Reagents to study Wnt signaling
Reagents to study Wnt signaling can be obtained from several distributors or commercial vendors. In cases where reagents are not available, we would be happy to help , but otherwise we refer you to distributors. We have no commercial interests in those distributors or vendors, but they are professionals, can provide you with products of guaranteed quality and with the necessary background information. Reagents like purified Wnt proteins, antibodies to Wnts or to b-catenin, TOPflash reporter constructs and Wnt expression constructs can be obtained from commercial sources (R&D systems, Abcam, Cell Signaling, Upstate, Santa Cruz Biotech or Transduction Laboratories) and easily traced by a websearch. The Wnt homepage does not include advertisements for commercial products or direct links to vendor catalogues.
This page is frequently updated. If you find anything that is published and missing on this site, alert me. If cannot find information you are looking for, then it is most likely unavailable. Specifically, beyond the Wnt-producing cells that are listed, there are no other ones available. We are trying to express other Wnts, with various degrees of success, but more work needs to be done before these are useful. Note that reagents not made in our own lab should be requested from the original sources. This is common practice in the Biomedical research community and avoids propriety issues.
In genereal, good non-commercial sources of cDNA clones are Addgene, the ATCC, the DGRC or the Mammalian Gene Collection, which list most of the mammalian (mouse and human) Wnt pathway cDNA clones. Here a list of clones from our lab, now available through the ATCC.
| Clone | from | # |
|---|---|---|
| Human WNT1 (PAL1) | ATCC | 57198 |
| Human WNT1 | MGC | 30915522 |
| Human WNT3 (pHP1) | ATCC | MBA-174 |
| Mouse Wnt1 (pMT70) | ATCC | pMT70 |
| Mouse Wnt3 | ATCC | MBA-175 |
| Mouse Wnt3A | ATCC | MBA-176 |
| Drosophila Wingless | DGRC | RE02607 |
Randy Moon's lab has an extensive catalogue of Wnt clones. Otherwise, locate the researchers who originally did the work. For those who want to study human Wnt gene activity, be assured that the mouse homologs are similar enough (sometimes even identical in protein sequence) to have the same activity as human counterparts. Companies like Upstate and R&D systems are making Wnt cDNA clones in expression vectors available.
TOPflash reporters are commercially available. Super8XTOPFlash can be obtained from the Moon lab.
A series of lenti-viral vectors and reporters for Wnt signaling generated by Fuerer et al (Lentiviral Vectors to Probe and Manipulate the Wnt Signaling Pathwa, PLoS One. 2010 Feb 23;5(2):e9370) are available from Addgene.
reporter animals (There is a separate page on Wnt reporters in animals)
TOPGAL mice (made by Elaine Fuchs) can be obtained from Jackson labs.
Axin2-LacZ (Conductin-LacZ) mice (from Walter Birchmeier) are provided by EMMA or by Jackson Labs
Lgr5tm1(cre/ERT2) mice from Hans Clevers can be obtained from Jackson labs.
Cells producing Active Wnt and Wingless protein (see the separate page on purifying active Wnt, which also tells you how to handle the conditioned medium).
| Wnt Producing Cell | From | Name | Source |
|---|---|---|---|
| Mouse Wnt3A | Nusse | CRL-2647 | ATCC |
| Mouse Wnt5A | Nusse | CRL-2814 | ATCC |
| S2-Tub-wg (Drosophila Wingless S2 cells) | Nusse | 165 | DGRC |
Regular S2 cells and protocols are also available from the DGRC
Several active Wnt proteins can be purchased from R&D systems.
| Antigen | From | Name |
|---|---|---|
| Drosophila Frizzled 1 | Adler | 1C11 |
| Drosophila Frizzled 2 | Nusse | 12A7 |
| Drosophila Wingless | Cohen | 4D4 |
| Drosophila Armadillo | Wieschaus | N2 7A1 |
| beta-catenin | Balsamo | PY489-B |
There are good antibodies to detect beta-catenin either on Western Blots or by staining (Transduction labs). There is also a monoclonal antibody to the non-phosphorylated ("activated") form of b-catenin (Van Noort, 2002) available from Upstate. Cell Signaling, R&D systems and Santa Cruz Biotech sell monoclonal and polyvalent antibodies to several mammalian Wnt proteins, including Wnt3A and to Wnt signaling components.
Note: Our lab is not able to send out the anti-Dishevelled or anti-Axin antibodies anymore. Because of the availability of the monoclonal antibody to Wingless (see above), we have not maintained supplies of the rabbit anti-wingless antibody and this is not available.
Generating antibodies to Wnts, tips
It has been notoriously difficult to generate useful antibodies to vertebrate Wnt proteins. Several groups have made antibodies to peptides (Papkoff J, et al.) or Wnt-GST fusion proteins (Burrus LW, et al.). These sera work in Western blots or immunoprecipitations but usually only in extracts of cells that are engineered to over-express Wnts by transfections. In general, these sera do not detect endogenous Wnt proteins in cell extracts, nor do they detect Wnt proteins in tissues by staining techniques. Hence, there are few data on Wnt protein distribution in intact vertebrate animals.
In Drosophila however, the situation is different. There are good antisera to two Drosophila Wnt proteins: Wingless (van den Heuvel M, et al) and DWnt-3/5. (Fradkin LG, et al., Yoshikawa, 2003). It is clear why these proteins are better immunogens: they both contain long inserts in the proteins (compared to other Wnt proteins) and it has been shown that these inserts are the antigenic determinants (unpublished data, Nusse Lab). A mouse monoclonal Neumann C, et al.)to the Wingless insert works well in staining and in Western blot experiments and is available from the Developmental Studies Hybridoma Bank at The University of Iowa.
In addition, Kostriken R, et al. have made antibodies to a Leech Wnt. They took a non-conserved stretch of the protein and multimerized it to get a better immunogen.
It seems therefore that one successful strategy to get better sera is to use non-conserved parts of Wnt proteins. By generating fusion proteins (we like GST fusions) and by multimerizing the inserts, one might be able to get a useful antiserum. Note that all Wnt proteins are less conserved around the sites of the Wingless and DWnt-3/5 inserts (Alignments). These domains are also, in general, good sites for the insertion of epitopes (myc, FLAG), as we found out. Possibly, these domains stick out of the otherwise highly structurally constrained Wnt proteins and are therefore better accessible to antibodies. In addition, the Wingless and DWnt-3/5 inserts are not-conserved and are better recognized as foreign by the mammalian immune system.
Note however that because these antigenic domains in Wingless and DWnt-3/5 are not conserved, the antibodies to these proteins will not recognize any other Wnt.
Other good sites for inserting epitopes in Wnts are close to the amino-terminus.