pgl4 Luciferase Reporter Vectors

Technical Manual pgl4 Luciferase Reporter s INSTRUCTIONS FOR USE OF PRODUCTS E51, E61, E71, E81, E1, E6701, E6711, E6721, E6731, E6741, E6751, E6761, E6771, E6881, E681, E601, E611, E621, E631, E641, E651, E661, E671, E681, E61, E7501, E7511, E7521, E8411, E81, E8431, E8441, E8451, E8461, E81 AND E8481. PRINTED IN USA..

pgl4 Luciferase Reporter s I. Description...1 II. Product Components and Storage Conditions...3 III. All technical literature is available on the Internet at: www.promega.com/tbs/ Please visit the web site to verify that you are using the most current version of this Technical Manual. Please contact Promega Technical Services with questions regarding the use of these products. E-mail: techserv@promega.com General Considerations...4 A. The pgl4 Backbone...4 B. The pgl4 Reporter Genes...6 C. Distinguishing Features of the pgl4 s... D. Common Features of the pgl4 s... IV. pgl4 Sequences, Restriction Enzyme Tables and Maps...16 A. Sequences, Restriction Enzyme Tables and GenBank Numbers...16 B. pgl4 Maps...17 luc2 Maps...18 hrluc Maps...25 V. References...30 VI. Related Products...30 I. Description The pgl4 Luciferase Reporter s (a,b,c,d) are the next generation of reporter gene vectors optimized for expression in mammalian cells. Numerous configurations of pgl4 s are available, including those with the synthetic firefly luc2 (Photinus pyralis) and Renilla hrluc (Renilla reniformis) genes, which have been codon optimized for more efficient expression in mammalian cells. Furthermore, both the reporter genes and the vector backbone, including the bla (β-lactamase or ) and mammalian selectable marker genes for hygromycin (Hygro or Hyg r ), neomycin (Neo or Neo r ) and puromycin (Puro or Puro r ), have been engineered to reduce the number of consensus transcription factor binding sites, reducing background and the risk of anomalous transcription. The pgl4 backbone, provided with a choice of luc2 or hrluc genes, is also supplied with two Rapid Response Luciferase Reporter genes for each luciferase gene. The proteins encoded by these Rapid Response Luciferase genes respond more quickly and with greater magnitude to changes in transcriptional activity than their more stable counterparts. Page 1

I. Description (continued) The pgl4 family includes: Basic vectors with no that contain a multiple cloning region for cloning a of choice s containing a minimal s containing response elements and a minimal Promoter-containing vectors that can be used as expression controls or as co-reporter vectors Poly(A) block (for background reduction) Selectable Marker None Hygro r Neo r Puro r pgl4 s Upstream Element Multiple cloning region Promoter/ response elements Luciferase Gene Firefly (luc2) Rapid Response ( P, CP) Renilla (hrluc) Rapid Response ( P, CP) 487MA Figure 1. Generic pgl4 map showing the variety of features. Advantages of the pgl4 s include: Improved sensitivity and biological relevance due to: Increased reporter gene expression: Codon optimization of synthetic genes for mammalian expression Reduced background and risk of expression artifacts: Removal of cryptic DNA regulatory elements and transcription factor binding sites Improved temporal response: Rapid Response technology available using destabilized luciferase genes Enhanced usability and convenience: Flexible detection options: Choice of either synthetic luc2 (Photinus pyralis) or hrluc (Renilla reniformis) reporter genes Easy transition from transient to stable cells: Choice of mammalian selectable markers Easy transfer from one vector to another: Common multiple cloning site and a unique transfer scheme Page 2

II. Product Components and Storage Conditions Product Size Cat.# pgl4.10[luc2] (a,b) 20µg E51 pgl4.11[luc2p] (a,b) 20µg E61 pgl4.12[luc2cp] (a,b) 20µg E71 pgl4.13[luc2/sv40] (a,b) 20µg E81 pgl4.14[luc2/hygro] (a,b) 20µg E1 pgl4.[luc2p/hygro] (a,b) 20µg E6701 pgl4.16[luc2cp/hygro] (a,b) 20µg E6711 pgl4.17[luc2/neo] (a,b) 20µg E6721 pgl4.18[luc2p/neo] (a,b) 20µg E6731 pgl4.[luc2cp/neo] (a,b) 20µg E6741 pgl4.20[luc2/puro] (a,b) 20µg E6751 pgl4.21[luc2p/puro] (a,b) 20µg E6761 pgl4.22[luc2cp/puro] (a,b) 20µg E6771 pgl4.23[luc2/minp] (a,b) 20µg E8411 pgl4.[luc2p/minp] (a,b) 20µg E81 pgl4.25[luc2cp/minp] (a,b) 20µg E8431 pgl4.[luc2/minp/hygro] (a,b) 20µg E8441 pgl4.27[luc2p/minp/hygro] (a,b) 20µg E8451 pgl4.[luc2cp/minp/hygro] (a,b) 20µg E8461 pgl4.2[luc2p/cre/hygro] (a,b) 20µg E81 pgl4.30[luc2p/nfat-re/hygro] (a,b,c) 20µg E8481 pgl4.70[hrluc] (a,d) 20µg E6881 pgl4.71[hrlucp] (a,d) 20µg E681 pgl4.72[hrluccp] (a,d) 20µg E601 pgl4.73[hrluc/sv40] (a,d) 20µg E611 pgl4.74[hrluc/tk] (a,d) 20µg E621 pgl4.75[hrluc/cmv] (a,d,e) 20µg E631 pgl4.76[hrluc/hygro] (a,d) 20µg E641 pgl4.77[hrlucp/hygro] (a,d) 20µg E651 pgl4.78[hrluccp/hygro] (a,d) 20µg E661 pgl4.7[hrluc/neo] (a,d) 20µg E671 pgl4.80[hrlucp/neo] (a,d) 20µg E681 pgl4.81[hrluccp/neo] (a,d) 20µg E61 pgl4.82[hrluc/puro] (a,d) 20µg E7501 pgl4.83[hrlucp/puro] (a,d) 20µg E7511 pgl4.84[hrluccp/puro] (a,d) 20µg E7521 Page 3

II. Product Components and Storage Conditions (continued) Available Separately: Product Size Cat.# pgl4.31[luc2p/gal4uas/hygro] (a,b) 20µg C351 The CheckMate /Flexi Mammalian Two-Hybrid System Technical Manual, #TM3, is shipped with the pgl4.31[luc2p/gal4uas/hygro] and contains protocol information for use of this vector. Storage Conditions: Store the pgl4 Luciferase Reporter s at 20 C. III. General Considerations III.A. The pgl4 Backbone To reduce the risk of anomalous expression and increase the reliability of reporter gene expression, the pgl3 region upstream of the reporter gene was re-engineered to create the pgl4 s. The pgl3 region from the start of the reporter gene (the Nco I restriction site) to the bacterial gin of replication sequence was also redesigned. The modifications to this region include: a greatly reduced number of consensus transcription factor binding sites (Figure 2); a redesign of the multiple cloning region; removal of the f1 gin of replication; deletion of an intronic sequence; and a reduction in the number of modules. (Promoter modules are composite regulatory elements consisting of at least two transcription factor binding sites separated by a spacer. Promoter modules can have synergistic or antagonistic functions (1).) Note: The synthetic in the pgl4 s expresses a protein sequence identical to that expressed by the gene in the pgl3 s. The only regions of the pgl4 backbone not optimized for reduced anomalous expression are the downstream of the reporter gene and the bacterial gin of replication. Modifications to the pgl4 s have resulted in an improved signalto-background ratio. Some of these improved ratios are presented in Table 1, where several pgl4 s are compared to their controls (the corresponding less vectors), and the fold increase in the signal-to-background ratio is compared for the pgl4 s and previous generations of reporter vectors (e.g., pgl3 and phrl s). Page 4

GBF1 Arnt CDP FAST-1/Smad Brn-2 pgl3 Backbone MEIS1 RP58 Neu1/3 Lmo2 AD-b Cut-like Nkx2.5 E2F TALE STAT5 ELF-2 CCAAT GBF3 Prom L Gut B-cell PAR Mamm.C GBF3 Elk-1 Msx-1 HNF 1 HLF E2F NFAT Hox1.3 LHX3 ST/TA SF1 Pax2/5/8 AC-t Myo E2F STAT5 CREB HMX3 NKX3.1 MIS HNF4 HNF1 SRF B-cell HNF 1 MOK-2 CDE HNF3 EBV Elk-1 FOXL1 KLF3 CCAAT B-cell CPBP Pax1 Cone-rod Pax-3 FLI PAR Ras C2HC1 Pax1 Tax/CREB CCAAT Mus RFX1 Musc. Pax1 Pbx1 B-cell Ikaros2 v-mar MIBP-1 MyT1 NUDR ATF CCAAT NUDR EKLF RFX1 E4BP4 CDF-1 HOX PAX AD-b OBF1 NF-kB CREB Gut MEIS1 CCAAT GBF1 IS NRF2 Elf-2E2F NF-kB HLF BACH1 Neu-rGBF1 IRF-3 HIF-1 v-myb Pit1 OBF1 Barb Ikaros3 HLF MEIS1 c-myb OBF1 STAT5 MEF2 WTS Neu-r MEIS1 HoxC-Rel ST/TA OBF1 FAST-1 POZ CREB v-myb GBF1MREMMC RFX1 POZ B-cell My11 Pro L S8 STs TTF1 E2F v-myb EG3 E2F Tax PAX-6 GBF1 Bright Myo Myo FoxA2 c-myb Cdf1 Brn-3 X-Box Sox-5 c-myb NF Y Ikaros2 Neu-r Gsh-1 E2F CCAAT NUDR PAR Gfi-1B GBF1 HLF NUDR HAND2 E2F Neu1/3 TATA HNF4 PAR NKX3.1 Lmo2 E4BP4 Tal-1a E2F TCF PAX6 HNF1 AC-t RFX1 IRF2 E4BP4 GBF1 Elk-1 Cart-1 NKX3.1 CCAAT Mamm.C TCF11 Nkx2.5 GBF3 Cdx-2 AB-D Tal-1a Brn-3 Brn-3 OBF-1 COMP1 RP58 PAR Pdx1 Cart-1 Cart-1 CDP Clox FOXC1 AC-t Pbx-1 Pbx1 IF1 PR CDP NUDR Pax1 MyT1 Arnt CDP OBF1 NKX3.1 Elk-1 AC-t Nco I Runt-2 Pax1 AD-b Baso PL Avian C CDF-1 Pax TALE Hox-1.3 E4BP4 AD-b NKX3.1 Dec1 HNF1 GBF1 AP1 MIT/TFE Runt-2 Avian C E4BP4 NKX3.1 Cart-1 CDF1 Mamm C Cart-1 NUDR TCF/LEF1 GBF1 Nkx2.5 Pdx-1 Cdx-2 Brn-3 FOXC1 Cart-1 OBF1 AD-b PAR GBF3 RP58 Tal-1a COMP1 CDP Avian C Pbx1 Clox Pbx-1 pgl4 Backbone Nco I Figure 2. Reduced number of consensus transcription factor binding sites for the pgl4 s. The number of consensus transcription factor binding sites identified in the pgl3 backbone has been greatly reduced in the pgl4 backbone. Note: The SV40, HSV-TK and CMV s contain several consensus transcription factor binding sites. Due to the complex nature of the s these sites were not altered. However, the number and type of consensus transcription factor binding sites vary depending on the. For maximum reduction of anomalous expression in your assay system, we recommend that you evaluate the s to determine the one that results in the lowest level of anomalous expression with your system. IRF1 TEF-1 61MA Page 5

III.A. The pgl4 Backbone (continued) Poly(A) Signal/Transcriptional Pause Site for Background Reduction All pgl4 s contain a synthetic /transcriptional pause site (2) located upstream of either the multiple cloning region (in less vectors) or the SV40, CMV or HSV-TK (in -containing vectors). The synthetic / is present to reduce the effects of spurious transcription on luciferase reporter gene expression. Table 1. Signal-to-Background Comparison for Several of the pgl4, pgl3 and phrl s. 1 Signal-to- Fold Increase Background for s Ratio 1 pgl4 s 2 pgl4.13[luc2/sv40] vs. pgl4.10[luc2] 3,200 ± 0 3.7 pgl3-control vs. pgl3-basic 670± 57 pgl4.73[hrluc/sv40] vs. pgl4.70[hrluc] 630 ± 78 32 phrl-sv40 vs. phrl-null ± 2 pgl4.74[hrluc/tk] vs. pgl4.70[hrluc] 7 ± 8 33 phrl-tk vs. phrl-null 2.3 ± 0. pgl4.75[hrluc/cmv] vs. pgl4.70[hrluc] 1,100 ± 120 64 phrl-cmv vs. phrl-null 17 ± 2 1 To generate signal-to-background ratios the luciferase-containing vectors were transfected into CHO cells. At hours post-transfection the cells were lysed, luminescent signals were generated using the Dual-Luciferase Assay System and the relative light units were corrected for transfection efficiency, yielding normalized signals. Signal-to-background ratio = signal from -containing vector/signal from corresponding less vector. 2 Fold increase for pgl4 s = (signal-to-background ratio from pgl4 /signalto-background ratio from corresponding pgl3 or phrl ) 1. The experiment was repeated in CHO and other cell lines (HeLa, NIH/3T3 and HEK 23 cells) generating similar results. III.B. The pgl4 Reporter Genes To increase expression and reliability of the firefly luciferase reporter, a synthetic firefly luciferase gene, luc2, has been engineered. The gene was synthetically redesigned by changing the codons to those most frequently used in mammalian cells while simultaneously removing most of the consensus sequences for transcription factor binding sites (Figure 3). Additionally, the number of predicted modules present within the luc+ reporter gene (and thought to cause anomalous expression) has been reduced to a single module in the luc2 gene. To maintain the integrity of the firefly luciferase protein sequence from the luc+ gene to the luc2 gene, some of the consensus transcription factor binding sites and modules were not removed. In the transfection experiment shown in Figure 4, the synthetic firefly luc2 luciferase gene displayed an increase in expression compared to luc+. Page 6

luc+ PXR/CAR/RXR Pbx-1 CCAAT SRF Gfl-1B Cut-like RFX1 BRN-23 GBF3 OBF1 VIS1 En-1 HEN1 SRF Sox-5 NMP4 NKX3.1 AREB6 C-Myb SRF HNF1 AhR ATF4 Otx2 VIS1 VIS 1 Lmo2 NFY MyT1 VIS 1 ST/TA MEF Lmo2 Mt TCF/LEF-1 GFI1 Pit1 OBF 1 E2F GSh-1 MIBP-1/RFX1 POZ CDF-1 v-myb FAST-1/S MAD Pbx1/Meis1 MESI1 COMP1 E2F Pax-3 Tst-1/Oct-6 MEIS 1 E2F Ikaros 3 WHP CBF 3 E4BP4 ST/TA CDE/CHR TCF/LEF-1 MSX1/MSX-2 MyT1 P53 C-Ets-1 GBF3 AD-b HNF1 Oct1,2 GABP E2 E4BP4 NGN1/3 v-myb Brn3 FOXF2 PAR Pbx1 TEF-1 CCAAT OBF1 C2HC SRE OBF1 Cut-like FOXF2 MEIS1 ST/TA Elk-1 C2H2 SOX-5 GBF2 Pbx1 MOK-2 v-myb POZ Brn2 c-ets-1 MMC CCAATHIF1 Pax1 COMP1 VIS1 PBX/MEIS1 ST/TA ATF MEF2 E4BP4 Tst-1/Oct-6 SRF Brn23 COMP1 MOK-2 GATA Clox RF-7 c-myb TATA GBF1 GLI-k POZ HNF6 B-cell MEF TALE ZF Smad4 MIBP1 Pbx1 Cut-like TCF/LEF-1 Albumin D-box HEN1 Lmo2 RFX1 v-myb C-r CHOP CDE/CHR ST/TA HNF4 CREB ST/TA NKX3.1 WHP Pax-6 Tax/CREB FLI FAST-1/SMAD NF-KB Se-CtRNA PXR/RXR/CAR MZF-1 Thing1 AP 2 MAZ BPV CREB c-myb CREB NMP4 COMP1 GLI-K C-r Pbx1/Meis1 PAR PAX2/5/8 P53FLI E2F CREB HAND2 NMP4 E2F E4BP4 PAR Avian C MyT1 c-myb TALE MOK-2 Pbx-1 Pax-3 Cut-like NUR77/Nurr1/Nor-1 Ikaros-3 ST/TA Cut-like RAR CREB Elk-1 Elk-1 E2FCREB PAR GFI1 E2F E2F C-Abl c-myb v-myb CDF-1 ST/TA SRF v-myb NF-kB p53 p53 PAX luc2 Bel-1 VDR/RXR FKHRL1 LBP1c/LSF v-myb PAX c-myb CDF1 Baso p53 MA Figure 3. Reduced number of consensus transcription factor binding sites for the luc2 gene. The number of consensus transcription factor binding sites identified in the luc+ gene (top) have been greatly reduced in the luc2 gene (below), while conserving the protein sequence. To ensure that the synthetic construction affected only expression, both the luc+ and luc2 genes were cloned into the pgl3-control. The vectors were co-transfected with an internal control for assessing transfection efficiency, and after hours the luminescence (in relative light units) was measured and normalized to the control. When compared to luc+, the luc2 gene demonstrated a 4.1- to 11.8-fold increase in expression for the four mammalian cell lines tested. For more information on the hrluc gene, please refer to the Renilla Luciferase Reporter s Technical Manual, #TM237. See Table 2 for a list of the features in each pgl4. Page 7

10,000,000 Luminescence (Relative Light Units) 1,000,000 100,000 10,000 7. 4. 4.1 luc+ luc2 11.8 1,000 NIH/3T3 CHO HEK 23 HeLa Figure 4. The firefly luc2 gene displays higher expression than luc+. The luc2 gene was cloned into the pgl3-control (Cat.# E1741), replacing the luc+ gene. Thus both firefly luciferase genes were in the same pgl3-control backbone. The two vectors containing either of the firefly luciferase genes were co-transfected into NIH/3T3, CHO, HEK 23 and HeLa cells using the phrl-tk (Cat.# E61) for a transfection control. Twenty-four hours post-transfection the cells were lysed with Passive Lysis Buffer (Cat.# E41) and luminescence was measured using the Dual-Luciferase Assay System (Cat.# E10). Luminescence (relative light units) was normalized to the Renilla luciferase expression from the phrl-tk transfection control. The fold increase in expression values is listed above each pair of bars. A repeat of this experiment yielded similar results. Table 2. Features of the pgl4 s. Protein Reporter Multiple Degrada- Gene Promoter/ Mammalian Cloning Reporter tion Response Selectable Region Gene Sequence Element Marker pgl4.10[luc2] Yes luc2 1 No No No pgl4.11[luc2p] Yes hpest No No pgl4.12[luc2cp] Yes hcl1-hpest No No pgl4.13[luc2/sv40] No No SV40 No pgl4.14[luc2/hygro] Yes No No Hygro pgl4.[luc2p/hygro] Yes hpest No Hygro pgl4.16[luc2cp/hygro] Yes hcl1-hpest No Hygro pgl4.17[luc2/neo] Yes No No Neo pgl4.18[luc2p/neo] Yes hpest No Neo pgl4.[luc2cp/neo] Yes hcl1-hpest No Neo pgl4.20[luc2/puro] Yes No No Puro pgl4.21[luc2p/puro] Yes hpest No Puro pgl4.22[luc2cp/puro] Yes hcl1-hpest No Puro pgl4.23[luc2/minp] Yes No minp No pgl4.[luc2p/minp] Yes hpest No pgl4.25[luc2cp/minp] Yes hcl1-hpest No pgl4.[luc2/minp/hygro] Yes No Hygro pgl4.27[luc2p/minp/hygro] Yes hpest Hygro pgl4.[luc2cp/minp/hygro] Yes hcl1-hpest Hygro pgl4.2[luc2p/cre/hygro] No hpest CRE Hygro pgl4.30[luc2p/nfat-re/hygro] No hpest NFAT-RE Hygro pgl4.31[luc2p/gal4uas/hygro] No hpest GAL4UAS Hygro 1 luc2 is the synthetic firefly luciferase gene. (continued) 31MA Page 8

Table 2. Features of the pgl4 s (continued). Protein Reporter Multiple Degrada- Gene Promoter/ Mammalian Cloning Reporter tion Response Selectable Region Gene Sequence Element Marker pgl4.70[hrluc] Yes hrluc 2 No No No pgl4.71[hrlucp] Yes hpest No No pgl4.72[hrluccp] Yes hcl1-hpest No No pgl4.73[hrluc/sv40] No No SV40 No pgl4.74[hrluc/tk] No No HSV-TK No pgl4.75[hrluc/cmv] No No CMV No pgl4.76[hrluc/hygro] Yes No No Hygro pgl4.77[hrlucp/hygro] Yes hpest No Hygro pgl4.78[hrluccp/hygro] Yes hcl1-hpest No Hygro pgl4.7[hrluc/neo] Yes No No Neo pgl4.80[hrlucp/neo] Yes hpest No Neo pgl4.81[hrluccp/neo] Yes hcl1-hpest No Neo pgl4.82[hrluc/puro] Yes No No Puro pgl4.83[hrlucp/puro] Yes hpest No Puro pgl4.84[hrluccp/puro] Yes hcl1-hpest No Puro 2 hrluc is the synthetic Renilla gene. III.C. Distinguishing Features of the pgl4 s The following features are available for the pgl4 s. Reporter Genes: Firefly luciferase (luc2) or Renilla luciferase (hrluc) Regular or Rapid Response genes Upstream Elements: Promoterless basic vectors s with minimal s s containing response elements and minimal s s with constitutive s such as SV40, HSV-TK and CMV Selectable Markers: Hygro Neo Puro The Rapid Response pgl4 s Computational models predict that genetic reporters with reduced intracellular stability will yield faster response to changes in transcriptional rate and an increase in the relative magnitude of the response (3). Destabilized reporter proteins (i.e., those with faster protein degradation rates) are therefore expected to be more responsive and better suited to monitor rapid processes (such as activation and repression) than those with slower degradation rates. To generate reporter proteins that have increased protein degradation rates (i.e., destabilized reporters) one or both of two different protein degradation sequences have been incorporated into the synthetic firefly luc2 and Renilla hrluc luciferase genes. The first degradation sequence, PEST, is a forty-amino acid sequence isolated from the C-terminal region of mouse ornithine decarboxylase (4). The second Page

III.C. Distinguishing Features of the pgl4 s (continued) degradation sequence includes CL1 and PEST. CL1, ginally isolated from yeast, has also been shown to increase protein degradation (5). The codons within the PEST and CL1-PEST sequences have been optimized for expression in mammalian cells, and the number of consensus transcription factor binding sites has been reduced. To reflect the changes in these two protein degradation sequences they have been designated hpest and hcl1-hpest. The Rapid Response pgl4 Reporter gene design is shown in Figure 5. As the result of inclusion of the protein degradation sequences in the Rapid Response pgl4 s, the rate of reporter response to cellular stimuli has increased. In Figure 6 and Table 3 increased rates of reporter response in the CRE (camp response element) model system are demonstrated. For the firefly luciferasebased Rapid Response pgl4 Reporter s (pgl4.11[luc2p] and pgl4.12[luc2cp]), the rate of reporter response for the first two hours postinduction increased one- and twofold, respectively, over the luc2 control (pgl4.10[luc2]). Similar results for the same time frame were detected for the Renilla-based Rapid Response pgl4 Reporter s (pgl4.71[hrlucp] and pgl4.72[hrluccp]). The rate of response for the hrlucp- and hrluccp-destabilized Renilla reporters increased one- and threefold, respectively, when compared to the nondestabilized hrluc reporter. Gene Design luc2 luc2 luc2p luc2 hpest luc2cp luc2 hcl1 hpest hrluc hrluc hrlucp hrluc hpest hrluccp hrluc hcl1 hpest 4861MA Figure 5. Gene design of the Rapid Response pgl4 Reporter s. A consequence of inclusion of the degradation sequences is that the destabilized luciferase proteins do not accumulate in the cell to the same extent as the nondestabilized luciferase-containing controls. As a result, destabilized reporter proteins typically generate lower signal intensities (Figure 7). The luc2p and luc2cp proteins displayed 18.7% and 3.%, respectively, of the relative light units obtained using the firefly luciferase gene luc2. Similar reductions in relative light intensities were displayed by the Renilla luciferase-based Rapid Response pgl4 Reporter s. The Renilla reporter proteins hrlucp and hrluccp displayed 40% and 5.8%, respectively, of the relative light units of the hrluc control. Luminescence obtained using the Rapid Response pgl4 Reporter s can vary depending on the mammalian cell line and experimental conditions used, thus optimization is recommended. Page 10

Table 3. Increase in Reporter Response for the Rapid Response pgl4 Reporter s (results calculated from the data shown in Figure 6). Induction Fold Increase in at 2 Hours 1 Reporter Response Rate 2 pgl4.10[luc2] 6.6 pgl4.11[luc2p] 13.8 1 pgl4.12[luc2cp] 21.6 2 pgl4.70[hrluc] 2.7 pgl4.71[hrlucp] 6.3 1 pgl4.72[hrluccp] 12.2 3 1 Induction = signal from induced samples/signal from noninduced samples. 2 Reporter Response Rate = (induction of Rapid Response Reporter/induction of a regular reporter) 1. A. 30 25 pgl4.10[luc2] pgl4.11[luc2p] pgl4.12[luc2cp] Induction 20 10 5 0 0 1 2 3 4 Time (hours) 5 6 B. 16 pgl4.70[hrluc] pgl4.71[hrlucp] pgl4.72[hrluccp] 12 Induction 8 4 0 0 1 2 3 4 Time (hours) 5 6 32MA Figure 6. Increase in reporter response rate. To determine the increase in reporter response rate for the Rapid Response pgl4 Reporter s, a DNA segment containing multiple CREs (camp response element) and a minimal HSV-TK were cloned into each of the four Rapid Response pgl4 Reporter s (pgl4.11[luc2p], pgl4.12[luc2cp], pgl4.71[hrlucp] and pgl4.72[hrluccp]) and the two control vectors (pgl4.10[luc2] and pgl4.70[hrluc]). The CRE-containing vectors were then transiently transfected into HEK 23 cells. Twenty-four hours later 100µM of RO (RO-20-17) and 1µM of ISO (isoproterenol hydrochlde) were added to the transiently transfected cells to induce reporter gene expression. RO alone (100µM) was added to a subset of the wells to serve as a noninduced control. Cells were harvested, lysed and assayed with either the Luciferase Assay System (Cat.# E00; Panel A) or the Renilla Luciferase Assay System (Cat.# E10; Panel B). Induction was calculated by dividing the relative light units obtained from the induced wells by the relative light units obtained from noninduced wells. Two repeats of this experiment yielded similar results. Page 11

Luminescence (Relative Light Units) 100,000,000 10,000,000 1,000,000 100,000 10,000 pgl4.10[luc2] 18.7% pgl4.11[luc2p] 3.% pgl4.12[luc2cp] pgl4.70[hrluc] 40% pgl4.71[hrlucp] 5.8% pgl4.72[hrluccp] Figure 7. Relative expression of Rapid Response pgl4 luciferase genes. To determine the relative expression of the Rapid Response pgl4 luciferase genes, a DNA segment containing multiple CREs (camp response element) and a minimal HSV-TK was cloned into each of the four Rapid Response pgl4 Reporter s (pgl4.11[luc2p], pgl4.12[luc2cp], pgl4.71[hrlucp], and pgl4.72[hrluccp]) and the two control vectors (pgl4.10[luc2] and pgl4.70[hrluc]), which do not contain degradation sequences. The resulting vectors were cotransfected with a second reporter (transfection control) into HEK 23 cells. The transfection controls for the firefly luc2-containing vectors were the phrl-tk and, for the Renilla hrluc vectors, the pgl3-control. Twenty-four hours later the cells were lysed with Passive Lysis Buffer and luminescence (relative light units) was measured using the Dual- Luciferase Assay System. (The firefly luc2 data is shown by three bars on the left, while the hrluc data is contained in the three bars on the right.) Luminescence (relative light units) was normalized to the transfection control. The effects of the protein degradation sequences on the accumulation of luciferase enzyme are shown as percent expression of the control. The Promoterless pgl4 s The less pgl4 s contain no enhancer or elements. These vectors, which contain a multiple cloning region immediately upstream of the luciferase reporter gene, can be used to clone in a desired regulatory element(s) to drive expression of the reporter gene. The Minimal Promoter pgl4 s The minimal (minp) vectors contain a TATA-box element immediately upstream of the luciferase reporter gene and immediately downstream of the multiple cloning region. These vectors can be used to clone in a desired less-response element to drive expression of the reporter gene. The minimal TATA has low basal activity and allows for sensitive response element activity measurements. 33MA Page 12

A. Luminescence (Relative Light Units) 1 10 1 10 8 1 10 7 1 10 6 4-Fold 1 10 5 Noninduced Forskolin B. Luminescence (Relative Light Units) 1 10 7 -Fold 1 10 6 1 10 5 1 10 4 Noninduced Ionomycin + PMA 45MA Figure 8. High levels of reporter induction for pgl4.2[luc2p/cre/hygro] and pgl4.30[luc2p/nfat-re/hygro] in transient transfection of HEK 23 cells. pgl4.2 (Panel A) and pgl4.30 (Panel B) Reporter s were transiently transfected into HEK 23 cells. After twenty-four hours, reporter gene expression was induced by addition of 100µM forskolin to the pgl4.2-transfected cells for 5 hours and by addition of 1µM ionomycin plus 10ng/ml PMA to the pgl4.30-transfected cells for 17 hours. Noninduced controls were treated with an equivalent amount of DMSO vehicle for both pgl4.2- and pgl4.30-transfected cells. Luciferase activity was measured using the Bright-Glo Luciferase Assay System (Cat.# E10). The numbers shown above the graph bars represent fold induction for the respective vectors, calculated by dividing the relative light units obtained for the induced wells by the relative light units obtained from noninduced wells (n = ; standard error bars are shown). Results will vary depending on the cell line and the transfection protocol used. The CRE and NFAT-RE Reporter s The pgl4.2[luc2p/cre/hygro] and pgl4.30[luc2p/nfat-re/hygro] s are designed for use in both transient transfection assays and in stable cell line generation to monitor the camp and NFAT signaling pathways, respectively (Figure 8 shows a transient transfection). These vectors feature the Rapid Response Luciferase luc2p reporter gene and contain a hygromycin selection cassette to facilitate stable cell line expression. pgl4.2[luc2p/cre/hygro] contains three tandem CRE sequences upstream of the minimal sequence to drive luc2p expression. pgl4.30[luc2p/nfat-re/hygro] contains three tandem NFAT-RE sequences upstream of the minimal sequence to drive expression of the luc2p reporter. Page 13

III.C. Distinguishing Features of the pgl4 s (continued) The GAL4UAS Reporter Another response element vector, the pgl4.31[luc2p/gal4uas/hygro] is part of the CheckMate /Flexi Mammalian Two-Hybrid System. This reporter vector contains five consensus binding sequences, or Upstream Activating Sequences (UAS), for the GAL4 DNA-binding domain (GAL4UAS) upstream of a minimal adenoviral and is designed for transcriptional activation of the firefly luciferase by association of the GAL4 DNA-binding and VP16 activation domains bound upstream of the luciferase gene. The Internal Control pgl4 s The pgl4.13[luc2/sv40] and pgl4.73[hrluc/sv40] s are intended for use as internal control reporters and may be used with most experimental reporter vectors to co-transfect mammalian cells. These vectors contain the region, which provides strong, constitutive expression of luciferase in a variety of cell types, as well as the SV40 gin of replication, which results in transient, episomal replication in cells expressing the SV40 large T antigen such as COS-1 or COS-7 cells (6).! These -containing vectors may not be appropriate for use in examining the function of a response element of interest. Minimal -containing vectors are better suited for examining a response element of interest. The pgl4.74[hrluc/tk] is intended for use as an internal control reporter and may be used with most experimental reporter vectors to co-transfect mammalian cells. The pgl4.74[hrluc/tk] contains the herpes simplex virus thymidine kinase (HSV-TK) upstream of hrluc to provide low to moderate levels of Renilla luciferase expression in co-transfected mammalian cells of both embryonal and mature mammalian tissues (6,7). The pgl4.75[hrluc/cmv] is intended for use as an internal control reporter and may be used with most experimental reporter vectors to co-transfect mammalian cells. The pgl4.75[hrluc/cmv] contains the CMV immediateearly region, which provides strong, constitutive expression of Renilla luciferase in a variety of cell types. The promiscuous nature of the CMV immediate-early has been demonstrated in transgenic mice, where its transcriptional activity was observed in of the murine tissues examined (8). Selectable Markers Hygromycin B is an aminoglycosidic antibiotic that inhibits protein synthesis by disrupting translocation and promoting mistranslation at the 80S ribosome. Hygromycin B phosphotransferase (Hygro or Hyg r ) inactivates hygromycin B by phosphorylation. For the selection of stable cell lines, an expression cassette for the gene encoding hygromycin B phosphotransferase is available in the following pgl4 s: pgl4.14[luc2/hygro], pgl4.[luc2p/hygro], pgl4.16[luc2cp/hygro], pgl4.76[hrluc/hygro], pgl4.77[hrlucp/hygro], and pgl4.78 [hrluccp/hygro]. G418 is an aminoglycosidic antibiotic that inhibits protein synthesis. Neomycin or aminoglycoside 3 phosphotransferase (Neo or Neo r ) confers resistance to G418. For the selection of stable cell lines, an expression cassette for the gene encoding Page 14

neomycin phosphotransferase is available in the following pgl4 s: pgl4.17[luc2/neo], pgl4.18[luc2p/neo], pgl4.[luc2cp/neo], pgl4.7[hrluc/neo], pgl4.80[hrlucp/neo] and pgl4.81[hrluccp/neo]. Puromycin dihydrochlde is a nucleoside antibiotic that inhibits protein synthesis. Puromycin-N-acetyltransferase (Puro or Puro r ) confers resistance to puromycin. For the selection of stable cell lines, an expression cassette for the gene encoding puromycin-n-acetyltransferase is available in the following pgl4 s: pgl4.20[luc2/puro], pgl4.21[luc2p/puro], pgl4.22[luc2cp/puro], pgl4.82[hrluc/puro], pgl4.83[hrlucp/puro] and pgl4.84[hrluccp/puro]. The genes for hygromycin, neomycin and puromycin resistance have also been designed for reduced anomalous expression and codon optimized by the same process used on the firefly and Renilla luciferase reporter genes (earning all nine genes the designation synthetic ). The expression cassette contains the to express the Hygro, Neo or Puro resistance gene and a synthetic at the 3 end for transcriptional termination (separate from the synthetic /translational pause site located upstream of the reporter gene). III.D. Common Features of the pgl4 s SV40 Late Poly(A) Signal In addition to the features previously listed, each of the pgl4 s contains a downstream of the reporter gene. Polyadenylation signals cause the termination of transcription by RNA polymerase II and signal the addition of approximately 200 250 adenosine residues to the 3 -end of the RNA transcript (). Polyadenylation has been shown to enhance RNA stability and translation efficiency (10,11). The is extremely efficient and has been shown to increase the steady-state level of RNA approximately fivefold more than the SV40 early (12,13). The has been positioned 3 to the reporter gene in the pgl4 s to increase the level of luciferase expression. Redesigned Multiple Cloning Region The multiple cloning region of the pgl4 s (Figure ) has been synthetically constructed and is based on the multiple cloning region of the pgl3 s. However, differences between the two multiple cloning regions exist. The pgl4 multiple cloning region includes the following restriction sites: Bgl I,,,,,,,,,, and. The Bgl I, and restriction sites have been added to the pgl4 multiple cloning region and are not found in the pgl3 multiple cloning region. The Mlu I and Sma I restriction sites found in the pgl3 multiple cloning region have not been included in the pgl4 multiple cloning region. The purpose of two restriction sites is to be able to move DNA of interest (i.e., response elements, enhancers, s, etc.) among the pgl4 s. Additionally, due to the unique DNA recognition properties of Bgl I and, the two restriction sites in the pgl4 s offer directionality. Thus transfer between pgl4 s by using either the Bgl I or restriction enzymes retains the desired directionality of your DNA fragment of interest. Note: Additional Bgl I and restriction sites are present in the hrluc gene. Therefore, these two enzymes should not be used for cloning into Renilla-based pgl4 s. Page

RVprimer3 5...ACAAAACAAACTAGCAAAATAGGCTGTCCCCAGTGCAAGTGCAGGTGCCAGAACATTTCTCT / SfiI BglI Acc65I KpnI EcolCRI SacI NheI XhoI EcoRV BglII GGCCTAACTGGCCGGTACCTGAGCTCGCTAGCCTCGAGGATATCAAGATCT SfiI BglI HindIII GGCCTCGGCGGCCAAGCTTGGCAATCCGGTACTGTTGGTAAAGCCACCATGG...3 AGACACTAGAGGGTATATAATGGAAGCTCGACTTCCAGCTT Luciferase start minp Figure. The multiple cloning region of the pgl4 s. This map represents the less pgl4 s but also demonstrates the position and sequence of the minimal, minp, found in the pgl4.23 pgl4. s. The minp sequence is shaded in gray. Note: The BglI and EcoRV sites are also present in the hrluc gene and should not be used for cloning into the hrluc- (Renilla luciferase-) containing pgl4 s. 35MB IV. pgl4 Sequences, Restriction Enzyme Tables and Maps IV.A. Sequences, Restriction Enzyme Tables and GenBank Numbers Sequence information and restriction enzyme tables for the pgl4 s are available online at: www.promega.com/vectors/ The GenBank /EMBL accession numbers are listed below in Table 4. Note: Due to the use of updated software for generating vector maps and restriction enzyme tables, the manner in which we report restriction enzyme cut sites has changed. The location is now reported at the 5 -end of the cut DNA (the base to the right of the cut site). The maps and restriction enzyme tables associated with the pgl4 s have been updated accordingly. Table 4. GenBank /EMBL Accession Numbers for the pgl4 s. pgl4.10[luc2] pgl4.11[luc2p] pgl4.12[luc2cp] pgl4.13[luc2/sv40] pgl4.14[luc2/hygro] pgl4.[luc2p/hygro] pgl4.16[luc2cp/hygro] pgl4.17[luc2/neo] pgl4.18[luc2p/neo] GenBank /EMBL Accession Number AY738222 AY738223 AY7382 AY738225 AY864 AY86 AY86430 DQ188837 DQ188838 Page 16

Table 4. GenBank /EMBL Accession Numbers (continued) pgl4.[luc2cp/neo] pgl4.20[luc2/puro] pgl4.21[luc2p/puro] pgl4.22[luc2cp/puro] pgl4.23[luc2/minp] pgl4.[luc2p/minp] pgl4.25[luc2cp/minp] pgl4.[luc2/minp/hygro] pgl4.27[luc2p/minp/hygro] pgl4.[luc2cp/minp/hygro] pgl4.2[luc2p/cre/hygro] pgl4.30[luc2p/nfat-re/hygro] pgl4.31[luc2p/gal4uas/hygro] pgl4.70[hrluc] pgl4.71[hrlucp] pgl4.72[hrluccp] pgl4.73[hrluc/sv40] pgl4.74[hrluc/tk] pgl4.75[hrluc/cmv] pgl4.76[hrluc/hygro] pgl4.77[hrlucp/hygro] pgl4.78[hrluccp/hygro] pgl4.7[hrluc/neo] pgl4.80[hrlucp/neo] pgl4.81[hrluccp/neo] pgl4.82[hrluc/puro] pgl4.83[hrlucp/puro] pgl4.84[hrluccp/puro] GenBank /EMBL Accession Number DQ18883 DQ188840 DQ188841 DQ1888 DQ04455 DQ04456 DQ04457 DQ04458 DQ0445 DQ044 DQ04461 DQ04462 DQ487213 AY7382 AY738227 AY7382 AY73822 AY738230 AY738231 AY86431 AY86432 AY86433 DQ188843 DQ188844 DQ188845 DQ188846 DQ1888 DQ188848 IV.B. pgl4 Maps The following section contains circular vector maps and sequence reference points for the pgl4 s. For each map a selected set of restriction enzyme sites is also shown, including those in the multiple cloning regions, EcoRI, which denotes the Rapid Response Reporter and BamHI and SalI, which denote the selectable marker region. Information for pgl4.31[luc2p/gal4uas/hygro] can be found in the CheckMate /Flexi Mammalian Two-Hybrid System Technical Manual, #TM3 and online at: www.promega.com/vectors/ Note: The restriction enzyme sites shown on these vector maps were derived from sequence analysis software and have not been verified by restriction enzyme digestion with each enzyme listed. The location given specifies the 5 end of the cut DNA (the base to the right of the cut site). Page 17

pgl4 luc2 Maps 20 Sal I 2020 BamH I pgl4.10[luc2] (bp) pause site (for background reduction) 18 luc2 reporter gene 100 1752 1787 2008 Reporter primer 4 binding region 2076 205 ColEI-derived plasmid replication gin 2333 β-lactamase ( ) coding region 31 384 /transcriptional pause site 408 Reporter primer 3 binding region 41 10 luc2 Figure 10. pgl4.10[luc2] circle map and sequence reference points. 21MA Sal I 2148 BamH I pgl4.11[luc2p] (4370bp) pause site (for background reduction) luc2p reporter gene 100 1875 2136 Reporter primer 4 binding region 2204 2223 ColEI-derived plasmid replication gin 61 β-lactamase ( ) coding region 3252 4112 /transcriptional pause site 17 4370 Reporter primer 3 binding region 43 4338 luc2p 22MA EcoR I 1750 Figure 11. pgl4.11[luc2p] circle map and sequence reference points. 2205 Sal I 2 BamH I pgl4.12[luc2cp] (41bp) pause site (for background reduction) EcoRV luc2cp reporter gene 100 2 2187 Reporter primer 4 binding region 2255 2274 ColEI-derived plasmid replication gin 2512 β-lactamase ( ) coding region 3303 4163 /transcriptional pause site 48 41 Reporter primer 3 binding region 4370 438 luc2cp 23MA EcoR I 1750 Figure 12. pgl4.12[luc2cp] circle map and sequence reference points. Page 18

25 Sal I BamH I pgl4.13[luc2/sv40] (4641bp) luc2 pause site (for background reduction) 51 46 luc2 reporter gene 4 21 2186 07 Reporter primer 4 binding region 25 4 ColEI-derived plasmid replication gin 2732 β-lactamase ( ) coding region 3523 4383 /transcriptional pause site 4488 4641 Reporter primer 3 binding region 450 4 MA luc2 Maps Figure 13. pgl4.13[luc2/sv40] circle map and sequence reference points. Hyg r 2020 BamH I Sal I 3625 pgl4.14[luc2/ Hygro] (5841bp) luc2 pause site (for background reduction) 4862MA luc2 reporter gene 100 1752 1787 2008 2056 hygromycin (Hyg r ) coding region 3536 35 38 Reporter primer 4 binding region 3675 364 ColEI-derived plasmid replication gin 332 β-lactamase ( ) coding region 23 5583 /transcriptional pause site 5688 5841 Reporter primer 3 binding region 570 580 Figure 14. pgl4.14[luc2/hygro] circle map and sequence reference points. Hyg r 2148 BamH I Sal I 3753 EcoR I 1750 pgl4.[luc2p/ Hygro] (56bp) luc2p pause site (for background reduction) 4863MA luc2p reporter gene 100 1875 2136 2184 02 hygromycin (Hyg r ) coding region 27 3688 3736 Reporter primer 4 binding region 3803 3822 ColEI-derived plasmid replication gin 40 β-lactamase ( ) coding region 4851 5711 /transcriptional pause site 5816 56 Reporter primer 3 binding region 518 537 Figure. pgl4.[luc2p/hygro] circle map and sequence reference points. Page

Hyg r 2 BamH I Sal I 3804 Figure 16. pgl4.16[luc2cp/hygro] circle map and sequence reference points. Neo r 2020 BamH I Sal I 3383 luc2cp reporter gene 100 2 2187 2235 53 hygromycin (Hyg r ) coding region 78 37 373-3787 Reporter primer 4 binding region 3854 3873 ColEI-derived plasmid replication gin 4111 β-lactamase ( ) coding region 402 5762 /transcriptional pause site 5867 20 Reporter primer 3 binding region 56 588 luc2 reporter gene 100 1752 1787 2008 2056 neomycin phosphotransferase (Neo r ) coding region 323 3318 33 Reporter primer 4 (RVprimer4) binding region 33 52 ColEI-derived plasmid replication gin 360 β-lactamase ( ) coding region 4481 51 /transcriptional pause site 5446 55 Reporter primer 3 binding region 5548 5567 Figure 17. pgl4.17[luc2/neo] circle map and sequence reference points. Neo r 2148 BamH I Sal I 3511 EcoR I 1750 pgl4.16[luc2cp/ Hygro] (20bp) EcoR I 1750 pgl4.17[luc2/ Neo] (55bp) pgl4.18[luc2p/ Neo] (5727bp) luc2cp luc2 luc2p pause site (for background reduction) pause site (for background reduction) pause site (for background reduction) Figure 18. pgl4.18[luc2p/neo] circle map and sequence reference points. 4864MA 5131MA 5132MA luc2p reporter gene 100 1875 2136 2184 02 neomycin phosphotransferase (Neo r ) coding region 27 21 46 4 Reporter primer 4 binding region 3561 3580 ColEI-derived plasmid replication gin 3818 β-lactamase ( ) coding region 4 546 /transcriptional pause site 5574 5727 Reporter primer 3 binding region 5676 565 Page 20

Neo r 2 BamH I Figure. pgl4.[luc2cp/neo] circle map and sequence reference points. Puro r 2020 BamH I luc2cp reporter gene 100 2 2187 2235 53 neomycin phosphotransferase (Neo r ) coding region 78 32 7 3545 Reporter primer 4 binding region 3612 3631 ColEI-derived plasmid replication gin 386 β-lactamase ( ) coding region 40 5520 /transcriptional pause site 5625 5778 Reporter primer 3 binding region 5727 5746 luc2 reporter gene 100 1752 1787 2008 2056 puromycin-n-acetyltransferase (Puro r ) coding region 308 3123 3171 Reporter primer 4 binding region 3238 3257 ColEI-derived plasmid replication gin 5 β-lactamase ( ) coding region 46 5146 /transcriptional pause site 5251 5404 Reporter primer 3 binding region 5353 5372 Figure 20. pgl4.20[luc2/puro] circle map and sequence reference points. Puro r 2148 BamH I Sal I 3562 Sal I 3188 Sal I 3316 EcoR I 1750 pgl4.[luc2cp/ Neo] (5778bp) EcoR I 1750 pgl4.20[luc2/ Puro] (5404bp) pgl4.21[luc2p/ Puro] (5532bp) luc2cp luc2 luc2p pause site (for background reduction) pause site (for background reduction) pause site (for background reduction) Figure 21. pgl4.21[luc2p/puro] circle map and sequence reference points. 5133MA 51MA 5135 MA luc2p reporter gene 100 1875 2136 2184 02 puromycin-n-acetyltransferase (Puro r ) coding region 27 32 3251 32 Reporter primer 4 binding region 33 3385 ColEI-derived plasmid replication gin 3623 β-lactamase ( ) coding region 4414 5274 /transcriptional pause site 537 5532 Reporter primer 3 binding region 5481 5500 Page 21

Puro r 2 BamH I Sal I 3367 pgl4.22[luc2cp/ Puro] (5583bp) EcoR I 1750 luc2cp pause site (for background reduction) 5136MA luc2cp reporter gene 100 2 2187 2235 53 puromycin-n-acetyltransferase (Puro r ) coding region 78 3277 3302 3350 Reporter primer 4 binding region 17 36 ColEI-derived plasmid replication gin 3674 β-lactamase ( ) coding region 4465 5325 /transcriptional pause site 5430 5583 Reporter primer 3 binding region 5532 5551 Figure 22. pgl4.22[luc2cp/puro] circle map and sequence reference points. 2067 Sal I 2061 BamH I pgl4.23[luc2/minp] (43bp) / Bmt I 32 Minimal Minimal 78 108 luc2 reporter gene 141 173 18 204 Reporter primer 4 binding region 2117 2136 ColE1-derived plasmid replication gin 2374 β-lactamase ( ) coding region 3165 4025 /transcriptional pause site 4130 43 Reporter primer 3 binding region 32 51 luc2 548MA Figure 23. pgl4.23[luc2/minp] circle map and sequence reference points. 25 Sal I 218 BamH I EcoR I 171 pgl4.[luc2p/minp] (4411bp) luc2p / Bmt I 32 Minimal 54MA Minimal 78 108 luc2p reporter gene 141 16 56 2177 Reporter primer 4 binding region 25 ColE1-derived plasmid replication gin 2502 β-lactamase ( ) coding region 323 43 /transcriptional pause site 58 4411 Reporter primer 3 binding region 43 437 Figure. pgl4.[luc2p/minp] circle map and sequence reference points. Page 22

Sal I BamH I 26 20 EcoR I 171 pgl4.25[luc2cp/minp] (4462bp) luc2cp / Bmt I 32 Minimal 550MA Minimal 78 108 luc2cp reporter gene 141 70 2007 22 Reporter primer 4 binding region 226 23 ColE1-derived plasmid replication gin 2553 β-lactamase ( ) coding region 34 04 /transcriptional pause site 430 4462 Reporter primer 3 binding region 4411 4430 Figure 25. pgl4.25[luc2cp/minp] circle map and sequence reference points. Sal I 36 Hyg r BamH I 2061 pgl4.[luc2/minp/hygro] (5882bp) luc2 / Bmt I 32 Minimal 551MA Minimal 78 108 luc2 reporter gene 141 173 18 204 207 25 hygromycin (Hyg r ) coding region 2540 3577 31 364 Reporter primer 4 binding region 3716 3735 ColE1-derived plasmid replication gin 373 β-lactamase ( ) coding region 64 56 /transcriptional pause site 572 5882 Reporter primer 3 binding region 5831 5850 Figure. pgl4.[luc2/minp/hygro] circle map and sequence reference points. BamH I 218 Sal I 374 Hyg r EcoR I 171 luc2p pgl4.27[luc2p/minp/hygro] (10bp) / Bmt I Minimal Figure 27. pgl4.27[luc2p/minp/hygro] circle map and sequence reference points. 32 552MA Minimal 78 108 luc2p reporter gene 141 16 56 2177 2225 43 hygromycin (Hyg r ) coding region 3705 372 3777 Reporter primer 4 binding region 3844 3863 ColE1-derived plasmid replication gin 4101 β-lactamase ( ) coding region 482 5752 /transcriptional pause site 5857 10 Reporter primer 3 binding region 55 578 Page 23

Sal I 3845 Hyg r pgl4.[luc2cp/minp/hygro] (61bp) BamH I 20 luc2cp Minimal 78 108 luc2cp reporter gene 141 70 2007 22 2276 4 hygromycin (Hyg r ) coding region 27 3756 3780 38 Reporter primer 4 binding region 385 314 ColE1-derived plasmid replication gin β-lactamase ( ) coding region 443 5803 /transcriptional pause site 508 61 Reporter primer 3 binding region 10 2 Figure. pgl4.[luc2cp/minp/hygro] circle map and sequence reference points. / Sal I 3868 EcoR I 171 pgl4.2[luc2p/cre/hygro] (84bp) Hyg r / Bmt I Minimal Figure 2. pgl4.2[luc2p/cre/hygro] circle map and sequence reference points. / Sal I 3881 Hyg r CRE NFAT-RE Minimal luc2p BamH I 23 pgl4.30[luc2p/nfat-re/hygro] (7bp) Minimal luc2p BamH I 2276 camp response element (CRE) 33 1 Minimal 2 182 luc2p reporter gene 2 0 2030 2251 22 2717 hygromycin (Hyg r ) coding region 27 377 3803 3851 Reporter primer 4 binding region 318 337 ColE1-derived plasmid replication gin 4175 β-lactamase ( ) coding region 4 58 /transcriptional pause site 531 84 Reporter primer 3 binding region 33 52 NFAT response element 33 122 Minimal 136 1 luc2p reporter gene 2 2003 2043 2312 2730 hygromycin (Hyg r ) coding region 2755 372 3816 3864 Reporter primer 4 binding region 331 350 ColE1-derived plasmid replication gin 4188 β-lactamase ( ) coding region 47 583 /transcriptional pause site 544 7 Reporter primer 3 binding region 46 65 Figure 30. pgl4.30[luc2p/nfat-re/hygro] circle map and sequence reference points. 32 EcoR I 1865 553MA 554MA 555MA Page

pgl4 hrluc Maps pgl4.70[hrluc] (3522bp) hrluc / hrluc reporter gene 100 1035 1067 18 Reporter primer 4 binding region 1356 1375 ColEI-derived plasmid replication gin 1613 β-lactamase ( ) coding region 04 /transcriptional pause site 336 3522 Reporter primer 3 binding region 31 0 1306 1300 Sal I BamH I Figure 31. pgl4.70[hrluc] circle map and sequence reference points. 25MA hrluc Maps 1437 Sal I 1431 BamH I pgl4.71[hrlucp] (3653bp) / hrlucp reporter gene 100 18 18 14 Reporter primer 4 binding region 1487 06 ColEI-derived plasmid replication gin 1744 β-lactamase ( ) coding region 2535 335 /transcriptional pause site 3500 3653 Reporter primer 3 binding region 32 3621 hrlucp MA EcoR I 1033 1488 Sal I 1482 BamH I Figure 32. pgl4.71[hrlucp] circle map and sequence reference points. pgl4.72[hrluccp] (3704bp) / hrluccp EcoR I 1033 Figure 33. pgl4.72[hrluccp] circle map and sequence reference points. 27MA hrluccp reporter gene 100 1212 10 Reporter primer 4 binding region 38 57 ColEI-derived plasmid replication gin 175 β-lactamase ( ) coding region 2586 46 /transcriptional pause site 3551 3704 Reporter primer 3 binding region 3653 3672 Page 25

1705 Sal I 16 BamH I pgl4.73[hrluc/sv40] (321bp) hrluc pause site (for background reduction) 51 46 hrluc reporter gene 4 14 14 1687 Reporter primer 4 binding region 1755 1774 ColEI-derived plasmid replication gin 2012 β-lactamase ( ) coding region 03 33 /transcriptional pause site 3768 321 Reporter primer 3 binding region 3870 388 Figure. pgl4.73[hrluc/sv40] circle map and sequence reference points. 2021 Sal I 20 BamH I pgl4.74[hrluc/tk] (37bp) hrluc pause site (for background reduction) HSV-TK HSV-TK 27 77 hrluc reporter gene 8 1750 1784 2005 Reporter primer 4 binding region 2071 200 ColEI-derived plasmid replication gin 2330 β-lactamase ( ) coding region 31 37 /transcriptional pause site 4084 37 Reporter primer 3 binding region 4186 05 Figure 35. pgl4.74[hrluc/tk] circle map and sequence reference points. 2065 Sal I 205 BamH I pgl4.75[hrluc/cmv] (41bp) hrluc pause site (for background reduction) CMV immediateearly CMV immediate early 14 755 hrluc reporter gene 85 174 18 20 Reporter primer 4 binding region 21 21 ColEI-derived plasmid replication gin 2372 β-lactamase ( ) coding region 3163 4023 /transcriptional pause site 41 41 Reporter primer 3 binding region 30 4 30MA 2MA MA Figure 36. pgl4.75[hrluc/cmv] circle map and sequence reference points. Page

Sal I 205 Sal I 3036 Figure 37. pgl4.76[hrluc/hygro] circle map and sequence reference points. Hyg r Hyg r pgl4.77[hrlucp/hygro] (5252bp) 1431 BamH I pgl4.76[hrluc/ Hygro] (5121bp) 1300 BamH I hrluc hrlucp pause site (for background reduction) EcoR I 1033 / Figure 38. pgl4.77[hrlucp/hygro] circle map and sequence reference points. 4868MA 4865MA hrluc reporter gene 100 1035 1067 18 1336 1754 hygromycin (Hyg r ) coding region 177 16 40 88 Reporter primer 4 binding region 255 274 ColEI-derived plasmid replication gin 3212 β-lactamase ( ) coding region 4003 4863 /transcriptional pause site 468 5121 Reporter primer 3 binding region 5070 508 hrlucp reporter gene 100 18 18 14 1467 1885 hygromycin (Hyg r ) coding region 10 2 271 30 Reporter primer 4 binding region 3086 3105 ColEI-derived plasmid replication gin 33 β-lactamase ( ) coding region 41 44 /transcriptional pause site 50 5252 Reporter primer 3 binding region 5201 5220 Sal I 3087 Hyg r 1482 BamH I pgl4.78[hrluccp/hygro] (5303bp) hrluccp / EcoR I 1033 486MA hrluccp reporter gene 100 1212 10 18 36 hygromycin (Hyg r ) coding region 61 28 3022 3070 Reporter primer 4 binding region 3137 36 ColEI-derived plasmid replication gin 334 β-lactamase ( ) coding region 4185 5045 /transcriptional pause site 50 5303 Reporter primer 3 binding region 5252 5271 Figure 3. pgl4.78[hrluccp/hygro] circle map and sequence reference points. Page 27

Sal I 23 Neo r pgl4.7[hrluc/ Neo] (487bp) 1300 BamH I hrluc pause site (for background reduction) Figure 40. pgl4.7[hrluc/neo] circle map and sequence reference points. 5137MA hrluc reporter gene 100 1035 1067 18 1336 1754 neomycin phosphotransferase (Neo r ) coding region 177 2573 258 46 Reporter primer 4 binding region 2713 2732 ColEI-derived plasmid replication gin 270 β-lactamase ( ) coding region 3761 4621 /transcriptional pause site 487 Reporter primer 3 binding region 48 48 Sal I 274 Neo r pgl4.80[hrlucp/neo] (5010bp) 1431 BamH I hrlucp / EcoR I 1033 5138MA hrlucp reporter gene 100 18 18 14 1467 1885 neomycin phosphotransferase (Neo r ) coding region 10 2704 272 2777 Reporter primer 4 binding region 44 63 ColEI-derived plasmid replication gin 3101 β-lactamase ( ) coding region 382 52 /transcriptional pause site 4857 5010 Reporter primer 3 binding region 45 478 Figure 41. pgl4.80[hrlucp/neo] circle map and sequence reference points. Sal I 45 Neo r 1482 BamH I pgl4.81[hrluccp/neo] (5061bp) hrluccp / EcoR I 1033 Figure. pgl4.81[hrluccp/neo] circle map and sequence reference points. 513MA hrluccp reporter gene 100 1212 10 18 36 neomycin phosphotransferase (Neo r ) coding region 61 2755 2780 Reporter primer 4 binding region 5 214 ColEI-derived plasmid replication gin 32 β-lactamase ( ) coding region 343 4803 /transcriptional pause site 408 5061 Reporter primer 3 binding region 5010 502 Page

Sal I 68 Sal I 25 Figure 43. pgl4.82[hrluc/puro] circle map and sequence reference points. Figure 44. pgl4.83[hrlucp/puro] circle map and sequence reference points. Sal I 50 Puro r Puro r Puro r 1482 BamH I pgl4.82[hrluc/ Puro] (4684bp) 1300 BamH I pgl4.84[hrluccp/puro] (48bp) pgl4.83[hrlucp/puro] (48bp) 1431 BamH I hrluc hrlucp hrluccp / EcoR I 1033 pause site (for background reduction) / EcoR I 1033 Figure 45. pgl4.84[hrluccp/puro] circle map and sequence reference points. 51MA 5140MA 5141MA hrluc reporter gene 100 1035 1067 18 1336 1754 puromycin-n-acetyltransferase (Puro r ) coding region 177 2378 03 51 Reporter primer 4 binding region 2518 2537 ColEI-derived plasmid replication gin 2775 β-lactamase ( ) coding region 35 44 /transcriptional pause site 4531 4684 Reporter primer 3 binding region 4633 4652 hrlucp reporter gene 100 18 18 14 1467 1885 puromycin-n-acetyltransferase (Puro r ) coding region 10 250 25 2582 Reporter primer 4 binding region 4 ColEI-derived plasmid replication gin 206 β-lactamase ( ) coding region 367 4557 /transcriptional pause site 48 Reporter primer 3 binding region 64 83 hrluccp reporter gene 100 1212 10 18 36 puromycin-n-acetyltransferase (Puro r ) coding region 61 25 2585 33 Reporter primer 4 binding region 2700 27 ColEI-derived plasmid replication gin 257 β-lactamase ( ) coding region 3748 48 /transcriptional pause site 13 48 Reporter primer 3 binding region 48 48 Page 2

V. References 1. Klingenhoff, A. et al. () Functional modules can be detected by formal models independent of overall nucleotide sequence similarity. Bioinform., 180 6. 2. pgl3 Luciferase Reporter s Technical Manual, #TM033, Promega Corporation. 3. Schimke R.T. (73) Control of enzyme levels in mammalian tissues. Adv. Enzymol. Mol. Biol. 37, 135 87. 4. Li, X. et al. (8) Generation of destabilized green fluorescent protein as a transcription reporter. J. Biol. Chem. 273, 70 5. 5. Gilon, T., Chomsky, O. and Kulka, R.G. (8) Degradation signals for ubiquitin system proteolysis in Saccharomyces cerevisiae. EMBO J. 17, 275. 6. Gluzman, Y. (81) SV40-transformed simian cells support the replication of early SV40 mutants. Cell 23, 175 82. 7. Wagner, E.F. et al. (85) Transfer of genes into embryonal carcinoma cells by retrovirus infection: Efficient expression from an internal. EMBO J. 4, 3 6. 8. Stewart, C.L. et al. (87) Expression of retroviral vectors in transgenic mice obtained by embryo infection. EMBO J. 6, 383 8.. Schmidt, E.V. et al. (0) The cytomegalovirus enhancer: A pan-active control element in transgenic mice. Mol. Cell. Biol. 10, 4406 11. 10. Proudfoot, N.J. (1) Poly(A) signals. Cell 64, 671 4. 11. Bernstein, P. and Ross, J. (8) Poly(A), binding protein and the regulation of mrna stability. Trends Biochem. Sci. 14, 373 7. 12. Jackson, R.J. and Standart, N. (0) Do the tail and 3 untranslated region control mrna translation? Cell 62,. 13. Carswell, S. and Alwine, J.C. (8) Efficiency of utilization of the simian virus 40 late polyadenylation site: Effects of upstream sequences. Mol. Cell. Biol., 48 58. VI. Related Products Renilla Luciferase Assay Systems Product Size Cat.# EnduRen Live Cell Substrate 0.mg E6481 3.4mg E6482 mg E6485 ViviRen Live Cell Substrate 0.37mg E641 3.7mg E6 37mg E645 Renilla Luciferase Assay System 100 assays E10 1,000 assays E20 Luciferase Reporter Cell Lines Product Size Cat.# GloResponse CRE-luc2P HEK23 Cell Line each E8500 GloResponse NFAT-RE-luc2P HEK23 Cell Line each E8510 Page 30

Firefly Luciferase Assay Systems Product Size Cat.# ONE-Glo Luciferase Assay System* 10ml E6110 100ml E6120 1L E6130 Bright-Glo Luciferase Assay System* 10ml E10 100ml E20 10 100ml E50 Steady-Glo Luciferase Assay System 10ml E2510 100ml E2520 10 100ml E2550 Luciferase Assay System 100 assays E00 Luciferase 1000 Assay System 1,000 assays E4550 Luciferase Assay System with Reporter Lysis Buffer 100 assays E4030 *For Laboratory Use. Firefly and Renilla (Dual-Reporter) Luciferase Assay Systems Product Size Cat.# Dual-Glo Luciferase Assay System 10ml E220 100ml E240 10 100ml E280 Dual-Luciferase Reporter Assay System 100 assays E10 Dual-Luciferase Reporter 1,000 Assay System 1,000 assays E80 Luminometers Product Size Cat.# GloMax 20/20 Luminometer each E5311 GloMax 20/20 Luminometer w/single Auto-Injector each E5321 GloMax 20/20 Luminometer w/dual Auto-Injector each E5331 GloMax 6 Microplate Luminometer each E6501 GloMax 6 Microplate Luminometer w/single Injector each E6511 GloMax 6 Microplate Luminometer w/dual Injectors each E6521 Lysis Buffer Product Size Cat.# Passive Lysis 5X Buffer 30ml E41 Antibiotic Product Size Cat.# Antibiotic G-418 Sulfate 100mg V781 Page 31

(a) For research use only. This product and/or its use is subject to one or more of the following Promega patents: U.S. Pat. Appln. Ser. Nos. 0/645,706, 10/43,508, 10/4,1, PCT Pat. Appln. Ser. No. PCT/US03/3, PCT/US2005/033218, U.S. Pat. Nos. 5,670,356, 6,387,675 and 6,552,17, Australian Pat. No. 684 and various corresponding patent applications and issued patents. The terms of the limited license conveyed with the purchase of this product are as follows: Researchers may use this product in their research and they may transfer derivatives to others for research use provided that at the time of transfer a copy of this label license is given to the recipients and the recipients agree to be bound by the terms and conditions of this label license. In addition, researchers must do one of the following: (1) use luminescent assay reagents purchased from Promega Corporation for all determinations of luminescence activity resulting from the research use of this product and its derivatives; or (2) contact Promega to obtain a license for the use of the product and its derivatives in conjunction with luminescent assay reagents not purchased from Promega. No reach-through payments shall be owed to Promega relating to an organization s commercialization of products that are the discoveries resulting from the research use of this product or its derivatives, provided that such products of the organization do not fall within the scope of the valid claims of any issued patents assigned or licensed to Promega, or that such commercialization would not be a violation of the terms of this label license. No other use of this product or its derivatives is authzed without the express written consent of Promega including, without limitation, Commercial Use. Commercial Use means any and all uses of this product and derivatives by a party for monetary or other consideration and may include but is not limited to use in: (1) product manufacture; and (2) to provide a service, information or data; and/or resale of the product or its derivatives, whether or not such product or derivatives are resold for use in research. With respect to such Commercial Use, or any diagnostic, therapeutic or prophylactic uses, please contact Promega for supply and licensing information. If the purchaser is not willing to accept the conditions of this limited use statement, Promega is willing to accept the return of the unopened product and provide the purchaser with a full refund. However, in the event the product is opened, then the purchaser agrees to be bound by the conditions of this limited use statement. (b)cat.# C351, E51, E61, E71, E81, E1, E6701, E6711, E6721, E6731, E6741, E6751, E6761, E6771, E8411, E81, E8431, E8441, E8451, E8461, E81, E8481: The method of recombinant expression of Coleoptera luciferase is covered by U.S. Pat. Nos. 5,583,0, 5,674,713 and 5,700,673. A license (from Promega for research reagent products and from The Regents of the University of California for all other fields) is needed for any commercial sale of nucleic acid contained within or derived from this product. (c)cat.# E8481: The NFAT response element and its use are licensed under one or more of the following patents: U.S. Pat. Nos. 5,837,840, 6,7,25, 5,8,810, 6,06,5, 6,388,052, 6,0,0, 6,171,781, 6,352,830, 6,312,8 and 6,875,571. (d) Cat.# E6881, E681, E601, E611, E621, E631, E641, E651, E661, E671, E681, E61, E7501, E7511, E7521: Licensed from University of Georgia Research Foundation, Inc., under U.S. Pat. Nos. 5,22,658, 5,418,5, Canadian Pat. No. 2,105,84 and related patents. (e) Cat.# E631: The CMV and its use are covered under U.S. Pat. Nos. 5,168,062 and 5,385,83 owned by the University of Iowa Research Foundation, Iowa City, Iowa, and licensed FOR RESEARCH USE ONLY. Research Use includes contract research for which monetary or other consideration may be received. Other commercial users must obtain a license to these patents directly from the University of Iowa Research Foundation. 2004 2007 Promega Corporation. All Rights Reserved. Dual-Luciferase, Flexi, GloMax and Steady-Glo are registered trademarks of Promega Corporation. Bright-Glo, CheckMate, Dual-Glo, EnduRen, GloResponse, ONE-Glo, Rapid Response and ViviRen are trademarks of Promega Corporation. GenBank is a registered trademark of the U.S. Department of Health and Human Services. Products may be covered by pending or issued patents or may have certain limitations. Please visit our Web site for more information. All prices and specifications are subject to change without prior notice. Product claims are subject to change. Please contact Promega Technical Services or access the Promega catalog online for the most up-to-date information on Promega products. Page 32