T-follicular regulatory cells expand to control germinal center plasma cell output but fail to curb autoreactivity.

Autoantibodies generated in germinal centers (GCs) contribute to the pathogenesis of autoimmune diseases. GCs are controlled by specialized FoxP3+ T-follicular regulatory cells (Tfr), but their role in established autoimmunity is unclear. We generated autoimmune bone marrow chimeras in which Tfr could be specifically ablated by diphtheria toxin. Furthermore, we tracked the clonal persistence and evolution of Tfr populations using Confetti reporters. Ablation of Tfr caused increased early plasma cell output, but longer-term ablation did not increase plasma cell levels beyond those of Tfr-sufficient controls, suggesting that Tfr fail to contain chronic autoreactive GC responses. In agreement, Tfr were robustly induced in early autoreactive GCs but then waned. Moreover, we observed polyclonal Tfr expansion when ablating part of the Tfr subset. Hence, under homeostatic conditions, a polyclonal population of Tfr operates to control autoreactivity by limiting the output of plasma cells from GCs, but in chronic autoimmunity, this mechanism fails.

Cell-targeted gene modification by delivery of CRISPR-Cas9 ribonucleoprotein complexes in pseudotyped lentivirus-derived nanoparticles.

To fully utilize the potential of CRISPR-Cas9-mediated genome editing, time-restricted and targeted delivery is crucial. By modulating the pseudotype of engineered lentivirus-derived nanoparticles (LVNPs), we demonstrate efficient cell-targeted delivery of Cas9/single guide RNA (sgRNA) ribonucleoprotein (RNP) complexes, supporting gene modification in a defined subset of cells in mixed cell populations. LVNPs pseudotyped with severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) spike protein resulted in angiotensin-converting enzyme 2 (ACE2)-dependent insertion or deletion (indel) formation in an ACE2+/ACE2- population of cells, whereas Nipah virus glycoprotein pseudotyping resulted in Ephrin-B2/B3-specific gene knockout. Additionally, LVNPs pseudotyped with Edmonston strain measles virus glycoproteins (MV-H/F) delivered Cas9/sgRNA RNPs to CD46+ cells with and without additional expression of SLAM (signaling lymphocytic activation molecule; CD150). However, an engineered SLAM-specific measles virus pseudotype (measles virus-hemagglutinin/fusion [MV-H/F]-SLAM) efficiently targeted LVNPs to SLAM+ cells. Lentiviral vectors (LVs) pseudotyped with MV-H/F-SLAM efficiently transduced >80% of interleukin (IL)-4/IL-21-stimulated primary B cells cultured on CD40 ligand (CD40L)-expressing feeder cells. Notably, LVNPs pseudotyped with MV-H/F and MV-H/F-SLAM reached indel rates of >80% and >60% in stimulated primary B cells, respectively. Collectively, our findings demonstrate the modularity of LVNP-directed delivery of ready-to-function Cas9/sgRNA complexes. Using a panel of different pseudotypes, we provide evidence that LVNPs can be engineered to induce effective indel formation in a subpopulation of cells defined by the expression of surface receptors.

Antigen footprint governs activation of the B cell receptor.

Antigen binding by B cell receptors (BCR) on cognate B cells elicits a response that eventually leads to production of antibodies. However, it is unclear what the distribution of BCRs is on the naïve B cell and how antigen binding triggers the first step in BCR signaling. Using DNA-PAINT super-resolution microscopy, we find that most BCRs are present as monomers, dimers, or loosely associated clusters on resting B cells, with a nearest-neighbor inter-Fab distance of 20-30 nm. We leverage a Holliday junction nanoscaffold to engineer monodisperse model antigens with precision-controlled affinity and valency, and find that the antigen exerts agonistic effects on the BCR as a function of increasing affinity and avidity. Monovalent macromolecular antigens can activate the BCR at high concentrations, whereas micromolecular antigens cannot, demonstrating that antigen binding does not directly drive activation. Based on this, we propose a BCR activation model determined by the antigen footprint.

Increased maternofoetal transfer of antibodies in a murine model of systemic lupus erythematosus, but no immune activation and neuroimmune sequelae in offspring.

Maternally transferred autoantibodies can negatively impact the development and health of offspring, increasing the risk of neurodevelopmental disorders. We used embryo transfers to examine maternofoetal immune imprinting in the autoimmune BXSB/MpJ mouse model. Anti-double-stranded DNA antibodies and total immunoglobulins were measured, using allotypes of the IgG subclass to distinguish maternally transferred antibodies from those produced endogenously. Frequencies of germinal center and plasma cells were analysed by flow cytometry. Microglial morphology in offspring CNS was assessed using immunohistochemistry. In contrast to prior findings, our results indicate that BXSB/MpJ mothers display a mild autoimmune phenotype, which does not significantly impact the offspring.

Comparison of gamma and x-ray irradiation for myeloablation and establishment of normal and autoimmune syngeneic bone marrow chimeras.

Murine bone marrow (BM) chimeras are a versatile and valuable research tool in stem cell and immunology research. Engraftment of donor BM requires myeloablative conditioning of recipients. The most common method used for mice is ionizing radiation, and Cesium-137 gamma irradiators have been preferred. However, radioactive sources are being out-phased worldwide due to safety concerns, and are most commonly replaced by X-ray sources, creating a need to compare these sources regarding efficiency and potential side effects. Prior research has proven both methods capable of efficiently ablating BM cells and splenocytes in mice, but with moderate differences in resultant donor chimerism across tissues. Here, we compared Cesium-137 to 350 keV X-ray irradiation with respect to immune reconstitution, assaying complete, syngeneic BM chimeras and a mixed chimera model of autoimmune disease. Based on dose titration, we find that both gamma and X-ray irradiation can facilitate a near-complete donor chimerism. Mice subjected to 13 Gy Cesium-137 irradiation and reconstituted with syngeneic donor marrow were viable and displayed high donor chimerism, whereas X-ray irradiated mice all succumbed at 13 Gy. However, a similar degree of chimerism as that obtained following 13 Gy gamma irradiation could be achieved by 11 Gy X-ray irradiation, about 85% relative to the gamma dose. In the mixed chimera model of autoimmune disease, we found that a similar autoimmune phenotype could be achieved irrespective of irradiation source used. It is thus possible to compare data generated, regardless of the irradiation source, but every setup and application likely needs individual optimization.