Immunological consequences of cladribine treatment in multiple sclerosis: A real-world study.

BACKGROUND: Cladribine is a synthetic deoxyadenosine analogue approved for the treatment of highly active relapsing multiple sclerosis (RMS). Cladribine is considered to be a semi-selective immune-reconstitution therapy (IRT) that induces long-term remission following short course of treatment. Here, we evaluated the effect of cladribine on immune cell reduction and reconstitution during the first two years of treatment. METHODS: We analyzed our longitudinal, prospective, real-world cohort of 80 cladribine-treated RMS patients from two tertiary centers in Germany. Laboratory testing was conducted monthly and included evaluation of cellular as well as soluble parameters. Laboratory outcomes were correlated with infectious adverse events (AEs) and clinical or paraclinical disease activity. RESULTS: Selective alterations in immune cell populations occurred following cladribine treatment, with the most marked effects observed in year two of treatment. Specifically, a rapid reduction in CD56+ natural killer cells (nadir: month 1 (year 1) and 14 (year 2); -37 and -41% from baseline) was followed by a greater reduction in CD19+ B cells (nadir: month 2 and 14; -81 and -82%); a moderate effect on CD4+ (nadir: month 3 and 15; -48 and -61%) and CD8+ T cells (nadir: month 5 and 18; -40 and -48%). Despite the marked effect on B cells, immunoglobulin levels were unaffected. There was no or minimal effect on thrombocytes and innate immune cells. Clinical and paraclinical disease activity was unrelated to the observed immune alterations. Lymphopenia was the most commonly observed AE (86.3% of patients; grade III-IV lymphopenia: 38.8%). The cumulative incidence of infections was 55% with cladribine treatment, which were mostly mild or moderate. In total, 19 herpes infections developed in 8 (10%) cladribine-treated patients; all cases were dermatomal and 94.7% of the herpetic infections occurred during a period of lymphopenia. CONCLUSIONS: The immunophenotyping data obtained in our real-world setting are comparable to those demonstrated in pivotal clinical trials and provide further evidence that cladribine may represent a form of IRT. However, regarding the side-effect profile of cladribine, severe lymphopenia (exceeding grade II CTCAE) was more frequent, which may have prompted the development of herpes infections. Of note, lymphocyte dynamics did not correlate with clinical and paraclinical measures of disease activity in the two-year follow-up period.

Natural Killer Cells Are Present in Rag1-/- Mice and Promote Tissue Damage During the Acute Phase of Ischemic Stroke.

Rag1-/- mice, lacking functional B and T cells, have been extensively used as an adoptive transfer model to evaluate neuroinflammation in stroke research. However, it remains unknown whether natural killer (NK) cell development and functions are altered in Rag1-/- mice as well. This connection has been rarely discussed in previous studies but might have important implications for data interpretation. In contrast, the NOD-Rag1nullIL2rgnull (NRG) mouse model is devoid of NK cells and might therefore eliminate this potential shortcoming. Here, we compare immune-cell frequencies as well as phenotype and effector functions of NK cells in Rag1-/- and wildtype (WT) mice using flow cytometry and functional in vitro assays. Further, we investigate the effect of Rag1-/- NK cells in the transient middle cerebral artery occlusion (tMCAO) model using antibody-mediated depletion of NK cells and adoptive transfer to NRG mice in vivo. NK cells in Rag1-/- were comparable in number and function to those in WT mice. Rag1-/- mice treated with an anti-NK1.1 antibody developed significantly smaller infarctions and improved behavioral scores. Correspondingly, NRG mice supplemented with NK cells were more susceptible to tMCAO, developing infarctions and neurological deficits similar to Rag1-/- controls. Our results indicate that NK cells from Rag1-/- mice are fully functional and should therefore be considered in the interpretation of immune-cell transfer models in experimental stroke. Fortunately, we identified the NRG mice, as a potentially better-suited transfer model to characterize individual cell subset-mediated neuroinflammation in stroke.

Neutrophil granulocytes promote flow stagnation due to dynamic capillary stalls following experimental stroke.

Flow stagnation of peri-ischemic capillaries due to dynamic leukocyte stalls has been described to be a contributor to ongoing penumbral injury in transient brain ischemia, but has not been investigated in permanent experimental stroke so far. Moreover, it is discussed that obstructing neutrophils are involved in this process; however, their contribution has not yet been proven. Here, we characterize the dynamics of neutrophil granulocytes in two models of permanent stroke (photothrombosis and permanent middle cerebral artery occlusion) using intravital two-photon fluorescence microscopy. Different to previous studies on LysM-eGFP+ cells we additionally apply a transgenic mouse model with tdTomato-expressing neutrophils to avoid interference from additional immune cell subsets. We identify repetitively occurring capillary stalls of varying duration promoted by neutrophils in both models of permanent cerebral ischemia, validating the suitability of our new transgenic mouse model in determining neutrophil occlusion formation in vivo. Flow cytometric analysis of peripheral blood (PB) and brain tissue from mice subjected to photothrombosis reveal an increase in the total proportion of neutrophils, with selective upregulation of endothelial adherence markers in the PB. In conclusion, the dynamic microcirculatory stall phenomenon that is described after transient ischemia followed by reperfusion also occurs after permanent small- or large-vessel stroke and is clearly attributable to neutrophils.