Current Molecular Medicine - Volume 13, Issue 4, 2013

Pancreatic cancer is characterized by extremely poor prognosis because of early recurrence and metastasis, and increasing evidence supports the critical role of microRNA in cancer progression. Here we identified that microRNA-34b functioned as a tumor-suppressing microRNA by targeting oncogenic Smad3 in pancreatic cancer. As a hypovascular tumor with a potential endoplasmic reticulum stress microenvironment, miR-34b was silenced after ER stress inducer thapsigargin (Tg) treatment and negatively regulated by ER stress chaperone glucose regulated protein 78 (GRP78) in pancreatic cancer cells. In human specimens, we found that miR-34b was down-regulated in pancreatic cancer tissues and low level of miR-34b expression was positively correlated with tumor-node-metastasis (TNM) stage, lymph-node metastasis and overall survival. Functional assays showed that over-expression of miR-34b inhibited pancreatic cancer progression in vitro and in vivo. In addition, Smad3 was demonstrated as a direct target of miR-34b and negatively regulated by miR- 34b at mRNA and protein levels. Luciferase assays confirmed that miR-34b could directly bind to the 3'untranslated region of Smad3. An inverse correlation between miR-34b and Smad3 was observed in 64 pancreatic cancer tissues. Our findings indicate that miR-34b acts as a tumor metastasis suppressor through negatively modulating Smad3, which may provide a potential therapeutic strategy for pancreatic cancer.

Malaria sexual stage and mosquito transmission-blocking vaccines (SSM-TBV) have recently gained prominence as a necessary tool for malaria eradication. SSM-TBVs are unique in that, with the exception of parasite gametocyte antigens, they primarily target parasite or mosquito midgut surface antigens expressed only inside the mosquito. As such, the primary perceived limitation of SSM-TBVs is that the absence of natural boosting following immunization will limit its efficacy, since the antigens are never presented to the human immune system. An ideal, safe SSM-TBV formulation must overcome this limitation. We provide a focused evaluation of relevant nano-/microparticle technologies that can be applied toward the development of leading SSM-TBV candidates, and data from a proof-of-concept study demonstrating that a single inoculation and controlled release of antigen in mice, can elicit long-lasting protective antibody titers. We conclude by identifying the remaining critical gaps in knowledge and opportunities for moving SSM-TBVs to the field.

Inhalation anesthetic isoflurane has been reported to induce caspase activation and accumulation of β-amyloid (Aβ), however, the down-stream consequences of these effects are largely unknown. Isoflurane has also been shown to impair learning and memory, however, the up-stream mechanisms of these effects remain largely to be determined. Facilitation of synaptic NMDA receptor endocytosis can reduce synaptic function, leading to learning and memory impairment. We therefore set out to determine the effects of isoflurane on synaptic NMDA receptor endocytosis. Primary neurons from wild-type and Alzheimer's disease transgenic mice were treated with 2% isoflurane for six hours. Synaptic surface levels of NMDA receptor 2B (NR2B) and NR2B internalization were determined by surface and cleavable biotinylation assay, western blot analysis and immunofluorescence. Here we show that isoflurane can induce caspase-3 activation, increase levels of β-site amyloid precursor protein-cleaving enzyme and cause accumulation of Aβ in the primary neurons. Isoflurane facilitates synaptic NR2B endocytosis as evidenced by reducing surface NR2B levels, increasing NR2B internalization, and decreasing the ratio of synaptic surface NR2B to synapsin in mice primary neurons. Moreover, caspase activation inhibitor Z-VAD and γ-secretase inhibitor L-685,458 attenuated the isofluranefacilitated NR2B endocytosis. These results suggest that isoflurane induces caspase activation and Aβ accumulation, leading to facilitation of synaptic NMDA receptor endocytosis, which potentially serve as the upstream mechanism of the isoflurane-induced impairment of learning and memory. These findings will encourage further studies to determine the underlying mechanism by which isoflurane and other anesthetics promote Alzheimer's disease neuropathogenesis and induce cognitive dysfunction.

Sex/gender differences in terms of incidence, prevalence, age at onset and severity have been documented for several complex adulthood diseases. However, several pediatric diseases also displayed a gender disparity. Unfortunately, epidemiologic studies investigating gender disparity in pediatric age show dissimilar results often depending on the spatial and temporal issues, to considerable regional environmental variations, to social conditions or to infectious agent virulence. Anyway, studies over time showed that gender disparity in childhood mortality and morbidity may be narrow in some pathological conditions whereas in other severe diseases, e.g. sepsis, some cancers and some immune disorders, the disproportion was found as significant. In this work we briefly review literature data dealing with sex/gender differences in morbidity and mortality observed during the pediatric age. In particular, communicable and non-communicable diseases, including cancer, have been considered. The possible mechanisms underlining these differences, e.g. hormonal and epigenetic, are also discussed. The analysis of literature available as concerns pediatric age seems to underline that gender differences start very early in human beings and that hormones as well as gene expression in XX and XY cells can play a role. A reappraisal of the gender issue in pediatric research could thus be pivotal: it might contribute to the improvement of diagnostic and therapeutic strategies as well as to the improvement of the appropriateness of the cures.

Cancer cells require a robust supply of reduced nitrogen to produce nucleotides, non-essential amino acids and a high cellular redox activity. Glutamine provides a major substrate for respiration as well as nitrogen for the production of proteins, hexosamines, and macromolecules. Therefore, glutamine is one of key molecules in cancer metabolism during cell proliferation. The notion of targeting glutamine metabolism in cancer, originally rationalized by the number of pathways fed by this nutrient, has been reinforced by more recent studies demonstrating that its metabolism is regulated by oncogenes. Glutamine can exert its effects by modulating redox homeostasis, bioenergetics, nitrogen balance or other functions, including by being a precursor of glutathione, the major nonenzymatic cellular antioxidant. Glutaminase (GA) is the first enzyme that converts glutamine to glutamate, which is in turn converted to alpha-ketoglutarate for further metabolism in the tricarboxylic acid cycle. Different GA isoforms in mammals are encoded by two genes, Gls and Gls2. As each enzymatic form of GA has distinct kinetic and molecular characteristics, it has been speculated that the differential regulation of GA isoforms may reflect distinct functions or requirements in different tissues or cell states. GA encoded by Gls gene (GLS) has been demonstrated to be regulated by oncogenes and to support tumor cell growth. GA encoded by Gls2 gene (GLS2) reduces cellular sensitivity to reactive oxygen speciesassociated apoptosis possibly through glutathione-dependent antioxidant defense, and therefore to behave more like a tumor suppressor. Thus, modulation of GA function may be a new therapeutic target for cancer treatment.

Glioblastoma multiforme (GBM), the most common and aggressive form of primary brain tumor, presents a dismal prognosis. Current standard therapies are only able to improve patient survival by a few months. The search for alternative approaches in glioblastoma treatment, together with the recent discovery of a new class of small RNA molecules that are capable of regulating gene expression, prompted a race for a deeper and thorough understanding of how these molecules work. Today, it is known that microRNAs are involved in many cellular processes that are altered in GBM tumors, such as angiogenesis, invasion, cell proliferation and apoptosis. Research in this area is now gathering efforts to translate these findings into clinically relevant therapies that could improve the diagnosis and outcome of GBM patients. In this review, we discuss the use of microRNAs as potential diagnostic, prognostic and therapeutic tools against glioblastoma. We will also assess the current challenges and future perspectives of microRNA-based therapies, with a special focus on why this promising therapeutic approach is not yet in the clinic and how to overcome this limitation.

Calcineurin-NFAT signaling is critical for numerous aspects of vertebrate function during and after embryonic development. Initially discovered in T cells, the NFAT gene family, consisting of five members, regulates immune system, inflammatory response, angiogenesis, cardiac valve formation, myocardial development, axonal guidance, skeletal muscle development, bone homeostasis, development and metastasis of cancer, and many other biological processes. In this review we will focus on the NFAT literature relevant to the two closely related pathological systems: inflammation and cancer.

The pharmacological effects (i.e., inhibition of endocrine secretion and cell proliferation) mediated by the hormone somatostatin (SRIF) are derived from its universal high-affinity binding to five different G proteincoupled receptors (GPCRs), named sst1-5. However, SRIF has a half-life of less than 3 min, whereas the available mono- and bi-specific SRIF preferential analogs show prolonged half-life and increased potency. These compounds may control tumor development, cell proliferation and metastatization by direct actions, including cell division arrest in G0/G1 phase (i.e., induction of cyclin-dependent kinase inhibitor p27kip1 or p21Cip1), induction of apoptosis (i.e., induction of p53 and Bax) and suppression of cell invasion. Along with these direct actions on the biology of cancer progression, in vivo SRIF analogs may also regulate tumor growth through indirect actions, by suppressing the secretion of growth-promoting hormones and growth factors and angiogenesis. Interestingly, when ssts are co-expressed, they may interact forming homo- or heterodimers, also with other GPCRs such as type 2 dopamine receptor and the μ-opioid receptor 1, altering their original pharmacological and functional properties. Dimers can be not only constitutive, but perhaps also ligandpromoted: hence, compounds with high affinity for different ssts isoforms may be used to achieve effects elicited by specific dimers. Future developments in the knowledge of ssts dynamics upon SRIF and SRIF analogs binding in neoplastic tissues may allow the full elucidation of the pathophysiological role of this system and the exploitation of the therapeutic potential of its modulation.

MicroRNAs (miRNAs) are ubiquitously expressed small, non-coding RNAs that negatively regulate gene expression at a post-transcriptional level. So far, over 1000 miRNAs have been identified in human cells and their diverse functions in normal cell homeostasis and many different diseases have been thoroughly investigated during the past decade. MiR-29, one of the most interesting miRNA families in humans to date, consists of three mature members miR-29a, miR-29b and miR-29c, which are encoded in two genetic clusters. Members of this family have been shown to be silenced or down-regulated in many different types of cancer and have subsequently been attributed predominantly tumor-suppressing properties, albeit exceptions have been described where miR-29s have tumor-promoting functions. MiR-29 targets expression of diverse proteins like collagens, transcription factors, methyltransferases and others, which may partake in abnormal migration, invasion or proliferation of cells and may favor development of cancer. Furthermore, members of the miR-29 family can be activated by interferon signaling, which suggests a role in the immune system and in hostpathogen interactions, especially in response to viral infections. In this review, we summarize current knowledge on the genomic organization and regulation of the miR-29 family and we provide an overview of its implication in cancer suppression and promotion as well as in host immune responses. The numerous remarkable properties of these miRNAs and their often altered expression patterns might make the miR-29 family promising biomarkers and therapeutic targets for various diseases in future.

Diabetes mellitus is one of the most prevalent chronic diseases. Since glucose is the main fuel of the brain, its levels should be maintained within a narrow range to ensure normal brain function. Indeed, the literature shows that uncontrolled blood glucose levels, whether too high or too low, impact brain structure and function potentiating cognitive impairment. Uncoupling proteins (UCPs) are a family of mitochondrial anioncarrier proteins located on the inner mitochondrial membrane, and their primary function is to leak protons from the intermembrane space into the mitochondrial matrix. The specific role of neuronal UCPs has been widely discussed and although there is no general agreement, there is a strong conviction that these proteins may be involved in the defense against mitochondrial reactive oxygen species (ROS) production and, consequently, protecting against oxidative damage. The generation of ROS is increasingly recognized as playing an important role in diabetes, neurodegenerative disorders and aging where mitochondria are both sources and targets of these reactive species. This review examines the neurodegenerative events associated with diabetes, highlighting the role of hyperglycemia and/or hypoglycemia on cognitive function. The role of mitochondria, neuronal UCPs and their impact in central nervous system will be elucidated. Finally, we will discuss neuronal UCPs as possible therapeutic targets for the treatment of diabetes-associated central complications and neurodegenerative diseases, namely Alzheimer's and Parkinson's diseases.

Over the years, there has been an exponential increase in the number of gene therapy approaches that are under investigation for the treatment of cancer. This can be attributed to our growing understanding of the molecular mechanisms that contribute to the onset and maintenance of cancer as well as to the development of gene delivery vectors. In this review, we will focus on the use of lentiviral vectors (LVs) in immuno gene therapy of cancer, as these efficacious gene delivery vehicles have come to the forefront because of their many attractive features. LVs have been successfully applied to generate potent dendritic cellbased anti-cancer vaccines and to deliver cancer-specific receptors to T-cells. Moreover, LVs are under investigation for the modulation of cancer cells. We will describe various strategies of this ‘genuine’ cancer gene therapy, amongst which transfer of suicide genes, modulation of pro- and anti-apoptotic molecules, strategies to optimize chemo- and radiotherapy, expression of molecules that affect angiogenesis or affect the immunogenicity of tumor cells. These will be discussed in view of our current knowledge of tumor immunology. Finally we will discuss some important issues and future directions to push the field forward.

Bone metastasis is a debilitating side effect of advanced prostatic carcinoma impacting nearly all of the men developing this disease. Even though a majority of these lesions are considered osteoblastic, it is believed that there is an underlying osteolytic component. Lytic processes are governed primarily by osteoclasts, the primary bone resorptive cell. Osteolysis has been implicated in tumor cell seeding and nourishment of tumor growth via development of pro-tumorigenic changes in the microenvironment. Herein, we provide a current view of the processes involved in regulating osteolysis in the presence of prostate cancer bone metastases. Several factors have been implicated in the division, differentiation, and activation of osteoclasts, including, but not limited to, interleukin-6, receptor activator of nuclear factor kappa B ligand (RANKL), osteoprotegerin (OPG), and parathyroid hormone-related protein (PTHrP). Effector molecules in bone resorption play a significant role, such as matrix metalloproteinases (MMPs), cathepsins, and acid secretion. The primary method for treating skeletal events associated with prostate cancer bone metastases has been bisphosphonates. However, a new therapeutic, denosumab, a monoclonal antibody that inhibits RANKL in a mechanism similar to that attributed to the endogenous mediator OPG, has received approval for treatment of skeletally associated metastases. Additional novel targets are continuously being developed for bone metastases. In this review, we describe the processes involved in osteolysis of the prostate cancer bone microenvironment, and introduce therapeutics that may play a role in inhibiting tumor growth leading to increased survival and quality of life.

Histone deacetylase inhibitors (HDACi) have emerged as a new generation of anticancer therapeutics. The classical broad-spectrum HDACi typically alter the cell cycle distribution and induce celldeath, apoptosis and differentiation in malignant and transformed cells. This provides the basis for the clinical potential of HDACi in cancer therapy. Currently two compounds, suberoylanilide hydroxamic acid (SAHA, Vorinostat, Zolinza™) and depsipeptide (Romidepsin, Istodax™) have been approved for by the US Food and Drug Administration for the treatment of refractory cutaneous T-cell lymphoma. Apart from clinical application in oncology, HDACi have also been investigated as potential therapeutics for various pathologies including those of the central nervous system (such as Huntington's disease and multiple sclerosis), cardiac conditions (particularly hypertrophy), arthritis and malaria. Further, evidence is accumulating for potent immunomodulatory effects of classical HDACi which is the focus of this review. We review the antiinflammatory effects of HDACi and in particular findings implicating regulation of the innate and adaptive immune systems by HDAC enzymes. The recent findings highlighting the immunomodulatory function of HDAC11 which relates to balancing immune activation versus tolerance are also discussed.

Recently, the combining of different drugs has greatly improved response and survival rates in gynecological malignancies. Results are however far from being satisfactory. Treatments used in case of advanced or recurrent disease offer limited results in terms of long-term responses. The urgent need for new and more effective treatments has prompted researchers to investigate and propose new therapeutic strategies. One of the most interesting approaches that are being explored is constituted by immunotherapy. Currently, immunotherapeutic strategies include vaccination with peptide, viral vectors, carbohydrates and antiidiotypic antibodies. In addition, cell based immunotherapy has been adopted in vitro activated lymphocytes and dendritic cells. Most experience has been acquired in ovarian cancer and cervical cancer. Little has been investigated in endometrial and rare gynecologic neoplasms. The clinical experiences and results achieved with immunotherapy in this setting of patients have been reviewed and the future avenues that are currently being explored have also been discussed.

The embryonic phenotype transformation of cardiomyocytes is an important characteristic of pathological cardiac hypertrophy. It includes transcriptional reprogramming of gene expression, a switch from lipid metabolism to carbohydrate metabolism, and a shift from α-myosin heavy chain (MHC) to fetal ß-MHC expression. The embryonic and adult cardiacmyocytes have distinct gene expression profiles. A series of genes that are expressed in embryos are later shut down after birth through the inhibition of endogenous constitutively activated molecules. These genes can be reactivated if these inhibitors are inactivated or downregulated, as occurs under certain pathological conditions. This promotes pathological cardiac hypertrophy. In this review, we list a class of endogenous molecules whose expression is inactivated during cardiac hypertrophy. They play a positive role in inhibition of the occurrence and development of cardiac hypertrophy and constitute the first natural line of defense against pathological cardiac hypertrophy.

Aptamers selected from a large random sequence pool are oligonucleic acid or peptide molecules that bind to a specific target molecule with high affinity and sensitivity. Targets range from small molecules to proteins and peptides, even tissue or cells. As such, aptamers have captured the attention of scientists actively developing technologies for diverse biomedical applications. Particularly, when functionalized with nanomaterials, aptamers offer properties for both biomedical and bioanalytical applications. In this review, these features and properties are discussed with particular emphasis on the use of aptamer-based biosensor/detection platforms.