POLR1B and neural crest cell anomalies in Treacher Collins syndrome type 4.

PURPOSE: Treacher Collins syndrome (TCS) is a rare autosomal dominant mandibulofacial dysostosis, with a prevalence of 0.2-1/10,000. Features include bilateral and symmetrical malar and mandibular hypoplasia and facial abnormalities due to abnormal neural crest cell (NCC) migration and differentiation. To date, three genes have been identified: TCOF1, POLR1C, and POLR1D. Despite a large number of patients with a molecular diagnosis, some remain without a known genetic anomaly. METHODS: We performed exome sequencing for four individuals with TCS but who were negative for pathogenic variants in the known causative genes. The effect of the pathogenic variants was investigated in zebrafish. RESULTS: We identified three novel pathogenic variants in POLR1B. Knockdown of polr1b in zebrafish induced an abnormal craniofacial phenotype mimicking TCS that was associated with altered ribosomal gene expression, massive p53-associated cellular apoptosis in the neuroepithelium, and reduced number of NCC derivatives. CONCLUSION: Pathogenic variants in the RNA polymerase I subunit POLR1B might induce massive p53-dependent apoptosis in a restricted neuroepithelium area, altering NCC migration and causing cranioskeletal malformations. We identify POLR1B as a new causative gene responsible for a novel TCS syndrome (TCS4) and establish a novel experimental model in zebrafish to study POLR1B-related TCS.

LARP7 variants and further delineation of the Alazami syndrome phenotypic spectrum among primordial dwarfisms: 2 sisters.

Alazami syndrome (AS) (MIM# 615071) is an autosomal recessive microcephalic primordial dwarfism (PD) with recognizable facial features and severe intellectual disability due to depletion or loss of function variants in LARP7. To date, 15 patients with AS have been reported. Here we describe two consanguineous Algerian sisters with Alazami PD due to LARP7 homozygous pathogenic variants detected by whole exome sequencing. By comparing these two additional cases with those previously reported, we strengthen the key features of AS: severe growth restriction, severe intellectual disability and some distinguishing facial features such as broad nose, malar hypoplasia, wide mouth, full lips and abnormally set teeth. We also report significant new findings enabling further delineation of this syndrome: disproportionately mild microcephaly, stereotypic hand wringing and severe anxiety, thickened skin over the hands and feet, and skeletal, eye and heart malformations. From previous reviews, we summarize the main etiologies of PD according to the involved mechanisms and cellular pathways, highlighting their clinical core features.

Cationic liposome formulations for RNAi-based validation of therapeutic targets in rheumatoid arthritis.

Several molecules have been identified as critical mediators of chronic inflammation in immune system-mediated disorders such as rheumatoid arthritis (RA), and biological therapies targeting these molecules have been developed during the past two decades. Compared with conventional therapies, anti-TNF biotherapies have greatly improved the treatment of patients with RA, and several biological agents with distinct mechanisms of action are under development. Despite significant advances in this field, unmet medical needs remain. RA is the prototype disease for the evaluation of targeted therapies, and various novel genes have been described as being critically involved in disease pathogenesis. Thus, a novel area of research has recently emerged in the field of RA therapy, involving the genetic screening and validation of novel candidates in vivo using RNAi. Among the vehicles for the efficient targeting of macrophages, which play a critical role in disease chronicity, cationic liposomes represent the most promising option for the safe and specific use of RNAi in vivo. This review discusses the role of cationic liposomes as a mechanism for the systemic administration of siRNAs in the validation of RA therapeutic targets.

Efficient suppression of murine arthritis by combined anticytokine small interfering RNA lipoplexes.

OBJECTIVE: Blocking tumor necrosis factor (TNF) effectively inhibits inflammation and joint damage in rheumatoid arthritis (RA), but 40% of RA patients respond only transiently or not at all to the current anti-TNF biotherapies. The purpose of this study was to develop an alternative targeted therapy for this subgroup of RA patients. As proof of concept, we tested the efficiency of an RNA interference (RNAi)-based intervention that targets proinflammatory cytokines in suppressing murine collagen-induced arthritis (CIA). METHODS: Two synthetic short interfering RNA (siRNA) sequences were designed for each of the proinflammatory cytokines interleukin-1 (IL-1), IL-6, and IL-18. Their silencing specificity was assessed according to lipopolysaccharide-induced messenger RNA expression in J774.1 mouse macrophages as compared with control siRNA. For in vivo administration, siRNA were formulated as lipoplexes with the RPR209120/DOPE liposome and a carrier DNA and were injected intravenously (0.5 mg/kg) into DBA/1 mice with CIA. RESULTS: Weekly injections of anti-IL-1, anti-IL-6, or anti-IL-18 siRNA-based lipoplexes significantly reduced the incidence and severity of arthritis, abrogating joint swelling and destruction of cartilage and bone, both in the preventative and the curative settings. The most striking therapeutic effect was observed when the 3 siRNA were delivered in combination. The siRNA lipoplex cocktail reduced all pathologic features of RA, including inflammation, joint destruction, and the Th1 response, and overall parameters of RA were improved as compared with anti-TNF siRNA lipoplex-based treatment. CONCLUSION: Our results present a novel option for in vivo RNAi-based antiinflammatory immunotherapy. Our findings indicate that intravenous administration of a lipoplex cocktail containing several anticytokine siRNA is a promising novel antiinflammatory therapy for RA, as well as a useful and simple tool for understanding the pathophysiology of RA and for evaluating new therapeutic candidates.

Efficient new cationic liposome formulation for systemic delivery of small interfering RNA silencing tumor necrosis factor alpha in experimental arthritis.

OBJECTIVE: Tumor necrosis factor alpha (TNFalpha) is among the most prominent cytokines in rheumatoid arthritis (RA) and is secreted mainly by macrophages. A direct method for restoring the immunologic balance in RA is use of small interfering RNA (siRNA) for silencing the TNFalpha transcript. The aim of this study was to determine the therapeutic effect of systemic administration of TNFalpha siRNA in an experimental model of RA, optimizing its delivery using new liposome formulations. METHODS: Murine macrophages were transfected with siRNA targeting TNFalpha, and expression was measured. The therapeutic effect in collagen-induced arthritis (CIA) was assessed after intravenous delivery of TNFalpha siRNA. Delivery was optimized using a carrier DNA for complexation with the cationic liposome RPR209120/DOPE. Levels of TNFalpha and other cytokines were measured in sera and joint tissue-conditioned media. Biodistribution was determined using a fluorescent siRNA. RESULTS: In vitro, TNFalpha siRNA efficiently and specifically modulated the expression of TNFalpha at both the messenger RNA and protein levels. In vivo, complete cure of CIA was observed when TNFalpha siRNA was administered weekly, complexed with the liposome and combined with carrier DNA. Inhibition (50-70%) of articular and systemic TNFalpha secretion was detected in the siRNA-injected groups, which correlated with a decrease in the levels of interleukin-6 and monocyte chemotactic protein 1. The main organs targeted by siRNA were the liver and spleen; the addition of liposome RPR209120 and carrier DNA significantly increased organ uptake. CONCLUSION: We demonstrated the efficiency of systemic delivery of siRNA designed to silence TNFalpha in CIA, using a liposome carrier system as a way to address the methodologic limitations in vivo.