Optimizing anisotropic transport on bioinspired sawtooth surfaces.

Species ranging from butterflies and other insects, to cactuses and lotus plants have evolved to use geometrically patterned surfaces to influence the transport of water droplets. While this phenomenon is well known, an ideal geometry has yet to be discovered. To determine the impact of surface geometry on droplet transport, we have studied the contact angle and droplet motion across anisotropically wetting patterned surfaces. The surface geometries tested were sawtooth patterns with angles (8.62-26.70°) and lengths (0.56-1.67 µm). The droplet contact angles were measured on 45° angled surfaces to simulate the droplet in motion. Velocities were measured using a high-speed camera shooting at 500 frames per second and the tailing edges of the droplets were hand tracked over 18 frames. It was found that travel along the sawtooth ridges is significantly faster than travel against the ridges for geometries with shallow angles. The optimal geometry was determined to be α = 8.62° and b = 1.67 µm and was replicated using nanoimprint lithography using materials with different surface energies. When replicated with acrylate resins and PDMS, the contact angles remained high, regardless of wettability, but we find that the overall velocity and velocity hysteresis depends on the hydrophobicity. More hydrophobic surfaces have overall higher hysteresis. The ability to tune imprinted surfaces to achieve ideal wetting characteristics using geometry will lead to interesting anisotropic material design.

Systematic computer-aided disulfide design as a general strategy to stabilize prefusion class I fusion proteins.

Numerous enveloped viruses, such as coronaviruses, influenza, and respiratory syncytial virus (RSV), utilize class I fusion proteins for cell entry. During this process, the proteins transition from a prefusion to a postfusion state, undergoing substantial and irreversible conformational changes. The prefusion conformation has repeatedly shown significant potential in vaccine development. However, the instability of this state poses challenges for its practical application in vaccines. While non-native disulfides have been effective in maintaining the prefusion structure, identifying stabilizing disulfide bonds remains an intricated task. Here, we present a general computational approach to systematically identify prefusion-stabilizing disulfides. Our method assesses the geometric constraints of disulfide bonds and introduces a ranking system to estimate their potential in stabilizing the prefusion conformation. We found, for the RSV F protein, that disulfides restricting the initial stages of the conformational switch can offer higher stability to the prefusion state than those preventing unfolding at a later stage. The implementation of our algorithm on the RSV F protein led to the discovery of prefusion-stabilizing disulfides, providing evidence that supports our hypothesis. Furthermore, the evaluation of our top design as a vaccine candidate in a cotton rat model demonstrated robust protection against RSV infection, highlighting the potential of our approach for vaccine development.

Human Metapneumovirus (hMPV) Infection and MPV467 Treatment in Immunocompromised Cotton Rats Sigmodon hispidus.

Human metapneumovirus (hMPV) is an important cause of respiratory disease in immunocompromised individuals, yet hMPV infection has not been modeled before in immunocompromised animals. In this work, cotton rats S. hispidus immunosuppressed by cyclophosphamide were infected with hMPV, and viral replication and pulmonary inflammation in these animals were compared to those in normal hMPV-infected S. hispidus. The efficacy of prophylactic and therapeutic administration of the anti-hMPV antibody MPV467 was also evaluated. Immunosuppressed animals had higher pulmonary and nasal titers of hMPV on day 5 post-infection compared to normal animals, and large amounts of hMPV were still present in the respiratory tract of immunosuppressed animals on days 7 and 9 post-infection, indicating prolonged viral replication. Immunosuppression was accompanied by reduced pulmonary histopathology in hMPV-infected cotton rats compared to normal animals; however, a delayed increase in pathology and pulmonary chemokine expression was seen in immunosuppressed cotton rats. Prophylactic and therapeutic MPV467 treatments protected both upper and lower respiratory tracts against hMPV infection. The lung pathology and pulmonary expression of IP-10 and MIP-1α mRNA were reduced by therapeutic MPV467 administration. These results indicate that immunosuppressed cotton rats represent a useful model for studying hMPV pathogenesis and for evaluating therapeutics that could alleviate hMPV-induced disease in immunocompromised subjects.

Assessing Extracellular Vesicles in Human Biofluids Using Flow-Based Analyzers.

Extracellular vesicles (EVs) are increasingly being analyzed by flow cytometry. Yet their minuscule size and low refractive index cause the scatter intensity of most EVs to fall below the detection limit of most flow cytometers. A new class of devices, known as spectral flow analyzers, are becoming standards in cell phenotyping studies, largely due to their unique capacity to detect a vast panel of markers with higher sensitivity for light scatter detection. Another class of devices, known as nano-analyzers, provides high-resolution detection of sub-micron-sized particles. Here, the EV phenotyping performance between the Aurora (Cytek) spectral cell analyzer and the NanoFCM (nFCM) nanoflow analyzer are compared. These two devices are specifically chosen given their lead in becoming gold standards in their respective fields. Immune cell-derived EVs remain poorly characterized despite their clinical potential. Therefore, B- and T-cell line-derived EVs and donor-matched human biofluid-derived EVs from plasma, urine, and saliva are used in combination with a panel of established immune markers for this comparative study. A comparative evaluation of both cytometry platforms is performed, discussing their potential and suitability for different applications. It is found that nFCM can accurately i) analyze small EVs (40-200 nm) matching the size accuracy of electron microscopy; ii) measure the concentration of a single EV particle per volume; iii) identify underrepresented EV marker subsets; and iv) provide co-localization of EV surface markers. It can also be shown that human sample biofluids have unique EV marker signatures that can have future clinical relevance. Finally, nFCM and Aurora have their unique strength, preferred fashion of data acquisition, and visualization to fit different research interests.

Serum extracellular vesicles profiling is associated with COVID-19 progression and immune responses.

Coronavirus disease 2019 (COVID-19) has transformed very quickly into a world pandemic with severe and unexpected consequences on human health. Concerted efforts to generate better diagnostic and prognostic tools have been ongoing. Research, thus far, has primarily focused on the virus itself or the direct immune response to it. Here, we propose extracellular vesicles (EVs) from serum liquid biopsies as a new and unique modality to unify diagnostic and prognostic tools for COVID-19 analyses. EVs are a novel player in intercellular signalling particularly influencing immune responses. We herein show that innate and adaptive immune EVs profiling, together with SARS-CoV-2 Spike S1+ EVs provide a novel signature for SARS-CoV-2 infection. It also provides a unique ability to associate the co-existence of viral and host cell signatures to monitor affected tissues and severity of the disease progression. And provide a phenotypic insight into COVID-associated EVs.

Nonsustained Ventricular Tachycardia Is Independently Associated With Sustained Ventricular Arrhythmias in Nonischemic Dilated Cardiomyopathy.

BACKGROUND: Spontaneous nonsustained ventricular tachycardia (NSVT) on Holter, VT inducibility during electrophysiology study, and late gadolinium enhancement (LGE) on cardiac magnetic resonance (CMR) have been associated with sustained ventricular arrhythmias (SVAs) in nonischemic dilated cardiomyopathy (DCM). This study aimed to analyze whether these parameters carry independent prognostic value for spontaneous SVA in DCM. METHODS: Between 2011 and 2018, patients with the DCM clinical spectrum and documented SVA, suspected SVA, or considered to be at intermediate or high risk for SVA were enrolled in the prospective Leiden Nonischemic Cardiomyopathy Study. Patients underwent a comprehensive evaluation including 24-hour Holter, LGE-CMR, and electrophysiology study. Holters were assessed for the presence of NSVT (≥3 beats; rate, ≥120 bpm; lasting <30 s) and NSVT characteristics (coupling interval, duration, cycle length, morphology, regularity). Patients were followed at 6 to 12 monthly intervals. RESULTS: Of all 115 patients (age, 59±12 years; 77% men; left ventricular ejection fraction, 33±13%; history of SVA, 36%; LGE in 63%; median LGE mass, 13 g; interquartile range, 8-23 g), 62 (54%) had NSVT on Holter, and sustained monomorphic VT was inducible in 34 of 114 patients (30%). NSVT was not associated with LGE on CMR or VT inducibility during electrophysiology study nor were its features (all P>0.05). During 4.0±1.8 years of follow-up, SVA occurred in 39 patients (34%). NSVT (HR, 4.47 [95% CI, 1.87-10.72]; P=0.001) and VT inducibility (HR, 3.08 [95% CI, 1.08-8.81]; P=0.036) were independently associated with SVA during follow-up. A bivariable model including only noninvasively acquired parameters also allowed identification of a high-risk subgroup (ie, those with both NSVT and LGE on CMR). The findings remained similar when only patients without prior SVA were included. CONCLUSIONS: In patients with DCM, NSVT on Holter and VT inducibility during electrophysiology study predict SVA during follow-up independent of LGE on CMR. NSVTs may serve as an initiator, and sustained VT inducibility indicates the presence of the substrate for SVA in DCM. Registration: URL: https://www.clinicaltrials.gov; Unique identifier: NCT01940081.

Human herpes simplex viruses in benign and malignant thyroid tumours.

To test the hypothesis that herpes viruses may have a role in thyroid neoplasia, we analysed thyroid tissues from patients with benign (44) and malignant (65) lesions for HSV1 and HSV2 DNA. Confirmatory studies included direct sequencing, analysis of viral gene expression, and activation of viral-inducible signalling pathways. Expression of viral entry receptor nectin-1 was examined in human samples and in cancer cell lines. In vitro experiments were performed to explore the molecular mechanisms underlying thyroid cancer cell susceptibility to HSV. HSV DNA was detected in 43/109 (39.4%) examined samples. HSV capsid protein expression correlated with HSV DNA status. HSV-positive tumours were characterized by activation of virus-inducible signalling such as interferon-beta expression and nuclear NFkappaB expression. Lymphocyte infiltration and oncocytic cellular features were common in HSV-positive tumours. HSV1 was detected with the same frequency in benign and malignant thyroid tumours. HSV2 was significantly associated with papillary thyroid cancer and the presence of lymph node metastases. The expression of HSV entry receptor nectin-1 was increased in thyroid tumours compared to normal thyroid tissue and further increased in papillary thyroid cancer. Nectin-1 expression was detected in all examined thyroid cancer cell lines. Nectin-1 expression in cancer cells correlated with their susceptibility to HSV. Inhibition of PI3K/AKT or MAPK/ERK signalling did not affect the level of nectin-1 expression but decreased thyroid cancer cell susceptibility to HSV. These findings showed that HSV is frequently detected in thyroid cancer. During tumour progression, thyroid cells acquire increased susceptibility to HSV due to increased expression of viral entry mediator nectin-1 and activation of mitogenic signalling in cancer cells.

Single Cell Label-Free Probing of Chromatin Dynamics During B Lymphocyte Maturation.

Large-scale intracellular signaling during developmental growth or in response to environmental alterations are largely orchestrated by chromatin within the cell nuclei. Chemical and conformational modifications of the chromatin architecture are critical steps in the regulation of differential gene expression and ultimately cell fate determination. Therefore, establishing chemical properties of the nucleus could provide key markers for phenotypic characterization of cellular processes on a scale of individual cells. Raman microscopy is a sensitive technique that is capable of probing single cell chemical composition-and sub-cellular regions-in a label-free optical manner. As such, it has great potential in both clinical and basic research. However, perceived limitations of Raman spectroscopy such as low signal intensity and the difficulty in linking alterations in vibrational signals directly with ensuing biological effects have hampered advances in the field. Here we use immune B lymphocyte development as a model to assess chromatin and transcriptional changes using confocal Raman microscopy in combination with microfluidic devices and correlative transcriptomics, thereby linking changes in chemical and structural properties to biological outcomes. Live B lymphocytes were assessed before and after maturation. Multivariate analysis was applied to distinguish cellular components within each cell. The spectral differences between non-activated and activated B lymphocytes were then identified, and their correlation with known intracellular biological changes were assessed in comparison to conventional RNA-seq analysis. Our data shows that spectral analysis provides a powerful tool to study gene activation that can complement conventional molecular biology techniques and opens the way for mapping the dynamics in the biochemical makeup of individual cells.

Epicutaneous immunization using synthetic virus-like particles efficiently boosts protective immunity to respiratory syncytial virus.

Despite the substantial health and economic burden caused by RSV-associated illness, no vaccine is available. The sole licensed treatment (palivizumab), composed of a monoclonal neutralizing antibody, blocks the fusion of the virus to the host cell but does not prevent infection. The development of a safe and efficacious RSV vaccine is therefore a priority, but also a considerable challenge, and new innovative strategies are warranted. Most of the adult population encounter regular RSV infections and can elicit a robust neutralizing antibody response, but unfortunately it wanes over time and reinfections during subsequent seasons are common. One approach to protect the mother and young infant from RSV infection is to administer a vaccine capable of boosting preexisting RSV immunity during pregnancy, which would provide protection to the fetus through passive transfer of maternal antibodies, thus preventing primary RSV infection in newborns during their first months of life. Here, we describe the preclinical evaluation of an epicutaneous RSV vaccine booster that combines epicutaneous patches as a delivery platform and a Synthetic Virus-Like Particles (SVLP)-based vaccine displaying multiple RSV F-protein site II (FsII, palivizumab epitope) mimetic as antigen (V-306). We demonstrated in mice that epicutaneous immunization with V-306 efficiently boosts preexisting immunity induced by the homologous V-306 administered subcutaneously. This boosting was characterized by a significant increase in F- and FsII-specific antibodies capable of competing with palivizumab for its target antigen and neutralize RSV. More importantly, epicutaneous booster immunization with V-306 significantly decreased lung viral replication in experimental mice after intranasal RSV challenge, without inducing enhanced RSV disease. In conclusion, an epicutaneous booster vaccine based on V-306 is safe and efficacious in enhancing RSV preexisting immunity in mice. This needle-free vaccine candidate would be potentially suited as a booster vaccine for vulnerable populations such as young infants via pregnant women, and the elderly.

Neurovirulence and latency of drug-resistant clinical herpes simplex viruses in animal models.

Herpes simplex virus (HSV) resistance to acyclovir or foscarnet results from mutations in viral thymidine kinase (TK) and/or DNA polymerase (pol) genes. Replication kinetics and virulence of TK and/or DNA pol clinical mutants were assessed using models of mouse encephalitis and cotton rat genital infection. Replication capacities in Vero cells of a DNA pol altered strain (L850I) and a TK/DNA pol mutant (C467deletion/A912V) were significantly lower than those of unrelated wild-type (WT) strains, while a double DNA pol mutant (S724N/P920S) demonstrated replication kinetics similar to the WT. The replication of a TK-deficient mutant (G439.5addition) was impaired (low m.o.i.) or unaltered (high m.o.i.) compared to that of a WT virus depending on the viral inoculum. Compared to a survival rate of 6% for mice infected intranasally with WT HSV-1 or -2 viruses, G439.5add, C467deletion/A912V and L850I strains were associated with survival rates of 100% (P < 0.05) whereas mice infected with the S724N/P920S mutant had a survival rate of 33% (P = 0.08). Brain viral titers were higher in mice infected with WT HSV-1 or -2 strains and the double DNA pol mutant. All strains except the DNA pol mutant L850I were able to establish latency in the dorsal root ganglia of cotton rats. A good correlation was generally found between replication kinetics of DNA pol mutants and their neurovirulence potential in mice whereas such correlation was not straightforward for TK mutants.

Extracellular Vesicles Orchestrate Immune and Tumor Interaction Networks.

Extracellular vesicles (EVs) are emerging as potent and intricate intercellular communication networks. From their first discovery almost forty years ago, several studies have bolstered our understanding of these nano-vesicular structures. EV subpopulations are now characterized by differences in size, surface markers, cargo, and biological effects. Studies have highlighted the importance of EVs in biology and intercellular communication, particularly during immune and tumor interactions. These responses can be equally mediated at the proteomic and epigenomic levels through surface markers or nucleic acid cargo signaling, respectively. Following the exponential growth of EV studies in recent years, we herein synthesize new aspects of the emerging immune-tumor EV-based intercellular communications. We also discuss the potential role of EVs in fundamental immunological processes under physiological conditions, viral infections, and tumorigenic conditions. Finally, we provide insights on the future prospects of immune-tumor EVs and suggest potential avenues for the use of EVs in diagnostics and therapeutics.

The American cotton rat: a novel model for pulmonary tuberculosis.

Several animal models are used to study Mycobacterium tuberculosis (MTB) infections, but none is a fully ideal model of human disease. The American cotton rat is an excellent model for the study of several human viral and bacterial respiratory infectious diseases, but until now has not been reported to be a model with MTB infection. Preliminary experiments were designed in which two species of cotton rats (Sigmodon hispidus and Sigmodon fulviventer) received respiratory challenges with M. tuberculosis via either intranasal or aerosol inoculation. Granulomatous disease, often with central necrosis, developed in the lungs, spleen, and lymph nodes of infected animals. The number of MTB bacilli in the lungs increased logarithmically until reaching a plateau in the second month after aerosol inoculation. There were differences in response to infection between the two species, with S. fulviventer demonstrating greater mortality than S. hispidus. Cytokine gene expression analysis by reverse transcriptase polymerase chain reaction (RT-PCR) was performed on both normal appearing and granulomatous lung tissue from infected animals. Many cytokine genes were more highly expressed in the focal areas of inflammation. Cotton rats provide another valuable tool in future research with tuberculosis.

Evaluation of the potential effects of AS03-adjuvanted A(H1N1)pdm09 vaccine administration on the central nervous system of non-primed and A(H1N1)pdm09-primed cotton rats.

An increased risk of narcolepsy following administration of an AS03-adjuvanted A(H1N1)pdm09 pandemic influenza vaccine (Pandemrix™) was described in children and adolescents in certain European countries. We investigated the potential effects of administration of the AS03-adjuvanted vaccine, non-adjuvanted vaccine antigen and AS03 Adjuvant System alone, on the central nervous system (CNS) in one-month-old cotton rats. Naïve or A(H1N1)pdm09 virus-primed animals received 2 or 3 intramuscular injections, respectively, of test article or saline at 2-week intervals. Parameters related to systemic inflammation (hematology, serum IL-6/IFN-γ/TNF-α) were assessed. Potential effects on the CNS were investigated by histopathological evaluation of brain sections stained with hematoxylin-and-eosin, or by immunohistochemical staining of microglia, using Iba1 and CD68 as markers for microglia identification/activation, albumin as indicator of vascular leakage, and hypocretin. We also determined cerebrospinal fluid (CSF) hypocretin levels and hemagglutination-inhibiting antibody titers. Immunogenicity of the AS03-adjuvanted A(H1N1)pdm09 pandemic influenza vaccine was confirmed by the induction of hemagglutination-inhibiting antibodies. Both AS03-adjuvanted vaccine and AS03 alone activated transient innate (neutrophils/eosinophils) immune responses. No serum cytokines were detected. CNS analyses revealed neither microglia activation nor inflammatory cellular infiltrates in the brain. No differences between treatment groups were detected for albumin extravascular leakage, CSF hypocretin levels, numbers of hypocretin-positive neuronal bodies or distributions of hypocretin-positive axonal/dendritic projections. Consequently, there was no evidence that intramuscular administration of the test articles promoted inflammation or damage in the CNS, or blood-brain barrier disruption, in this model.

Development of an intradermal DNA vaccine delivery strategy to achieve single-dose immunity against respiratory syncytial virus.

Respiratory syncytial virus (RSV) is a massive medical burden in infants, children and the elderly worldwide, and an effective, safe RSV vaccine remains an unmet need. Here we assess a novel vaccination strategy based on the intradermal delivery of a SynCon® DNA-based vaccine encoding engineered RSV-F antigen using a surface electroporation device (SEP) to target epidermal cells, in clinically relevant experimental models. We demonstrate the ability of this strategy to elicit robust immune responses. Importantly we demonstrate complete resistance to pulmonary infection at a single low dose of vaccine in the cotton rat RSV/A challenge model. In contrast to the formalin-inactivated RSV (FI-RSV) vaccine, there was no enhanced lung inflammation upon virus challenge after DNA vaccination. In summary the data presented outline the pre-clinical development of a highly efficacious, tolerable and safe non-replicating vaccine delivery strategy.

Efficacy of trivalent inactivated influenza vaccines in the cotton rat Sigmodon hispidus model.

Annually adjusted inactivated influenza vaccines can prevent infection and limit the spread of seasonal influenza when vaccine strain closely matches circulating strain. For the years when the match is difficult to achieve, a rapid screening of a larger repertoire of vaccines may be required but is difficult to accomplish due to the lack of a convenient small animal model of seasonal influenza vaccines. The goal of this work was to determine whether the cotton rat Sigmodon hispidus, a small laboratory animal susceptible to infection with unadapted influenza viruses, may become such a model. Cotton rats were immunized with a trivalent inactivated vaccine (TIV) FluLaval (2006/2007) and vaccine immunogenicity and antiviral efficacy was evaluated against the homologous H1N1 and a heterologous H3N2 challenge. FluLaval induced a strong virus-specific IgG and neutralizing antibody response against homologous virus, elicited sterilizing immunity in the lungs and significantly reduced viral replication in the nose of infected animals. FluLaval was efficacious in cotton rats as either a single-time or a double immunization, although higher level of protection of the upper respiratory tract was achieved following two doses of vaccine. Antibodies against a heterologous influenza strain were induced in FluLaval-vaccinated animals, but vaccine lacked antiviral efficacy and did not reduce replication of a heterologous virus. Similarity of these findings to human TIV data suggests that the cotton rat may prove to be a reliable small animal model of human influenza vaccines.

Chronic helminth infection does not exacerbate Mycobacterium tuberculosis infection.

BACKGROUND: Chronic helminth infections induce a Th2 immune shift and establish an immunoregulatory milieu. As both of these responses can suppress Th1 immunity, which is necessary for control of Mycobacterium tuberculosis (MTB) infection, we hypothesized that chronic helminth infections may exacerbate the course of MTB. METHODOLOGY/PRINCIPAL FINDINGS: Co-infection studies were conducted in cotton rats as they are the natural host for the filarial nematode Litomosoides sigmodontis and are an excellent model for human MTB. Immunogical responses, histological studies, and quantitative mycobacterial cultures were assessed two months after MTB challenge in cotton rats with and without chronic L. sigmodontis infection. Spleen cell proliferation and interferon gamma production in response to purified protein derivative were similar between co-infected and MTB-only infected animals. In contrast to our hypothesis, MTB loads and occurrence and size of lung granulomas were not increased in co-infected animals. CONCLUSIONS/SIGNIFICANCE: These findings suggest that chronic filaria infections do not exacerbate MTB infection in the cotton rat model. While these results suggest that filaria eradication programs may not facilitate MTB control, they indicate that it may be possible to develop worm-derived therapies for autoimmune diseases that do not substantially increase the risk for infections.

The anti-tumor agent, 5,6-dimethylxanthenone-4-acetic acid (DMXAA), induces IFN-beta-mediated antiviral activity in vitro and in vivo.

The 2009 outbreak of pandemic H1N1 influenza, increased drug resistance, and the significant delay in obtaining adequate numbers of vaccine doses have heightened awareness of the need to develop new antiviral drugs that can be used prophylactically or therapeutically. Previously, we showed that the experimental anti-tumor drug DMXAA potently induced IFN-ß but relatively low TNF-α expression in vitro. This study confirms these findings in vivo and demonstrates further that DMXAA induces potent antiviral activity in vitro and in vivo. In vitro, DMXAA protected RAW 264.7 macrophage-like cells from VSV-induced cytotoxicity and moreover, inhibited replication of influenza, including the Tamiflu®-resistant H1N1 influenza A/Br strain, in MDCK cells. In vivo, DMXAA protected WT C57BL/6J but not IFN-ß(-/-) mice from lethality induced by the mouse-adapted H1N1 PR8 influenza strain when administered before or after infection. Protection was accompanied by mitigation of weight loss, increased IFN-ß mRNA and protein levels in the lung, and significant inhibition of viral replication in vivo early after DMXAA treatment. Collectively, this study provides data to support the use of DMXAA as a novel antiviral agent.

Methods for monitoring dynamics of pulmonary RSV replication by viral culture and by real-time reverse transcription-PCR in vivo: Detection of abortive viral replication.

Viral infection is normally detected either by viral culture or by PCR methods. Rarely is a combination of the two techniques used in the same study. Yet, when applied simultaneously, viral culture and PCR may reveal important features of viral biology, such as an abortive replication, as in the case of respiratory syncytial virus (RSV) infection. In this unit, we describe methods for detecting abortive RSV replication in a cotton rat model by using the plaque-forming unit assay and the real-time reverse-transcription PCR (qRT-PCR) assay. All steps of the process of monitoring viral replication in vivo are described, starting from the design of animal infection protocols. We continue on to the methods for extracting and processing lung samples for viral culture and RNA extraction, and finish with the actual methods of viral titration by the qRT-PCR and the plaque-forming unit assays.

Characterization of late tuberculosis infection in Sigmodon hispidus.

We previously described primary tuberculosis in Sigmodon hispidus cotton rats up to 6 months following a pulmonary challenge. At that time, we observed fewer animals demonstrating disease as time from exposure progressed. We hypothesized that some cotton rats may control a primary infection to latency in a similar fashion to humans. The current experiment was designed to examine the natural progression of disease in S. hispidus at a later timepoint following a respiratory challenge with Mycobacterium tuberculosis (Mtb). An additional objective was to test whether cotton rats may become latently infected, and to determine whether latent disease might be activated by cyclophosphamide induced immune suppression. Thirty-four percent of the inoculated cotton rats died prior to 9 months following the challenge. However, 50% of immunocompetent animals surviving past 9 months demonstrated positive lung tissue cultures for Mtb without histologic evidence of disease. None of the immunosuppressed animals demonstrated this pattern. These findings are consistent with the development of latent tuberculosis infection in some cotton rats. Furthermore, it appears reactivation of disease occurs with cyclophosphamide induced immunosuppression. Cotton rats may serve as a model for latent as well as active tuberculosis infection.

Age-related differences in pulmonary cytokine response to respiratory syncytial virus infection: modulation by anti-inflammatory and antiviral treatment.

BACKGROUND: Respiratory syncytial virus (RSV) is the major cause of severe lower respiratory tract infection in infants and young children. Recently, RSV has also been recognized as a serious health risk in elderly individuals, but the pathogenesis of RSV infection in elderly individuals remains unknown. METHODS: Dynamics of pulmonary cytokine response (including interferon- gamma , interleukin [IL]-4, IL-10, IL-6, monocyte chemoattractant protein-1, and growth-regulated oncogene [GRO] mRNA) during acute RSV infection were investigated in young (<2 months old) and aged (>9 months old) cotton rats (Sigmodon hispidus). Therapeutic treatments that diminish viral replication (antiviral antibody) and pulmonary inflammation (anti-inflammatory corticosteroid) in RSV-infected cotton rats were used to evaluate the contribution of virus replication and inflammation to the development of RSV disease with respect to age. RESULTS: The time of the peak expression of the majority of cytokines was shifted with respect to age. Antiviral and anti-inflammatory treatments had a similar effect on cytokine expression in aged and young cotton rats. GRO mRNA transcripts were more abundant in the lungs of aged cotton rats. CONCLUSIONS: The present study reports an age-related delay in the pulmonary cytokine response to RSV and an imbalance in chemokine production with respect to age and underscores different components of RSV pathogenesis with respect to their molecular signature.