Faculty Bibliography

Background: We have previously demonstrated that anti-beta-sheet conformational monoclonal antibodies (mAbs) recognize pathological oligomeric forms of Abeta and Tau in tissue samples of human Alzheimer's Disease (AD) brains and in AD mouse models (Goni et al 2015, Alzheimer & Dementia pp 845-6). We have now tested one of our mAbs in aged 3xTg AD animals with extensive preexisting Abeta and Tau related pathology with weekly injections of the TABP1 mAb. Methods: Two groups of 16 months old 3xTg AD animals were inoculated i.p. biweekly for three weeks and weekly thereafter for 5 weeks with either 100 mug of TABP1 in 100 muL of sterile saline or with 100 muL of vehicle alone. Radial Arm Maze behavioral analysis was performed after the treatment, followed by sacrifice and harvesting of the brains for immuno-histochemical and biochemical analyses. Results: No adverse reactions were demonstrated during the treatment. The TABP1 infused animals showed significant cognitive rescue compared to the controls. No significant differences were noted with the immunohistochemical quantitation of amyloid plaques or tau pathology; although there was a trend for reduced deposition in the infused animals. However, there was a significant decrease of the soluble and oligomeric Abeta (mainly Abeta1-42) and pathological Tau in the infused animals versus the controls. Conclusions: Anti-conformational monoclonal antibodies infused i.p. can ameliorate behavioral deficits in AD model mice. The mechanism is likely related to reductions of the levels of soluble oligomeric forms of Abeta and Tau; these species have been most closely linked to the cognitive deficits in AD patients. The results are encouraging for the further testing of humanized versions of these mAbs in clinical trials

Background: The neuropathological hallmarks of Alzheimer's disease (AD) are senile plaques (SP) and neurofibrillary tangles (NFTs). Passive immunization with anti-Abeta antibodies is a promising therapeutic approach for AD with several on-going clinical trials; however, toxicity with amyloid related imaging abnormalities (ARIA) is problematic in many of these trails. This toxicity is in part related to the effector function of the antibodies used. Recently, an affibody molecule that lacks effector function, but binds to monomeric Abeta peptides, with aggregation inhibition capacity, was generated and tested in AD model transgenic fruit flies, demonstrating abolition of Abeta related neurotoxic effects and restoration of their life span. Here we assessed the efficacy of passive immunization with the affibody in a mouse model of AD. Methods: APP/ PS1 transgenic AD model mice were injected intraperitoneally twice a week with the Abeta-binding ZSYM73-ABD Affibody molecule from the age of 6 months (at a point where the mice already have amyloid deposition). Control mice received a non-Abeta binding affibody. Their behavior was assessed at 9 months of age and brain tissue subsequently was harvested for analysis of treatment efficacy. Results: The treated (Abeta-binding ZSYM73-ABD) mice didn't show a significant difference from controls on locomotor testing. ZSYM73- ABD treated-mice performed the same as wild-type mice. The amyloid burden of in treated animals was reduced by 49 % in the cortex and 50% in the hippocampus. There was no significant difference in astrogliosis or microhemorrhages between treated and control mice. Conclusions: These results indicate that passive immunization with an Affibody molecule can significantly decrease the amyloid burden and improve cognitive function in a transgenic mouse model of AD

BACKGROUND: Peripheral surgical trauma may incite neuroinflammation that leads to neuronal dysfunction associated with both depression and cognitive deficits. In a previous study, we found that adult mice developed neuroinflammation and short-term working memory dysfunction in a delayed, transient manner after splenectomy that was ameliorated by the cyclooxygenase-2 inhibitor meloxicam. We tested the hypothesis that splenectomy in mice would also cause anhedonia, the diminished response to pleasure or rewarding stimuli that is a hallmark of depression, and that treatment with meloxicam would be ameliorative. METHODS: After Institutional Animal Care and Use Committee approval, Swiss-Webster mice underwent sucrose preference training before being randomized into groups on day 0, when they had either splenectomy and anesthesia or anesthesia alone. Within each group, half were randomized to receive intraperitoneal saline at 24 hours, while the other half received intraperitoneal meloxicam at 24 hours. Sucrose preference ratios were determined on days 1, 5, 9, and 14. Additional mice were randomized into groups for brain histochemistry. Specimens were stained for glial fibrillary acidic protein (GFAP), a marker of astrocytes, and CD45, a protein tyrosine phosphatase that identifies microglial activation. RESULTS: On day 5, mice receiving splenectomy and saline demonstrated diminished sucrose preference, which was not seen in mice receiving splenectomy and meloxicam. Semiquantitative analysis of histological slides taken from splenectomized mice treated with meloxicam revealed reduced microglial-based neuroinflammation and reactive astrocytosis compared to mice receiving saline. CONCLUSION: Splenectomy in mice is associated with neuroinflammation and anhedonia, as evidenced by reactive microgliosis, astrocytosis, and behavioral changes. Postsurgical treatment with meloxicam attenuates both neuroinflammation and anhedonia. These findings suggest that cyclooxygenase-2-dependent mechanisms may play a role in the development of postoperative mood disorders, possibly via modulation of peripheral effects on neuroinflammation.

Cancer cachexia is a debilitating condition characterized by a combination of anorexia, muscle wasting, weight loss, and malnutrition. This condition affects an overwhelming majority of patients with pancreatic cancer and is a primary cause of cancer-related death. However, few, if any, effective therapies exist for both treatment and prevention of this syndrome. In order to develop novel therapeutic strategies for pancreatic cancer cachexia, appropriate animal models are necessary. In this study, we developed and validated a syngeneic, metastatic, murine model of pancreatic cancer cachexia. Using our model, we investigated the ability of transforming growth factor beta (TGF-beta) blockade to mitigate the metabolic changes associated with cachexia. We found that TGF-beta inhibition using the anti-TGF-beta antibody 1D11.16.8 significantly improved overall mortality, weight loss, fat mass, lean body mass, bone mineral density, and skeletal muscle proteolysis in mice harboring advanced pancreatic cancer. Other immunotherapeutic strategies we employed were not effective. Collectively, we validated a simplified but useful model of pancreatic cancer cachexia to investigate immunologic treatment strategies. In addition, we showed that TGF-beta inhibition can decrease the metabolic changes associated with cancer cachexia and improve overall survival.

Alzheimer's disease (AD) is the leading cause of dementia worldwide. Late-onset AD (LOAD), is the most common form of Alzheimer's disease, representing about >95% of cases and early-onset AD represents <5% of cases. Several risk factors have been discovered that are associated with AD, with advancing age being the most prominent. Other environmental risk factors include diabetes mellitus, level of physical activity, educational status, hypertension and head injury. The most well known genetic risk factor for LOAD is inheritance of the apolipoprotein (apo) E4 allele. Recently, rare variants of TREM2 have been reported as a significant risk factor for LOAD, comparable to inheritance of apoE4. In this review we will focus on the role(s) of TREM2 in AD as well as in other neurodegenerative disorders.

Inheritance of the apolipoprotein E4 (apoE4) genotype has been identified as the major genetic risk factor for late-onset Alzheimer's disease (AD). Studies have shown that the binding between apoE and amyloid-beta (Abeta) peptides occurs at residues 244-272 of apoE and residues 12-28 of Abeta. ApoE4 has been implicated in promoting Abeta deposition and impairing clearance of Abeta. We hypothesized that blocking the apoE/Abeta interaction would serve as an effective new approach to AD therapy. We have previously shown that treatment with Abeta12-28P can reduce amyloid plaques in APP/PS1 transgenic (Tg) mice and vascular amyloid in TgSwDI mice with congophilic amyloid angiopathy (CAA). In the present study, we investigated whether the Abeta12-28P elicits a therapeutic effect on tau-related pathology in addition to amyloid pathology using old triple transgenic Alzheimer's disease mice (3xTg, with PS1M146V , APPS we and tauP30 IL transgenes) with established pathology from the ages of 21 to 26 months. We show that treatment with Abeta12-28P substantially reduces tau pathology both immunohistochemically and biochemically, as well as reducing the amyloid burden and suppressing the activation of astrocytes and microglia. These affects correlate with a behavioral amelioration in the treated Tg mice

The accumulation of aggregated, hyperphosphorylated tau as neurofibrillary tangles and neuropil threads are cardinal features of Alzheimer's disease (AD). The other lesions found in AD include amyloid plaques and congophilic amyloid angiopathy, both associated with the extracellular accumulation of the amyloid-beta (Abeta) peptide. AD is the most common cause of dementia globally. Currently, there are no effective means to treat AD or even to slow it down. The dominant theory for the causation of AD is the amyloid cascade hypothesis, which suggests that the aggregation of Abeta as oligomers and amyloid plaques is central to the pathogenesis of AD. Numerous therapies have been developed directed to Abeta-related pathology, in particular various immunotherapeutic approaches. So far all of these have failed in clinical trials. Recently, there has been more focus on therapy directed to tau-related pathology, which correlates better with the cognitive status of patients, compared to the amyloid burden. Immunotherapeutic targeting of tau pathology has shown great potential in treating tau pathologies in mouse models of AD. A number of studies have shown the efficacy of both passive and active immunization. This review summarizes recent advances in therapy targeting pathological tau protein, in particular focusing on immunotherapeutic approaches which are showing great promise. (c) 2014 S. Karger AG, Basel.

Anti-amyloid beta (Abeta) immunotherapy provides potential benefits in Alzheimer's disease patients. Nevertheless, strategies based on Abeta1-42 peptide induced encephalomyelitis and possible microhemorrhages. These outcomes were not expected from studies performed in rodents. It is critical to determine if other animal models better predict side effects of immunotherapies. Mouse lemur primates can develop amyloidosis with aging. Here we used old lemurs to study immunotherapy based on Abeta1-42 or Abeta-derivative (K6Abeta1-30). We followed anti-Abeta40 immunoglobulin G and M responses and Abeta levels in plasma. In vivo magnetic resonance imaging and histology were used to evaluate amyloidosis, neuroinflammation, vasogenic edema, microhemorrhages, and brain iron deposits. The animals responded mainly to the Abeta1-42 immunogen. This treatment induced immune response and increased Abeta levels in plasma and also microhemorrhages and iron deposits in the choroid plexus. A complementary study of untreated lemurs showed iron accumulation in the choroid plexus with normal aging. Worsening of iron accumulation is thus a potential side effect of Abeta-immunization at prodromal stages of Alzheimer's disease, and should be monitored in clinical trials.

Although the mechanisms underlying mild traumatic brain injury (mTBI) are becoming well understood, treatment options are still limited. In the present study, mTBI was induced by a weight drop model to produce a closed head injury to mice and the effect of inhaled nitric oxide (INO) was evaluated by a short term memory task (object recognition task) and immunohistochemical staining of glial fibrillary acidic protein (GFAP) and CD45 for the detection of reactive astrocytes and microglia. Results showed that mTBI model did not produce brain edema, skull fracture or sensorimotor coordination dysfunctions. Mice did however exhibit a significant deficit in short term memory (STM) and strong inflammatory reaction in the ipsilateral cortex and hippocampus compared to sham-injured controls 24h after mTBI. Additional groups of untreated mice tested 3 and 7 days later, demonstrated that recognition memory had recovered to normal levels by Day 3. Mice treated with 10ppm INO for 4 or 8h, beginning immediately after TBI demonstrated significantly improved STM at 24h when compared with room air controls (p<0.05). Whereas mice treated with 10ppm INO for 24h showed no improvement in STM. Mice treated with INO 10ppm for 8h exhibited significantly reduced microglia and astrocyte activation compared with room air controls. These data demonstrate that mTBI produces a disruption of STM which is evident 24h after injury and persists for 2-3 days. Treatment with low concentration or short durations of INO prevents this memory loss and also attenuates the inflammatory response. These findings may have relevance for the treatment of patients diagnosed with concussion.