Daniela Rogaia

Effects on differentiation by the promyelocytic leukemia PML/RARalpha protein depend on the fusion of the PML protein dimerization and RARalpha DNA binding domains.

The block of terminal differentiation is a prominent feature of acute promyelocytic leukemia (APL) and its release by retinoic acid correlates with disease remission. Expression of the APL‐specific PML/RARalpha fusion protein in hematopoietic precursor cell lines blocks terminal differentiation, suggesting that PML/ RARalpha may have the same activity in APL blasts. We expressed different PML/RARalpha mutants in U937 and TF‐1 cells and demonstrated that the integrity of the PML protein dimerization and RARalpha DNA binding domains is crucial for the differentiation block induced by PML/RARalpha, and that these domains exert their functions only within the context of the fusion protein. Analysis of the in vivo dimerization and cell localization properties of the PML/RARalpha mutants revealed that PML/RARalpha–PML and PML/RARalpha–RXR heterodimers are not necessary for PML/RARalpha activity on differentiation. We propose that a crucial mechanism underlying PML/RARalpha oncogenic activity is the deregulation of a transcription factor, RARalpha, through its fusion with the dimerization interface of another nuclear protein, PML.

Formation of PML/RARα high molecular weight nuclear complexes through the PML coiled-coil region is essential for the PML/RARα-mediated retinoic acid response

Retinoic Acid (RA) treatment induces disease remission of Acute Promyelocytic Leukaemia (APL) patients by triggering terminal differentiation of neoplastic cells. RA-sensitivity in APL is mediated by its oncogenic protein, which results from the recombination of the PML and the RA receptor α (RARα) genes (PML/RARα fusion protein). Ectopic expression of PML/RARα into haemopoietic cell lines results in increased response to RA-induced differentiation. By structure-function analysis of PML/RARα-mediated RA-differentiation, we demonstrated that fusion of PML and RARα sequences and integrity of the PML dimerization domain and of the RARα DNA binding region are required for the effect of PML/RARα on RA-differentiation. Indeed, direct fusion of the PML dimerization domain to the N- or C-terminal extremities of RARα retained full biological activity. All the biologically active PML/RARα mutants formed high molecular weight complexes in vivo. Functional analysis of mutations within the PML dimerization domain revealed that the capacity to form PML/RARα homodimers, but not PML/RARα-PML heterodimers, correlated with the RA-response. These results suggest that targeting of RARα sequences by the PML dimerization domain and formation of nuclear PML/RARα homodimeric complexes are crucial for the ability of PML/RARα to mediate RA-response.

2q31.2q32.3 Deletion Syndrome : Report of an Adult Patient

A 36‐year‐old patient with a disorder characterized by severe mental retardation, behavioral problems, dysmorphic face, “muscular build,” and hand/foot anomalies, is reported. Following a diagnosis of de novo pericentric inversion of chromosome 8 based on standard cytogenetic analysis, a subsequent 75 kb array‐CGH investigation disclosed a deletion spanning for about 13.7 Mb in the 2q31.2q32.3 region. Whole painting of chromosome 8 established the intrachromosomal nature of the rearrangement and FISH analysis with locus‐specific probes confirmed the deletion on the long arm of chromosome 2. The deleted region, clinical outcome, and medical history in this patient are mainly superimposable to those reported in a published 8‐year‐old boy, suggesting that this genomic segment is prone to rearrangements and its hemizygosity gives rise to a clinically recognizable syndrome. The role of some genes mapping in the deleted region and related with distinct disorders is discussed. Interestingly, deletion of MSTN gene, a negative regulator of muscle growth, was associated in our patient with a “muscular build,” a feature which could be regarded as a handle for clinical recognition of this syndrome.

Terminal megakaryocytic differentiation of TF-1 cells is induced by phorbol esters and thrombopoietin and is blocked by expression of PML/RARα fusion protein

We have analyzed the differentiation program of growth factor-dependent TF-1 erythroleukemia cells as well as clones with inducible expression of the APL-specific PML/RARα protein. We have shown that TF-1 cells may be induced to megakaryocytic differentiation by phorbol ester (phorbol dibutyrate, PDB) addition, particularly when combined with thrombopoietin (Tpo). RT-PCR studies showed that Tpo induces Tpo receptor (TpoR or c-mpl), whose expression was further potentiated by PDB addition. When the cells are induced with both PDB and Tpo erythropoietin receptor (EpoR) expression was inhibited. In the absence of Zn2+-induced PML/RARα expression, PDB and Tpo induced megakaryocytic differentiation of TF-1 MTPR clones as observed in ‘wild-type’ TF-1 cells. Conversely, when PML/RARα expression was induced by Zn2+, PDB and Tpo treatment of these clones caused only a reduced level of megakaryocytic differentiation. These observations indicate that: (1) TF-1 cells as well as other erythroleukemic cells, possess the capacity to differentiate to megakaryocytic cells when grown in the presence of protein kinase (PKC) activators and more efficiently when combined with Tpo; (2) the PML/RARα gene has a wide capacity to interfere with the program of hematopoietic differentiation, including megakaryocytic differentiation. Finally, we also observed that PML/RARα expression in TF-1 cells induces an up-modulation of interleukin-3 receptor, c-kit and c-mpl, a phenomenon which may offer these cells a growth advantage.

Deletion 2p15-16.1 syndrome: case report and review.

We report on a 9‐year‐old female patient with facial anomalies and developmental delay, heterozygous for three de novo rearrangements: a paracentric inversion of chromosome 7, an apparently balanced translocation between chromosome 1 and 7, involving the same inverted chromosome 7, detected by standard cytogenetic analysis [46,XX, der(7) inv(7)(q21.1q32.1)t(1;7)(q23q32.1)]; and a 2p16.1 deletion, spanning about 3.5 Mb of genomic DNA, shown by SNP‐array analysis [arr 2p16.1 (56,706,666–60,234,485)x1 dn]. Clinical features and cytogenetic imbalance in our patient were similar to those reported in five published cases, suggesting that this genomic region is prone to recombination and its hemizygosity results in a distinct although variable spectrum of clinical manifestations.

Acute Promyelocytic Leukaemia Cells Resistant to Retinoic Acid Show Further Perturbation of the RARα Signal Transduction System

Acute promyelocytic leukaemia (APL) cell lines resistant to all-trans retinoic acid (ATRA) have been previously derived from the NB4 cell line, and characterized as having lost the expression of the intact pml/RAR alpha fusion protein. To confirm the association between ATRA-resistance and alteration in the fusion protein at the clonal level, 16 clones were generated from ATRA-resistant APL cell lines. All clones show immunological (HLA class I and II, CD11b and c, CD13 and 33), molecular and growth features similar to the parental cell lines. To investigate whether the irradiation protocol used to generate the previously reported retinoic acid-resistant NB4.306 cell line induced additional alterations that could render these cells able to escape the anti-proliferative effect of retinoic acid (ATRA), an additional ATRA-resistant APL cell line, [NB4.007/6], was generated, under the selective pressure of ATRA, from the NB4 cell line without previous radiation. This cell line shows resistance to the anti-proliferative and differentiating action of ATRA. The NB4.007/6 cell line contains the t(15;17) chromosome translocation, shows the usual pml/RAR alpha hybrid DNA but expresses no detectable amount of the usual pml/RAR alpha protein in Western blot analysis, similarly to the NB4.306 cell line. Finally, the relative resistance to ATRA of NB4.306 and NB4.007/6 was evaluated by comparing the phenotypic (CD11b) changes induced by ATRA in these two lines with those induced in the parental, ATRA-sensitive, NB4 cell line. It is estimated that NB4.306 and NB4.007/6 are about 300 and 70 times less sensitive to ATRA than the original NB4 cell line.

DPP6 gene disruption in a family with Gilles de la Tourette syndrome

Gilles de la Tourette syndrome (TS) is a neurodevelopmental disorder characterized by multiple motor and vocal tics, frequently associated with psychiatric co-morbidities. Despite the significant level of heritability, the genetic architecture of TS still remains elusive. Herein, we investigated an Italian family where an 8-year-old boy, his father, and paternal uncle have a diagnosis of TS. Array-CGH and high resolution SNP-array analyses revealed a heterozygous microdeletion of ∼135 kb at the 7q36.2 locus in the proband and his father. Fluorescent in situ hybridization and quantitative PCR (qPCR) analyses confirmed the presence of the alteration also in the paternal uncle. The deletion selectively involves the first exon of the DPP6 gene, leading to a down-regulation of its expression, as demonstrated by the reduced messenger RNA (mRNA) levels assessed by RT-qPCR. The DPP6 gene encodes for a type II membrane glycoprotein expressed predominantly in the central nervous system. To date, a de novo DPP6 exonic duplication, of uncertain significance, was reported in one patient with TS. Moreover, the DPP6 gene has been implicated in the pathogenesis of autism spectrum disorder (ASD) and, notably, in haloperidol-induced dyskinesia. This first familial case provides evidence for association between DPP6 haploinsufficiency and TS, further suggesting a plausible molecular link between TS and ASD, and might shed some light on the efficacy and tolerability profiles of antidopaminergic agents used for tic management, thus prompting further studies on a larger cohort of patients.

Recurrent ∼100 Kb microdeletion in the chromosomal region 14q11.2, involving CHD8 gene, is associated with autism and macrocephaly

The most frequent causes of Intellectual Disability (ID)/Autism Spectrum Disorders (ASDs) are chromosomal abnormalities, genomic rearrangements and submicroscopic deletions coupled with duplications. We report here on an 11‐year‐old girl showing autism, macrocephaly, and facial dysmorphism, in which array‐CGH showed a de novo microdeletion of ∼114 Kb in the 14q11.2 chromosomal region, involving the SUPT16H, CHD8, and RAB2B genes. Four patients with ID and/or ASD and/or macrocephaly with overlapping deletions have been previously described: three showed very large rearrangements (>1 Mb), while one had a microdeletion of ∼101 Kb, largely overlapping the one reported herein. The minimal critical region, considering present and previous cases, contains the SUPT16H and CHD8 genes. Notably, recent studies also disclosed CHD8 heterozygous loss‐of‐function mutations in patients with ASD and macrocephaly. Our finding shows the presence of a recurrent microdeletion associated with a clinically recognizable phenotype, and further on underlines the pivotal role of CHD8 gene in the pathogenesis of the disorder.

A novel MED12 mutation: Evidence for a fourth phenotype.

Mutations of the MED12 gene have been reported mainly in males with FG (Opitz–Kaveggia), Lujan–Fryns, or X‐linked Ohdo syndromes. Recently, a different phenotype characterized by minor anomalies, severe intellectual disability (ID), and absent language was reported in female and male patients belonging to the same family and carrying a frameshift MED12 mutation (c.5898dupC). Here, we report on two brothers and their niece affected by severe and mild ID, respectively, where whole exome sequencing combined with variant analysis within a panel of ID‐related genes, disclosed a novel c.2312T>C (p.Ile771Thr) MED12 mutation. This variant, which has not been reported as a polymorphism, was not present in a third unaffected brother, and was predicted to be deleterious by five bioinformatic databases. This finding together with the phenotypic analogies shared with the carriers of c.5898dupC mutation suggests the existence of a fourth MED12‐related disorder, characterized by severe ID, absent or deficient language and, milder, clinical manifestation in heterozygotes. We have reviewed the literature on MED12 heterozygotes, their clinical manifestations, and discuss the possible biological causes of this condition.

Nablus mask-like facial syndrome: deletion of chromosome 8q22.1 is necessary but not sufficient to cause the phenotype

Nablus mask‐like facial syndrome (NMLFS) has many distinctive phenotypic features, particularly tight glistening skin with reduced facial expression, blepharophimosis, telecanthus, bulky nasal tip, abnormal external ear architecture, upswept frontal hairline, and sparse eyebrows. Over the last few years, several individuals with NMLFS have been reported to have a microdeletion of 8q21.3q22.1, demonstrated by microarray analysis. The minimal overlapping region is 93.98–96.22 Mb (hg19). Here we present clinical and microarray data from five singletons and two mother‐child pairs who have heterozygous deletions significantly overlapping the region associated with NMLFS. Notably, while one mother and child were said to have mild tightening of facial skin, none of these individuals exhibited reduced facial expression or the classical facial phenotype of NMLFS. These findings indicate that deletion of the 8q21.3q22.1 region is necessary but not sufficient for development of the NMLFS. We discuss possible genetic mechanisms underlying the complex pattern of inheritance for this condition.