Chromosomal Rearrangements Research Articles

Modification of the hi-c technology for molecular genetic analysis of formalin-fixed paraffin-embedded sections of tumor tissues

Molecular genetic analysis of tumor tissues is the most important step towards understanding the mechanisms of cancer development, and it is also necessary for the choice of targeted therapy. Hi-C (high-throughput chromatin conformation capture) technology can be used to detect various types of genomic variants, including balanced chromosomal rearrangements: inversions and translocations. In this work, we propose a modification of the Hi-C method for the analysis of chromatin contacts in formalin-fixed paraffin-embedded (FFPE) sections of tumor tissues. Our results demonstrate that this protocol allow to generate high-quality Hi-C data and detect all types of chromosomal rearrangements. We have analyzed various databases to compile a comprehensive list of translocations that hold clinical importance for targeted therapy selection. The practical value of molecular genetic testing is its ability to influence patient treatment strategies and provide prognostic insights. Detecting specific chromosomal rearrangements can guide the choice of targeted therapies, which is a critical aspect of personalized medicine in oncology.

Genome-wide association for agro-morphological traits in a triploid banana population with large chromosome rearrangements

Abstract Banana breeding is hampered by the very low fertility of domesticated bananas and the lack of knowledge about the genetic determinism of agronomic traits. We analysed a breeding population of 2 723 triploid hybrids resulting from crosses between diploid and tetraploid M. acuminata parents, which was evaluated over three successive crop-cycles for 24 traits relating to yield components and plant, bunch and fruit architectures. A subset of 1 129 individuals was genotyped-by-sequencing revealing 205 612 single nucleotide polymorphisms. Most parents were heterozygous for one or several large reciprocal chromosomal translocations, which are known to impact recombination and chromosomal segregation. We applied two linear mixed models to detect associations between markers and traits: (i) a standard model with a kinship calculated using all SNPs and (ii) a model with chromosome-specific kinships that aims at recovering statistical power at alleles carried by long non-recombined haplotypic segments. For 23 of the 24 traits, we identified one to five significant quantitative trait loci (QTLs) for which the origin of favourable alleles could often be determined among the main ancestral contributors to banana cultivars. Several QTLs, located in the rearranged regions, were only detected using the second model. The resulting QTL landscape represents an important resource to support breeding programs. The proposed strategy for recovering power at SNPs carried by long non-recombined rearranged haplotypic segments is an important methodological advance for future association studies in banana and other species affected by chromosomal rearrangements.

A novel ITGB8 transcript variant sustains ovarian cancer cell survival through genomic instability and altered ploidy on a mutant p53 background.

Transcript variants and protein isoforms are central to unique tissue functions and maintenance of homeostasis, in addition to being associated with aberrant states such as cancer, where their crosstalk with the mutated tumor suppressor p53 may contribute to genomic instability and chromosomal rearrangements. We previously identified several novel splice variants in ovarian cancer RNA-sequencing datasets; herein, we aimed to elucidate the biological effects of the Integrin Subunit Beta 8 variant (termed pITGB8-205). Resolution of the full-length sequence of pITGB8-205 through rapid amplification of cDNA ends (RACE-PCR). Cell cycle analysis and karyotype studies were performed to further explore genomic instability. RNA-seq and proteomics analyses were used to identify the differential expression of the genes. This full-length study revealed a unique 5' sequence in pITGB8-205 that differed from the reported ITGB8-205 sequence, suggesting differential regulation of this novel transcript. Under a p53 mutant background, overexpression of pITGB8-205 triggered genetic instability reminiscent of oncogene-induced replicative stress with extensive abnormal mitoses and chromosomal and nuclear aberrations indicative of chromosomal instability, leading to near whole-genome duplication that imposes energy stress on cellular resources. Micronuclei and aneuploidy are striking features of pITGB8-205-overexpressing p53-mutant cells but are not enhanced in p53 wild-type (WT) cells. RNA-seq and proteomics analyses further suggested that p53 inactivation in ovarian cancer provides a permissive intracellular molecular niche for pITGB8-205 to mediate its effects on genomic instability. This observation is pivotal considering that most high-grade serous ovarian carcinoma (HGSC) tumors express mutant p53. The resulting aneuploid clones with enhanced self-renewal and survival capabilities disrupt clonal dominance under stress yet maintain a balance between replicative stress and prosurvival advantages. pITGB8-205-overexpressing clones sustain ovarian tumor cell survival, achieve homeostasis and are formidable opponents of therapy.

Clinical application of chromosome microarray analysis and karyotyping in prenatal diagnosis in Northwest China

IntroductionKaryotyping and chromosome microarray analysis (CMA) are the two main prenatal diagnostic techniques currently used for genetic testing. We aimed to evaluate the value of chromosomal karyotyping and CMA for different prenatal indications.MethodsA total of 2084 amniocentesis samples from pregnant women who underwent prenatal diagnosis from 16 to 22 + 6 weeks of gestation between January 2021 and December 2022 were retrospectively collected. The pregnant women were classified according to different prenatal diagnostic indications and underwent CMA and karyotype analysis. Clinical data were collected, and the results of the CMA and karyotype analysis were statistically analyzed to compare the effects of the two diagnostic techniques.ResultsThe total detection rate of abnormal chromosomes was significantly higher using CMA than karyotype analysis. The detection rate of abnormal chromosomes using CMA was significantly higher than that using karyotyping for ultrasound abnormalities, high-risk serologic screening, adverse pregnancy history, positive noninvasive prenatal test (NIPT) screening, and ultrasound abnormalities combined with adverse pregnancy history indications. Among the fetuses with inconsistent results between the two testing methods, 144 had an abnormal CMA but a normal karyotype, with the highest percentage of pregnant women with ultrasound abnormalities at 38.89% (56/144). CMA had the highest detection rate for structural abnormalities combined with soft-index abnormalities among all ultrasound abnormalities. The highest detection rate of copy number variants in the group of structural abnormalities in a single system was in the genitourinary system (3/29, 10.34%).ConclusionCMA can improve the detection rate of chromosomal abnormalities in patients with ultrasound abnormalities, high-risk serologic screening, adverse maternal history, positive NIPT screening, and ultrasound abnormalities combined with adverse maternal history and can increase the detection rate of chromosomal abnormalities in karyotypic normality by 6.91% (144/2,084), this result is higher than similar studies. However, karyotype analysis remains advantageous over CMA regarding balanced chromosomal rearrangement and detection of low-level chimeras, and the combination of the two methods is more helpful in improving the detection rate of prenatal chromosomal abnormalities.

Successful Pregnancy following PGT-SR in a Couple with Complex Chromosome Rearrangement and Recurrent IVF Failures: A Case Report.

Successful Pregnancy following PGT-SR in a Couple with Complex Chromosome Rearrangement and Recurrent IVF Failures: A Case Report.

Resolving complex duplication variants in autism spectrum disorder using long-read genome sequencing.

Rare or de novo structural variation, primarily in the form of copy number variants, is detected in 5%-10% of autism spectrum disorder (ASD) families. While complex structural variants involving duplications can generally be detected using microarray or short-read genome sequencing (GS), these methods frequently fail to characterize breakpoints at nucleotide resolution, requiring additional molecular methods for validation and fine-mapping. Here, we use Oxford Nanopore Technologies PromethION long-read GS to characterize complex genomic rearrangements (CGRs) involving large duplications that segregate with ASD in five families. In total, we investigated 13 CGR carriers and were able to resolve all breakpoint junctions at nucleotide resolution. While all breakpoints were identified, the precise genomic architecture of one rearrangement remained unresolved with three different potential structures. The findings in two families include potential fusion genes formed through duplication rearrangements, involving IL1RAPL1-DMD and SUPT16H-CHD8 In two of the families originating from the same geographical region, an identical rearrangement involving ANK2 was identified, which likely represents a founder variant. In addition, we analyze methylation status directly from the long-read data, allowing us to assess the activity of rearranged genes and regulatory regions. Investigation of methylation across the CGRs reveals aberrant methylation status in carriers across a rearrangement affecting the CREBBP locus. In aggregate, our results demonstrate the utility of nanopore sequencing to pinpoint CGRs associated with ASD in five unrelated families, and highlight the importance of a gene-centric description of disease-associated complex chromosomal rearrangements.

Beyond chromosomal rearrangements: The expanding landscape of gene fusions and chimeric RNAs

BCR–ABL, the pioneering gene fusion resulting from chromosomal translocation, has marked a major milestone in understanding genetic alterations in cancer. Initially, gene fusions were linked solely to chromosomal rearrangements, serving as diagnostic markers and cancer drivers. However, advancements in high-throughput sequencing and bioinformatics have revealed additional mechanisms underlying gene fusion. The term “gene fusion” primarily refers to fusion events at the DNA level, whereas “chimeric RNA” encompasses a wide range of transcripts containing exons from different parental genes, including gene fusion transcripts. Recent developments have identified numerous chimeric RNAs in various cancer types, extending even to non-cancerous tissues. Chimeric RNAs, originating from events such as trans-splicing, read-through, and intergenic splicing, form a complex landscape with varied functions. While some chimeric RNAs have defined roles and therapeutic potential, a comprehensive understanding of their diverse functions remains a priority. Exploring the full spectrum of chimeric RNA activities is crucial for revealing their clinical and therapeutic implications. In addition, chimeric RNAs are key players in tumorigenesis, affecting cellular processes, and driving cancer progression. Understanding their intricate interactions with cellular pathways is essential for developing targeted therapies and precision medicine approaches. The dynamic nature of chimeric RNAs highlights the need for ongoing research to fully harness their diagnostic and therapeutic potential.

Black flies (Diptera: Simuliidae) in the Galapagos Islands: Native or adventive?

Invasive species are a threat to ecosystems worldwide, but determining if a species is adventive or native is not always straightforward. The black flies that inhabit the Galapagos Islands, long known as Simulium ochraceum, are blood-feeding pests of humans and livestock. They first came to the attention of residents in 1989, suggesting a recent arrival. Earlier colonization, however, has been suggested, based largely on polymorphic genetic loci. To address questions of origin, provenance, and length of residency, we conducted a macrogenomic analysis of the polytene chromosomes of the S. ochraceum complex from seven sites in the Galapagos Islands and 30 sites in mainland Ecuador, Central America, and the Caribbean. Among 500 analyzed larvae, we discovered 88 chromosomal rearrangements representing 13 cytoforms, at least seven of which are probably full species. All evidence points to a single, cohesive cytoform with full species status in the Galapagos, conspecific with mainland populations, and widely distributed in the Neotropical Region. It has an identical, nearly monomorphic banding sequence with 10 novel fixed inversions and a subtle but unique Y-linked chromosomal rearrangement across all populations sampled in the Galapagos, the mainland, and the Caribbean. We recalled the name Simulium antillarum from synonymy with S. ochraceum and applied it to the Galapagos black flies, and we established that wolcotti is a junior synonym of antillarum. The time(s) and mode(s) of arrival of S. antillarum in the Galapagos remain uncertain, although the wide geographic distribution, including islands in the Caribbean, suggests that the species is an adept colonizer. Regardless of how long it has been in the archipelago, S. antillarum might have assumed a functional role in the streams of San Cristobal, but otherwise has had a detrimental effect on humans and livestock and potentially on the unique birds and mammals of the Galapagos Islands.

Recurrent Xp22.31-Yq11 Unbalanced Translocations: Molecular Diagnosis and Clinical Implications in Three Families.

Unbalanced translocation between chromosomes X and Y is a recurring chromosomal rearrangement. The presence of a derivative chromosome X (derX), where a Yq11-qter segment is attached to the short arm of chromosome X, replacing a terminal Xpter-p22.31, poses challenges for interpretation of findings by prenatal cell-free DNA (cfDNA) screening, establishing genotype-phenotype correlation in male and female individuals, and for genetic counseling. In this report, we provide clinical outcomes, inheritance, and clinical implications of derX in three families referred to diagnostic testing due to discrepant results for sex chromosomes reported by cfDNA, abnormal prenatal ultrasound findings, recurrent pregnancy losses, or affected family members with derX transmitted through multiple generations. Reports of discrepant sex and risk for sex chromosome aneuploidy such as 45,X, 47,XXY and 47,XYY are common false positive outcomes of a prenatal cfDNA screening if either a mother or a fetus has unbalanced Xp-Yq translocation. In addition, mothers who carry der(X) facing a recurrent risk of ambiguity in prenatal testing. Pregnancy loss and neonatal death/stillbirth of male offspring are common in affected families, but this risk does not directly correlate with the size of deleted Xp region. This study emphasizes the importance of CMA and familial testing for accurate diagnosis and genetic counseling.

High prevalence of chromosome 17 in breast cancer micronuclei: a means to get rid of tumor suppressors?

Micronuclei (MN), defined as small extra-nuclear chromatin bodies enclosed by a nuclear envelope, serve as noticeable markers of chromosomal instability (CIN). The MN have been used for breast cancer (BC) screening, diagnosis, and prognosis. However, more recently they have gained attention as seats for active chromosomal rearrangements. BC subtypes exhibit differential CIN levels and aggressiveness. This study aimed to investigate MN chromosomal contents across BC subtypes, exploring its potential role in aggressiveness and pathogenesis. Immunostaining of BC cells was performed with anti-centromeric antibody followed by confocal microscopy. Further, fluorescence in situ hybridization (FISH) was done to check the presence of specific chromosomes in the MN. The real time PCR was also done from the RNA isolated from MN to check the expression of TP53 gene. BC cell lines (CLs) showed the presence of both centromere-positive ( +) and -negative ( -) MN, with significant variation in frequency among hormone and human epidermal growth factor receptor positive and triple-negative (TN) BC cells. FISH targeting chromosomes 1, 3, 8, 11, and 17 detected centromeric signals for all the above chromosomes in MN with a relatively higher prevalence of chromosome 17 in all the CLs. Out of all the CLs, TNBC cells demonstrated the highest frequency of centromere + and chromosome 17 + MN. TP53 expression could also be demonstrated inside the MN by FISH and real time PCR. Patient sample imprints also confirmed the presence of chromosome 17 in MN with polysomy of the same in corresponding nuclei. The high prevalence of chromosome 17 in BC MN may connote the importance of its rearrangements in the pathogenesis of BC. Further, the higher prevalence of chromosome 17 and 1 signals in TNBC MN point towards the significance of pathogenetic events involving the genes located in these chromosomes in evolution of this more aggressive phenotype.

Increased evolutionary rate in the Z-chromosome of sympatric and allopatric species of Morpho butterflies.

Divergent evolution of genomes among closely related species is shaped by both neutral processes and ecological forces, such as local adaptation and reinforcement. These factors can drive accelerated evolution of sex chromosomes relative to autosomes. Comparative genomic analyses between allopatric and sympatric species with overlapping or divergent ecological niches offer insights into reinforcement and ecological specialization on genome evolution. In the butterfly genus Morpho, several species coexist in sympatry, with specialization across forest strata and temporal niches. We analyzed the genomes of eight Morpho species, along with previously published genomes of three others, to compare chromosomal rearrangements and signs of positive selection in the Z chromosome vs autosomes. We found extensive chromosomal rearrangements in Z chromosome, particularly in sympatric species with similar ecological niches, suggesting a role for inversions in restricting gene flow at a postzygotic level. Z-linked genes also exhibited significantly higher dN/dS ratios than autosomal genes across the genus, with pronounced differences in closely related species living in sympatry. Additionally, we examined the evolution of eight circadian clock genes, detecting positive selection in Period, located on the Z chromosome. Our findings suggest that the Z chromosome evolves more rapidly than autosomes, particularly among closely related species, raising questions about its role in pre- and post-zygotic isolation mechanisms.

Comparative Analysis of Fluorescence In Situ Hybridization and Next-Generation Sequencing in Sperm Evaluation: Implications for Preimplantation Genetic Testing and Male Infertility

Pre-implantation genetic testing (PGT) is a crucial process for selecting embryos created through assisted reproductive technology (ART). Couples with chromosomal rearrangements, infertility, recurrent miscarriages, advanced maternal age, known single-gene disorders, a family history of genetic conditions, previously affected pregnancies, poor embryo quality, or congenital anomalies may be candidates for PGT. Preimplantation genetic testing for aneuploidies (PGT-A) enables the selection and transfer of euploid embryos, significantly enhancing implantation rates in assisted reproduction. Fluorescence in situ hybridization (FISH) is the preferred method for analyzing biopsied cells to identify these abnormalities. While FISH is a well-established method for identifying sperm aneuploidy, NGS offers a more comprehensive assessment of genetic material, potentially enhancing our understanding of male infertility. Chromosomal abnormalities, arising during meiosis, can lead to aneuploid sperm, which may hinder embryo implantation and increase miscarriage rates. This review provides a comparative analysis of fluorescence in situ hybridization (FISH) and next-generation sequencing (NGS) in sperm evaluations, focusing on their implications for preimplantation genetic testing. This analysis explores the strengths and limitations of FISH and NGS, aiming to elucidate their roles in improving ART outcomes and reducing the risk of genetic disorders in offspring. Ultimately, the findings will inform best practices in sperm evaluations and preimplantation genetic testing strategies.

Mosaic aneuploidy in a patient with periocular basal cell carcinoma. Report of a case

Basal cell carcinoma constitutes approximately 80% of non-melanocytic skin tumors and originates in the basal layer of the epidermis and its appendages. Genetic alterations that affect neoplastic development have been identified, caused by external physical or chemical agents, hereditary, chromosomal rearrangements, allelic loss and gene amplification. This article presents a white-skinned male individual, 64 years old, with a diagnosis of periocular basal cell carcinoma, who underwent a cytogenetic study of the tumor tissue and a mosaic chromosomal aneuploidy was identified.The presence of mosaic aneuploidy in patients with periocular basal cell carcinoma suggests that chromosomal aberrations may play an important role in tumor progression and aggressiveness. This finding highlights the need to integrate cytogenetic studies in the clinical evaluation of skin tumors, facilitating a better understanding of the underlying biological mechanisms, opening new avenues for therapeutic research.

Comparative analysis of chromosome-level genomes provides insights into chromosomal evolution in Chiroptera.

Chiroptera (bats) presents a fascinating model due to its remarkable variation in chromosome numbers, which range from 14 to 62. This astonishing diversity makes bats an excellent subject for studying chromosome evolution. The black-bearded tomb bat (Taphozous melanopogon) occupies a pivotal phylogenetic position within Chiroptera, emphasizing its crucial role in the systematic examination of bat chromosome evolution. In this study, we present the first chromosome-level genome of T. melanopogon within the family Emballonuridae. Together with previously published genomes, we construct a strongly supported phylogenetic tree of bats, which supports that Emballonuridae forms a basal group within Yangochiroptera. Furthermore, we reconstruct ancestral karyotypes at key nodes along the bat phylogeny and conduct a synteny analysis among the genomes of 12 bat species. Our findings identified evolutionary breakpoint regions (EBRs) that are of particular interest. Notably, some bat genomes exhibit an enrichment of genes related to host defense against microbial pathogens within EBRs. Remarkably, one species possesses multiple copies of some β-defensin genes, while six other species have experienced the loss of some β-defensin genes due to EBRs. Furthermore, some olfactory receptor genes are located in EBRs of 12 species, 4 of which have a significant enrichment in sensory perception of smell. Together, our comparative genomic analysis underscores the potential link between chromosome rearrangements and the adaptation of bats to defend against microbial pathogens.

De novo genome assemblies of two cryptodiran turtles with ZZ/ZW and XX/XY sex chromosomes provide insights into patterns of genome reshuffling and uncover novel 3D genome folding in amniotes.

Understanding the evolution of chromatin conformation among species is fundamental to elucidate the architecture and plasticity of genomes. Nonrandom interactions of linearly distant loci regulate gene function in species-specific patterns, affecting genome function, evolution, and, ultimately, speciation. Yet, data from nonmodel organisms are scarce. To capture the macroevolutionary diversity of vertebrate chromatin conformation, here we generate de novo genome assemblies for two cryptodiran (hidden-neck) turtles via Illumina sequencing, chromosome conformation capture, and RNA-seq: Apalone spinifera (ZZ/ZW, 2n = 66) and Staurotypus triporcatus (XX/XY, 2n = 54). We detected differences in the three-dimensional (3D) chromatin structure in turtles compared to other amniotes beyond the fusion/fission events detected in the linear genomes. Namely, whole-genome comparisons revealed distinct trends of chromosome rearrangements in turtles: (1) a low rate of genome reshuffling in Apalone (Trionychidae) whose karyotype is highly conserved when compared to chicken (likely ancestral for turtles), and (2) a moderate rate of fusions/fissions in Staurotypus (Kinosternidae) and Trachemys scripta (Emydidae). Furthermore, we identified a chromosome folding pattern that enables "centromere-telomere interactions" previously undetected in turtles. The combined turtle pattern of "centromere-telomere interactions" (discovered here) plus "centromere clustering" (previously reported in sauropsids) is novel for amniotes and it counters previous hypotheses about amniote 3D chromatin structure. We hypothesize that the divergent pattern found in turtles originated from an amniote ancestral state defined by a nuclear configuration with extensive associations among microchromosomes that were preserved upon the reshuffling of the linear genome.

Improving the Utility of a Cancer Gene Mutation Panel for Multiple Myeloma Patients

Abstract Multiple myeloma is a plasma cell malignancy that accounts for 1-2% of all cancer diagnoses and 10-15% of hematopoietic neoplasms. Clonal rearrangement of the IG locus suggests a monoclonal model for pathogenesis. The presence of cytogenetic abnormalities in >90% of cases suggests transformation by chromosomal instability and rearrangement. Classification and consensus guidelines by The International Myeloma Working Group (IMWG) and others reflect this by categorizing myeloma based on ploidy, translocations, and chromosomal abnormalities. Interestingly, a portion of Emory’s test volume for cancer gene mutation profiling by second generation short-read sequencing is for multiple myeloma cases. This suggests our 75-gene myeloid neoplasm panel (MMP75) is being utilized for medical purposes that are not met by cytogenetic and microarray characterizations performed during the diagnostic workup of multiple myeloma. Inspired by this observation, this study investigates providers motivations for ordering MMP75 and assesses the adequacy of our current implementation for their stated purposes. Anecdotes from ordering physicians indicate interest in MMP75 results when informing prognosis, selecting treatments, and evaluating for treatment associated secondary neoplasms. A more formal survey is underway that will statistically capture how the results of MMP75 testing were ultimately used: to inform diagnosis, determine prognosis, guide treatment, explain progression, identify/rule-out secondary neoplasia, or no effect on management. We also explore the variants called by MMP75 when performed using bone marrow from patients who received a cytogenetic workup for multiple myeloma at some point. A retrospective analysis of the 5-year interval between Jan 2019 and Jan 2024 identified 156 cases meeting this criterion. The number of pathogenic variants per case ranged between 1 and 8, with mutations detected across 42 genes. The genes most frequently identified with pathogenic mutations were TP53 (22.4%), DNMT3A (19.2%), TET2 (14.7%), and ASXL1 (12.2%). All four have been associated with adverse outcomes in patients with multiple myeloma. Activating events in therapeutic targets included mutations in the RAS/RAF pathway (16.7%), JAK/STAT signaling (2.6%), and the kinase KIT (0.6%). While these findings support the use of MMP75 for detection of relevant mutations, the genetic variants identified are not unique to multiple myeloma. Mutations detected in DNMT3A, TET2, and ASXL1 are common in clonal hematopoiesis of indeterminant potential (CHIP) and myeloid neoplasms. Hotspot mutations in TP53 and activating events in the RAS/RAF pathway also occur in various hematologic malignancies. This test therefore detects events that occur in both the plasma cell compartment and other cells of origin. This encumbers distinguishing variants that inform on a patient’s multiple myeloma from events that suggest a secondary neoplasm. Future directions include determining whether the effect of plasma cell enrichment on a mutations variant allele frequency (VAF) in repeat testing can help distinguish true multiple myeloma variants from events in other cells.

Targeting DLBCL by mutation-specific disruption of cancer-driving oncogenes.

Diffuse large B cell lymphomas (DLBCL) are highly aggressive tumors. Their genetic complexity and heterogeneity have hampered the development of novel approaches for precision medicine. Our study aimed to develop a personalized therapy for DLBCL by utilizing the CRISPR/Cas system to induce knockouts (KO) of driver genes, thereby causing cancer cell death while minimizing side effects. We focused on OCI-LY3 cells, modeling DLBCL, and compared them with BJAB cells as controls. Analysis of whole exome sequencing revealed significant mutations in genes like PAX5, CD79B, and MYC in OCI-LY3 cells. CRISPR/Cas9-mediated KO of these genes resulted in reduced cancer cell viability. Subsequent single and dual gRNA targeting of PAX5 mutations inhibited proliferation specifically in OCI-LY3 cells. Moreover, dual gRNA targeting of PAX5 and MYC induced chromosomal rearrangements, reducing cell proliferation substantially. However, targeting single intronic mutations did not affect cell viability, highlighting the importance of disrupting protein function. Targeting multiple mutations simultaneously addresses intra-tumoral heterogeneity, and the transient delivery of CRISPR/Cas9 allows for permanent gene disruption. While challenges such as incomplete editing efficiency and delivery limitations exist, further optimization may enhance therapeutic efficacy. Overall, our findings demonstrate the efficacy of CRISPR/Cas9 in targeting oncogenic mutations, opening avenues for precision medicine in DLBCL treatment.

Pangenome – its Aspect and Prospect

Pangenome is a very new discipline showing a collection of unique and variable genomes of any species in one model. This discipline is a combination of three subjects of Biology like Computer Science and Applied Mathematics. All genes from all species or strains are called Pangenomes. Pangenome was first discovered during the preparation of protein-based vaccine of the G group of Streptococcus sp. which is the main cause of neonatal life-threatening disease by a team of scientists led by Tettelin. Conventional method of Vaccine preparation was not successful due to the existence of five different serotypes in this organism. Then Tettelin with groups of scientists tried to use the genome sequence information for preparing protein- based vaccine in G group of Streptococcus. During their studies, two gap free genomes were found in this G group of bacteria. After sequencing studies of many strains, they found several regions of diversity (genomic diversity) among different isolates of same strain. After sequencing a large number of genomes, they realized that genes belong to isolates present in the species but not present in genomes. Then the Pangenome concept came to their mind and genes were classified into Core genome, Accessory or Dispensable genome and Species-specific genomes. Bacteria genomes have a distinct number of genes but there are differences in the genomes of different strains of a single species that is mainly due to horizontal gene transfer of genes from other bacteria. The Pangenome concept and its discovery was discussed. Plant genomes are dynamic with whole genome duplication, tandem duplication, transposable element duplication, chromosomal rearrangements or structural variations like deletion, inversion, translocation and recombination between species. Several methods have already been tried for the improvement of crop plants like Marker Assisted Selection (MAS), QTL mapping, Single Nucleotide Polymorphisms (SNP), Copy number variations and Genome Wide Association Studies (GWAS) by comparing with Reference Genome Assemblies representing the genome sequence of the genome of an individual or organism. But the Reference genome is not able to locate all genetic variations of a species. To overcome this limitation the concept of Pangenomes may help in the crop improvement which has been discussed. Pangenomic studies have already been done in many crop plants like Rice, Wheat, Maize, Brassica, Soybean etc. Some of all these aspects have been discussed.

Predicting rapid adaptation in time from adaptation in space: A 30-year field experiment in marine snails

Predicting the outcomes of adaptation is a major goal of evolutionary biology. When temporal changes in the environment mirror spatial gradients, it opens up the potential for predicting the course of adaptive evolution over time based on patterns of spatial genetic and phenotypic variation. We assessed this approach in a 30-year transplant experiment in the intertidal snail Littorina saxatilis . In 1992, snails were transplanted from a predation-dominated environment to one dominated by wave action. On the basis of spatial patterns, we predicted transitions in shell size and morphology, allele frequencies at positions throughout the genome, and chromosomal rearrangement frequencies. Observed changes closely agreed with predictions and transformation was both dramatic and rapid. Hence, adaptation can be predicted from knowledge of the phenotypic and genetic variation among populations.

Chromosome 8p Syndromes Clinical Presentation and Management Guidelines.

Rearrangements of the p-arm of Chromosome 8 can result in a spectrum of neurodevelopmental challenges, along with increased risk of epilepsy, structural brain and cardiac malformations, persisting developmental delays, and other health challenges. The majority of patients reported on in this sample are characterized by an inverted-duplication deletion rearrangement, but deletions, duplications, and mosaic ring changes in 8p result in similar phenotype. In this report, we add to the phenotypic and functional description of these patients according to their specific chromosomal rearrangement, share neuro-psychometric values, and propose surveillance care guidelines for caregivers and medical providers of patients with Chromosome 8p Syndromes. Observations from clinical experience with 24 patients seen at our 8p-dedicated Multi-Disciplinary Neurogenetics program are shared.