Özet

Quantitative Methods to Study Protein Arginine Methyltransferase 1-9 Activity in Cells

Published: August 07, 2021
doi:

Özet

These protocols provide the methodology used to assess the enzymatic activity of individual members of the protein arginine methyltransferase (PRMT) family in cells. Detailed guidelines on assessing PRMT activity using endogenous and exogenous biomarkers, methyl-arginine recognizing antibodies, and inhibitor tool compounds are described.

Abstract

Protein methyltransferases (PRMTs) catalyze the transfer of a methyl group to arginine residues of substrate proteins. The PRMT family consists of nine members that can monomethylate or symmetrically/asymmetrically dimethylate arginine residues. Several antibodies recognizing different types of arginine methylation of various proteins are available; thus, providing tools for the development of PRMT activity biomarker assays. PRMT antibody-based assays are challenging due to overlapping substrates and motif-based antibody specificities. These issues and the experimental setup to investigate the arginine methylation contributed by individual PRMTs are discussed. Through the careful selection of the representative substrates that are biomarkers for eight out of nine PRMTs, a panel of PRMT activity assays were designed. Here, the protocols for cellular assays quantitatively measuring the enzymatic activity of individual members of the PRMT family in cells are reported. The advantage of the described methods is their straightforward performance in any lab with cell culture and fluorescent western blot capabilities. The substrate specificity and chosen antibody reliability were fully validated with knockdown and overexpression approaches. In addition to detailed guidelines of the assay biomarkers and antibodies, information on the use of an inhibitor tool compound collection for PRMTs is also provided.

Introduction

Arginine methylation is an important post-translational modification that regulates protein-protein and protein-RNA interactions, thus playing an important role in various cellular processes such as pre-mRNA splicing, DNA damage, transcription response, and growth factor-mediated transduction1,2. Arginine is methylated by protein arginine methyltransferases (PRMTs) resulting in monomethyl arginine (Rme1), asymmetrical dimethylarginine (Rme2a), or symmetrical dimethylarginine (Rme2s)3. Based on the methylation type, PRMTs are classified into three groups: Type I (PRMT1, 2, 3, 4, 6, and 8), which catalyze mono- and asymmetric dimethylation; Type II (PRMT5 and PRMT9), which catalyze mono- and symmetric dimethylation; and Type III (PRMT7), which can only monomethylate arginine3.

Due to a growing number of commercially available arginine methylation-specific antibodies, PRMT activity can be measured using western blotting. Fluorescent-based western blot is the preferred technique over chemiluminescent detection due to a greater dynamic range and linearity, higher sensitivity, and allowing for multiplexing4. To quantify the protein methylation levels, normalization of the methylation signal to total protein levels is required. By choosing the antibodies for total and methylated protein raised in different host species (e.g., mouse and rabbit), secondary antibodies labeled with different fluorophores can be used and the signal for both antibodies can be determined in the same sample band. Methyl-arginine antibodies were developed to identify and characterize monomethylated, asymmetrically, or symmetrically dimethylated proteins where methyl-arginine is found in a specific context. Since the majority of PRMTs methylate glycine- and arginine-rich motifs within their substrates5, several antibodies were raised for the peptides containing monomethyl or asymmetric, symmetric dimethyl-arginine-glycine repeats such as D5A12, ASYM24, or ASYM25, and SYM11, respectively. Other methyl-arginine antibodies were generated against a peptide library containing asymmetric, symmetric dimethyl- and monomethyl arginine in a repeat context facilitating the detection of methyl-arginine in these particular contexts6. There is also an increasing number of antibodies that recognize specific arginine mark on a single protein which enable selective detection of methylation such as histone H4R3me2a or BAF155-R1064me2a.

There are several commercially available PRMT inhibitors, which can be used as tools for PRMT cellular assays. However, not all of them are thoroughly characterized for selectivity and off-target effects and some should be used with caution. The Structural Genomic Consortium, in collaboration with academic labs and pharma partners, has developed well-characterized potent, selective, and cell-permeable PRMT inhibitors (chemical probes) that can be used with no restrictions by the scientific community. Information on these inhibitors can be found on https://www.thesgc.org/chemical-probes/epigenetics and https://www.chemicalprobes.org/. Chemical probes are small-molecule inhibitors with in vitro IC50 or Kd < 100 nM, over 30-fold selectivity over proteins in the same family, and significant cellular activity at 1 µM. Additionally, each chemical probe has a close chemical analog that is inactive against the intended target7,8,9,10,11,12.

The goal of this protocol is to measure the cellular activity of individual PRMT family members using the fluorescent western blot method. Here detailed information on validated assay biomarkers, antibodies, and potent cell-active inhibitors as well as valuable strategies for successful assay implementation are provided.

Protocol

1. Cell culturing and plating

NOTE: Culture cells with recommended media and test routinely for mycoplasma contamination. HEK293T, MCF7, and C2C12 cells were chosen as examples since these cell lines were successfully used in PRMT assays.

  1. Culture HEK293T, MCF7, and C2C12 in DMEM supplemented with 10% fetal bovine serum (FBS), penicillin (100 U mL−1), and streptomycin (100 µg mL−1) in 10 cm tissue-culture treated (TC) dishes.
  2. For the PRMT8 assay, grow PRMT1 inducible knockdown HEK293T cells in media containing doxycycline (2 µg/mL) for 3 days before assay start.
  3. To plate the cells, remove and discard media from the plate.
  4. Add 10 mL of PBS (without Ca+2 and Mg+2 ions) to wash cells and discard the solution.
  5. Add 1 mL of Trypsin-EDTA (0.25%), incubate for 1 min at room temperature (RT), and then discard the solution. Incubate until cells become round and detach from the plate. Tap the plate to help detach cells, if needed. For hard-to-trypsinize cells, such as C2C12, incubate the plate for 1-2 min at 37 °C.
    NOTE: Avoid cell exposure to trypsin solution for longer periods (>10 min) as it will reduce cell viability.
  6. Add 1 mL of prewarmed media to the plate, and gently pipette cells up and down to break-up cell clumps. Transfer cells to a 15 mL tube, and add 3-5 mL of media.
  7. To measure cell number, mix 10 µL of cells with 10 µL of Trypan blue and transfer 10 µL to hemocytometer or use any other cell counting method.
  8. Dilute cells to recommended cell density and put 500 µL/well into 24-well TC plates (Table 1). For endogenous assays (PRMT1, PRMT4, PRMT5, PRMT7, and PRMT9), move to Step 3.1.

2. Cell transfection

  1. For exogenous assays (PRMT3, PRMT6, PRMT8) transfect HEK293T cells with the recommended amount of DNA (Table 2). HEK293T cells are easy to transfect so any transfection reagent can be used, following the manufacturer's instruction.

3. Compound treatment

NOTE: Do not exceed 0.1% final dimethyl sulfoxide (DMSO) concentration in culture media. Keep the same DMSO concentration in each well. The selective PRMT inhibitors (chemical probes) and their closely related inactive analogs can be found in Table 3.

  1. For endogenous assays (PRMT1, PRMT4, PRMT5, PRMT7, and PRMT9), remove media from cells and replace with 500 µL of media with compound or DMSO alone (control).
    NOTE: It usually takes 2 days to observe over 80% decrease in R methylation levels.
  2. For exogenous assays (PRMT3, PRMT6, PRMT8), remove media 4 h after transfection, add 500 µL of media with compound or DMSO alone (control), and incubate for 20-24 h.

4. Cell lysate preparation

  1. Remove all media from wells, wash with 100 µL of PBS to remove residual media, and add 60 µL of lysis buffer (20 mM Tris-HCl pH 8, 150 mM NaCl, 1 mM ethylenediaminetetraacetic acid (EDTA), 10 mM MgCl2, 0.5% Triton X-100, 12.5 U mL−1 benzonase, complete EDTA-free protease inhibitor cocktail) to each well.
    1. Incubate for less than 1 min at RT, rocking the plate to distribute the lysis buffer over the cells. Then add 3 µL of 20% w/v sodium dodecyl sulfate (SDS), to a final 1 % concentration, and mix by gently shaking. Transfer lysate into microcentrifuge tubes and keep it on ice.
      NOTE: Add benzonase and protein inhibitor cocktail fresh before use. The addition of benzonase rapidly hydrolyzes nucleic acids which reduces cell lysate viscosity.
  2. Determine protein concentration of the samples using BCA Protein Assay Kit or use any other method which tolerates 1% SDS in solution.
    1. Add 2 µL of lysate and protein standards (0, 1, 2, 4, and 8 µg/mL of BSA in lysis buffer) into the wells of the 96-well clear plate.
    2. Mix reagent A with reagent B at 50:1 ratio and add 200 µL per well. Incubate for 20 min at 37 °C and read the absorbance.
  3. Adjust the protein concentration with lysis buffer to be equal across the samples.
  4. Add 20 µL of 4x Loading Buffer to 60 µL of cell lysate and heat at 95 °C for 5 min. After heat denaturation, the lysates can be stored at -20 °C.

5. Western blot analysis

  1. Load 5-20 µg of total cell lysate for analysis of histone proteins and 20-100 µg for other proteins into a 4-12% Bis-Tris protein gel.
  2. Run the gel in MOPS SDS running buffer (50 mM MOPS, 50 mM Tris Base, 0.1% SDS w/v, 1 mM EDTA, pH 7.7) for about 2 h at 100 V or until the dye front reaches the bottom of the gel.
  3. If performing a wet transfer, assemble the transfer sandwich in ice-cold Tris-Glycine transfer buffer (25 mM Tris, 192 mM Glycine, 20% v/v methanol, and 0.05% w/v SDS).
    1. Place sponges, filter paper, PVDF membrane, and gel according to manufacturer's instructions. Activate PVDF membrane by soaking in methanol and equilibrate gel in transfer buffer for 30 s before assembly.
      NOTE: Use recommended PVDF western blotting membrane since it has low autofluorescence and suitability for low molecular weight proteins, such as histones (Table of Materials).
  4. Transfer proteins from the gel to PVDF membrane in Tris-Glycine transfer buffer at 70 V for 1.5 h on ice.
  5. Block membrane for 30 min in blocking buffer (5% w/v milk in phosphate-buffered saline, PBS). Rinse with wash buffer (PBST: 0.1% v/v Tween-20 in PBS), and incubate with primary antibodies in bovine serum albumin (BSA) solution (5% BSA in PBST) overnight at 4 °C (Table 3).
    NOTE: For longer storage, filter-sterilize BSA solution, add 0.02% w/v sodium azide, and keep at 4 °C.
  6. Wash membrane 3 x 5 min with PBST. Then incubate with goat-anti-rabbit (IR800) and donkey anti-mouse (IR680) antibodies in recommended blocking buffer (Table of Materials, Table 3) for 30 min at RT and wash 3 x 5 min with PBST.
  7. Read the signal on a fluorescent western blot imager at 800 and 700 nm. Preferably use the instrument which allows imaging strong and faint bands clearly in a single image with high sensitivity and dynamic range, high signal-to-noise ratio, a warning when an image saturation is reached as well as multiplexing of two fluorescent colors in the same sample band.
  8. Determine band intensities for western blot analysis using appropriate software for fluorescent western imaging.

Representative Results

Examples of western blot results for cellular assays of individual PRMTs are presented below. Assays details are also summarized in Table 4.

PRMT1 assay
PRMT1 is the main contributor to histone 4 arginine 3 asymmetric dimethylation (H4R3me2a) in cells13. Upon loss of PRMT1 activity, global Rme1 and Rme2s levels increase significantly13. As shown in Figure 1A and 1B, several antibodies can be used to monitor global changes in Rme1, Rme2a, Rme2s, as well as H4R3me2a. A significant decrease in global Rme2a and H4R3me2a levels and increases in Rme1 and Rme2s can be observed after 3 days of PRMT1 knockdown (Figure 1A, B). Cell lines differ in basal H4R3me2a signal, therefore, to facilitate monitoring the loss of PRMT1 activity, cell lines such as MCF7 with high basal methylation levels can be used (Figure 1C). The optimal time to observe the effect of PRMT1 inhibition, e.g. upon treatment with type I PRMT inhibitor MS0238, is 2 days (Figure 1D,1E). Longer treatment results in reduced cell viability and growth.

PRMT3 assay
For the PRMT3 cellular assay, no selective biomarker proteins which methylation changes could be detected in western blot upon PRMT3 knockdown or overexpression. PRMT3 was shown to asymmetrically dimethylate H4R3 in vitro14, however, the mark is predominantly deposited by PRMT1, and therefore an exogenous assay with overexpressed PRMT3 was designed. Consistent with in vitro findings, overexpression of wild-type PRMT3 but not its catalytic mutant (E338Q) led to an increase in H4R3me2a levels (Figure 2A). HEK293T cells were used since they have low basal methylation of this mark (Figure 1C). The assay was further validated with PRMT3 selective inhibitor SGC7077, which inhibited PRMT3-dependent H4R3 asymmetric methylation (Figure 2B).

PRMT4 assay
PRMT4 asymmetrically dimethylates BAF155 at arginine 106415. Since the antibody detecting BAF165-R1064me2a is commercially available, the PRMT4 activity in cells can be monitored by western blot by detecting the changes in the R1064me2a mark levels. The loss of PRMT4 protein or inhibition of catalytic activity with the PRMT4 selective inhibitor, TP-06410, results in a decrease in BAF165-R1064me2a levels (Figure 3). A 2-day treatment is usually sufficient to remove most of the methylation signal.

PRMT5 assay
PRMT5 is responsible for the majority of protein arginine symmetric dimethylation. It has been previously reported that the various SMN complex proteins, including SmBB', are PRMT5 substrates16. PRMT5 activity can be monitored by looking at changes in global levels of symmetric arginine dimethylation or symmetric dimethylation of SmBB' proteins. Knockdown of PRMT5, but not PRMT1, 3, 4, 6, and 7 results in a decrease in global Rme2s levels (Figure 4A). In most cell lines, the treatment of cells with PRMT5 selective inhibitors LLY-28311 and GSK591 for 2-3 days suppressed most of the SmBB'Rme2s signal (Figure 4B). Most cells are sensitive to PRMT5 inhibition, which results in a decrease in cell proliferation and cell death with prolonged inhibitor exposure.

PRMT6 assay
It has been reported that PRMT6 is the main contributor to histone H3 arginine 2 asymmetric dimethylation (H3R2me2a) in cells17. In HEK293T cells, PRMT6 knockdown for 3 days was not sufficient to observe a significant decrease in H3R2me2a levels. However, overexpression of wild type PRMT6 but not its catalytic mutant (V86K/D88A) increases levels of H3R2me2a, as well as H3R8me2a and H4R3me2a (Figure 5A). There are several inhibitors that inhibit PRMT6 activity with different potency and selectivity: selective, allosteric PRMT6 inhibitor SGC687018, PRMT type I inhibitor MS0238, and PRMT4/6 inhibitor MS0499. All of these inhibited PRMT6 dependent H3R2 (Figure 5B), as well as H4R3 and H3R8 asymmetric dimethylation (data not shown).

PRMT7 assay
PRMT7 monomethylates arginine 469 in both constitutive and inducible forms of HSP70 (HSPA8 and HSPA1/6, respectively)12. Although there are no commercially available antibodies, which detect HSP70-R469me1 levels, the mark can be detected with pan monomethyl antibodies. The loss of PRMT7 protein or inhibition of catalytic activity with the PRMT7 selective inhibitor, SGC302712, results in decreased levels of HSP70-R469me1 (Figure 6A, B). SGC3027 is a cell-permeable prodrug, which in cells is converted by reductases to the PRMT7 selective inhibitor SGC8158, therefore cellular potency may differ between cell lines. Several cancer cell lines express inducible HSP70 isoforms at high levels, and methylation can be hard to detect due to an overlapping unspecific band of nuclear origin (Figure 6C). Therefore, for the PRMT7 cellular assay, cell lines that express mostly HSPA8 such as C2C12 are recommended, or since HSP70 localizes mainly in the cytoplasm, determine HSP70-R469me1 levels in the cytoplasmic fraction of preferred cell lines.

PRMT8 assay
PRMT8 is the only PRMT with a tissue-restricted expression pattern – largely expressed in the brain19. It shares 80% sequence similarity and has a similar substrate preference as PRMT119. It differs from PRMT1 mainly at the N-terminus, where myristoylation results in the association of PRMT8 with the plasma membrane20. It has been reported that PRMT8 together with PRMT1 methylates RNA-binding protein EWS21. Since PRMT8 activity is low in non-neuronal cell lines and EWS can also be methylated by PRMT1, an assay in which PMRT8 is co-overexpressed together with EWS in PRMT1 knockdown cells was developed. Since PRMT1 is an essential gene and its long-term loss results in cell death, an inducible system in which PRMT1 is knocked down for 3 days before use in the PRMT8 assay was utilized (Figure 7A). Co-expression of wild-type PRMT8, but not catalytically inactive mutant (E185Q), together with EWS resulted in increased levels of EWS asymmetric dimethylation (Figure 7B). Several asymmetric dimethylarginine antibodies were tested and the methylation was only detected with Asym25 antibody. The assay was further validated with a PRMT type I selective chemical probe, MS0238, which decreased PRMT8-dependent asymmetric dimethylation of exogenous EWS (Figure 7B). Although MS023 is very potent in inhibiting PRMT8 in in vitro assays, in cells high concentrations of MS023 are required to see methylation inhibition21.

PRMT9 assay
PRMT9 was shown to symmetrically dimethylate SAP145 at arginine 50822. Unfortunately, no commercially available antibodies can recognize the mark. For the PRMT9 assay, antibodies that were kindly gifted by Dr. Yanzhong Yang (Beckman Research Institute of City of Hope) were used. When overexpressed, wild type but not R508K mutant SAP145 is methylated by PRMT9 (Figure 8A). The assay was designed to monitor the levels of endogenous SAP145-R508me2s and was validated with Compound X, a prototype PRMT9 inhibitor (work in progress, not yet published), which potently inhibits PRMT9 in vitro with nanomolar potency. Compound X decreased SAP145-R508me2s levels in a dose-dependent manner (Figure 8B).

Figure 1
Figure 1. PRMT1 cellular assay. (A) PRMT1 knockdown results in a decrease of global asymmetric arginine dimethylation (Rme2a) and increased levels of symmetric arginine dimethylation (Rme2s) and monomethylation (Rme1). The PRMT1 knockdown efficiency is presented in panel B. (B) PRMT1 knockdown decreases asymmetric dimethylation of histone H4R3 (H4R3me2a). (C) The basal H4R3me2a levels differ across different cell lines. (D) Type I PRMT inhibitor MS023 decreases H4R3me2a levels in a dose-dependent manner. MCF7 cells were treated with MS023 for 2 days. (E) The graph represents the nonlinear fit of H4R3me2a signal intensities normalized to total histone H4. MS023 IC50 = 8.3 nM (n=1). Please click here to view a larger version of this figure.

Figure 2
Figure 2. PRMT3 cellular assay. (A) The overexpression of wild-type (WT) but not E338Q catalytic mutant of PRMT3 increases H4R3me2a levels in HEK293T cells. Cells were transfected with FLAG-tagged PRMT3 for 24 h. (B) PRMT3 selective inhibitor, SGC707, decreases ectopic PRMT3 dependent H4R3 asymmetric demethylation Please click here to view a larger version of this figure.

Figure 3
Figure 3. PRMT4 cellular assay. (A) PRMT4 knockdown results in a decrease of BAF155-R1064 asymmetric arginine dimethylation (HEK293T cells). (B) PRMT4 selective inhibitor, TP-064, decreases BAF155-R1064Rme2a levels. HEK293T cells were treated with compound for 2 days. Please click here to view a larger version of this figure.

Figure 4
Figure 4. PRMT5 cellular assay. (A) PRMT5 knockdown results in a decrease of global symmetric arginine dimethylation levels (MCF7 cells). (B) PRMT5 selective inhibitors GSK591 and LLY-283, decrease SmBB' symmetric arginine dimethylation (green), while total levels of SmBB' remain unchanged (red). MCF7 cells were treated with compounds for 2 days. Please click here to view a larger version of this figure.

Figure 5
Figure 5. PRMT6 cellular assay. (A) The overexpression of wild type (WT) but not V86K/D88A catalytic mutant PRMT6 increases H4R3me2a, H3R2me2a, and H3R8me2a levels in HEK293T cells. Cells were transfected with FLAG-tagged PRMT6 for 24 h. (B) PRMT6 selective inhibitor (SGC6870), PRMT type I inhibitor (MS023), and PRMT4/6 inhibitor (MS049) decrease PRMT6 dependent H3R2me2a levels. Please click here to view a larger version of this figure.

Figure 6
Figure 6. PRMT7 cellular assay. (A) PRMT7 knockout results in a decrease of HSP70-R469 monomethylation (HCT116 cells). (B) PRMT7 selective inhibitors, SGC3027, decreases HSP70-R469 monomethylation in C2C12 cells. Cells were treated with compound for 2 days. (C) Detection of HSP70-R469 methylation of inducible HSP70 (HSPA1/6) with pan monomethyl arginine antibodies (Rme1) can be difficult due to an overlapping unspecific band of nuclear origin. It is recommended to measure HSP70 methylation levels in the cytoplasmic fraction. Please click here to view a larger version of this figure.

Figure 7
Figure 7. PRMT8 cellular assay. (A) PRMT8 methylation of EWS can be detected when PRMT1 activity is inhibited by knockdown. HEK293T cells were transduced with an inducible PRMT1 knockdown vector. After 3 days of doxycycline treatment, PRMT1 levels were drastically reduced. (B) When PRMT1 is knocked down, exogenous EWS is asymmetrically dimethylated by overexpressed wild type PRMT8 but not catalytic mutant (E185Q) of PRMT8. The methylation is decreased by a high concentration of PRMT type I inhibitor (MS023). HEK293T PRMT1KD cells were co-transfected with FLAG-tagged PRMT8 wild type or catalytic mutant and GFP-tagged EWS and treated with MS023 for 20 h. Please click here to view a larger version of this figure.

Figure 8
Figure 8. PRMT9 cellular assay. (A) Wild type but not R508K mutant SAP145 is methylated by PRMT9. HEK293T cells were transfected with GFP-tagged SAP145 for 1 day. (B) The prototype PRMT9 inhibitor (Compound X) decreases PRMT9 dependent R508 symmetric dimethylation of SAP145 in a dose-dependent manner. HEK293T cells were treated with the compound for 2 days. Please click here to view a larger version of this figure.

PRMT Cells Density per ml
PRMT1 MCF7 1 x 105
PRMT3 HEK293T 2 x 105
PRMT4 HEK293T 1 x 105
PRMT5 MCF7 1 x 105
PRMT6 HEK293T 2 x 105
PRMT7 C2C12 1 x 105
PRMT8 HEK293T (PRMT1 KD)* 2 x 105
PRMT9 HEK293T 2 x 105
*treat cells with doxycycline (2 µg/mL) 3 days before plating for PRMT8 assay

Table 1. Cell types and densities recommended for PRMT assays.

PRMT  µg DNA/24-well Addgene # Additional notes
PRMT3 0.5 FLAG-PRMT3 164695
 or 0.5 FLAG-PRMT3 (E338Q) 164696
PRMT6 0.5 FLAG-PRMT6 164697
or 0.5 FLAG-PRMT6(V86K/D88A) 164698
PRMT8 0.05 EWS-GFP 164701
0.45 PRMT8-FLAG 164699
or 0.45 PRMT8(E185Q)-FLAG 164700
PRMT9 0.05 SAP145-GFP NA gift from Dr. Yanzhong Yang, Beckman Research Institute of City of Hope
or 0.05 SAP145-R508K-GFP
0.45 empty vector

Table 2. The DNA concentration recommended for transfection experiment.

PRMT Antibody Chemical probe (Cell activity IC50) Negative control
PRMT1 H4R3me2a (1:2000) MS023 -PRMT type I MS094
Rme1 (1:1000) (PRMT1, PRMT6, PRMT3, PRMT4 IC50 = 9, 56, 1000, 5000 nM, respectively)
Rme2s (1:2000)
Rme2a (1:2000)
Rme2a (ASYM24, 1:3000)
Rme2a (ASYM25, 1:2000)
H4 (1:2000)
B-actin (1:500 )
PRMT3 H4 (1:2000) SGC707 (IC50 = 91 nM) XY-1
H4R3me2a (1:2000)
FLAG (1:5000)
PRMT4 BAF155 (1:200) TP-064 (IC50 = 43 nM) TP064N
BAF155-R1064me2a (1:3000) SKI-73 (IC50 = 540 nM)* SKI-73N*
PRMT5 anti-SmBB’ (1:100) LLY-283 (IC50 = 30 nM) LLY-284
Rme2s (#13222, 1:2000) GSK591 (IC50 = 56 nM) SGC2096
PRMT6 H4R3me2a (1:2000) SGC6870 (IC50 = 0.9 µM) SGC6870N
H4 (1:2000) MS023 -PRMT type I MS094
H3R2me2a ( 1:2000) (PRMT1, PRMT6, PRMT3, PRMT4 IC50 = 9, 56, 1000, 5000 nM, respectively)
H3R8me2a (1:2000) MS049 (PRMT 4, 6 IC50 = 970,  1400  nM, respectively) MS049N
H3 ( 1:5000)
FLAG ( 1:5000)
PRMT7 Rme1 (1:1000) SGC3027 (IC50 = 1300 nM) * SGC3027N*
Hsp/Hsc70 (1:2000)*
PRMT8 GFP (1:3000) MS023  (50 µM) MS094
Rme2a (ASYM25,1:2000)
FLAG (1:5000)
PRMT9 SAP145 (1:1000)
SAP145-R508me2s -kind gift from Dr. Yanzhong Yang, Beckman Research Institute of City of Hope (1:1000) (PIMID: 25737013)
Secondary antibodies goat-anti-rabbit IgG-IR800 (1:5000)
donkey anti-mouse IgG-IR680 (1:5000)
*- antibody recognizes HSPA8, HSPA1 and HSPA6 (tested with overexpressed GFP-tagged proteins), *prodrug – the IC50 may differ between various cell lines

Table 3. Recommended antibodies and PRMT chemical probe/negative control tool compounds.

PRMT Biomarker Assay readout Assay validation Recommended cell line Ref.
PRMT1 H4R3me2a, Rme1, Rme2s, Rme2a H4R3me2a levels normalized to total H4 global Rme1, Rme2a or Rme2s levels normalized to B-actin. Knockdown of PRMT1 decreased basal H4R3me2a and global Rme2a levels and increased global Rme1 and Rme2s levels in cells (Fig.1A, B). PRMT Type I chemical probe MS023 decreased the levels of H4R3me2a in a dose-dependent manner (Fig. 1D).  Cells differ in basal H4R3me2a levels (Fig. 1C). MCF7 cells have high basal H4R3me2a levels which makes it preferable for assays monitoring the decrease in PRMT1 activity.  8
PRMT3 H4R3me2a H4R3me2a methylation levels caused by exogenous FLAG-tagged PRMT3 WT or catalytic E338Q mutant (background) normalized to total histone H4 Overexpression of wild type PRMT3 but not its catalytic mutant (E338Q) increased H4R3me2a (Fig. 2A). PRMT3 selective inhibitor SGC707 decreased PRMT3 dependent increase in H4R3me2a levels (Fig. 2B) HEK293T cells have low basal H4R3me2a levels (Fig 1C), which is preferable for monitoring exogenous PRMT3 activity 7
PRMT4 BAF155-R1064me2a BAF155-R1064me2a levels normalized to total BAF155 PRMT4 knockdown decreased asymmetric dimethylation of BAF155 (Fig. 3A). 2 day treatment with PRMT4 selective chemical probe (TP-064) decreased asymmetric dimethylation of BAF155 (Fig. 3B).  Any cell line 10
PRMT5 SmBB’-Rme2s SmBB’-Rme2s levels detected with pan Rme2s antibodies (CST) normalized to total SmBB’ Knockdown of PRMT5 resulted in decreased SmBB’ symmetric dimethylation levels (Fig. 4A). 2 day treatment with PRMT5 selective chemical probes, GSK591 and LLY285, decreased SmBB’-Rme2s levels (Fig. 4B).  Any cell line 11
PRMT6 H4R3me2a
H3R2me2a
H3R8me2a
H4R3me2a, H3R2me2a or H3R8me2a methylation levels are increased by exogenous FLAG-tagged PRMT6 WT but not catalytic V86K,D88A mutant (background) normalized to total histone H4 or H3, respectively Overexpression of wild type PRMT6 but not its catalytic mutant (V86K,D88A) increased H3R2me2a, H3R8me2a and H4R3me2a levels (Fig. 5A). Allosteric PRMT6 inhibitor (SGC6870), PRMT type I inhibitor MS023 , PRMT4/6 inhibitor MS049 decreased PRMT6 dependent increase in H3R2me2a levels (Fig. 5B).  HEK293T cells have low basal H4R3me2a, H3R2me2a and H3R8me2a levels, which is preferable for monitoring exogenous PRMT6 activity 8,9
PRMT7 HSP70-R469me1 HSP70-Rme1 methylation levels normalized to total HSP70  PRMT7 knockout or knockdown reduced HSP70 monomethylation (Fig. 6A). 2 day treatment with PRMT7 selective chemical probe SGC3027 decreased PRMT7 dependent HSP70 monomethylation in a dose-dependent manner (Fig. 6B).  C2C12, HT180
Several cancer cell lines express an inducible form of HSP70 whose methylation signal overlaps with an unspecific protein of nuclear origin (Fig. 6C). In this case, we recommend analyzing HSP70 methylation levels in the cytoplasmic fraction.
12
PRMT8 EWS-Rme2a Exogenous GFP-tagged EWS methylation levels caused by exogenous FLAG-tagged PRMT8 WT or E185Q catalytic mutant (background), normalized to total GFP signal in PRMT1 KO cells.  Overexpression of the wild type PRMT8 but not catalytic E185Q mutant methylated ectopic EWS only in PRMT1 KD cells (Fig. 7A). PRMT type I chemical probe MS023 inhibited asymmetric dimethylation of exogenous EWS by PRMT8 (Fig. 8B).  HEK293T PRMT1 KD (inducible).
PRMT1 knockdown results in cell death therefore we recommend using an inducible system.
8
PRMT9 SAP145-R508me2s PRMT9 dependent SAP145 symmetric dimethylation at R508 normalized to SAP145 The loss PRMT9 but not PRMT5 lead to decreased symmetric dimethylation of SAP145. GFP-tagged SAP145 WT but not SAP145mut (R508K) was methylated by PRMT9 (Fig. 8A). 2-day treatment with Copound X, the prototype PRMT9 inhibitor,  decreased SAP145-R508me2s levels in a dose-dependent manner Fig 8B). Any cell line 21

Table 4. PRMT assays summary.

Discussion

Here, the detailed cellular assay protocols for members of the PRMT family are described that use fluorescent western blotting methods. Unique substrates for which the changes in arginine methylation can be easily detected upon individual PRMT loss or catalytic inhibition and cannot be compensated by other family members were selected. Some proteins are methylated by multiple PRMTs21,23, suggesting an overlap in substrate specificity where some PRMTs contribute only a small amount of cellular mark in a given protein substrate24,25,26,27, for example, both PRMT8 and PRMT1 contribute to methylation of EWS. Therefore, each assay required thorough validation of substrates and antibodies with knockdown and/or overexpression experiments and further validation with well-characterized selective inhibitors. PRMT specific substrates were identified for which methylation mark changes could be detected within 2-3 days post-PRMT loss/inhibition to avoid compounding effects of reduced cell viability and proliferation that may indirectly affect the methyl-arginine mark levels. Although it was possible to find unique substrates for PRMT1, 4, 5, 7, and 9; for PRMT3, 6, and 8 the gain of function approach had to be employed. Several arginine methyl-specific antibodies were tested for various cellular targets, but none were able to detect significant changes within 3 days of PRMT3 and PRMT6 knockdown; therefore, biomarker assays were developed using ectopically expressed enzymes together with catalytically inactive mutants, which served as a control for the baseline substrate methylation. PRMT8 is a close PRMT1 homolog and shares similar substrate preferences. As a PRMT8 selective biomarker could not be identified, an assay in PRMT1 knockdown cells was developed, where PRMT8 was co-expressed together with EWS. PRMT1 is also a major enzyme responsible for H4R3 asymmetric methylation, therefore, to use H4R3me2a as a biomarker for PRMT3 and PRMT6 cellular assays, cells with low basal H4R3me2a levels were chosen as well as catalytically inactive mutants were used as a background control. Although endogenous assays are preferred, exogenous assays prove invaluable for testing the cellular potency of several selective PRMT inhibitors7,8,9. With growing knowledge of PRMT biology, we expect to improve the assays by finding more specific biomarker proteins for PRMT3, PRMT6, and PRMT8.

The use of validated antibodies and appropriate controls are critical for the PRMT assay performance. All antibodies recommended here have been thoroughly validated by knockdown and overexpression experiments, however, batch-to-batch differences, especially in the case of polyclonal antibodies, may still influence their performance. Therefore, it is crucial to use genetic methods and chemical probes together with their closely related negative controls to confirm assay reliability. Additionally, for PRMT assays that require protein overexpression, it is crucial to use catalytically inactive mutants along with wild-type protein to determine the basal methylation levels.

This collection of quantitative assays for profiling the activity of PRMTs in cells can be broadly useful for the scientific community since it can be rapidly and easily implemented with minimal equipment and limited technical expertise, involving only basic cell culturing and fluorescent western blotting techniques. The recommended antibodies and chemical probes for PRMTs can also be utilized for activity-based protein profiling (ABPP) assays to establish the suitability of a given ABPP probe, monitor target engagement, and assess off-target effects by using the competitive ABPP format. The assay development approaches discussed here can also be extrapolated for other enzyme families such as protein lysine-methyltransferases and acetyltransferases.

Açıklamalar

The authors have nothing to disclose.

Acknowledgements

The Structural Genomics Consortium is a registered charity (no: 1097737) that receives funds from AbbVie, Bayer AG, Boehringer Ingelheim, Genentech, Genome Canada through Ontario Genomics Institute [OGI-196], the EU and EFPIA through the Innovative Medicines Initiative 2 Joint Undertaking [EUbOPEN grant 875510], Janssen, Merck KGaA (aka EMD in Canada and US), Pfizer, Takeda and the Wellcome Trust [106169/ZZ14/Z].

Materials

10 cm TC dishes Greiner bio-one 664160
24-well TC plates Greiner bio-one 662160
4–12% Bis-Tris Protein Gels ThermoFisher Scientiffic NP0323BOX, NP0322BOX,NP0321BOX
Amersham Hybond P PVDF membrane Millipore-Sigma 10600021
anti-Asym 24 Millipore-Sigma 07-414
anti-Asym 25 Millipore-Sigma 09-814
anti-B-actin Santa Cruz Biotechnologies sc-47778
anti-BAF155 Santa Cruz Biotechnologies sc-32763
anti-BAF155-R1064me2a Millipore-Sigma ABE1339
anti-FLAG (#, 1:5000) Millipore-Sigma F4799
anti-GFP Clontech 632381
anti-H3 Abcam ab10799
anti-H3R2me2a Millipore-Sigma 04-848
anti-H3R8me2a Rockland 600-401-I67
anti-H4 Abcam ab174628
anti-H4R3me2a Active Motif 39705
anti-Hsp/Hsc70 Enzo ADI-SPA-820
anti-PRMT1 Millipore-Sigma 07-404
anti-PRMT3 Abcam ab191562
anti-PRMT4 Bethyl #A300-421A
anti-PRMT5 Abcam ab109451
anti-PRMT6 Abcam ab47244
anti-PRMT7 Abcam ab179822
anti-Rme1 CST 8015
anti-Rme2a CST 13522
anti-Rme2s CST 13222
anti-Rme2s (ASYM25), Millipore, , 1:2000) 09-814
anti-SAP145 (Abcam, #, 1:1000) Abcam ab56800
anti-SAP145-R508me2s kind gift from Dr. Yanzhong Yang, Beckman Research Institute of City of Hope
anti-SmBB’ Santa Cruz Biotechnologies sc-130670
benzonase PRODUCED IN-HOUSE
BSA Millipore-Sigma A7906
C2C12 gift from Dr. Stephane Richard, McGill University
cOmplete, EDTA-free Protease Inhibitor Cocktail Millipore-Sigma 11873580001
DMEM Wisent 319-005-CL
DMSO Bioshop DMS666.100
donkey anti-mouse IgG-IR680 Licor 926-68072
doxycycline Millipore-Sigma D9891
EDTA Bioshop EDT111.500
FBS Wisent 80150
glycine Bioshop GLN002.5
goat-anti-rabbit IgG-IR800 Licor 926-32211
HEK293T gift from Dr. Sam Benchimol, York University
Image Studio Software ver 5.2 Licor
Loading buffer: NuPAGE LDS Sample Buffer (4x) ThermoFisher Scientiffic NP0007
MCF7 ATCC® HTB-22™
NaCl Bioshop SOD001.1
NuPAGE MOPS SDS Running Buffer ThermoFisher Scientiffic NP0001
Odyssey Blocking Buffer (dilute 4 x with PBST) Licor 927-40000 Intercept (PBS) Blocking Buffer can also be used # 927-70001
Odyssey CLX Imaging System Licor model number 9140
PBS (tissue culture) Wisent 311-010-CL
PBS (western blot) Bioshop PBS405.4
penstrep Wisent 450-201-EL
Pierce™ BCA Protein Assay Kit ThermoFisher Scientiffic 23225
SDS Bioshop SDS001.1
skim milk powder Bioshop SKI400.500
TC20 automated cell counter Biorad 1450102
Tripsin-EDTA (0.25%) Wisent 325-043-EL
Tris Bioshop TRS003.5
Tritton X-100 Bioshop TRX506
trypan blue GIBCO 15250-061
Tween-20 Bioshop TWN510.500

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Szewczyk, M. M., Vu, V., Barsyte-Lovejoy, D. Quantitative Methods to Study Protein Arginine Methyltransferase 1-9 Activity in Cells. J. Vis. Exp. (174), e62418, doi:10.3791/62418 (2021).

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