IgM single antigen bead HLA-assay is affected by imlifidase through the cleavage of IgG but not IgM.

AIM: The aim of this study was to investigate if human IgM is a cleavable substrate for imlifidase and to explain an observed effect in anti-HLA IgM single antigen bead (SAB) assays in sensitized patients. METHODS: Serum samples collected pre- and 24 h post-imlifidase administration from sensitized patients enrolled in a phase II trial were investigated for anti-HLA IgG and IgM using SAB assays, with and without in vitro IgG depletion using a CaptureSelect™ affinity matrix. In addition, pre-dose samples and purified human IgM samples were treated with imlifidase in vitro and evaluated by SDS-PAGE, Western blot (PE-conjugated anti-human IgM) and SAB (IgG, IgM) assays. RESULTS: By comparing the mean fluorescence intensity (MFI) of HLA-beads, pre- and post-imlifidase administration, three IgM-related patterns were observed; IgM-specific HLA-SABs with an increased MFI post-imlifidase, IgM-specific HLA-SABs with a decreased MFI post-imlifidase, and IgM-specific HLA-SABs with a marginal MFI difference between the pre- and post-imlifidase administration. These IgM signal patterns were observed despite neither purified IgM nor serum IgM could be cleaved by imlifidase. After removing IgG, the effects observed on anti-HLA IgM was largely eliminated with the biggest differences seen in patients with very high anti-HLA IgG in pre-dose samples. CONCLUSION: We demonstrate that imlifidase does not cleave human IgM, including HLA-specific IgM antibodies from highly sensitized subjects. Observed decreases of SAB-HLA IgM signals after imlifidase treatment may result from the cleavage of IgG-IgM complexes which are bound to SAB-HLA. Serum analysis of patients with high levels of anti-HLA IgG will result in a more accurate SAB-HLA IgM reading after IgG depletion.

Transcription factor binding site analysis identifies FOXO transcription factors as regulators of the cutaneous wound healing process.

The search for significantly overrepresented and co-occurring transcription factor binding sites in the promoter regions of the most differentially expressed genes in microarray data sets could be a powerful approach for finding key regulators of complex biological processes. To test this concept, two previously published independent data sets on wounded human epidermis were re-analyzed. The presence of co-occurring transcription factor binding sites for FOXO1, FOXO3 and FOXO4 in the majority of the promoter regions of the most significantly differentially expressed genes between non-wounded and wounded epidermis implied an important role for FOXO transcription factors during wound healing. Expression levels of FOXO transcription factors during wound healing in vivo in both human and mouse skin were analyzed and a decrease for all FOXOs in human wounded skin was observed, with FOXO3 having the highest expression level in non wounded skin. Impaired re-epithelialization was found in cultures of primary human keratinocytes expressing a constitutively active variant of FOXO3. Conversely knockdown of FOXO3 in keratinocytes had the opposite effect and in an in vivo mouse model with FOXO3 knockout mice we detected significantly accelerated wound healing. This article illustrates that the proposed approach is a viable method for identifying important regulators of complex biological processes using in vivo samples. FOXO3 has not previously been implicated as an important regulator of wound healing and its exact function in this process calls for further investigation.