Optimisation of a PC12 cell-based in vitro stroke model for screening neuroprotective agents

Stroke causes death and disability globally but no neuroprotectant is approved for post-stroke neuronal injury. Neuroprotective compounds can be identified using oxygen glucose deprivation (OGD) of neuronal cells as an in vitro stroke model. Nerve growth factor (NGF)-differentiated PC12 pheochromocytoma cells are frequently used. However, investigators often find their clonal variant undifferentiable and are uncertain of optimal culture conditions. Hence we studied 3 commonly used PC12 variants: PC12 Adh, PC12 from Riken Cell Bank (PC12 Riken) and Neuroscreen-1 (NS-1) cells. We found DMEM the optimal media for PC12 Riken and NS-1 cells. Using a novel serum-free media approach, we identified collagen IV as the preferred adhesive substrate for both cell lines. We found PC12 Adh cells cannot attach without serum and is unable to differentiate using NGF. NS-1 cells differentiated to a maximal 72.7 ± 5.2% %, with substantial basal differentiation. We optimised differentiated NS-1 cells for an in vitro stroke model using 3 h of OGD resulting in ~ 70% viable cells. We screened 5 reported neuroprotectants and provide the first report that serotonin is antiapoptotic in a stroke model and the 5-HT1A agonist 8-hydroxy-2-(di-n-propylamino) tetralin (8-OH-DPAT) is neuroprotective in PC12 cells. Thus we demonstrate the optimisation and validation for a PC12 cell-based in vitro stroke model.

Pseudomonas aeruginosa Elastase Contributes to the Establishment of Chronic Lung Colonization and Modulates the Immune Response in a Murine Model

Chronic infection by Pseudomonas aeruginosa in cystic fibrosis (CF) patients is a major contributor to progressive lung damage and is poorly treated by available antibiotic therapy. An alternative approach to the development of additional antibiotic treatments is to identify complementary therapies which target bacterial virulence factors necessary for the establishment and/or maintenance of the chronic infection. The P. aeruginosa elastase (LasB) has been suggested as an attractive anti-virulence target due to its extracellular location, its harmful degradative effects on host tissues and the immune system, and the potential to inhibit its activity using small molecule inhibitors. However, while the relevance of LasB in acute P. aeruginosa infection has been demonstrated, it is still unclear whether this elastase might also play a role in the early phase of chronic lung colonization. By analyzing clinical P. aeruginosa clonal isolates from a CF patient, we found that the isolate RP45, collected in the early phase of persistence, produces large amounts of active LasB, while its clonal variant RP73, collected after years of colonization, does not produce it. When a mouse model of persistent pneumonia was used, deletion of the lasB gene in RP45 resulted in a significant reduction in mean bacterial numbers and incidence of chronic lung colonization at Day 7 post-challenge compared to those mice infected with wild-type (wt) RP45. Furthermore, deletion of lasB in strain RP45 also resulted in an increase in immunomodulators associated with innate and adaptive immune responses in infected animals. In contrast, deletion of the lasB gene in RP73 did not affect the establishment of chronic infection. Overall, these results indicate that LasB contributes to the adaptation of P. aeruginosa to a persistent lifestyle. In addition, these findings support pharmacological inhibition of LasB as a potentially useful therapeutic intervention for P. aeruginosa-infected CF patients prior to the establishment of a chronic infection.

Effect of the Route of Administration of the Vaccinia Virus Strain LIVP to Mice on Its Virulence and Immunogenicity

The mass smallpox vaccination campaign has played a crucial role in smallpox eradication. Various strains of the vaccinia virus (VACV) were used as a live smallpox vaccine in different countries, their origin being unknown in most cases. The VACV strains differ in terms of pathogenicity exhibited upon inoculation of laboratory animals and reactogenicity exhibited upon vaccination of humans. Therefore, each generated strain or clonal variant of VACV needs to be thoroughly studied in in vivo systems. The clonal variant 14 of LIVP strain (LIVP-14) was the study object in this work. A comparative analysis of the virulence and immunogenicity of LIVP-14 inoculated intranasally (i.n.), intradermally (i.d.), or subcutaneously (s.c.) to BALB/c mice at doses of 108, 107, and 106 pfu was carried out. Adult mice exhibited the highest sensitivity to the i.n. administered LIVP-14 strain, although the infection was not lethal. The i.n. inoculated LIVP-14 replicated efficiently in the lungs. Furthermore, this virus was accumulated in the brain at relatively high concentrations. Significantly lower levels of LIVP-14 were detected in the liver, kidneys, and spleen of experimental animals. No clinical manifestations of the disease were observed after i.d. or s.c. injection of LIVP-14 to mice. After s.c. inoculation, the virus was detected only at the injection site, while it could disseminate to the liver and lungs when delivered via i.d. administration. A comparative analysis of the production of virus-specific antibodies by ELISA and PRNT revealed that the highest level of antibodies was induced in i.n. inoculated mice; a lower level of antibodies was observed after i.d. administration of the virus and the lowest level after s.c. injection. Even at the lowest studied dose (106 pfu), i.n. or i.d. administered LIVP-14 completely protected mice against infection with the cowpox virus at the lethal dose. Our findings imply that, according to the ratio between such characteristics as pathogenicity/immunogenicity/protectivity, i.d. injection is the optimal method of inoculation with the VACV LIVP-14 strain to ensure the safe formation of immune defense after vaccination against orthopoxviral infections.

A Phenotypic Characterization of Two Isolates of a Multidrug-Resistant Outbreak Strain of Mycobacterium tuberculosis with Opposite Epidemiological Fitness

Tuberculosis (TB) is an infectious disease, caused by Mycobacterium tuberculosis, primarily affecting the lungs. The M. tuberculosis strain of the Haarlem family named M was responsible for a large multidrug-resistant TB (MDR-TB) outbreak in Buenos Aires. This outbreak started in the early 1990s and in the mid 2000s still accounted for 29% of all MDR-TB cases in Argentina. By contrast, a clonal variant of strain M, named 410, has caused a single tuberculosis case since the onset of the outbreak. The molecular bases of the high epidemiological fitness of the M strain remain unclear. To assess its unique molecular properties, herein, we performed a comparative protein and lipid analysis of a representative clone of the M strain (Mp) and the nonprosperous M variant 410. We also evaluated their growth in low pH. The variant 410 had higher levels of latency proteins under standard conditions and delayed growth at low pH, suggesting that it is more sensitive to stress stimuli than Mp. Moreover, Mp showed higher levels of mycolic acids covalently attached to the cell wall and lower accumulation of free mycolic acids in the outer layer than the 410 strain. The low expression of latency proteins together with the reduced content of surface mycolic acids may facilitate Mp to evade the host immune responses.

Rapid Emergence of a New Clone Impacts the Population at Risk and Increases the Incidence of Type emm89 Group A Streptococcus Invasive Disease

Background Invasive group A Streptococcus (iGAS) disease caused by type emm89 strains has been increasing worldwide, driven by the emergence of an epidemic clonal variant (clade 3 emm89). The clinical characteristics of patients with emm89 iGAS disease, and in particular with clade 3 emm89 iGAS disease, are poorly described. Methods We used population-based iGAS surveillance data collected in metropolitan Toronto, Ontario, Canada during the period 2000–2014. We sequenced the genomes of 105 emm89 isolates representing all emm89 iGAS disease cases in the area during the period and 138 temporally matched emm89 iGAS isolates collected elsewhere in Ontario. Results Clades 1 and 2 and clade O, a newly discovered emm89 genetic variant, caused most cases of emm89 iGAS disease in metropolitan Toronto before 2008. After rapid emergence of new clade 3, previously circulating clades were purged from the population and the incidence of emm89 iGAS disease significantly increased from 0.14 per 100000 in 2000–2007 to 0.22 per 100000 in 2008–2014. Overall, emm89 organisms caused significantly more arthritis but less necrotizing fasciitis than strains of the more common type emm1. Other clinical presentations were soft tissue and severe respiratory tract infections. Clinical outcomes did not differ significantly between emm89 clades overall. However, clade 3 emm89 iGAS disease was more common in youth and middle-aged individuals. Conclusions The rapid shift in emm89 iGAS strain genetics in metropolitan Toronto has resulted in a significant increase in the incidence of emm89 iGAS disease, with noticeably higher rates of clade 3 disease in younger patients.

An Amplicon-Targeted Ultra-Deep Sequencing Approach Reveals the Presence at the Onset of Multiple Myeloma and the Selection over Time of TP53 Sub-Clonal Variants, Which Adversely Influence Patients' Overall Survival

INTRODUCTION In newly diagnosed Multiple Myeloma (MM) patients (pts), Copy Number (CN) losses of chromosome 17p13, carrying the TP53 tumor-suppressor gene, are strong predictors of poor outcomes. On the contrary, the prognostic relevance of TP53 mutations at the onset of the disease is less clear, due to the very limited frequency of clonal lesions, as revealed by Sanger sequencing. To address this poorly investigated issue, we used an ultra-deep sequencing (UDS) approach to characterize the TP53 structural architecture in both newly diagnosed and relapsed MM pts and to assess the prognostic role and evolution over time of small TP53 mutated sub-clones. SAMPLES AND METHODS A cohort of 99 newly diagnosed MM pts treated up-front with bortezomib-based regimens and autologous stem cell transplantation, was included in this molecular study. In 29 cases, samples were collected both at diagnosis and at relapse(s). DNA was obtained from CD138+ highly purified plasma cells. TP53 gene mutational status was analysed by using an amplicon-targeted UDS approach (GSJ, 454 Roche Life Sciences). In order to discriminate between low frequency sub-clonal TP53 variants and sequencing errors, sequencing raw data were filtered according to cut-off values based on different ranges of sequences' coverage depth. Additional filters were also applied, based on both quality and biological cut-offs, to obtain a final confident list of variants. Analysis of CN alterations (CNAs) was performed by SNPs array and results analysed with ChAS software. RESULTS With a median coverage of 1386X, a list of 129 correctly called TP53 variants (either missense, or nonsense or splice ones), including 20 INDELs, was detected. Only deleterious and N/A variants (according to SIFT classification) were included in the list. Most newly diagnosed MM pts (55%) carried at least one TP53 sub-clonal variant (on average 1.08 variants per pts), with 45/99 (45%) carrying non-mutated TP53. Pts carrying TP53 sub-clonal variants bared also TP53 CN hemizygous losses (20%), CKS1B gains (56%) and cdkn2c losses (14%). According to TP53 sub-clonal mutational load, pts were stratified in two sub-groups, including 28 pts with ≥2 (high load) and 71 with <2 variants (low load), respectively. Eleven out of 129 variants were recurrent (RVs), as being detected in at least 3% of pts, with Variants Allele Frequencies (VAFs) ranging from 0.24 to 70.1% (median 0,53%); RVs were observed in 29 pts. The clinical impact of the TP53 sub-clonal mutational load, as well as of variants recurrence, was evaluated in 90/99 MM (median follow up = 70 months). Results of statistical analysis are summarized in Table 1. Pts carrying either high TP53 sub-clonal mutational load or RVs had significantly shorter OS and OS after relapse, as compared to the others, while no difference between these two groups was seen regarding PFS and TTP. Multivariate analysis showed that high TP53 mutational load, as well as the presence of TP53 RVs, both resulted independent factors adversely affecting OS and OS after relapse (Table 2). Of note, none of the detected genomic aberrations significantly influenced the response to front-line induction therapy. The distribution of both TP53 sub-clonal variants and genomic CNAs was overall modified in samples collected at relapse(s): 90% of relapsed pts carried at least one sub-clonal variant (on average 1.63 variants per pts) with 3/29 (10%) relapsed MM carrying non-mutated TP53. Moreover, 5 different sub-clonal lesions proved a linear increment of both TP53 VAFs (from 29.4% to 54.6%; from 7.8% to 12.4%; from 0.5% to 4.3%) and TP53 CN loss smooth signal (from 7% to 89% and from 50% to 100%), as evaluated in longitudinally collected samples. CONCLUSIONS The UDS analysis of TP53 coding sequence in newly diagnosed MM highlighted for the first time a high rate of variants, recurring with a wide range of frequencies among samples. The increased number of TP53 sub-clonal variants per pts in samples collected at relapse(s), compared to that seen at the onset of the disease, suggests a sub-clonal dynamics over time. This finding might explain the adverse impact of high TP53 sub-clonal mutational load and TP53 RVs on OS, due to a shorter OS after relapse. Acknowledgments: Roche Diagnostics for applicationsupport in the realization of this project. Disclosures Zamagni: Celgene Corporation: Honoraria, Speakers Bureau; Janssen Pharmaceuticals: Honoraria, Speakers Bureau; Amgen: Honoraria, Speakers Bureau. Martinelli:Novartis: Consultancy, Speakers Bureau; BMS: Consultancy, Speakers Bureau; Ariad: Consultancy; AMGEN: Consultancy; ROCHE: Consultancy; Pfizer: Consultancy; MSD: Consultancy. Cavo:Janssen-Cilag, Celgene, Amgen, BMS: Honoraria.

Characterization of a Multigene Family Undergoing High-Frequency DNA Rearrangements and Coding for Abundant Variable Surface Proteins in Mycoplasma agalactiae

ABSTRACT A family of abundant surface proteins (Vpmas [variable proteins ofMycoplasma agalactiae]) undergoing phase variation inM. agalactiae has been characterized using monoclonal antibodies and specific polyclonal sera. Two expressed members of 39 kDa (Vpma39) and 34 kDa (Vpma34), which varied in expression between clones of a lineage, shared a common amino-terminal sequence but were immunologically distinct. An amino-terminal oligonucleotide probe identified multiple vpma genes which were clustered within a 14-kb ClaI genomic fragment. Rearrangements were found to have occurred within the vpma locus between clones which correlated with changes in their Vpma phenotype. Two neighboringvpma genes were cloned and sequenced from one M. agalactiae clonal variant expressing Vpma39. The two genes,vpmaX and vpmaY, were orientated divergently and shared highly homologous 5′ untranslated regions, 25-amino-acid (aa) lipoprotein leader sequences, and amino-terminal sequences. ThevpmaY gene coded for 346 aa and 84% of the open reading frame, comprised of 1.5 units of a large repeat of 186 aa. Although the sequence for an entire second vpmaY repeat was present, it was prematurely terminated by insertion of two nucleotides. ThevpmaX gene encoded 221 aa and possessed 102 aa of the 186-aa repeat of vpmaY. Many of the features in common between the vpma genes were also found to be shared by thevsp genes of M. bovis, which also undergo DNA rearrangements concomitant with phenotypic changes. Since M. bovis is the closest phylogenetic relative to M. agalactiae, the vpma and vsp gene families most probably represent homologous systems.