Lens Biology is a Dimension of Neurobiology.

There is a second cell type in your body that expresses scores of the most intensively studied genes in neuroscience and exclusively shares critical interdependent modes of molecular regulation that include a network first described as responsible for the basic bifurcation of neuronal from non-neuronal gene expression in vertebrates. Neurons and lens cells are among the most ancient animal cell types, yet neurons have an exclusive status also attributed to roles underlying sensation, movement, and cognition. However, this status is challenged by cells in the lens of the eye. The extent and detail of internally consistent parallels with neuron biology now catalogued in their second native cell type in the lens provide a detailed model of interdependent neuron gene expression in lens development and non-neuronal role in vision. These comprehensive parallels identify the lens as a dimension of neurobiology and a fundamental new perspective on neurodevelopment and its disorders. Finally, this understanding identifies that hallmark neuronal gene expression and key modes of associated molecular regulation evolved in tandem in the lens.

"Moonlighting" GAPDH Protein Localizes with AMPA Receptor GluA2 and L1 Axonal Cell Adhesion Molecule at Fiber Cell Borders in the Lens.

PURPOSE: The canonical role of glyceraldehyde phosphate dehydrogenase (GAPDH) is as an enzyme in glycolysis. GAPDH is also a principal "moonlighting" protein with additional roles at diverse sites in a variety of cells. Surface GAPDH on mammalian, yeast, and bacterial cells acts as a receptor and also mediates cell contacts. In neurons, extracellular GAPDH localizes at synapses. Two GAPDH binding partners at synapses are α-Amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid glutamate receptor (AMPA) GluA2 subunit at dendritic spines and L1 cell adhesion molecule at pre-synaptic membranes, and both proteins are also expressed in lenses. Fiber cell membrane protrusions and dendritic spines have similar size, shape, and spacing, contain F-actin, and express clathrin/AP-2 Adaptor at their surfaces linked with Tyr-phosphatase STEP-regulated endocytosis of AMPA/GluA2 receptors. AMPA receptors work with NMDA (N-methyl-d-aspartate) and GABA (γ-aminobutyric acid) receptors, calcium calmodulin kinase II (CaMKIIα), channel proteins, STEP, and ephrin receptors, which are also expressed in lenses. In neurons, coordinate AMPA/GluA2 receptor endocytosis with GAPDH is linked with disease. GAPDH was previously characterized as a fiber cell membrane protein and shown to decrease substantially in interior fiber cells in human age-related cataract. Here, we examined GAPDH spatial expression in healthy lenses in two vertebrate species. METHODS: In situ methods were used to examine GAPDH expression in lenses of healthy young adult rabbits and chickens. Immunoblots were used to detect L1 in lenses. RESULTS: The present study demonstrated that GAPDH is present at fiber cell borders in adult rabbit and chicken lenses with evidence of focal concentrations along the fiber cell perimeter, and overlapped with detection of p-Tyr-GluA2, L1, STEP, actin and clathrin. We observed that L1-140 kDa was the prominent form in lens. CONCLUSIONS: Our findings indicate investigations into GAPDH "moonlighting" activities similar to its role in cell-cell interactions at neuron surfaces are warranted in the lens.

KCC2 expression supersedes NKCC1 in mature fiber cells in mouse and rabbit lenses.

PURPOSE: Na-K-Cl cotransporter 1 (NKCC1) and K-Cl cotransporter 2 (KCC2) have fundamental roles in neuron differentiation that are integrated with gamma-aminobutyric acid (GABA) and glutamate receptors, GABA synthesized by GAD25/65/67 encoded by GAD1/GAD2 genes, and GABA transporters (GATs). Cells in the eye lens express at least 13 GABA receptor subunits, α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) and N-methyl D-aspartate (NMDA) glutamate receptors, GAD1/GAD2, GAT1-4 and vGAT, and NKCC1. NKCC1:KCC2 ratios determine the switch in GABA actions from trophic/growth promoting early in development to their classic inhibitory roles in adult neurons. Lens epithelial cells cover the anterior surface and differentiate to elongated fiber cells in the lens interior with comparable morphology and sub-cellular structures as neurons. NKCC1 is expressed before KCC2 in neuron development and increases cell chloride, which stimulates differentiation and process formation. Subsequently, KCC2 increases and extrudes cell chloride linked with maturation. KCC2 has an additional structural moonlighting role interacting with F-actin scaffolding in dendritic spine morphogenesis. We examined KCC2 versus NKCC1 spatial expression in relation to fiber cell developmental status within the lens. METHODS: Immunofluorescence and immunoblots were used to detect expression in mouse and rabbit lenses. RESULTS: NKCC1 was restricted to peripheral elongating lens fiber cells in young adult mouse and rabbit lenses. Lens KCC2 expression included the major KCC2b neuronal isoform and was detected in interior fiber cells with decreased NKCC1 expression and localized at the membranes. Lens expression of RE-1 silencing transcription factor (REST) regulated KCC2 is consistent with GAD1 and GAD2, several GABA and glutamate receptor subunits, miR-124, and other REST-regulated genes expressed in lenses. CONCLUSIONS: NKCC1 in peripheral elongating fiber cells is superseded by KCC2 expression in interior mature fiber cells that also express >20 additional integral GABA biology genes, AMPA/NMDA glutamate receptors, and an array of accessory proteins that together underlie morphogenesis in neurons. The present findings provide further evidence that this fundamental neuronal regulation is extensively conserved in lens and identify additional parallels in the morphogenetic programs that underlie lens fiber cell and neuronal differentiation and contribute to the development of visual acuity.

Fragile X Syndrome FMRP Co-localizes with Regulatory Targets PSD-95, GABA Receptors, CaMKIIα, and mGluR5 at Fiber Cell Membranes in the Eye Lens.

Fmr1 and FMRP underlie Fragile X Syndrome (FXS) and are linked with related autism spectrum disorders (ASD). Fmr1 also has an essential role in eye and lens development. Lenses express FMRP along with γ-aminobutyric acid (GABA) receptors (GABARs), post-synaptic density protein 95 (PSD-95), Tyr-phosphatase STEP, CaMKIIα and Alzheimer's disease Aß precursor protein, which are verified targets of FMRP regulation in neurons and outline major topics in FXS/ASD research. PSD-95 as well as CaMKIIα transcripts undergo polypryimidine tract binding protein dependent alternative splicing in lens, consistent with PSD-95 translation in lens. At least 13 GABAR subunits and GAD25/65/67 GABA metabolism enzymes are expressed in lenses beginning in embryonic development, matching neural development. Interestingly, GABAergic drugs (e.g. baclofen) studied as FXS/ASD therapeutics are shown to resolve developmental vision defects in experimental myopia. Here, we demonstrated that FMRP co-localizes at fiber cell membranes with PSD-95, GABAAδ, GABAAß3, GABBR1, STEP, CaMKIIα, and mGluR5 in young adult lenses. GAD65 and GABA detection was greatest at the peri-nuclear lens region where fiber cell terminal differentiation occurs. These findings add to an extensive list of detailed parallels between fiber cell and neuron morphology and their lateral membrane spine/protrusions, also reflected in the shared expression of genes involved in the morphogenesis and function of these membrane structures, and shared use of associated regulatory mechanisms first described as distinguishing the neuronal phenotype. Future studies can determine if GABA levels currently studied as a FXS/ASD biomarker in the brain, and generated by GAD25/65/67 in a comparable cell environment in the lens, may be similarly responsive to Fmr1 mutation in lens. The present demonstration of FMRP and key regulatory targets in the lens identifies a potential for the lens to provide a new research venue, in the same individual, to inform about Fmr1/FMRP pathobiology in brain as well as lens.

Lens GABA receptors are a target of GABA-related agonists that mitigate experimental myopia.

Coordinated growth of eye tissues is required to achieve visual acuity. However, visual experience also guides this process. Experimental myopia can be produced by altering light entering the eye, but also by changing light/dark regimens. Drug discovery studies demonstrated that γ-aminobutyric acid (GABA)-related agonists (e.g., baclofen) will mitigate experimental myopia, and are also drugs studied for their capacity to affect neurodevelopmental disorders that include Fragile X Syndrome and related autism spectrum disorders. GABA receptors thought to mediate these responses in the eye have been studied in the neural retina as well as the cornea and sclera which are both innervated tissues. In addition to neurons, lenses express GAD25/65/67 GABA metabolic enzymes and at least 13 GABA receptor subunits with developmental expression profiles that match neural development. Evidence that lens GABA receptors are expressed in a cell environment comparable to neurons is seen in the lens expression of AMPA and NMDA glutamate receptors together with an unexpectedly comprehensive array of associated signaling proteins that include post-synaptic-density 95 (PSD95), calcium calmodulin kinase IIα (CaMKIIα), Fragile X Syndrome mental retardation protein (FMRP), ephrin receptors, Ca(V)1.2, 1.3 channels, cyclin-dependent kinase 5 (Cdk5), and neuronal C-src among others. Moreover, lens cells share fundamental molecular regulatory mechanisms that integrate the regulation and function of these genes at the DNA, RNA, and protein levels in neurons. GABA has trophic, growth promoting effects early in neuron development and later assumes its classic inhibitory role in the adult neural system. We hypothesize that the extensive parallels between GABA and glutamate receptor biology in lens and brain identifies the lens as a site of GABA agonist drug action affecting experimental myopia, acting through lens GABA receptors to similarly affect growth in both elongated cell types.

PTBP-dependent PSD-95 and CamKIIα alternative splicing in the lens.

PURPOSE: Parallels described between neurons and lens fiber cells include detailed similarities in sub-cellular structures that increasingly show shared expression of genes involved in the construction and function of these structures in neurons. Intriguingly, associated modes of molecular regulation of these genes that had been thought to distinguish neurons have been identified in the lens as well. Both elongated cell types form membrane protrusions with similar size, shape, and spacing that exclude microtubules, contain F-actin, and are coated with the clathrin/AP-2 adaptor. Lenses express glutamate and gamma-aminobutyric acid (GABA) receptors with signaling and channel proteins shown to act together at neuronal membranes. Postsynaptic density protein 95 (PSD-95) and Ca(2+)/calmodulin-dependent protein kinase (CaMKIIα) expression and functions illustrate the integration of aspects of neuronal molecular and cell biology and were investigated here in the lens. METHODS: Immunofluorescence, immunoblot, and RT-PCR methods were used to assess protein expression and alternative transcript splicing. RESULTS: We showed the essential dendritic spine scaffold protein PSD-95 is expressed in lenses and demonstrated lens PSD-95 transcripts undergo polypyrimidine tract binding protein (PTBP)-dependent alternative splicing of its pivotal exon 18 required to avoid nonsense-mediated decay, and showed PTBP-dependent alternative splicing of CaMKIIα transcripts in the lens. The PSD-95 protein was observed at fiber cell membranes overlapping with N-methyl-D-aspartate (NMDA) and α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) glutamate and GABA receptor proteins, tyrosine phosphatase STEP, CaMKIIα, the Ca(V)1.3 calcium channel, and clathrin, which were previously identified at lens fiber cell membranes. During neurogenesis, miR-124 is expressed that suppresses PTBP1 and promotes these splicing events. miR-124 is also expressed in mammalian lenses and upregulated during lens regeneration in amphibians, consistent with previous demonstrations of PTBP1,2 and PTBP-dependent PTBP2 exon 10 splicing in rodent lenses. CONCLUSIONS: Findings of this dendritic spine scaffold protein and conservation of its key mode of molecular regulation in the lens provides further evidence that key aspects of the neuron morphogenetic program are shared with the lens.

NMDA glutamate receptor NR1, NR2A and NR2B expression and NR2B Tyr-1472 phosphorylation in the lens.

Detailed parallels described between lens fiber cell and neuron morphology, sub-cellular structure, and molecular biology include striking similarities in the ultrastructure of their vesicle transport machinery and the membrane protrusions that occur along the lateral surfaces of both cell types. α-Amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) and N-methyl-D-aspartate receptor (NMDA) glutamate receptors (AMPARs/NMDARs) are the predominant receptors in neurons. These receptors have fundamental roles in neuron morphogenesis as well as neuron physiology and dynamic cell signaling, and specifically at dendritic spines. As a result, AMPAR and NMDAR dysregulation underlies several primary neural disorders that have also shown epidemiological associations with cataract. Previously, we demonstrated AMPAR GluA1 and REST (RE-1 silencing transcription factor)-regulated GluA2 subunits are expressed in the lens, and showed C-terminal phospho-tyrosine-GluA2, and striatal-enriched tyrosine phosphatase (STEP), as well as GluA2 Q/R RNA editing in lenses similar to neurons. Here, we demonstrated that REST-regulated NMDAR NR1, NR2A, and NR2B are also expressed in lenses and localize predominantly in fiber cell membranes, consistent with REST transcription factors, as well as miR-124 and other REST gene targets identified in the lens. We also showed NR2B Tyr-1472 phosphorylation occurs in lens. These p-Tyr-GluA2 and p-Tyr-NR2B phosphorylation events are linked with membrane insertion regulated by STEP. We next determined that NR1 transcripts that include exon 5 are produced in lens consistent with Fox-1 RNA binding protein isoforms linked with this alternative splicing event, and shown to be expressed in lens as well as brain. These findings provide further evidence that fundamental neuronal morphogenetic programs, and hallmark neuronal gene expression and modes of regulation, are shared with elongated fiber cells of the lens.

Amyloid-ß and tau pathology of Alzheimer's disease induced by diabetes in a rabbit animal model.

Alzheimer's disease (AD) is the major age-dependent disease of the brain, but what instigates late-onset AD is not yet clear. Epidemiological, animal model, and cell biology findings suggest links between AD and diabetes. Although AD pathology is accelerated by diabetes in mice engineered to accumulate human-sequence amyloid-ß (Aß) peptides, they do not adequately model non-inherited AD. We investigated AD-type pathology induced solely by diabetes in genetically unmodified rabbits which generate human-sequence Aß peptides. After 15 weeks, alloxan-treated diabetic rabbits with expected high blood glucose showed ~5-fold increase in Aß40/Aß42 in cortex and hippocampus, and significantly, generated Aß-derived assemblies found in human AD. Deposits of these putative pathogenic toxins were detected by Aß/Aß oligomer antibodies in brain parenchyma and surrounding vasculature, also co-localizing with markedly elevated levels of RAGE. Soluble brain extracts showed diabetes-induced buildup of Aß oligomers on dot-blots. Phospho-tau also was clearly elevated, overlapping with ßIII-tubulin along neuronal tracts. Indications of retina involvement in AD led to examination of AD-type pathology in diabetic retinas and showed Aß accumulation in ganglion and inner nuclear cell layers using Aß/oligomer antibodies, and RAGE again was elevated. Our study identifies emergence of AD pathology in brain and retina as a major consequence of diabetes; implicating dysfunctional insulin signaling in late-onset AD, and a potential relationship between Aß-derived neurotoxins and retinal degeneration in aging and diabetes, as well as AD. AD-type pathology demonstrated in genetically unmodified rabbits calls attention to the considerable potential of the model for investigation of AD pathogenesis, diagnostics, and therapeutics.

Parallels between neuron and lens fiber cell structure and molecular regulatory networks.

Studies over the past fifty years have identified extensive similarities between neurons and elongated fiber cells that make up in the interior of the ocular lens. Electron micrographs showed parallels in the organization of their intracellular vesicle transport machinery and between lens fiber cell lateral protrusions and dendritic spines. Consistent with those observations, a number of gene products first characterized as highly neuron-preferred in their expression were also demonstrated in lens fiber cells. Going further, a fundamental network of regulatory factors with critical roles in determining the neuronal phenotype were also identified in lenses, and showed a corresponding mutually exclusive distribution of neural and non-neural factor isoforms in mitotic lens epithelial cells and post-mitotic fiber cells consistent with their interlocking functions in neural cells. These included REST/NRSF transcription factors, members of major RNA binding protein families, and "brain-specific" miRNAs that were each shown to have global roles in governing neural and non-neural gene expression and alternative transcript splicing in vertebrates. This review discusses these extensive parallels between neurons and fiber cells and implications regarding common themes in lens and neural cell physiology and disease, which may also suggest related evolutionary processes.

GluA2 AMPA glutamate receptor subunit exhibits codon 607 Q/R RNA editing in the lens.

Regulated GluA2 AMPA receptor subunit expression, RNA editing, and membrane localization are fundamental determinants of neuronal Ca(2+) influx, and underlie basic functions such as memory and the primary brain disorder epilepsy. Consistent with this, AMPARs, and specifically GluA2, are targets of common antiepileptic drugs (AEDs) and antidepressants. Recently, epidemiological associations between epilepsy and increased cataract prevalence were found comparable to cataract links with diabetes and smoking. Similarly, use of AEDs and several antidepressants also showed links with increased cataract. Here, we demonstrated GluA2 in lenses, consistent with REST/NRSF and REST4 we described previously in lenses, as well as GluA1 and ADAR2 in the lens. Surprisingly, we found predominant neuron-like Q/R editing of GluA2 RNAs also occurs in the lens and evidence of lens GluA2 phosphorylation and STEP phosphatases linked with GluA2 membrane localization in neurons. This study is among the first to show GluA2 expression and predominant Q/R RNA editing in a non-neural cell. Our results suggest GluA2 AMPARs have related roles in lens physiology and disease processes, and provide evidence these anticonvulsant and antidepressant drug targets also occur in the lens.

miR-124, miR-125b, let-7 and vesicle transport proteins in squid lenses in L. pealei.

PURPOSE: Studies over the past several decades identified parallels between neuron and lens fiber cell morphology, development, and physiology. Consistent with this, mammalian lens fiber cells were shown to express a substantial complement of genes that cluster with respect to synaptic vesicle transport and exocytosis. Expression of these genes in these two cell types also appears consistent with similarities described between lens fiber cell lateral protrusions and neuronal dendrites. Recently, we showed vertebrate neurons and lens fiber cells share expression of a core set of factors that form an interlocking regulatory network which has a fundamental role in determining neural cell identity. These included the REST/NRSF transcription factor, neural RNA binding proteins and miR-124. In addition, we identified miR-125 and let-7 in mammalian lenses that have been shown to regulate dendrite formation in neurons. The present study examined expression of miR-124, miR-125, and let-7 as well as genes involved in vesicle transport in lens in the squid Loligo (also referred to as Doryteuthis) pealei. METHODS: Northern blot, RT-PCR, immunoblots, and in situ detection were used to analyze expression in squid and vertebrate tissues. RESULTS: The present study provided evidence that miR-124, miR-125, let-7 and vesicle transport-related proteins are produced in squid lenses. Consistent with these mRNAs and miRNAs in squid lenses, and polyribosomes shown by others, we detected substantial levels of tRNA and rRNA in anuclear squid lenses which do not produce an epithelial cell layer that would be analogous to vertebrate lenses. CONCLUSIONS: Our study provided evidence that miR-124, miR-125, and let-7, as well as proteins involved in vesicle transport linked with synaptic and cargo vesicle transport in vertebrates are also expressed in squid lenses.

Evidence that "brain-specific" FOX-1, FOX-2, and nPTB alternatively spliced isoforms are produced in the lens.

PURPOSE: Alternative RNA splicing is essential in development and more rapid physiological processes that include disease mechanisms. Studies over the last 20 years demonstrated that RNA binding protein families, which mediate the alternative splicing of a large percentage of genes in mammals, contain isoforms with mutually exclusive expression in non-neural and neural progenitor cells vs. post-mitotic neurons, and regulate the comprehensive reprogramming of alternative splicing during neurogenesis. Polypyrimidine tract binding (PTB) proteins and Fox-1 proteins also undergo mutually exclusive alternative splicing in neural and non-neural cells that regulates their tissue-specific expression and splicing activities. Over the past 50 years, striking morphological similarities noted between lens fiber cells and neurons suggested that cell biology processes and gene expression profiles may be shared as well. Here, we examined mouse and rat lenses to determine if alternative splicing of neuronal nPTB and Fox-1/Fox-2 isoforms also occurs in lenses. METHODS: Immunoblot, immunofluorescence, and RT-PCR were used to examine expression and alternative splicing of transcripts in lens and brain. RESULTS: We demonstrated that exon 10 is predominantly included in nPTB transcripts consistent with nPTB protein in lenses, and that alternatively spliced Fox-1/-2 lens transcripts contain exons that have been considered neuron-specific. We identified a 3' alternative Fox-1 exon in lenses that encodes a nuclear localization signal consistent with its protein distribution detected in fiber cells. Neuronal alternative splicing of kinesin KIF1Bß2 has been associated with PTB/nPTB and Fox-2, and we found that two 'neuron-specific' exons are also included in lenses. CONCLUSIONS: The present study provides evidence that alternative neuronal nPTB and Fox-1/Fox-2 isoforms are also produced in lenses. These findings raise questions regarding the extent these factors contribute to a similar reprogramming of alternative splicing during lens differentiation, and the degree that alternative gene transcripts produced during neurogenesis are also expressed in the lens.

HuB/C/D, nPTB, REST4, and miR-124 regulators of neuronal cell identity are also utilized in the lens.

PURPOSE: An interlocking network of transcription factors, RNA binding proteins, and miRNAs globally regulates gene expression and alternative splicing throughout development, and ensures the coordinated mutually exclusive expression of non-neural and neuronal forms of these factors during neurogenesis. Striking similarities between lens fiber cell and neuron cell morphology led us to determine if these factors are also used in the lens. HuR and polypyrimidine tract binding protein (PTB) have been described as 'global regulators' of RNA alternative splicing, stability, and translation in non-neuronal (including ectodermal) tissues examined to date in diverse species, and REST/NRSF (RE-1 Silencing Transcription Factor/Neuron Restrictive Silencing Factor) represses>2,000 neuronal genes in all non-neuronal tissues examined to date, but has not included the lens. During neurogenesis these factors are replaced by what has been considered neuron-specific HuB/C/D, nPTB, and alternatively spliced REST (REST4), which work with miR-124 to activate this battery of genes, comprehensively reprogram neuronal alternative splicing, and maintain their exclusive expression in post-mitotic neurons. METHODS: Immunoprecipitation, western blot, immunofluorescence, and immunohistochemistry were used to determine the expression and distribution of proteins in mouse and rat lenses. Mobility shift assays were used to examine lenses for REST/NRSF DNA binding activity, and RT-PCR, DNA sequencing, and northern blots were used to identify RNA expression and alternative splicing events in lenses from mouse, rat, and goldfish (N. crassa). RESULTS: We demonstrated that REST, HuR, and PTB proteins are expressed predominantly in epithelial cells in mouse and rat lenses, and showed these factors are also replaced by the predominant expression of REST4, HuB/C/D and nPTB in post-mitotic fiber cells, together with miR-124 expression in vertebrate lenses. REST-regulated gene products were found to be restricted to fiber cells where REST is decreased. These findings predicted nPTB- and HuB/C/D-dependent splicing reactions can also occur in lenses, and we showed Neuronal C-src and Type 1 Neurofibromatosis 1 splicing as well as calcitonin gene related peptide (CGRP) and neural cell adhesion molecule (NCAM-180) alternative transcripts in lenses. Transgenic mice with increased HuD in lens also showed increased growth associated protein 43 (GAP43) and Ca++/Calmodulin dependent kinase IIα (CamKIIα) HuD target gene expression in the lens, similar to brain. CONCLUSIONS: The present study provides the first evidence this fundamental set of regulatory factors, previously considered to have a unique role in governing neurogenesis are also used in the lens, and raises questions about the origins of these developmental factors and mechanisms in lens and neuronal cells that also have a basic role in determining the neuronal phenotype.

Increased expression and local accumulation of the prion protein, Alzheimer Aß peptides, superoxide dismutase 1, and nitric oxide synthases 1 & 2 in muscle in a rabbit model of diabetes.

BACKGROUND: Muscle disease associated with different etiologies has been shown to produce localized accumulations of amyloid and oxidative stress-related proteins that are more commonly associated with neurodegeneration in the brain. In this study we examined changes in muscle tissue in a classic model of diabetes and hyperglycemia in rabbits to determine if similar dysregulation of Alzheimer Aß peptides, the prion protein (PrP), and superoxide dismutase 1 (SOD1), as well as nitric oxide synthases is produced in muscle in diabetic animals. This wild-type rabbit model includes systemic physiological expression of human-like Alzheimer precursor proteins and Aß peptides that are considered key in Alzheimer protein studies. RESULTS: Diabetes was produced in rabbits by injection of the toxic glucose analogue alloxan, which selectively enters pancreatic beta cells and irreversibly decreases insulin production, similar to streptozotocin. Quadriceps muscle from rabbits 16 wks after onset of diabetes and hyperglycemia were analyzed with biochemical and in situ methods. Immunoblots of whole muscle protein samples demonstrated increased PrP, SOD1, as well as neuronal and inducible Nitric oxide synthases (NOS1 and NOS2) in diabetic muscle. In contrast, we detected little change in Alzheimer Aß precursor protein expression, or BACE1 and Presenilin 1 levels. However, Aß peptides measured by ELISA increased several fold in diabetic muscle, suggesting a key role for Aß cleavage in muscle similar to Alzheimer neurodegeneration in this diabetes model. Histological changes in diabetic muscle included localized accumulations of PrP, Aß, NOS1 and 2, and SOD1, and evidence of increased central nuclei and cell infiltration. CONCLUSIONS: The present study provides evidence that several classic amyloid and oxidative stress-related disease proteins coordinately increase in overall expression and form localized accumulations in diabetic muscle. The present study highlights the capacity of this wild-type animal model to produce an array of hallmark pathological features that have also been described in other muscle diseases.

miRNA and Dicer in the mammalian lens: expression of brain-specific miRNAs in the lens.

Micro RNAs (miRNAs) are approximately 22 nucleotide molecules that regulate gene expression post-transcriptionally and govern a wide range of physiological and developmental processes. Evidence now indicates that miRNAs can also coordinately down-regulate transcript levels for very large groups of genes in a tissue-specific manner, in addition to their ability to suppress protein translation. Here, we examine expression of specific miRNAs and Dicer ribonuclease that is required for miRNA biogenesis in mouse and rat lenses. Northern blot analysis demonstrated lens expression of brain-specific miR-124 and miR-7 in lenses, as well as miR-125b and let-7a. In addition, we provide evidence that muscle specific miR-1 is not present in lens. We detected Dicer transcripts in 21 day, 6 week, and 1 year mouse lenses and 15 day rat lens, and detected Dicer protein in adult lens protein samples. Immunohistochemical examination of late embryonic, post-natal, and adult rat lens sections identified expression of Dicer in differentiating fiber cells that undergo pronounced cell elongation in the lens interior and anterior epithelial cells. The present study provides evidence that miRNAs, which include brain-specific forms, and Dicer are expressed in mammalian lenses, indicating that fundamental aspects of miRNA biology are utilized by the lens during late embryonic and post-natal development and in adult lenses.

Synapsin and synaptic vesicle protein expression during embryonic and post-natal lens fiber cell differentiation.

PURPOSE: Reorganization of cytoskeleton and membrane biogenesis are dynamically coordinated during lens fiber cell differentiation and development to produce an organ with precise dimensions and optical properties. Cargo vesicle trafficking is fundamental to cell elongation and has also been implicated in degenerative disease mechanisms. Alzheimer precursor protein (AbetaPP) acts with kinesin, synapsin, and synaptic vesicle proteins to mediate cargo vesicle transport and membrane fusion in neurons. In our previous studies we demonstrated that AbetaPP is also a key element in lens fiber cell formation, and in early-onset cataract that occurs along with early-onset Alzheimer disease in Down syndrome. In the present study we examine lens expression and regulation of a complement of genes associated with cargo and synaptic vesicle transport in neurons. METHODS: RT-PCR, immunoblot, and immunohistochemical methods were used to characterize expression of AbetaPP and kinesin associated motor proteins, synapsins, and synaptic vesicle proteins in mouse and rat embryonic, post-natal, and adult lenses. Phospho-specific anti-synapsin antibodies were used to determine the distributions of site-1 phosphorylated and dephosphorylated synapsin protein. RESULTS: We demonstrate that a substantial complement of cargo and synaptic vesicle proteins involved in AbetaPP mediated vesicle transport are expressed in lenses along the anterior-posterior axis of fiber cells in embryonic and adult lenses, consistent with vesicles, actin filaments, and neuron-like arrangement of microtubules in lenses shown by others. We identify temporal regulation of synapsins I, II, and III during embryonic and post-natal lens development consistent with their roles in neurons. Regulation of vesicle cytoskeleton attachment, actin polymerization, and the capacity to stimulate cell differentiation by synapsins are governed in large part by phosphorylation at a conserved Ser9 residue (site-1). We demonstrate discrete distributions of Ser9 phospho- and dephospho-synapsins along the axial length of rapidly elongating embryonic lens fiber cells, and decreased levels of site-1 phosphorylated synapsins in adult lenses. CONCLUSIONS: The present findings demonstrate several fundamental parallels between lens and neuron vesicle trafficking cell biology and development, and suggest that more extensive AbetaPP related vesicle trafficking disease mechanisms may be shared by lens and brain.

Beta-amyloid secretases and beta-amloid degrading enzyme expression in lens.

PURPOSE: Beta- and gamma-secretases are proteases involved in the processing of the Alzheimer precursor protein (AbetaPP) that releases the transmembrane beta-amyloid fragment (Abeta), associated with age-dependent disease in lens and brain. Gamma-secretase is a protein complex containing Presenilin and Nicastrin proteins, which also processes Notch and other receptors involved in the eye and lens development. Neprilysin (NEP), a major protease involved in degrading Abeta, acts with beta- and gamma-secretases to regulate steady-state levels of Abeta. Previously, we demonstrated AbetaPP and Presenilin expression and processing in the lens and demonstrated cell degeneration in classic Alzheimer disease (AD) transgenic and systemic oxidative stress animal models, suggesting that additional AbetaPP processing proteins are also present in the lens. Here we investigate lens expression of beta-secretases, nicastrin and NEP proteins, and compare their protein distribution to Notch and Presenilin in lens. METHODS: RT-PCR was used to analyze mRNA transcripts. Immunoblots and immunohistochemistry were used to examine the protein expression and distribution of secretase and Abeta degrading proteins, as well as Presenilin and Notch proteins in mouse lenses. RESULTS: Beta-acting cleaving enzymes, BACE (BACE1) and BACE2, Nicastrin, Presenilins, Notch and NEP are expressed in the lens. In situ examination of protein distribution in lens indicates expression of each of these proteins is upregulated in peripheral elongating fiber cells at the lens equatorial margin and overlaps with Notch and Presenilin proteins, and also with the distribution of AbetaPP and Abeta proteins demonstrated in a previous study. Neprilysin exon 1-4 splicing, previously described as diagnostic for neuronal expression, also occurs in lens. CONCLUSIONS: BACE, BACE2, Nicastrin and NEP are expressed primarily in elongating peripheral fiber cells, overlapping with Notch, Presenilin, and AbetaPP protein distribution in lens, consistent with their role in regulating Notch and AbetaPP ectodomain shedding in lens. Lens expression of beta- and gamma-secretases together with NEP suggests these proteins may also regulate Abeta turnover in the lens. The presence of Abeta processing and degrading proteases in lens provides further evidence that Alzheimer-related cell biology is fundamentally involved in lens development, and provides additional evidence that mechanisms of Alzheimer pathophysiology can contribute to lens degeneration, suggesting further that therapeutics targeting Abeta proteases may be applicable to lens degenerative disease.

Lens defects and age-related fiber cell degeneration in a mouse model of increased AbetaPP gene dosage in Down syndrome.

Early-onset cataract and Alzheimer's disease occur with high frequency in Down syndrome (trisomy 21), the most common chromosome duplication in human live births. Previously, we used in vivo and lens organ culture models to demonstrate Alzheimer pathophysiology in oxidative stress-related lens degeneration. Currently, well-characterized Alzheimer transgenic mouse models are used to extend these findings. Here, we report on mice carrying a complete copy of a wild-type human AbetaPP (hAbetaPP) gene from the Down syndrome critical region on chromosome 21. hAbetaPP mice produce fiber cell membrane defects similar to those described in human cataracts and increased age-related lens degeneration. hAbetaPP expression and mRNA alternative splicing in human and mouse lens and cornea favor longer, potentially more amyloidogenic forms. Endogenous mouse AbetaPP expression is increased in transgenic lenses, consistent with the cycle of oxidative stress proposed in the mechanism of Alzheimer pathophysiology. Alternative splicing previously designated as neuron-specific occurs in human lens and cornea, and is maintained by hAbetaPP expressed in mouse tissues. These present data implicate AbetaPP in fiber cell formation and in early-onset cataracts in Down syndrome. Finally, our findings provide further support for our hypothesis that Alzheimer pathophysiology contributes to the cataract formation that is increasing in the aging population.