Valerie Taylor

TREM‐1 promotes survival during septic shock in mice

Triggering receptor expressed on myeloid (TREM)‐1 is integral to the inflammatory response occurring during septic shock, although its precise function has yet to be determined. Here we show that in vivo silencing of TREM‐1 using siRNA duplexes in a fecal peritonitis mouse model resulted in a blunted inflammatory response and increased mortality. This was associated with impaired bacterial clearance related to marked inhibition of the neutrophil oxidative burst. By contrast, TREM‐1‐silenced mice were highly resistant to a lethal endotoxin challenge, while partial silencing of TREM‐1 in the bacterial peritonitis model produced a significant survival benefit. These data highlight the crucial role of the TREM‐1 pathway in mounting an adequate inflammatory and cytotoxic response to polymicrobial sepsis, and both the therapeutic promise and potential risks of its modulation.

Succinate recovers mitochondrial oxygen consumption in septic rat skeletal muscle

Objective:Mitochondrial dysfunction, particularly affecting complex I of the respiratory chain, could play a fundamental role in the development of multiple organ failure during sepsis. Increasing electron flow through complex II by addition of succinate may improve mitochondrial oxygen utilization and thus adenosine triphosphate production. Design:Ex vivo animal study. Setting:University research laboratory. Subjects:Male adult Wistar rats. Interventions:Fecal peritonitis was induced in conscious, fluid-resuscitated, hemodynamically-monitored rats. Sham-operation and naïve animals acted as controls. At 48 hrs, clinical severity was graded. Soleus muscle was taken for measurement of mitochondrial complex activities and oxygen consumption. The effect of glutamate plus malate (complex I substrates) and succinate (complex II substrate) on mitochondrial respiration was assessed. Measurements and Main Results:In the presence of glutamate plus malate, mitochondrial oxygen consumption was abnormally low in skeletal muscle tissue from moderately-to-severely septic animals as compared with naïve and sham-operation controls (both p < .01). On addition of succinate, mitochondrial respiration was augmented in all groups, particularly in moderately-to-severely septic animals (39% ± 6% increase) as compared with naïve (11% ± 5%; p < .01) and sham-operation controls (10% ± 5%; p < .01). In the presence of succinate, mitochondrial oxygen consumption was similar between the groups. Conclusions:Succinate increases mitochondrial oxygen consumption in ex vivo skeletal muscle taken from septic animals, bypassing the predominant inhibition occurring at complex I. This warrants further exploration in vivo as a putative therapeutic modality.

Early functional and transcriptomic changes in the myocardium predict outcome in a long-term rat model of sepsis.

Myocardial function is depressed in sepsis and is an important prognosticator in the human condition. Using echocardiography in a long-term fluid-resuscitated Wistar rat model of faecal peritonitis we investigated whether depressed myocardial function could be detected at an early stage of sepsis and, if so, whether the degree of depression could predict eventual outcome. At 6 h post-insult, a stroke volume <0.17 ml prognosticated 3-day mortality with positive and negative predictive values of 93 and 80%, respectively. Subsequent fluid loading studies demonstrated intrinsic myocardial depression with poor-prognosis animals tolerating less fluid than either good-prognosis or sham-operated animals. Cardiac gene expression analysis at 6 h detected 527 transcripts significantly up- or down-regulated by the septic process, including genes related to inflammatory and cell cycle pathways. Predicted mortality was associated with significant differences in transcripts of genes expressing proteins related to the TLR2/MyD88 (Toll-like receptor 2/myeloid differentiation factor 88) and JAK/STAT (Janus kinase/signal transducer and activator of transcription) inflammatory pathways, β-adrenergic signalling and intracellular calcium cycling. Our findings highlight the presence of myocardial depression in early sepsis and its prognostic significance. Transcriptomic analysis in heart tissue identified changes in signalling pathways that correlated with clinical dysfunction. These pathways merit further study to both better understand and potentially modify the disease process.

Differential effects of vasopressin and norepinephrine on vascular reactivity in a long-term rodent model of sepsis.

Objective:There is escalating interest in the therapeutic use of vasopressin in septic shock. However, little attention has focused on mechanisms underlying its pressor hypersensitivity, which contrasts with the vascular hyporesponsiveness to catecholamines. We investigated whether a long-term rodent model of sepsis would produce changes in endogenous levels and pressor reactivity to exogenous norepinephrine and vasopressin comparable with those seen in septic patients. Design:In vivo and ex vivo animal study. Setting:University research laboratory. Subjects:Male adult Wistar rats. Interventions and Measurements:Fecal peritonitis was induced in conscious, fluid-resuscitated rats. Biochemical and hormonal profiles were measured at time points up to 48 hrs. Pressor responses to intravenous norepinephrine, vasopressin, and F-180, a selective V1 receptor agonist, were measured at 24 hrs. Contractile responses to these drugs were assessed in mesenteric arteries taken from animals at 24 hrs using wire myography. Comparisons were made against sham operation controls. Main Results:Septic rats became unwell and hypotensive, with a mortality of 64% at 48 hrs (0% in controls). Plasma norepinephrine levels were elevated in septic animals at 24 hrs (1968 ± 490 vs. 492 ± 90 pg/mL in controls, p = .003), whereas vasopressin levels were similar in the two groups (4.5 ± 0.8 vs. 3.0 ± 0.5 pg/mL, p = not significant). In vivo, the pressor response to norepinephrine was markedly reduced in the septic animals, but responses to vasopressin and F-180 were relatively preserved. In arteries from septic animals, norepinephrine contractions were decreased (efficacy as measured by maximum contractile response, Emax: 3.0 ± 0.3 vs. 4.7 ± 0.2 mN, p < .001). In contrast, the potency of vasopressin (expressed as the negative log of the concentration required to produce 50% of the maximum tension, pD2: 9.1 ± 0.04 vs. 8.7 ± 0.05, p < .001) and F-180 (pD2 8.2 ± 0.04 vs. 7.6 ± 0.02, p < .001) was enhanced (n ≥ 6 for all groups). Conclusions:This long-term animal model demonstrates changes in circulating vasoactive hormones similar to prolonged human sepsis, and decreased pressor sensitivity to norepinephrine. Ex vivo sensitivity to vasopressin agonists was heightened. This model is therefore appropriate for the further investigation of mechanisms underlying vasopressin hypersensitivity, which may include receptor or calcium-handling alterations within the vasculature.

Pharmacological inhibition of DDAH1 improves survival, haemodynamics and organ function in experimental septic shock

The aim of the present study was to investigate the therapeutic effects of pharmacological inhibition of DDAH1 (dimethylarginine dimethylaminohydrolase 1), an enzyme that metabolizes endogenously produced nitric oxide synthase inhibitors, principally ADMA (asymmetric dimethylarginine). The present study employs a series of rodent models to evaluate the effectiveness a DDAH1-selective inhibitor (L-257). Short-term models involved the development of endotoxaemia using lipopolysaccharide and long-term models involved the intraperitoneal administration of faecal slurry. In order to generate the most relevant model possible, following induction of severe sepsis, animals received appropriate fluid resuscitation and in some models vasopressor therapy. The effects of L-257 on survival, haemodynamics and organ function were subsequently assessed. Survival was significantly longer in all L-257 treatment groups (P<0.01) and no adverse effects on haemodynamics and organ function were observed following L-257 administration to either animals with sepsis or naïve animals. Haemodynamic performance was preserved and the noradrenaline dose required to maintain target blood pressure was reduced in the treated animals (P<0.01). Animals receiving L-257 had significantly increased plasma ADMA concentrations. Plasma nitrite/nitrate was reduced as was severity of sepsis-associated renal dysfunction. The degree of tachycardia was improved as were indices of tissue and microvascular perfusion. The results of the present study show that the selective DDAH-1 inhibitor L-257 improved haemodynamics, provided catecholamine sparing and prolonged survival in experimental sepsis. Further studies will determine its potential utility in human septic shock.

Hydroxychloroquine Protects against Cardiac Ischaemia/Reperfusion Injury In Vivo via Enhancement of ERK1/2 Phosphorylation.

An increasing number of investigations including human studies demonstrate that pharmacological ischaemic preconditioning is a viable way to protect the heart from myocardial ischaemia/reperfusion (I/R) injury. This study investigated the role of hydroxychloroquine (HCQ) in the heart during I/R injury. In vitro and in vivo models of myocardial I/R injury were used to assess the effects of HCQ. It was found that HCQ was protective in neonatal rat cardiomyocytes through inhibition of apoptosis, measured by TUNEL and cleaved caspase-3. This protection in vitro was mediated through enhancement of ERK1/2 phosphorylation mediated by HCQ in a dose-dependent fashion. A decrease in infarct size was observed in an in vivo model of myocardial I/R injury in HCQ treated animals and furthermore this protection was blocked in the presence of the ERK1/2 inhibitor U0126. For the first time, we have shown that HCQ promotes a preconditioning like protection in an in vivo simulated rat myocardial I/R injury model. Moreover, it was shown that HCQ is protective via enhanced phosphorylation of the pro-survival kinase ERK1/2.

Inhibition of vascular adenosine triphosphate-sensitive potassium channels by sympathetic tone during sepsis.

Objective:Excessive opening of the adenosine triphosphate-sensitive potassium channel in vascular smooth muscle is implicated in the vasodilation and vascular hyporeactivity underlying septic shock. Therapeutic channel inhibition using sulfonylurea agents has proved disappointing, although agents acting on its pore appear more promising. We thus investigated the hemodynamic effects of adenosine triphosphate-sensitive potassium channel pore inhibition in awake, fluid-resuscitated septic rats, and the extent to which these responses are modulated by the high sympathetic tone present in sepsis. Temporal changes in ex-vivo channel activity and subunit gene expression were also investigated. Design:In vivo and ex vivo animal study. Setting:University research laboratory. Subjects:Male adult Wistar rats. Interventions and Measurements:Fecal peritonitis was induced in conscious, fluid-resuscitated rats. Pressor responses to norepinephrine and PNU-37883A (a vascular adenosine triphosphate-sensitive potassium channel inhibitor acting on the Kir6.1 pore-forming subunit) were measured at 6 or 24 hrs, in the absence or presence of the autonomic ganglion blocker, pentolinium. The aorta and mesenteric artery were examined ex vivo for 86rubidium efflux as a marker of adenosine triphosphate-sensitive potassium channel activity, and for adenosine triphosphate-sensitive potassium channel subunit gene expression using quantitative reverse transcription-polymerase chain reaction. Main Results:A total of 120 rats (50 sham-operated controls, 70 septic) were included. Septic rats became hypotensive after 12 hrs, with a 24-hr mortality of 51.7% (0% in controls). At 6 hrs, there was an attenuated pressor response to norepinephrine (p < .01) despite blood pressure being elevated (p < .01). PNU-37883A had no pressor effect, except in the presence of pentolinium (p < .01). Kir6.1 subunit mRNA increased significantly in the mesenteric artery while 86rubidium efflux was increased in both the aorta and mesenteric artery at 24 hrs. Conclusions:Despite evidence of increased adenosine triphosphate-sensitive potassium channel activity in sepsis, it appears to be inhibited in vivo by high sympathetic tone. This may explain, at least in part, the reduced efficacy of adenosine triphosphate-sensitive potassium channel blockers in human septic shock. (Crit Care Med 2012; 40:–1268)

Deep learning diffusion fingerprinting to detect brain tumour response to chemotherapy

Artificial neural networks are being widely implemented for a range of different biomedical imaging applications.Convolutional neural networks are by far the most popular type of deep earning architecture,but often require very large datasets for robust training and evaluation We introduce deep learning diffusion fingerprinting (DLDF), which we have used to classifydiffusion-weighted magnetic resonance imaging voxels in a mouse model of glioblastoma (GL261 cell line), both prior to and in response to Temozolomide (TMZ) chemotherapy.We show that, even with limited training, DLDF can automatically segment brain tumours from normal brain, can automatically distinguish between young and older (after 9 days of growth) tumours and that DLDF can detect whether or not a tumour has been treated with chemotherapy.Our results also suggest that DLDF can detect localised changes in the underlying tumour microstructure, which are not evident using conventional measurements of the apparent diffusion coefficient (ADC).Tissue category maps generated by DLDF showed regions containing a mixture of normal brain and tumour cells, and in some cases evidence of tumour invasion across the corpus callosum, which were broadly consistent with histology.In conclusion, DLDF shows the potential for applying deep learning on a pixel-wise level,which reduces the need for vast training datasets and could easily be applied to other multi-dimensional imaging acquisitions Abbreviations ANN artificial neural network CT x-ray computed tomography PET positron emission tomography CNN convolutional neural network HARDI high angular resolution diffusion weighted imaging NODDI neurite orientation dispersion and density imaging VERDICT vascular, extracellular and restricted diffusion for cytometry in tumours DLDF deep learning with diffusion fingerprinting TMZ Temozolomide PFA paraformaldehyde H&E hematoxylin and eosin GFAP glial fibrillary acidic protein

Non-invasive imaging of disrupted protein homeostasis induced by proteasome inhibitor treatment using chemical exchange saturation transfer MRI

Proteasome inhibitors (PIs) are now standard of care for several cancers, and noninvasive biomarkers of treatment response are critically required for early patient stratification and treatment personalization. The present study evaluated whether chemical exchange (CEST) magnetic resonance imaging (MRI) can provide measurements that can be used as the noninvasive biomarkers of proteasome inhibition, alongside diffusion MRI and relaxometry. The sensitivity of human colorectal carcinoma cells to the PI Ixazomib was assessed via in vitro and in vivo dose-response experiments. Acute in vivo response to Ixazomib was assessed at three dosing concentrations, using CEST MRI (amide, amine, hydroxyl signals), diffusion MRI (ADC) and relaxometry (T1, T2). These responses were further evaluated with the known histological markers for Ixazomib and Bradford assay ex vivo. The CEST signal from amides and amines increased in proportion to Ixazomib dose in colorectal cancer xenografts. The cell lines differed in their sensitivity to Ixazomib, which was reflected in the MRI measurements. A mild stimulation in tumor growth was observed at low Ixazomib doses. Our results identify CEST MRI as a promising method for safely and noninvasively monitoring disrupted tumor protein homeostasis induced by proteasome inhibitor treatment, and for stratifying sensitivity between tumor types.

Development of noninvasive biomarkers of response to proteasome inhibitor therapy (ixazomib) by imaging disrupted protein homeostasis in mouse models of solid tumors

With clinically-approved proteasome inhibitors now a standard of care for multiple myeloma, and increasing interest in their use in solid tumors, methods for monitoring therapeutic response in vivo are critically required. Here, we show that tumor protein homeostasis can be noninvasively monitored, using chemical exchange (CEST) magnetic resonance imaging (MRI) as a surrogate marker for proteasome inhibition, alongside diffusion MRI and relaxometry. We show that the in vivo CEST signal associated with amides and amines increases in proportion to proteasome inhibitor dose (ixazomib) and the magnitude of therapeutic effect in colorectal cancer xenografts. Moreover, we show that SW1222 and LS174T human colorectal cancer cell lines demonstrate differing sensitivities to ixazomib, which was reflected in our MRI measurements. We also found evidence of a mild stimulation in tumor growth at low ixazomib doses. Our results therefore identify CEST MRI as a promising method for safely and noninvasively monitoring changes in tumor protein homeostasis.