Evaluating Soluble EMMPRIN as a Marker of Disease Activity in Multiple Sclerosis: Studies of Serum and Cerebrospinal Fluid.

Extracellular matrix metalloproteinase inducer (EMMPRIN, CD147) is an inducer of matrix metalloproteinases and has roles in leukocyte activation and migration. We reported previously that in MS and its animal model, experimental autoimmune encephalomyelitis, cell surface-associated EMMPRIN was significantly elevated in leukocytes around inflammatory perivascular cuffs in the CNS. In this study we report that activated T-cells can secrete soluble form of EMMPRIN (sEMMPRIN) upon activation. As sEMMPRIN is also present in biological fluids, we determined whether sEMMPRIN is altered in the CSF and sera of MS subjects. Sera from individuals without neurological conditions served as controls, while CSFs collected from subjects undergoing discectomy, and without evidence of CNS pathology, were used as a comparator group. We found that serum levels of sEMMPRIN from clinically stable MS patients or other inflammatory conditions did not differ from control subjects. Paired serum and CSF samples demonstrated poor correlation of sEMMPRIN. Interestingly, sEMMPRIN levels were approximately 60% higher in CSFs compared to sera. sEMMPRIN CSF levels were significantly higher in secondary progressive compared to primary progressive subjects. Thus we conclude that measurement of sEMMPRIN in serum is not informative for disease activity in MS. The differential expression of sEMMPRIN in the CSF of primary and secondary progressive MS invites hypotheses of the still undefined roles of EMMPRIN in the CNS.

Impact of Minocycline on Extracellular Matrix Metalloproteinase Inducer, a Factor Implicated in Multiple Sclerosis Immunopathogenesis.

Extracellular matrix metalloproteinase inducer (EMMPRIN, CD147) is a transmembrane glycoprotein that is upregulated on leukocytes in active lesions in multiple sclerosis (MS) and its animal model, experimental autoimmune encephalomyelitis (EAE). Administration of anti-EMMPRIN Abs reduces the severity of EAE. Minocycline is a tetracycline antibiotic with immune-modulatory properties that decreases the severity of EAE; it was recently found to attenuate the conversion from a first demyelinating event to clinically definite MS in a phase III trial. We investigated whether and how minocycline affects the expression of EMMPRIN on T cells in culture and in mice afflicted with EAE. EMMPRIN expression in cultures of mouse splenocytes or human PBMCs was elevated upon polyclonal T cell activation, and this was reduced by minocycline correspondent with decreased P-Akt levels. An established MS medication, IFN-ß, also diminished EMMPRIN levels on human cells whereas this was not readily observed for fingolimod or monomethylfumarate. In EAE-afflicted mice, minocycline treatment significantly reduced EMMPRIN levels on splenic lymphocytes at the presymptomatic (day 7) phase, and prevented the development of disease. Day 7 spleen transcripts from minocycline-treated EAE mice had a significantly lower MMP-9/TIMP-1 ratio, and significantly lower MCT-1 and CD98 levels, factors associated with EMMPRIN function. Day 16 (peak clinical severity) CNS samples from EAE mice had prominent representation of inflammatory perivascular cuffs, inflammatory molecules and EMMPRIN, and these were abrogated by minocycline. Overall, minocycline attenuated the activation-induced elevation of EMMPRIN on T cells in culture and in EAE mice, correspondent with reduced immune function and EAE CNS pathology.

Substitution for Asn460 cripples ß-galactosidase (Escherichia coli) by increasing substrate affinity and decreasing transition state stability.

Substrate initially binds to ß-galactosidase (Escherichia coli) at a 'shallow' site. It then moves ∼3Å to a 'deep' site and the transition state forms. Asn460 interacts in both sites, forming a water bridge interaction with the O3 hydroxyl of the galactosyl moiety in the shallow site and a direct H-bond with the O2 hydroxyl of the transition state in the deep site. Structural and kinetic studies were done with ß-galactosidases with substitutions for Asn460. The substituted enzymes have enhanced substrate affinity in the shallow site indicating lower E·substrate complex energy levels. They have poor transition state stabilization in the deep site that is manifested by increased energy levels of the E·transition state complexes. These changes in stability result in increased activation energies and lower k(cat) values. Substrate affinity to N460D-ß-galactosidase was enhanced through greater binding enthalpy (stronger H-bonds through the bridging water) while better affinity to N460T-ß-galactosidase occurred because of greater binding entropy. The transition states are less stable with N460S- and N460T-ß-galactosidase because of the weakening or loss of the important bond to the O2 hydroxyl of the transition state. For N460D-ß-galactosidase, the transition state is less stable due to an increased entropy penalty.

Absence of the cellular prion protein exacerbates and prolongs neuroinflammation in experimental autoimmune encephalomyelitis.

Although the physiological roles of the cellular prion protein (PrP C) remain to be fully elucidated, PrP C has been proposed to represent a potential regulator of cellular immunity. To test this hypothesis, we evaluated the consequences of PrP C deficiency on the course of experimental autoimmune encephalomyelitis induced by immunization with myelin oligodendrocyte glycoprotein peptide. Consistent with augmented proliferative responses and increased cytokine gene expression by myelin oligodendrocyte glycoprotein-primed Prnp-/- T cells, PrP C-deficient mice demonstrated more aggressive disease onset and a lack of clinical improvement during the chronic phase of experimental autoimmune encephalomyelitis. Acutely, Prnp-/- spinal cord, cerebellum, and forebrain exhibited higher levels of leukocytic infiltrates and pro-inflammatory cytokine gene expression, as well as increased spinal cord myelin basic protein and axonal loss. During the chronic phase, a remarkable persistence of leukocytic infiltrates was present in the forebrain and cerebellum, accompanied by an increase in interferon-gamma and interleukin-17 transcripts. Attenuation of T cell-dependent neuroinflammation thus represents a potential novel function of PrP C.

Mgmt deficiency alters the in vivo mutational spectrum of tissues exposed to the tobacco carcinogen 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK).

It has been proposed that O(6)-methylguanine DNA methyltransferase (MGMT) gene silencing in premalignant lesions and cancers of the lung might result in the acquisition of a 'mutator' phenotype. Previously, however, we found that Mgmt(-/-) mouse DNA failed to show an increase in spontaneous mutations. We thus hypothesized that only during exposure to specific environmental carcinogens would the consequences of MGMT deficiency become evident. Metabolism of the tobacco-derived nitrosamine, 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) generates alkylating species that can react with the O(6) position of deoxyguanine, thereby yielding substrates for MGMT-mediated repair. To investigate how MGMT might regulate the mutational effects of NNK, Mgmt(-/-) mice were crossed with a lacI-based transgenic reporter line (Big Blue) thus enabling an assessment of the in vivo mutagenic effects of this agent. We observed the induction of a complex spectrum of NNK-dependent lacI mutations in both control and Mgmt(-/-) tissues, but only a trend in the mutant frequency increases that could be attributed to MGMT deficiency. The mutational spectra of NNK-treated Mgmt(-/-) lungs revealed an increase in the absolute number of G:C to A:T changes accompanied by a shift in these from CpG to GpG sites, consistent with an S(N)1 alkylation mechanism. In keeping with the high levels of MGMT expressed in the liver, more pronounced mutagenic effects and greater differences in O(6) position of deoxyguanosine adduct levels following NNK were observed in Mgmt(-/-) versus wild-type mice. Extrapolating to humans, MGMT-deficient cells would likely exhibit an increased mutational burden, but only following exposures to specific environmental mutagens such as NNK.