CRISPR: a journey of gene-editing based medicine.

CRISPR (Clustered Regularly Interspaced Short Palindromic Repeat) is one of the hallmark of biological tools, contemplated as a valid and hopeful alternatives to genome editing. Advancements in CRISPR-based technologies have empowered scientists with an editing kit that allows them to employ their knowledge for deleting, replacing and lately "Gene Surgery", and provides unique control over genes in broad range of species, and presumably in humans. These fast-growing technologies have high strength and flexibility and are becoming an adaptable tool with implementations that are altering organism's genome and easily used for chromatin manipulation. In addition to the popularity of CRISPR in genome engineering and modern biology, this major tool authorizes breakthrough discoveries and methodological advancements in science. As scientists are developing new types of experiments, some of the applications are raising questions about what CRISPR can enable. The results of evidence-based research strongly suggest that CRISPR is becoming a practical tool for genome-engineering and to create genetically modified eukaryotes, which is needed to establish guidelines on new regulatory concerns for scientific communities.

Use of Flaviviral genetic fragments as a potential prevention strategy for HIV-1 Silencing.

INTRODUCTION: Coinfection with certain members of the Flaviviridae, such as Dengue Virus (DV), West Nile Virus (WNV) Yellow Fever Virus (YFV) and most importantly, GBV-C have been documented to reduce HIV-1 viral load in vivo. Numerous studies strongly support the notion that persistent coinfection with non-pathogenic virus prolongs survival in HIV-1 infected individuals. Coinfected individuals show higher CD4+ cell counts, lower HIV-1 RNA viral loads and live three times longer than clinically matched HIV-1 monoinfected patients. We have previously shown that one of the major anti-HIV defenses conferred by GBV-C coinfection is the upregulation of intracellular miRNAs in CD4+ cells that share significant mutual homologies with GBV-C and HIV-1 (>80%) genomes. METHODOLOGY: Genome-wide bioinformatics analyses were carried out to search for miRNA binding sites in mutual homologies between HIV and several members of the Flaviviridae. RESULTS: Several miRNAs shared significant mutual homology with HIV-1 genetic sequences and GBV-A, B, C, DV, WNV and YFV. These may be responsible for beneficial effects in HIV-1 infected individuals. Three highly mutual homologous miRNAs (i.e. miR-627-5, miR-369-5 and miR-548f), expressed in CD4+ cell lines, reduce HIV-1 replication by up to 90% whereas miRNAs with low mutual homologies (i.e. miR-34-1 and miR-508) impart only slight inhibition of HIV-1. CONCLUSION: We hypothesize that a recombinant GBV-C-based vector can be constructed which expresses several beneficial genetic motifs of the Flaviviridae without causing any side effects while stimulating a wide array of beneficial miRNAs that can more efficiently prevent HIV-1 infection.

Inhibition of Ebola Virus by Anti-Ebola miRNAs in silico.

INTRODUCTION: MicroRNAs (miRNAs) are small, noncoding RNA molecules that regulate transcriptional and posttranscriptional gene regulation of the organisms. miRNA provides immune defense when the body is faced with challenges intracellular agents. miRNA molecules trigger gene silencing in eukaryotic cells. More than 3,000 different human miRNAs (hsa-miRs) have been identified thus far. During ontogenesis, viral or intracellular parasitic infections, miRNAs are differentially expressed to protect the host from intracellular invaders. In a viral infection context, miRNAs have been connected with the interplay between host and pathogen, and occupy a major role in pathogenesis. METHODOLOGY: An in silico approach was used to analyze the four major Ebola Virus genome sequences including the recently characterized Ebola virus responsible for West African epidemic that has killed over 10,000 people. All totaled, 2,543 mature human miRNA sequences were retrieved through an miR-database, and the identification of mature miRNAs were aligned with full length sequences of the four major Ebola viruses via computational tools. RESULTS: We identified 32 miRNAs that exhibited significant inhibitory capacity to block more than one EBV strains. miR-607 showed capacity to quell all four major EBVs. Ten putative miRNAs were found to have near perfect identity at seed sequences with numerous targets of Ebola virus that may completely degrade the viral transcripts. CONCLUSION: We hypothesize that a miRNA-based vaccine can quell Ebola virus infection. Future approaches will focus on validation of these miRNAs in quelling the Ebola virus to further elucidate their biological functions in primate and other animal models.

Bacteriophage therapy: a potential solution for the antibiotic resistance crisis.

The emergence of multiple drug-resistant bacteria has prompted interest in alternatives to conventional antimicrobials. One of the possible replacement options for antibiotics is the use of bacteriophages as antimicrobial agents. Phage therapy is an important alternative to antibiotics in the current era of drug-resistant pathogens. Bacteriophages have played an important role in the expansion of molecular biology and have been used as antibacterial agents since 1966. In this review, we describe a brief history of bacteriophages and clinical studies on their use in bacterial disease prophylaxis and therapy. We discuss the advantages and disadvantages of bacteriophages as therapeutic agents in this regard.

Role of perfumes in pathogenesis of autism.

Autism spectrum disorders (ASDs) are developmental conditions characterized by deficits in social interaction, verbal and nonverbal communication, and obsessive/stereotyped patterns of behavior. Although there is no reliable neurophysiological marker associated with ASDs, dysfunction of the parieto-frontal mirror neuron system and underdeveloped olfactory bulb (OB) has been associated with the disorder. It has been reported that the number of children who have ASD has increased considerably since the early 1990 s. In developed countries, it is now reported that 1-1.5% of children have ASD, and in the US it is estimated that one in 88 children suffer from ASD. Currently, there is no known cause for ASD. During the last three decades, the most commonly accepted paradigm about autism is that it is a genetically inherited disease. The recent trio analyses, in which both biological parents and the autistic child's exomes are sequenced, do not support this paradigm. On the other hand, the environmental factors that may induce genetic mutations in vitro have not been clearly identified, and there is little irrefutable evidence that pesticides, water born chemicals, or food preservatives play critical roles in inducing the genetic mutations associated with known intellectual deficiencies that have been linked to autism spectrum disorder (ASD). Here, we hypothesize and provide scientific evidence that ASD is the result of exposure to perfumes and cosmetics. The highly mutagenic, neurotoxic, and neuromodulatory chemicals found in perfumes are often overlooked and ignored as a result of a giant loophole in the Federal Fair Packaging and Labeling Act of 1973, which explicitly exempts fragrance producers from having to disclose perfume ingredients on product labels. We hypothesize that perfumes and cosmetics may be important factors in the pathogenesis of ASD. Synthetic perfumes have gained global utility not only as perfumes but also as essential chemicals in detergents, cosmetics, soap, and a wide variety of commonly used items, even in food flavoring to enhance product taste. Here we provide evidence that a majority of perfumes are highly mutagenic at femtomolar concentrations, and cause significant neuromodulations in human neuroblastoma cells at extremely low levels of concentration, levels that are expected to reach a developing fetal brain if the pregnant mothers are exposed to these chemicals.

Hepatitis C virus, human immunodeficiency virus and Pseudomonas phage PS5 triad share epitopes of immunogenic determinants.

A lytic phage for Pseudomonas aeruginosa belongs to the Myoviridea family was isolated from urine for use in therapeutics. Pair of hepatitis C virus (HCV) primers highlighted segments on the genome of this phage. The sequence of these PCR products as well as the possible serological cross reactivity/relationship between HCV and the phage were investigated. One hundred HCV positive human sera were analyzed by ELISA. Ninety six well plates were coated with multiple epitopes of HCV proteins (Kit), phage and Pseudomonas cells. Initially the positive and negative control sera supplied in the test kit were used to evaluate the cross reactivity between the phage and anti-HCV antibodies. The results suggested a value over than 0.105 for a HCV positive reaction. Of the 100 HCV positive sera tested, sixty five and thirty percent showed cross reaction with phage lysate and Pseudomonas aeruginosa, respectively. High HCV antibody titer correlated to high cut off value for phage cross reaction, whereas no such correlation existed between HCV antibody titer and Pseudomonas cross reaction. The PCR products were sequenced and aligned with the HCV genome of H77. Sequence homology was detected in the 5', 3' UTRs and NS3 regions. Further these products showed similarity with HIV-1 Env, Pol & 3'LTR regions as well.