Paul G. FitzGerald

Cancer-Associated Retinopathy (CAR Syndrome) with Antibodies Reacting with Retinal, Optic-Nerve, and Cancer Cells

A VARIETY of neurologic disorders are associated with different forms of cancer.1 2 3 4 5 6 7 Secondary neurologic effects that become manifest in the absence of metastasis are collectively called ...

A Juvenile-Onset, Progressive Cataract Locus on Chromosome 3q21-q22 Is Associated with a Missense Mutation in the Beaded Filament Structural Protein–2

Juvenile-onset cataracts are distinguished from congenital cataracts by the initial clarity of the lens at birth and the gradual development of lens opacity in the second and third decades of life. Genomewide linkage analysis in a multigenerational pedigree, segregating for autosomal dominant juvenile-onset cataracts, identified a locus in chromosome region 3q21.2-q22.3. Because of the proximity of the gene coding for lens beaded filament structural protein-2 (BFSP2) to this locus, we screened for mutations in the coding sequence of BFSP2. We observed a unique C-->T transition, one that was not observed in 200 normal chromosomes. We predicted that this led to a nonconservative R287W substitution in exon 4 that cosegregated with cataracts. This mutation alters an evolutionarily conserved arginine residue in the central rod domain of the intermediate filament. On consideration of the proposed function of BFSP2 in the lens cytoskeleton, it is likely that this alteration is the cause of cataracts in the members of the family we studied. This is the first example of a mutation in a noncrystallin structural gene that leads to a juvenile-onset, progressive cataract.

Autosomal-dominant congenital cataract associated with a deletion mutation in the human beaded filament protein gene BFSP2

Congenital cataracts are a common major abnormality of the eye that frequently cause blindness in infants. At least one-third of all cases are familial; autosomal-dominant congenital cataract appears to be the most-common familial form in the Western world. Elsewhere, in family ADCC-3, we mapped an autosomal-dominant cataract gene to chromosome 3q21-q22, near the gene that encodes a lens-specific beaded filament protein gene, BFSP2. By sequencing the coding regions of BFSP2, we found that a deletion mutation, DeltaE233, is associated with cataracts in this family. This is the first report of an inherited cataract that is caused by a mutation in a cytoskeletal protein.

The Mr 115 kd fiber cell-specific protein is a component of the lens cytoskeleton

Electron microscope level immunocytochemistry was used to localize a lens fiber cell-specific protein with an Mr of 115 kd. Affinity-purified polyclonal antibodies were utilized on sections of detergent-extracted, acrylic-embedded lens cortical fiber cells. Monoclonal antibodies were utilized for pre-embeddment labelling of a subcellular fraction of lens fiber cells generated by homogenization, and high-speed centrifugation. The results indicate that the Mr 115 kd antigen is a component of the lens fiber cell cytoskeleton, specifically the beaded filament (BF), a cytoskeletal element thought to be unique to the differentiated lens fiber cell.

cDNA analysis of the 49 kDa lens fiber cell cytoskeletal protein: a new, lens-specific member of the intermediate filament family?

Two proteins, with molecular weights of 49 (CP49) and 115 kDa (CP115) as judged by SDS PAGE, have been shown by immunocytochemistry to be components of the beaded filament, a cytoskeletal structure thus far demonstrated only in the lens fiber cell. We have used antibodies reactive with CP49 to screen a mouse lens cDNA expression library. An immunoreactive clone with an approximately 1.0 kb insert was identified and purified. DNA sequence analysis shows the presence of an open reading frame that extends from the upstream cloning site for 660 bases. Contained within this reading frame are 2 peptide sequences nearly identical to 2 peptide sequences obtained from purified bovine CP49. Northern analysis revealed that the mRNA for the CP49 is not detectable in mouse brain, muscle, lung, liver, or heart. A search of the Genbank database showed that the partial cDNA sequence for the murine CP49 is unique, but that this partial sequence shows a strong similarity to multiple members of the intermediate filament family, with greatest similarity to type I acidic cytokeratins. The data presented here suggests that the CP49 is related to, and possibly represents a new member of the intermediate filament family. These data, in concert with previously published work, suggests 1) the CP49 and CP115, which have been localized to the beaded filament, are related to the family of IF proteins, and 2) these two proteins comprise a cytoskeletal structure which is structurally distinct from classical 8-11 nm intermediate filaments, thus possibly comprising a structurally novel form of intermediate filament.

Real-time Observation of Coiled-coil Domains and Subunit Assembly in Intermediate Filaments

We have utilized electron paramagnetic resonance spectroscopy to study secondary structure, subunit interaction, and molecular orientation of vimentin molecules within intact intermediate filaments and assembly intermediates. Spectroscopy data prove α-helical coiled-coil structures at individual amino acids 316–336 located in rod 2B. Analysis of positions 305, 309, and 312 identify this region as conforming to the helical pattern identified within 316–336 and thus demonstrates that, contrary to some previous predictions, this region is in an α-helical conformation. We show that by varying the position of the spin label, we can identify both intra- and inter-dimer interactions. With a label attached to the outside of the α-helix, we have been able to measure interactions between positions 348 of separate dimers as they align together in intact filaments, identifying the exact point of overlap. By mixing different spin-labeled proteins, we demonstrate that the interaction at position 348 is the result of an anti-parallel arrangement of dimers. This approach provides high resolution structural information (<2 nm resolution), can be used to identify molecular arrangements between subunits in an intact intermediate filament, and should be applicable to other noncrystallizable filamentous systems as well as to the study of protein fibrils.

The structure of vimentin linker 1 and rod 1B domains characterized by site-directed spin-labeling electron paramagnetic resonance (SDSL-EPR) and X-ray crystallography.

Background: The complete structure is not known for any intermediate filament (IF) protein. Results: Linker 1 and rod 1B in human vimentin were characterized using electron paramagnetic resonance spectroscopy and x-ray crystallography. Conclusion: The rod 1B adopts two functional conformations that mediate formation of an anti-parallel “A11” tetramer. Significance: Understanding vimentin structure provides insight into all IFs and the related human pathologies. Despite the passage of ∼30 years since the complete primary sequence of the intermediate filament (IF) protein vimentin was reported, the structure remains unknown for both an individual protomer and the assembled filament. In this report, we present data describing the structure of vimentin linker 1 (L1) and rod 1B. Electron paramagnetic resonance spectra collected from samples bearing site-directed spin labels demonstrate that L1 is not a flexible segment between coiled-coils (CCs) but instead forms a rigid, tightly packed structure. An x-ray crystal structure of a construct containing L1 and rod 1B shows that it forms a tetramer comprising two equivalent parallel CC dimers that interact with one another in the form of a symmetrical anti-parallel dimer. Remarkably, the parallel CC dimers are themselves asymmetrical, which enables them to tetramerize rather than undergoing higher order oligomerization. This functionally vital asymmetry in the CC structure, encoded in the primary sequence of rod 1B, provides a striking example of evolutionary exploitation of the structural plasticity of proteins. EPR and crystallographic data consistently suggest that a very short region within L1 represents a minor local distortion in what is likely to be a continuous CC from the end of rod 1A through the entirety of rod 1B. The concordance of this structural model with previously published cross-linking and spectral data supports the conclusion that the crystallographic oligomer represents a native biological structure.

Long-Term Effects of Intravitreal Injection of GMP-Grade Bone-Marrow–Derived CD34+ Cells in NOD-SCID Mice with Acute Ischemia-Reperfusion Injury

PURPOSE To determine long-term safety of intravitreal administration of good manufacturing practice (GMP)-grade human bone-marrow-derived CD34(+) cells in NOD-SCID (nonobese diabetic-severe combined immunodeficiency) mice with acute retinal ischemia-reperfusion injury, a model for retinal vasculopathy. METHOD Acute ischemia-reperfusion injury was induced in the right eye of adult NOD-SCID mice (n = 23) by transient elevation of intraocular pressure. Seven days later, 12 injured eyes and 5 normal contralateral eyes were injected each intravitreally with 5 × 10(4) CD34(+) cells isolated under GMP conditions from a healthy human donor bone marrow using an immunomagnetic cell isolation system. The remaining 11 injured eyes were not treated and served as controls. Mice were euthanized 1 day, 4 months, and 8 months later. Both eyes were enucleated and examined by immunohistochemical analysis and hematoxylin and eosin staining. Among mice followed for 8 months, electroretinography (ERG) was performed on both eyes before euthanization. All major organs were examined grossly and histologically after serial sectioning. RESULTS Immunohistochemical staining 4 months after injection showed detectable CD34(+) cells in the retinal vasculature. ERG at 8 months after CD34(+) cell injection showed signals that were similar in untreated eyes. Histology of the enucleated eyes injected with CD34(+) cells showed no intraocular tumor or abnormal tissue growth after 8 months. Histologic analysis of all major organs showed no abnormal proliferation of human cells. CONCLUSIONS Intravitreal administration of GMP-grade human bone-marrow-derived CD34(+) cells appears to be well tolerated long-term in eyes with acute retinal ischemic injury. A clinical trial will start to further explore this therapy.

Age-related changes in a fiber cell-specific extrinsic membrane protein

Western blot analysis using a monoclonal antibody raised against a lens fiber cell-specific, extrinsic membrane protein reveals several immunologically related bands in fractions derived from bovine lens. Previous work suggests that the parent molecule is the Mr 115 species, and that lower molecular weight bands represent the products of a progressive, step-wise, post-translational degradation. In this report we compare the extent of proteolytic degradation in extracts prepared from the lens cortex and lens nucleus, using both protease-suppressive and protease-permissive isolation protocols. The results suggest that the observed degradation is a result of in vivo post-translational modification of the Mr 115 antigen, and thus represents physiologic aging of this protein. This analysis also suggests that degradation alters the solubility and/or membrane affinity of this antigen, resulting in a progressive shift to the insoluble phase.

Immunologic conservation of the fiber cell beaded filament

Lenses were obtained from the eyes of four different classes of Chordates, including Mammalia (rat, mouse, cow, human), Aves (chicken), Amphibia (tiger salamander), and Osteichthyes (steelhead), as well as from one Mollusca (squid). Buffer soluble, urea soluble and urea insoluble fractions were prepared from each, and probed by western blot analysis for the presence of the lens fiber cell 115 and 49 kD beaded filament proteins. Application of both polyclonal and monoclonal antibodies revealed that an immunologic homologue to the bovine fiber cell 115 kD protein is present in all examples of Chordates tested, and that this homologue possessed properties very similar to those of its bovine counterpart. Both monoclonal and polyclonal antibodies revealed an immunologically cross-reactive homologue in squid as well, but suggested that the squid protein had a native molecular weight of closer to 70-80 kD. A monoclonal antibody to the bovine 49 kD beaded filament protein was successful at identifying an immunologic homologue to this protein in mouse, chicken, and tiger salamander. Ultrastructural analysis of rat, human, and fish lenses showed that a beaded filament was present in these lenses, which was indistinguishable from that seen in the bovine lens. In the squid a filamentous, beaded structure was observed, but it differed from that seen in the bovine lens. We conclude from the data presented that the beaded filament, and its constituent proteins, are well-conserved. This data should facilitate the identification of lens cytoskeletal proteins and structure in a wide range of animal models, and establish that probes for these proteins may be of broad applicability.