The innate immunity adaptor SARM translocates to the nucleus to stabilize lamins and prevent DNA fragmentation in response to pro-apoptotic signaling.

Sterile alpha and armadillo-motif containing protein (SARM), a highly conserved and structurally unique member of the MyD88 family of Toll-like receptor adaptors, plays an important role in innate immunity signaling and apoptosis. Its exact mechanism of intracellular action remains unclear. Apoptosis is an ancient and ubiquitous process of programmed cell death that results in disruption of the nuclear lamina and, ultimately, dismantling of the nucleus. In addition to supporting the nuclear membrane, lamins serve important roles in chromatin organization, epigenetic regulation, transcription, nuclear transport, and mitosis. Mutations and other damage that destabilize nuclear lamins (laminopathies) underlie a number of intractable human diseases. Here, we report that SARM translocates to the nucleus of human embryonic kidney cells by using its amino-terminal Armadillo repeat region. Within the nucleus, SARM forms a previously unreported lattice akin to the nuclear lamina scaffold. Moreover, we show that SARM protects lamins from apoptotic degradation and reduces internucleosomal DNA fragmentation in response to signaling induced by the proinflammatory cytokine Tumor Necrosis Factor alpha. These findings indicate an important link between the innate immunity adaptor SARM and stabilization of nuclear lamins during inflammation-driven apoptosis in human cells.

Flow cytometric evaluation of adhesion of Streptococcus pyogenes to epithelial cells.

The precise roles of various surface molecules in the attachment of Streptococcus pyogenes to host epithelia are currently unclear. A flow cytometry assay that facilitates the analysis of the kinetics of S. pyogenes adhesion to epithelial cells was developed. Dose- and time-dependent adhesion isotherms with both buccal epithelial cells (BECs) and Hep-2 cells as substrata were obtained. Although binding equilibrium is reached within 2 h on both cell types, saturation of binding sites on BECs is not achieved within a wide range of experimental conditions. This indicates a high degree of non-specific attachment to that cell type. Since no rinsing step is necessary when using flow cytometry to analyze adhesion, low-affinity associations were observable. This was confirmed by determining bacterial desorption rates early and late in the adsorption process. Binding irregularities were also easily detected since the cytometer records and displays data for up to 10,000 epithelial cells per time point. It is proposed to use this methodology to assign roles to particular surface molecules/characteristics during distinct phases of adhesion.