A homozygous Y443C variant in the RNPC3 is associated with severe syndromic congenital hypopituitarism and diffuse brain atrophy.

Biallelic RNPC3 variants have been reported in a few patients with growth hormone deficiency, either in isolation or in association with central hypothyroidism, congenital cataract, neuropathy, developmental delay/intellectual disability, hypogonadism, and pituitary hypoplasia. To describe a new patient with syndromic congenital hypopituitarism and diffuse brain atrophy due to RNPC3 mutations and to compare her clinical and molecular characteristics and pituitary functions with previously published patients. A 20-year-old female presented with severe growth, neuromotor, and developmental delay. Her weight, height, and head circumference were 5135 gr (-25.81 SDS), 68 cm (-16.17 SDS), and 34 cm (-17.03 SDS), respectively. She was prepubertal, and had dysmorphic facies, contractures, and spasticity in the extremities, and severe truncal hypotonia. There were no radiological signs of a skeletal dysplasia. The bone age was extremely delayed at 2 years. Investigation of pituitary function revealed growth hormone, prolactin, and thyroid-stimulating hormone deficiencies. Whole-exome sequencing revealed a novel homozygous missense (c.1328A > G; Y443C) variant in RNPC3. Cranial MRI revealed a hypoplastic anterior pituitary with diffuse cerebral and cerebellar atrophy. The Y443C variant in RNPC3 associated with syndromic congenital hypopituitarism and abnormal brain development. This report extends the RNPC3-related hypopituitarism phenotype with a severe neurodegenerative presentation.

Anti-RNPC-3 antibody predicts poor prognosis in patients with interstitial lung disease associated to systemic sclerosis.

OBJECTIVE: To analyse the prevalence, the clinical characteristics, the overall survival and the event-free survival (EFS) of SSc patients who express anti-U11/U12 RNP (RNPC-3) antibodies. METHODS: A total of 447 SSc patients from Barcelona (n = 286) and Milan (n = 161) were selected. All samples were tested using a particle-based multi-analyte technology. We compared anti-RNPC-3 positive and negative patients. Epidemiological, clinical features and survival were analysed. End-stage lung disease (ESLD) was defined if the patient developed forced vital capacity <50% of predicted, needed oxygen therapy or lung transplantation. EFS was defined as the period of time free of either ESLD or death. RESULTS: Nineteen of 447 (4.3%) patients had anti-RNPC-3 antibodies and interstitial lung disease (ILD) was more frequent (11, 57.9% vs 144, 33.6%, P =0.030) in individuals with anti-RNPC-3 antibodies. More patients reached ESLD in the positive group (7, 36.8% vs 74, 17.3%, P = 0.006), and a higher use of non-glucocorticoid immunosuppressive drugs was observed (11, 57.9% vs 130, 30.4%, P = 0.012). Anti-RNPC-3 positive patients had lower EFS, both in the total cohort (log-rank P =0.001), as well as in patients with ILD (log-rank P = 0.002). In multivariate Cox regression analysis, diffuse cutaneous subtype, age at onset, the presence of ILD or pulmonary arterial hypertension and the expression of anti-RNPC-3 positivity or anti-topo I were independently associated with worse EFS. CONCLUSION: The presence of anti-RNPC-3 was associated with higher frequency of ILD and either ESLD or death. These data suggest anti-RNPC-3 is an independent poor prognosis antibody in SSc, especially if ILD is also present.

Establishing intellectual disability as the key feature of patients with biallelic RNPC3 variants.

Some mammalian genes contain both major and minor introns, the splicing of which require distinctive major and minor spliceosomes, respectively; these genes are referred to as minor intron containing-genes. RNPC3 (RNA-binding domain-containing protein 3) is one of the proteins that are unique to the minor spliceosome U11/U12 di-snRNP. Only two families with biallelic pathogenic variants in the RNPC3 gene encoding the protein have been reported so far, and the affected members in both families had proportional short stature. While the affected members of the originally identified family did not have intellectual disability, the patients from the other family exhibited intellectual disability. Here, we report on a patient with severe primordial microcephalic dwarfism and intellectual disability who carried compound heterozygous variants in RNPC3 (NM_017619.3): c.261dup, p.Leu88Thrfs*11 and c.1228T>G, p.Phe410Val. The single nucleotide substitution c.1228T>G had a very high predictive score for pathogenicity: the p.Phe410 residue is highly conserved down to fish. Based on ACMG (American College of Medical Genetics and Genomics) guideline, this non-synonymous variant was scored as likely pathogenic. This documentation of yet another patient with biallelic RNPC3 variants exhibiting intellectual disability lends further support to the notion that intellectual disability is a key feature of the spectrum of RNPC3-related disorders.

Early developmental arrest and impaired gastrointestinal homeostasis in U12-dependent splicing-defective Rnpc3-deficient mice.

Splicing is an essential step in eukaryotic gene expression. While the majority of introns is excised by the U2-dependent, or major class, spliceosome, the appropriate expression of a very small subset of genes depends on U12-dependent, or minor class, splicing. The U11/U12 65K protein (hereafter 65K), encoded by RNPC3, is one of seven proteins that are unique to the U12-dependent spliceosome, and previous studies including our own have established that it plays a role in plant and vertebrate development. To pinpoint the impact of 65K loss during mammalian development and in adulthood, we generated germline and conditional Rnpc3-deficient mice. Homozygous Rnpc3-/- embryos died prior to blastocyst implantation, whereas Rnpc3+/- mice were born at the expected frequency, achieved sexual maturity, and exhibited a completely normal lifespan. Systemic recombination of conditional Rnpc3 alleles in adult (Rnpc3lox/lox ) mice caused rapid weight loss, leukopenia, and degeneration of the epithelial lining of the entire gastrointestinal tract, the latter due to increased cell death and a reduction in cell proliferation. Accompanying this, we observed a loss of both 65K and the pro-proliferative phospho-ERK1/2 proteins from the stem/progenitor cells at the base of intestinal crypts. RT-PCR analysis of RNA extracted from purified preparations of intestinal epithelial cells with recombined Rnpc3lox alleles revealed increased frequency of U12-type intron retention in all transcripts tested. Our study, using a novel conditional mouse model of Rnpc3 deficiency, establishes that U12-dependent splicing is not only important during development but is indispensable throughout life.

Expanding the phenotype of biallelic RNPC3 variants associated with growth hormone deficiency.

Pathogenic variants in components of the minor spliceosome have been associated with several human diseases. Recently, it was reported that biallelic RNPC3 variants lead to severe isolated growth hormone deficiency and pituitary hypoplasia. The RNPC3 gene codes for the U11/U12-65K protein, a component of the minor spliceosome. The minor spliceosome plays a role in the splicing of minor (U12-type) introns, which are present in ~700-800 genes in humans and represent about 0.35% of all introns. Here, we report a second family with biallelic RNPC3 variants in three siblings with a growth hormone deficiency, central congenital hypothyroidism, congenital cataract, developmental delay/intellectual deficiency and delayed puberty. These cases further confirm the association between biallelic RNPC3 variants and severe postnatal growth retardation due to growth hormone deficiency. Furthermore, these cases show that the phenotype of this minor spliceosome-related disease might be broader than previously described.

A Novel RNPC3 Gene Variant Expands the Phenotype in Patients with Congenital Hypopituitarism and Neuropathy.

INTRODUCTION: Pathogenic biallelic RNPC3 variants cause congenital hypopituitarism (CH) with congenital cataracts, neuropathy, developmental delay/intellectual disability, primary ovarian insufficiency, and pituitary hypoplasia. Here, we aimed to evaluate the clinical and molecular characteristics of 2 patients with CH and neuropathy. MATERIALS AND METHODS: Proband was evaluated by clinical, laboratory, and radiological exams, followed by exome sequencing (ES). Clinical investigation of an affected sibling and variant segregation in the family was performed by Sanger sequencing. A three-dimensional protein model study was conducted to predict the effect of the variant on the function of the RNPC3 peptide. RESULTS: Proband was a 16-month-old girl who was referred for the evaluation of failure to thrive. Her height, weight, and head circumference were 55.8 cm (-7.6 SDS), 6.5 kg (-3.6 SDS), and 41.8 cm (-3.82), respectively. She had a developmental delay and intellectual disability. Central hypothyroidism, growth hormone, and prolactin deficiencies were identified, and MRI revealed pituitary hypoplasia. Electroneuromyography performed for the gait abnormality revealed peripheral neuropathy. A homozygous novel variant c.484C>T/p.(Pro162Ser) in the RNPC3 was detected in the ES. Her brother had the same genotype, and he similarly had pituitary hormone deficiencies with polyneuropathy. CONCLUSION: Expanding our knowledge of the spectrum of RNPC3 variants, and apprehending clinical and molecular data of additional cases, is decisive for accurate diagnosis and genetic counseling.

Identification of RNPC3 as a novel JAK2 fusion partner gene in B-acute lymphoblastic leukemia refractory to combination therapy including ruxolitinib.

BACKGROUND: Hematopoietic neoplasms with chromosomal translocations involving JAK2 are rare, and most of them show myeloproliferative neoplasm-associated features, followed by B-acute lymphoblastic leukemia (B-ALL). De novo B-ALL cases with JAK2 rearrangements are suggested to be appropriately considered as BCR-ABL1-like B-ALL, but its partners varied. METHODS: Fluorescence in situ hybridization (FISH), RNA sequencing (RNA-Seq), whole-genome sequencing, and reverse transcription polymerase chain reaction (RT-PCR) were performed to identify the pathogenic fusion gene in a 29-year-old woman with relapsed B-ALL and rare t(1;9)(p13;p22) translocation. RESULTS: We identified RNPC3 as a new JAK2 fusion partner in the patient. She was treated with a combination of chemotherapy and targeted drug ruxolitinib and chimeric antigen receptor T-cell therapy, but failed to achieve complete remission. She had no chance to undergo allogeneic hematopoietic stem cell transplantation and died of disease progression 7 months after the initial diagnosis. Her clinical course demonstrated that this novel RNPC3-JAK2 fusion might portend an unfavorable prognosis. CONCLUSION: This finding adds to the expanding compendium of JAK2 fusions found in B-ALL and suggests the potential need for a diagnostic FISH analysis as well as RNA-Seq in the appropriate clinical setting.

Experimental approaches to studying the nature and impact of splicing variation in zebrafish.

From a fixed number of genes carried in all cells, organisms create considerable diversity in cellular phenotype through differential regulation of gene expression. One prevalent source of transcriptome diversity is alternative pre-mRNA splicing, which is manifested in many different forms. Zebrafish models of splicing dysfunction due to mutated spliceosome components provide opportunity to link biochemical analyses of spliceosome structure and function with whole organism phenotypic outcomes. Drawing from experience with two zebrafish mutants: cephalophonus (a prpf8 mutant, isolated for defects in granulopoiesis) and caliban (a rnpc3 mutant, isolated for defects in digestive organ development), we describe the use of glycerol gradient sedimentation and native gel electrophoresis to resolve components of aberrant splicing complexes. We also describe how RNAseq can be employed to examine relatively rare alternative splicing events including intron retention. Such experimental approaches in zebrafish can promote understanding of how splicing variation and dysfunction contribute to phenotypic diversity and disease pathogenesis.