Horr B , Kurtz R , Pandey A , Hoffstrom BG , Schock E , LaBonne C .

R24 OD021485 NIH HHS , R01 DE016289 NIDCR NIH HHS, S10 OD010645 NIH HHS , R01 DE026434 NIDCR NIH HHS

             protein binding

	Figure 1. Immunofluorescence testing of serum. The serum from mouse M3 immunized with FoxD3-Flag, Twist-Flag, Six1-Flag, Slug-Flag and Sox3-Flag produced in Hek293T cells was tested by immunofluorescence on XTC cells transfected with each of the target or RFP-Flag as a negative control. A secondary Alexa 488-conjugated anti-mouse antibody was used to visualize the mouse primary antibodies (green). Notice the green nuclei in each of the transfections, with some non-transfected cells lacking signal.
	Figure 2. Primary screening method. (A) Diagram representing the strategy used to rapidly identify wells producing antibodies to multiple targets at once. Four plates per fusion were used. Thirty microlitres were taken from each well and placed in the master plate (total volume 120†µl). The master plate was diluted with 200†µl of TBST (TBS with 0.1% Tween 20). From the 320†µl of the master plate, 50†µl was added to each of the five ELISA plates plus the glass-bottom plate containing XTC cells transfected with each of the five targets. Simultaneously, 50†µl of supernatant was added to each well of five ELISA plates, each coated with individual proteins. Wells positive in either or both assays (A1 to H12) were then tested on each of the original plates (blue) to identify the plate number (deconvolution, 1A1 to 4H12). (B) Primary screen by ELISA using the cytoplasmic domain of Adam13/33 expressed in Hek293T cells (top) and his-tag bacterial fusion protein (bottom). The mice were immunized using the bacterial fusion protein. Highlighted wells are above the chosen background (0.2 for Hek293T and 0.5 for bacterial fusion protein). Wells highlighted in green are common to both ELISA and were selected for further screening.
	Figure 3. Manual clone picking. (A) Plates containing the hybridoma fusion were placed on a mirror to visualize large colonies. (B) Investigator pipetting a single colony guided by the mirror. (C) Photographs of the plate as seen in the mirror. (D) Higher magnification of four wells. Individual colonies are highlighted with red arrowheads.
	Figure 4. Secondary screening. (A) RNA-sequencing (RNA-Seq) expression data for Xenopus brachyury (tbxt) from Xenbase. No mRNA is detected for this gene at stage 1 (fertilized egg), but it is strongly expressed during gastrulation (stage 12). (B) Capillary western blot (0.04 embryo equivalent) at stage 1 and stage 12 for three independent hybridomas (8F8, 12H2, 5D11). Note that bands are visible only at stage 12. (C) Signal intensity of the chemiluminescence for clone 12H2 at stages 1 and 12. Note that a single peak is present in stage 12 (green), but not stage 1 (blue), but the background signal is similar. (D) Whole-mount immunofluorescence of a neurula stage embryo. Sox3 is in magenta, and DAPI (to stain nuclei) is in blue. MAb DA5H6sox3 detects the nuclei of cells within the neural plate. (E,F) Chemiluminescence signal (E) from a capillary western blot (F) of embryo extracts (0.04 embryo equivalent per lane) incubated with antibodies to Sox3 (green), Ribophorin1 (Rpn1, red) and the muscle marker 12101 (blue). Antibodies were incubated either separately (lanes 1-3) or together (lane 4).
	Figure 5. Immunostaining. (A) Whole-mount immunostaining using DA12H2xbra on bisected gastrula (Xbra/Tbxt). The dorsal side is to the left, and the animal pole is up. The antibody stains the nuclei in both the dorsal and ventral marginal zones (mesoderm). (B) Whole-mount immunostaining using a monoclonal antibody to Adam13/33 (DA8E6adam13) on embryos injected at the two-cell stage with a morpholino that blocks translation of Adam13. The cranial neural crest cells (black arrows) are visible on the non-injected (NI) side, but are absent on the injected side (MO13). (C) Immunofluorescence of a cranial neural crest explant using mAb DA1A8slug (green) and counterstained with DAPI (blue). Note that most of the nuclei are stained for Slug/Snai2 except for a small section on the left of the explant (dorsal) that is likely to be composed of neural plate cells
	Fig. S1. Western blot of embryos at blastula stage expressing myc-tag Xenopus Sox2 or Sox3. Left blot is using the myc 9E10 monoclonal antibody (Green) and anti actin for loading control (Red). The right blot is performed using the anti Sox3 antibody (DA5H6sox3, Green). Note that the upper band corresponding to Sox2 is not recognized by mAb DA5H6sox3.
	Fig. S2. Characterization of the Rpn1 antibody (Mono5, m5) by Immunofluorescence (Left, green) and Immunoprecipitation followed by Mass spectrometry (Right). The nuclei are labelled with (DAPI) and the actin cytoskeleton is in red (Phalloidin). The main protein pulled down by m5 not pulled down by another mAb (m4) is MGC52808 (ribophorin 1/Rpn1), an ER resident protein.

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