p50–NF-κB Complexes Partially Compensate for the Absence of RelB: Severely Increased Pathology in p50−/−relB−/−Double-knockout Mice

RelB-deficient mice (relB−/−) have a complex phenotype including multiorgan inflammation and hematopoietic abnormalities. To examine whether other NF-κB/Rel family members are required for the development of this phenotype or have a compensatory role, we have initiated a program to generate double-mutant mice that are deficient in more than one family member. Here we report the phenotypic changes in relB−/− mice that also lack the p50 subunit of NFκB (p50−/−). The inflammatory phenotype of p50−/−relB−/− double-mutant mice was markedly increased in both severity and extent of organ involvement, leading to premature death within three to four weeks after birth. Double-knockout mice also had strongly increased myeloid hyperplasia and thymic atrophy. Moreover, B cell development was impaired and, in contrast to relB−/− single knockouts, B cells were absent from inflammatory infiltrates. Both p50−/− and heterozygous relB−/+ animals are disease-free. In the absence of the p50, however, relB−/+ mice (p50−/−relB−/+) had a mild inflammatory phenotype and moderate myeloid hyperplasia. Neither elevated mRNA levels of other family members, nor increased κB-binding activities of NF-κB/Rel complexes could be detected in single- or double-mutant mice compared to control animals. These results indicate that the lack of RelB is, in part, compensated by other p50-containing complexes and that the “classical” p50-RelA–NF-κB activity is not required for the development of the inflammatory phenotype

VEGFR-3 is expressed on megakaryocyte precursors in the murine bone marrow and plays a regulatory role in megakaryopoiesis

Introduction VEGFR-3 is a member of the VEGFR receptor tyrosine kinase family. It is expressed on lymphatic endothelial cells (LECs) and plays a central role in the regulation of lymphangiogenesis. 1 On binding to its ligands, VEGF-C and VEGF-D, VEGFR-3 is activated and orchestrates the outgrowth of lymphatic vessels. During murine hematopoiesis, Sca-1 ϩ hematopoietic stem cells give rise to the precursors of all hematopoietic lineages. 10 Megakaryocytes develop from CD34 ϩ progenitors. Methods Cell culture HEL cells were obtained from DSMZ and cultivated in RPMI (Gibco-BRL) containing 10% FCS and 1% penicillin-streptomycin. Differentiation was induced with 10nM tetradecanoyl phorbol acetate (TPA; Sigma-Aldrich). Primary human microvascular LECs (Cambrex) from the dermis (HMVECdLyNeo) were cultivated in EGM-2MV (Lonza) and 5% FCS supplemented with growth factors provided by the manufacturer. Bovine lymphatic endothelial cells were cultivated in DMEM (Gibco-BRL) containing 20% FCS and 1% penicillin-streptomycin on gelatin-coated plastic. HEK-293 cells were cultivated in DMEM supplemented with 10% FCS and 1% penicillin-streptomycin. Western blot analysis Cell lysates were analyzed using standard Western blotting techniques. The membranes were probed with Abs specific for VEGFR-3 (R&D Systems), CD31 (Santa Cruz Biotechnology), CD34 (Abcam), CD42a (Santa Cruz Biotechnology), CD61 (R&D Systems), CD144 (Santa Cruz Biotechnology), or GpA (International Blood Group Reference Laboratory). Probing with hypoxanthine phosphoribosyltransferase (HPRT) Abs (Santa Cruz Biotechnology) served as a loading control. PCR analysis RNA was prepared using peqGOLD RNAPure (PeqLab). Synthesis of cDNA using Superscript II (Invitrogen) was performed according to the manufacturer's recommendations. For PCR, cDNAs were amplified as follows: 94°C for 30 seconds, 60°C for 30 seconds, and 72°C for 90 seconds (VEGFR-2, Prox1, LYVE-1, Podoplanin, HPRT, Fli-1, Fog-2, Gata-2, and Elf-1) or 94°C for 30 seconds, 54°C for 30 seconds, and 72°C for 90 seconds (VEGFR-3). Details of the primers used are in supplemental Methods (available on the Blood Web site; see the Supplemental Materials link at the top of the online article). Tubule formation on collagen gels Collagen type 1 was prepared from rat tails. Tendons were isolated, dissolved in acetic acid, then filtered, lyophilized, and redissolved in 0.1% acetic acid at 4 mg/mL. Cells were seeded on collagen gels (2 mg/mL) and cultured in the presence of 30 ng/mL of VEGF 165 (Promokine) for 8 days. Tubule formation was analyzed as described previously. 22 Immunohistochemistry For the immunohistochemical analysis of VEGFR-3 expression in the BM, cryosections of decalcified murine femurs embedded in tissue-freezing medium (Leica) were fixed in acetone and stained with VEGFR-3 Abs (eBiosciences). The stained sections were then analysed at room temperature using an Axioskop (Zeiss) equipped with a PlanNeoflur 20ϫ/0.50 and an Axiocam (Zeiss) and Axiovision software (Ziess). MACS BM cells isolated from femurs and tibias of C57BL/6 mice were treated with Fc-block (BD Biosciences) and then incubated with Abs against VEGFR-3 (R&D Systems), Sca-1, CD41, or CD38 (BD Biosciences), followed by specific secondary MACS Abs (Miltenyi-Biotec) according to the manufacturerЈs recommendations. Cell populations were then either enriched or depleted for the labeled epitope using LS or LD columns (Miltenyi-Biotec), respectively. The purity of the sorted populations was controlled by flow cytometry. CD42 FACS BM was isolated from femurs and tibias of C57BL/6 mice and stained with Abs specific for VEGFR-3 (R&D Systems) and/or CD42a (Emfret) and analyzed by FACS. Lethal irradiation and BM transplantation C57BL/6 mice were irradiated with lethal doses (9 Gy) from a ␥ source. After 24 hours, the mice were all transplanted in parallel by IV injection with either complete BM, BM depleted of VEGFR-3 ϩ cells, or BM mock depleted with an appropriate isotype control using MACS. EDTA blood samples were taken from all animals on days 0, Isolation and culture of primary murine BM cells BM was isolated from femurs and tibias of C57BL6 mice. After lysis of RBCs with ammonium-chloride-potassium buffer, the cells were transferred to IMDM (Gibco-BRL) supplemented with 1% penicillin/streptomycin, 10% HEK-293 cell-conditioned DMEM, Nutridoma SP (Roche), L-glutamine, and 100 pg/mL of recombinant murine TPO (RDI Diagnostics). Depending on the experiment, the cells were cultured with either 100 g/mL of mF4-31C1 VEGFR-3-blocking Abs (kindly provided by ImClone Systems), 100 g/mL of rat IgG isotype control, or 400 ng/mL of VEGF-C-Cys, a mutant form of VEGF-C that activates VEGFR-3 but not VEGFR-2. Long-term injections C57BL/6 mice were injected daily with 25 g of VEGF-C-Cys for 3 weeks. Blood was taken on days 0, 3, 7, 10, 14, 17, and 21. In the blocking Ab experiments, mice were injected with 600 g/animal/injection of mF4-31C1 VEGFR-3-blocking Ab, isotype control Ig, or PBS on a MondayWednesday-Friday schedule for 6 weeks. Blood was taken on days 0, Recovery kinetics after sublethal irradiation Experimental C57BL/6 mice were sublethally irradiated (4.5 Gy) in a ␥ source. They were then either injected daily with VEGF-C-Cys (25 g/animal/injection) or PBS or were intraperitoneally injected with 600 g/animal/injection of mF4-31C1 VEGFR-3-blocking Abs, isotype control Ig, or PBS every other day. Blood was taken on days 0, 7, 11, 14, 18, and 21 after irradiation and analyzed. In each experiment, all animals were treated at the same time and on the same day and all animals were bled at each time point. BM was isolated from femurs and tibias 20 days after irradiation, and the number and ploidy of CD41 ϩ cells in the BM was assessed. Significance was tested using 2-tailed unpaired t tests assuming equal variance. TPO administration C57BL/6 mice were administered with 5 g of recombinant murine TPO (RDI), followed by daily injections of either 25 g of VEGF-C-Cys or PBS. One group received only PBS throughout. Blood was taken and analyzed 0, 3, 5, 7, and 10 days after TPO administration. All animals were treated at the same time and on the same day and all animals were bled at each time point. After 10 days, the animals were killed and the number and ploidy of CD41 ϩ 1900 THIELE et al BLOOD, 30 AUGUST 2012 ⅐ VOLUME 120, NUMBER 9 For personal use only. on October 6, 2016. by guest www.bloodjournal.org From cells in the BM was assessed. Significance was tested using 2-tailed unpaired t tests assuming equal variance. 5-FU treatment C57BL/6 mice were intraperitoneally injected with a single dose of 5-FU (Sigma-Aldrich) at 150 mg/kg. Control mice remained untreated. The 5-FU-treated mice then received daily injections of either 25 g of VEGF-C-Cys or PBS throughout the experiment. Blood was taken and analyzed 0, All animal experiments were approved by the local regulatory authorities and were performed according to German legal requirements. Results Expression of VEGFR-3 and other lymphatic endothelial markers is up-regulated on phorbol diester-induced megakaryocytic differentiation of HEL cells VEGFR-3 is widely used as a marker for lymphatic endothelium. Originally, however, the receptor was cloned from the HEL cell line. 7 This cell line can be induced to differentiate into the erythrocyte lineage by EPO treatment 23 and into the megakaryocyte lineage in response to TPA. Consistent with the notion that HEL cells differentiate into the megakaryocyte lineage on TPA treatment, we detected strong up-regulation of several markers and transcription factors associated with megakaryocytic differentiation A survey of the literature revealed that virtually all markers described to date as being expressed on megakaryocytes can also be expressed on endothelial cells (supplemental These observations raised the question of whether HEL cells really undergo megakaryocytic differentiation after TPA treatment or if they adopt an endothelial phenotype with LEC characteristics. To address this point, we investigated whether TPA-treated HEL cells are capable of forming capillaries, reasoning that if the cells differentiated into endothelial cells, this should be the case. However, in contrast to control bovine LECs, TPA-treated HEL cells could not be induced to form capillaries VEGFR-3 IN MEGAKARYOPOIESIS 1901 BLOOD, 30 AUGUST 2012 ⅐ VOLUME 120, NUMBER 9 For personal use only. on October 6, 2016. by guest www.bloodjournal.org From VEGFR-3 is expressed on megakaryocytic progenitors through to the promegakaryoblast stage in the BM The up-regulation of VEGFR-3 during HEL cell megakaryocytic differentiation suggested to us that VEGFR-3 may play a role in megakaryopoiesis. Because of the limited megakaryocytic differentiation capacity of HEL cells and their cancerous nature, we explored this possibility further using murine BM. First we characterized VEGFR-3 expression in the BM. FACS staining revealed that approximately 2% of murine BM cells were VEGFR-3 ϩ ( To define further the stages of megakaryopoiesis during which VEGFR-3 is expressed, costainings with the stem cell marker Sca-1 and with CD38, CD41, and VEGFR-3 were performed. Expression of Sca-1 is lost during myeloid differentiation. 25 CD38 expression, in turn, is increased early in megakaryopoiesis from the BFU-MK stage on. These observations suggested to us that VEGFR-3 might be expressed on hematopoietic stem cells through to the promegakaryoblast stage. However, Sca1 is not just expressed on hematopoietic stem cells, but also on the immediate progenitors arising from the stem cells. These data are consistent with the notion that VEGFR-3 is not expressed on hematopoietic stem cells, but rather on megakaryocyte precursors through to the premegakaryoblast stage, and that VEGFR-3 expression is lost as megakaryocytes further mature. This notion is further substantiated by the observation that VEGFR-3 ϩ BM cells coexpressed CD42, a marker for megakaryocytes that is not expressed on hematopoietic precursor cells (supplemental Manipulation of VEGFR-3 influences megakaryopoiesis in vitro To examine the role that VEGFR-3 plays during megakaryopoiesis, we cultivated primary murine BM cells with physiologic concentrations of TPO to maintain the megakaryocyte precursors. The cells were grown for 3 days in the presence or absence of VEGF-C-Cys, a mutant form of VEGF-C that specifically activates VEGFR-3 but not VEGFR-2, 20 because VEGFR-2 is also present on megakaryocytic cells. Our data suggest that the specific activation of VEGFR-3 during megakaryopoiesis impairs the transition to polyploid stages, whereas blocking the receptor promotes differentiation and endoreplication. For personal use only. on October 6, 2016. by guest www.bloodjournal.org From Neither activation nor blocking of VEGFR-3 influences steady-state megakaryopoiesis or thrombopoiesis in vivo To study the potential effects of VEGFR-3 manipulation on megakaryopoiesis and thrombopoiesis in vivo, we first injected VEGF-C-Cys to activate VEGFR-3, or PBS as a control, into mice on a daily basis for 3 weeks. Thrombocyte concentrations in the blood were monitored regularly. After 3 weeks of treatment, the mice were killed. BM cells were isolated and stained for CD41 and DNA content to evaluate the number and ploidy of the CD41 ϩ population. We observed a significant decrease in apoptotic CD41 ϩ BM cells in the VEGF-C-Cys-treated group (P Ͻ .01), a trend toward reduced polyploidy, and an increase in 2n CD41 ϩ cells, which were consistent with our in vitro observations. VEGF-C-Cys had no effect on platelet counts or the number of CD41 ϩ cells in the BM (supplemental To determine the effect of inhibiting VEGFR-3 activation on megakaryopoiesis and thrombopoiesis in vivo, mice were injected daily with VEGFR-3-blocking Abs or an appropriate isotype control for 6 weeks. Platelet counts were monitored regularly and the numbers and ploidy distribution of CD41 ϩ BM cells were analyzed at the end of the experiment. Under these conditions, no effects on the measured parameters were observed (supplemental Activation of VEGFR-3 increases platelet counts in TPO-stimulated animals, modulates 5-FU-induced thrombocytopenia and thrombocytosis, and influences ploidy distribution and numbers of CD41 ؉ BM cells after sublethal irradiation Thrombocyte homeostasis is tightly controlled in mammals, and alternative mechanisms exist that can compensate for perturbation . FACS analysis showed that 1.85% Ϯ 0.31% SEM (n ϭ 9) of the murine BM cells expressed VEGFR-3. Dot plots of 1 representative experiment are depicted. Density plots were used to define a region in which 95% (the 2 outer contours) of the negative control events were excluded. The region was then applied to a plot displaying the stained sample. The number of positive events in both the negative control and the actual sample was then assessed. The percentage of true positive cells was calculated by subtraction of the number of events in the negative control within the defined region from the number of events found in the same region for the actual sample. Identical numbers of events were acquired. (B) VEGFR-3 is expressed on isolated mononuclear cells in the murine BM. Sections of murine femurs were stained with VEGFR-3-specific Abs (left panel, VEGFR-3; right panel, control). MK indicates megakaryocyte. Scale bars indicate 100 m. (C) Ploidy of VEGFR-3 ϩ cells in the murine BM. VEGFR-3 ϩ BM cells were enriched by MACS and then analyzed in FACS. As a control, cells were treated with an appropriate isotype control. Clumping cells mimicking polyploidy were excluded from the analysis by appropriate gating strategies. The resulting histogram plot shows the DNA content of VEGFR-3 ϩ cells. Dot plots of the DNA content of the cells were used for the quantification of VEGFR-3 ϩ and isotype-treated cells within different ploidy classes or cell cycle stages, respectively (a detailed scheme of the gating strategy is provided in supplementa

RelB-Dependent Stromal Cells Promote T-Cell Leukemogenesis

BACKGROUND: The Rel/NF-kappaB transcription factors are often activated in solid or hematological malignancies. In most cases, NF-kappaB activation is found in malignant cells and results from activation of the canonical NF-kappaB pathway, leading to RelA and/or c-Rel activation. Recently, NF-kappaB activity in inflammatory cells infiltrating solid tumors has been shown to contribute to solid tumor initiation and progression. Noncanonical NF-kappaB activation, which leads to RelB activation, has also been reported in breast carcinoma, prostate cancer, and lymphoid leukemia. METHODOLOGY/PRINCIPAL FINDINGS: Here we report a novel role for RelB in stromal cells that promote T-cell leukemogenesis. RelB deficiency delayed leukemia onset in the TEL-JAK2 transgenic mouse model of human T acute lymphoblastic leukemia. Bone marrow chimeric mouse experiments showed that RelB is not required in the hematopoietic compartment. In contrast, RelB plays a role in radio-resistant stromal cells to accelerate leukemia onset and increase disease severity. CONCLUSIONS/SIGNIFICANCE: The present results are the first to uncover a role for RelB in the crosstalk between non-hematopoietic stromal cells and leukemic cells. Thus, besides its previously reported role intrinsic to specific cancer cells, the noncanonical NF-kappaB pathway may also play a pro-oncogenic role in cancer microenvironmental cells

Pigment epithelium-derived factor protects retinal ganglion cells

BACKGROUND: Retinal ganglion cells (RGCs) are responsible for the transmission of visual signals to the brain. Progressive death of RGCs occurs in glaucoma and several other retinal diseases, which can lead to visual impairment and blindness. Pigment epithelium-derived factor (PEDF) is a potent antiangiogenic, neurotrophic and neuroprotective protein that can protect neurons from a variety of pathologic insults. We tested the effects of PEDF on the survival of cultured adult rat RGCs in the presence of glaucoma-like insults, including cytotoxicity induced by glutamate or withdrawal of trophic factors. RESULTS: Cultured adult rat RGCs exposed to glutamate for 3 days showed signs of cytotoxicity and death. The toxic effect of glutamate was concentration-dependent (EC(50 )= 31 μM). In the presence of 100 μM glutamate, RGC number decreased to 55 ± 4% of control (mean ± SEM, n = 76; P < 0.001). The glutamate effect was completely eliminated by MK801, an NMDA receptor antagonist. Trophic factor withdrawal also caused a similar loss of RGCs (54 ± 4%, n = 60, P < 0.001). PEDF protected against both insults with EC(50 )values of 13.6 ng/mL (glutamate) and 3.4 ng/mL (trophic factor withdrawal), respectively. At 100 ng/mL, PEDF completely protected the cells from both insults. Inhibitors of the nuclear factor κB (NFκB) and extracellular signal-regulated kinases 1/2 (ERK1/2) significantly reduced the protective effects of PEDF. CONCLUSION: We demonstrated that PEDF potently and efficaciously protected adult rat RGCs from glutamate- and trophic factor withdrawal-mediated cytotoxicity, via the activation of the NFκB and ERK1/2 pathways. The neuroprotective effect of PEDF represents a novel approach for potential treatment of retinopathies, such as glaucoma

RelB is required for Peyer’s patch development: differential regulation of p52–RelB by lymphotoxin and TNF

Targeted disruption of the Rel/NF-κB family members NF-κB2, encoding p100/p52, and RelB in mice results in anatomical defects of secondary lymphoid tissues. Here, we report that development of Peyer’s patch (PP)-organizing centers is impaired in both NF-κB2- and RelB-deficient animals. IL-7-induced expression of lymphotoxin (LT) in intestinal cells, a crucial step in PP development, is not impaired in RelB-deficient embryos. LTβ receptor (LTβR)-deficient mice also lack PPs, and we demonstrate that LTβR signaling induces p52–RelB and classical p50–RelA heterodimers, while tumor necrosis factor (TNF) activates only RelA. LTβR-induced binding of p52–RelB requires the degradation of the inhibitory p52 precursor, p100, which is mediated by the NF-κB-inducing kinase (NIK) and the IκB kinase (IKK) complex subunit IKKα, but not IKKβ or IKKγ. Activation of RelA requires all three IKK subunits, but is independent of NIK. Finally, we show that TNF increases p100 levels, resulting in the specific inhibition of RelB DNA binding via the C-terminus of p100. Our data indicate an important role of p52–RelB heterodimers in lymphoid organ development downstream of LTβR, NIK and IKKα

p100 Deficiency Is Insufficient for Full Activation of the Alternative NF-κB Pathway: TNF Cooperates with p52-RelB in Target Gene Transcription

<div><h3>Background</h3><p>Constitutive activation of the alternative NF-κB pathway leads to marginal zone B cell expansion and disorganized spleen microarchitecture. Furthermore, uncontrolled alternative NF-κB signaling may result in the development and progression of cancer. Here, we focused on the question how does the constitutive alternative NF-κB signaling exert its effects in these malignant processes.</p> <h3>Methodology/Principal Findings</h3><p>To explore the consequences of unrestricted alternative NF-κB activation on genome-wide transcription, we compared gene expression profiles of wild-type and NF-κB2/p100-deficient (<em>p100^−/−</em>) primary mouse embryonic fibroblasts (MEFs) and spleens. Microarray experiments revealed only 73 differentially regulated genes in <em>p100^−/−</em> vs. wild-type MEFs. Chromatin immunoprecipitation (ChIP) assays showed in <em>p100^−/−</em> MEFs direct binding of p52 and RelB to the promoter of the <em>Enpp2</em> gene encoding ENPP2/Autotaxin, a protein with an important role in lymphocyte homing and cell migration. Gene ontology analysis revealed upregulation of genes with anti-apoptotic/proliferative activity (<em>Enpp2/Atx</em>, <em>Serpina3g</em>, <em>Traf1</em>, <em>Rrad</em>), chemotactic/locomotory activity (<em>Enpp2/Atx</em>, <em>Ccl8</em>), and lymphocyte homing activity (<em>Enpp2/Atx</em>, <em>Cd34</em>). Most importantly, biochemical and gene expression analyses of MEFs and spleen, respectively, indicated a marked crosstalk between classical and alternative NF-κB pathways.</p> <h3>Conclusions/Significance</h3><p>Our results show that p100 deficiency alone was insufficient for full induction of genes regulated by the alternative NF-κB pathway. Moreover, alternative NF-κB signaling strongly synergized both <em>in vitro</em> and <em>in vivo</em> with classical NF-κB activation, thereby extending the number of genes under the control of the p100 inhibitor of the alternative NF-κB signaling pathway.</p> </div

TNF synergizes with the lack of p100 in the induction of target gene expression.

<p>(A) Western blot of NF-κB family members in cytoplasmic and nuclear protein extracts (15 µg/sample) from unstimulated (0 h) and TNF-stimulated (6 and 24 h, 20 ng/ml recombinant murine TNF) wild-type and <i>p100^−/−</i> MEFs. As cytoplasmic and nuclear loading controls β-actin and RNA Pol II were assayed, respectively. (B) Changes in mRNA levels of selected genes were analyzed by qRT-PCR. From 16 analyzed genes, 12 responded synergistically to TNF and the lack of p100 whereas only four genes responded similarly to TNF treatment of wild-type (grey squares) and <i>p100^−/−</i> MEFs (black circles; see also <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0042741#pone.0042741.s004" target="_blank">Figure S4</a>). qRT-PCR data represent n = 3 independent TNF stimulation experiments and are expressed as mean values ± SD. Differences between wild-type and <i>p100^−/−</i> MEFs at each time-point were analyzed by Welch tests. <i>P</i>≤0.05 was considered significant (*).</p

Synergistic regulation of gene expression by the classical (TNF) and the alternative (<i>p100^−/−</i>) NF-κB pathway <i>in vivo</i>.

<p>Changes in mRNA levels of selected genes contributing to chemotaxis, lymphocyte homing, and cell adhesion were analyzed by qRT-PCR using RNA samples isolated from spleens of control (wild-type for the <i>Nfkb2</i> locus and heterozygous for the <i>TnfLta</i> locus), <i>p100^−/−</i> (deficient for the <i>p100/Nfkb2</i> and wild-type for the <i>TnfLta</i> locus), and <i>p100^−/− Tnf^−/−</i> (deficient for both the <i>p100/Nfkb2</i> and the <i>TnfLta</i> locus) animals. Four independent experiments were performed representing n = 6 control mice, n = 5 <i>p100^−/−</i> mice, and n = 4 <i>p100^−/− Tnf^−/−</i> mice. Data are presented as mean values ± SD. Significant differences (<i>P</i>≤0.05) were calculated by Student's <i>t</i>-test and are indicated (*). * <i>P</i>≤0.05; ** <i>P</i>≤0.01; n.s. = not significant.</p

Gene expression analysis of wild-type and <i>p100^−/−</i> spleens.

<p>(A) Changes in mRNA levels of selected genes were analyzed by qRT-PCR using RNA samples isolated from spleens of four wild-type and four <i>p100^−/−</i> animals. Data are expressed as mean values ± SD. Differences were analyzed by Welch tests. <i>P</i>≤0.05 was considered significant. All genes shown were significantly differentially regulated in wild-type compared to mutant mice. (B) Western blot analysis of total protein extracts from wild-type and <i>p100^−/−</i> spleens (30 µg/sample; protein extracts from three independent spleens are shown for each genotype) for the presence of p100/p52, ENPP2/ATX, and TRAF1. p52 wild-type protein and p52 protein resulting from the knock-in of the stop codon migrated with different speed due to a few amino acids difference in length. The asterisk indicates an unspecific signal. The membrane was probed for β-actin as a loading control.</p