Introduction. Clustered-Regularly Interspaced Short Palindromic Repeats (CRISPR), and CRISPR associated (Cas) protein (CRISPR/Cas) structures were first identified in E. coli in 1987 and guard prokaryotic cells from any invading pathogens, harmful events and plasmids by recognizing and cutting foreign nucleic acid sequences that contain short palindromic repeats spacer sequences. Several genome editing approaches have been developed based on these mechanisms; the most recent is known as CRISPR/Cas. Before the CRISPR technique was revealed in 2012, editing the genomes of plants and animals took many years and cost hundreds of thousands of dollars. Thus, CRISPR/Cas has attracted significant interest in the scientific community, especially for disease diagnosis and treatment, as it is quicker, less expensive and more precise than other genome editing approaches. The evidence from gene mutations in specific patients generated using CRISPR/Cas can assist in the prediction of the optimal treatment schedule for individual patients and for innovation purposes in other researches like replication in cell culture of coronaviruses like severe acute respiratory syndrome coronavirus-2 (SARS-CoV2 or COVID-19). However, in numerous situations, the effects of the furthermost significant driver mutations are not yet understood and interpretation of the optimal treatment is impossible. CRISPR/Cas classifications feature highly sensitive and selective tools for the detection of various target genes. When we see the next steps of genomic research, it is obvious that genome-wide association studies are relatively new way to identify the genes involved in human disease. Furthermore, CRISPR/Cas provides a tool to manipulate non-coding regions and will thus accelerate examination of these poorly characterized regions of the genome and play a vital role in the progress of whole genome libraries. Aim. We aimed to review the history of CRISPR/Cas, the mechanisms of CRISPR techniques, its current status as a tool for studying both natural mutations and genomic manipulations, and explore how CRISPR/Cas may improve the treatment of diseases.
Introduction. Clustered-Regularly Interspaced Short Palindromic Repeats (CRISPR), and CRISPR associated (Cas) protein (CRISPR/Cas) structures were first identified in E. coli in 1987 and guard prokaryotic cells from any invading pathogens, harmful events and plasmids by recognizing and cutting foreign nucleic acid sequences that contain short palindromic repeats spacer sequences. Several genome editing approaches have been developed based on these mechanisms; the most recent is known as CRISPR/Cas. Before the CRISPR technique was revealed in 2012, editing the genomes of plants and animals took many years and cost hundreds of thousands of dollars. Thus, CRISPR/Cas has attracted significant interest in the scientific community, especially for disease diagnosis and treatment, as it is quicker, less expensive and more precise than other genome editing approaches. The evidence from gene mutations in specific patients generated using CRISPR/Cas can assist in the prediction of the optimal treatment schedule for individual patients and for innovation purposes in other researches like replication in cell culture of coronaviruses like severe acute respiratory syndrome coronavirus-2 (SARS-CoV2 or COVID-19). However, in numerous situations, the effects of the furthermost significant driver mutations are not yet understood and interpretation of the optimal treatment is impossible. CRISPR/Cas classifications feature highly sensitive and selective tools for the detection of various target genes. When we see the next steps of genomic research, it is obvious that genome-wide association studies are relatively new way to identify the genes involved in human disease. Furthermore, CRISPR/Cas provides a tool to manipulate non-coding regions and will thus accelerate examination of these poorly characterized regions of the genome and play a vital role in the progress of whole genome libraries. Aim. We aimed to review the history of CRISPR/Cas, the mechanisms of CRISPR techniques, its current status as a tool for studying both natural mutations and genomic manipulations, and explore how CRISPR/Cas may improve the treatment of diseases.
Cutaneous myiasis caused by the Chrysomya bezziana in Asian and African countries is common in wild and domestic mammals. A herd of Persian fallow deer (n=80, consisting of adult and young male and female animals) with an average age range of 3 months to 6 years was viewed. Observed were 40 deaths putting the heard near to extinction. The animals were found with traumatic cutaneous wounds mostly in one ear, the eyes and head as well as the ventral part of the neck. The ears were necrotised and could no longer remain upright; the wounds were full of maggots of different sizes and stages of development. Based on morphological features, the collected larvae were examined by a central Khuzestan veterinary laboratory and identified as C. bezziana larvae. This is the first ever occurrence of C. bezziana that caused such a population reduction of these wonderful animals in a herd of Persian fallow deer held under the supervision of Iranian Nature Preservation Organization and kept at Helveh Park in Shush county (East-South of Iran) where original ecology and its treatment and control of myiasis have been discussed. This paper is apparently the first report of an infestation of cutaneous myiasis due to C. bezziana in Persian fallow deer. Also we report high infestation Rhipicephalus microplus as an important ectoparasite of these Persian fallow deer that has been never discussed before.
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