Multiple sclerosis (MS) has been considered a putative T cell mediated autoimmune disease. However, it is becoming increasingly clear that its pathology is far more complicated and is characterized by both an inflammatory component as well as a neurodegenerative process 1. To date, the relationship between inflammation and the neurodegeneration in MS is unclear. Nevertheless, it is currently thought that potential new treatments should ideally have anti-inflammatory as well as neuroprotective properties 2.

Numerous models of autoimmune diseases including experimental autoimmune encephalomyelitis (EAE), diabetes in nonobese mice, thyroiditis, and adjuvant arthritis have been shown to be worsened by castration of male animals 345678. Furthermore, testosterone treatment ameliorates EAE 9. These protective effects are thought to be mediated by testosterone's immunomodulatory properties such as decreasing the production of pro-inflammatory cytokines TNFα and IL-1β by macrophages 10 and monocytes 11 as well as increasing production of the anti-inflammatory cytokine IL-10 by T cells 12.

In addition, evidence supporting a neuroprotective effect of testosterone has been found in a variety of neurological diseases as well as in the cognitive decline associated with normal aging 13. Testosterone is converted to estrogen in the brain by aromatase, and the neuroprotective properties of testosterone treatment in vivo may be due at least in part to this conversion. However, several in vitro studies have shown that testosterone can also be more directly neuroprotective 14. Testosterone has been shown to protect spinal cord neurons in culture from glutamate-mediated toxicity, as well as to induce neuronal differentiation and increase neurite outgrowth 15. Testosterone treatment also protected cultured neurons against beta-amyloid toxicity induced cell death 16.

While CNS infiltrating immune cells were once thought to always be deleterious, it has since been established that they have the potential to be beneficial under certain conditions, since neurotrophic factors have been detected in peripheral blood mononuclear cells (PBMCs) 17. Indeed, production of the neurotrophic factors BDNF and NT-3 by immune cells has been shown to accompany better recovery from spinal cord injury 18, and the production of neurotrophic factors by immune cells has been hypothesized as a potential means of neuroprotection in MS 19.

Recently, a pilot clinical trial using testosterone to treat 10 male MS patients was completed 20. In these patients, cognitive function improved and the brain atrophy rate was significantly slowed. Here, immunomodulatory effects of testosterone treatment as well as its ability to induce neurotrophic growth factor production in PBMCs were examined in these patients to explore a potential novel pathway underlying testosterone's beneficial effects.

Testosterone treatment significantly decreased CD4 T cell populations (average decrease 17%, p = .03) while increasing NK cell populations (average increase 64%, p = .03, Figure 1A). Furthermore, DTH recall responses were significantly decreased during treatment compared to pre-treatment values (mean millimeters induration pre-treatment 11.2 ± 2.3; treatment 6.5 ± 1.8, p = .03, Figure 1B).

Regarding effects of testosterone treatment on cytokine levels, there was a significant decrease in IL-2 production during the treatment period as compared to pretreatment baseline (p < .001, Figure 1C). Average decreases in IL-2 were -34% for CD3/CD28 and -58% for PHA stimulation. In contrast, a significant increase was observed in TGFβ1 levels (p < .0001, Figure 1D) with average increases of 167% for CD3/CD28 and 179% over baseline for PHA stimulations. No significant changes were observed in other cytokines (IFNγ, TNFα, IL-10, IL-17, IL-12p40) tested.

Testosterone treatment significantly increased levels of growth factors in supernatants of ex vivo stimulated PBMCs. Specifically, BDNF levels in PBMC supernatants revealed average increases of over 9 fold at treatment month 12, as compared to pretreatment baseline, for CD3/CD28 stimulation, and almost 11 fold for PHA stimulation, (p < .0001, Figure 1E). Highly significant increases in PDGF-BB production were also observed during testosterone treatment, with PDGF-BB levels increasing approximately 3.5 fold during both CD3/CD28 and PHA stimulation conditions (p < .0001, Figure 1F). No significant changes were observed in other growth factors (NGF, CNTF) tested.

Correlation coefficients of cytokine and growth factor changes with functional and clinical outcomes were computed as an exploratory analysis. The increases in BDNF, PDGF-BB and TGFβ1 production were significantly correlated (TGFβ1 and BDNF r = .72; TGFβ1 and PDGF-BB, r = .89; BDNF and PDGF-BB, r = .91). There was a moderate (but not significant) correlation between TGFβ1 and IL-2 changes (r = .48). Interestingly, there was a positive association between the decrease in CD4+ cells and decreased responses in the DTH skin test (r = .59) that showed a statistical trend (p = .07). However, changes in IL-2 did not significantly correlate with either CD4+ percentage or DTH. As reported previously 20, testosterone treatment in our study increased cognitive function as measured by the Paced Auditory Serial Addition Task (PASAT). Percent increases in BDNF (r = .74, p = .01) and PDGF-BB (r = .73, p = .02) from baseline to month 12 of treatment were significantly associated with improvements in PASAT testing during the same time. However, the associations with the PASAT were driven by the two strongest responders in growth factors who also had the strongest improvement in cognitive function and should thus be interpreted with caution.

Next, we aimed to determine whether levels of BDNF, PDGF-BB, and TGFβ1, which were induced by in vivo testosterone treatment, were functionally significant. Glutamate excitotoxicity is a widely used model for neurotoxicity and is thought to contribute to neurodegeneration observed in MS 23. Thus, to test the biological significance of growth factor levels produced by immune cells during treatment, neuronal cultures were exposed to 2 h of 1 mM glutamate in the presence or absence of recombinant growth factors similar to the levels seen in the best treatment responder at month 12 (2000 pg/ml TGFβ1, 500 pg/ml BDNF, 100 pg/ml PDGF-BB). Brightfield microscopy images indicated that addition of growth factors induced partial protection of axonal integrity in those cultures (black arrows) and decreased the number of TUNEL positive cells (white triangles, Figure 2A–C). LDH quantification showed that the addition of growth factors during glutamate exposure significantly reduced LDH release from neuronal cultures, in line with a neuroprotective effect (p = .04, Figure 2D).

Our data suggest that testosterone treatment in MS is associated with effects on markers that could play a role in the inflammatory as well as the neurodegenerative component of the disease. A decrease in DTH responses, decreased IL-2 and increased TGFβ1 production suggest an anti-inflammatory effect. This was accompanied by a decrease in CD4+ cells and an increase in NK cells. Based on our current understanding of MS pathogenesis, CD4+ autoreactive T cells and their differentiation into a Th1 phenotype are crucial events in disease development, and these cells are probably also important players in the long-term evolution of the disease 24, while NK cells have been suggested to play a regulatory role by killing myelin-specific T cells and immature dendritic cells, promoting regulatory T cells and enhancing Th2-like responses 25.

Both IL-2 and TGFβ1 have been proposed as treatment targets in MS. Blocking the IL-2α receptor chain with the monoclonal antibody daclizumab has been shown to decrease active lesions on MRI 26. Interestingly, daclizumab treatment is also accompanied by a decrease in CD4+ T cells, as well as an increase in a subpopulation of NK cells numbers 27, consistent with our results on alterations in lymphocyte subpopulations during testosterone treatment.

The role of TGFβ1 in the immune system is complex as it can affect multiple cell lineages, either promoting or opposing their differentiation, survival, and proliferation. However, TGFβ1 appears to be a critical modulator of T cell-mediated self-reactivity 28 and has been successfully used to treat EAE 29. Unfortunately, a clinical trial of TGFβ2 administration in secondary-progressive MS had to be stopped due to nephrotoxicity of the recombinant cytokine 30.

In addition to these immunomodulatory effects, we saw significant increases in growth factor production by PBMCs. Neuroprotective effects of testosterone treatment have been described using both in vitro cultures and in vivo models. Since testosterone is lipophilic, in vivo effects of systemic testosterone treatment are thought to be mediated by testosterone crossing the blood brain barrier. In the CNS, testosterone may bind androgen receptors or may be converted by aromatase to estrogen, with estrogen known to have neuroprotective properties 31. Here, we describe a novel potential neuroprotective pathway of testosterone treatment, namely through the induction of BDNF, PDGF-BB, and TGFβ1 by peripheral blood immune cells.

This is relevant to MS since neurotrophic factors such as BDNF have been detected in infiltrating immune cells in CNS lesions in both experimental autoimmune encephalomyelitis (EAE) 32 and MS 33 and it has been suggested that the immune cell-mediated import of BDNF and other neurotrophic factors into the central nervous system has the functional relevance of curbing the detrimental effects of inflammation on the surrounding tissue 19. Supporting the clinical relevance of this phenomenon, an increase in BDNF production by PBMCs during relapse was previously only observed in patients who achieved full recovery, while patients with incomplete recovery demonstrated no alterations in BDNF production 34. In addition, a recent study has shown correlations of BDNF production by peripheral immune cells with MRI-based measures of disease severity. Lower BDNF production was associated with lower Magnetic Transfer Ratio (MTR) in normal appearing white matter, suggesting more white matter damage in patients with lower BDNF production 35.

The neuroprotective effects in vivo and in vitro of BDNF are well known 36. PDGF-BB has also been shown to be neuroprotective in vitro 37 and in vivo 38. It is interesting to note that TGFβ1, in addition to its anti-inflammatory effects, also protected neurons from glutamate toxicity in vitro and in vivo 39. Supporting the protective potential of growth factors produced by PBMCs in our study, we found that a combination of recombinant growth factors at similar concentrations as seen at month 12 of treatment could reduce glutamate-induced neurotoxicity in vitro. In this regard, it is intriguing that when the subjects in our study were assessed for MRI and clinical outcomes, a slowing in brain atrophy and an increase in cognitive function was observed during testosterone treatment as compared to baseline 20.

Previously, clinical trials using neurotrophic factors have been disappointing in neurodegenerative diseases despite promising results from pre-clinical studies 40. The negative results of these clinical trials have highlighted that the manner and site of administration are of critical importance. Similarly, anti-inflammatory strategies in MS using monoclonal antibodies or recombinant cytokines have been associated with either partial efficacy or significant toxicities.

In contrast, treatment with physiological levels of testosterone is safe and appears to orchestrate simultaneous alterations in multiple growth factors and cytokines with the delivery system being the subjects' own peripheral blood immune cells. This immunomodulatory and potential neuroprotective pathway warrants further study in MS and other neurodegenerative diseases, which contain an inflammatory component, namely Alzheimer's Disease, Parkinson's disease and spinal cord injury 41.

BDNF: Brain-derived neurotrophic factor; CNTF: Ciliary neurotrophic factor; DTH: Delayed type hypersensitivity; EAE: Experimental autoimmune encephalomyelitis; EDSS: Expanded disability status scale; IL: Interleukin; LDH: Lactate Dehydrogenase; MRI: Magnetic resonance imaging; MS: Multiple sclerosis; NGF: Nerve growth factor; NK cell: Natural killer cell; NT-3: Neurotrophin 3; PASAT: Paced Auditory Serial Addition Task; PBMCs: Peripheral blood mononuclear cells; PDGF: Platelet-derived growth factor; PHA: Phytohemagglutinin; RRMS: Relapsing-remitting MS; TGF: Transforming growth factor; TNF: Tumor necrosis factor.

The authors declare that they have no competing interests.

SMG contributed to study design and concept, acquired the immunological data, performed the neurotoxicity assay, and was responsible for analysis, interpretation and preparation of the manuscript. SC contributed to the neurotoxicity assay and critically revised the manuscript. BSG was responsible for patient assessment and acquisition of the clinical data and critically revised the manuscript. RRV obtained funding, was responsible for study design and concept and contributed to interpretation and preparation of the manuscript. All authors have read and approved the final manuscript.