Discovery of a MUC3B gene reconstructs the membrane mucin gene cluster on human chromosome 7

Human tissue surfaces are coated with mucins, a family of macromolecular sugar-laden proteins serving diverse functions from lubrication to formation of selective biochemical barriers against harmful microorganisms and molecules. Membrane mucins are a distinct group of mucins that are attached to epithelial cell surfaces where they create a dense glycocalyx facing the extracellular environment. All mucin proteins carry long stretches of tandemly repeated sequences that undergo extensive O-linked glycosylation to form linear mucin domains. However, the repetitive nature of mucin domains makes them prone to recombination and render their genetic sequences particularly difficult to read with standard sequencing technologies. As a result, human mucin genes suffer from significant sequence gaps that have hampered investigation of gene function in health and disease. Here we leveraged a recent human genome assembly to identify a previously unmapped MUC3B gene located within a cluster of four structurally related membrane mucin genes that we entitle the MUC3 cluster at q22 locus in chromosome 7. We found that MUC3B shares high sequence identity with the known MUC3A gene, and that the two genes are governed by evolutionarily conserved regulatory elements. Furthermore, we show that MUC3A, MUC3B, MUC12 and MUC17 in the human MUC3 cluster are exclusively expressed in intestinal epithelial cells. Our results complete existing genetic gaps in the MUC3 cluster that is a conserved genetic unit during primate evolution. We anticipate our results to be the starting point for detection of new polymorphisms in the MUC3 cluster associated with human diseases. Moreover, our study provides the basis for exploration of intestinal mucin gene function in widely used experimental models such as human intestinal organoids and genetic mouse models.

Effects of cystic fibrosis on the oral cavity

Cystic fibrosis is a complex, lethal, multi-system autosomal recessive disease resulting from mutations on chromosome 7 that cause dysfunction of an ion channel located on epithelial surfaces. Pulmonary disease is the leading cause of morbidity and mortality in CF. The specific dental manifestations of the disease may result from the condition itself or from complications of treatment. This study presents the dental problems observed in patients with cystic fibrosis and reported in the literature. Particular attention was paid to dental caries, disturbances in the mineralization of hard dental tissues, gingivitis and changes in the content and properties of saliva.

Further host-genomic characterization of total antibody response to PRRSV vaccination and its relationship with reproductive performance in commercial sows: genome-wide haplotype and zygosity analyses

Background The possibility of using antibody response (S/P ratio) to PRRSV vaccination measured in crossbred commercial gilts as a genetic indicator for reproductive performance in vaccinated crossbred sows has motivated further studies of the genomic basis of this trait. In this study, we investigated the association of haplotypes and runs of homozygosity (ROH) and heterozygosity (ROHet) with S/P ratio and their impact on reproductive performance. Results There was no association (P-value ≥ 0.18) of S/P ratio with the percentage of ROH or ROHet, or with the percentage of heterozygosity across the whole genome or in the major histocompatibility complex (MHC) region. However, specific ROH and ROHet regions were significantly associated (P-value ≤ 0.01) with S/P ratio on chromosomes 1, 4, 5, 7, 10, 11, 13, and 17 but not (P-value ≥ 0.10) with reproductive performance. With the haplotype-based genome-wide association study (GWAS), additional genomic regions associated with S/P ratio were identified on chromosomes 4, 7, and 9. These regions harbor immune-related genes, such as SLA-DOB, TAP2, TAPBP, TMIGD3, and ADORA. Four haplotypes at the identified region on chromosome 7 were also associated with multiple reproductive traits. A haplotype significantly associated with S/P ratio that is located in the MHC region may be in stronger linkage disequilibrium (LD) with the quantitative trait loci (QTL) than the previously identified single nucleotide polymorphism (SNP) (H3GA0020505) given the larger estimate of genetic variance explained by the haplotype than by the SNP. Conclusions Specific ROH and ROHet regions were significantly associated with S/P ratio. The haplotype-based GWAS identified novel QTL for S/P ratio on chromosomes 4, 7, and 9 and confirmed the presence of at least one QTL in the MHC region. The chromosome 7 region was also associated with reproductive performance. These results narrow the search for causal genes in this region and suggest SLA-DOB and TAP2 as potential candidate genes associated with S/P ratio on chromosome 7. These results provide additional opportunities for marker-assisted selection and genomic selection for S/P ratio as genetic indicator for litter size in commercial pig populations.

The frequent and clinically benign anomalies of chromosomes 7 and 20 in Shwachman-diamond syndrome may be subject to further clonal variations

Background An isochromosome of the long arm of chromosome 7, i(7)(q10), and an interstitial deletion of the long arm of chromosome 20, del(20)(q), are the most frequent anomalies in the bone marrow of patients with Shwachman-Diamond syndrome, which is caused in most cases by mutations of the SBDS gene. These clonal changes imply milder haematological symptoms and lower risk of myelodysplastic syndromes and acute myeloid leukaemia, thanks to already postulated rescue mechanisms. Results Bone marrow from fourteen patients exhibiting either the i(7)(q10) or the del(20)(q) and coming from two large cohorts of patients, were subjected to chromosome analyses, Fluorescent In Situ Hybridization with informative probes and array-Comparative Genomic Hybridization. One patient with the i(7)(q10) showed a subsequent clonal rearrangement of the normal chromosome 7 across years. Four patients carrying the del(20)(q) evolved further different del(20)(q) independent clones, within a single bone marrow sample, or across sequential samples. One patient with the del(20)(q), developed a parallel different clone with a duplication of chromosome 3 long arm. Eight patients bore the del(20)(q) as the sole chromosomal abnormality. An overall overview of patients with the del(20)(q), also including cases already reported, confirmed that all the deletions were interstitial. The loss of material varied from 1.7 to 26.9 Mb and resulted in the loss of the EIF6 gene in all patients. Conclusions Although the i(7)(q) and the del(20)(q) clones are frequent and clinically benign in Shwachman Diamond-syndrome, in the present work we show that they may rearrange, may be lost and then reconstructed de novo, or may evolve with independent clones across years. These findings unravel a striking selective pressure exerted by SBDS deficiency driving to karyotype instability and to specific clonal abnormalities.

Solanum galapagense-derived purple tomato fruit color is conferred by novel alleles of the Anthocyanin fruit and atroviolacium loci

One hypothesis for the origin of endemic species of tomato on the Galápagos islands postulates a hybridization of Solanum pimpinellifolium and S. habrochaites. S. galapagense accession LA1141 has purple fruit pigmentation which has previously been described in green-fruited wild tomatoes such as S. habrochaites. Characterization of LA1141 derived purple pigmentation provides a test of the hybridization hypothesis. Purple pigmentation was recovered in progenies derived from LA1141 and the anthocyanins malvidin 3(coumaroyl)rutinoside-5-glucoside, petunidin 3-(coumaroyl) rutinoside-5-glucoside, and petunidin 3-(caffeoyl)rutinoside-5-glucoside were abundant. Fruit color was evaluated in an introgression population and three quantitative trait loci (QTLs) were mapped and validated in subsequent populations. The loci atroviolacium on chromosome 7, Anthocyanin fruit on chromosome 10, and uniform ripening also on chromosome 10, underly these QTLs. Sequence analysis suggested that the LA1141 alleles of Aft and atv are unique relative to those previously described from S. chilense accession LA0458 and S. cheesmaniae accession LA0434, respectively. Phylogenetic analysis of the LA1141 Aft genomic sequence did not support a green-fruited origin and the locus clustered with members of the red-fruited tomato clade. The LA1141 allele of Aft is not the result of an ancient introgression and underlies a gain of anthocyanin pigmentation in the red-fruited clade.

Single-Cell Transcriptomic and Proteomic Analysis of Acute Myeloid Leukemia (AML) Patients with Abnormalities on Chromosome 7

Background: Chromosome 7 (chr7) abnormalities are commonly seen in patients with acute myeloid leukemia (AML) or myelodysplastic syndrome and are associated with poor prognosis. Flow cytometry (FCM) is typically used clinically to quantify residual malignancy during treatment but the relationship of cell surface immunophenotype with genetic features is incompletely defined. Single-cell RNA sequencing (scRNA-seq) with oligonucleotide-conjugated antibodies may be able to integrate cytogenetic genotypes found within leukemic clones with specific transcriptomic and immunophenotypic signatures. Methods: Bone marrow (BM) aspirate was collected from 12 AML patients with known abnormalities on chr7 according to cytogenetics and 3 healthy donors (HDs). We previously established a reference for normal immune cells where we assessed the BM of 20 HDs (PMID:30518681). HDs in present study were selected from this same cohort. Multi-parameter FCM was performed as previously described and scRNA-seq with 31 antibodies (10x Genomics, 3'v2) was performed on BM mononuclear cells. Data from 16 samples (including 1 patient replicate) were mapped onto the atlas with dimension reduction in gene expression (GEX) by principal component analysis and Uniform Manifold Approximation and Projection (UMAP). Cell clusters were constructed and surface proteins were utilized to determine cellular annotation. Patient GEX profiles were compared to those of HDs, and two algorithms were used to identify malignant cells with chromosomal abnormalities. Alterations of large chromosomal segments were identified by Hidden Markov Model. Clinical cytogenetics and expression matrices from the model output were combined to annotate individual cells as malignant or normal for all potential regions. Machine learning classifiers were applied to predict malignant cells using protein expression and important proteins were selected by models with measure for significant features. Results: After quality control, 132,658 cells were included, of which 43,441 and 12,572 cells from AML patients and HD respectively had additional cell surface immunophenotyping data. Samples were well-integrated by UMAP (Figure 1A) and cell annotation overlapped with previously reported annotations by GEX of HDs (Figure 1B), with 15,270 malignant cells identified (Figure 1C). Malignant groups were created if more than 20 cells shared the same chromosomal alterations. Among all 12 patients, 3 of them only had monosomy 7 as the sole genetic aberration, while 9 patients had abnormalities on other chromosomes. The correlation between cell types showed distinct features among patients, and cells in different groups had different protein expression profiles. For example, 22% of the cells (n = 432) from the myeloid population of patient 1 (n = 1957) were identified as normal and 77% had a loss of chr7 (Figure 2A). Clustering in lower resolution separated them into two groups: CD11b+CD33+ (n = 1026) and CD133+CD34+ (n = 931). The CD133+CD34+ group had a higher percentage of malignant cells overall (74% vs. 83%) while a subset of the CD11b+CD33+ group (CD16+CD13+) had the highest percentage of cells with losses on both chr2 and chr7 (60%). Data from patient 2 also suggested that cells with different immunophenotypes were estimated to have different chromosomal changes (Figure 2B). While 69% of the malignant cells had a loss on chr7, most of those without changes on chr7 were from CD45+CD11b+ group where 62% of the cells did not have a detectable change on chr7. The top significant proteins for distinguishing malignant from normal cells among all patients were CD117, CD33, CD34, CD44, and CD47. FCM intensity was compared with the scRNA-seq immunophenotyping data, confirming the similarity in distribution. The scRNA-seq data with immunophenotyping can capture and recapitulate the leukemic immunophenotype, further linking it with copy number changes to reveal potential subclonal structures. Conclusion: By comparing the expression profile of AML patients with abnormalities on chr7 to HDs, this study provides evidence that leukemic immunophenotype is correlated with chromosomal structural changes. The experiments on a single-cell level were able to identify clones in higher resolution and revealed potential cell surface protein markers that could be used clinically to identify specific malignant populations in patients with myeloid malignancies. Figure 1 Figure 1. Disclosures Ghiaur: Syros Pharmaceuticals: Consultancy; Menarini Richerche: Research Funding. Hourigan: Sellas: Research Funding.

MDS-Associated Splicing Factor Mutations Promote Alternative Splicing of a Differentiation-Impaired CSF3R Isoform

Background. Myelodysplastic syndromes (MDS) constitute the most common group of bone marrow failure disorders, characterized by ineffective hematopoiesis and a significant risk of transformation to AML. Efforts to understand the molecular basis of MDS led to the identification of acquired somatic mutations in the RNA splicing factors SF3B1, U2AF1, SRSF2, ZRSR2, and LUC7L2 in 45-85% of adult MDS patients. How they perturb hematopoiesis and promote expansion of abnormal clones remain unknown. Elevated levels of alternate isoforms of granulocyte colony stimulating factor receptor (CSF3R) patients with MDS and other myeloid neoplasias have been reported with a strong correlation reported with loss of chromosome 7. Constitutive splicing produces the canonical Class I CSF3R isoform that supports proliferation and differentiation. Alternative splicing promoting intron excision in CSF3R exon 17 results in a differentiation-defective Class IV CSF3R isoform. We hypothesized that aberrant splicing activity of MDS-associated splicing factor mutations promote Class IV CSF3R expression, resulting in dysgranulopoiesis. Methods. We constructed a CSF3R minigene that was transiently expressed in K562 cells along with eukaryotic expression vectors containing cDNAs for wild-type or mutant forms of SF3B1, U2AF1, or SRSF2. To determine role of LUC7L2, a splicing factor residing on chromosome 7, the CSF3R minigene was transiently expressed in K562 cells with knockout LUC7L2. Class IV or Class I was measure by qPCR using specific primers. Putative exonic splicing enhancer motifs (ESEs) within exon 17 were deleted in the minigene and transfected into K562 cells expressing either wildtype or mutant SRSF2. To determine impact of mutant SRSF2 on granulopoiesis, wildtype or mutant SRSF2 were overexpressed in GCSF-treated CD34+ cells and morphology was assessed on day 14. To determine impact of Class IV isoform on granulopoiesis, Lin-, Sca-1+, and c-Kit+ (LSK) cells from Csf3r null mice were transduced with Class I or Class IV and colony forming unit (CFU) assay for granulopoiesis was performed with Methocult 3534. Colony scores and cell morphology were assessed on day 8. Results. K562 cells with transient expression of mutant SRSF2 P95H and LUC7L2 knockout resulted in statistically significant increase in Class IV:I CSF3R mRNA ratios normalized to a minigene-only control. Interestingly, expression of mutant U2AF1 S34F significantly decreased Class IV:I while U2AF1 Q157P increased Class IV:I ratios. K562 cells expressing mutant SF3B1 K700E did not show significant differences in Class IV splicing. To further investigate how SRSF2 regulates CSF3R splicing, we deleted two putative SRSF2-binding ESE motifs (ESE1 and ESE2) within exon 17 of the CSF3R minigene and transfected them into K562 cells stably expressing either wildtype SRSF2 or mutant P95H, P95L, or P95R. Deletion of either ESE1 or ESE2 resulted in decreased Class IV:I in all SRSF2 P95 mutant cells compared to minigene-only and wildtype controls. Next, we assessed the effect of SRSF2 P95 mutations on neutrophil differentiation in CD34+ cells. Overexpression of SRSF2 P95H, P95L, or P95R led to increased neutrophilic precursors compared to untransduced CD34+ cells. To determine the effect of a single CSF3R isoform on granulopoiesis, we cultured LSK cells from Csf3r null mice transduced with either Class I or Class IV on MethoCult 3534 with addition of GCSF. On day 8, cells expressing Class I had more total colony numbers with significantly higher CFU-GM colonies than cells expressing Class IV compared to empty vector control. Conclusions. We demonstrated that mutated SRSF2, U2AF1, and LUC7L2 deficiency alters CSF3R splicing in its terminal exon. Interestingly, mutations on different residues of the same gene (U2AF1) had opposing effects on CSF3R splicing. Mutant SRSF2 resulted in increased intron excision to promote increased levels of Class IV isoform. Mutation of two putative SRSF2 binding sites within CSF3R exon 17 reversed the increased splicing promoted by mutant SRSF2, further support our observation that CSF3R is a target for mutant SRSF2. Our observation with overexpression of mutant SRSF2 P95 in CD34+ cells suggests that defective neutrophil differentiation is related to increased Class IV. Our findings shed insights into how aberrant splicing of CSF3R drives MDS progression and provides a new model of dysgranulopoiesis. Disclosures No relevant conflicts of interest to declare.