References

Heidi Ledford & Ewen Callaway http://www.nature.com/news/gene-drive-mosquitoes-engineered-to-fight-malaria-1.18858

Malaria Resistant Mosquitos by Design

Posted in CRISPR/Cas9 & Gene Editing, Curation, Malaria, tagged CRISPR, CRISPR/Cas and crispr, eradication transgenesis, gene drive, Malaria, malaria prevention, MCR, mosquitoes, Plasmodium falciparum on November 24, 2015| Leave a Comment »

Malaria Resistant Mosquitos by Design

Larry H. Bernstein, MD, FCAP, Curator

Curator

CRISPR-Powered Malaria Mosquito Gene Drive

Using the precision gene-editing tool, researchers demonstrate an ability to create large populations of malaria parasite–resistant mosquitoes.

By Tracy Vence | November 24, 2015 http://www.the-scientist.com//?articles.view/articleNo/44609/title/CRISPR-Powered-Malaria-Mosquito-Gene-Drive/

Using CRISPR, investigators at the Universities of California (UC) in San Diego and Irvine have engineered transgenic Anopheles stephensimosquitoes carrying an anti-malaria parasite effector gene “capable of introgressing the genes throughout wild vector populations,” they wrote in a PNAS paper published this week (November 23). The resulting gene-drive system could help wipe out the malaria pathogen (Plasmodium falciparum) within a targeted population of A. stephensi vectors, Anthony James of UC Irvine and his colleagues wrote.

“We know the gene works,” James said in a statement. “The mosquitoes we created are not the final brand, but we know this technology allows us to efficiently create large populations.”

As Nature noted, this study is not the first to report engineered Anopheles that stifle the malaria parasite but, until now, “researchers lacked a way to ensure that the resistance genes would spread rapidly through a wild population.” CRISPR/Cas9 gene-editing enabled this feat. “Males and females derived from transgenic females . . . produce progeny with a high frequency of mutations in the targeted genome sequence, resulting in near-Mendelian inheritance ratios of the transgene,” James and his colleagues wrote in their paper. (See “Reining in Gene Drives,” The Scientist, November 2015.)

“This work suggests that we’re a hop, skip, and jump away from actual gene-drive candidates for eventual release,” Kevin Esvelt of the Wyss Institute who was not involved in the work told Nature. “This is a major advance because it shows that gene drives will likely be effective in mosquitoes,” Esvelt told MIT Technology Review. “Technology is no longer the limitation.”

In the UC Irvine statement, study coauthor Ethan Bier of UC San Diego added that “the ability of this system to carry large genetic payloads should have broad applications to the future use of related CRISPR-based ‘active genetic’ systems.”

Reining in Gene Drives

Researchers have developed two methods to avoid the unchecked spread of engineered genes through wild populations.

By Karen Zusi | November 18, 2015 http://www.the-scientist.com/?articles.view/articleNo/44501/title/Reining-in-Gene-Drives/

“Gene drive” is a phenomenon that causes a gene to be inherited at a rate faster than Mendelian principles would dictate. It relies on genes that can copy themselves onto a corresponding location in a paired chromosome, thereby overriding typical allele inheritance patterns. In conjunction with CRISPR/Cas9, gene drives can be created with almost any DNA sequence, raising questions about the risk of engineered genes spreading quickly through a population. But a team of researchers from Harvard University published a study this week (November 16) in Nature Biology that offers some safety constraints on the system.

A description of the first CRISPR/Cas9 gene drive system was published in March by a team at the University of California, San Diego, and showed rapid spreading of a normally recessive phenotype inDrosophila. Other labs are researching the system’s potential to wipe out insect-borne diseases such as malaria by spreading mutated genes throughout a mosquito population. But the strategy carries the risk of accidental contamination of wild populations.

“We have a responsibility to keep our experiments confined to the laboratory,” Kevin Esvelt, an evolutionary engineer and coauthor on the paper, told Nature. “The basic lesson is: if you don’t have to build a gene drive that can spread through a wild population, then don’t.”

‘Gene drive’ mosquitoes engineered to fight malaria

Mutant mozzies could rapidly spread through wild populations.

http://www.nature.com/polopoly_fs/7.31719.1448290628!/image/1.18858%20.jpg_gen/derivatives/landscape_630/1.18858%20.jpg

The Anopheles stephensi mosquito can spread the malaria parasite to humans.

Mutant mosquitoes engineered to resist the parasite that causes malaria could wipe out the disease in some regions — for good.

Humans contract malaria from mosquitoes that are infected by parasites from the genusPlasmodium. Previous work had shown that mosquitoes could be engineered to rebuff the parasiteP. falciparum¹, but researchers lacked a way to ensure that the resistance genes would spread rapidly through a wild population.

In work published on 23 November in the Proceedings of the National Academy of Sciences, researchers used a controversial method called ‘gene drive’ to ensure that an engineered mosquito would pass on its new resistance genes to nearly all of its offspring² — not just half, as would normally be the case.

The result: a gene that could spread through a wild population like wildfire.

“This work suggests that we’re a hop, skip and jump away from actual gene-drive candidates for eventual release,” says Kevin Esvelt, an evolutionary engineer at Harvard University in Cambridge, Massachusetts, who studies gene drive in yeast and nematodes.

For Anthony James, a molecular biologist at the University of California, Irvine, and an author of the paper, such a release would spell the end of a 30-year quest to use mozzie genetics to squash malaria.

James and his laboratory have painstakingly built up the molecular tools to reach this goal. They have worked out techniques for creating transgenic mosquitoes — a notoriously challenging endeavour — and isolated genes that could confer resistance to P. falciparum. But James lacked a way to ensure that those genes would take hold in a wild population.

Fast forward

The concept of engineering a gene drive has been around for about a decade, and James’s laboratory had tried to produce them in the past. The process was agonizingly slow.

Then, in January, developmental biologists Ethan Bier and Valentino Gantz at the University of California, San Diego, contacted James with a stunning finding: they had engineered a gene drive in fruit flies, and wondered whether the same system might work in mosquitoes. James jumped at the opportunity to find out.

Bier and Gantz had used a gene-editing system called CRISPR–Cas9 to engineer a gene drive. They inserted genes encoding the components of the system that were designed to insert a specific mutation in their fruit flies. The CRISPR–Cas9 system then copied that mutation from one chromosome to the other³. James used that system in mosquitoes to introduce two genes that his past work showed would cause resistance to the malaria pathogen.

The resulting mosquitoes passed on the modified genes to more than 99% of their offspring. Although the researchers stopped short of confirming that all the insects were resistant to the parasite, they did show that the offspring expressed the genes.

“It’s a very significant development,” says Kenneth Oye, a political scientist who studies emerging technologies at the Massachusetts Institute of Technology in Cambridge. “Things are moving rapidly in this field.”

Other teams are developing gene drives that could control malaria. A team at Imperial College London has developed a CRISPR-based gene drive in Anopheles gambiae, the mosquito species that transmits malaria in sub-Saharan Africa. The group’s gene drive inactivates genes involved in egg production in female mosquitoes, which could be used to reduce mosquito populations, according to team member Austin Burt, an evolutionary geneticist. Their results will be published inNature Biotechnology next month, Burt says.

Oye notes that such technological advances are outpacing the regulatory and policy discussionsthat surround the use of gene drive to engineer wild populations. Gene drives are controversial because of the potential that they hold for altering entire ecosystems.

Before testing gene drive in the field, Oye hopes that researchers will study the long-term consequences of the changes, such as their stability and potential to spread to other species, as well as methods to control them. “I’m less worried about malevolence than getting something wrong,” he says.

Esvelt says that the US-based researchers made a wise decision in selecting a non-native mosquito species for their experiments. (The team worked with Anopheles stephensi, which is native to the Indian subcontinent.) “Even if they escaped the lab, there’d be no one to mate with and spread the drive,” Esvelt says.

James predicts that it will take his team less than a year to prepare mosquitoes that would be suitable for field tests, but he is in no rush to release them. “It’s not going to go anywhere until the social science advances to the point where we can handle it,” he says. “We’re not about to do anything foolish.”

Nature http://dx.doi.org:/10.1038/nature.2015.18858

References

Isaacs, A. T. et al. PLoS Pathog. 7, e1002017 (2011).
- Article PubMed ChemPort
Gantz, V. M. et al. Proc. Natl Acad. Sci. USA http://dx.doi.org/10.1073/pnas.1521077112(2015).

With This Genetic Engineering Technology, There’s No Turning Back

Designers of a “selfish” gene able to spread among mosquitoes say it could wipe out malaria, but the scientific community is at odds over whether or not we should do it.

By Antonio Regalado on November 23, 2015 http://www.technologyreview.com/news/543721/with-this-genetic-engineering-technology-theres-no-turning-back/

The students in Anthony James’s basement insectary at the University of California, Irvine, knew they’d broken the laws of evolution when they looked at the mosquitoes’ eyes.

By rights, the bugs, born from fathers with fluorescent red eyes and mothers with normal ones, should have come out only about half red. Instead, as they counted them, first a few and then by the hundreds, they found 99 percent had glowing eyes.

More important than the eye color is that James’s mosquitoes also carry genes that stop the malaria parasite from growing. If these insects were ever released in the wild, their “selfish” genetic cargo would spread inexorably through mosquito populations, and potentially stop the transmission of malaria.

The technology, called a “gene drive,” was built using the gene-editing technology known as CRISPR and is being reported by James, a specialist in mosquito biology, and a half dozen colleagues today in the Proceedings of the National Academy of Sciences.

A functioning gene drive in mosquitoes has been anticipated for more than a decade by public health organizations as a revolutionary novel way to fight malaria. Now that it’s a reality, however, the work raises questions over whether the technology is safe enough to ever be released into the wild.

“This is a major advance because it shows that gene drives will likely be effective in mosquitoes,” says Kevin Esvelt, a gene drive researcher at Harvard University’s Wyss Institute. “Technology is no longer the limitation.”

Highly efficient Cas9-mediated gene drive for population modification of the malaria vector mosquito Anopheles stephensi

Significance

Malaria continues to impose enormous health and economic burdens on the developing world. Novel technologies proposed to reduce the impact of the disease include the introgression of parasite-resistance genes into mosquito populations, thereby modifying the ability of the vector to transmit the pathogens. Such genes have been developed for the human malaria parasite Plasmodium falciparum. Here we provide evidence for a highly efficient gene-drive system that can spread these antimalarial genes into a target vector population. This system exploits the nuclease activity and target-site specificity of the Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR) system, which, when restricted to the germ line, copies a genetic element from one chromosome to its homolog with ≥98% efficiency while maintaining the transcriptional activity of the genes being introgressed.

Genetic engineering technologies can be used both to create transgenic mosquitoes carrying antipathogen effector genes targeting human malaria parasites and to generate gene-drive systems capable of introgressing the genes throughout wild vector populations. We developed a highly effective autonomous Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR)-associated protein 9 (Cas9)-mediated gene-drive system in the Asian malaria vector Anopheles stephensi, adapted from the mutagenic chain reaction (MCR). This specific system results in progeny of males and females derived from transgenic males exhibiting a high frequency of germ-line gene conversion consistent with homology-directed repair (HDR). This system copies an ∼17-kb construct from its site of insertion to its homologous chromosome in a faithful, site-specific manner. Dual anti-Plasmodium falciparum effector genes, a marker gene, and the autonomous gene-drive components are introgressed into ∼99.5% of the progeny following outcrosses of transgenic lines to wild-type mosquitoes. The effector genes remain transcriptionally inducible upon blood feeding. In contrast to the efficient conversion in individuals expressing Cas9 only in the germ line, males and females derived from transgenic females, which are expected to have drive component molecules in the egg, produce progeny with a high frequency of mutations in the targeted genome sequence, resulting in near-Mendelian inheritance ratios of the transgene. Such mutant alleles result presumably from nonhomologous end-joining (NHEJ) events before the segregation of somatic and germ-line lineages early in development. These data support the design of this system to be active strictly within the germ line. Strains based on this technology could sustain control and elimination as part of the malaria eradication agenda.

http://www.technologyreview.com/news/543181/crispr-gene-editing-to-be-tested-on-people-by-2017-says-editas/

CRISPR Gene Editing Trial

Posted in Auditory and vision, BioTechnology - Venture Creation, Venture Capital, Clinical & Translational, Clinical Genomics, CRISPR/Cas9 & Gene Editing, Curation, tagged CRISPR, familial blindness, gene editing on November 10, 2015| Leave a Comment »

CRISPR Gene Editing Trial

Larry H Bernstein, MD, FCAP, Curator

LPBI

CRISPR Gene Editing to Be Tested on People by 2017

A biotechnology company says it will test advanced gene-engineering methods to treat blindness.

By Antonio Regalado on November 5, 2015

Editas CEO Katrine Bosley

The biotechnology startup Editas Medicine intends to begin tests of a powerful new form of gene repair in humans within two years.

Speaking this week at the EmTech conference in Cambridge, Massachusetts, Editas CEO Katrine Bosley said the company hopes to start a clinical trial in 2017 to treat a rare form of blindness using CRISPR, a groundbreaking gene-editing technology.

If Editas’s plans move forward, the study would likely be the first to use CRISPR to edit the DNA of a person.

CRISPR technology was invented just three years ago but is so precise and cheap to use it has quickly spread through biology laboratories. Already, scientists have used it to generate genetically engineered monkeys, and the technique has stirred debate over whether modified humans are next (see “Engineering the Perfect Baby”).

Editas is one of several startups, including Intellia Therapeutics and CRISPR Therapeutics, that have plans to use the technique to correct DNA disorders that affect children and adults. Bosley said that because CRISPR can “repair broken genes” it holds promise for treating several thousand inherited disorders caused by gene mistakes, most of which, like Huntington’s disease and cystic fibrosis, have no cure.

Editas, which had not previously given a timeline for an initial human test of CRISPR, will try to treat one form of a rare eye disease called Leber congenital amaurosis, which affects the light-receiving cells of the retina.

The condition Editas is targeting affects only about 600 people in the U.S., says Jean Bennet, director of advanced retinal and ocular therapeutics at the University of Pennsylvania’s medical school. “The target that they have selected is fantastic; it has all the right characteristics in terms of making a correction easily,” says Bennett, who isn’t involved in the Editas study.

Children with LCA are born seeing only large, bright shapes, and infants are diagnosed when they don’t look into their mother’s eyes or react to colorful balloons. Their poor vision can progress to “stone cold blindness where everything is black,” says Bennett.

Editas picked the disease in part because it is relatively easy to address with CRISPR, Bosley said. The exact gene error is known, and the eye is easy to reach with genetic treatments. “It feels fast, but we are going at the pace science allows,” she said. There are still questions about how well gene-editing will work in the retina and whether side effects could be caused by unintentional changes to DNA.

Editas plans to deliver the CRISPR technology as a gene therapy. The treatment will involve injecting into the retina a soup of viruses loaded with the DNA instructions needed to manufacture the components of CRISPR, including a protein that can cut a gene at a precise location. Bosley said in order to treat LCA, the company intends to delete about 1,000 DNA letters from a gene called CEP290 in a patient’s photoreceptor cells.

After the edit, preliminary lab experiments show, the gene should function correctly again. Bosley said Editas still needs to test the approach further in the lab and in animals before a human study starts.

Editas was created by venture capital funds including Third Rock Ventures in 2013 and was cofounded by scientists including Feng Zhang of the MIT/Harvard Broad Institute. It has raised more than $160 million in capital, allowing it to pursue ideas for several treatments simultaneously, Bosley said.

Although the Editas study could be the first for CRISPR in humans, it wouldn’t be the first clinical study of gene editing. An older method called zinc fingers is already in testing to treat HIV infection by the biotechnology company Sangamo Biosciences. But the versatility and ease with which CRISPR can change DNA means it may outpace earlier approaches.

Theoretically, gene editing could be used to repair broken genes in any part of the body. But in practice it is difficult to make DNA repairs in most cell types, such as brain cells. The eye is an exception because doctors can inject treatment directly under the retina.

There is already a gene-therapy treatment for one form of LCA in late-stage clinical testing by Philadelphia biotech Spark Therapeutics, says Bennett, who helped develop that treatment. In that case, an entire, healthy version of a gene is being added to eye cells. Typically, gene therapy can only add genes, not edit them.

LCA has several different genetic causes, and standard gene therapy won’t work for the form of the disease Editas is looking at. That is because the required gene, CEP290, is too big to fit inside a virus, says Bennett, and so there is no easy way to add it.

By targeting an exceptionally rare illness, Editas may have an easier time getting a treatment tested and approved. However, the eventual cost of such a treatment could be extraordinarily high, given the small number of people who would need it. Bennett says only around 3,000 Americans have LCA, and about 20 percent of those have the form being targeted by Editas.

RNAi, CRISPR and Gene Expression

Posted in Biological Networks, Gene Regulation and Evolution, CANCER BIOLOGY & Innovations in Cancer Therapy, Cell Biology, Signaling & Cell Circuits, Chemical Biology and its relations to Metabolic Disease, Chemical Genetics, Clinical & Translational, CRISPR/Cas9 & Gene Editing, Curation, Developmental biology, Disease Biology, Disease Biology, Small Molecules in Development of Therapeutic Drugs, Gene Regulation, Genomic Expression, tagged Cancer - General, cell differentiation, CRISPR, Notch signaling, RNAi, stem cells on November 2, 2015| Leave a Comment »

RNAi, CRISPR and Gene Expression

Larry H. Bernstein, MD, FCAP, Curator

LPBI

2.2.16

2.2.16 RNAi, CRISPR and Gene Expression, Volume 2 (Volume Two: Latest in Genomics Methodologies for Therapeutics: Gene Editing, NGS and BioInformatics, Simulations and the Genome Ontology), Part 2: CRISPR for Gene Editing and DNA Repair

Down and Out with RNAi and CRISPR

Gene-Silencing and Gene-Disabling Techniques Are Moving To the Heart of Drug Discovery

MaryAnn Labant

Click Image To Enlarge +

In the future, CRISPR activators may provide more efficient ways to express not only wild-type but also mutant forms of genes under the endogenous promoter.

Arrayed CRISPR Screens

Click Image To Enlarge +

Tool Selection

Click Image To Enlarge +

Converging Technologies

The libraries alleviate concerns for false-positive or false-negative data. The high potency allows less reagent use; thus, more screens or validations can be conducted per library.

Validating Antibodies with RNAi

Unreliable antibody specificity is a widespread problem for researchers, but RNAi is assuaging scientists’ concerns as a validation method.

The method is not common among antibody suppliers—time and cost being the chief barriers to its adoption, although some companies are beginning to embrace RNAi validation.

Junk DNA Kept in Good Repair by Nuclear Membrane

The details appeared October 26 in Nature Cell Biology, in an article entitled, “Heterochromatic breaks move to the nuclear periphery to continue recombinational repair.”

Gene Found that Regulates Stem Cell Number Production

The gene Prkci promotes the generation of differentiated cells (red). However if Prkci activity is reduced or absent, neural stem cells (green) are promoted. [In Kyoung Mah]

Their study (“Atypical PKC-iota Controls Stem Cell Expansion via Regulation of the Notch Pathway”) was published in a Stem Cell Reports.

Atypical PKC-iota Controls Stem Cell Expansion via Regulation of the Notch Pathway

In Kyoung Mah,1 Rachel Soloff,2,3 Stephen M. Hedrick,2 and Francesca V. Mariani1, *

Stem Cell Reports (2015), http://dx.doi.org/10.1016/j.stemcr.2015.09.021

RESULTS

http://www.eurekalert.org/pub_releases/2015-10/uowh-mor102215.php

Mini-kidney organoids re-create disease in lab dishes

Posted in Cell Biology, Signaling & Cell Circuits, tagged CRISPR, kidney disease, miniature kidneys, Organoids, pluripotent stem cells on October 23, 2015| Leave a Comment »

Mini-kidney organoids re-create disease in lab dishes

Reporter: Irina Robu, PhD

Kidney disease affects about 700 million people worldwide and the costs are tremendous. Dialysis and kidney transplantation are the only options of kidney failure which can cause harmful side effects and poor quality-of-life.

To re-create human disease, Freedman and his colleagues used the gene-editing technique called CRISPR. They engineered mini-kidneys with genetic changes linked to two common kidney diseases, polycystic kidney disease and glomerulonephritis. The mini-kidney organoids are grown using genome editing to recreate human kidney disease in petri dishes. The achievement is published on Nature Communications, today October 23 and it paves the way for personalized drug discovery for kidney disease.

Pluripotent stem cells are used to grow the mini-kidney organoids. When treated with a chemical cocktail, the stem cell matured into structures that resemble miniature kidneys. The organoids contain filtering cells, blood vessel cells and tubules and developed characteristics of these diseases. Those with mutations in polycystic kidney disease genes formed balloon like, fluid filled sacks, called cysts, from kidney tubules. The organoids with mutations in podocalyxin, a gene linked to glomerulonephritis, lost connections between filtering cells.

Source

http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2881665/bin/nihms199923f2.jpg

A NEW ERA OF GENETIC MANIPULATION

Posted in Academic Publishing, Bacterial Resistance, Diagnostics and Lab Tests, Disease Biology, Small Molecules in Development of Therapeutic Drugs, Gene Regulation, Genetics & Pharmaceutical, Genome Biology, tagged biomarkers, Cas9, CRISPR, CRISPR/Cas9, Demet Sag, Dr. Sag, functional genomics, Functional TransGenomics, gene editing, genome structure and function, germline, Immunology, immunomodulation, innate immune defense, manipulation of gene, Microbiology, scientific, stem cels, translational genomics on April 14, 2015| Leave a Comment »

Demet Sag, PhD, CRA, GCP

Gene engineering and editing specifically are becoming more attractive. There are many applications derived from microbial origins to correct genomes in many organisms including human to find solutions in health.

There are four customizable DNA specific binding protein applications to edit the gene expression in translational genomics. The targeted DNA double-strand breaks (DSBs) could greatly stimulate genome editing through HR-mediated recombination events. We can mainly name these site-specific DNA DSBs:

meganucleases derived from microbial mobile genetic elements (Smith et al., 2006),
zinc finger (ZF) nucleases based on eukaryotic transcription factors (Urnov et al., 2005;Miller et al., 2007),
transcription activator-like effectors (TALEs) from Xanthomonasbacteria (Christian et al., 2010; Miller et al., 2011; Boch et al., 2009; Moscou and Bogdanove, 2009), and
most recently the RNA-guided DNA endonuclease Cas9 from the type II bacterial adaptive immune system CRISPR (Cong et al., 2013;Mali et al., 2013a).

There is a new ground breaking study published in Science by Valentino Gantz and Ethan Bier of the University of California, San Diego, described an approach called mutagenic chain reaction (MCR).

This group developed a new technology for editing genes that can be transferable change to the next generation by combining microbial immune defense mechanism, CRISPR/Cas9 that is the latest ground breaking technology for translational genomics with gene therapy-like approach.

In short, this so-called “mutagenic chain reaction” (MCR) introduces a recessive mutation defined by CRISPR/Cas9 that lead into a high rate of transferable information to the next generation. They reported that when they crossed the female MCR offspring to wild type flies, the yellow phenotype observed more than 95 percent efficiency.

Structural and Metagenomic Diversity of Cas9 Orthologs

(A) Crystal structure of Streptococcus pyogenes Cas9 in complex with guide RNA and target DNA.

(B) Canonical CRISPR locus organization from type II CRISPR systems, which can be classified into IIA-IIC based on their cas gene clusters. Whereas type IIC CRISPR loci contain the minimal set of cas9, cas1, andcas2, IIA and IIB retain their signature csn2 and cas4 genes, respectively.

(C) Histogram displaying length distribution of known Cas9 orthologs as described in UniProt, HAMAP protein family profile MF_01480.

(D) Phylogenetic tree displaying the microbial origin of Cas9 nucleases from the type II CRISPR immune system. Taxonomic information was derived from greengenes 16S rRNA gene sequence alignment, and the tree was visualized using the Interactive Tree of Life tool (iTol).

(E) Four Cas9 orthologs from families IIA, IIB, and IIC were aligned by ClustalW (BLOSUM). Domain alignment is based on the Streptococcus pyogenes Cas9, whereas residues highlighted in red indicate highly conserved catalytic residues within the RuvC I and HNH nuclease domains.

(Cell. Author manuscript; available in PMC 2015 Feb 27.Published in final edited form as:

Cell. 2014 Jun 5; 157(6): 1262–1278.doi: 10.1016/j.cell.2014.05.010)

The uniqueness of this study comes from:

There is a big difference between the new type of mutation and traditional mutation is expressivity of the character since previously mutations were passive and non-transferable at 100% rate. However, in classical Mendelian Genetics, only one fourth f the recessive traits can be presented in new generation. Yet, in this case this can be achieve about 97% plus transferred to new generation.

MCR alterations is active that is they convert matching sequences at the same target site so mutated sites took over the wild type character without degenerating by wild type alleles segregating independently during the breeding process

Therefore, the altered sequences routinely replace the wild type (original) sequences at that site. The data demonstrated that among 92 flies, only one female became wild type but remaining 41 females had yellow eyes yet all 50 males showed wild type eye coloring at the second generation.

The genetic engineering of the genome occurred in a single generation with high efficiency.

Their technique developed by Gantz and Bier had three basic parts:

Both somatic and germline cells expressed a Cas9 gene,

A guide RNA (gRNA) targeted to a genomic sequence of interest,

The Cas9/gRNA cassettes have the flanking homolog arms that matches the two genomic sequences immediately adjacent to either side of the target cut site

There are many applications in translational genomics that requires multiple steps to make it perfect for complicated organisms, such as plants, mosquitoes and human diseases.

Short Walk from Past to the Future of CRISPR/Cas9

The RNA-guided Cas9 nuclease from the microbial clustered regularly interspaced short palindromic repeats (CRISPR) adaptive immune system can be used to facilitate efficient genome engineering in eukaryotic cells by simply specifying a 20-nt targeting sequence within its guide RNA.

CRISPR/Cas systems are part of the adaptive immune system of bacteria and archaea, protecting them against invading nucleic acids such as viruses by cleaving the foreign DNA in a sequence-dependent manner.

The latest ground-breaking technology for genome editing is based on RNA-guided engineered nucleases, which already hold great promise due to their:

simplicity,
efficiency and
versality

Although CRISPR arrays were first identified in the Escherichia coli genome in 1987 (Ishino et al., 1987),

their biological function was not understood until 2005, when it was shown that the spacers were homologous to viral and plasmid sequences suggesting a role in adaptive immunity (Bolotin et al., 2005; Mojica et al., 2005; Pourcel et al., 2005).

Two years later, CRISPR arrays were confirmed to provide protection against invading viruses when combined with Cas genes (Barrangou et al., 2007).

The mechanism of this immune system based on RNA-mediated DNA targeting was demonstrated shortly thereafter (Brouns et al., 2008; Deltcheva et al., 2011; Garneau et al., 2010; Marraffini and Sontheimer, 2008).

The most widely used system is the type II clustered regularly interspaced short palindromic repeat (CRISPR)/Cas9 (CRISPR-associated) system from Streptococcus pyogenes (Jinek et al., 2012).

Then, five independent groups demonstrated that the two-component system was functional in eukaryotes (human, mouse and zebrafish), indicating that the other functions of the CRISPR locus genes were supported by endogenous eukaryotic enzymes (Cho et al., 2013, Cong et al., 2013, Hwang et al., 2013, Jinek et al., 2013 and Mali et al., 2013).

Beginning with target design, gene modifications can be achieved within as little as 1-2 weeks, and modified colonial cell lines can be derived within 2-3 weeks

Genome editing with site-specific nucleases.

Double-strand breaks induced by a nuclease at a specific site can be repaired either by non-homologous end joining (NHEJ) or homologous recombination (HR). In most cases, NHEJ causes random insertions or deletions (indels), which can result in frameshift mutations if they occur in the coding region of a gene, effectively creating a gene knockout.

Alternatively, when the DSB generates overhangs, NHEJ can mediate the targeted introduction of a double-stranded DNA template with compatible overhangs

Even though the generation of breaks in both DNA strands induces recombination at specific genomic loci, NHEJ is by far the most common DSB repair mechanism in most organisms, including higher plants, and the frequency of targeted integration by HR remains much lower than random integration.

Unlike its predecessors, the CRISPR/Cas9 system does not require any protein engineering steps, making it much more straightforward to test multiple gRNAs for each target gene

Unlike ZFNs and TALENs, the CRISPR/Cas9 system can cleave methylated DNA in human cells (Hsu et al., 2013), allowing genomic modifications that are beyond the reach of the other nucleases (Ding et al., 2013).

The main practical advantage of CRISPR/Cas9 compared to ZFNs and TALENs is the ease of multiplexing. The simultaneous introduction of DSBs at multiple sites can be used to edit several genes at the same time (Li et al., 2013; Mao et al., 2013) and can be particularly useful to knock out redundant genes or parallel pathways.

Finally, the open access policy of the CRISPR research community has promoted the widespread uptake and use of this technology in contrast, for example, to the proprietary nature of the ZFN platform.

The community provides access to plasmids (e.g., via the non-profit repository Addgene), web tools for selecting gRNA sequences and predicting specificity:

http://cbi.hzau.edu.cn/ cgi-bin/CRISPR; http://www.genome.arizona.edu/crispr/; and http:// http://www.rgenome.net/cas-offinder,
http://www.e-crisp.org/E-CRISP/index. html
hosts active discussion groups (e.g.: https://groups.google. com/forum/#!forum/crispr).

Downside:

One area that will likely need to be addressed when moving to more complex genomes, for instance, is off-target CRISPR/Cas9 activity since fruit fly has only four chromosomes and less likely to have off-target effects. However, this study provided proof of principle.

Yet, this critics is not new since one of the few criticisms of the CRISPR/Cas9 technology is the relatively high frequency of off-target mutations reported in some of the earlier studies (Cong et al., 2013; Fu et al., 2013; Hsu et al., 2013; Jiang et al., 2013a; Mali et al., 2013; Pattanayak et al., 2013).

Several strategies have been developed to reduce off-target genome editing, the most important of which is the considered design of the gRNA.

fusions of catalytically inactive Cas9 and FokI nuclease have been generated, and these show comparable efficiency to the nickases but substantially higher (N140-fold) specificity than the wild-type enzyme (Guilinger et al., 2014; Tsai et al., 2014)

Altering the length of the gRNA can also minimize non-target modifications. Guide RNAs with two additional guanidine residues at the 5′ end were able to avoid off-target sites more efficiently than normal gRNAs but were also slightly less active at on-target sites (Cho et al., 2014)

What more:

The CRISPR/Cas9 system can be used for several purposes in addition to genome editing:

The ectopic regulation of gene expression, which can provide useful information about gene functions and can also be used to engineer novel genetic regulatory circuits for synthetic biology applications.

The external control of gene expression typically relies on the use of inducible or repressible promoters, requiring the introduction of a new promoter and a particular treatment (physical or chemical) for promoter activation or repression.

Disabled nucleases can be used to regulate gene expression because they can still bind to their target DNA sequence. This is the case with the catalytically inactive version of Cas9 which is known as dead Cas9 (dCas9).

Preparing the host for an immunotherapy is possible if it is combined with TLR mechanism:

On the other hand, the host mechanism needs to be review carefully for the design of an effective outcome.

The mechanism of microbial response and infectious tolerance are complex.

During microbial responses, Toll-like receptors (TLRs) play a role to differentiate and determine the microbial structures as a ligand to initiate production of cytokines and pro-inflammatory agents to activate specific T helper cells.

Uniqueness of TLR comes from four major characteristics of each individual TLR :

ligand specificity,
signal transduction pathways,
expression profiles and
cellular localization.

Thus, TLRs are important part of the immune response signaling mechanism to initiate and design adoptive responses from innate (naïve) immune system to defend the host.

TLRs are expressed cell type specific patterns and present themselves on APCs (DCs, MQs, monocytes) with a rich expression levels Specific TLR stimulat ion links innate and acquired responses through simple recognition of pathogen-associated molecular patterns (PAMPs) or co-stimulation of PAMPs with other TLR or non-TLR receptors, or even better with proinflammatory cytokines.

Some examples of ligand – TLR specificity shown in Table1, which are bacterial lipopeptides, Pam3Cys through TLR2, double stranded (ds) RNAs through TLR3, lipopolysaccharide (LPS) through TLR4, bacterial flagellin through TLR5, single stranded RNAs through TLR7/8, synthetic anti-viral compounds imiquinod through TLR 7 and resiquimod through TLR8, unmethylated CpG DNA motifs through TLR9.

The specificity is established by correct pairing of a TLR with its proinflammatory cytokine(s), so that these permutations influence creation and maintenance of cell differentiat ion.

Immunotherapy: The immune cells can be used as a sensor to scavenger the circulating malformed cells in vivo diagnostics or attack and remember them, for instance, relapse of cancer, re-infection with a same or similar agent (bacteria or virus) etc.

Not only using unique microbial and other model organism properties but also using the human host defense mechanism during innate immune responses may bring a new combat to create a new method of precision medicine. This can be a new type of immunotherapy, immune cell mediated gene therapy or vaccine even a step for an in vivo diagnostics.

Molecular Genetics took a long road from discovery of restriction enzymes, developing PCR assays, cloning were the beginning. Now, having technology to sequence and compare the sequences between organisms also help to design more sophisticated methods.

Generating mutant lines in Drosophila with the classical genetics methods relies on P elements, a type of transposon and balancers after crossing selected flies with specific markers. This fly pushing is a very tedious work but powerful to identify primary pathways, mechanisms and gene interactions in system and translational genomics.

Thus, Microbial Immunomodulation is an important factor not only using the microorganisms or their mechanisms but also modulating the immune cells based on the host interaction may generate new types of diagnostics and targeted therapy tools.

Microbial immunomodulation. Microbes from the environment, and from the various microbiota, modulate the immune system. Some of this is due to direct effects of defined microbial products on elements of the immune system. But modulation of the immune system also secondarily alters the host–microbiota relationship and leads to changes in the composition of the microbiota, and so to further changes in immunoregulation (shown as indirect pathways). At the end of the day balance is the key for survival.

Graham A. W. Rook,^*,1 Christopher A. Lowry,² and Charles L. Raison³Microbial ‘Old Friends’, immunoregulation and stress resilience Evol Med Public Health. 2013; 2013(1): 46–64. Published online 2013 Apr 9. doi: 10.1093/emph/eot004 PMCID: PMC3868387

CRISPR-Cas9 mediated NHEJ in transient transfection experiments.

Table 1.

Species	Transformation method	Cas9 codon optimization	Promoters (Cas9, gRNA)	Target	Mutation frequency	Detection method	Off-target (no. of sites analyzed)	Detection method	Multiplex (deletion)	Reference
Arabidopsis thaliana	PEG-protoplast transfection	Arabidopsis (with intron)	CaMV35SPDK, AtU6	PDS3<comma> FLS2	1.1–5.6%	PCR + sequencing				Li et al. (2013)
A. thaliana	Leaf agroinfiltration	Arabidopsis (with intron)	CaMV35SPDK, AtU6	PDS3	2.70%	PCR + sequencing			Yes (48 bp)	Li et al. (2013)
A. thaliana	PEG-protoplast transfection	Arabidopsis (with intron)	CaMV35SPDK, AtU6	RACK1b<comma> RACK1c	2.5–2.7%	PCR + sequencing	No (1 site)	PCR + sequencing		Li et al. (2013)
A. thaliana	Leaf agroinfiltration	C. reinhardtii	CaMV35S, AtU6	Co-transfected GFP	n.a.	Pre-digested PCR + RE				Jiang et al. 2013a and Jiang et al. 2013b
Nicotiana benthamiana	PEG-protoplast transfection	Arabidopsis (with intron)	CaMV35SPDK, AtU6	PDS3	37.7–38.5%	PCR + sequencing				Li et al. (2013)
N. benthamiana	Leaf agroinfiltration	Arabidopsis (with intron)	CaMV35SPDK, AtU6	PDS3	4.80%	PCR + sequencing				Li et al. (2013)
N. benthamiana	Leaf agroinfiltration	Human	CaMV35S, AtU6	PDS	1.8–2.4%	PCR + RE	No (18 sites)	PCR + RE		Nekrasov et al. (2013)
N. benthamiana	Leaf agroinfiltration	C. reinhardtii	CaMV35S, AtU6	Co-transfected GFP	n.a.	pre-digested PCR + RE				Jiang et al. 2013a and Jiang et al. 2013b
N. benthamiana	Leaf agroinfiltration	Human	CaMV35S, CaMV35S	PDS	12.7–13.8%					Upadhyay et al. (2013)
Nicotiana tabacum	PEG-protoplast transfection	Tobacco	2xCaMV35S, AtU6	PDS<comma> PDR6	16.27–20.3%	PCR + RE			Yes (1.8 kb)	Gao et al. (2014)
Oryza sativa	PEG-protoplast transfection	Rice	2xCaMV35S, OsU3	PDS<comma> BADH2<comma> MPK2<comma> Os02g23823	14.5–38.0%	PCR + RE	Noa (3 sites)	PCR + RE		Shan et al. (2013)
O. sativa	PEG-protoplast transfection	Human	CaMV35S, OsU3 or OsU6	MPK5	3–8%	RE + qPCR and T7E1 assay	No (2 sites) Yes (1 site with a mismatch at position 12)	RE + PCR		Xie and Yang (2013)
O. sativa	PEG-protoplast transfection	Rice	CaMV35S, OsU6	SWEET14	n.a.	pre-digested PCR + RE				Jiang et al. 2013a and Jiang et al. 2013b
O. sativa	PEG-protoplast transfection	Rice	ZmUbi, OsU6	KO1 KOL5; CPS4 CYP99A2; CYP76M5 CYP76M6	n.a.	PCR + sequencing			Yes (115<comma> 170<comma> 245 kb)	Zhou et al. (2014)
Triticum aestivum	PEG-protoplast transfection	Rice	2xCaMV35S, TaU6	MLO	28.50%	PCR + RE				Shan et al. (2013)
T. aestivum	PEG-protoplast transfection	Plant	ZmUbi, TaU6	MLO-A1	36%	T7E1				Wang et al. 2014a and Wang et al. 2014b
T. aestivum	Agrotransfection of cells from immature embryos	Human	CaMV35S, CaMV35S	PDS<comma> INOX	18–22%	PCR + sequencing				Upadhyay et al. (2013)
T. aestivum	Agrotransfection of cells from immature embryos	Human	CaMV35S, CaMV35S	INOX		PCR + sequencing	No*	PCR + RE	Yes (53 bp)	Upadhyay et al. (2013)
Zea mays	PEG-protoplast transfection	Rice	2xCaMV35S, ZmU3	IPK	16.4–19.1%	PCR + RE				Liang et al. (2014)
Citrus sinensis	Leaf agroinfiltration	Human	CaMv35S, CaMV35S	PDS	3.2–3.9%	PCR + RE	No (8 sites)	PCR + RE		Jia et al. (2014)

References:

A brief overview of CRISPR-mediated immunity and explain how the emerging new properties of this defense system are being repurposed for genome engineering in bacteria, yeast, human cells, insects, fish, worms, plants, frogs, pigs, and rodents.

Also look at F1000Prime Rep. 2014; 6: 3. For the list of microorganisms use in CRISPR applications.

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2014/06/11
Published

Koch Institute for Integrative Cancer Research @MIT – Summer Symposium 2014: RNA Biology, Cancer and Therapeutic Implications, June 13, 2014 8:30AM – 4:30PM, Kresge Auditorium @MIT

2014/06/04
Published

An expanded-DNA Biology from Scripps Research Institute: Beyond A-T and C-G: Applications for new Medicines and Nanotechnology

2014/05/11
Published

Foundation Medicine reported 4,702 Clinical Tests in Q1, 715 were the FoundationOne Heme Cancer Test, average Reimbursement of $3,400 per Test

2014/05/08
Published

The Cancer Research Concentration @ Leaders in Pharmaceutical Business Intelligence

2014/05/06
Published

Aviva’s Perspective on New Oncology Database Asset Positioning by Business Scenario – Password protected

2014/05/05
Published

Cancer Research: Curations and Reporting: Aviva Lev-Ari, PhD, RN

2014/04/20
Published

Predictions on Biotech Sector’s Two-year Boom

Demet Sag, Ph.D., CRA, GCP

2014/03/27
Published

DNA: One man’s trash is another man’s treasure, but there is no JUNK after all

2013/06/24
Published

Ribozymes and RNA Machines – Work of Jennifer A. Doudna

2013/04/15
Published

Zebrafish—Susceptible to Cancer

2013/04/02
Published

Diagnosing Diseases & Gene Therapy: Precision Genome Editing and Cost-effective microRNA Profiling

2013/03/28
Published

Directions for Genomics in Personalized Medicine

2013/01/27
Published

About the author:

Dr Sag has a Bachelor’s degree in Basic and Industrial Microbiology as a Sum cum Laude among 450 graduating class of Science faculty, an MSc in Microbial Engineering and Biotechnology (Bioprocessing improvement) and PhD in Molecular and Developmental Genetics (Functional Genome and Stem Cell Biology).

She is an translational functional genomic scientist to develop diagnostics and targeted therapies by non-invasive methods for personalized medicine from bench to bedside and engineering tools through clinical trials and regulatory affairs.

You may contact with her at 858-729-4942 or by demet.sag@gmail.com if you have questions.