Abstract
Impaired clearance of amyloid β (Aβ) in late-onset Alzheimer’s disease (AD) affects disease progression. The role of peripheral monocytes in Aβ clearance from the central nervous system (CNS) is unclear. We use a flow cytometry assay to identify Aβ-binding monocytes in blood, validated by confocal microscopy, Western blotting, and mass spectrometry. Flow cytometry immunophenotyping and correlation with AD biomarkers are studied in 150 participants from the AIBL study. We also examine monocytes in human cerebrospinal fluid (CSF) and their migration in an APP/PS1 mouse model. The assay reveals macrophage-like Aβ-binding monocytes with high phagocytic potential in both the periphery and CNS. We find lower surface Aβ levels in mild cognitive impairment (MCI) and AD-dementia patients compared to cognitively unimpaired individuals. Monocyte infiltration from blood to CSF and migration from CNS to peripheral lymph nodes and blood are observed. Here we show that Aβ-binding monocytes may play a role in CNS Aβ clearance, suggesting their potential as a biomarker for AD diagnosis and monitoring.
Subject terms: Cellular neuroscience, Diagnostic markers, Alzheimer's disease
Impaired Aβ clearance in late-onset Alzheimer’s disease (AD) affects progression. Here, the authors show that CD14 + CD16+ monocytes carry Aβ in peripheral circulation and CSF in AD, suggesting a role in Aβ clearance.
Introduction
Late-onset (sporadic) AD is a prevalent progressive neurodegenerative disorder. The onset of symptoms marks the beginning of the preclinical and prodromal stages, which span 20–30 years, followed by overt dementia1,2. During the preclinical stage, ~30% of CU elderly individuals exhibit increased retention of Aβ-PET ligands and reduced Aβ42 levels in CSF and plasma2.
The underlying pathogenic mechanisms of AD involve the failure of extracellular Aβ1-42 clearance and intraneuronal formation of tau-positive tangles and neurites3–5. Aβ1-42 is produced from the proteolytic cleavage of amyloid precursor protein (APP), which is widely expressed in the CNS. The balance between Aβ1-42 production and clearance is critical for maintaining Aβ homeostasis in the brain. Microglial and astrocytic activation, along with pro-inflammatory responses, play key roles in clearing Aβ and interacting with tau and glial cells in the AD brain6,7.
Besides microglia clearing Aβ in the brain, Michaud et al. (2013) proposed a hypothesis on Aβ clearance by monocytes from the luminal side of the brain vasculature8. Similarly, our previous human studies have shown a negative association between the innate phagocytic activity of peripheral monocytes and Aβ accumulation in the brain, suggesting their potential involvement in Aβ clearance in the CNS9. Sensitive, specific, and quantitative methods are needed to detect this phenomenon in the blood and to understand the underlying principles. Furthermore, animal experiments using mice models of AD have demonstrated that certain peripheral monocyte subsets can enter the brain10, which are defined as infiltrating monocytes. Given that monocytes often slip out of the .bloodstream and settle in tissues, investigating whether these monocytes in CNS could overcome the blood-brain barrier (BBB) and travel back to the periphery is integral to understanding the Aβ clearance pathways in AD pathogenesis.
This study aimed to understand how monocytes are involved in the communication between the peripheral blood and the CNS to clear Aβ in AD. We explored the study in five sections: (1) We developed a flow cytometry-based assay to identify monocytes in the blood that strongly bind to Aβ. This method was validated for sensitivity, specificity, and quantifiability using flow cytometry, confocal microscopy, Western blotting, and mass spectrum technologies; (2) We characterized the Aβ-binding monocyte phenotypes and studied the Aβ phagocytosis process to understand their function in Aβ clearance; (3) We also explored the correlation between the abundance of these Aβ-binding monocytes and established AD markers, such as brain Aβ levels and cognitive decline, to assess their clinical association with AD; (4) In addition, we investigated the potential of peripheral monocytes to move into the brain by examining their presence in CSF, shedding light on their activity within the CNS; and (5) Finally, animal experiments demonstrated the migration of these monocytes from the CNS to the periphery, illustrating their role in clearing Aβ and providing insights into their potential as therapeutic targets. This structured approach aimed to advance our understanding of the involvement of peripheral monocytes in Aβ clearance and their implications for AD diagnosis and treatment.
Results
A flow cytometry-based assay that accurately identified Aβ-binding monocytes in the blood
Comparative analysis of anti-Aβ monoclonal antibodies
We assessed several anti-human Aβ monoclonal antibodies for their ability to identify Aβ-binding monocytes in six blood samples (3 CU, 2 MCI, and 1 AD-Dementia) using flow cytometry. The antibodies included clones W0-211, 4G8, and 6E10, with 22C11, an anti-APP mAb, serving as a control. Our results showed that most monocytes in the blood did not carry Aβ, with only a very small number showing Aβ binding. Among the antibodies tested, W0-2 demonstrated the highest sensitivity, followed by 4G8 and 6E10; In contrast, 22C11 was unable to recognize Aβ on the surface of monocytes (Supplementary Fig. 1). This difference in recognition ability may be due to variations in the antigenic sites targeted by the different antibodies. A diagram illustrating the binding domains of the antibodies used in this study is presented in Supplementary Fig. 2.
In addition, typical flow cytometry histograms provided a clear visual representation of fluorescence intensity of the secondary antibody (expressed as % of Max), which is proportional to the level of Aβ on cell surfaces after Aβ peptide binding by human blood leukocytes (Supplementary Fig. 3) and monocyte subsets (Fig. 1a). Cells within the green circles exhibited substantial binding of Aβ peptides, confirming the presence of Aβ peptides on the cell surface of monocytes.
To verify our findings, human peripheral blood mononuclear cells (5 PBMCs, all CU) were stained with W0-2 and 6E10 mAbs to detect surface (n = 3) and intracellular Aβ (n = 2), respectively. Further examination using Z-stack imaging revealed the co-localization of surface and intracellular Aβ peptides in intermediate monocytes (Fig. 1b). This confirmed the existence of Aβ-binding monocytes in the blood, particularly intermediate monocytes carrying Aβ peptides on their cell surface and inside the cytoplasm.
Validation of the assay and confirmation of the affinity of CD14+CD16+ monocytes to synthetic Aβ1-42 peptides
Following the identification of the Aβ-binding monocytes using the flow cytometry-based W02 mAb and secondary antibody assay in blood samples, validating this assay was crucial. This validation involved incubating human blood (n = 6, all CU) with synthetic Aβ1-42 peptides to confirm the specificity of the assay (Fig. 2a).
Our results demonstrated a significant binding of Aβ1-42 peptides to human monocytes compared to the DMSO vehicle control (Tukey’s multiple comparisons test q = 11.74, DF = 30, adjusted p < 0.0001; Fig. 2b). Importantly, this binding remained intact even after the wash procedure, indicating a strong affinity. In contrast, lymphocytes and neutrophils did not exhibit comparable levels of binding to Aβ1-42 peptides, as shown by one-way ordinary ANOVA (F (5, 30) = 33.38, P < 0.0001) and subsequent Tukey’s multiple comparisons tests (monocytes vs. lymphocytes q = 13.69, DF = 30, adjusted p < 0.0001; monocytes vs. neutrophils q = 14.08, DF = 30, adjusted p < 0.0001, Fig. 2b). These analyses confirmed the binding capacity of periphery monocytes to Aβ1-42 peptides in the blood, which was not observed among lymphocytes and neutrophils.
Furthermore, the three subsets of monocytes demonstrated different Aβ1-42 binding capacities. Intermediate (CD14+CD16+) monocytes exhibited the highest binding capacity to synthetic Aβ1-42 peptides compared with the vehicle control (Tukey’s multiple comparisons test q = 11.86, DF = 30, adjusted p < 0.0001), which was significantly higher than that of non-classical (CD14−CD16+) monocytes (Tukey’s multiple comparisons test q = 5.378, DF = 30, adjusted p = 0.0033; Fig. 2c). Classical (CD14+CD16-) monocytes displayed the lowest binding capacity. Significant differences were observed among the three subsets, as determined by one-way ordinary ANOVA (F (5, 30) = 32.13, P < 0.0001) and Tukey’s multiple comparisons tests (intermediate vs. non-classical q = 8.689, DF = 30, adjusted p < 0.0001; intermediate vs. classical q = 14.07, DF = 30, adjusted p < 0.0001; non-classical vs. classical q = 5.378, DF = 30, adjusted p = 0.0078, Fig. 2c).
Taken together, our application of the Aβ1-42 binding assay using human blood pre-incubated with synthetic Aβ1-42 peptides validated the specific binding of monocytes to Aβ1-42 peptides, particularly among intermediate CD14+CD16+ monocytes. This supported the authenticity of identifying Aβ-binding monocytes in blood samples, mirroring the in vivo scenario.
Confirmation of the presence of Aβ1-42 on Aβ-binding monocytes in the blood
Additional validation tests were crucial to verify the presence of Aβ1-42 peptides on these monocytes, considering their potential role in clearing Aβ from the brain. PBMCs from four CU individuals were sorted based on CCR2 and CD14 expression. CCR2 was selected as a surrogate marker for cell sorting because of its use in priming with the anti-Aβ antibody W0-2 for Western blotting and mass spectrometry analyses. The resulting CCR2++CD14+, CCR2+CD14+, and CCR2-CD14- populations were examined using multiple techniques. Western blots, employing W0-2 mAb for priming, showed substantial amounts of Aβ1-42 peptides on CCR2++CD14+ monocytes, but smaller amounts on CCR2+CD14+ monocytes, while no signal of Aβ1-42 peptides was detected on CCR2−CD14− lymphocytes (Fig. 3a). Two distinct Aβ bands emerged: a ~ 9–14 KD band representing Aβ1-42 dimer/tetramer, and a ~4.5 KD band indicating Aβ1-42 monomer. Over 90% of Aβ1-42 peptides on CCR2++CD14+ monocytes were shown in the dimer/tetramer form, while CCR2+CD14+ monocytes demonstrated a balanced mix of oligomers and monomers.
The results were further corroborated through SELDI-TOF mass spectrometry, where the sorted PBMCs from two CU individuals were immune-precipitated by W0-2 mAb. Diverse Aβ1-42 species, including dimers, were detected in CCR2++CD14+ and CCR2+CD14+ monocytes, while CCR2−CD14− lymphocytes exhibited no presence of Aβ1-42 (Fig. 3b). Moreover, triple-quadrupole mass spectrometry (TQ-MS) identified the fragments of 28-42 (Aβ-specific) on various cell types from three CU individuals, which included CCR2++CD14+ and CCR2+CD14+ monocytes, and CCR2−CD14− lymphocytes. Fragment 16–27 (sourced from Aβ and APP) was also detected in abundance (Fig. 3c). Together, Western blotting and mass spectrometry confirmed the presence of Aβ1-42 peptides on the surface of Aβ-binding monocytes.
Characterization of Aβ-binding monocytes
Peripheral Aβ-binding monocytes exhibit a macrophage-like phenotype associated with Aβ phagocytosis function
We used four-color immunophenotypic analysis to characterize the phenotypes of the Aβ-binding monocytes. The characterization relied on basic monocyte classification using CD14 and CD16 antibodies, with additional phenotypic markers introduced into the flow cytometry assay either individually or as a pair (n ≥ 3, with a total of 22 blood samples analyzed, regardless of clinical classification).
Results showed that these Aβ-binding monocytes were LIN-1+ and HLA-DR+ (i.e., MHC-II), indicating their differentiation from dendritic cells (Fig. 4a, b). These cells also expressed chemotactic receptors CX3CR1 and CCR2, indicating strong migratory capabilities (Fig. 4c, d). In addition, they exhibited CD68+ macrophage-like and TREM2+ microglia-like phenotypes (Fig. 4e, f). In contrast, the remaining CD14+CD16+ monocytes lacked expressions of these two markers. Notably, CD68+ monocytes accounted for 0.05 ± 0.03% of total monocytes, and TREM2+ monocytes accounted for 0.06 ± 0.06% of total monocytes (n = 6, regardless of clinical classification). Furthermore, Aβ-binding monocytes expressed various Aβ-binding receptors12,13, including CD85A/LILRB3, CD85D/LILRB2 receptors (Fig. 4g, h), and CD91/LRP1 (Fig. 4i). These cells also expressed complement receptors (CD11b, CD11c, and CD35/CR1) (Fig. 4j–l), and receptors associated with phagocytosis function (MerTK, P2X7R, CD163 and CD33) (Fig. 4m–p). Notably, Aβ+ monocytes displayed elevated expression levels for CCR2 (n = 7, Aβ+ vs. Aβ- monocytes: 66.7 ± 37.8 vs. 24.3 ± 6.2 (Mean ± SD), Wilcoxon matched-pairs signed rank test P = 0.047 with two-tails), CD68 (n = 7, 974.7 ± 886.5 vs. 5.5 ± 1.1, Wilcoxon matched-pairs signed rank test P = 0.016), and TREM2 (n = 6, 166.8 ± 253.1 vs. 6 ± 1.6, Wilcoxon matched-pairs signed rank test P = 0.063), compared to Aβ- monocytes (asterisked in Fig. 2d–f).
Subsequently, we examined monocyte subsets. Across intermediate (CD14+CD16+), non-classical (CD14−CD16+), and classical (CD14+CD16−) monocyte subsets, the Aβ-binding monocytes exhibited similar immune phenotyping characteristics (Supplementary Fig. 4).
Phagocytic activity of monocytes correlating with surface Aβ levels
To investigate the association between surface Aβ levels on monocytes and their phagocytic functions, we took another cohort of three individuals (1 CU, 1 MCI, and 1 AD-dementia) and separated their PBMCs. The CD14+ monocytes were categorized arbitrarily into Aβ−, Aβ+, and Aβ++ monocytes based on their surface Aβ levels (Supplementary Fig. 5). The uptake of yellow-orange (YO) beads by these three monocyte populations was assessed using a well-established, real-time tri-color flow cytometry phagocytosis function assay9. The area under curves (AUC) of YO beads by Aβ++, Aβ+, and Aβ− monocytes were 219392 ± 20589, 184012 ± 27627, and 109437 ± 11056 (arbitrary unit), respectively, indicating their different phagocytic abilities. The results showed that CD14+Aβ++ monocytes exhibited the highest phagocytic activity, followed by CD14+Aβ+ monocytes, while CD14+Aβ− monocytes displayed the lowest uptake of YO beads (Friedman test P = 0.0278, followed by Dunn’s multiple comparisons test: CD14+Aβ++ vs. CD14+Aβ− monocytes adjusted P = 0.0429).
Aβ phagocytosis: tracing the journey from extracellular to intracellular
To investigate monocyte phagocytic activity, we developed a Two-Color Fluorescent Reporting System to monitor monocyte/microglial phagocytosis of oligomerized Aβ1-42 (oAβ1-42) in real-time. This system incorporated AF647-conjugated Aducanumab to visualize surface-bound oAβ1-42 and pHrodo red to highlight intra-lysosomal oAβ1-42. We employed flow cytometry at multiple time points (0.5, 1, 2, 4, and 24 h) for continuous observation.
Initially, we focused on pHrodo-oAβ1-42 phagocytosis by various cell types, including neuronal (HT22), glial (U251) cells, and microglial cells (BV2). BV2 cells exhibited surface adhesion of pHrodo-oAβ1-42 followed by internalization after 2 h, while most peptides were phagocytosed into lysosomes by 24 h (Supplementary Fig. 6). After 2 h, HT22 cells displayed surface adhesion without subsequent internalization, while U251 cells exhibited surface adhesion with weak internalization. In both cell types, internalization became more apparent after 24 h (Supplementary Fig. 7).
We then studied the phagocytic function of human PBMCs. Preliminary results suggest that peripheral monocytes from three individuals (1 CU, 1 MCI, and 1 AD-dementia) all showed substantial internalization of pHrodo-oAβ1-42 after 24 h (Suppl. Fig. 8). Notably, classic monocytes (CD14+CD16−) differentiated into intermediate monocytes (CD14+CD16+) after a 24-h treatment with pHrodo-oAβ1-42, resulting in an increased percentage of intermediate monocytes over the total of intermediate and classic monocytes [= intermediate/(intermediate + classic) x 100%] -- from 6.6 ± 2.7 at 2 h to 63.3 ± 23.8 at 24 h, suggesting a pro-inflammatory response upon pHrodo-oAβ1-42 treatment (Supplementary Fig. 8).
Peripheral monocyte surface Aβ quantification: a potential biomarker for AD
An overview
Quantifying Aβ on the surface of peripheral monocytes could serve as a potential biomarker for AD, providing a non-invasive method for early detection and monitoring. Our study involved 150 participants, including 78 CU, 36 MCI, and 36 AD-dementia individuals. The cohort consisted of 73 males and 77 females, with a mean age of 75 years.
In addition, based on Aβ-PET burden (Centiloid, CL) in the brain, 84 individuals in the cohort had Aβ-PET burden more than 25 CL, indicating higher brain Aβ deposition, while 66 individuals had Aβ-PET burden less than or equal to 25 CL, which was classified as the normal brain Aβ group. Table 1 displays their corresponding APOE genotypes, clinical classifications, CL values, cognitive function scores, and composite scores. Table 2 summarizes the percentages of lymphocytes, monocytes, and neutrophils, as well as the percentage of Aβ++ monocytes and the fluorescence intensity of the secondary antibody for total monocytes. Table 3 elaborates on the percentages of lymphocyte subsets and monocyte subsets, as well as the percentage of Aβ++ monocytes and the fluorescence intensity of the secondary antibody for monocyte subsets.
Table 1.
Demographics | Control (≤25CL)a | Case (>25CL) |
---|---|---|
Number of Participants (n) | 66 | 84 |
Age (mean (SD)) | 74.85 (7.46) | 75.31 (7.42) |
Sex = Male (%) | 27 (40.9) | 46 (54.8) |
Years of Education (mean (SD)) | 12.91 (3.11) | 12.40 (2.98) |
APOE genotype (%) | ||
E2/E2 | 1 (1.5) | 0 (0.0) |
E2/E3 | 10 (15.2) | 0 (0.0) |
E2/E4 | 3 (4.5) | 2 (2.4) |
E3/E3 | 37 (56.1) | 28 (33.3) |
E3/E4 | 14 (21.2) | 38 (45.2) |
E4/E4 | 1 (1.5) | 16 (19.0) |
Clinical Classification (%) | ||
AD-dementia | 8 (12.1) | 28 (33.3) |
CU | 49 (74.2) | 29 (34.5) |
MCI | 9 (13.6) | 27 (32.1) |
Image PET Centiloid (mean (SD)) | 2.74 (11.73) | 89.15 (32.44) |
MMSE (mean (SD)) | 28.05 (2.38) | 25.27 (5.09) |
CDR (mean (SD)) | 0.28 (0.70) | 0.58 (0.61) |
Episodic Memory (mean (SD)) | 0.28 (0.90) | − 0.50 (1.46) |
Composite PACC score (mean (SD)) | 0.25 (0.79) | − 1.07 (2.00) |
aStratified by brain Aβ-PET burden.
The demographic table was used for binary logistic regression, leading to the reclassification of the study cohort into two groups: ≤ 25 CL and > 25 CL, rather than using categories such as AD-dementia, MCI, and CU.
Table 2.
Tube of W0−2+2nd | CU (n = 78) | MCI (n = 36) | AD-Dementia (n = 36) |
---|---|---|---|
% of Lymphocytes | 24.4 ± 6.8 | 23.9 ± 6.7 | 26 ± 9.7 |
% of Monocytes | 6.1 ± 2.2 | 6.2 ± 2 | 6.2 ± 2.4 |
% of Aβ++ Monocytes | 1.3 ± 1.1 | 0.7 ± 0.6 | 0.6 ± 0.6 |
MFI of Monocytes | 294.6 ± 148.9 | 210.3 ± 101 | 192.7 ± 78 |
% of Neutrophils | 42.7 ± 9.6 | 41.5 ± 9.8 | 40.1 ± 12.5 |
The table illustrates the results from the first round of flow cytometry examination of W0-2 and secondary antibody staining, involving the percentages of lymphocytes, monocytes, and neutrophils in the blood, the percentage of Aβ++ monocytes and mean fluorescent intensity of total monocytes in 150 participants (78 CU, 36 MCI, and 36 AD-dementia). Data is presented as Mean ± SD.
Table 3.
Tube of W0−2 + 2nd and CD14, CD16, CD45 | CU (n = 64) | MCI (n = 25) | AD-Dementia (n = 24) |
---|---|---|---|
1) Lymphocyte subtypes: | |||
% of NK cells (CD45+CD14−CD16+) | 17.8 ± 8 | 17.4 ± 5.2 | 12.7 ± 7.5 |
% of T&B cells (CD45+CD14−CD16−) | 82.2 ± 8 | 82.6 ± 5.2 | 87.3 ± 7.5 |
2) Monocyte subsets: | |||
% of Intermediate Monocytes (CD45+CD14+CD16+) | 7 ± 4.5 | 5.9 ± 2.4 | 4.9 ± 2.7 |
% of Aβ++ Intermediate Monocytes | 3.5 ± 4.7 | 2.1 ± 2.7 | 2.9 ± 3.9 |
MFI of Intermediate Monocytes | 434.3 ± 423.7 | 320.5 ± 278.7 | 416.4 ± 352.3 |
% of Classic Monocytes (CD45+CD14+CD16−) | 47 ± 16.4 | 48.3 ± 11.8 | 58.3 ± 12.3 |
% of Aβ++ Classic Monocytes | 0.23 ± 0.32 | 0.18 ± 0.3 | 0.15 ± 0.22 |
MFI of Classic Monocytes | 163.7 ± 100 | 143.2 ± 89.5 | 138.2 ± 59.4 |
% of Non-classic Monocytes (CD45+CD14−CD16+) | 14.2 ± 6.8 | 12.2 ± 6.2 | 12.9 ± 6.9 |
% of Aβ++ Non-classic Monocytes | 0.35 ± 0.93 | 0.16 ± 0.45 | 0.12 ± 0.28 |
MFI of Non-classic Monocytes | 104.8 ± 101.2 | 90.2 ± 66.8 | 101.5 ± 62.2 |
Data is presented as Mean ± SD.
Differences in monocyte surface Aβ between CU, MCI, and AD-dementia
We first examined the percentage of Aβ-binding monocytes based on clinical classification. The results demonstrated a 43% decrease in the percentage of Aβ++ monocytes in total monocytes in AD-dementia patients compared to CU individuals (One-way Kruskal-Wallis test (2, 147) = 9.487, P < 0.0001, multiple comparisons test MCI vs. CU Z = 2.877, DF = 147, adjusted p = 0.0080, AD-dementia vs. CU Z = 4.257, DF = 147, p < 0.0001, MCI vs. AD-dementia no significance, Fig. 5a).
In addition, we analyzed the fluorescence intensity of the secondary antibody for monocytes based on clinical classification. The results indicated a significant reduction in monocyte surface Aβ levels in the AD-dementia group compared to the CU group. Specifically, there was a notable 26% decrease in monocyte surface Aβ levels in AD-dementia patients compared to CU individuals (One-way Kruskal-Wallis test (2, 147) = 17.78, P = 0.0001, multiple comparisons test MCI vs. CU Z = 3.148, DF = 147, adjusted p = 0.0033, AD-dementia vs. CU Z = 3.656, DF = 147, adjusted p = 0.0005, MCI vs. AD-dementia no significance, Fig. 5i).
Our investigation also revealed significant differences in the percentage of NK cells, the percentage of intermediate monocytes, and the percentage of classical monocytes across the MCI, AD-dementia patients, and CU individuals (Supplementary Fig. 9).
Correlation between monocyte surface Aβ and Aβ-PET burden
We further investigated the correlation between monocyte surface Aβ and Aβ PET scoring. Firstly, we examined the association between the percentage of Aβ-binding monocytes and Aβ PET scoring. The results showed a negative correlation between the percentage of Aβ++ monocytes and CLs (Spearman correlation r = − 0.24, P = 0.0038, Fig. 5b).
We then explored the relationship between the fluorescence intensity of the secondary antibody for monocytes and Aβ PET scoring. The findings suggested a weak negative relationship between the fluorescence intensity and CLs (Fig. 5j). Although the Spearman coefficient (r) value was around − 0.2, this correlation was statistically significant (P = 0.0224).
Notably, the significance of the correlation diminished when considering monocyte subsets (Supplementary Fig. 10–12). This is likely because the classification of monocyte subsets led to cell numbers being spread thin, resulting in insufficient sample size to detect within each subset.
Correlation between monocyte surface Aβ and cognitive decline
Cognitive decline is a key clinical feature of AD. To investigate the relationship between monocyte surface Aβ and cognitive function, we conducted various cognitive assessments focusing on executive function, attention, language, and episodic memory (EM). We also used two composite scores, the clinical dementia rating (CDR), and the preclinical Alzheimer cognitive composite (PACC). The results revealed positive correlations between the percentage of Aβ++ monocytes and cognitive scores, as well as the fluorescence intensity of the secondary antibody for monocytes and cognitive scores, except for a negative correlation with CDR (Fig. 5c–h, k–p). Spearman correlation coefficient (r) values, ranging from 0.2 to ~ 0.4, indicated a moderate correlation. Importantly, all r values demonstrated statistical significance (P < 0.05).
Implication of monocyte surface Aβ as a biomarker for predicting brain Aβ
Finally, we evaluated the diagnostic potential of monocyte surface in predicting brain Aβ levels. Using a multivariate generalized linear model, both the percentage of Aβ++ monocytes and the fluorescence intensity of the secondary antibody for monocytes remained significant after adjusting for age and APOE ε4 allele status (0/1/2). The coefficient t-scores and P-values were − 2.835 and 0.0053, and − 2.783 and 0.0062, respectively.
Subsequently, a panel comprising four biomarkers -- the percentage of Aβ++ monocytes, the percentage of Aβ+ NK cells, the percentage of Aβ++ classical monocytes, and the percentage of classic monocytes -- outperformed other examined biomarker combinations. This panel was used as a candidate tool to distinguish individuals whose brain Aβ-PET burden was more than 25 CL from those whose were less than or equal to 25 CL. After adjustments for age, sex, years of education, and APOE genotype, the resulting area under the curve (AUC) of the new panel was 0.871 (CI: 0.803 to 0.938).
When compared to the basic panel, which relied solely on demographic characteristics (i.e., age, sex, years of education, and APOE genotype), the AUC was calculated to be 0.808 (CI: 0.721 to 0.895). Upon integrating monocyte surface Aβ biomarkers, the discrimination performance for AD significantly improved, approaching statistical significance (DeLong test P = 0.059, Fig. 5q). The new panel demonstrated a moderate sensitivity of 0.65 (CI: 0.524 to 0.758), and an impressive specificity of 0.976 (CI: 0.877 to 0.999). Figure 5r visually demonstrates the improved precision and recall metrics achieved by the new panel compared to the basic panel.
Altered surface Aβ among CU with high brain Aβ-PET burden
Although there were no statistically significant differences between the CU − ve and CU + ve groups, we observed that many CU participants exhibited low surface Aβ levels overlapping with the MCI and AD-dementia groups. We compared CU individuals based on brain Aβ-PET status (CU-ve: ≤ 25 CL, n = 49; CU + ve: > 25 CL, n = 29), MCI + ve (n = 27), and AD-dementia (n = 36), excluding those with MCI-ve (n = 9) from the comparison. The results indicated that CU+ve individuals had a percentage of Aβ++ monocytes lower than that of CU-ve individuals and similar to that of MCI+ve/AD-dementia across all three monocyte subsets (Supplementary Table 2 and Supplementary. Figs. 13a, 14a, c, e).
Conversely, CU + ve individuals exhibited slightly elevated surface Aβ fluorescent intensity compared with CU − ve individuals, and this intensity decreased in MCI + ve/AD-dementia individuals in total monocytes and classic monocytes, representing an inverted U-shaped pattern (Supplementary Table 2 and Supplementary Figs. 13b, 14d). However, this phenomenon was not observed in the CU + ve groups of the intermediate and non-classic monocytes (Supplementary Fig. 14b, f). In addition, CU + ve individuals showed a slightly elevated percentage of NK cells in total lymphocytes compared with CU − ve individuals, which returned to normal levels in MCI + ve and decreased in AD-dementia (Supplementary Table 2 and Supplementary Fig. 15a).
The decreased Aβ++ monocytes, increased surface Aβ intensity, and increased percentage of NK cells (i.e., decreased percentage of T&B cells) may indicate an early dysregulation in CU + ve individuals. The percentage changes in monocyte subsets appeared to follow a linear pattern (Supplementary Table 2 and Supplementary Fig. 15b–d) without the inverted U-shaped pattern described above.
Investigating monocyte infiltration into CSF and potential brain migration
To demonstrate the presence of peripheral monocytes entering the CSF and potentially the brain -- identified by the CD45, a pan-peripheral leukocyte surface marker; we investigated CSF pellet cells involving 15 samples (2 AD-dementia, 2 MCI, and 11 CU). The findings indicated that the presence of peripheral lymphocytes and monocytes in the CSF is not unique but rather, occurs in all participants, regardless of clinical classification. In addition, the CSF CD45+ cell composition is distinct from the peripheral. The preliminary results indicated an average of 994 ± 413 cells/mL in the 15 CSF samples, comprising 61 ± 13.6% CD45+ peripheral immune cells and 39 ± 13.6% CD45− cells. Among CD45+ cells, an average of 238 ± 133 lymphocytes/mL and 86 ± 73 monocytes/mL were detected (Fig. 6a, a typical case). Most lymphocytes were CD3+ T cells (64.6 ± 16.1%), primarily consisting of 73 ± 10.8% CD4+ T helper cells, and 18.3 ± 9.5% CD8+ cytotoxic T cells (Fig. 6i). In contrast to the peripheral, B cells (CD45+CD19+), NK cells (CD45+CD16+ lymphocytes), and neutrophils (CD45+CD15+) were present in small quantities. CSF monocytes mainly comprised of CD14+CD16+ intermediate monocytes, constituting 89.4 ± 8% of total monocytes (Fig. 6c). In contrast to peripheral monocytes, non-classical and classical monocytes accounted for only 5.2 ± 6.1% and 5.4 ± 6.3%, respectively. A pie chart illustrates the CSF cellular composition, with 17.57 ± 7.84% CD3+CD4+ T cells, 4.91 ± 3.4% CD3+CD8+ T cells, 12.29 ± 6.47% intermediate monocytes, 0.55 ± 0.27% non-classical monocytes, 0.63 ± 0.46% classical monocytes, 1.11 ± 0.28% neutrophils 39 ± 13.6% CD45− cells, and debris (Fig. 6j).
Due to the limited cell numbers, we only characterized CSF monocytes using part of the markers that applied to peripheral monocytes. The findings revealed that major CSF monocyte populations were positive for CX3CR1 (89.7 ± 8.3%), double positive for Lin-1 and HLA-DR (72.8 ± 10.2%), and double positive for CD11b and CD11c (80.4 ± 11.3%); with 54.2 ± 20% co-expressing CX3CR1 and CCR2, and 75.9 ± 14.7% co-expressing CD14 and CD163 (Fig. 6d–g).
In addition, CSF monocytes showed surface Aβ binding compared to lymphocytes (red cycle in Fig. 6h). In addition, three western blots of CSF pellet cell samples all affirmed the existence of Aβ peptides (Suppl. Fig. 16). Furthermore, most CSF monocytes expressed CD68 and TREM2 (Fig. 6k, l).
To investigate the potential entry of CSF monocytes into the brain, post-mortem brain samples from two motor neuron disease patients were examined (n = 3, 1 patient with front cortex and temporal cortex, the other with temporal cortex only). The initial findings confirmed the presence of CD45+CD14+CD16+ monocytes in the examined brain samples (Supplementary Fig. 17). Results showed that the most populated brain resident monocyte is the CD14+CD16+ monocyte (57.8 ± 1.7%); the CD14−CD16+ and the CD14+CD16− accounted for 21.4 ± 1.9% and 2.1 ± 0.9%, respectively, which is consistent to CSF results. Due to high levels of autofluorescence in brain cells, additional markers such as CX3CR1 were used to distinguish the monocytes/macrophages in the brain (Supplementary Fig. 17).
Peripheral migration of injected PBMCs in AD model mice
The presence of Aβ-binding monocytes in the CSF confirms their ability to enter the CNS. We further investigated whether these CSF peripheral monocytes can exit the CNS. Our investigation aimed to determine whether CSF-infiltrated peripheral leukocytes have the capability to migrate out of the CNS, providing insights into the entry and exit mechanisms of these immune cells between the CSF and periphery. To investigate whether infiltrated peripheral leukocytes possess the ability to migrate out of the CNS, CFSE-labeled C57BL/6 mouse PBMCs or Cx3CR1-eGFP mouse PBMCs were injected into the lateral ventricles of APP/PS1 (AD model) mouse brains. The aim was to examine whether these monocytes could re-enter the periphery through venous and lymphatic drainage pathways. The results indicated that the introduced PBMCs or monocytes were present in the blood and/or deep cervical lymph nodes (dcLN) in 15 out of 17 AD mice (88%, Supplementary Table 1) two days post intracerebroventricular injection (Fig. 7d–l). Among these mice, the detection rate was 80% in young mice aged 15-35 weeks (n = 10), and 100% in older mice aged 68-80 weeks (n = 7). The detection rates in both blood and dcLN were equal at 71%. The Aβ peptides carried by the CX3CR1+ monocytes were detected using Qdot655-conjugated W0-2 mAb (Fig. 7f, l). Brain tissues were utilized for quality control (Fig. 7a–c).
In addition, we conducted further experiments by injecting fluorescent beads into the ventricles of three APP/PS1 mice, and none of the beads were detected in either the circulation or lymph nodes (see Supplementary Table 1 and Suppl. Fig. 18), indicating that the cell migration observed is a physiological process.
Discussion
This study developed a flow cytometry-based assay to identify CD14+CD16+ monocytes binding to Aβ in the blood, revealing a macrophage-like phenotype with high Aβ phagocytic potential. Surface Aβ levels on monocytes were significantly lower in MCI and AD-dementia patients compared to CU, suggesting impaired brain Aβ clearance in AD. Using human CSF pellet cells and the APP/PS1 mouse model, the study demonstrated monocyte infiltration from the blood into the CSF, potentially into the brain, and peripheral monocytes exit from the CNS. The findings suggest that peripheral monocytes play a significant role in Aβ clearance and that monocyte surface Aβ could potentially serve as a blood-based biomarker for AD diagnosis and therapeutic effect monitoring.
Brain Aβ1-42 are drained into the cerebral venous blood14 and lymphatic system15, initially existing as free Aβ until it binds to protein chaperones like lipoproteins and albumin16. Moreover, the volumetric dilution factor between CSF (140–270 mL) and plasma (~ 2800 mL) differs roughly by 15-fold. In contrast, the concentration of Aβ42 in CSF (900 ng/L) is about 30-fold higher than that in plasma (30 ng/L)17–20. This 2-fold difference in the dilution factor implies that the “missing Aβ1-42” is sequestered in a compartment distinct from plasma, suggesting the existence of an undefined Aβ pool. While erythrocytes have been found to bind Aβ21,22, other cell types, such as monocytes8, are more likely to be involved in eliminating Aβ within the lumen of cerebral veins and transporting Aβ in the blood.
We hypothesize that peripheral monocytes also enter the brain to complete Aβ phagocytosis, as we have previously shown that innate phagocytosis can be inhibited by as little as 1% serum23. Therefore, it is unlikely that monocytes could efficiently clear Aβ in the blood. This hypothesis is supported by studies suggesting the brain parenchyma infiltration of peripheral CD45highLy6Chigh monocytes24, CD45highCD115+ monocytes10, or CD45+CD163+ monocytes25 in reducing brain Aβ plaque load.
The presence of CD45+CD163+CD14+CD16+ monocytes in the CSF with high surface Aβ binding, as shown in this study, indicates their active role in Aβ clearance in the brain. Potential sites for the entry of peripheral monocytes into the brain include the choroid plexus, meninges, and perivascular spaces of aged AD mice24. The mechanism triggering this cellular ingress pathway in AD remains unclear, but an interferon γ-dependent recruitment of monocytes to the brain upon programmed death-1 blockade has been proposed26. In addition, a recent study proposes that arachnoid cuff exit (ACE) points enable fluid and molecule exchange between the subarachnoid space and dura mater, supporting cellular trafficking during neuroinflammation27.
We hypothesize that peripheral monocytes leave the brain and return to the blood after completing Aβ phagocytosis via a specific cellular egress pathway. Two recent studies have shown how CSF exchanges with the glymphatic system to remove waste, including Aβ, from the brain28,29. In this study, the injection of PBMCs into the brain ventricles and their detection in the blood and lymph nodes provide first-hand evidence for the potential return of these infiltrated monocytes to the periphery. Our findings are even more significant as we have demonstrated not only the exchange of fluids and molecules but also the trafficking of immune cells via this cellular ingress and egress system in AD.
Genome-wide association studies have implicated disruptions in phagocytosis and endocytosis pathways30,31 to late-onset AD, consistent with our findings of altered monocyte phagocytosis9. Our investigation of peripheral monocytes in AD showed significant changes in surface markers, suggesting peripheral immune responses, although the exact reasons remained unknown32. In this study, we observed elevated expression of CCR2, CD68, and TREM2 in Aβ-binding monocytes in the blood. Most CSF monocytes were intermediate (CD14+CD16+) monocytes, a subset not commonly found in peripheral monocytes, and expressed CD68 and TREM2, resembling tissue macrophages and microglia. This suggests that perivascular or CSF monocytes may contribute to the pool of Aβ-binding monocytes in the blood. The upregulation of CD68 and TREM2 in CSF monocytes may result from the unique perivascular and CSF environment, lacking serum but containing Aβ, highlighting the association of TREM2 with AD33.
In a study involving 252 participants from AIBL, AD patients exhibited a 16% reduction in plasma Aβ1-42 compared to healthy controls20. The plasma Aβ1-42/Aβ1-40 ratio, phosphorylated-tau181, glial fibrillary acidic protein, and neurofilament light were also evaluated as potential blood biomarkers for AD34. In addition to plasma Aβ diagnostics for AD, our findings highlight the potential use of blood cell-based Aβ diagnostics. The correlation between the reduction in Aβ-carrying monocytes in AD patients and their association with brain Aβ burden and cognitive decline underscores the clinical relevance of our study, emphasizing the potential for these markers to enhance AD diagnosis and prognosis.
To address concerns about potential BBB damage from cell injections and the presence of these cells in circulation, our data showed minimal counts of injected beads in the periphery, suggesting it is a physiological event with limited migration via BBB leakage. In addition, limitations such as the difficulty in obtaining CSF samples from AD patients compared to blood samples resulted in a small study cohort. While the improvement in our model’s performance (AUC 0.87 vs 0.81) is marginal, we find the diagnostic potential of Aβ-binding monocytes in peripheral blood promising, emphasizing the need for further validation to confirm their utility.
In this study, we observed that surface Aβ levels on monocytes were significantly lower in MCI and AD-dementia compared to CU, suggesting impaired brain Aβ clearance. We also showed that CD45+CD163+CD14+CD16+ monocytes actively clear Aβ in the CSF. Importantly, our study provided direct evidence of monocytes leaving the brain and re-entering the bloodstream. These findings highlight the importance of understanding these cellular processes in AD. Such insights could pave the way for developing treatments that enhance Aβ clearance by promoting monocyte Aβ phagocytosis, thereby advancing our understanding and treatment of AD.
Methods
The flow cytometry-based assay
To accurately identify monocytes in the blood that strongly bind to Aβ, we first compared several anti-human Aβ monoclonal antibodies for their ability to identify Aβ-binding monocytes in the blood. 100 µL anti-coagulated peripheral whole blood from six individuals (3 CU, 2 MCI and 1 AD-Dementia) were stained with various anti-Aβ antibodies and an anti-APP antibody -- 20 µg/mL W0-2, 40 µg/mL 4G8 or 20 µg/mL 6E10 (kindly provided by Dr Qiao-Xin Li), 20 µg/mL 22C11 (Sigma-Aldrich), with the optimal concentrations determined by antibody titrations, incubated on a shaker, protected from light, at room temperature for 15 min. Afterward, the blood sample was washed twice using phosphate buffer saline (PBS), centrifuged at 300 × g for 5 min to remove the unbound antibody, and subsequently incubated with 10 µg/mL FITC-conjugated donkey anti-mouse IgG (H + L) (Jackson Laboratories) for 15 min. Then, red blood cells were lysed, and leukocytes were fixed using 2 mL BD FACS Lysing Solution (BD Biosciences) for 10 min. Cells were washed with 2 mL PBS, pelleted by centrifugation, resuspended in 100 µL PBS, incubated with RPE-conjugated anti-CD16 (Dako) and APC-conjugated anti-CD14 (BD) antibodies for another 15 min, then washed with 2 mL PBS, pelleted, resuspended with 0.5 mL PBS, and analyzed with a flow cytometer (BD FACSCalibur). The antibodies’ performance was assessed by comparing the fluorescent intensity of the secondary antibody to sensitively identify Aβ-binding monocytes within the monocytes; especially the monocyte subsets, which were classified based on CD14 and CD16 positivity.
After optimization, the final assay was determined to be: 100 µL anti-coagulated peripheral whole blood stained with 20 µg/mL W0-2, incubated on a shaker, protected from light, at room temperature for 15 min, washed twice with PBS, subsequently incubated with 10 µg/mL Alexa Fluor® 488-conjugated goat anti-mouse IgG2a secondary antibody (Life Technologies) for 15 min, lysed and fixed with 2 mL FACS Lysing Solution (BD) for 10 min, washed with 2 mL PBS, pelleted by centrifugation, resuspended with 0.5 mL PBS, and analyzed with FACSCalibur. Stopped at 40,000 events and collected the remaining cells in the FACS tube by centrifugation. Cells were resuspended in 100 µL PBS, incubated with RPE-conjugated anti-CD16 (Dako), PerCP-conjugated anti-CD45, and APC-conjugated anti-CD14 (BD) antibodies for another 15 min, then washed with 2 mL PBS, pelleted, and resuspended with 0.5 mL PBS, and reanalyzed with FACSCalibur. Autofluorescence, IgG2a isotype antibody, and secondary antibody alone were prepared for each sample.
Confocal microscopy
Three CU PBMCs were stained with W0-2 and AF488-conjugated secondary antibodies, and two CU PBMCs were stained with RPE-CD16 and APC-CD14 antibodies, fixed and permeabilized, and strained with FITC-conjugated 6E10. A Leica SP8 confocal microscope was utilized to identify Aβ in terms of W0-2 plus secondary antibody on the cell surface or 6E10 in the cytoplasm with Z-stack imaging. The confocal images were analyzed, and channels were merged using Fiji (ImageJ 1.51n, NIH, USA). The 3D view of cell surface Aβ was generated using Imaris Viewer (Oxford Instruments).
The synthesized Aβ1-42 incubation
To form oligomerized Aβ1-42, synthesized Aβ1-42 powder (China Peptides, Shanghai) was dissolved in a solution of 90% DMSO and 10% 10 mM PBS (PH = 7.4), and preincubated at 4 °C overnight. 10 µM oAβ1-42 was added to a tube of 100 µL peripheral whole blood from six CU individuals. DMSO was added to another tube of blood as vehicle control. Blood samples were incubated on a shaker at 37 °C for 15 min, washed three times with PBS, and stained with W0-2, secondary, CD16, CD45, and CD14 antibodies described as above.
FACS Sorting
Human PBMCs were separated using Ficoll-Paque Plus (GE Healthcare) and were stained with FITC-conjugated CD14 and AF647-conjugated CCR2 antibodies. CCR2 was used as a surrogate of W0-2 to identify blood Aβ-binding monocytes as Aβ was primed by W0-2 in the Western blot and SELDI-TOF Mass Spectrometry. The cells were then sorted into CCR2++CD14+, CCR2+CD14+ monocytes, and CCR2−CD14− lymphocytes. The sorted populations were concentrated to 1 x106 cells/mL, and a protease inhibitor cocktail (cOmplete, Roche) was added before freezing.
Western Blotting
Sorted PBMCs from 4 CU individuals were pooled to make two sets of cells with 1 x 106 cells per cell type. Cells were ultrasonicated at 4 °C for 20 s, denatured within LDS sample buffer (ThermoFisher) at 90 °C for 5 min, and reduced by 50 µM DTT. 24 µL proteins and 7 µL SeeBlue protein standard (Thermo Fisher) were loaded to 10-well NuPage gel (Thermo Fisher). Electrophoresis was conducted with an MES buffer at 100 V for 50 min. Proteins were transferred to a 0.2 µm pore size nitrocellulose membrane (Bio-Rad) at 100 V for 35 min. Immunodetection was carried out using 1:1000 W0-2 antibody and 1:10,000 rabbit anti-mouse HRP conjugated IgG (Invitrogen), and ECL substrate (ThermoFisher).
SELDI-TOF Mass spectrometry
2 μL of 0.25 mg/mL W0-2 mAb was added to the spots of the PS10 ProteinChip array, and the chip was incubated in a humid chamber at 4 °C overnight. The antibody was removed and 5 μL of blocking buffer (0.5 M ethanolamine in PBS) was added, the array was incubated for 30 min. The blocking buffer was removed, and each spot was washed with 200 μL of 0.5% Triton X-100/PBS (wash buffer) for 5 min three times. The solvent was removed, and the spots were washed with 20 μL of PBS for 5 minutes three times. Sorted cell lysates from two CU PBMCs were added to each spot; the array was incubated at room temperature for 2 h. The samples were removed, and each spot was washed twice with 200 μL of wash buffer for 10 sec, followed by a wash with 200 μL PBS twice for 10 s, and finally, the arrays were washed with 200 μL 1 mM HEPES twice for 10 seconds. The array was air-dried. A volume of 1 μL of sinapinic acid (SPA, 50% saturated in 50% (v/v) acetonitrile and 0.5% in TFA) was applied to each spot twice. The array was air-dried between each application. All the incubations and washes were performed on a shaking table. Chips were analyzed in a PBSIIC, SELDI–TOF MS and peaks were analyzed using Ciphergen ProteinChip software 3.1.
Triple-quadrupole mass spectrometry
For immunoprecipitation, 19 µg of anti-Aβ mAbs (clone 6E10 and clone 4G8 at a 1:1 ratio) was loaded onto ProteinG W columns. Columns were blocked with 25 mM dimethylpyrazole (DMP) and washed with PBS. Subsequently, 7.5 x 104 sorted cells per cell type from three CU individuals were mixed with 20 µL of urea 8 M and 80 µL of PBS (0.5% CHAPS), sonicated, and loaded into columns. The columns were washed with PBS and then water. Samples were eluted using a mixture of 30% acetonitrile, 10% isopropyl alcohol, and 0.1% formic acid. After the speed vacuum, enzymatic digestion was performed. For digestion, samples were treated with urea protocol, followed by Lys-N digestion. Digested peptides were desalted using an Oasis HLB μElution 96-well plate (Waters Corp). LC-ESI-QQQ-MRM assay was conducted using an Agilent 1200 Infinity series UHPLC system connected to 6495 triple-quadrupole MS (TQ-MS). Data processing involved Skyline software to extract peak areas for Aβ peptides and derive light-to-heavy ratios by comparing them to stable isotope-labeled analogs.
Four-color flow cytometry phenotyping scheme
A four-color flow cytometry scheme was used to phenotype Aβ-binding monocytes in blood and CSF. For blood samples, Lin-1 and HLA-DR antibodies (BD) were tested together with CD45, W0-2 and secondary antibodies. CCR2, CD11b, CD11c, CD35/CR1, CD68, CD85A/LILRB3, CD85D/LILRB2, CD91/LRP1, CD163, CX3CR1 (BD), MerTK, TREM2 (R&D Systems), and P2X7 (made in house) antibodies were tested together with CD14, CD16, W0-2 and secondary antibodies. At least three samples were tested for each antibody or antibody combination, with a total of 23 blood samples analyzed, regardless of clinical classification. For 14 CSF pellet cells, Lin-1, HLA-DR, CCR2, CD3, CD4, CD8, CD11b, CD11c, CD14, CD16, CD68, CX3CR1, TREM2, W0-2 and secondary antibodies were tested together with CD45 antibody.
Two-Color Fluorescent Reporting System
To form oligomerized Aβ1-42, 0.5 mg synthesized Aβ1-42 powder (China Peptides, Shanghai) was dissolved in 250 μL 10 mM NaOH, diluted with 250 μL ultrapure water, neutralized with 56 μL 10X TBS pH 7.4 (ThermoFisher), and incubated at 37 °C overnight. Aβ1-42 aggregates were collected with 16,000 × g centrifugation for 1 min, washed once with HBSS (ThermoFisher), collected with 16,000 × g centrifugation for 1 minute, resuspended with 200 μL filtered 0.1 M NaHCO3, mixed with 36 μL 10 mg/mL pHrodo red dye (ThermoFisher), incubated at room temperature for 1 h with rotation in the dark, collected with 16,000 × g centrifugation for 1 min, washed once with 1 mL methanol, washed three times with 1 mL HBSS, resuspended in 200 μL HBSS, sonicated at room temperature for 10 min, and stored in aliquots at − 80 °C for further use.
To prepare cell cultures, HT22 (Millipore, Cat. No: SCC129), U251 (Sigma-Aldrich, Cat. No: 09063001) and BV2 cells (provided by Professor Rosario Donato, University of Perugia) were cultured in RPMI 1640 media (ThermoFisher) with 10% FBS and 100 U/mL penicillin-streptomycin with T75 flasks until 90% confluency, trypsinized, pelleted at 300 × g for 5 min, resuspended with complete media, and plated in 1 mL to 35 mm cell culture dishes (Falcon) with 4 x 105 cells/mL concentration, cultured overnight and changed to FBS-free RPMI 1640 media for further tests.
To prepare PBMCs, two tubes of anticoagulated blood were mixed, diluted with 15 mL PBS, carefully suspended on 15 mL Ficoll-Paque PLUS (Cytiva), and centrifuged with 400 × g for 30 min without brake. PBMCs were aspirated using a transfer pipette, washed with PBS, pelleted with 400 × g for 5 min, resuspended in 10 mL red cell lysis buffer at room temperature for 10 min, washed with PBS, pelleted with 400 × g for 5 min, resuspended in 200 μL PBS, diluted with FBS-free RPMI 1640 media, and plated in 1 mL to 35 mm cell culture dishes with 5 x 105 cells/mL concentration for further use.
To test cell phagocytosis, each dish of cells was given 5 μL pHrodo red-conjugated oligomerized Aβ1-42 with the gentle mix, incubated for multiple time points (0.5, 1, 2, 4, and 24 h). Cells were then collected with a cell scraper, washed once with PBS, pelleted with 300 × g for 5 min, resuspended in 100 μL PBS, stained with 20 µg/mL AF-647 Aducanumab (Biogen) at room temperature for 15 minutes, washed once with PBS, centrifuged, resuspended with 0.5 mL PBS, and analyzed using a flow cytometer (BD FACSCalibur).
AIBL cohort study
A total of 150 Caucasian participants were randomly selected from the AIBL study: a longitudinal, prospective observational study integrating peripheral biomarkers with neuroimaging, neuropsychological assessments, and lifestyle data35. This study was conducted in Melbourne, Victoria and Perth, Western Australia, with our samples collected from the Melbourne site. The participants, comprising 73 males and 77 females, had a mean age of 75 and were fluent in English (Table 1). According to the AIBL Participant Consent Form (March 2020), no payments are made to participants in this study. However, all study participants are eligible for reimbursement of transportation costs incurred by traveling to and from clinic appointments and the cost of food if required to fast before a blood test. Participants will incur no expenses for any tests or procedures undertaken for study purposes. As per the NINCDS-ADRDA criteria, they were categorized into three clinical groups: cognitively unimpaired controls (CU, n = 78), mild cognitive impairment (MCI, n = 36) or prodromal AD36,37, and AD-dementia (AD, n = 36)35,38. In addition, participants were stratified based on the Aβ-PET neuroimaging results (as described below). Researchers remained blinded to all clinical and demographic information until completion.
A 3D T1-weighted MRI was obtained for screening and co-registration with the PET images. The PET methodology has been previously described39. All Aβ-PET scans were spatially normalized using CapAIBL40 and quantified using the Centiloid (CL) scale. The thresholds of Aβ-PET positivity were selected based on postmortem studies that the individuals with Aβ-PET load ≥ 15CL and < 25CL may have sparse Aβ plaques41,42.
The cognitive assessments have been extensively outlined and validated in prior research within the AIBL cohort43–46. In summary, the episodic memory composite includes the California Verbal Learning Test (Second Edition, CVLT-II), Logical Memory, and Rey Complex Figure Test. The preclinical Alzheimer cognitive composite (PACC) includes the California Verbal Learning Test (Second Edition, CVLT-II), Logical Memory, Digit Symbol Coding, and Mini-Mental State Examination (MMSE). These assessments served as robust and established measures in our study.
Peripheral whole blood was collected via venepuncture between 8:00 a.m. and 10:30 a.m. after overnight fasting. Whole blood was kept in EDTA anticoagulant Vacutainer® tubes (BD Biosciences) and kept on ice during transportation. Processing of whole blood was completed within three hours after collection.
By using the flow cytometry assay, we initially quantified the percentage of Aβ-binding monocytes and the fluorescence intensity of the secondary antibody, which reflects the level of Aβ on cell surfaces. Since this assay utilizes a secondary antibody, the W0-2 mAb cannot be used concurrently with other antibodies. Therefore, after restaining the cells with CD14 and CD16 antibodies, we quantified the percentage of Aβ-binding monocytes and the fluorescence intensity of the secondary antibody based on the CD14 and CD16 classification of monocytes. Notably, only 113 samples from a total of 150 individuals were co-investigated with CD14, CD16, and CD45 antibodies. These samples were obtained from 64 CU, 25 MCI, and 24 AD-dementia individuals. The limited investigation of these antibodies was due to their introduction after the start of the AIBL cohort study.
FACS data was analyzed using Flow Jo V10 software (Flow Jo, LLC). The Aβ++ monocyte data was analyzed based on clinical classification (CU, MCI, and AD-dementia) using one-way ordinary ANOVA or Kruskal-Wallis test if the data was not normally distributed, followed by multiple comparisons tests. Two-tail P-values were presented. Correlations were evaluated through nonparametric Spearman correlation analysis, exploring the relationship between the Aβ++ monocytes and brain Aβ levels or cognitive functions, respectively. All between-group comparisons and Spearman correlation analyses were executed and visually represented using GraphPad Prism (Version 9.2). In addition, ROC analysis and Precision-Recall analysis were conducted and graphically presented using IBM SPSS Statistics (Version 29.0).
CSF Pellet cell collection
15 CSF pellet cell samples, nine males and five females with a mean age of 78 were collected from the AIBL study. This cohort included two individuals with AD, two with MCI, and 11 CU participants, of which seven were Aβ PET+ and eight were Aβ PET-. Approximately 10 mL of CSF samples were obtained via lumbar puncture and then centrifuged at 300 g for 10 min at 4 °C. The resultant CSF pellet cells were resuspended in 200 µL1x PBS and kept on ice during transportation. All processing of the CSF pellet cells was completed within three hours after collection.
Fluorescence flow cytometry tracking of intraventricular injection of live mononuclear cells into peripheral blood and lymph
Twenty-one 15- to 80-week-old APP/PS1 (JAX APPsw, PSEN1dE9; 14 males and 7 females) mice used in this study were bred and housed with cage mates in a pathogen-free environment at the KMB Bioresources Facilities. Twenty-six 7-week-old female C57BL/6 donor mice were purchased from Ozgene. Peripheral blood was obtained from the C57BL/6 mice through cardiac puncture at a donor to recipient ratio of 2:1. Mononuclear cells were isolated via density centrifugation, labeled with carboxyfluorescein succinimidyl ester (CFSE, Abcam), and prepared for intraventricular injection. The APP/PS1 recipient mice were anesthetized using 2% isofluorane in the air to attain a surgical plane. Their heads were securely immobilized in a stereotaxic frame (RWD Life Science) with the application of eye lubricant. Pre-operative analgesia is administered, followed by a scalp incision and treatment of the skull with hydrogen peroxide to expose bregma. The cannulation site, located at 0.46 mm posterior and 0.8 mm lateral to bregma, was drilled, and 5 µL of cells were injected into the lateral ventricle (2.25 to 2.5 mm below the bone surface) using a microinjection needle. The injection speed was set at 1 µL/min, and the needle was retained for 10 min after injection to prevent leakage of the cells. The wound was closed with sutures. After a 2-day period, the recipient mice were anesthetized with isoflurane, peripheral blood was collected via cardiac puncture, and they were humanely killed by cervical dislocation. The brain was quickly removed, and the hippocampus and retrosplenial cortex were dissected and soaked in ice-cold PBS. The deep cervical lymph nodes (dcLNs) were severed from both sides beneath the sternomastoid muscles and soaked in ice-cold PBS. The blood underwent lysis using red blood cell lysis buffer. The dissected brain tissue and dcLNs were minced and filtered through a 100 µm cell strainer using the plunger end of a 1 mL syringe. The cell strainer was continuously rinsed with ice-cold PBS. The lysed blood and homogenized samples were centrifuged at 300 × g and 4 °C for 5 min. The supernatant was carefully aspirated, and the pellets were resuspended in 100 µL PBS and analyzed using a flow cytometer (BD FACSCalibur).
Eight 8- to 12-week-old CX3CR1-eGFP mice (JAX, 3 males, and 5 females) were utilized to collect CX3CR1-eGFP+ monocytes for monocyte-specific tracking. These monocytes were injected into the recipients’ lateral ventricles without CFSE labeling. After a two-day period, the recipient mice were euthanized, and tissues were collected. The lysed blood and homogenized brain and lymph node samples were centrifuged at 300 × g at 4 °C for 5 min. The supernatant was carefully discarded, and the pellets were resuspended in 100 µL ice-cold PBS. To identify Aβ-binding monocytes, 20 µg/mL Qdot655-conjugated W0-2 mAb was added to the cell suspension, which was then incubated on ice for 20 min and washed once with PBS before analysis using a flow cytometer (BD FACSCalibur).
In addition, 6 µm high-intensity alignment green beads (Polysciences) were injected into the lateral ventricle of three APP/PS1 mice (aged 32 weeks, 49 weeks, and 55 weeks) as a controlled study. Two days post-injection, peripheral blood, and dcLNs were collected to trace these fluorescent beads.
W0-2 mAb Direct labeling
Directly labeling W0-2 mAb with a fluorescent dye caused high non-specific binding. To preserve the antibody’s activity, a high-fidelity method was used, involving attaching dye molecules to heavy chain N-linked glycans. W0-2 mAb was directly labeled with RPE, Qdot525, and Qdot655 using the SiteClick labeling kits (Thermo Fisher). These fluorescently labeled antibodies were used in later stages of experiments.
Ethical approval
The St Vincent’s Hospital Melbourne Human Research Ethics Committee granted ethical approval for the human studies (Ref: HREC-A 028/06). Informed consent was obtained from all participants and caregivers.
Ethical approval for the animal study was granted by The Florey Animal Ethics Committees (Ref: 22–058).
Reporting summary
Further information on research design is available in the Nature Portfolio Reporting Summary linked to this article.
Supplementary information
Acknowledgements
We thank Dr. Verena Wimmer and Dr. Carolina Chavez for their help with confocal microscopy. This work was supported by National Health and Medical Research Council (NHMRC) Project Grants - 2016803 to (Masters); ARC Future Fellowship FT120100581 (to Gu), NHMRC Project Grants - 1048082, 1061419, 1120095, and 110178 (to Gu), and State Government of Victoria (Victorian Government) - Operational Infrastructure Support Grant to the Florey Institute.
Author contributions
X.H.: data collection, analysis, writing; C.F., Y. Li, Q.L., J.S., K.P., C. Dubois, C. Drysdale, R.R.: sample and data collection; J.D.: analysis. Y.Y.L., P.M.: cognitive tests; C.R.: brain imaging; Q.L., Y.P., L.J., H.C., R.M., P.M., Y.Y.L., A.B., Y. Lin, K.B.: results interpretation and writing; Y. Li: proofreading; C.M. and B.G.: design and writing.
Peer review
Peer review information
Nature Communications thanks Serge Rivest, Charlotte Teunissen, and the other anonymous reviewer(s) for their contribution to the peer review of this work. A peer review file is available.
Data availability
Human participant data is available upon request through an AIBL EOI mechanism from the corresponding author, CM, via the link https://aibl.org.au/collaboration/#data-access. The data are not publicly available due to containing information that could compromise the privacy of research participants. The animal data that support the findings of this study are available via the link https://figshare.com/s/4e7f588f527163643c5f.
Competing interests
The authors declare no competing interests.
Footnotes
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Contributor Information
Colin L. Masters, Email: c.masters@unimelb.edu.au
Ben J. Gu, Email: ben.gu@innatephagolab.com.au
Supplementary information
The online version contains supplementary material available at 10.1038/s41467-024-52396-1.
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Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Supplementary Materials
Data Availability Statement
Human participant data is available upon request through an AIBL EOI mechanism from the corresponding author, CM, via the link https://aibl.org.au/collaboration/#data-access. The data are not publicly available due to containing information that could compromise the privacy of research participants. The animal data that support the findings of this study are available via the link https://figshare.com/s/4e7f588f527163643c5f.