences and subsequent canonical variables are uncorrelated with earlier variables and contain the maximal amount of the remaining information. Unlike principal components analysis, canonical analysis relies on predefined groups. The goal of the analysis is to summarize information on group differences in the data using the canonical variables. The analysis is usually descriptive, and plots of the first two or three canonical variables and of the listing standardized original values contributing most heavily to the canonical variables are examined. Because canonical analysis relies on predefined groups, we did unrelated analyses in which we defined either two or five groups. When two groups were delineated, cells were defined as derived from either late- or early-stage AD brain. When five groups were delineated, cells were defined as derived from each of the five brains studied, with no information provided as to disease state. This latter definition is a conservative approach from the point of view of distinguishing brains at different disease stages and should more objectively allow us to evaluate differences between early- and late-stage AD brains.
ISH.
A partial neurofilament medium subunit (NF-M) cDNA clone (GenBank accession no. T29264) in pT7T3D plasmid vector was purchased (Genetic Research) and sequenced. This clone contains the last 109 bp of the coding region (base pairs 5,442–5,551) and a 227-bp 3′-untranslated region, base pairs 5,442–5,778, based on the sequence published by Myers et al. (16). The entire sequence is unique to NF-M, with no sequence homology to neurofilament light or heavy subunit. RNA probes were made in the presence of 35S-labeled UTP by using the Promega Riboprobe system. Methods for ISH were as described (17), with modifications for fixed human postmortem tissue (5, 6). In brief, 18-μm sections were treated with proteinase K (1 μg/ml) at 37°C for 30 min and then refixed for adherence with 4% paraformaldehyde for 20 min. After glycine and acetylation treatments, slides were incubated with probes at 56°C overnight. Slides were then washed extensively in 4× SSC/0.2 M DTT, followed by a high-stringency wash in 50% formamide/0.3 M NaCl/0.02 M Tris⋅HCl, pH 8/1 mM EDTA/0.01 M DTT, at 65°C for 30 min. Slides were then treated with RNase A (20 μg/ml) at 37°C for 30 min and washed under conditions of increasing stringency (final wash, 0.1× SSC at 50°C). After air drying, slides were dipped in NTB2 emulsion, exposed for 4 weeks, developed, and counterstained with hematoxylin/eosin. By using the captured image of the neuron on a video screen and bright-field illumination, the area of the neuron was traced by a MCID image analyzer and recorded in a computer (MicroVideo Instruments, Ontario, Canada). Grains over cells were counted manually by using a ×100 oil-immersion objective. Fifty neurons in the CA1 and subiculum per section and two sections per brain on separate slides were counted. The grain density for each brain was expressed as an average of counts from 100 neurons plus standard deviation.
RESULTS
Accuracy of Measurement.
In a recently published paper (8), we described a method of preparing tissue smears from human postmortem brain and using single whole cell bodies isolated from the smears for RNA profiling based on a single cell approach developed by Eberwine et al. (7) with modifications. The entire procedure can be divided into three parts: (i) isolation of single neurons, (ii) aRNA amplification, and (iii) analysis of expression profiles. We have shown that the amplified aRNA size ranged from a few hundred base pairs to 4.5 kb and is of good complexity. Reverse dot-blot hybridization was used as a quantitative measurement of RNA levels. In the same study (8), we have shown that hybridization intensity was quantitatively related to concentrations of input RNA for three cDNAs with different levels of RNA. However, the linear relationship was less evident for another three cDNAs, which can be ascribed to two different sources: (i) different behavior for different cDNA and (ii) other experimental variations. To distinguish these two possibilities, we repeated the same experiment in this study and included 14 more cDNAs. Radiolabeled aRNA from a single cell was used at four concentrations (1.5×, 1.0×, 0.5×, and 0.25×) for hybridization with 20 cDNAs that were selected on the basis of their potential relevance to the pathogenesis of AD. A few control genes were also included in the assay. The cDNAs were categorized as follows: (i) a housekeeping gene, glyceraldehyde-3-phosphate dehydrogenase (GAPDH); (ii) stress genes, HSP27, HSP90, αB-crystallin, ferritin L and H subunits; (iii) cell cycle/apoptosis genes, cyclins D1, B1, G1, and E, CDK4, and wee1; (iv) structural genes, nestin and NF-M; (v) a transcription factor, CREB; (vi) others, presenilin 1, ras-like protein (TC25), α1-ACT, tuberin, and GAD. We have noted some degrees of data variation that may be partly caused by the variation in loading DNA. After normalization of aRNA signal to the plasmid signal on each spot, the specific hybridization signals for each cDNA were plotted against the concentrations of the input aRNA. The r2 values for all cDNAs with different levels of RNA abundance were all higher than 0.854, indicating a linear relationship between concentration of aRNA and signals detected. This suggests that dot-blot hybridization can serve as a semiquantitative assay to measure the abundance of multiple RNA species in a single hybridization experiment.
The amount of plasmid DNA on each spot was monitored by reprobing the blot with a probe specific to the vector part of the plasmid and the variability of the same batch of plasmid DNA on separate blots was examined. The study of 70 blots containing a set of 20 cDNAs showed a blot-to-blot variation between 15.4 and 40.8%.
Amplification Reactions.
To demonstrate that the enzymatic reactions in the procedure are linear and do not result in nonproportional amplification of RNA, we used three artificial λ poly(A)+ RNAs to spike the total RNA isolated from human hippocampus. Because there is no endogenous λ RNA in total human RNA, we were able to monitor the amplified λ RNAs and determine whether their levels correlate with the amounts added. Three λ RNAs (0.5, 2.0, and 6.6 kb) were added to human RNA (100 ng/μl) at four concentrations of λ RNA: 20, 4, 0.8, and 0.16 ng/μl, respectively. Hybridization signal for λ RNA was not detected in the unspiked sample. It is evident in Fig. 1A that hybridization intensity is influenced by two factors, the amount of the aRNA probe used and that of plasmid DNA immobilized on the filter membrane. However, when the molar excess of DNA over RNA is great, the amount of DNA beyond that will have little influence on total amount of hybridization (Fig. 1A, compare 0.5-kb synthetic λ RNA in blots c and d). Normalized hybridization intensity was plotted against the molar concentration of λ RNA added. The specific signal is linearly related to the RNA concentration between 0.2 and 120 nM for all three RNA species (Fig. 1B). The respective r2 values for 0.5-, 2.0-, and 6.6-kb λ RNAs are 0.993, 0.947, and 0.988, respectively. Our findings are consistent with a recent study by Lockhart et al. (18) who used similar procedures for the reverse-transcription reaction, second-strand cDNA synthesis, and in vitro transcription of aRNA but used a method different from dot-blot hybridization for the detection of signals. Fig. 1B noted that when every RNA was added at equal molar concentration and the corresponding plasmid DNA was spotted at equal molar concentration, the normalized hybridization intensity was directly related to the length of the transcript.
Gene Expression Profiles.
We used the single-cell approach to identify and quantify aRNA for the same 20 genes listed above in multiple cells of each brain in two early- and three late-stage AD brain samples. To compare signals across blots, the individual hybridization intensity of each cDNA on each blot must be normalized to an internal control. To our knowledge, there is no report of any gene whose expression level remains constant under every circumstance. The best control we have discovered for normalization is the average of the measurements for all cDNAs in an assay. Fig. 2 shows that the average of all the measurements is linear to the amount of radiolabeled aRNA used in the assay (r2 = 0.992). Among the 20 cDNAs selected, the differences in expression between AD at early and late stages appear to be limited to a small number of genes, and the magnitude of change seems to be relatively small (see below). The average of all the measurements could, therefore, serve as a good internal control.
The single-cell aRNA data were subjected to an analysis of variance (ANOVA). The changes of RNA level were (i) significant (P < 0.05) for α1-ACT, cyclin D1, HSP27, GAD, and wee1; (ii) marginal (0.1 < P < 0.05) for GAPDH, nestin, αB-crystallin, and TC25; and (iii) not significant for CREB, presenilin 1, HSP90, NF-M, tuberin, ferritin L and H, cyclins B1, G1, and E, and CDK4. In late-stage AD, expression level was decreased by 37.7% for cyclin D1, by 28.2% for HSP27, and by 19% for GAD. In contrast, the expression level was increased by 12.2% for wee1 and by 24.3% for α1-ACT (Fig. 3).
In addition, we estimated the variability for each of the factors tested in the analysis, namely, replication (each cDNA spotted twice) on a blot, cell-to-cell variation within a brain, brain-to-brain variation, and disease state. The proportion of the total variance accounted for by variation in each of these four factors averaged 62%, 16%, 4.4%, and 17.6%, respectively. In general, replication is the biggest source of variation. Despite the efforts to reduce experimental error by normalization, there are still factors beyond our control. We therefore use statistical analysis to distinguish real differences from background noise. The variation for cells within the same brain is larger than variation for brains within the same group. For genes whose expression levels differ significantly between early- and late-stage AD, the variation at the disease level then becomes larger than the cell-to-cell variance. Because the variation among cells within the same brain is not very high compared with the experimental variation, the numbers of single neurons needed to represent a case of AD may not be high.
By simultaneously considering all of the markers (20 cDNAs) in a multivariate analysis, additional information can be derived about altered levels of message expression of single cells due to individual brain differences and to disease-stage differences. We used canonical analysis on data from all 20 markers (15) to define weighted linear combinations of cDNAs that distinguish brains. This analysis, by being sensitive to correlation among genes provides information beyond that provided by univariate analysis. First, data from single neurons from CA1 subiculum of five brains were analyzed by comparing cells from brains at an early and late stage of AD (Fig. 4A). Duplicate blots were obtained for each cell from a specific brain to control for experimental variation; thus, each point in this plot represents one of the duplicated data points from a cell. Canonical variable 1 represents the weighted combination of cDNAs that best distinguished the cells as being from early- or late-stage AD brain. Canonical variable 2 is an analysis of residual variation among cells and clearly does not add greatly to the analysis. Cells of late AD brains can be seen to cluster together. Cells of early AD brains are separated from the cluster formed by cells of late-stage AD brains. The influence of each cDNA on canonical variable 1 is presented graphically (Fig. 4B). The genes contributing heavy weights to canonical variable 1, either positive or negative, are not necessarily the genes with significant changes in expression identified by ANOVA. The top five genes with the heaviest weights are CREB, cyclin D1, wee1, NF-M, and crystallin.
Canonical analysis was performed again with the same data without using any information as to disease state but defining which cells came from each of the five brains. In this five-group analysis, cells of early-stage AD brains are separated from the cluster formed by cells of late-stage AD brains, as well as from each other (Fig. 4C). The influence of each cDNA on canonical 1 in the five-group analysis (Fig. 4D) is slightly different from that in the two-group analysis. The top five genes with the greatest influences are CREB, cyclin D1, NF-M, crystallin, and cyclin G1.
When only the nine markers with statistically marginal to significant ANOVA changes in expression were used for a five-group canonical analysis, separation of the five brains was not as marked as with 20 markers (data not shown). This suggests that markers other than these nine may provide additional information. In this secondary analysis, the size of the canonical coefficient for each gene correlated better with the probability of its expression being significantly different when examined by ANOVA (data not shown).
Validation of aRNA Methodology.
Comparison of the levels of NF-M aRNA among two early- and three late-stage AD brains by ANOVA revealed no difference (Fig. 5A). To validate the results seen with the aRNA method, ISH (Fig. 5B) was performed to examine neurons from two early- and three late-stage AD samples; these were not necessarily from the same individuals used for the aRNA analysis (Table 1). Quantification of grain density also showed no change in NF-M message in CA1/subiculum neurons of early- and late-stage AD brains (Fig. 5C). The result of gene expression obtained by the aRNA method was consistent with the results obtained by the well-established ISH analysis.
DISCUSSION
In this study, we have demonstrated that (i) the enzymatic reactions in the aRNA method results in linear amplification of RNAs and (ii) using dot blots to analyze levels of aRNA is feasible. We used this method to obtain RNA profiles of individual neurons of postmortem human brains. ANOVA was performed to compare the expression levels for individual genes in early- and late-stage AD brains. It was found that the expression levels of cyclin D1, HSP27, and GAD were significantly decreased in late-stage AD samples and that expression of α1-ACT and wee1 were increased (Fig. 3). By using multivariate canonical analysis of the single cell aRNA profiling data, we were able to reveal differences in message expression caused by disease state and brain differences. Canonical analysis sorted differences by disease state in the absence of defining a priori which cells or brains came from which disease state. The genes with significant changes in expression identified by ANOVA were not necessarily the ones contributing heavy weights to canonical variable 1, because in a multivariate analysis, the size of a computed variable depends on interactions among all the markers tested. ANOVA analysis and canonical analysis reinforce each other, with the canonical analysis providing a more interactive presentation. The combination of both types of analyses thus leads us to conclude that the single-cell aRNA method is, in our hands, capable of revealing differences in message expression caused by brain differences and disease state.
How changes in expression of certain genes relate to the pathogenesis of AD awaits further study. Expression of many cell cycle regulators in postmitotic neurons has been reported, but the functions of the proteins encoded by these genes may be unrelated to cell division. Cyclin D1, for example, which is essential for progression through the G1 phase of the cell cycle, could be induced in postmitotic neurons undergoing apoptosis (19, 20). By using the single-cell aRNA approach, we found a significant 37.7% decrease of cyclin D1 RNA in AD. Cyclin D1 usually forms a complex with CDK4, but we did not detect any change in the expression level of CDK4 gene. Immunoreactivities of cdc2/cyclin B1 were found to be elevated in neurofibrillary tangle-containing neurons in AD and cdc2/cyclin B1 was shown to phosphorylate neurofibrillary tangle and recombinant tau in vitro (21). We did not, however, detect any change in the expression of cyclin B1 gene in late-stage AD compared with early-stage AD.
Small stress proteins including HSP27 and αB-crystallin have been reported to act as cellular inhibitors of apoptosis (22, 23). We found a 28.2% decrease of HSP27 RNA in AD. It is possible that selective reduction of HSP27 expression in AD may contribute to the vulnerability of certain populations of neurons to neurodegeneration.
Inflammatory mechanisms have been shown to be part of the pathogenic events of AD (24). In this study, the finding of an elevated level of α1-ACT, an acute-phase protein, in AD is consistent with this hypothesis.
To validate the results seen with the aRNA method, we performed ISH with a marker gene, NF-M. In adult neurons, neurofilaments are important for the maintenance of the highly polarized morphology of axons and for normal axonal caliber. The expression level of NF-M detected by the aRNA method was found to be the same in AD at early and late stages. The result obtained by the well-established ISH analysis was consistent with the aRNA result. By using Northern blot and dot-blot analyses, studies have shown a decrease in gene expression for neurofilament light subunit (25, 26) and NF-M (27) in AD neocortex. However, in contrast to the reported decrease of NF-M gene expression in AD neocortex, we could not detect any change in NF-M message in single neurons of CA1/subiculum in early- relative to late-stage AD brain by two methods. The decrease in NF-M message in AD detected by the “grind and find” type of assay could be due to the loss of neurons in AD brains. Our results clearly demonstrate that molecular analysis at the single-cell level should provide further insights into the molecular alterations, either causative or consequential, in AD pathogenesis.
aRNA profiling for a larger number of genes should soon be possible. Recent advances in obtaining the complete sequence of the human genome and the development of improved technologies for the simultaneous evaluation of the expression of large numbers of genes provide ways to carry out research in human disease. For example, two techniques for analyzing differences in gene expression in normal and cancer cells have recently been reported: sequencing-based serial analysis of gene expression or SAGE (28) and high-density cDNA microarray on a glass microscope slide (29). SAGE has been used in the study of gastrointestinal tumors to analyze differential expression of 45,000 different genes (30) and cDNA microarray used in the study of melanoma to examine 870 genes (31). Other materials, such as high-density cDNA array on a nylon membrane containing 588 human genes (CLONTECH), array of 18,394 genes (Genome Systems, St. Louis) and high-density oligonucleotide array containing 10,000 genes (Affymetrix, Santa Clara, CA) are currently or soon will be commercially available. This study is our initial attempt to address the molecular mechanisms underlying the progression of AD pathology. In the near future, the combination of aRNA amplification on defined cell populations and high-density cDNA or oligonulceotide arrays promises the development of information necessary to fully understand the complexity of the molecular processes in AD and other diseases.
Acknowledgments
We thank Dr. James Eberwine and Dr. Rachael Neve for cDNA clones. We also thank Janet Cheetham for preparing tissue samples and Keith Bourgeois for running canonical analysis on computer. This work was supported by grants from the National Institute of Aging (LEAD AG09016, RO1 AG14441, and Alzheimer’s Disease Center AG08665), the American Health Assistance Foundation, and the Markey Fund.
ABBREVIATIONS
- AD
Alzheimer’s disease
- ISH
in situ hybridization
- aRNA
antisense RNA
- CREB
cAMP-responsive element binding protein
- α1-ACT
α1-anti-chymotrypsin
- GAD
glutamate decarboxylase
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