Early-Onset Cerebral Amyloid Angiopathy and Alzheimer Disease Related to an APP Locus Triplication.

BACKGROUND AND OBJECTIVE: To report a triplication of the amyloid-ß precursor protein (APP) locus along with relative messenger RNA (mRNA) expression in a family with autosomal dominant early-onset cerebral amyloid angiopathy (CAA) and Alzheimer disease (AD). METHODS: Four copies of the APP gene were identified by quantitative multiplex PCR of short fluorescent fragments, fluorescent in situ hybridization (FISH), and array comparative genomic hybridization. APP mRNA levels were assessed using reverse-transcription-digital droplet PCR in the proband's whole blood and compared with 10 controls and 9 APP duplication carriers. RESULTS: Beginning at age 39 years, the proband developed severe episodic memory deficits with a CSF biomarker profile typical of AD and multiple lobar microbleeds in the posterior regions on brain MRI. His father had seizures and recurrent cerebral hemorrhage since the age of 37 years. His cerebral biopsy showed abundant perivascular amyloid deposits, leading to a diagnosis of CAA. In the proband, we identified 4 copies of a 506-kb region located on chromosome 21q21.3 and encompassing the whole APP gene without any other gene. FISH suggested that the genotype of the proband was 3 copies/1 copy corresponding to an APP locus triplication, which was consistent with the presence of 2 APP copies in the healthy mother and with the paternal medical history. Analysis of the APP mRNA level showed a 2-fold increase in the proband and a 1.8 fold increase in APP duplication carriers compared with controls. DISCUSSION: Increased copy number of APP is sufficient to cause AD and CAA, with likely earlier onset in case of triplication compared with duplication.

Further refinement of COL4A1 and COL4A2 related cortical malformations.

Mutations in COL4A1 have been reported in schizencephaly and porencephaly combined with microbleeds or calcifications, often associated with ocular and renal abnormalities, myopathy, elevated creatine kinase levels and haemolytic anaemia. In this study, we aimed to clarify the phenotypic spectrum of COL4A1/A2 mutations in the context of cortical malformations that include schizencephaly, polymicrogyria and/or heterotopia. METHODS: We screened for COL4A1/A2 mutations in 9 patients with schizencephaly and/or polymicrogyria suspected to be caused by vascular disruption and leading to a cerebral haemorrhagic ischaemic event. These included 6 cases with asymmetrical or unilateral schizencephaly and/or polymicrogyria and 3 cases with bilateral schizencephaly. RESULTS: One de novo missense COL4A1 mutation (c.3715 G > A, p.(Gly1239Arg)) and two COL4A2 mutations were found, respectively in one familial case (c.4129G > A, p.(Gly1377Arg)) and one sporadic patient (c.1776+1G > A). In three other cases, COL4A1 variants of unknown significance were identified. None of our patients demonstrated neuromuscular or hematological anomalies. Brain malformations included a combination of schizencephaly, mainly asymmetrical, with porencephaly or ventriculomegaly (3/3 mutated patients). We did not observe microbleeds or microcalcifications in any of our cases, hence we do not believe that they represent a distinctive feature of COL4A1/A2 mutations. CONCLUSIONS: Our study further emphasizes the need to search for both COL4A1 and COL4A2 mutations in children presenting with uni- or bilateral polymicrogyria with schizencephaly, even in the absence of intracranial microbleeds, calcification or associated systemic features.

Optical Coherence Tomography Angiography of Familial Retinal Arteriolar Tortuosity.

BACKGROUND AND OBJECTIVE: To analyze the location of familial retinal arterial tortuosity (fRAT) in the three-dimensional structure of retinal capillaries. PATIENTS AND METHODS: Retrospective observational study. Twelve eyes of six patients (two of whom were brothers) were imaged by optical coherence tomography angiography (OCTA). The data from their ocular and systemic examinations were recorded. RESULTS: OCTA imaging clearly showed increased tortuosity of second- and third-order retinal arteries in all cases, visible in the superficial vascular plexus (SVP) up to the arteriole termination in the capillaries. No change was visible in the deep capillary plexus (DCP). CONCLUSIONS: OCTA shows that fRAT affects all the course of the arterioles up to the capillaries in the SVP. The DCP does not show arteriolar tortuosity because it does not contain arterioles. [Ophthalmic Surg Lasers Imaging Retina. 2018;49:397-401.].

APP Mutations in Cerebral Amyloid Angiopathy with or without Cortical Calcifications: Report of Three Families and a Literature Review.

BACKGROUND: Specific APP mutations cause cerebral amyloid angiopathy (CAA) with or without Alzheimer's disease (AD). OBJECTIVE: We aimed at reporting APP mutations associated with CAA, describe the clinical, cerebrospinal fluid AD biomarkers, and neuroimaging features, and compare them with the data from the literature. METHODS: We performed a retrospective study in two French genetics laboratories by gathering all clinical and neuroimaging data from patients referred for a genetic diagnosis of CAA with an age of onset before 66 years and fulfilling the other Boston revised criteria. We studied the segregation of mutations in families and performed a comprehensive literature review of all cases reported with the same APP mutation. RESULTS: We screened APP in 61 unrelated French patients. Three mutations, located in the Aß coding region, were detected in five patients from three families: p.Ala692Gly (Flemish), p.Glu693Lys (Italian), and p.Asp694Asn (Iowa). Patients exhibited CAA and progressive cognitive impairment associated with cortical calcifications in the Iowa and Italian mutation carriers, but not the patient carrying the Flemish mutation. CONCLUSIONS: This is the first evidence of cortical calcification in patients with an APP mutation other than the Iowa mutation. We discuss the radiological, cerebrospinal fluid, and clinical phenotype of patients carrying these mutations in the literature.

COL4A2 mutation causing adult onset recurrent intracerebral hemorrhage and leukoencephalopathy.

Type IV collagen α1 and α2 chains form heterotrimers that constitute an essential component of basement membranes. Mutations in COL4A1, encoding the α1 chain, cause a multisystem disease with prominent cerebrovascular manifestations, including porencephaly, bleeding-prone cerebral small vessel disease, and intracranial aneurysms. Mutations in COL4A2 have only been reported in a few porencephaly families so far. Herein, we report on a young adult patient with recurrent intracerebral hemorrhage, leukoencephalopathy, intracranial aneurysms, nephropathy, and myopathy associated with a novel COL4A2 mutation. We extensively investigated a 29-year-old male patient with recurrent deep intracerebral hemorrhages causing mild motor and sensory hemisyndromes. Brain MRI showed deep intracerebral hemorrhages of different age, diffuse leukoencephalopathy, multiple cerebral microbleeds and small aneurysms of the carotid siphon bilaterally. Laboratory work-up revealed significant microscopic hematuria and elevation of creatine-kinase. Genetic testing found a de novo glycine mutation within the COL4A2 triple helical domain. The presented case completes the spectrum of cerebral and systemic manifestations of COL4A2 mutations that appears to be very similar to that in COL4A1 mutations. Therefore, we emphasize the importance of screening both COL4A1 and COL4A2 in patients showing recurrent intracerebral hemorrhage of unknown etiology, particularly if associated with leukoencephalopathy.

A novel hereditary extensive vascular leukoencephalopathy mapping to chromosome 20q13.

OBJECTIVE: The detection of a leukoencephalopathy is a frequent situation in neurologic practice. In a number of cases, the etiology remains obscure despite extensive investigations. We characterized the clinical, pathologic, and genetic features of a novel hereditary vascular leukoencephalopathy. METHODS: After the observation of a similar leukoencephalopathy in 2 sisters, clinical, neuroimaging, and molecular genetics investigations were conducted in 21 of their consenting relatives. Pathologic data were obtained in one patient. RESULTS: Fourteen members presented with significant white matter lesions at MRI examination, among whom only 5 individuals were symptomatic. The main clinical manifestations included gait disturbances, transient movement disorders, stroke, and cognitive dysfunction. The 9 remaining members aged from 26 to 60 years were asymptomatic. The MRI pattern was highly stereotyped with symmetric white matter hyperintensities worsening with patient's age. We mapped the gene involved in this condition on chromosome 20q13. Neuropathologic examination suggested that this leukoencephalopathy is underlaid by a cerebral arteriolopathy affecting small preterminal arterioles, clearly distinct from amyloid angiopathy and hypertension-related small-vessel disease. CONCLUSIONS: These data establish that this family is affected by a novel autosomal dominant vascular leukoencephalopathy mapping to chromosome 20q13. This disease is characterized by a progressive and age-related hemispheric and brainstem leukoencephalopathy contrasting with the paucity and late onset of clinical symptoms in most of the cases.

COL4A1-related disease: raised creatine kinase and cerebral calcification as useful pointers.

BACKGROUND: Mutations in COL4A1 are responsible for a spectrum of clinical phenotypes characterized by neurological, ocular, and renal involvement. Neurological features are the most prominent but as such are rather nonspecific. CASE PRESENTATION: Here, we report three new cases that, like five patients we previously described, show the novel common finding of raised creatine kinase (CK) concentration. CONCLUSION: Raised CK concentration, in addition to intracranial calcification, is to be considered another useful pointer to a final diagnosis of COL4A1-related disease.

A cortical form of CADASIL with cerebral Aß amyloidosis.

Cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy (CADASIL) was diagnosed by genetic testing in a 53-year-old patient, 10 years before death. Following two strokes with partial recovery, he developed rapidly progressive cognitive decline 3 years before death. Neuropathology confirmed CADASIL. Characteristic arteriolar changes were associated with subcortical infarcts, and status cribrosus in basal ganglia and the cortico-subcortical junctions. Leukoencephalopathy was very mild. Severe arteriolar changes in the cerebral cortex and leptomeninges were associated with numerous intracortical microinfarcts. There was abundant Abeta deposition throughout the cerebral cortex, mainly as Aß42 diffuse plaques, frequently periarteriolar. There was no cerebral amyloid angiopathy apart from rare Aß40 deposits around Notch3-positive deposits. Amyloid plaques were rare. Tau pathology was minimal. Alzheimer disease associated with CADASIL has been described, but the few reported cases had abundant amyloid plaques, amyloid angiopathy, fibrillar plaques and neurofibrillary tangles. Aß accumulation could result from abnormal Aß synthesis or impaired elimination due to the arteriolar changes of CADASIL. We did not find Aß deposits in our other CADASIL cases with milder cortical arteriolar changes. Additional genetic predisposing factors were not identified. This case suggests that besides the classical, purely subcortical form of CADASIL, a "cortical" form with numerous lacunar infarcts and Aß deposition in the cerebral cortex may occur and may be difficult to differentiate clinically from Alzheimer disease.

Ophthalmological features associated with COL4A1 mutations.

OBJECTIVE: To investigate the wide variability of ocular manifestations associated with mutations in the COL4A1 gene that encodes collagen IValpha1. METHODS: We clinically evaluated 7 patients from 2 unrelated families in whom ocular features segregated with COL4A1 mutations that were identified by direct sequencing. RESULTS: The G2159A transition (c.2159G>A) that leads to the missense mutation p.Gly720Asp was identified in family A. An ocular phenotype of variable severity was observed in all affected relatives. The missense mutation c.2263G>A, p.Gly755Arg was identified in family B. One patient from family B also displayed notable ocular features. CONCLUSIONS: The COL4A1 mutations may be associated with various ophthalmologic developmental anomalies of anterior segment dysgenesis type, which are reminiscent of Axenfeld-Rieger anomalies (ARA). Cerebrovascular disorders should be added to the list of signs potentially associated with ARA. CLINICAL RELEVANCE: These data suggest that cerebral magnetic resonance imaging may be recommended in the clinical treatment of patients with apparently isolated ARA, even when neurological symptoms or signs are lacking.

Activating NOTCH3 mutation in a patient with small-vessel-disease of the brain.

The most common causative diagnosis of hereditary small-vessel-disease of the brain, CADASIL, is due to highly stereotyped mutations in the NOTCH3 receptor. NOTCH3 has 33 exons but all CADASIL mutations occur within the Epidermal Growth Factor-like Repeats encoded by exons 2-24, lead to an odd number of cysteine residues and are associated with GOM deposits and abnormal NOTCH3 protein accumulation. The majority of CADASIL mutations appear to retain normal level of signaling activity, while very few mutations show reduced activity. Herein we identified a novel heterozygous missense mutation (c.4544T>C) in exon 25 of NOTCH3 in a patient with cerebral small-vessel-disease but lacking GOM deposits and NOTCH3 accumulation. The mutation should result in a p.L1515P substitution in the evolutionarily highly conserved juxtamembranous region of NOTCH3, which constitutes the heterodimerization domain. The p.L1515P mutant exhibits increased canonical NOTCH3 signaling, although in a ligand-independent fashion. Biochemical analysis suggests that the mutation renders NOTCH3 hyperactive through destabilization of the heterodimer. Therefore, our study suggests that the p.L1515P mutation falls in a novel mechanistic class of NOTCH3 mutations and that NOTCH3 activating mutations should be further considered for molecular analysis of patients with cerebral small-vessel-disease.

A large genomic deletion in the PDHX gene caused by the retrotranspositional insertion of a full-length LINE-1 element.

The long interspersed element-1 (LINE-1 or L1) retrotransposition has altered the human genome in many ways. In particular, recent in vitro studies have demonstrated that the retrotranspositional insertion of L1 elements has resulted in significant genomic deletions. Here we provide evidence for its operation in the human genome by identifying a approximately 46-kb pathological genomic deletion in the PDHX gene directly linked to the insertion of a full-length L1 element, in a patient with pyruvate dehydrogenase complex (PDHc) deficiency. Both the deduced bottom and top strand cleavage sites in the PDHX gene coincide with the consensus L1 endonuclease (EN) target sequence 5'-TTTT/A-3', while the full-length L1 element is followed by a 67-bp poly(A) tail. Interestingly, two hairpin structures, potentially formed by the inverted repeats present immediately 5' to the top strand nick site and 3' to the bottom strand nick site, may have facilitated the accessibility of L1 EN to the target sequences and also brought the two otherwise distantly located sequences into close proximity. Since the L1 element inserted in the PDHX gene is full-length, we favor the model of the template jumping as opposed to that of the microhomology-mediated end-joining for linking the 5' end of the nascent L1 copy to its genomic target. Our finding not only serves as an important complement to the in vitro approaches to studying L1 retrotransposition, but also reveals a novel mechanism causing human genetic disease.

A novel gross deletion caused by non-homologous recombination of the PDHX gene in a patient with pyruvate dehydrogenase deficiency.

We report here the molecular analysis of a pyruvate dehydrogenase E3-binding protein (PDH-E3BP) deficiency in a new patient, born to first cousin parents. She has initially presented with a non-progressive and unspecific encephalopathy, followed by an acute neurological deterioration at 14 years of age. E3BP subunit was undetectable on Western blot. The sequence of exons 1-9 and exon 11 of the PDHX gene were normal, but exon 10 was impossible to amplify with standard PCR. Long-range PCR including exons 9-11 (11.5 kb) was performed. The patient's sample displayed a unique PCR product of 7.5 kb, whereas the parents' samples displayed two bands (11.5 and 7.5 kb). The deletion breakpoints were determined by restriction analysis followed by direct sequencing. The homozygous deletion covered the end of intron 9, exon 10 and the beginning of intron 10 and was found to be 3913 bp long. The cDNA sequencing confirmed the deletion of exon 10. The most probable mechanism for this gross deletion appears to be a slipped mispairing mediated by an exact direct repeat CCACTG. It is the first time that a non-homologous recombination is reported in the PDHX gene causing pyruvate dehydrogenase complex (PDHc) deficiency.

Leigh's disease due to a new mutation in the PDHX gene.

OBJECTIVE: To describe the clinical course, neuroradiological presentation, biochemical and molecular studies of a new patient with pyruvate dehydrogenase complex (PDHc) deficiency. To compare this case with the data on other published cases. METHODS: Brain magnetic resonance imaging (MRI), basal metabolic investigations with lactate measurements in body fluids, PDHc activity assay on cultured skin fibroblasts, immunoblot analysis and molecular studies (polymerase chain reaction [PCR] and sequencing procedures). RESULTS: Our patient accused an unspecific encephalopathy for years and presented at 13 years of age an acute deterioration with basal ganglia necrosis and subcortical white matter involvement. PDHc deficiency was secondary to a large deletion (3913 bp) in the PDHX gene, which encodes E3 binding protein (E3BP) subunit. INTERPRETATION: These data provide an additional case of E3BP deficiency with a unique and previously unreported deletion in the PDHX gene.

First characterization of a large deletion of the PDHA 1 gene.

Pyruvate dehydrogenase complex (PDC) deficiency is one of the major recognized causes of congenital lactic acidosis. The most common form is due to PDHA 1 gene (Xp22.12) defects. Here, we report the case of a Polynesian girl presenting with delayed neurological development, cortical atrophy, and posterior corpus callosum agenesis. Elevated lactate and pyruvate levels in blood and cerebrospinal fluid suggested PDC deficiency. However, PDC activity was within the normal range in lymphocytes and the direct sequencing of the 11 exons and intron-exon junctions of the PDHA 1 gene did not show any changes. Long-range PCR amplification of the whole gene (16 kb) from blood DNA revealed a heterozygous deletion of approximately 4.2kb. Fine mapping of the deletion breakpoint was achieved using purified long-range PCR products for restriction enzyme analysis and direct sequencing. The deletion removed a 4,227 bp region covering part of intron 5 to part of intron 9 [g.10,145_14,371 del 4,227]. The deletion breakpoint contained a short direct repeat (GTAG), which may be derived either from the upstream or the downstream homologous sequence. The presence of a GAG triplet and inverted repeats in the vicinity of the deletion suggest replication slippage at a polymerase alpha arrest site. This is the first time that a large intragenic deletion of the PDHA 1 gene has been characterized.

The SR protein SC35 is responsible for aberrant splicing of the E1alpha pyruvate dehydrogenase mRNA in a case of mental retardation with lactic acidosis.

Pyruvate dehydrogenase (PDH) complex deficiency is a major cause of lactic acidosis and Leigh's encephalomyelopathies in infancy and childhood, resulting in early death in the majority of patients. Most of the molecular defects have been localized in the coding regions of the E1alpha PDH gene. Recently, we identified a novel mutation of the E1alpha PDH gene in a patient with an encephalopathy and lactic acidosis. This mutation, located downstream of exon 7, activates a cryptic splice donor and leads to the retention of intronic sequences. Here, we demonstrate that the mutation results in an increased binding of the SR protein SC35. Consistently, ectopic overexpression of this splicing factor enhanced the use of the cryptic splice site, whereas small interfering RNA-mediated reduction of the SC35 protein levels in primary fibroblasts from the patient resulted in the almost complete disappearance of the aberrantly spliced E1alpha PDH mRNA. Our findings open the exciting prospect for a novel therapy of an inherited disease by altering the level of a specific splicing factor.