Protracted late infantile ceroid lipofuscinosis due to TPP1 mutations: Clinical, molecular and biochemical characterization in three sibs.

OBJECTIVE: This work investigated the molecular cause responsible for a late-onset parkinsonism-dystonia phenotype in three Italian siblings, and clinically characterize this condition. METHODS: Extensive neurophysiological and neuroradiological exams were performed on the three sibs. Most frequent late-onset metabolic diseases were ruled out through laboratory and biochemical analyses. A whole exome sequencing (WES) approach was used to identify the molecular cause underlying this condition. RESULTS AND CONCLUSIONS: Peculiar neurologic phenotype was characterized by dystonia-parkinsonism, cognitive impairment, gait ataxia and apraxia, pyramidal signs. WES analysis allowed the identification of a compound heterozygosity for two nucleotide substitutions (c.1340G>A, p.R447H; c.790C>T, p.Q264X) affecting the TPP1 gene in the three affected siblings. Biochemical analyses demonstrated abrogated TPP1 catalytic activity in primary skin fibroblasts, but revealed residual activity in leukocytes. Our findings document that late infantile neuronal ceroid lipofuscinosis (CLN2), which is caused by TPP1 gene mutations, should be considered in the differential diagnosis of autosomal recessive dystonia-parkinsonism syndromes. The availability of enzyme replacement therapy and other therapeutic approaches for ceroid lipofuscinoses emphasizes the value of reaching an early diagnosis in patients with atypical and milder presentation of these disorders.

A restricted spectrum of mutations in the SMAD4 tumor-suppressor gene underlies Myhre syndrome.

Myhre syndrome is a developmental disorder characterized by reduced growth, generalized muscular hypertrophy, facial dysmorphism, deafness, cognitive deficits, joint stiffness, and skeletal anomalies. Here, by performing exome sequencing of a single affected individual and coupling the results to a hypothesis-driven filtering strategy, we establish that heterozygous mutations in SMAD4, which encodes for a transducer mediating transforming growth factor ß and bone morphogenetic protein signaling branches, underlie this rare Mendelian trait. Two recurrent de novo SMAD4 mutations were identified in eight unrelated subjects. Both mutations were missense changes altering Ile500 within the evolutionary conserved MAD homology 2 domain, a well known mutational hot spot in malignancies. Structural analyses suggest that the substituted residues are likely to perturb the binding properties of the mutant protein to signaling partners. Although SMAD4 has been established as a tumor suppressor gene somatically mutated in pancreatic, gastrointestinal, and skin cancers, and germline loss-of-function lesions and deletions of this gene have been documented to cause disorders that predispose individuals to gastrointestinal cancer and vascular dysplasias, the present report identifies a previously unrecognized class of mutations in the gene with profound impact on development and growth.

Ferroportin and erythroid cells: an update.

In recent years there have been major advances in our knowledge of the regulation of iron metabolism that have had implications for understanding the pathophysiology of some human disorders like beta-thalassemia and other iron overload diseases. However, little is known about the relationship among ineffective erythropoiesis, the role of iron-regulatory genes, and tissue iron distribution in beta-thalassemia. The principal aim of this paper is an update about the role of Ferroportin during human normal and pathological erythroid differentiation. Particular attention will be given to beta-thalassemia and other diseases with iron overload. Recent discoveries indicate that there is a potential for therapeutic intervention in beta-thalassemia by means of manipulating iron metabolism.

Hematopoietic differentiation: a coordinated dynamical process towards attractor stable states.

BACKGROUND: The differentiation process, proceeding from stem cells towards the different committed cell types, can be considered as a trajectory towards an attractor of a dynamical process. This view, taking into consideration the transcriptome and miRNome dynamics considered as a whole, instead of looking at few 'master genes' driving the system, offers a novel perspective on this phenomenon. We investigated the 'differentiation trajectories' of the hematopoietic system considering a genome-wide scenario. RESULTS: We developed serum-free liquid suspension unilineage cultures of cord blood (CB) CD34+ hematopoietic progenitor cells through erythroid (E), megakaryocytic (MK), granulocytic (G) and monocytic (Mo) pathways. These cultures recapitulate physiological hematopoiesis, allowing the analysis of almost pure unilineage precursors starting from initial differentiation of HPCs until terminal maturation. By analyzing the expression profile of protein coding genes and microRNAs in unilineage CB E, MK, G and Mo cultures, at sequential stages of differentiation and maturation, we observed a coordinated, fully interconnected and scalable character of cell population behaviour in both transcriptome and miRNome spaces reminiscent of an attractor-like dynamics. MiRNome and transcriptome space differed for a still not terminally committed behaviour of microRNAs. CONCLUSIONS: Consistent with their roles, the transcriptome system can be considered as the state space of a cell population, while the continuously evolving miRNA space corresponds to the tuning system necessary to reach the attractor. The behaviour of miRNA machinery could be of great relevance not only for the promise of reversing the differentiated state but even for tumor biology.

ROCK2 and its alternatively spliced isoform ROCK2m positively control the maturation of the myogenic program.

Signal transduction cascades involving Rho-associated kinases (ROCK), the serine/threonine kinases downstream effectors of Rho, have been implicated in the regulation of diverse cellular functions including cytoskeletal organization, cell size control, modulation of gene expression, differentiation, and transformation. Here we show that ROCK2, the predominant ROCK isoform in skeletal muscle, is progressively up-regulated during mouse myoblast differentiation and is highly expressed in the dermomyotome and muscle precursor cells of mouse embryos. We identify a novel and evolutionarily conserved ROCK2 splicing variant, ROCK2m, that is preferentially expressed in skeletal muscle and strongly up-regulated during in vivo and in vitro differentiation processes. The specific knockdown of ROCK2 or ROCK2m expression in C2C12 myogenic cells caused a significant and selective impairment of the expression of desmin and of the myogenic regulatory factors Mrf4 and MyoD. We demonstrate that in myogenic cells, ROCK2 and ROCK2m are positive regulators of the p42 and p44 mitogen-activated protein kinase-p90 ribosomal S6 kinase-eucaryotic elongation factor 2 intracellular signaling pathways and, thereby, positively regulate the hypertrophic effect elicited by insulin-like growth factor 1 and insulin, linking the multifactorial functions of ROCK to an important control of the myogenic maturation.

Expression of alternative transcripts of ferroportin-1 during human erythroid differentiation.

BACKGROUND AND OBJECTIVES: Ferroportin-1 (FPN1) is expressed in various types of cells that play critical roles in mammalian iron metabolism and appears to act as an iron exporter in these tissues. The aim of this study was to investigate whether erythroid cells possess specific mechanisms for iron export. DESIGN AND METHODS: The expression of FPN1 during human erythroid differentiation, the characterization of alternative transcripts, the modulation by iron and the subcellular localization of this protein were studied. RESULTS: FPN1 mRNA and protein are highly expressed during human erythroid differentiation. The iron-responsive element (IRE) in the 5'- untranslated region (UTR) of FPN1 mRNA is functional but, in spite of that, FPN1 protein expression, as well as mRNA level and half-life, seem not to be affected by iron. To explain these apparenthy discordant results we searched for alternative transcripts of FPN1 and found at least three different types of transcripts, displaying alternative 5' ends. Most of the FPN1 transcripts code for the canonical protein, but only half of them contain an IRE in the 5'-UTR and have the potential to be translationally regulated by iron. Expression analysis shows that alternative FPN1 transcripts are differentially expressed during erythroid differentiation. Finally, sustained expression of alternative FPN1 transcripts is apparently observed only in erythroid cells. INTERPRETATION AND CONCLUSIONS: This is the first report describing the presence of FPN1 in erythroid cells at all stages of differentiation, providing evidence that erythroid cells possess specific mechanisms of iron export. The existence of multiple FPN1 transcripts indicates a complex regulation of the FPN1 gene in erythroid cells.