Genetic homogeneity of Pelizaeus-Merzbacher disease: tight linkage to the proteolipoprotein locus in 16 affected families. PMD Clinical Group.

Among the numerous leukodystrophies that have an early onset and no biochemical markers, Pelizaeus-Merzbacher disease (PMD) is one that can be identified using strict clinical criteria and demonstrating an abnormal formation of myelin that is restricted to the CNS in electrophysiological studies and brain magnetic resonance imaging (MRI). In PMD, 12 different base substitutions and one total deletion of the genomic region containing the PLP gene have been reported, but, despite extensive analysis, PLP exon mutations have been found in only 10%-25% of the families analyzed. To test the genetic homogeneity of this disease, we have carried out linkage analysis with polymorphic markers of the PLP genomic region in 16 families selected on strict diagnostic criteria of PMD. We observed a tight linkage of the PMD locus with markers of the PLP gene (cDNA PLP, exon IV polymorphism) and of the Xq22 region (DXS17, DXS94, and DXS287), whereas the markers located more proximally (DXYS1X and DXS3) or distally (DXS11) were not linked to the PMD locus. Multipoint analysis gave a maximal location score for the PMD locus (13.98) and the PLP gene (8.32) in the same interval between DXS94 and DXS287, suggesting that in all families PMD is linked to the PLP locus. Mutations of the extraexonic PLP gene sequences or of another unknown close gene could be involved in PMD. In an attempt to identify molecular defects of this genomic region that are responsible for PMD, these results meant that RFLP analysis could be used to improve genetic counseling for the numerous affected families in which a PLP exon mutation could not be demonstrated.     

Molecular diagnostics for myelin proteolipid protein gene mutations in Pelizaeus-Merzbacher disease.

Pelizaeus-Merzbacher disease (PMD) is a clinically heterogeneous, slowly progressive leukodystrophy. The recent detection of mutations in the myelin proteolipid protein (PLP) gene in several PMD patients offers the opportunity both to design DNA-based tests that would be useful in diagnosing a proportion of PMD cases and, in particular, to evaluate the diagnostic utility of single-strand conformation polymorphism (SSCP) analysis for this disease. A combination of SSCP analysis and direct sequencing of PCR-amplified DNA was used to screen for PLP mutations in 24 patients affected with leukodystrophies of unknown etiology. Two heretofore undescribed mutations in the PLP gene were identified, Asp202His in exon 4 and Gly73Arg in exon 3. The ease and efficiency of SSCP analysis in detecting new mutations support the utilization of this technique in screening for PLP mutations in patients with unexplained leukodystrophies.     

Complete deletion of the proteolipid protein gene (PLP) in a family with X-linked Pelizaeus-Merzbacher disease.

Pelizaeus-Merzbacher disease (PMD) is an X-linked neurologic disorder characterized by dysmyelination in the central nervous system. Proteolipid protein (PLP), a major structural protein of myelin, is coded on the X chromosome. It has been postulated that a defect in the PLP gene is responsible for PMD. Different single-nucleotide substitutions have been found in conserved regions of the PLP gene of four unrelated PMD patients. Novel Southern blot patterns suggested a complex rearrangement in a fifth family. Linkage to PLP has been shown in others. We evaluated the PLP locus in a four-generation family with two living males affected with X-linked PMD. Analysis of DNA from the affected males revealed complete absence of a band, with PLP probes encompassing the promoter region, the entire coding region, and the 3' untranslated region and spanning at least 29 kb of genomic DNA. DNA from unaffected relatives gave the expected band pattern. Two obligate and one probable carrier women were hemizygous for the PLP locus by dosage analysis. Although it is unlikely, the previously described point mutations in PLP could represent polymorphisms. The finding of complete deletion of the PLP gene in our family is a stronger argument that mutations in PLP are responsible for X-linked PMD.     

A point mutation at the X-chromosomal proteolipid protein locus in Pelizaeus-Merzbacher disease leads to disruption of myelinogenesis.

A group of inherited neurological disorders are the X-chromosome linked dysmyelinoses, in which myelin membranes of the CNS are missing or perturbed due to a strongly reduced number of differentiated oligodendrocytes. In animal dysmyelinoses (jimpy mouse, msd-mouse, md rat, shaking pup) mutations of the main integral myelin membrane protein, proteolipid protein, have been identified. Pelizaeus-Merzbacher disease (PMD) or sudanophilic leucodystrophy is an X-linked dysmyelinosis in humans. We report here on the molecular basis of the defect of affected males of a PMD kindred. Rearrangements of the PLP gene were excluded by Southern blot hybridisation analysis and PCR amplification of overlapping domains of the PLP gene. Sequence analysis revealed one single C----T transition in exon IV, which leads to a threonine----isoleucine substitution within a hydrophobic intramembrane domain. The impact of this amino-acid exchange on the structure of PLP in the affected cis membrane domain is discussed. A space filling model of this domain suggests a tight packing of the alpha-helices of the loop which is perturbed by the amino-acid substitution in this PMD exon IV mutant. The C----T transition in exon IV abolishes a Hph I restriction site. This mutation at the recognition site for Hph I (RFLP) and allele-specific primers have been used for mutation screening the PMD kindred.     

综述与专论: 少突胶质细胞病——佩梅病的临床特点及致病机制

佩梅病（Pelizaeus-Merzbacher disease,PMD）是髓鞘形成低下性脑白质营养不良疾病中最常见的一种,其临床特点主要表现为发育落后尤其是大运动落后、眼震、肌张力低下等。其致病机制主要为脑白质髓鞘形成细胞-少突胶质细胞发生病理性改变从而导致髓鞘形成不良,相应理论基础包括以往研究中PLP1点突变通过影响PLP1/DM20寡聚体的形成,进而影响少突胶质细胞的存活,髓鞘分子结构的形成等;而PLP1重复突变则使少突胶质细胞及髓鞘脂的发育停止。近年来对细胞器互作网络（organelle interaction network,OIN）的研究进一步揭示了PLP1突变的致病机制：PLP1点突变通过影响PLP1蛋白上膜进而影响少突胶质细胞髓鞘化。PLP1重复突变则改变内质网线粒体间的连接,继而影响线粒体的形态功能等产生致病作用。目前已有相关研究表明,一些小分子化合物或药物例如胆固醇、吡拉西坦等以及基因疗法在动物体内对PMD临床症状有改善作用,其在PMD 患者体内的疗效有待进一步证实。     

Therapy of Pelizaeus-Merzbacher disease in mice by feeding a cholesterol-enriched diet

Duplication of PLP1 (proteolipid protein gene 1) and the subsequent overexpression of the myelin protein PLP (also known as DM20) in oligodendrocytes is the most frequent cause of Pelizaeus-Merzbacher disease (PMD), a fatal leukodystrophy without therapeutic options. PLP binds cholesterol and is contained within membrane lipid raft microdomains. Cholesterol availability is the rate-limiting factor of central nervous system myelin synthesis. Transgenic mice with extra copies of the Plp1 gene are accurate models of PMD. Dysmyelination followed by demyelination, secondary inflammation and axon damage contribute to the severe motor impairment in these mice. The finding that in Plp1-transgenic oligodendrocytes, PLP and cholesterol accumulate in late endosomes and lysosomes (endo/lysosomes), prompted us to further investigate the role of cholesterol in PMD. Here we show that cholesterol itself promotes normal PLP trafficking and that dietary cholesterol influences PMD pathology. In a preclinical trial, PMD mice were fed a cholesterol-enriched diet. This restored oligodendrocyte numbers and ameliorated intracellular PLP accumulation. Moreover, myelin content increased, inflammation and gliosis were reduced and motor defects improved. Even after onset of clinical symptoms, cholesterol treatment prevented disease progression. Dietary cholesterol did not reduce Plp1 overexpression but facilitated incorporation of PLP into myelin membranes. These findings may have implications for therapeutic interventions in patients with PMD.     

Additional copies of the proteolipid protein gene causing Pelizaeus-Merzbacher disease arise by separate integration into the X chromosome

The proteolipid protein gene (PLP) is normally present at chromosome Xq22. Mutations and duplications of this gene are associated with Pelizaeus-Merzbacher disease (PMD). Here we describe two new families in which males affected with PMD were found to have a copy of PLP on the short arm of the X chromosome, in addition to a normal copy on Xq22. In the first family, the extra copy was first detected by the presence of heterozygosity of the AhaII dimorphism within the PLP gene. The results of FISH analysis showed an additional copy of PLP in Xp22.1, although no chromosomal rearrangements could be detected by standard karyotype analysis. Another three affected males from the family had similar findings. In a second unrelated family with signs of PMD, cytogenetic analysis showed a pericentric inversion of the X chromosome. In the inv(X) carried by several affected family members, FISH showed PLP signals at Xp11.4 and Xq22. A third family has previously been reported, in which affected members had an extra copy of the PLP gene detected at Xq26 in a chromosome with an otherwise normal banding pattern. The identification of three separate families in which PLP is duplicated at a noncontiguous site suggests that such duplications could be a relatively common but previously undetected cause of genetic disorders.     

Increased Plp1 gene expression leads to massive microglial cell activation and inflammation throughout the brain

PMD (Pelizaeus–Merzbacher disease) is a rare neurodegenerative disorder that impairs motor and cognitive functions and is associated with a shortened lifespan. The cause of PMD is mutations of the PLP1 [proteolipid protein 1 gene (human)] gene. Transgenic mice with increased Plp1 [proteolipid protein 1 gene (non-human)] copy number model most aspects of PMD patients with duplications. Hypomyelination and demyelination are believed to cause the neurological abnormalities in mammals with PLP1 duplications. We show, for the first time, intense microglial reactivity throughout the grey and white matter of a transgenic mouse line with increased copy number of the native Plp1 gene. Activated microglia in the white and grey matter of transgenic mice are found as early as postnatal day 7, before myelin commences in normal cerebra. This finding indicates that degeneration of myelin does not cause the microglial response. Microglial numbers are doubled due to in situ proliferation. Compared with the jp (jimpy) mouse, which has much more oligodendrocyte death and hardly any myelin, microglia in the overexpressors show a more dramatic microglial reactivity than jp, especially in the grey matter. Predictably, many classical markers of an inflammatory response, including TNF-α (tumour necrosis factor-α) and IL-6, are significantly up-regulated manyfold. Because inflammation is believed to contribute to axonal degeneration in multiple sclerosis and other neurodegenerative diseases, inflammation in mammals with increased Plp1 gene dosage may also contribute to axonal degeneration described in patients and rodents with PLP1 increased gene dosage.     

A (G-to-A) mutation in the initiation codon of the proteolipid protein gene causing a relatively mild form of Pelizaeus-Merzbacher disease in a Dutch family

Pelizaeus-Merzbacher disease (PMD) is an X-linked recessive disorder that is characterized by dysmyelination of the central nervous system resulting from mutations in the proteolipid protein (PLP) gene. Mutations causing either overexpression or expression of a truncated form of PLP result in oligodendrocyte cell death because of accumulation of PLP in the endoplasmic reticulum. It has therefore been hypothesized that absence of the protein should result in a less severe phenotype. However, until now, only one patient has been described with a complete deletion of the PLP gene. We report a Dutch family with a relatively mild form of PMD, in which the disease cosegregates with a (G-to-A) mutation in the initiation codon of the PLP gene. This mutation should cause the total absence of PLP and is therefore in agreement with the hypothesis that absence of PLP leads to a mild form of PMD.     

Mitochondrial hsp60 chaperonopathy causes an autosomal-recessive neurodegenerative disorder linked to brain hypomyelination and leukodystrophy

Hypomyelinating leukodystrophies (HMLs) are disorders involving aberrant myelin formation. The prototype of primary HMLs is the X-linked Pelizaeus-Merzbacher disease (PMD) caused by mutations in PLP1. Recently, homozygous mutations in GJA12 encoding connexin 47 were found in patients with autosomal-recessive Pelizaeus-Merzbacher-like disease (PMLD). However, many patients of both genders with PMLD carry neither PLP1 nor GJA12 mutations. We report a consanguineous Israeli Bedouin kindred with clinical and radiological findings compatible with PMLD, in which linkage to PLP1 and GJA12 was excluded. Using homozygosity mapping and mutation analysis, we have identified a homozygous missense mutation (D29G) not previously described in HSPD1, encoding the mitochondrial heat-shock protein 60 (Hsp60) in all affected individuals. The D29G mutation completely segregates with the disease-associated phenotype. The pathogenic effect of D29G on Hsp60-chaperonin activity was verified by an in vivo E. coli complementation assay, which demonstrated compromised ability of the D29G-Hsp60 mutant protein to support E. coli survival, especially at high temperatures. The disorder, which we have termed MitCHAP-60 disease, can be distinguished from spastic paraplegia 13 (SPG13), another Hsp60-associated autosomal-dominant neurodegenerative disorder, by its autosomal-recessive inheritance pattern, as well as by its early-onset, profound cerebral involvement and lethality. Our findings suggest that Hsp60 defects can cause neurodegenerative pathologies of varying severity, not previously suspected on the basis of the SPG13 phenotype. These findings should help to clarify the important role of Hsp60 in myelinogenesis and neurodegeneration.     

Combined genetic and imaging diagnosis for two large Chinese families affected with Pelizaeus-Merzbacher disease

Pelizaeus-Merzbacher disease (PMD) is a rare X-linked recessive disorder characterized by nystagmus, impaired motor development, ataxia, and progressive spasticity. Genetically defective or altered levels of proteolipid protein (PLP1) or gap-junction alpha protein 12 gene have been found to be a common cause. Here we report on two large Han Chinese families affected with this disease. The probands of both families had produced sons featuring cerebral palsy that had never been correctly diagnosed. PMD was suspected after careful analysis of family history and clinical features. Three rounds of molecular testing, including RT-PCR, genetics linkage and SRY sequence analyses, in combination with fetal ultrasound and magnetic resonance imaging, confirmed the diagnosis. In Family 1, in addition to two patients, three carriers were identified, including one who was not yet married. Genetic testing indicated that a fetus did not have the disease. A healthy girl was born later. In Family 2, two patients and two carriers were identified, while a fetus was genetically normal. A healthy girl was born later. We concluded that by combining genetic testing and imaging, awareness of the symptoms of PMD and understanding of its molecular biology, there is great benefit for families that are at risk for producing offspring affected with this severe disease.     

Quantitative multiplex real-time PCR for detection of PLP1 gene duplications in Pelizaeus-Merzbacher patients

Pelizaeus-Merzbacher disease (PMD) is an X-linked recessive disorder of central nervous system (CNS) myelination typically affecting males. A genomic duplication of variable size at Xq22.2, containing the entire proteolipid protein 1 gene (PLP1), is responsible for approximately 60-70% of PMD cases. The aim of this study was to develop a rapid and robust method for determination of PLP1 gene dosage. We optimized two multiplex real-time quantitative PCR (Q-PCR) assays targeting exons 3 and 6 of the PLP1 gene, and then validated these assays by retrospective analysis of a set of genomic DNAs from 67 previously tested patients and 43 normal controls. Samples were analyzed in multiplex PCR reactions using TaqMan chemistry and the ABI Prism 7000 Sequence Detection System. PLP1 dosage was determined by the relative quantitative comparative threshold cycle method (DeltaDeltaCt) using the human serum albumin gene as the endogenous reference gene. Three clearly non-overlapping ranges of results, corresponding to the presence of one, two, or three PLP1 copies, were detected in both assays. The results were completely concordant with gender and previous PLP1 gene dosage testing based on quantitative fluorescent multiplex PCR and analysis of a dinucleotide polymorphism in the first intron of the PLP1 gene. We conclude that multiplex real-time Q-PCR represents a fast and reliable tool for PLP1 duplication testing in PMD families.     

Pelizaeus-Merzbacher disease: identification of Xq22 proteolipid-protein duplications and characterization of breakpoints by interphase FISH.

Pelizaeus-Merzbacher disease (PMD) is an X-linked, dysmyelinating disorder of the CNS. Duplications of the proteolipid protein (PLP) gene have been found in a proportion of patients, suggesting that, in addition to coding-region or splice-site mutations, overdosage of the gene can cause PMD. We show that the duplication can be detected by interphase FISH, using a PLP probe in five patients and their four asymptomatic carrier mothers. The extent of the duplication was analyzed in each family by interphase FISH, with probes from a 1. 7-Mb region surrounding the PLP gene between markers DXS83 and DXS94. A large duplication >=500 kb was detected, with breakpoints that differed, between families, at the proximal end. Distinct separation of the duplicated PLP signals could be seen only on metaphase chromosomes in one family, providing further evidence that different duplication events are involved. Quantitative fluorescent multiplex PCR was used to confirm the duplication in patients, by the detection of increased copy number of the PLP gene. Multiallelic markers from the duplicated region were analyzed, since the identification of two alleles in an affected boy would indicate a duplication. The majority of boys were homozygous for all four markers, compared with their mothers, who were heterozygous for one to three of the markers. These results suggest that intrachromosomal rearrangements may be a common mechanism by which duplications arise in PMD. One boy was heterozygous for the PLP marker, indicating a duplication and suggesting that interchromosomal rearrangements of maternal origin also can be involved. Since duplications are a major cause of PMD, we propose that interphase FISH is a reliable method for diagnosis and identification of female carriers.     

DMD Mutations in 576 Dystrophinopathy Families: A Step Forward in Genotype-Phenotype Correlations

Recent advances in molecular therapies for Duchenne muscular dystrophy (DMD) require precise genetic diagnosis because most therapeutic strategies are mutation-specific. To understand more about the genotype-phenotype correlations of the DMD gene we performed a comprehensive analysis of the DMD mutational spectrum in a large series of families. Here we provide the clinical, pathological and genetic features of 576 dystrophinopathy patients. DMD gene analysis was performed using the MLPA technique and whole gene sequencing in blood DNA and muscle cDNA. The impact of the DNA variants on mRNA splicing and protein functionality was evaluated by in silico analysis using computational algorithms. DMD mutations were detected in 576 unrelated dystrophinopathy families by combining the analysis of exonic copies and the analysis of small mutations. We found that 471 of these mutations were large intragenic rearrangements. Of these, 406 (70.5%) were exonic deletions, 64 (11.1%) were exonic duplications, and one was a deletion/duplication complex rearrangement (0.2%). Small mutations were identified in 105 cases (18.2%), most being nonsense/frameshift types (75.2%). Mutations in splice sites, however, were relatively frequent (20%). In total, 276 mutations were identified, 85 of which have not been previously described. The diagnostic algorithm used proved to be accurate for the molecular diagnosis of dystrophinopathies. The reading frame rule was fulfilled in 90.4% of DMD patients and in 82.4% of Becker muscular dystrophy patients (BMD), with significant differences between the mutation types. We found that 58% of DMD patients would be included in single exon-exon skipping trials, 63% from strategies directed against multiexon-skipping exons 45 to 55, and 14% from PTC therapy. A detailed analysis of missense mutations provided valuable information about their impact on the protein structure.     

A DNA replication mechanism for generating nonrecurrent rearrangements associated with genomic disorders

The prevailing mechanism for recurrent and some nonrecurrent rearrangements causing genomic disorders is nonallelic homologous recombination (NAHR) between region-specific low-copy repeats (LCRs). For other nonrecurrent rearrangements, nonhomologous end joining (NHEJ) is implicated. Pelizaeus-Merzbacher disease (PMD) is an X-linked dysmyelinating disorder caused most frequently (60%-70%) by nonrecurrent duplication of the dosage-sensitive proteolipid protein 1 (PLP1) gene but also by nonrecurrent deletion or point mutations. Many PLP1 duplication junctions are refractory to breakpoint sequence analysis, an observation inconsistent with a simple recombination mechanism. Our current analysis of junction sequences in PMD patients confirms the occurrence of simple tandem PLP1 duplications but also uncovers evidence for sequence complexity at some junctions. These data are consistent with a replication-based mechanism that we term FoSTeS, for replication Fork Stalling and Template Switching. We propose that complex duplication and deletion rearrangements associated with PMD, and potentially other nonrecurrent rearrangements, may be explained by this replication-based mechanism.     

Molecular confirmation of founder mutation c.-167A>G in Tunisian patients with PMLD disease

Pelizaeus Merzbacher disease and Pelizaeus Merzbacher like disease (PMLD) are hypomyelinating leucodystrophies of the central nervous system (CNS) with a very similar phenotype. PMD is an X-linked recessive condition caused by mutations, deletion duplication or triplication of the proteolipid protein 1 gene (PLP1). However, PMLD is a recessive autosomal hypomyelinating leukodystrophy caused by mutations of the GJC2 gene. In this study, we analyzed 5 patients belonging to 4 Tunisian families. Direct sequencing of GJC2 gene in all probands showed the same homozygous founder mutation c.-167A>G localized in the promoter region. We also generated two microsatellite markers GJC2 195GT and GJC2 76AC closed to the GJC2 gene to confirm the presence of a founder effect for this mutation. Haplotype study showed that the c.-167A>G promoter mutation occurred in a specific founder haplotype in Tunisian population. The identification of this founder mutation has important implications towards genetic counseling in relatives of these families and the antenatal diagnosis.     

Elevated CSF N-acetylaspartylglutamate suggests specific molecular diagnostic abnormalities in patients with white matter diseases

Background: In order to identify biomarkers useful for the diagnosis of genetic white matter disorders we compared the metabolic profile of patients with leukodystrophies with a hypomyelinating or a non-hypomyelinating MRI pattern. Methods: We used a non-a priori method of in vitro ¹H-NMR spectroscopy on CSF samples of 74 patients with leukodystrophies. Results: We found an elevation of CSF N-acetylaspartylglutamate (NAAG) in patients with Pelizaeus–Merzbacher disease (PMD)—PLP1 gene, Pelizaeus–Merzbacher-like disease—GJC2 gene and Canavan disease—ASPA gene. In the PMD group, NAAG was significantly elevated in the CSF of all patients with PLP1 duplication (19/19) but was strictly normal in 6 out of 7 patients with PLP1 point mutations. Additionally, we previously reported increased CSF NAAG in patients with SLC17A5 mutations. Conclusions: Elevated CSF NAAG is a biomarker that suggests specific molecular diagnostic abnormalities in patients with white matter diseases. Our findings also point to unique pathological functions of the overexpressed PLP in PMD patients with duplication of this gene.     

Pelizaeus-Merzbacher disease: an X-linked neurologic disorder of myelin metabolism with a novel mutation in the gene encoding proteolipid protein

The nosology of the inborn errors of myelin metabolism has been stymied by the lack of molecular genetic analysis. Historically, Pelizaeus-Merzbacher disease has encompassed a host of neurologic disorders that present with a deficit of myelin, the membrane elaborated by glial cells that encircles and successively enwraps axons. We describe here a Pelizaeus-Merzbacher pedigree of the classical type, with X-linked inheritance, a typical clinical progression, and a pathologic loss of myelinating cells and myelin in the central nervous system. To discriminate variants of Pelizaeus-Merzbacher disease, a set of oligonucleotide primers was constructed to polymerase-chain-reaction (PCR) amplify and sequence the gene encoding proteolipid protein (PLP), a structural protein that comprises half of the protein of the myelin sheath. The PLP gene in one of two affected males and the carrier mother of this family exhibited a single base difference in the more than 2 kb of the PLP gene sequenced, a C----T transition that would create a serine substitution for proline at the carboxy end of the protein. Our results delineate the clinical features of Pelizaeus-Merzbacher disease, define the possible molecular pathology of this dysmyelinating disorder, and address the molecular classification of inborn errors of myelin metabolism. Patients with the classical form (type I) and the more severely affected, connatal variant of Pelizaeus-Merzbacher disease (type II) would be predicted to display mutation at the PLP locus. The other variants (types III-VI), which have sometimes been categorized as Pelizaeus-Merzbacher disease, may represent mutations in genes encoding other structural myelin proteins or proteins critical to myelination.     

Genetic Background Influences UPR but not PLP Processing in the <Emphasis Type="Italic">rumpshaker</Emphasis> Model of PMD/SPG2

Mutations of the proteolipid protein gene (PLP1) cause Pelizaeus-Merzbacher disease (PMD) and Spastic paraplegia type 2 (SPG2). The rumpshaker mutation is associated with mild forms of PMD or SPG2 in man and the identical mutation occurs in mice, the phenotype depending on genetic background. The mild phenotype in C3H mice becomes a lethal disease when expressed on the C57BL/6 background. rumpshaker PLP is synthesised at a similar rate to wild type but is rapidly degraded by the proteasome. We show that the rates of synthesis, degradation and myelin incorporation of PLP/DM20 are similar in mutants on both backgrounds and therefore differences in PLP processing are unlikely to be the basis of the phenotypic variation. An unfolded protein response (UPR) is activated in rumpshaker. Whereas activation of CHOP correlates with phenotypic severity, we find no difference in the response of BiP and X-box protein1 (Xbp1) between the two strains. Electronic Supplementary Material Supplementary material is available to authorised users in the online version of this article at . Special issue dedicated to Anthony Campagnoni.