A Framework for Orthology Assignment from Gene Rearrangement Data

AbstractALK gene rearrangement was observed in 3%–5% of non-small cell lung cancer patients, and multiple ALK-tyrosine kinase inhibitors (TKIs) have been sequentially used. Multiple ALK-TKI resistance mutations have been identified from the patients, and several compound mutations, such as I1171N + F1174I or I1171N + L1198H are resistant to all the approved ALK-TKIs. In this study, we found that gilteritinib has an inhibitory effect on ALK-TKI–resistant single mutants and I1171N compound mutants in vitro and in vivo. Surprisingly, EML4-ALK I1171N + F1174I compound mutant-expressing tumors were not completely shrunk but regrew within a short period of time after alectinib or lorlatinib treatment. However, the relapsed tumor was markedly shrunk after switching to the gilteritinib in vivo model. In addition, gilteritinib was effective against NTRK-rearranged cancers including entrectinib-resistant NTRK1 G667C-mutant and ROS1 fusion-positive cancer.

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The first two complete mitogenomes of the order Apodida from deep-sea chemoautotrophic environments: New insights into the gene rearrangement, origin and evolution of the deep-sea sea cucumbers

Comparative Biochemistry and Physiology Part D Genomics and Proteomics ◽

10.1016/j.cbd.2021.100839 ◽

2021 ◽

Vol 39 ◽

pp. 100839

Author(s):

Shao'e Sun ◽

Zhongli Sha ◽

Ning Xiao

Keyword(s):

Deep Sea ◽

Gene Rearrangement ◽

Sea Cucumbers ◽

Origin And Evolution

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Novel gene rearrangement in the mitochondrial genome of Muraenesox cinereus and the phylogenetic relationship of Anguilliformes

Scientific Reports ◽

10.1038/s41598-021-81622-9 ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Kun Zhang ◽

Kehua Zhu ◽

Yifan Liu ◽

Hua Zhang ◽

Li Gong ◽

...

Keyword(s):

Mitochondrial Genome ◽

Gene Rearrangement ◽

Tandem Duplication ◽

Mitochondrial Gene ◽

Gene Arrangement ◽

Protein Coding ◽

Muraenesox Cinereus ◽

Complete Mitogenome ◽

Relationship Of ◽

Rna Genes

AbstractThe structure and gene sequence of the fish mitochondrial genome are generally considered to be conservative. However, two types of gene arrangements are found in the mitochondrial genome of Anguilliformes. In this paper, we report a complete mitogenome of Muraenesox cinereus (Anguilliformes: Muraenesocidae) with rearrangement phenomenon. The total length of the M. cinereus mitogenome was 17,673 bp, and it contained 13 protein-coding genes, two ribosomal RNAs, 22 transfer RNA genes, and two identical control regions (CRs). The mitochondrial genome of M. cinereus was obviously rearranged compared with the mitochondria of typical vertebrates. The genes ND6 and the conjoint trnE were translocated to the location between trnT and trnP, and one of the duplicated CR was translocated to the upstream of the ND6. The tandem duplication and random loss is most suitable for explaining this mitochondrial gene rearrangement. The Anguilliformes phylogenetic tree constructed based on the whole mitochondrial genome well supports Congridae non-monophyly. These results provide a basis for the future Anguilliformes mitochondrial gene arrangement characteristics and further phylogenetic research.

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Mitochondrial Genomes from Two Specialized Subfamilies of Reduviidae (Insecta: Hemiptera) Reveal Novel Gene Rearrangements of True Bugs

Genes ◽

10.3390/genes12081134 ◽

2021 ◽

Vol 12 (8) ◽

pp. 1134

Author(s):

Fei Ye ◽

Hu Li ◽

Qiang Xie

Keyword(s):

Gene Rearrangement ◽

Hot Spot ◽

Phylogenetic Analyses ◽

Mitochondrial Gene ◽

Deep Understanding ◽

Gene Arrangement ◽

Mitochondrial Genomes ◽

Current View ◽

Novel Gene ◽

Spot Group

Reduviidae, a hyper-diverse family, comprise 25 subfamilies with nearly 7000 species and include many natural enemies of crop pests and vectors of human disease. To date, 75 mitochondrial genomes (mitogenomes) of assassin bugs from only 11 subfamilies have been reported. The limited sampling of mitogenome at higher categories hinders a deep understanding of mitogenome evolution and reduviid phylogeny. In this study, the first mitogenomes of Holoptilinae (Ptilocnemus lemur) and Emesinae (Ischnobaenella hainana) were sequenced. Two novel gene orders were detected in the newly sequenced mitogenomes. Combined 421 heteropteran mitogenomes, we identified 21 different gene orders and six gene rearrangement units located in three gene blocks. Comparative analyses of the diversity of gene order for each unit reveal that the tRNA gene cluster trnI-trnQ-trnM is the hotspot of heteropteran gene rearrangement. Furthermore, combined analyses of the gene rearrangement richness of each unit and the whole mitogenome among heteropteran lineages confirm Reduviidae as a ‘hot-spot group’ of gene rearrangement in Heteroptera. The phylogenetic analyses corroborate the current view of phylogenetic relationships between basal groups of Reduviidae with high support values. Our study provides deeper insights into the evolution of mitochondrial gene arrangement in Heteroptera and the early divergence of reduviids.

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Detection of New Translocation in Infant Twins with Concordant ALL and Discordant Outcome

Pediatric Reports ◽

10.3390/pediatric13010002 ◽

2020 ◽

Vol 13 (1) ◽

pp. 9-14

Author(s):

Golamreza Bahoush ◽

Maryam Vafapour ◽

Roxana Kariminejad

Keyword(s):

Gene Rearrangement ◽

Cytogenetic Study ◽

Lymphoblastic Leukemia ◽

Monozygotic Twins ◽

Protective Role ◽

Genetic Studies ◽

Cytogenetic Testing ◽

The Difference ◽

Special Case ◽

Mll Gene Rearrangement

About 2–5% of acute lymphoblastic leukemia (ALL) cases in pediatric patients are infants with an unfavorable prognosis because of high relapse probability. Early detection of the disease is, therefore, very important. Despite the fact that leukemia in twins occurs rarely, more attention has been paid to it in genetic studies. In the present study, through cytogenetic testing, a special case of concordant ALL in monozygotic twins was presented with different outcomes. In spite of an acceptable initial consequence to medical treatment in twins, in another brother (Twin B), early relapse was observed. In the cytogenetic study, both twins expressed t (4; 11) (q21; q23) while twin A expressed t (2; 7) (p10; q10). No cases have previously reported this mutation. Whether this translocation has a protective role for leukemia with mixed-lineage leukemia (MLL) gene rearrangement is still unclear. The difference in the translocation identified in the identical twins is also subject to further investigations.

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A unique case of adamantinoma-like Ewing sarcoma in the calcaneus, exhibiting prominent squamous differentiation and displaying EWSR1 gene rearrangement

Skeletal Radiology ◽

10.1007/s00256-021-03831-7 ◽

2021 ◽

Author(s):

Bharat Rekhi ◽

Rushabh Kothari ◽

Sanjeev Shah ◽

Omshree Shetty ◽

Mandip C. Shah

Keyword(s):

Ewing Sarcoma ◽

Gene Rearrangement ◽

Squamous Differentiation ◽

Unique Case ◽

Ewsr1 Gene

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Evaluation of Positive T- and B-Cell Gene Rearrangement Studies Among Patients Without a Definitive Diagnosis by Other Assays

American Journal of Clinical Pathology ◽

10.1093/ajcp/aqz112.067 ◽

2019 ◽

Vol 152 (Supplement_1) ◽

pp. S35-S36

Author(s):

Hadrian Mendoza ◽

Christopher Tormey ◽

Alexa Siddon

Keyword(s):

T Cell ◽

False Positive ◽

Gene Rearrangement ◽

Hematologic Malignancy ◽

False Negative ◽

False Positives ◽

False Negatives ◽

True Negative ◽

Flow Cytometric ◽

Pathology Reports

Abstract In the evaluation of bone marrow (BM) and peripheral blood (PB) for hematologic malignancy, positive immunoglobulin heavy chain (IG) or T-cell receptor (TCR) gene rearrangement results may be detected despite unrevealing results from morphologic, flow cytometric, immunohistochemical (IHC), and/or cytogenetic studies. The significance of positive rearrangement studies in the context of otherwise normal ancillary findings is unknown, and as such, we hypothesized that gene rearrangement studies may be predictive of an emerging B- or T-cell clone in the absence of other abnormal laboratory tests. Data from all patients who underwent IG or TCR gene rearrangement testing at the authors’ affiliated VA hospital between January 1, 2013, and July 6, 2018, were extracted from the electronic medical record. Date of testing; specimen source; and morphologic, flow cytometric, IHC, and cytogenetic characterization of the tissue source were recorded from pathology reports. Gene rearrangement results were categorized as true positive, false positive, false negative, or true negative. Lastly, patient records were reviewed for subsequent diagnosis of hematologic malignancy in patients with positive gene rearrangement results with negative ancillary testing. A total of 136 patients, who had 203 gene rearrangement studies (50 PB and 153 BM), were analyzed. In TCR studies, there were 2 false positives and 1 false negative in 47 PB assays, as well as 7 false positives and 1 false negative in 54 BM assays. Regarding IG studies, 3 false positives and 12 false negatives in 99 BM studies were identified. Sensitivity and specificity, respectively, were calculated for PB TCR studies (94% and 93%), BM IG studies (71% and 95%), and BM TCR studies (92% and 83%). Analysis of PB IG gene rearrangement studies was not performed due to the small number of tests (3; all true negative). None of the 12 patients with false-positive IG/TCR gene rearrangement studies later developed a lymphoproliferative disorder, although 2 patients were later diagnosed with acute myeloid leukemia. Of the 14 false negatives, 10 (71%) were related to a diagnosis of plasma cell neoplasms. Results from the present study suggest that positive IG/TCR gene rearrangement studies are not predictive of lymphoproliferative disorders in the context of otherwise negative BM or PB findings. As such, when faced with equivocal pathology reports, clinicians can be practically advised that isolated positive IG/TCR gene rearrangement results may not indicate the need for closer surveillance.

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