Association of GLOD4 with Alzheimer’s Disease in Humans and Mice
Abstract
Background:
Glyoxalase domain containing protein 4 (GLOD4), a protein of an unknown function, is associated with Alzheimer’s disease (AD). Three GLOD4 isoforms are known. The mechanism underlying GLOD4’s association with AD was unknown.
Objective:
To assess GLOD4’s role in the central nervous system by studying GLOD4 isoforms expression in human frontal cerebral cortical tissues from AD patients and in brains of Blmh–/–5xFAD mouse AD model of AD.
Methods:
GLOD4 protein and mRNA were quantified in human and mouse brains by western blotting and RT-qPCR, respectively. Mouse brain amyloid-β (Aβ) was quantified by western blotting. Behavioral assessments of mice were performed by cognitive/neuromotor testing. Glod4 gene in mouse neuroblastoma N2a-APPswe cells was silenced by RNA interference and Glod4, Aβ precursor protein (Aβpp), Atg5, p62, and Lc3 proteins and mRNAs were quantified.
Results:
GLOD4 mRNA and protein isoforms were downregulated in cortical tissues from AD patients compared to non-AD controls. Glod4 mRNA was downregulated in brains of Blmh–/–5xFAD mice compared to Blmh+/+5xFAD sibling controls, but not in Blmh–/– mice without the 5xFAD transgene compared to Blmh+/+ sibling controls. The 5xFAD transgene downregulated Glod4 mRNA in Blmh–/– mice of both sexes and in Blmh+/+ males but not females. Attenuated Glod4 was associated with elevated Aβ and worsened memory/sensorimotor performance in Blmh–/–5xFAD mice. Glod4 depletion in N2a-APPswe cells upregulated AβPP, and downregulated autophagy-related Atg5, p62, and Lc3 genes.
Conclusions:
These findings suggest that GLOD4 interacts with AβPP and the autophagy pathway, and that disruption of these interactions leads to Aβ accumulation and cognitive/neurosensory deficits.
INTRODUCTION
Alzheimer’s disease (AD) is the primary cause of dementia, affects 55.0 million individuals worldwide and ranks as the fifth leading cause of death globally.1 In the United States alone, an estimated 6.9 million individuals aged 65 and older (2% of the US population) live with AD dementia today, and this number is expected to grow to 13.8 million by 2060. AD is characterized by the extracellular accumulation of amyloid-β (Aβ) and the intracellular accumulation of neurofibrillary tangles of hyperphosphorylated tau protein leading to neuronal death. Mutations in amyloid-β protein precursor (AβPP), presenilin 1 (PSEN1), and presenilin 2 (PSEN2) lead to the familial early-onset AD, which is relatively rare.2 Although lifestyle and environmental factors have been recognized as modifiers of the susceptibility to AD,3 the causes of the most prevalent sporadic late-onset AD are largely unknown. Because there is no proven way to prevent AD and there is currently no cure available, it is important to identify factors influencing AD and their mode of action.
There is evidence suggesting that the glyoxalase domain containing protein 4 (GLOD4), a protein of unknown function, may play a significant role in the central nervous system (CNS) and may be linked to AD. For instance, an intronic SNP in GLOD4, rs2750012, was associated with increased risk of AD in the Arab population of northern Israel. This association has been replicated in metanalysis performed in seven independent GWAS datasets.4 Levels of one of the Glod4 protein isoforms, isoform 3, were significantly elevated in APPSwDI/NOS2–/– mouse model of AD compared to controls.5 Proteomic studies of microglial cells BV-2 showed that treatments with the anti-inflammatory drug polyphenol pentagalloyl glucose (PGG) downregulated GLOD4 while treatments with proinflammatory LPS/IFNγ upregulated GLOD4.6 In addition to GLOD4, PGG downregulated septin-7, ataxin-2, and adenylosuccinate synthetase isozyme 2 (ADSS), which were linked in earlier studies to neurodegenerative diseases such as AD, Parkinson’s disease, Huntington’s disease, Down’s syndrome, and frontotemporal dementia.6 GLOD4 was also identified among 38 duplicated genes in multiple cases of autism spectrum disorder.7
The GLOD4 gene (C17orf25) is found in a region on human chromosome 17 showing high heterozygosity in human hepatocellular carcinoma.8 Human GLOD4 is expressed in most tissues, including the brain (https://www.proteinatlas.org/ENSG00000167699-GLOD4).8 GLOD4 belongs to the glyoxalase gene family that includes glyoxalase 1 (GLO1), which detoxifies methylglyoxal.9 Methylglyoxal, a byproduct of glucose metabolism10 responsible for protein glycation can causes misfolding.11 Glycated proteins easily aggregate, which can give rise to amyloid plaques, a hallmark of AD.12 Although human GLOD4 was suggested to take part in the methylglyoxal detoxification,5 this still is to be shown. A yeast two-hybrid screen showed that GLOD4 protein interacts with mitochondrial ADP-ribose pyrophosphatase NUDT9, which may regulate cell growth.13
The human GLOD4 protein has 3 isoforms, differing in amino acid sequence (http://www.uniprot.org/blast/). The isoform 1 consists of 313 amino acids and contains motifs of the glyoxalase domain,9 antibiotic resistance domain, and a domain characteristic of the family of proteins resistant to the cytotoxic anticancer drug bleomycin (http://www.ncbi.nlm.nih.gov/protein/NP_057164.3).
Bleomycin hydrolase (BLMH) plays a key role in the CNS and is linked to AD. For example, BLMH can process AβPP to Aβ 14 and to further process Aβ.15 Enzymatic activities of BLMH are significantly downregulated in the human AD brain.16 Blmh–/– mice show astrogliosis, behavioral changes,17 and diminished ability to detoxify Hcy-thiolactone, which elevates brain Hcy-thiolactone level and increases its neurotoxicity.4 Proteomic studies of Blmh–/– mouse brain show that Blmh interacts with diverse cellular processes, such as synaptic plasticity, cytoskeleton dynamics, cell cycle, energy metabolism, and antioxidant defenses that are essential for brain homeostasis.18 Blmh–/–5xFAD mouse model of AD shows exacerbated cognitive/neuromotor deficits.19,20 These neurological impairments resulted from the disruption of interactions of Blmh with AβPP and the Phf8/H4K20me1/mTOR/autophagy pathway, which lead to Aβ accumulation and cognitive/neuromotor deficits.20
Here we examined the role of GLOD4 in the CNS by studying GLOD4 expression in AD brains. We also examined Glod4 expression in Blmh–/–5xFAD mouse model of AD in relation to cognitive/neuromotor performance in these mice and biochemical consequences of Glod4 gene silencing in mouse neuroblastoma N2a-APPswe cells. Our findings show that GLOD4 is important for CNS homeostasis.
MATERIALS AND METHODS
Human brain samples
Human frontal cerebral cortical tissues were obtained at autopsy by the Case Western Reserve University Brain Bank under an IRB-approved protocol, from clinically and pathologically confirmed cases of AD (n = 6) using criteria set up by the National Institute of Aging (NIA) and Consortium to Establish a Registry for Alzheimer’s Disease (CERAD).21 Brain tissues were also obtained from non-AD control patients (n = 6). Samples of frontal cortex, coded prior to shipment to keep laboratory personnel blinded as to diagnosis, were shipped on dry ice to the New Jersey Medical School and stored at– 80°C until used. The AD patients were 84±8-year-old, 67% female, postmortem interval was 8±5 h. Controls were 77±6-year-old (p = 0.100), 83% female (p = 0.549), postmortem interval was 16±8 (p = 0.103).
Mice
Blmh–/–5xFAD mice, obtained by crossing Blmh–/–22 and 5xFAD23 animals, were characterized in an earlier study.20 Blmh and 5xFAD genotypes were established by PCR using primers listed in Table 1. Mice were kept at the Rutgers-New Jersey Medical School Animal Facility as previously described.20 5xFAD mice carry a transgene with the K670N/M671L (Swedish), I716V (Florida), and V717I (London) mutations in human AβPP(695), and M146L and L286V mutations in human PS1 associated with familial early-onset AD. 5xFAD mice accumulate elevated levels of Aβ42 beginning around 2 months of age.23 Four groups of 5-month-old mice of both sexes were used in experiments: Blmh–/–, their wild type Blmh+/+ littermates, Blmh–/–5xFAD, and their Blmh+/+5xFAD littermates. The groups were derived from multiple litters and equal number of females and males were used in each group. Animal procedures were approved by the Institutional Animal Care and Use Committee at Rutgers-New Jersey Medical School.
Table 1
Gene | Primer sequence |
GLOD4 isoform 1* | Forward: 5′-CACCCGGATAACAGAAGACAGTT-3′ |
Reverse: 5′-TTCCAAAAGCTGCTGCATG-3′ | |
GLOD4 isoform 2* | Forward: 5′-CACCCGGATAACAGAAGACAGTT-3′ |
Reverse: 5′-CTTGTAGTCTCCGACGCCAT-3′ | |
GLOD4 isoform 3* | Forward: 5′-GCAGTGTCTGATCTTCAAAAGTCC-3′ |
Reverse: 5′-TTCTCCAAGATTGCTCACCTGG-3′ | |
Glod4 isoform 1# | Forward: 5′-CTTGCTTCTAGCCAAGCTGT-3′ |
Reverse: 5′-AGACACTGCTAGAGTCACCT-3′ | |
Glod4 isoform 2$ | Forward: 5′-ATCCTGACTCCGTTGGTGA-3′ |
Reverse: 5′-TGCAGCCTTCACCATCATC-3′ | |
Glod4 isoform 3$ | Forward: 5′-GTTCTAAACAGCCCAGATGTTC-3′ |
Reverse: 5′-TTGTAGTCTCCGATGCCATAAT-3′ | |
Actb | Forward: 5′-TGTTACCAACTGGGACGACA-3′ |
Reverse: 5′-GGGGTGTTGAAGGTCTCAAA-3′ | |
APP, App | Forward: 5′-CTTCCCCAAGATCCTGATAAACT-3′ |
Reverse: 5′-CCGGGTGTCTCCAGGTACT-3′ | |
Atg5 | Forward: 5′-AAGGCACACCCCTGAAATGG-3′ |
Reverse: 5′-TGATGTTCCAAGGAAGAGCTGAA-3′ | |
Sqstm1 (p62) | Forward: 5′-GGGGAAGGGTTCAATGAGAG-3′ |
Reverse: 5′-AATGGGCATATTTGGGGTCT-3′ | |
Map1lc3b (Lc3) | Forward: 5’-AGATCCCAGTGATTATAGAGCGA-3’ |
Reverse: 5’-ACTTCGGAGATGGGAGTGGA-3’ | |
Blmh | Forward p1:5′-CACTGTAGCTGTACTCACAC-3’ |
Reverse p2:5′-GCGACAGAGTACCATGTAGG-3′ (exon 3); Reverse p3:5′-ATTTGTCACGTCCTGCACGACG-3′ (neomycin cassette) | |
hAPP transgene in 5xFAD mice | Forward: 5′-AGAGTACCAACTTGCATGACTACG-3′; |
Reverse: 5′-ATGCTGGATAACTGCCTTCTTATC-3′ | |
hPS1 transgene in 5xFAD mice | Forward: 5′-GCTTTTTCCAGCTCTCATTTACTC-3′ |
Reverse: 5′-AAAATTGATGGAATGCTAATTGGT-3′ |
*Primers for human GLOD4 isoforms are specific and amplify only the indicated isoforms. #Primers for the major mouse Glod4 isoform 1 amplify also minor isoforms 2 and 3. $Primers for the mouse minor Glod4 isoforms 2 and 3 are specific and amplify only the indicated isoforms.
Behavioral testing
Cognitive and neuromotor performance was evaluated using the novel object recognition (NOR)24 and the hindlimb25 tests as previously described.20 Briefly, NOR evaluates recognition memory in two sessions. During the familiarization session, a mouse freely explores two identical objects for 20 s. Six hours later, during the test session with one object replaced by a novel object, a mouse is allowed to explore for 20 s. The time spent exploring each object is calculated from video recordings. Cognitively healthy mice spend more time exploring a novel object, while cognitively impaired mice do not differentiate between novel and familiar objects.
The hindlimb test evaluates neurodegeneration. A mouse is suspended by tail and videorecorded for 10 s in three trials over three days. Hindlimb clasping is scored from 0 to 3: score 0, hindlimbs splayed outward and away from the abdomen; score 1, one hindlimb retracted inwards towards the abdomen for at least 50% of the observation period; score 2, both hindlimbs partially retracted inwards towards the abdomen for at least 50% of the observation period; score 3, both hindlimbs completely retracted inwards towards the abdomen for at least 50% of the observation period. The scores were averaged for the three trials. A higher score indicates worse neurodegeneration.
Cell culture and Glod4 siRNA transfection
Mouse neuroblastoma N2a-APPswe cells, harboring a human AβPP transgene with the K670N and M671L Swedish mutations associated with familial early-onset AD26 were grown (37°C, 5% CO2) in DMEM/F12 medium (Thermo Scientific) supplemented with 5% FBS, non-essential amino acids, and antibiotics (penicillin/streptomycin) (MilliporeSigma).
Cell monolayers (50– 60% confluency), washed twice with PBS, were transfected with Glod4-targeting siRNAs (siRNA Glod4 #1: Cat. #43390816 ID s84641; siRNA Glod4 #2: Cat. #4390816 ID s84642, Thermo Scientific); siRNA scrambled (siRNAscr; Silencer R Negative Control siRNA #1, AM4635, Ambion) in Opti-MEM medium with Lipofectamine RNAiMax (Thermo Scientific) for 48 h.
Western blots
Proteins from human cerebral cortex, whole mouse brain, and N2a-APPswe cells were extracted using RIPA buffer (MilliporeSigma) with Protease Inhibitor cocktail (Sigma P8340) as previously described.20 Proteins were separated by SDS-PAGE on 16% acrylamide gels immobilized by transfer to a PVDF membrane (Cat. #1620177, Bio-Rad) using a Trans-Blot Turbo Transfer System (Trans-Blot®TurboTM, Bio-Rad) according to manufacturer’s specifications (20 min, 120 mA, 25 V), membranes were washed with TBST, blocked 1 h with 5% bovine serum albumin in TBST, and quantified with the following antibodies: anti-GLOD4 (Novus Biologicals NBP2-60713, 1:1,000 dil.), anti-GAPDH (MilliporeSigma PLA0125, 1:4,000 dil.), anti-Glod4 (Abcam AB188371, 1:1,000 dil.), anti-App (Abcam ab126732, 1:1,000 dil.), anti-β-actin (Abcam ab8227, 1:3,500 dil.), anti-LC3 (CST #12741S), anti Atg5 (CST #12994P), anti-p62 (CST #39749S), or anti-Gapdh (CST #5174, 1:2,000) overnight at 4°C. Membranes were washed three times with TBST, 10 min each, and incubated with goat anti-rabbit IgG secondary antibody conjugated with horseradish peroxidase (CST, #7074 S, 1:3,000). Positive signals were detected using Western Bright Quantum-Advansta K12042-D20 and GeneGnome XRQ NPC chemiluminescence detection system. Bands intensity was calculated using Gene Tools program from Syngene.
RNA isolation, cDNA synthesis, RT-qPCR analysis
Total RNA was isolated using Trizol reagent (MilliporeSigma). RNA concentration was measured using NanoDrop (Thermo Fisher Scientific) and integrity was assessed by agarose gel (1%) electrophoresis. cDNA was synthesized using Revert Aid First cDNA Synthesis Kit (Thermo Fisher Scientific) according to manufacturer’s protocol. RT-qPCR reactions (2 ng/μL cDNA, primers 0.3μM each, iTaq 5μL in a total volume of 10μL) were performed in two technical replicates using SYBR Green Mix and the CFX96 Touch Real-Time PCR Detection System (Bio-Rad). RT-qPCR primer sequences are listed in Table 1.
For mouse Actb, Glod4_1, Glod4_2, Glod4_3 the following reaction conditions were used: (1) initial denaturation 2 min, 95°C; (2) denaturation 15 s, 95°C; (3) primer annealing (temperature (T)), 15 s; (4) primer extension 10 s, 72°C; melting curve 65– 95°C. T = 60°C for Glod4_1, Glod4_2, Glod4_3, App, Atg5, p62; T = 56°C for Actb. The cycle of denaturation, annealing, and extension was repeated 40 times.
For human GAPDH, GLOD4_1, GLOD4_2, and GLOD4_3, the following reaction conditions were used: initial denaturation 2 min, 95°C; denaturation 35 s, 95°C; primer annealing 10 s, 62°C; primer extension, 30 s, 72°C; melting curve 65– 95°C. The cycle of denaturation, annealing, and extension was repeated 40 times.
The 2(–ΔΔCt) method was used to calculate the relative expression levels.27 Data were analyzed using CFX Manager™ Software and Microsoft Excel.
Data analysis
Normality of distributions was evaluated with the Shapiro-Wilk’s statistic. For variables with normal distributions, the results were calculated as mean±SD for variables with normal distributions or medians for non-normally distributed variables. A parametric unpaired t test was used for comparisons between two groups of variables with normal distribution. A Mann-Whitney rank sum test was used for comparisons between two groups of non-normally distributed variables. Data were analyzed using GraphPad Prism7 software (GraphPad Holdings LLC, San Diego CA, USA, https://www.graphpad.com) and MS Excel.
RESULTS
GLOD4 is downregulated in AD brains
Three isoforms of GLOD4 protein exist in humans: 34.8 kDa isoform 1 (GLOD4_1), 33.2 kDa isoform 2 (GLOD4_2), and 21.3 kDa isoform 3 (GLOD4_3). We quantified mRNAs for GLOD4 isoforms in frontal cerebral cortical tissues from brains of six AD patients and six non-AD controls by using RT-qPCR. We found that GLOD4_1 mRNA level was the highest in control human brains; GLOD4_2 and GLOD4_3 mRNAs were present at 10-fold lower levels (Fig. 1A). Similar pattern of GLOD4 mRNA isoforms expression was seen in AD brains (Fig. 1A). However, relative levels of GLOD4 mRNA isoforms were significantly reduced in AD brains: from 10.31 to 3.83 (by 63%) for GLOD4_1 mRNA, from 1.00 to 0.51 (by 49%) for GLOD4_2 mRNA, and from 1.10 to 0.30 (by 73%) for GLOD4_3 mRNA (Fig. 1A).
Fig. 1
GLOD4 protein, quantified by western blotting, was similarly downregulated in frontal cerebral cortex tissues from human AD brains. SDS-PAGE analyses revealed two bands reacting with anti-GLOD4 antibody in the cortical brain protein extracts: an upper band of 35/33 kDa corresponding to GLOD4_1 and GLOD4_2 and a lower band of 21 kDa corresponding to GLOD4_3, based on the molecular weight (Fig. 1B). Quantification showed that GLOD4_1/2 protein level was significantly reduced in AD brains compared to controls (0.62 versus 1.00) as was the level of GLOD4_3 protein (0.63 versus 1.00) (Fig. 1C).
Glod4 level is associated with Aβ and cognitive/neuromotor performance in Blmh–/–5xFAD mice
To determine whether downregulated GLOD4 levels seen in AD patients are associated with hallmarks of AD, we quantified Glod4 mRNA level in Blmh–/–5xFAD mice, a model of human AD; Blmh+/+5xFAD littermates were used as controls.20 The choice of the Blmh–/–5xFAD mouse model20 for studies of Glod4 was based on our previous findings showing that Blmh activity was reduced in human AD brains.16 Because Aβ starts to accumulate in 5xFAD mice at 2 months,23 this model allowed examination of a relationship between Glod4 expression, behavioral performance, and Aβ accumulation at an early age. Earlier analyses of gene expression in mouse liver showed that Glod4_1 mRNA is a major isoform while Glod4_3 is a minor isoform while Glod4_2 isoform was not detectable by PCR and that Glod4_3 mRNA isoform was not expressed Blmh–/– mouse liver.18
Using RT-qPCR we found that Glod4_1 was the most abundant isoform and Glod4_3 was present at 25-fold lower level than Glod4_1 in the mouse brain (0.041 versus 1.00, Table 2). The Glod4_2 mRNA isoform was essentially absent in the mouse brain, with an estimated level 1250-fold (0.0008 versus 1.00) and 51-fold (0.0008 versus 0.041) lower than those of Glod4_1 and Glod4_3 mRNAs, respectively (Table 2).
Table 2
Isoform | Relative expression* | ||||
Blmh+/+ mice | Blmh–/– mice | Fold change | pBlmhgenotype | pGlod4isoform | |
Glod4_1 | 1.00±0.26 | 1.24±0.53 | 1.24 | 0.340 | 1.0 |
Glod4_2 | 0.0008# | ||||
Glod4_3 | 0.041±0.014 | 0.00003±0.000006$ | 1,255 | 0.004 | 1E.-08 |
*Mouse brain Glod4 mRNA isoforms were quantified by RT-qPCR using Actb mRNA as a reference and primers listed in Table 1. Six to seven-week-old Blmh+/+ (n = 12) and Blmh–/– (n = 10) mice of both sexes were used in the experiments. Signals for Glod4_3 were observed in brain samples from all wild type Blmh+/+ mice and in two out of ten Blmh–/– mice. # Estimated from RT-qPCR measurements in duplicates with 10 samples containing 5– 80 ng cDNA prepared from wild type Blmh+/+ mouse brain RNA. Signals for Glod4_2 were observed for 4 out of 10 samples.
We found that Glod4_1/3 mRNA was significantly downregulated in brains of Blmh–/–5xFAD mice compared to Blmh+/+5xFAD sibling controls (Fig. 2A), thus recapitulating the findings in the human AD brain (Fig. 1A). Low Glod4 expression level in Blmh–/–5xFAD brains was accompanied by elevated Aβ level (Fig. 2B).
Fig. 2
Behavioral testing showed that Blmh–/–5xFAD mice with lower Glod4 level also had neurological impairments characteristic of human AD. Specifically, these mice spent the same time exploring novel and familiar objects, i.e., did not differentiate between novel and familiar objects in the NOR test, which shows impaired recognition memory. In contrast, Blmh+/+5xFAD mice that had higher Glod4_1 level spent more time exploring a novel object, i.e., had normal preference for novelty (Fig. 2C).
In the hindlimb clasping test, Blmh–/–5xFAD mice that showed downregulated Glod4_1 level also showed significantly higher scores (indicating neuromotor deficits) compared to Blmh+/+5xFAD animals that had higher Glod4_1 (Fig. 1A) and lower scores (i.e., better neuromotor performance) (Fig. 2D).
5xFAD transgene affects Glod4 expression in Blmh–/– and wild type Blmh+/+ mice
To assess whether the 5xFAD transgene affects Glod4 expression, we quantified Glod4 mRNA in Blmh–/– and Blmh+/+ mice without the 5xFAD transgene. We found that Glod4_1/3 mRNA was significantly downregulated in Blmh–/–5xFAD mice compared to non-transgenic Blmh–/– animals (Fig. 3A). We also found that the effect of the 5xFAD transgene on Glod4 mRNA expression in Blmh–/– mice was sex-independent, similar in females and males (Fig. 3B).
Fig. 3
Glod4_1/3 mRNA was significantly downregulated also in Blmh+/+5xFAD mice compared with non-transgenic wild type Blmh+/+ animals (Fig. 3A), although the difference was attenuated compared to the difference seen between Blmh–/–5xFAD and Blmh–/– mice. In contrast to Blmh–/– mice, the influence of the 5xFAD transgene on Glod4 mRNA expression in Blmh+/+ mice was sex-dependent: observed in males but not in females (Fig. 3C).
Reduced Glod4_1/3 mRNA expression, seen in Blmh–/–5xFAD mice compared to Blmh+/+5xFAD animals ((0.80±0.38 (n = 22) versus 1.06±0.31 (n = 15), p = 0.045) Figs. 2A, 3A), was sex-dependent, observed in female but not male mice (Fig. 3D). However, there was no significant difference in Glod4_1/3 mRNA expression between six to seven-week-old (Table 2) and 5-month-old (1.99±0.23 (n = 4) versus 1.67±0.62 (n = 7), p = 0.405; Fig. 3A) Blmh–/– and wild type Blmh+/+ mice without the 5xFAD transgene, showing that Blmh genotype does not affect Glod4 expression in the absence of the 5xFAD transgene.
Glod4 gene silencing affects AβPP and autophagy-related Atg5, p62, and lipidated LC3-II expression in mouse neural cells
To elucidate the mechanism by which Glod4 can affect behavioral hallmarks of AD, we first examined whether our findings of downregulated GLOD4 expression in brains of AD patients (Fig. 1A) can be recapitulated in mouse neuroblastoma cells N2a-APPswe carrying a mutated human AβPP transgene. We silenced the Glod4 gene by RNA interference using siRNA Glod4#1 and siRNA Glod4#2 for transfections; controls were transfected with scrambled siRNA (siRNAscr). Gene expression was examined by RT-qPCR using Actb mRNA as a reference.
We found that the Glod4 mRNA level was significantly reduced in Glod4-silenced cells (by 76% for siRNA Glod4#1 and by 98% for siRNA Glod4#2; Fig. 4A). Glod4 protein was also significantly downregulated (by 90%) in the silenced cells (Fig. 4B). The downregulation of Glod4 expression was accompanied by upregulation of AβPP mRNA (Fig. 4C) and AβPP protein (Fig. 4D).
Fig. 4
The regulator of autophagosome assembly Atg5 mRNA (Fig. 4E) and protein (Fig. 4F) were significantly downregulated. The receptor for degradation of ubiquitinated substrates p62 mRNA (Fig. 4G) and protein (Fig. 4H) were also significantly downregulated.
To determine whether autophagic flux was influenced by Glod4 silencing, we quantified the expression of Lc3 (microtubule associated protein 1A/1B-light chain 3) that is involved in the formation of autophagosomes. We found that Lc3 mRNA was downregulated (Fig. 4I). Of the two forms of Lc3 protein, the autophagosome-bound lapidated LC3-II protein was significantly downregulated (Fig. 4J) while un-lipidated LC3-I protein was not affected by Glod4 silencing (Fig. 4K). The LC-3I/LC3-II ratio was increased (Fig. 4L), suggesting impaired autophagy in Glod4-silenced cells. In contrast, the expression of Atg7 and Becn1 were not affected by Glod4 silencing (not shown). Representative images of western blots are shown in Fig. 4M.
To find whether the effects of Glod4 silencing on autophagy could be mediated by mTOR signaling, we quantified mRNAs levels for mTOR and PHF8 (a positive regulator of mTOR expression) in Glod4-silenced and control cells. We found that mTOR and Phf8 mRNA levels were not affected by the Glod4 gene silencing (not shown).
DISCUSSION
Our findings suggest that Glod4, a protein with an unknown function, may have a protective role in the CNS. Specifically, we showed that (i) GLOD4 mRNA and protein were downregulated in human AD patients compared to non-AD controls; (ii) Glod4 mRNA was similarly downregulated in Blmh–/–5xFAD mouse model of AD, mostly in females; (iii) The 5xFAD transgene downregulated Glod4 in Blmh–/– mice of both sexes and in Blmh+/+ males but not females; (iv) reduced Glod4 expression was associated with elevated Aβ and worsened memory/sensorimotor performance in Blmh–/–5xFAD mice (v); Glod4 silencing in N2a-APPswe cells upregulated AβPP and downregulated autophagy-related Atg5, p62, and LC3 genes. These findings suggest that Aβ accumulation in GLOD4-depleted brains can occur via two pathways shown in Fig. 4N.
In the first pathway, GLOD4 depletion upregulates AβPP, which increases Aβ accumulation leading to cognitive/neuromotor impairments. In the second pathway, GLOD4 depletion downregulates Atg5, p62, and lipidated LC3-II, which impairs autophagy flux and thus increases Aβ level and cognitive/neuromotor deficits. That impaired autophagy can increase Aβ accumulation mediated by AβPP is known. For example, Becn1, a protein initiating autophagy, is decreased in human AD brains while genetic reduction of Becn1 in transgenic mice that overexpress AβPP (APP+Becn+/– mice) increased Aβ in neuronal cells.28 However, as we did not find any effect of Glod4 depletion on Becn1 expression (not shown), Glod4 depletion upregulates AβPP and Aβ by a Becn1-independent mechanism.
AβPP level is an important determinant of AD, most strikingly manifested in individuals with Down syndrome who show an early AD neuropathology caused by an extra copy of the APP gene due to trisomy of chromosome 21.29–31 Transcriptional factors (SP-1, AP-1, CTCF, HSF1,NF-kB, USF, ApoE, androgen) and translational regulators (iron, IL-1, TGFβ, FMRP, hnRNP C, Rck/54, PSF/SFPQ) of AβPP expression have been identified.32 In previous work, we have shown that deletion of genes encoding enzymes participating in homocysteine metabolism in mice such as Cbs, Pon1, or Blmh elevated levels of AβPP and Aβ in the mouse brain. In the present study, we found that depletion of a protein of unknown function, Glod4, in neural cells (Fig. 4) and Blmh–/–5xFAD mice (Fig. 1) was associated with upregulation of AβPP. These findings identify reduced level of Glod4 as a new factor that can influence the development of AD by upregulating AβPP and Aβ. The mechanism by which Glod4 can regulate AβPP and Aβ levels remains to be elucidated in future studies.
Our findings that Glod4 was depleted in Blmh–/–5xFAD mice versus Blmh+/+5xFAD sibling controls but not in Blmh–/– versus sibling control wild type Blmh+/+ mice (Fig. 3A) suggest that Glod4 depletion may be secondary to Aβ accumulation in Blmh–/–5xFAD animals. However, to find out whether downregulation of Glod4 precedes or is secondary to Aβ accumulation, it would be necessary to examine Aβ and Glod4 levels in Blmh–/–5xFAD animals at different time points. Our findings also suggest that Hcy-thiolactone and/or N-Hcy-proteins, which accumulate in Blmh-deficient mice33 are unlikely to influence Glod4 expression. The mechanism of Glod4 depletion in mouse Blmh–/–5xFAD brain and in human AD brain remains to be studied.
Although Blmh depletion caused Glod4 depletion in Blmh–/–5xFAD mouse brain, downstream effects of Glod4 depletion leading to Aβ accumulation are different from those of Blmh depletion. Specifically, Blmh depletion in neural cells upregulated mTOR via Phf8/H4K20me1 and impaired autophagy by reducing the expression of Atg5, Atg7, Becn1 and increasing p62.20 In contrast, Glod4 depletion did not affect mTOR, Atg7, and Becn1 expression, but downregulated p62 expression (Fig. 4). Only Atg5 and lipidated LC3-II were similarly downregulated in Glod4 and Blmh depleted neural cells. These findings suggest that Glod4 depletion dysregulates autophagy via an mTOR independent mechanism, which remains to be examined.
We found that major GLOD4_1 isoform, and minor GLOD4_2 and GLOD4_3 isoforms, were expressed in the human brain. We also found that all three isoforms were similarly attenuated in AD brains (Fig. 1). In mice, Glod4_2 isoform was expressed at an extremely low level in wild type animals (0.0008 of the Glod4_1 expression level (Table 2) and that Glod4_1/3 isoforms were also downregulated in the Blmh–/–5xFAD mouse model (Figs. 2 and 3). These findings suggest that GLOD4 isoforms are unlikely to have an isoform-specific function in AD and thus leave open a question of what the role of GLOD4 isoforms in brain physiology is.
In conclusion, our findings suggest that Glod4 may interact with AβPP and the autophagy pathway, and that disruption of these interactions upregulates Aβ, which causes cognitive/neurosensory deficits, thereby highlighting Glod4’s role in brain homeostasis. Further studies are needed to assess causality of the association of GLOD4 depletion with AD.
AUTHOR CONTRIBUTIONS
Hieronim Jakubowski, PhD, DSc (Conceptualization; Data curation; Funding acquisition; Investigation; Methodology; Project administration; Resources; Supervision; Validation; Writing – original draft; Writing – review & editing); Olga Utyro (Data curation; Funding acquisition; Investigation; Methodology; Validation; Writing – review & editing); Olga Włoczkowska-Łapińska (Investigation; Methodology; Validation; Writing – review & editing).
ACKNOWLEDGMENTS
We thank H.G. Lee for samples of AD and control human brains, S.S. Sisodia for the mouse neuroblastoma N2a-APPswe cells, and J. Lazo for the Blmh–/– mouse.
FUNDING
Supported in part by grants 2015/17/N/NZ3/03626, 2018/29/B/NZ4/00771, 2019/33/B/NZ4/01760, and 2021/43/B/NZ4/00339 from the National Science Center, Poland, and Grant 17GRNT32910002 from the American Heart Association. The publication was financed by the Polish Minister of Science and Higher Education as part of the strategy of the Poznan University of Life Sciences for 2024-2026 in the field of improving scientific research and development work in priority research areas.
CONFLICT OF INTEREST
Hieronim Jakubowski is an Editorial Board Member of this journal but was not involved in the peer-review process nor had access to any information about its peer-review. All other authors have no conflict of interest to report.
DATA AVAILABILITY
The data that support the findings of this study are available in the methods and/or supplementary material of this article.
REFERENCES
1. | . 2024 Alzheimer’s disease facts and figures. Alzheimers Dement (2024) ; 20: : 3708–3821. |
2. | Tanzi RE . The genetics of Alzheimer disease. Cold Spring Harb Perspect Med (2012) ; 2: : a006296. |
3. | Dorszewska J , Prendecki M , Oczkowska A , et al. Molecular basis of familial and sporadic Alzheimer’s disease. Curr Alzheimer Res (2016) ; 13: : 952–963. |
4. | Sherva R , Baldwin CT , Inzelberg R , et al. Identification of novel candidate genes for Alzheimer’s disease by autozygosity mapping using genome wide SNP data. J Alzheimers Dis (2011) ; 23: : 349–359. |
5. | Hoos MD , Richardson BM , Foster MW , et al. Longitudinal study of differential protein expression in an Alzheimer’s mouse model lacking inducible nitric oxide synthase. J Proteome Res (2013) ; 12: : 4462–4477. |
6. | Mendonca P , Taka E and Soliman KFA. Proteomic analysis of the effect of the polyphenol pentagalloyl glucose on proteins involved in neurodegenerative diseases in activated BV-2 microglial cells. Mol Med Rep (2019) ; 20: : 1736–1746. |
7. | Zarrei M , Burton CL , Engchuan W , et al. A large data resource of genomic copy number variation across neurodevelopmental disorders. NPJ Genom Med (2019) ; 4: : 26. |
8. | Qin WX , Wan F , Sun FY , et al. Cloning and characterization of a novel gene (C17orf25) from the deletion region on chromosome 17p13.3 in hepatocelular carcinoma. Cell Res (2001) ; 11: : 209–216. |
9. | Farrera DO and Galligan JJ. The human glyoxalase gene family in health and disease. Chem Res Toxicol (2022) ; 35: : 1766–1776. |
10. | Thornalley PJ . Pharmacology of methylglyoxal: formation, modification of proteins and nucleic acids, and enzymatic detoxification–a role in pathogenesis and antiproliferative chemotherapy. Gen Pharmacol (1996) ; 27: : 565–573. |
11. | Li XH , Xie JZ , Jiang X , et al. Methylglyoxal induces tau hyperphosphorylation via promoting AGEs formation. Neuromolecular Med (2012) ; 14: : 338–348. |
12. | Gomes R , Sousa Silva M , Quintas A , et al. Argpyrimidine, a methylglyoxal-derived advanced glycation end-product in familial amyloidotic polyneuropathy. Biochem J (2005) ; 385: : 339–345. |
13. | Zhang HT , Yan ZQ , Hu XB , et al. Interaction of C17orf25 with ADP-ribose pyrophosphatase NUDT9 detected via yeast two-hybrid method. Sheng Wu Hua Xue Yu Sheng Wu Wu Li Xue Bao (Shanghai) (2003) ; 35: : 747–751. |
14. | Lefterov IM , Koldamova RP and Lazo JS. Human bleomycin hydrolase regulates the secretion of amyloid precursor protein. FASEB J (2000) ; 14: : 1837–1847. |
15. | Kajiya A , Kaji H , Isobe T , et al. Processing of amyloid beta-peptides by neutral cysteine protease bleomycin hydrolase. Protein Pept Lett (2006) ; 13: : 119–123. |
16. | Suszynska J , Tisonczyk J , Lee HG , et al. Reduced homocysteine-thiolactonase activity in Alzheimer’s disease. J Alzheimers Dis (2010) ; 19: : 1177–1183. |
17. | Towne CF , York IA , Watkin LB , et al. Analysis of the role of bleomycin hydrolase in antigen presentation and the generation of CD8 T cell responses. J Immunol (2007) ; 178: : 6923–6930. |
18. | Suszynska-Zajczyk J , Utyro O and Jakubowski H Methionine-induced hyperhomocysteinemia and bleomycin hydrolase deficiency alter the expression of mouse kidney proteins involved in renal disease. Mol Genet Metab (2014) ; 112: : 339–346. |
19. | Montoya SE , Thiels E , Card JP , et al. Astrogliosis and behavioral changes in mice lacking the neutral cysteine protease bleomycin hydrolase. Neuroscience (2007) ; 146: : 890–900. |
20. | Witucki L , Borowczyk K , Suszynska-Zajczyk J , et al. Deletion of the homocysteine thiolactone detoxifying enzyme bleomycin hydrolase, in mice, causes memory and neurological deficits and worsens Alzheimer’s disease-related behavioral and biochemical traits in the 5xFAD model of Alzheimer’s disease. J Alzheimers Dis (2023) ; 95: : 1735–1755. |
21. | Khachaturian ZS . Diagnosis of Alzheimer’s disease. Arch Neurol (1985) ; 42: : 1097–1105. |
22. | Schwartz DR , Homanics GE , Hoyt DG , et al. The neutral cysteine protease bleomycin hydrolase is essential for epidermal integrity and bleomycin resistance. Proc Natl Acad Sci U S A (1999) ; 96: : 4680–4685. |
23. | Oakley H , Cole SL , Logan S , et al. Intraneuronal beta-amyloid aggregates, neurodegeneration, and neuron loss in transgenic mice with five familial Alzheimer’s disease mutations: potential factors in amyloid plaque formation. J Neurosci (2006) ; 26: : 10129–10140. |
24. | Leger M , Quiedeville A , Bouet V , et al. Object recognition test in mice. Nat Protoc (2013) ; 8: : 2531–2537. |
25. | Lieu CA , Chinta SJ , Rane A , et al. Age-related behavioral phenotype of an astrocytic monoamine oxidase-B transgenic mouse model of Parkinson’s disease. PLoS One (2013) ; 8: : e54200. |
26. | Thinakaran G , Teplow DB , Siman R , et al. Metabolism of the ``Swedish’’ amyloid precursor protein variant in neuro2a (N2a) cells. Evidence that cleavage at the ``beta-secretase’’ site occurs in the Golgi apparatus. J Biol Chem (1996) ; 271: : 9390–9397. |
27. | Livak KJ and Schmittgen TD. Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) method. Methods (2001) ; 25: : 402–408. |
28. | Pickford F , Masliah E , Britschgi M , et al. The autophagy-related protein beclin 1 shows reduced expression in early Alzheimer disease and regulates amyloid beta accumulation in mice. J Clin Invest (2008) ; 118: : 2190–2199. |
29. | Hartley D , Blumenthal T , Carrillo M , et al. Down syndrome and Alzheimer’s disease: Common pathways, common goals. Alzheimers Dement (2015) ; 11: : 700–709. |
30. | Lott IT and Head E. Dementia in Down syndrome: unique insights for Alzheimer disease research. Nat Rev Neurol (2019) ; 15: : 135–147. |
31. | Helman AM , Siever M , McCarty KL , et al. Microbleeds and cerebral amyloid angiopathy in the brains of people with Down syndrome with Alzheimer’s disease. J Alzheimers Dis (2019) ; 67: : 103–112. |
32. | Sato K , Takayama KI , Hashimoto M , et al. Transcriptional and post-transcriptional regulations of amyloid-beta precursor protein (APP) mRNA. Front Aging (2021) ; 2: : 721579. |
33. | Borowczyk K , Tisonczyk J and Jakubowski H. Metabolism and neurotoxicity of homocysteine thiolactone in mice: protective role of bleomycin hydrolase. Amino Acids (2012) ; 43: : 1339–1348. |