Chromosomal Copy Research Articles

Ascorbate peroxidase modulation confirms key role in Leishmania infantum oxidative defence

Abstract Background Ascorbate peroxidase (APX) has emerged as a promising target for chemotherapy because of its absence in humans and crucial role in the antioxidant defence of trypanosomatids. APXs, which are class I haeme-containing enzymes, reduces hydrogen peroxide using ascorbate to produce water and monodehydroascorbate, thereby preventing cell damage caused by H2O2. Methods We aimed to create an APX-knockout L. infantum line using CRISPR/Cas9. Despite unsuccessful attempts at full knockouts, we achieved deletion of chromosomal copies post-APX episomal insertion, yielding LiΔchrAPX::LbAPX parasites. We performed phenotypic characterization to assess the impact of these genetic modifications, which included the determination of APX transcript expression levels using quantitative PCR, drug sensitivity, infectivity, and parasite survival in macrophages. Results Quantitative polymerase chain reaction (PCR) analysis revealed a 10- to 13-fold reduction in APX transcript expression in LiΔchrAPX::LbAPX compared with wild-type (LiWT) and APX-overexpressing (Li::Cas9::LbAPX) parasites, respectively. The episomes in those knockdown parasites remained stable even after 20 drug-free passages in vitro. Li::Cas9::LbAPX parasites showed increased resistance to trivalent antimony (SbIII) and isoniazid, reduced tolerance to H2O2, and unchanged macrophage infectivity compared with LiWT. In contrast, LiΔchrAPX::LbAPX parasites were more sensitive to SbIII and isoniazid, exhibited greater susceptibility to H2O2-induced oxidative stress, and 72 h post-infection, showed fewer infected macrophages and intracellular amastigotes compared with LiWT parasites. Conclusions Our findings hint at the indispensability of APX in L. infantum and raise the possibility of its potential as a therapeutic target for leishmaniasis. Graphical Abstract

Intercellular mosaic methylation in fast-growing Mycobacterium tuberculosis clinical isolates

Abstract Orphan DNA adenine methyltransferases (MTases) of Mycobacterium tuberculosis (Mtb) exhibit diversity across clinical isolates, but the forces driving this variation are not entirely clear. Recently, we observed several isolates exhibiting anomalous hypomethylation by Type I MTase Mycobacterial Adenine Methyltransferase C (MamC) despite a wild-type mamC genotype (‘MamC-anomalous’ isolates). Investigating this hypomethylation through multiple analyses revealed three key findings. First, heterogeneity analysis revealed intercellular mosaic methylation (IMM) in MamC-anomalous isolates. While they often exhibit phase-variable heterogeneity, this is the first report of IMM by a prokaryotic Type I MTase. Second, MamC-anomalous isolates exhibited a large, stable difference in chromosome copy number along the replication axis (a proxy for bacterial growth rate), suggesting a distinct growth phase accompanied by MamC hypomethylation. Third, MamC methylation efficiency decreased progressively with distance from origin of replication on both strands, with a marked exaggeration in MamC-anomalous isolates. In contrast, other Mtb MTases (MamA and MamB) exhibited lower methylation levels away from the origin only on the lagging strand, and without exaggeration in MamC-anomalous isolates. We conclude that, among Mtb MTases, MamC is uniquely linked to growth dynamics.

Abstract IA005: Tumor cell-based liquid biopsy to characterize prostate cancer

Abstract Circulating Tumor Cells (CTCs) hold the promise of comprehensive yet noninvasive molecular characterization of cancer cells during the course of tumor evolution and progression. To dissect the epigenetic profile of prostate CTCs, we undertook paired DNA methylation and RNA sequencing of single CTCs isolated from blood specimens of patients with prostate cancer. Across the genome, our study identified 40 core Partial Methylation Domains (PMDs) that arise early in tumorigenesis and are shared by all individual CTCs across multiple patients. Key among these is a single genomic locus harboring multiple interferon-inducible genes along with all the CD1 gene family members, implicated in innate immunity. Based on mouse models, we propose that early biallelic silencing of multiple genes residing within a single PMD may contribute to the escape from immune surveillance in prostate and potentially other cancers. Studies of CTC heterogeneity within individual patients are limited by the very small number of cells that can be isolated from standard 10ml blood volumes. To enable such analyses, we applied a new high throughput microfluidic platform, capable of processing an entire leukapheresis product, interrogating 2-3 L of blood volume equivalent. Applying this technology to patients with metastatic prostate cancer, we successfully enriched thousands of CTCs from individual cases, enabling the characterization of intra-patient heterogeneity at the level of cell morphology and marker expression, chromosome copy number variation and exome-wide genotyping, and transcriptionally-defined tumor cell subpopulations. Such high-volume microfluidic enrichment of CTCs constitutes a new dimension in liquid biopsies. Citation Format: Daniel A Haber, Shyamala Maheswaran, Hongshan Guo, Joanna Vuille, Shih-Bo Huang, Ben S Wittner, Lecia V Sequist, Richard J Lee, Patricia AR Brunker, David T Miyamoto, Avanish Mishra, Mehmet Toner. Tumor cell-based liquid biopsy to characterize prostate cancer [abstract]. In: Proceedings of the AACR Special Conference: Liquid Biopsy: From Discovery to Clinical Implementation; 2024 Nov 13-16; San Diego, CA. Philadelphia (PA): AACR; Clin Cancer Res 2024;30(21_Suppl):Abstract nr IA005.

PATH-21. SINGEL CELL TRANSCRIPTOMICS OF SPINAL EPENDYMOMA SUBTYPES IDENTIFIES INTRATUMORAL HETEROGENEITY

Abstract Spinal ependymomas comprise glial neoplasms that are classified by histological and molecular features. Two of the respective types, myxopapillary ependymomas (MPE) and spinal ependymomas (SP-EPN) are largely understudied. For each of these, our group identified clinically relevant subtypes with poorer (MPE-A; SP-EPN-A) and more favorable progression-free survival (MPE-B; SP-EPN-B) employing global methylation and transcriptomic profiling. As cellular origin and pathogenesis of these tumors are largely unknown, therapeutic options for patients with unfavorable subtypes are unavailable. We performed single cell transcriptomic sequencing of 12 formalin-fixed and paraffin-embedded spinal ependymomas including all MPE and SP-EPN subtypes and obtained a median of 10,091 cells per tumor after quality control. Uniform Manifold Approximation and Projection (UMAP) analysis revealed intertumoral heterogeneity as most samples formed separate clusters with tumors of the same subtype located in proximity. The expression of literature-defined neoplastic consensus cell states was examined for each cell of the data set and revealed intratumoral heterogeneity. Tumors expressed predominantly two programs, being a ciliated (ependymal-like) cell state (61% of all neoplastic cells) and the astrocytic state (31 % of all neoplastic cells). Interestingly, third and fourth most abundant states (mesenchymal and hypoxia) were almost exclusively expressed in MPE-A and SP-EPN-A. Furthermore, distinct clones of chromosomal copy number variations were identified across all tumors. These clones can be distinguished in UMAP representation of MPE single cell transcriptomes and to a lesser extend in SP-EPN. Next, we sought to characterize the resemblance of integrated tumor subtypes to normal spinal cord cell populations and observed a high similarity to human spinal cord ependymal cells. All spinal ependymoma subtypes display intratumoral heterogeneity with respect to the transcriptomic cell state resemblance of the neoplastic cells. Together with the transcriptomic similarity to ependymal and astrocytic cells, our data suggest the tumor origin within the astro-ependymal lineage.

Revealing the structural microenvironment of high metastatic risk uveal melanomas following decellularisation

Uveal melanoma (UM) is a rare aggressive intraocular tumour that spreads most commonly to the liver in tumours with loss of one copy of chromosome 3 (HR-M3); current treatments for metastatic disease remain largely ineffective. Pre-clinical research is increasingly using three-dimensional models that better recapitulate the tumour microenvironment (TME). One aspect of the TME is the acellular extracellular matrix (ECM) that influences cell proliferation, migration and response to therapy. Although commercial matrices are used in culture, the composition and biochemical properties may not be representative of the tumour ECM in vivo. This study identifies UM metastatic risk specific ECM proteins by developing methodology for decellularisation of low- and high- metastatic risk tissue samples (LR-D3 vs. HR-M3). Proteomic analysis revealed a matrisome signature of 34 core ECM and ECM-associated proteins upregulated in HR-M3 UM. Combining additional UM secretome and whole cell iTRAQ proteomic datasets revealed enriched GO and KEGG pathways including ‘regulating ECM binding’ and ‘PI3K/Akt signalling’. Structural analyses of decellularised matrices revealed microarchitecture of differing fibre density and expression differences in collagen 4, collagen 6A1 and nidogen 1, between metastatic risk groups. This approach is a powerful tool for the generation of ECM matrices relevant to high metastatic risk UM.

Trisomy 26 in a Holstein calf with disorders of sex development.

Hypospadias occurs sporadically in male livestock and is characterized by a non-fused urethra during fetal development. In this study, perineal hypospadias, a bifid scrotum, penile hypoplasia, and bilateral abdominal cryptorchidism were diagnosed in a neonatal Holstein male calf. Septicemia was also suspected due to hypothermia, blurred conjunctivae, and loss of sucking and swallowing reflexes. Gross pathology revealed that both testicles were located intraabdominally caudally to the kidneys. Histopathological examination of the hypospadias showed a urothelium-lined mucosal fold and parts of the corpus cavernosum penis and prepuce in the subcutis. Whole genome sequencing was performed on the affected calf. Analysis of short-read coverage depth along the chromosomes identified an entire extra copy of chromosome 26. Based on the comparison of available variant calling data from the sire, the identified trisomy 26 is due to non-disjunction of homologous chromosomes during the generation of paternal gametes. We have shown for the first time an association between bovine hypospadias and trisomy 26, which adds to the understanding of variation in fetal male sexual development.

Chromosomal Type II Toxin–Antitoxin Systems May Enhance Bacterial Fitness of a Hybrid Pathogenic Escherichia coli Strain Under Stress Conditions

The functions of bacterial plasmid-encoded toxin–antitoxin (TA) systems are unambiguous in the sense of controlling cells that fail to inherit a plasmid copy. However, its role in chromosomal copies is contradictory, including stress-response-promoting fitness and antibiotic treatment survival. A hybrid pathogenic Escherichia coli strain may have the ability to colonize distinct host niches, facing contrasting stress environments. Herein, we determined the influence of multiple environmental stress factors on the bacterial growth dynamic and expression profile of previously described TA systems present in the chromosome of a hybrid atypical enteropathogenic and extraintestinal E. coli strain. Genomic analysis revealed 26 TA loci and the presence of five type II TA systems in the chromosome. Among the tested stress conditions, osmotic and acid stress significantly altered the growth dynamics of the hybrid strain, enhancing the necessary time to reach the stationary phase. Using qPCR analyses, 80% of the studied TA systems were differentially expressed in at least one of the tested conditions, either in the log or in the stationary phase. These data indicate that type II TA systems may contribute to the physiology of pathogenic hybrid strains, enabling their adaptation to different milieus.

Neurofibroma-like Desmoplastic Melanoma: A Series of Five Cases Exploring the Role of Molecular Testing as a Diagnostic Adjunct and Highlighting the Differential Diagnosis With Diffuse-type Neurofibroma.

A subset of desmoplastic melanomas (DMs) can show extensive morphologic and immunohistochemical overlap with cutaneous diffuse-type neurofibroma. Neurofibroma-like desmoplastic melanoma (NFLDM) thus poses a significant diagnostic pitfall because the clinical implications of these 2 entities differ dramatically. A series of 17 DMs, including 5 cases of NFLDM, were compared with a cohort of 53 cutaneous diffuse-type neurofibromas to explore the utility of molecular testing in the differential diagnosis between NFLDM and neurofibroma and to determine potentially useful morphologic features in this differential diagnosis. Unlike NFLDM, cutaneous diffuse-type neurofibromas: (1) rarely feature intratumoral or peritumoral lymphoid aggregates, (2) consistently harbor an intrinsic stromal support vasculature composed of evenly spaced capillary-sized vessels, and (3) infiltrate adjacent adipose tissue in a dermatofibrosarcoma protuberans-like manner with a complete lack of chronic inflammation or fat necrosis at the leading edge of the tumor. Conversely, DMs, including NFLDM: (1) do not contain Wagner-Meissner bodies, (2) often induce fat necrosis and/or chronic inflammation at the interface with adjacent fibroadipose tissue, (3) lack the intrinsic capillary-sized stromal vasculature observed in most neurofibromas, and (4) may harbor foci of perineuriomatous differentiation, mimicking a hybrid nerve sheath tumor. Any deviation from the expected clinical or morphologic features of cutaneous diffuse-type neurofibroma should raise suspicion for NFLDM. Although not entirely sensitive or specific, molecular testing can help to support the diagnosis of NFLDM by demonstrating genetic abnormalities associated with melanoma, including a UV-light-induced mutational signature, high tumor mutational burden, and/or chromosomal copy number alterations typical of melanoma.

On the Therapeutic Use of Monoclonal Antibodies Against Amyloid Plaques in Older Adults with Down Syndrome: A Narrative Review and Perspective

Down syndrome (DS) is a genetic disorder caused by an extra copy of chromosome 21 (trisomy 21 or T21) and is associated with an increased risk of early-onset Alzheimer’s disease (AD), also known as DS-associated AD (DSAD). Individuals with DS typically develop amyloid neuropathology in their late-thirties to early-forties and the mean age of onset of clinical dementia is approximately 55 years. Recent advances in AD clinical research have focused on monoclonal antibodies (mAbs) targeting amyloid-β (Aβ) plaques as a potential therapeutic approach. Therefore, there has been guarded enthusiasm about using anti-amyloid mAbs in the prevention/treatment of DSAD. This narrative review and perspective explores the current understanding of amyloid pathology in AD and DSAD, the rationale for using anti-amyloid mAbs in the treatment of DSAD, and the challenges and opportunities for research toward the application of this therapeutic strategy to older adults with DS.

Investigating the role of RNA-binding protein Ssd1 in aneuploidy tolerance through network analysis.

RNA-binding proteins (RBPs) play critical cellular roles by mediating various stages of RNA life cycles. Ssd1, an RBP with pleiotropic effects, has been implicated in aneuploidy tolerance in Saccharomyces cerevisiae but its mechanistic role remains unclear. Here we used a network-based approach to inform on Ssd1's role in aneuploidy tolerance, by identifying and experimentally perturbing a network of RBPs that share mRNA targets with Ssd1. We identified RBPs whose bound mRNA targets significantly overlap with Ssd1 targets. For 14 identified RBPs, we then used a genetic approach to generate all combinations of genotypes for euploid and aneuploid yeast with an extra copy of chromosome XII, with and without SSD1 and/or the RBP of interest. Deletion of 10 RBPs either exacerbated or alleviated the sensitivity of wild-type and/or ssd1∆ cells to chromosome XII duplication, in several cases indicating genetic interactions with SSD1 in the context of aneuploidy. We integrated these findings with results from a global over-expression screen that identified genes whose duplication complements ssd1∆ aneuploid sensitivity. The resulting network points to a sub-group of proteins with shared roles in translational repression and p-body formation, implicating these functions in aneuploidy tolerance. Our results reveal a role for new RBPs in aneuploidy tolerance and support a model in which Ssd1 mitigates translation-related stresses in aneuploid cells.

Diversity, functional classification and genotyping of SHV β-lactamases in Klebsiella pneumoniae.

Interpreting the phenotypes of bla SHV alleles in Klebsiella pneumoniae genomes is complex. Whilst all strains are expected to carry a chromosomal copy conferring resistance to ampicillin, they may also carry mutations in chromosomal bla SHV alleles or additional plasmid-borne bla SHV alleles that have extended-spectrum β-lactamase (ESBL) activity and/or β-lactamase inhibitor (BLI) resistance activity. In addition, the role of individual mutations/a changes is not completely documented or understood. This has led to confusion in the literature and in antimicrobial resistance (AMR) gene databases [e.g. the National Center for Biotechnology Information (NCBI) Reference Gene Catalog and the β-lactamase database (BLDB)] over the specific functionality of individual sulfhydryl variable (SHV) protein variants. Therefore, the identification of ESBL-producing strains from K. pneumoniae genome data is complicated. Here, we reviewed the experimental evidence for the expansion of SHV enzyme function associated with specific aa substitutions. We then systematically assigned SHV alleles to functional classes (WT, ESBL and BLI resistant) based on the presence of these mutations. This resulted in the re-classification of 37 SHV alleles compared with the current assignments in the NCBI's Reference Gene Catalog and/or BLDB (21 to WT, 12 to ESBL and 4 to BLI resistant). Phylogenetic and comparative genomic analyses support that (i) SHV-1 (encoded by bla SHV-1) is the ancestral chromosomal variant, (ii) ESBL- and BLI-resistant variants have evolved multiple times through parallel substitution mutations, (iii) ESBL variants are mostly mobilized to plasmids and (iv) BLI-resistant variants mostly result from mutations in chromosomal bla SHV. We used matched genome-phenotype data from the KlebNET-GSP AMR Genotype-Phenotype Group to identify 3999 K. pneumoniae isolates carrying one or more bla SHV alleles but no other acquired β-lactamases to assess genotype-phenotype relationships for bla SHV. This collection includes human, animal and environmental isolates collected between 2001 and 2021 from 24 countries. Our analysis supports that mutations at Ambler sites 238 and 179 confer ESBL activity, whilst most omega-loop substitutions do not. Our data also provide support for the WT assignment of 67 protein variants, including 8 that were noted in public databases as ESBL. These eight variants were reclassified as WT because they lack ESBL-associated mutations, and our phenotype data support susceptibility to third-generation cephalosporins (SHV-27, SHV-38, SHV-40, SHV-41, SHV-42, SHV-65, SHV-164 and SHV-187). The approach and results outlined here have been implemented in Kleborate v2.4.1 (a software tool for genotyping K. pneumoniae), whereby known and novel bla SHV alleles are classified based on causative mutations. Kleborate v2.4.1 was updated to include ten novel protein variants from the KlebNET-GSP dataset and all alleles in public databases as of November 2023. This study demonstrates the power of sharing AMR phenotypes alongside genome data to improve the understanding of resistance mechanisms.

Prenatal diagnosis and postnatal follow-up of 15 fetuses with 16p13.11 microduplication syndrome.

The clinical phenotypes of 16p13.11 microduplication syndrome have been extensively reported in previous studies, mostly about adults and children, with limited information available on fetal cases. This study aims to explore the genotype-phenotype correlation of fetuses with 16p13.11 microduplication syndrome and analyze the characteristics of prenatal diagnosis indications and provide clinical information for prenatal and postnatal genetic counseling. We conducted a retrospective analysis of 3,451 pregnant women who underwent invasive prenatal diagnosis for SNP array between January 2018 and December 2022 at the Jinan Maternal and Child Health Hospital. Descriptive statistical analysis was performed on the prenatal diagnosis indications, pedigree analysis, pregnancy outcomes and postnatal follow-up of 15 fetuses with 16p13.11 microduplication syndrome. SNP array revealed that 15 fetuses had duplications in the 16p13.11 region with varying prenatal diagnosis indications. Among the cases, 6/15 exhibited ultrasound abnormalities, 5/15 had abnormal chromosomal copy number variations as indicated by non-invasive prenatal testing (NIPT), one case involved advanced maternal age, and 3/15 had other abnormalities. 16p13.11 microduplication syndrome was closely related to ultrasound abnormalities, especially structural abnormalities and soft marker anomalies (abnormal ultrasonic soft indicators), while the indication of NIPT could improve the detection rate of copy number variations (CNVs) in this region. Only 7/15 fetuses underwent pedigree verification, with one case of de novo 16p13.11 microduplication, and the others inherited from one parent. Pregnancy was terminated in 2/15 cases and the outcome of one case is unknown due to loss to follow-up. Among the remaining cases, only one case exhibited a ventricular septal defect, while another presented with omphalocele. No other obvious abnormalities were reported postnatally. The prenatal phenotypes of fetuses with 16p13.11 microduplication were highly associated with ultrasound abnormalities but lacked specificity. Comprehensive genetic tracing, outcome analysis, and follow-up are essential for providing accurate prenatal and postnatal genetic counseling.

Bovine aortic arch: a potential indicator that may not serve in prenatal diagnosis - a study based on fetal anatomy, genetics, and postnatal clinical outcomes

ObjectiveTo investigate the structural abnormalities, genetic results, and postnatal clinical outcomes of fetuses with bovine aortic arch (Bovine Aortic Arch, BAA) to provide a basis for prenatal counseling and management.MethodsA retrospective analysis was conducted on 216 fetuses diagnosed with bovine aortic arch through prenatal ultrasound screening at the First Affiliated Hospital of Anhui Medical University and the No.901 Hospital of the Joint Service of the People’s Liberation Army from January 2019 to February 2023. Their family history of genetic diseases, prenatal screening results, and postnatal follow-up data were collected. The fetuses were divided into an isolated BAA group (n = 192) and a non-isolated BAA group (n = 24). Chromosomal karyotyping and copy number variation (CNV) testing were conducted, and statistical analysis was performed using SPSS 22.0 software.ResultsOf the 216 fetuses with BAA, 192 were isolated BAA (88.89%), and 24 were non-isolated BAA (11.11%). Among the isolated BAA fetuses, only 1 case (0.52%) had chromosomal karyotype and pathogenic CNV abnormalities. Among the non-isolated BAA fetuses, 4 cases (16.67%) had chromosomal or CNV abnormalities, but the overall risk was low. The postnatal outcomes of isolated BAA fetuses were good (99.48%), while 79.17% of non-isolated BAA fetuses had good postnatal outcomes.ConclusionMost BAA fetuses are isolated, with a very low incidence of chromosomal abnormalities and pathogenic CNVs, and have good postnatal outcomes. The clinical value of isolated BAA is limited, and invasive prenatal diagnosis is not recommended for low-risk populations. Prenatal screening should focus on the risk of concurrent severe structural anomalies and chromosomal abnormalities.

B-213 Including Turner Syndrome Screening in Newborn Sequencing by Using NGS Read Counts to Infer Sex Chromosomes Copy Number: Leveraging Existing Data to Enhance Early Diagnosis

Abstract Background Turner Syndrome (TS) can lead to heart defects, short stature, and premature ovarian failure. Early diagnosis can improve outcomes, but routine screening is not standard, often delaying diagnosis until symptoms prompt karyotype analysis. Newborn NGS sequencing offers potential for early detection of genetic disorders and targets numerous gene regions on autosomes and sex chromosomes. It could be utilized to deduce sexual chromosomal copy number variations, including not only chrX monosomy but also its partial deletions and structural alterations, and chrY, which increases the risk of gonadoblastoma in TS patients. Thus, this study aims to validate a TS screening approach using NGS read count data from newborn sequencing to develop a strategy for early detection. Methods DNA samples with established chromosomal microarray ChrX and ChrY copy-number assessments were used. The cohort included 13 males (46,XY), 10 females (46,XX), 5 TS cases (45,X), 5 mosaic TS cases (2 with chrY, 3 without), 1 TS case with Isochromosome Xq, 8 Klinefelter Syndrome cases (47,XXY), and one case (48,XXYY). For NGS, a focused newborn sequencing panel targeting 388 genes derived from the larger xGEN Inherited Disease Panel (Integrated DNA Technologies) was employed. The larger panel covers 2,968 chrX regions, 53,455 autosomal regions, and 135 chrY regions. Sample processing utilized the xGEN DNA Library Prep and Hybridization Capture (Integrated DNA Technologies) and sequencing on NextSeq-500 (Illumina). The alignment was conducted with Dragen Enrichment v.3.9.5 and read count analysis with Samtools v.1.19.2. ChrX and ChrY copy numbers were assessed by comparing chrX and chrY read count ratios to autosomal read counts. Hierarchical clustering grouped samples based on ratio similarities, aiding result attribution. To identify structural alterations in each arm of chrX, every tested chrX region was analyzed for read count ratio calculation and subjected to circular binary segmentation using the DNAcopy R package. The observed sex chromosome counts were compared to expected results to validate the approach. Results Observed chrX/autosome and chrY/autosome ratio ranges matched the expected sex chromosome counts: 0.99-1.03 and 0.82-1.02 for 46,XY; 1.92-1.97 and 0.00-0.01 for 46,XX; 1.00-1.02 and 0.00-0.00 for 45,X; 1.15-1.46 and 0.00-0.00 for mosaic TS without chrY; 0.98-1.06 and 0.27-0.32 for mosaic TS with chrY; 2.45 and 0.0 for TS with Isochromosome Xq; 1.82-2.01 and 0.87-0.95 for 47,XXY; and 2.02 and 1.96 for 48,XXYY. Hierarchical cluster analysis grouped these values into three branches: one for 48,XXYY, one for 47,XXY, 46,XX, and Isochromosome Xq, and one for all other TS samples and 46,XY. TS and 47,XXY samples were further divided into subbranches from 46,XX and 46,XY. Circular binary segmentation of chrX read counts provided a visual profile of the copy number for each arm of chrX, explaining structural alterations in out-of-pattern chrX dosages, such as 2.45, 1.15, and 1.46. Conclusions There was complete agreement between the NGS read count-based assessment of sex chromosome copy number and the expected results for 46,XY, 46,XX, 45,X, TS with mosaic and structural variants, 47,XXY, and 48,XXYY samples. This suggests that TS can be effectively screened using newborn sequencing NGS data.

KaryoTap Enables Aneuploidy Detection in Thousands of Single Human Cells.

Investigating chromosomal instability and aneuploidy within tumors is essential for understanding tumorigenesis and developing diagnostic and therapeutic strategies. Single-cell DNA sequencing technologies have enabled such analyses, revealing aneuploidies specific to individual cells within the same tumor. However, it has been difficult to scale the throughput of these methods to detect rare aneuploidies while maintaining high sensitivity. To overcome this deficit, we developed KaryoTap, a method combining custom targeted DNA sequencing panels for the Tapestri platform with a computational framework to enable detection of chromosome- and chromosome arm-scale aneuploidy (gains or losses) and copy number neutral loss of heterozygosity in all human chromosomes across thousands of single cells simultaneously. KaryoTap allows detecting gains and losses with an average accuracy of 83% for arm events and 91% for chromosome events. Importantly, together with chromosomal copy number, our system allows us to detect barcodes and gRNAs integrated into the cells' genome, thus enabling pooled CRISPR- or ORF-based functional screens in single cells. As a proof of principle, we performed a small screen to expand the chromosomes that can be targeted by our recently described CRISPR-based KaryoCreate system for engineering aneuploidy in human cells. KaryoTap will prove a powerful and flexible approach for the study of aneuploidy and chromosomal instability in both tumors and normal tissues.

An elevated rate of whole-genome duplications in cancers from Black patients

In the United States, Black individuals have higher rates of cancer mortality than any other racial group. Here, we examine chromosome copy number changes in cancers from more than 1800 self-reported Black patients. We find that tumors from self-reported Black patients are significantly more likely to exhibit whole-genome duplications (WGDs), a genomic event that enhances metastasis and aggressive disease, compared to tumors from self-reported white patients. This increase in WGD frequency is observed across multiple cancer types, including breast, endometrial, and lung cancer, and is associated with shorter patient survival. We further demonstrate that combustion byproducts are capable of inducing WGDs in cell culture, and cancers from self-reported Black patients exhibit mutational signatures consistent with exposure to these carcinogens. In total, these findings identify a type of genomic alteration that is associated with environmental exposures and that may influence racial disparities in cancer outcomes.

Ploidy levels in diverse picocyanobacteria from the Baltic Sea.

In nature, the number of genome or chromosome copies within cells (ploidy) can vary between species and environmental conditions, potentially influencing how organisms adapt to changing environments. Although ploidy levels cannot be easily determined by standard genome sequencing, understanding ploidy is crucial for the quantitative interpretation of molecular data. Cyanobacteria are known to contain haploid, oligoploid, and polyploid species. The smallest cyanobacteria, picocyanobacteria (less than 2 μm in diameter), have a widespread distribution ranging from marine to freshwater environments, contributing significantly to global primary production. In this study, we determined the ploidy level of genetically and physiologically diverse brackish picocyanobacteria isolated from the Baltic Sea using a qPCR assay targeting the rbcL gene. The strains contained one to four genome copies per cell. The ploidy level was not linked with phylogeny based on the identity of the 16S rRNA gene. The variation of ploidy among the brackish strains was lower compared to what has been reported for freshwater strains and was more similar to what has been reported for marine strains. The potential ecological advantage of polyploidy among picocyanobacteria has yet to be described. Our study highlights the importance of considering ploidy to interpret the abundance and adaptation of brackish picocyanobacteria.

Genetic and clinical analysis of two children with microcephaly and mental retardation due to a frameshifting variant of CASK gene

To explore the clinical and genetic characteristics of two children with mental retardation and microcephaly. Two children who had visited the Anhui Children's Hospital respectively on March 12 and June 22, 2021 were selected as the study subjects. Peripheral venous blood samples were collected from them and their parents, and subjected to chromosomal karyotyping and whole exome sequencing analyses. Candidate variants were verified by Sanger sequencing and pathogenicity analysis. Chromosomal karyotyping and copy number detection of the two children had found no abnormality. Whole exome sequencing revealed that child 1 has harbored a c.471delT (p.Pro157Profs*9) frameshifting variant of the CASK gene, whilst child 2 has harbored a c.1259_1269delCTGAGAATAAC (p.Pro420fs*27) frameshifting variant of the CASK gene. Sanger sequencing confirmed that both variants were de novo in origin. Based on the guidelines from the American College of Medical Genetics and Genomics (ACMG) and the Association for Molecular Pathology (AMP), both variants were rated as pathogenic (PVS1+PS2+PP3). The de novo variants of the CASK gene probably underlay the pathogenesis of mental retardation and microcephaly in both children.

Single-cell RNA sequencing explored potential therapeutic targets by revealing the tumor microenvironment of neuroblastoma and its expression in cell death

BackgroundNeuroblastoma (NB) is the most common extracranial solid tumor in childhood and is closely related to the early development and differentiation of neuroendocrine (NE) cells. The disease is mainly represented by high-risk NB, which has the characteristics of high mortality and difficult treatment. The survival rate of high-risk NB patients is not ideal. In this article, we not only conducted a comprehensive study of NB through single-cell RNA sequencing (scRNA-seq) but also further analyzed cuproptosis, a new cell death pathway, in order to find clinical treatment targets from a new perspective.Materials and MethodsThe Seurat software was employed to process the scRNA-seq data. This was followed by the utilization of GO enrichment analysis and GSEA to unveil pertinent enriched pathways. The inferCNV software package was harnessed to investigate chromosomal copy number variations. pseudotime analyses involved the use of Monocle 2, CytoTRACE, and Slingshot software. CellChat was employed to analyze the intercellular communication network for NB. Furthermore, PySCENIC was deployed to review the profile of transcription factors.ResultUsing scRNA-seq, we studied cells from patients with NB. NE cells exhibited superior specificity in contrast to other cell types. Among NE cells, C1 PCLAF + NE cells showed a close correlation with the genesis and advancement of NB. The key marker genes, cognate receptor pairing, developmental trajectories, metabolic pathways, transcription factors, and enrichment pathways in C1 PCLAF + NE cells, as well as the expression of cuproptosis in C1 PCLAF + NE cells, provided new ideas for exploring new therapeutic targets for NB.ConclusionThe results revealed the specificity of malignant NE cells in NB, especially the key subset of C1 PCLAF + NE cells, which enhanced our understanding of the key role of the tumor microenvironment in the complexity of cancer progression. Of course, cell death played an important role in the progression of NB, which also promoted our research on new targets. The scrutiny of these findings proved advantageous in uncovering innovative therapeutic targets, thereby bolstering clinical interventions.

Aneuploidy of Specific Chromosomes is Beneficial to Cells Lacking Spindle Checkpoint Protein Bub3.

Accurate chromosome segregation is crucial for the proper development of all living organisms. Errors in chromosome segregation can lead to aneuploidy, characterized by an abnormal number of chromosomes, which generally impairs cell survival and growth. However, under certain stress conditions, such as in various cancers, cells with specific mutations and extra copies of advantageous chromosomes exhibit improved survival and proliferation. In our study, we discovered that cells lacking the spindle checkpoint protein Bub3 became aneuploid, retaining specific chromosomes. This finding was unexpected because although bub3 Δ cells have a higher rate of chromosome mis-segregation, they were not thought to maintain an aneuploid karyotype. We investigated whether the increased copy number of specific genes on these acquired chromosomes offered a benefit to Bub3-deficient cells. Our results revealed that several genes involved in chromosome segregation and cell cycle regulation prevented the gain of chromosomes upon Bub3-depletion, suggesting that these genes confer a survival advantage. Overall, our study demonstrates that cells lacking Bub3 selectively retain specific chromosomes to increase the copy number of genes that promote proper chromosome segregation.