Annachiara De Sandre-Giovannoli

Homozygous Defects in LMNA, Encoding Lamin A/C Nuclear-Envelope Proteins, Cause Autosomal Recessive Axonal Neuropathy in Human (Charcot-Marie-Tooth Disorder Type 2) and Mouse

The Charcot-Marie-Tooth (CMT) disorders comprise a group of clinically and genetically heterogeneous hereditary motor and sensory neuropathies, which are mainly characterized by muscle weakness and wasting, foot deformities, and electrophysiological, as well as histological, changes. A subtype, CMT2, is defined by a slight or absent reduction of nerve-conduction velocities together with the loss of large myelinated fibers and axonal degeneration. CMT2 phenotypes are also characterized by a large genetic heterogeneity, although only two genes---NF-L and KIF1Bbeta---have been identified to date. Homozygosity mapping in inbred Algerian families with autosomal recessive CMT2 (AR-CMT2) provided evidence of linkage to chromosome 1q21.2-q21.3 in two families (Zmax=4.14). All patients shared a common homozygous ancestral haplotype that was suggestive of a founder mutation as the cause of the phenotype. A unique homozygous mutation in LMNA (which encodes lamin A/C, a component of the nuclear envelope) was identified in all affected members and in additional patients with CMT2 from a third, unrelated family. Ultrastructural exploration of sciatic nerves of LMNA null (i.e., -/-) mice was performed and revealed a strong reduction of axon density, axonal enlargement, and the presence of nonmyelinated axons, all of which were highly similar to the phenotypes of human peripheral axonopathies. The finding of site-specific amino acid substitutions in limb-girdle muscular dystrophy type 1B, autosomal dominant Emery-Dreifuss muscular dystrophy, dilated cardiomyopathy type 1A, autosomal dominant partial lipodystrophy, and, now, AR-CMT2 suggests the existence of distinct functional domains in lamin A/C that are essential for the maintenance and integrity of different cell lineages. To our knowledge, this report constitutes the first evidence of the recessive inheritance of a mutation that causes CMT2; additionally, we suggest that mutations in LMNA may also be the cause of the genetically overlapping disorder CMT2B1.

Splicing-Directed Therapy in a New Mouse Model of Human Accelerated Aging

Antisense oligonucleotides reverse premature aging and extend life span in mutant mice that mimic aberrant splicing in progeria patients. Countering Careless Cutting Carpenters warn that one should “measure twice, cut once” to avoid unfixable assaults on building materials. Indeed, careless cutting lies at the heart of Hutchinson-Gilford progeria syndrome (HGPS). This premature aging disease is caused by a point mutation in the LMNA gene that activates a cryptic donor splice site in LMNA RNA; aberrant cutting and splicing results in the production of an mRNA that encodes progerin, a truncated form of the lamin A protein that is also produced in small amounts during normal aging. Until now, no model system has recapitulated the pathogenic LMNA splicing that occurs in HGPS patients. Here, Osorio et al. characterize such HGPS mutant mice mimics—called LmnaG609G/G609G mice—and show that antisense oligonucleotide–based therapy reverses various premature aging phenotypes and extends life span. Encoded by the LMNA gene, lamin A is a nuclear envelope protein that is important for nuclear stability, chromatin structure, and regulation of gene expression. Osorio et al. showed that the LmnaG609G/G609G mice produced reduced amounts of intact lamin A, accumulated progerin, displayed the nuclear abnormalities and transcriptional alterations seen in other progeroid models, and sported the key clinical features of human HGPS, such as a shortened life span, reduced size, disrupted metabolism, and enhanced bone and cardiovascular maladies relative to wild-type animals. The authors then used their newly characterized HGPS animal model to test the effects of antisense morpholino oligonucleotides that bound to and blocked the aberrant splice donor site in Lmna RNA. These reagents reduced progerin accumulation and corrected the nuclear abnormalities in both cultured mutant mouse and human HGPS fibroblasts. Furthermore, LmnaG609G/G609G mice that were treated with a combination of two antisense oligonucleotides that blocked aberrant splicing displayed reduced amounts of accumulated progerin, enhanced life expectancy, and a reversal of the phenotypical and molecular alterations associated with HGPS, including the righting of gene expression aberrations and normalization of blood glucose levels. Together, these findings provide preclinical proof of concept for the use of antisense oligonucleotide–based therapies in the treatment of HGPS. Furthermore, because progerin also accumulates during normal aging, the LmnaG609G/G609G mutant mice may be useful for preclinical testing of therapies designed to slow the human aging process and prevent age-related diseases. As the poet Ralph Waldo Emerson noted, “All diseases run into one—old age.” Hutchinson-Gilford progeria syndrome (HGPS) is caused by a point mutation in the LMNA gene that activates a cryptic donor splice site and yields a truncated form of prelamin A called progerin. Small amounts of progerin are also produced during normal aging. Studies with mouse models of HGPS have allowed the recent development of the first therapeutic approaches for this disease. However, none of these earlier works have addressed the aberrant and pathogenic LMNA splicing observed in HGPS patients because of the lack of an appropriate mouse model. Here, we report a genetically modified mouse strain that carries the HGPS mutation. These mice accumulate progerin, present histological and transcriptional alterations characteristic of progeroid models, and phenocopy the main clinical manifestations of human HGPS, including shortened life span and bone and cardiovascular aberrations. Using this animal model, we have developed an antisense morpholino–based therapy that prevents the pathogenic Lmna splicing, markedly reducing the accumulation of progerin and its associated nuclear defects. Treatment of mutant mice with these morpholinos led to a marked amelioration of their progeroid phenotype and substantially extended their life span, supporting the effectiveness of antisense oligonucleotide–based therapies for treating human diseases of accelerated aging.

Unique Preservation of Neural Cells in Hutchinson- Gilford Progeria Syndrome Is Due to the Expression of the Neural-Specific miR-9 MicroRNA

One puzzling observation in patients affected with Hutchinson-Gilford progeria syndrome (HGPS), who overall exhibit systemic and dramatic premature aging, is the absence of any conspicuous cognitive impairment. Recent studies based on induced pluripotent stem cells derived from HGPS patient cells have revealed a lack of expression in neural derivatives of lamin A, a major isoform of LMNA that is initially produced as a precursor called prelamin A. In HGPS, defective maturation of a mutated prelamin A induces the accumulation of toxic progerin in patient cells. Here, we show that a microRNA, miR-9, negatively controls lamin A and progerin expression in neural cells. This may bear major functional correlates, as alleviation of nuclear blebbing is observed in nonneural cells after miR-9 overexpression. Our results support the hypothesis, recently proposed from analyses in mice, that protection of neural cells from progerin accumulation in HGPS is due to the physiologically restricted expression of miR-9 to that cell lineage.

Molecular genetics of autosomal-recessive axonal Charcot-Marie-Tooth neuropathies

Autosomal-recessive forms of Charcot-Marie-Tooth (ARCMT) account for less than 10% of the families with CMT. On the other hand, in countries with a high prevalence of consanguinity this mode of inheritance accounts, likely, for the vast majority of CMT phenotypes. Like dominant forms, autosomal-recessive forms are generally subdivided into demyelinating forms (autosomal-recessive CMT1: ARCMT1 or CMT4) and axonal forms (ARCMT2). Until now, demyelinating ARCMT were more extensively studied at the genetic level than the axonal forms. Although the latter are undoubtedly the rarest forms among the heterogeneous group of CMT, three distinct forms have been genetically mapped and recent studies in the past 4 yr provided evidence that their respective causing genes have been characterized. Indeed, gene defects in encoding A-type lamins (LMNA), encoding Ganglioside-induced Differentiation-Associated Protein-1 (GDAP1) and encoding the mediator of RNA polymerase II transcription, subunit 25 homolog (MED25) have been identified in ARCMT2 subtypes. Given the clinical, electrophysiological and histological heterogeneity of CMT2, it is likely that unreported forms of ARCMT2, related to novel genes, remain to be discovered, leading to an even more complex classification. However, our goal in this review is to provide the reader with a clear view on the known genes and mechanisms involved in ARCMT2 and their associated phenotypes.

Induced Pluripotent Stem Cells Reveal Functional Differences Between Drugs Currently Investigated in Patients With Hutchinson-Gilford Progeria Syndrome

Hutchinson‐Gilford progeria syndrome is a rare congenital disease characterized by premature aging in children. Identification of the mutation and related molecular mechanisms has rapidly led to independent clinical trials testing different marketed drugs with a preclinically documented impact on those mechanisms. However, the extensive functional effects of those drugs remain essentially unexplored. We have undertaken a systematic comparative study of the three main treatments currently administered or proposed to progeria‐affected children, namely, a farnesyltransferase inhibitor, the combination of an aminobisphosphonate and a statin (zoledronate and pravastatin), and the macrolide antibiotic rapamycin. This work was based on the assumption that mesodermal stem cells, which are derived from Hutchinson‐Gilford progeria syndrome‐induced pluripotent stem cells expressing major defects associated with the disease, may be instrumental to revealing such effects. Whereas all three treatments significantly improved misshapen cell nuclei typically associated with progeria, differences were observed in terms of functional improvement in prelamin A farnesylation, progerin expression, defective cell proliferation, premature osteogenic differentiation, and ATP production. Finally, we have evaluated the effect of the different drug combinations on this cellular model. This study revealed no additional benefit compared with single‐drug treatments, whereas a cytostatic effect equivalent to that of a farnesyltransferase inhibitor alone was systematically observed. Altogether, these results reveal the complexity of the modes of action of different drugs, even when they have been selected on the basis of a similar mechanistic hypothesis, and underscore the use of induced pluripotent stem cell derivatives as a critical and powerful tool for standardized, comparative pharmacological studies.

An association of Hutchinson-Gilford progeria and malignancy.

Mutations in the LMNA gene encoding lamins A/C are responsible for a variety of disorders, commonly referred to as “laminopathies,” including the segmental premature aging syndrome Hutchinson–Gilford progeria. We describe in this report the rare association of osteosarcoma and slowly progressing progeria in an 11‐year‐old girl carrying a truncating heterozygous c.1868C > G (p.T623S) prelamin A mutation. These findings are discussed in light of recent data on the pathophysiological mechanisms underlying progeria and “physiological” aging in human, as well as previous data on other well‐known segmental aging syndromes.

Tight skin and limited joint movements as early presentation of Hutchinson-Gilford progeria in a 7-week-old infant

We present a 7-week-old male infant with pseudoscleroderma as a primary manifestation of the Hutchinson-Gilford syndrome of premature aging. He had suffered intra-uterine growth retardation; micrognathism and a cleft palate were evident at birth. He presented with feeding difficulties and severe, diffuse scleroderma-like lesions, a faint peri-oral cyanosis and prominent scalp veins. With time, special facial features became more and more apparent: frontal bossing, prominent eyes, thin and fine nose and lips, microstomia, low-set ears and occipito-parietal alopecia. Histopathology of the skin showed an increased density and thickness of collagen in the dermis and hypodermis. Within the 1st year of life, typical skeletal characteristics were observed. The diagnosis of Hutchinson-Gilford syndrome was confirmed by analysis of the lamin A gene, revealing a heterozygous c.1824C>T (G608G) mutation. Conclusion:Hutchinson-Gilford syndrome is an extremely rare disorder of which the full clinical spectrum becomes evident with time. Sclerodermatous changes in the infant can be the first manifestation.

Type B mandibuloacral dysplasia with congenital myopathy due to homozygous ZMPSTE24 missense mutation

Mutation in ZMPSTE24 gene, encoding a major metalloprotease, leads to defective prelamin A processing and causes type B mandibuloacral dysplasia, as well as the lethal neonatal restrictive dermopathy syndrome. Phenotype severity is correlated with the residual enzyme activity of ZMPSTE24 and accumulation of prelamin A. We had previously demonstrated that a complete loss of function in ZMPSTE24 was lethal in the neonatal period, whereas compound heterozygous mutations including one PTC and one missense mutation were associated with type B mandibuloacral dysplasia. In this study, we report a 30-year longitudinal clinical survey of a patient harboring a novel severe and complex phenotype, combining an early-onset progeroid syndrome and a congenital myopathy with fiber-type disproportion. A unique homozygous missense ZMPSTE24 mutation (c.281T>C, p.Leu94Pro) was identified and predicted to produce two possible ZMPSTE24 conformations, leading to a partial loss of function. Western blot analysis revealed a major reduction of ZMPSTE24, together with the presence of unprocessed prelamin A and decreased levels of lamin A, in the patients primary skin fibroblasts. These cells exhibited significant reductions in lifespan associated with major abnormalities of the nuclear shape and structure. This is the first report of MAD presenting with confirmed myopathic abnormalities associated with ZMPSTE24 defects, extending the clinical spectrum of ZMPSTE24 gene mutations. Moreover, our results suggest that defective prelamin A processing affects muscle regeneration and development, thus providing new insights into the disease mechanism of prelamin A-defective associated syndromes in general.

Novel LMNA Mutation in Atypical Werner Syndrome Presenting With Ischemic Disease

Background and Purpose— Laminopathies arise through mutations in genes encoding Lamin A/C (LMNA) or associated proteins. They cause 4 different groups of disorders with diverse severity and often overlapping features: diseases of striated muscle (leading to muscular or cardiac involvement), peripheral neuropathy, lipodystrophy syndromes, and accelerated aging disorders. Summary of Case— We report on a familial case of atypical Werner syndrome (a progeroid syndrome with Werner syndrome phenotype but without typical RECQL2 mutation) presenting with acute ischemic cerebral disease or peripheral artery disease associated with diffuse atherosclerosis, attributable to transmission of a novel LMNA mutation. Conclusions— In young patients with ischemic events and a positive family history, other progeroid features have to be searched and LMNA testing has to be considered, allowing for genetic counseling and presymptomatic testing of at-risk relatives.

An inherited LMNA gene mutation in atypical Progeria syndrome.

Hutchinson–Gilford Progeria syndrome (HGPS) is a rare genetic disorder, characterized by several clinical features that begin in early childhood, recalling an accelerated aging process. The diagnosis of HGPS is based on the recognition of common clinical features and detection of the recurrent heterozygous c.1824C>T (p.Gly608Gly) mutation within exon 11 in the Lamin A/C encoding gene (LMNA). Besides “typical HGPS,” several “atypical progeria” syndromes (APS) have been described, in a clinical spectrum ranging from mandibuloacral dysplasia to atypical Werner syndrome. These patientss clinical features include progeroid manifestations, such as short stature, prominent nose, premature graying of hair, partial alopecia, skin atrophy, lipodystrophy, skeletal anomalies, such as mandibular hypoplasia and acroosteolyses, and in some cases severe atherosclerosis with metabolic complications. APS are due in several cases to de novo heterozygous LMNA mutations other than the p.Gly608Gly, or due to homozygous BAFN1 mutations in Nestor–Guillermo Progeria syndrome (NGPS). We report here and discuss the observation of a non‐consanguineous Moroccan patient presenting with atypical progeria. The molecular studies showed the heterozygous mutation c.412G>A (p.Glu138Lys) of the LMNA gene. This mutation, previously reported as a de novo mutation, was inherited from the apparently healthy father who showed a somatic cell mosaicism.