scholarly journals Modeling the Manipulation of Natural Populations by the Mutagenic Chain Reaction

Genetics ◽  
2015 ◽  
Vol 201 (2) ◽  
pp. 425-431 ◽  
Author(s):  
Robert L. Unckless ◽  
Philipp W. Messer ◽  
Tim Connallon ◽  
Andrew G. Clark
Keyword(s):  
Natural Populations ◽  
Chain Reaction ◽  
Mutagenic Chain Reaction

scholarly journals Theoretical consequences of the Mutagenic Chain Reaction for manipulating natural populations

2015 ◽  
Author(s):  
Robert Unckless ◽  
Philipp Messer ◽  
Andrew Clark
Keyword(s):  
Critical Point ◽  
High Frequency ◽  
Natural Populations ◽  
Meiotic Drive ◽  
Fitness Cost ◽  
Chain Reaction ◽  
Internal Equilibrium ◽  
Rapid Fixation ◽  
Genetic Technologies ◽  
Mutagenic Chain Reaction

The use of recombinant genetic technologies for population manipulation has mostly remained an abstract idea due to the lack of a suitable means to drive novel gene constructs to high frequency in populations. Recently Gantz and Bier showed that the use of CRISPR/Cas9 technology could provide an artificial drive mechanism, the so-called Mutagenic Chain Reaction (MCR), which could lead to rapid fixation of even a deleterious introduced allele. We establish the equivalence of this system to models of meiotic drive and review the results of simple models showing that, when there is a fitness cost to the MCR allele, an internal equilibrium exists that is usually unstable. Introductions must be at a frequency above this critical point for the successful invasion of the MCR allele. These modeling results have important implications for application of MCR in natural populations.

Molecular Differentiation of Two Strains of the Parasitoid Anisopteromalus calandrae (Hymenoptera: Pteromalidae) Using Specific PCR Primers

2004 ◽  
Vol 39 (1) ◽  
pp. 1-10 ◽  
Author(s):  
Yu Cheng Zhu ◽  
Alan K. Dowdy ◽  
James E. Baker
Keyword(s):  
Dna Markers ◽  
Natural Populations ◽  
Pcr Amplification ◽  
Pcr Primers ◽  
Dna Fragments ◽  
Chain Reaction ◽  
Specific Primers ◽  
Specific Pcr ◽  
Anisopteromalus Calandrae ◽  
Polymerase Chain

Two strains (Sav and Bam) of the parasitoid Anisopteromalus calandrae (Howard) (Hymenoptera: Pteromalidae) showed different sensitivity to organophosphate insecticides. By using polymerase chain reaction (PCR) and DNA sequencing, we demonstrated clear molecular difference between these two strains. DNA markers that are specific for the Bam strain were developed, and PCR-generated DNA fragments were cloned and sequenced. Two DNA fragments unique to the Bam strain contained 365 and 584 nucleotides. A pair of specific primers was designed from each fragment. PCR-amplification of the DNA from individual wasps generated fragments of the expected sizes only in the Bam strain. Studies conducted on F1 and F2 hybrids produced from crossing and backcrossing between resistant and susceptible strains indicated that these DNA markers are located on mitochondria and inherited exclusively maternally. Probes developed from these fragments may be used in assessing genetic information of natural populations and in studies on physiological or biochemical differences between the strains of this beneficial insect.

scholarly journals Gene flow and cross-mating in Plasmodium falciparum in households in a Tanzanian village

Parasitology ◽  
1995 ◽  
Vol 111 (4) ◽  
pp. 433-442 ◽  
Author(s):  
H. A. Babiker ◽  
J. D. Charlwood ◽  
T. Smith ◽  
D. Walliker
Keyword(s):  
Plasmodium Falciparum ◽  
Gene Flow ◽  
Spatial Clustering ◽  
Natural Populations ◽  
Surface Proteins ◽  
Chain Reaction ◽  
Allelic Variants ◽  
Genes Encoding ◽  
Capture Recapture ◽  
Polymerase Chain

SUMMARYThe diversity of the genes encoding 2 merozoite surface proteins (MSP-1 and MSP-2) of Plasmodium falciparum has been examined in parasites infecting members of 4 households in a village in Tanzania. The polymerase chain reaction (PCR) was used to characterize allelic variants of these genes by the sizes and sequences of regions of tandemly repeated bases in each gene. In each household extensive polymorphism was detected among parasites in the inhabitants and in infected mosquitoes caught in their houses. Similar frequencies of the alleles of these genes were observed in all households. Capture-recapture data indicated that both Anopheles gambiae and A.funestus freely dispersed among households in the hamlet. The results confirm that cross-mating and gene flow occur extensively among the parasites, and are discussed within the context of spatial clustering of natural populations of P. falciparum.

scholarly journals Autocatalytic–Protection for an Unknown Locus CRISPR–Cas Countermeasure for Undesired Mutagenic Chain Reactions

2020 ◽  
Author(s):  
Ethan Schonfeld ◽  
Elan Schonfeld ◽  
Dan Schonfeld
Keyword(s):  
Genomic Sequence ◽  
Homing Endonuclease ◽  
Gene Drive ◽  
Proof Of Concept ◽  
Chain Reaction ◽  
Gene Encoding ◽  
Chain Reactions ◽  
Homology Directed Repair ◽  
Novel Approach ◽  
Mutagenic Chain Reaction

AbstractThe mutagenic chain reaction (MCR) is a genetic tool to use a CRISPR–Cas construct to introduce a homing endonuclease, allowing gene drive to influence whole populations in a minimal number of generations1,2,3. The question arises: if an active genetic terror event is released into a population, could we prevent the total spread of the undesired allele4? Thus far, MCR protection methods require knowledge of the terror locus5. Here we introduce a novel approach, an autocatalytic-Protection for an Unknown Locus (a-PUL), whose aim is to spread through a population and arrest and decrease an active terror event’s spread without any prior knowledge of the terror-modified locus, thus allowing later natural selection and ERACR drives to restore the normal locus6. a-PUL, using a mutagenic chain reaction, includes (i) a segment encoding a non-Cas9 endonuclease capable of homology-directed repair suggested as Type II endonuclease Cpf1 (Cas12a), (ii) a ubiquitously-expressed gene encoding a gRNA (gRNA1) with a U4AU4 3′-overhang specific to Cpf1 and with crRNA specific to some desired genomic sequence of non-coding DNA, (iii) a ubiquitously-expressed gene encoding two gRNAs (gRNA2/gRNA3) both with tracrRNA specific to Cas9 and crRNA specific to two distinct sites of the Cas9 locus, and (iv) homology arms flanking the Cpf1/gRNA1/gRNA2/gRNA3 cassette that are identical to the region surrounding the target cut directed by gRNA17. We demonstrate the proof-of-concept and efficacy of our protection construct through a Graphical Markov model and computer simulation.

scholarly journals Characterization of functional SSR markers in Prosopis alba and their transferability across Prosopis species

2015 ◽  
Vol 24 (2) ◽  
pp. eRC04 ◽  
Author(s):  
María F. Pomponio ◽  
Cintia Acuña ◽  
Vivien Petreath ◽  
Diego L. Lauenstein ◽  
Susana M. Poltri ◽  
...  
Keyword(s):  
Ssr Markers ◽  
Polymorphic Information Content ◽  
Natural Populations ◽  
Functional Markers ◽  
Chain Reaction ◽  
Prosopis Alba ◽  
Average Value ◽  
Polymerase Chain ◽  
Simple Sequence

<p><em>Aim of study</em>: The aim of the study was to characterize functional microsatellite markers in <em>Prosopis alba</em> and examine the transferability to species from the <em>Prosopis</em> genus.</p><p><em>Area of the study</em>: samples were obtained from natural populations of Argentina.<strong></strong></p><p><em>Material and Methods</em>: Eleven SSR functional markers related to stress and metabolism were amplified in a sample of 152 genotypes from <em>P.</em> <em>alba</em>, <em>P. denudans</em>, <em>P. hassleri</em> <em>P. chilensis</em>, <em>P. flexuosa</em>, and interspecific hybrids.</p><p><em>Main results:</em> In <em>P. alba</em>, the PIC average value was 0.36; and 6 out of the 11 primers showed high values of polymorphism ranging from 0.40 to 0.71. The cross-species transferability was high with high percentages of polymorphic loci.</p><p><em>Research highlights</em>: The SSR markers developed in <em>P.alba</em> were easily transferred to other <em>Prosopis</em> species which did not have functional markers.</p><p><strong>Keywords</strong>: genetic variation; functional markers; microsatellites; prosopis.</p><p><strong>Abbreviations: </strong>PIC: Polymorphic Information Content; PCR: Polymerase Chain Reaction; SSR: Simple Sequence Repeat.</p>

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