PTEN is a dual-specificity phosphatase and well-known tumor suppressor gene. When functioning properly, it works in its canonical pathway to inhibit AKT/mTOR and MAPK signaling, leading to cell death and growth regulation. PTEN mutations cause dysregulation of these pathways, resulting in cellular proliferation and overgrowth. When germline mutations are present as in patients with PTEN Hamartoma Tumor Syndrome (PHTS), benign and malignant neoplasias occur as well as cerebral overgrowth and neurodevelopmental abnormalities. This review article will summarize recent laboratory and clinical investigations relating to PTEN, highlighting the overgrowth aspects of this syndrome and the molecular drivers behind these key phenotypes. Finally, therapies developed targeted the PI3K/AKT/mTOR pathway for other tumor predisposition syndromes will be discussed. © 2013 Wiley Periodicals, Inc.

Perlman syndrome is a rare autosomal recessively inherited congenital overgrowth syndrome characterized by polyhydramnios, macrosomia, characteristic facial dysmorphology, renal dysplasia and nephroblastomatosis and multiple congenital anomalies. Perlman syndrome is associated with high neonatal mortality and, survivors have developmental delay and a high risk of Wilms tumor. Recently a Perlman syndrome locus was mapped to chromosome 2q37 and homozygous or compound heterozygous mutations were characterized in DIS3L2. The DIS3L2 gene product has ribonuclease activity and homology to the DIS3 component of the RNA exosome. It has been postulated that the clinical features of Perlman syndrome result from disordered RNA metabolism and, though the precise targets of DIS3L2 have yet to be characterized, in cellular models DIS3L2 knockdown is associated with abnormalities of cell growth and division. © 2013 Wiley Periodicals, Inc.

Human growth is a complex process starting at conception and completing in adolescence at the time of growth plate fusion. Growth can be divided into four phases: (1) fetal, where the predominant endocrine factors controlling growth are insulin and the insulin-like growth factors. (2) Infancy, where growth is mainly dependent upon nutrition. (3) Childhood, where the growth hormone–insulin-like growth factor-I (GH-IGF-I) axis and thyroid hormone are most important. (4) Puberty, where along with the GH-IGF-I axis the activation of the hypothalamo-pituitary–gonadal axis to generate sex steroid secretion becomes vital to the completion of growth. GH is released from the pituitary in a pulsatile fashion under the control of GHRH, Ghrelin, and somatostatin and, via a complex signal transduction cascade, initiates the release of IGF-I within many tissues but predominantly the liver and at the growth plate. IGF-I acts in an autocrine and paracrine manner via the IGF-I receptor to stimulate cell proliferation and longitudinal growth. Activation of the pituitary–gonadal axis during puberty occurs via a complex interaction of factors including kisspeptin, leptin, gonadotrophin releasing hormone, and tachykinin ultimately leading to augmentation of GH secretion, the pubertal growth spurt, and fusion of the growth plates. Many other hormones can affect the GH-IGF-I system or directly affect cell proliferation at the growth plate including thyroid hormone, vitamin D, and corticosteroids. © 2013 Wiley Periodicals, Inc.

This issue of the Seminar Series C is dedicated to the molecular mechanisms of childhood overgrowth and celebrates the last decade of unprecedented gene discovery. Constitutional gene disorders, somatic gene disorders and imprinting dysregulation are each considered. The constitutional overgrowth genes discussed include NSD1, EZH2, GPC3, DIS3L2, and PTEN whilst the somatic overgrowth genes include AKT3, PIK3R2, and PIK3CA. Abnormalities of imprinting, exemplified by disruption of the (epi)genetic regulation of the imprinted 11p15 gene cluster, constitutes the final section of this issue. Many of the genes discussed in this issue encode components of the PI3K/mTOR growth regulatory pathway. This signaling cascade consists of dual, parallel branches, anchored by the serine–threonine kinase, mTOR, and has diverse downstream effects including inhibition of apoptosis, activation of protein synthesis, and enhanced cell survival. Activation of the PI3K/mTOR pathway promotes growth whereas inhibition, or abrogation, results in decreased cellular growth. Despite the rapid advances of the last decade, there is still an enormous amount to discover. We hope that some of the work reviewed in this issue will facilitate the next decade's discoveries and we look forward to a 10 years as productive as the last. © 2013 Wiley Periodicals, Inc.

Human growth is a complex process starting at conception and completing in adolescence at the time of growth plate fusion. Growth can be divided into four phases: (1) fetal, where the predominant endocrine factors controlling growth are insulin and the insulin-like growth factors. (2) Infancy, where growth is mainly dependent upon nutrition. (3) Childhood, where the growth hormone–insulin-like growth factor-I (GH-IGF-I) axis and thyroid hormone are most important. (4) Puberty, where along with the GH-IGF-I axis the activation of the hypothalamo-pituitary–gonadal axis to generate sex steroid secretion becomes vital to the completion of growth. GH is released from the pituitary in a pulsatile fashion under the control of GHRH, Ghrelin, and somatostatin and, via a complex signal transduction cascade, initiates the release of IGF-I within many tissues but predominantly the liver and at the growth plate. IGF-I acts in an autocrine and paracrine manner via the IGF-I receptor to stimulate cell proliferation and longitudinal growth. Activation of the pituitary–gonadal axis during puberty occurs via a complex interaction of factors including kisspeptin, leptin, gonadotrophin releasing hormone, and tachykinin ultimately leading to augmentation of GH secretion, the pubertal growth spurt, and fusion of the growth plates. Many other hormones can affect the GH-IGF-I system or directly affect cell proliferation at the growth plate including thyroid hormone, vitamin D, and corticosteroids. © 2013 Wiley Periodicals, Inc.

NSD1 and EZH2 are SET domain-containing histone methyltransferases that play key roles in the regulation of transcription through histone modification and chromatin modeling: NSD1 preferentially methylates lysine residue 36 of histone 3 (H3K36) and is primarily associated with active transcription, while EZH2 shows specificity for lysine residue 27 (H3K27) and is associated with transcriptional repression. Somatic dysregulation of NSD1 and EZH2 have been associated with tumorigenesis. NSD1, as a fusion transcript with NUP98, plays a key role in leukemogenesis, particularly childhood acute myeloid leukemia. EZH2 is a major proto-oncogene and mono- and biallelic activating and inactivating somatic mutations occur as early events in the development of tumors, particularly poor prognosis hematopoietic malignancies. Constitutional NSD1 and EZH2 mutations cause Sotos and Weaver syndromes respectively, overgrowth syndromes with considerable phenotypic overlap. NSD1 mutations that cause Sotos syndrome are loss-of-function, primarily truncating mutations or missense mutations at key residues in functional domains. EZH2 mutations that cause Weaver syndrome are primarily missense variants and the rare truncating mutations reported to date are in the last exon, suggesting that simple haploinsufficiency is unlikely to be generating the overgrowth phenotype although the exact mechanism has not yet been determined. Many additional questions about the molecular and clinical features of NSD1 and EZH2 remain unanswered. However, studies are underway to address these and, as more cases are ascertained and technology improves, it is hoped that these will, in time, be answered. © 2013 Wiley Periodicals, Inc.

Simpson–Golabi–Behmel syndrome (SGBS) is a rare X-linked multiple congenital abnormality/intellectual disability syndrome characterized by pre- and post-natal overgrowth, distinctive craniofacial features, macrocephaly, variable congenital malformations, organomegaly, increased risk of tumor and mild/moderate intellectual deficiency. In 1996, Glypican 3 (GPC3) was identified as the major gene causing SGBS but the mutation detection rate was only 28–70%, suggesting either genetic heterogeneity or that some patients could have alternative diagnoses. This was particularly suggested by some reports of atypical cases with more severe prognoses. In the family reported by Golabi and Rosen, a duplication of GPC4 was recently identified, suggesting that GPC4 could be the second gene for SGBS but no point mutations within GPC4 have yet been reported. In the genetics laboratory in Tours Hospital, GPC3 molecular testing over more than a decade has detected pathogenic mutations in only 8.7% of individuals with SGBS. In addition, GPC4 mutations have not been identified thus raising the question of frequent misdiagnosis. In order to better delineate the phenotypic spectrum of SGBS caused by GPC3 mutations, and to try to define specific clinical criteria for GPC3 molecular testing, we reviewed the clinical features of all male cases with a GPC3 mutation identified in the two molecular laboratories providing this test in France (Tours and Paris). We present here the results of the analysis of 42 patients belonging to 31 families and including five fetuses and three deceased neonates. © 2013 Wiley Periodicals, Inc.

Perlman syndrome is a rare autosomal recessively inherited congenital overgrowth syndrome characterized by polyhydramnios, macrosomia, characteristic facial dysmorphology, renal dysplasia and nephroblastomatosis and multiple congenital anomalies. Perlman syndrome is associated with high neonatal mortality and, survivors have developmental delay and a high risk of Wilms tumor. Recently a Perlman syndrome locus was mapped to chromosome 2q37 and homozygous or compound heterozygous mutations were characterized in DIS3L2. The DIS3L2 gene product has ribonuclease activity and homology to the DIS3 component of the RNA exosome. It has been postulated that the clinical features of Perlman syndrome result from disordered RNA metabolism and, though the precise targets of DIS3L2 have yet to be characterized, in cellular models DIS3L2 knockdown is associated with abnormalities of cell growth and division. © 2013 Wiley Periodicals, Inc.

PTEN is a dual-specificity phosphatase and well-known tumor suppressor gene. When functioning properly, it works in its canonical pathway to inhibit AKT/mTOR and MAPK signaling, leading to cell death and growth regulation. PTEN mutations cause dysregulation of these pathways, resulting in cellular proliferation and overgrowth. When germline mutations are present as in patients with PTEN Hamartoma Tumor Syndrome (PHTS), benign and malignant neoplasias occur as well as cerebral overgrowth and neurodevelopmental abnormalities. This review article will summarize recent laboratory and clinical investigations relating to PTEN, highlighting the overgrowth aspects of this syndrome and the molecular drivers behind these key phenotypes. Finally, therapies developed targeted the PI3K/AKT/mTOR pathway for other tumor predisposition syndromes will be discussed. © 2013 Wiley Periodicals, Inc.

The megalencephaly-polymicrogyria-polydactyly-hydrocephalus (MPPH) and megalencephaly-capillary malformation (MCAP) syndromes are highly recognizable and partly overlapping disorders of brain overgrowth (megalencephaly). Both syndromes are characterized by congenital or early postnatal megalencephaly, with a high risk for progressive ventriculomegaly leading to hydrocephalus and cerebellar tonsillar ectopia leading to Chiari malformation, and cortical brain abnormalities, specifically polymicrogyria. MCAP is further characterized by distinct cutaneous capillary malformations, finger or toe syndactyly, postaxial polydactyly, variable connective tissue dysplasia and mild focal or segmental body overgrowth, among other features. MPPH, on the other hand, lacks consistent vascular or somatic manifestations besides postaxial polydactyly in almost half of reported individuals. We identified de novo germline mutations in PIK3R2 and AKT3 in individuals with MPPH, and both postzygotic, mosaic and rare germline mutations in PIK3CA in individuals with MCAP. PIK3R2, AKT3, and PIK3CA are members of the critical phosphatidylinositol-3-kinase (PI3K)-vakt murine thymoma viral oncogene homolog (AKT) pathway that is well implicated in cell growth, proliferation, survival, apoptosis, among other diverse cellular functions. The identified mutations in these three genes have been shown to lead to gain of function and activation of the PI3K-AKT pathway. Germline and postzygotic mutations of PIK3CA and other PI3K-AKT-mTOR pathway genes have also been identified in several other overgrowth syndromes, highlighting the key role of this signaling pathway in normal development and pathophysiology of a large group of congenital anomalies. © 2013 Wiley Periodicals, Inc.

Our understanding of Beckwith–Wiedemann syndrome (BWS) has recently been enhanced by advances in its molecular characterization. These advances have further delineated intricate (epi)genetic regulation of the imprinted gene cluster on chromosome 11p15.5 and the role of these genes in normal growth and development. Studies of the molecular changes associated with the BWS phenotype have been instrumental in elucidating critical molecular elements in this imprinted region. This review will provide updated information on the multiple new regulatory elements that have been recently found to contribute to in cis or in trans control of imprinted gene expression in the chromosome 11p15.5 region and the clinical expression of the BWS phenotype. © 2013 Wiley Periodicals, Inc.