A Vellucci

Human T cell lymphotropic virus type 1 (HTLV-1) infection can lead to development of adult T cell leukemia/lymphoma (ATL) or HTLV-1-associated myelopathy/tropical spastic paraparesis (HAM/TSP) in a subset of infected subjects. Understanding the interaction between host and HTLV-1 and the molecular mechanisms associated with disease pathogenesis is critical for development efficient therapies. Two HTLV-1 genes, tax and HTLV-1 basic leucine zipper factor (HBZ), have been demonstrated to play important roles in HTLV-1 infectivity and the growth and survival of leukemic cells. Increased HTLV-1 Tax expression induces the expression of various cellular genes such as IL-2 and IL-15, which directly contributes to lymphocyte activation and immunopathogenesis in HAM/TSP patients. However, little is known about the molecular and cellular mechanism of HBZ in development of HAM/TSP. It has been reported that HBZ mRNA expression was detected in HAM/TSP patients higher than in asymptomatic carriers and correlated with proviral load and disease severity. Unlike HTLV-1 tax, HBZ escapes efficient antiviral immune responses and therefore these reactivities are difficult to detect. Thus, it is important to focus on understanding the function and the role of HTLV-1 tax and HBZ in disease development of HAM/TSP and discuss the potential use of these HTLV-1 viral gene products as biomarkers and therapeutic targets for HAM/TSP.

Objective Previous work measures spinal cord thinning in chronic progressive myelopathies, including human T‐lymphotropic virus 1 (HTLV‐1)‐associated myelopathy/tropical spastic paraparesis (HAM/TSP) and multiple sclerosis (MS). Quantitative measurements of spinal cord atrophy are important in fully characterizing these and other spinal cord diseases. We aimed to investigate patterns of spinal cord atrophy and correlations with clinical markers. Methods Spinal cord cross‐sectional area was measured in individuals (24 healthy controls [HCs], 17 asymptomatic carriers of HTLV‐1 (AC), 47 HAM/TSP, 74 relapsing‐remitting MS [RRMS], 17 secondary progressive MS [SPMS], and 40 primary progressive MS [PPMS]) from C1 to T10. Clinical disability scores, viral markers, and immunological parameters were obtained for patients and correlated with representative spinal cord cross‐sectional area regions at the C2 to C3, C4 to C5, and T4 to T9 levels. In 2 HAM/TSP patients, spinal cord cross‐sectional area was measured over 3 years. Results All spinal cord regions are thinner in HAM/TSP (56 mm 2 [standard deviation, 10], 59 [10], 23 [5]) than in HC (76 [7], 83 [8], 38 [4]) and AC (71 [7], 78 [9], 36 [7]). SPMS (62 [9], 66 [9], 32 [6]) and PPMS (65 [11], 68 [10], 35 [7]) have thinner cervical cords than HC and RRMS (73 [9], 77 [10], 37 [6]). Clinical disability scores (Expanded Disability Status Scale [ p = 0.009] and Instituto de Pesquisas de Cananeia [ p = 0.03]) and CD8 + T‐cell frequency ( p = 0.04) correlate with T4 to T9 spinal cord cross‐sectional area in HAM/TSP. Higher cerebrospinal fluid HTLV‐1 proviral load ( p = 0.01) was associated with thinner spinal cord cross‐sectional area. Both HAM/TSP patients followed longitudinally showed thoracic thinning followed by cervical thinning. Interpretation Group average spinal cord cross‐sectional area in HAM/TSP and progressive MS show spinal cord atrophy. We further hypothesize in HAM/TSP that is possible that neuroglial loss from a thoracic inflammatory process results in anterograde and retrograde degeneration of axons, leading to the temporal progression of thoracic to cervical atrophy described here. Ann Neurol 2017;82:719–728.

Intrathecal antibody synthesis is a well-documented phenomenon in infectious neurological diseases as well as in demyelinating diseases, but little is known about the role of B cells in the central nervous systems. We examined B cell and T cell immunophenotypes in CSF of patients with HTLV-1-associated myelopathy/tropical spastic paraparesis (HAM/TSP) compared to healthy normal donors and subjects with the other chronic virus infection and/or neuroinflammatory diseases including HIV infection, multiple sclerosis (MS) and progressive multifocal leukoencephalopathy. Antibody secreting B cells (ASCs) were elevated in HAM/TSP patients, which was significantly correlated with intrathecal HTLV-1-specific antibody responses. High frequency of ASCs was also detected in patients with relapsing-remitting multiple sclerosis (RRMS). While RRMS patients showed significant correlations between ASCs and memory follicular helper CD4+ T cells, CD4+CD25+ T cells were elevated in HAM/TSP patients, which were significantly correlated with ASCs and HTLV-1 proviral load. These results highlight the importance of the B cell compartment and the associated inflammatory milieu in HAM/TSP patients where virus-specific antibody production may be required to control viral persistence and/or may be associated with disease development.

Abstract Objective Human T‐cell lymphotropic virus 1 (HTLV‐1)‐associated myelopathy/tropical spastic paraparesis (HAM/TSP) is a chronic, progressive myelopathy. A high proviral load (PVL) is one of the main risk factors for HAM/TSP. Recently, it was shown that raltegravir could inhibit cell‐free and cell‐to‐cell transmission of HTLV‐1 in vitro. Given the substantial clinical experience in human immunodeficiency virus infection and its excellent safety profile, this agent may be an attractive therapeutic option for HAM/TSP patients. Methods Sixteen subjects with HAM/TSP received raltegravir 400 mg orally twice daily in an initial 6‐month treatment phase, followed by a 9‐month post‐treatment phase. HTLV‐1 PVLs were assessed using droplet digital PCR from the PBMCs every 3 months, and from the CSF at baseline, month 6, and month 15. We also evaluated the ability of raltegravir to regulate abnormal immune responses in HAM/TSP patients. Results While a downward trend was observed in PBMC and/or CSF PVLs of some patients, raltegravir overall did not have any impact on the PVL in this HAM/TSP patient cohort. Clinically, all patients’ neurological scores and objective measurements remained relatively stable, with some expected variability. Immunologic studies showed alterations in the immune profiles of a subset of patients including decreased CD4 + CD25 + T cells and spontaneous lymphoproliferation. Interpretation Raltegravir was generally well tolerated in this HAM/TSP patient cohort. A subset of patients exhibited a mild decrease in PVL as well as variations in their immune profiles after taking raltegravir. These findings suggest that raltegravir may be a therapeutic option in select HAM/TSP patients. Clinical Trial Registration Number NCT01867320.