Quantitative analysis of three-dimensional fibrillar collagen microstructure within the normal, aged and glaucomatous human optic nerve head.

The aim of this study was to quantify connective tissue fibre orientation and alignment in young, old and glaucomatous human optic nerve heads (ONH) to understand ONH microstructure and predisposition to glaucomatous optic neuropathy. Transverse (seven healthy, three glaucomatous) and longitudinal (14 healthy) human ONH cryosections were imaged by both second harmonic generation microscopy and small angle light scattering (SALS) in order to quantify preferred fibre orientation (PFO) and degree of fibre alignment (DOFA). DOFA was highest within the peripapillary sclera (ppsclera), with relatively low values in the lamina cribrosa (LC). Elderly ppsclera DOFA was higher than that in young ppsclera (p < 0.00007), and generally higher than in glaucoma ppsclera. In all LCs, a majority of fibres had preferential orientation horizontally across the nasal-temporal axis. In all glaucomatous LCs, PFO was significantly different from controls in a minimum of seven out of 12 LC regions (p < 0.05). Additionally, higher fibre alignment was observed in the glaucomatous inferior-temporal LC (p < 0.017). The differences between young and elderly ONH fibre alignment within regions suggest that age-related microstructural changes occur within the structure. The additional differences in fibre alignment observed within the glaucomatous LC may reflect an inherent susceptibility to glaucomatous optic neuropathy, or may be a consequence of ONH remodelling and/or collapse.

Transretinal degeneration in ageing human retina: a multiphoton microscopy analysis.

AIM: Retinal cell remodelling has been reported as a consistent feature of ageing. However, the degree to which this results in transretinal degeneration is unclear. To address this, the authors used multiphoton microscopy to quantify retinal degeneration in post-mortem human eyes of two age groups. METHODS: Retinas from six young subjects (18-33 years old) and six older subjects (74-90 years old) were prepared as wholemount preparations. All retinas were stained with 4,6-diamidino-2-phenylindole and imaged by multiphoton confocal microscopy to quantify neuron densities in the retinal ganglion cell layer (RGCL), inner nuclear layer (INL) and outer nuclear layer (ONL). Neurons were counted using automated cell identification algorithms. All retinas were imaged hydrated to minimise tissue artefacts. RESULTS: In both groups, 56% of the area within the central 4 mm eccentricity and 27% of the area with eccentricity between 4 mm and 7 mm were imaged. Compared with young subjects, the peak RGCL neuron loss in the aged subjects (25.5%) was at 1 mm eccentricity. INL and ONL neuron densities significantly decreased at 1-2 mm eccentricity (8.7%) and 0.5-4 mm eccentricity (15.6%) respectively (P <0.05). The reduction in neuron density in the INL corresponded, spatially, to the region with the greatest neuron loss in the RGCL and ONL. CONCLUSIONS: This is the first study to correlate neurodegeneration in different populations of cells in the ageing retinas. These data confirm that the greatest neuronal loss occurs in the RGCL and ONL in human ageing retinas, whereas the INL is relatively preserved.

Topography of neuron loss in the retinal ganglion cell layer in human glaucoma.

AIM: To determine if retinal ganglion cell (RGC) loss influences the loss of surrounding RGCs to generate clustered patterns of cell death in human glaucoma. It is hypothesised that retinal ganglion cell loss accelerates the loss of surrounding cells to generate, at a local, cellular scale, clustered patterns of retinal of RGC death. The absence of these interactions would result in a diffuse pattern RGC loss. METHOD: Six glaucomatous retinas (67-83 years old) and six age-matched control retinas (61-89 years old) were prepared as wholemounts and stained by 4',6-diamidino-2-phenylindole (DAPI) solution (3 microg/ml in PBS). An area corresponding to central 14 degrees of the visual field was imaged. The nearest-neighbour distribution was determined for cells in both normal and glaucomatous RGCL. RESULTS: Clustered RGC loss in human glaucoma was observed on a background of diffuse loss. The mean nearest-neighbour distance (NND) of the glaucomatous retinas was significantly higher than with controls (p<0.001). The distribution of NND in glaucomatous retinas was skewed to the higher values with a higher positive kurtosis relative to controls. The quantitative analysis of the pattern of cell loss is supported by the visual inspection of the patterns of cell loss. DISCUSSION: The nearest-neighbour analysis is consistent with the presence of two patterns of cell loss in the RGCL in glaucoma. While the diffuse of cell loss can account for an overall reduction in the RGC population, an additional non-random pattern is consistent with the hypothesis that RGC loss has a local influence on the viability of surrounding cells.

Genetic modification of human trabecular meshwork with lentiviral vectors.

Glaucoma, a group of optic neuropathies, is the leading cause of irreversible blindness. Neuronal apoptosis in glaucoma is primarily associated with high intraocular pressure caused by chronically impaired outflow of aqueous humor through the trabecular meshwork, a reticulum of mitotically inactive endothelial-like cells located in the angle of the anterior chamber. Anatomic, genetic, and expression profiling data suggest the possibility of using gene transfer to treat glaucomatous intraocular pressure dysregulation, but this approach will require stable genetic modification of the differentiated aqueous outflow tract. We injected transducing unit-normalized preparations of either of two lentiviral vectors or an oncoretroviral vector as a single bolus into the aqueous circulation of cultured human donor eyes, under perfusion conditions that mimicked natural anterior chamber flow and maintained viability ex vivo. Reporter gene expression was assessed in trabecular meshwork from 3 to 16 days after infusion of 1.0 x 10(8) transducing units of each vector. The oncoretroviral vector failed to transduce the trabecular meshwork. In contrast, feline immunodeficiency virus and human immunodeficiency virus vectors produced efficient, localized transduction of the trabecular meshwork in situ. The results demonstrate that lentiviral vectors permit efficient genetic modification of the human trabecular meshwork when delivered via the afferent aqueous circulation, a clinically accessible route. In addition, controlled comparisons in this study establish that feline and human immunodeficiency virus vectors are equivalently efficacious in delivering genes to this terminally differentiated human tissue.

Characterization of myocilin-myocilin interactions.

PURPOSE: To determine whether myocilin (MYOC; also referred to as TIGR) is present as a complex in human aqueous humor, whether part of the complex formation may be due to MYOC-MYOC interactions and to characterize the sites of interaction. METHODS: Human aqueous humor was analyzed by using a gel filtration column for the identification of MYOC complexes. MYOC-MYOC interactions were studied with a yeast two-hybrid system. Expression of full-length and truncated MYOC proteins in AH109 yeast was analyzed for growth and color on minimal medium. Site-directed mutagenesis was used to selectively mutate eight leucine residues within the leucine zipper motif. In vitro transcription and translation was used to verify yeast two-hybrid analysis. RESULTS: MYOC was found to be present in human aqueous humor as a complex ranging from 120 to 180 kDa. Expression of full-length MYOC in yeast as well as in vitro binding studies revealed that MYOC can interact with itself. MYOC-MYOC interactions occurred mainly within amino acids 117-166, a region containing a leucine zipper domain. Glycine substitution for selective leucine residues confirmed that MYOC-MYOC interactions occurred mainly within the leucine zipper domain. CONCLUSIONS: MYOC is present in human aqueous humor, not as a monomer but as a complex. Part of this complex may form due to MYOC-MYOC interactions that take place mainly within the leucine zipper domain.

Cyclin-dependent kinase 5 is expressed in both Sertoli cells and metaphase spermatocytes.

OBJECTIVE: To gain insight into the function of cyclin-dependent kinase 5 (Cdk5) in spermatogenesis. DESIGN: The expression of the Cdk5 protein was determined with the use of immunohistochemical and immunoblot analysis. SETTING: Academic research laboratory. ANIMAL(S): Adult mouse and archival human testicular tissue were used for the immunohistochemical analysis. Adult mice were used as the source of tissues for the immunoblot analysis. INTERVENTION(S): The immunohistochemical analysis was performed with an anti-Cdk5 antibody. The double immunohistochemical analysis was performed with anti-Cdk5 and alpha-tubulin antibodies. Immunoblotting was used to examine multiple mouse tissues for Cdk5 expression. MAIN OUTCOME MEASURE(S): Analysis of Cdk5 protein distribution. RESULT(S): Cdk5 was localized specifically within the cytoplasm of Sertoli cells and meiotic metaphase germ cells. The double immunohistochemistry analysis demonstrated the co-localization of Cdk5 and alpha-tubulin within the Sertoli cells. Western blot analysis revealed a high level of expression of Cdk5 in the testicular lysate. CONCLUSION(S): The cyclin-dependent kinases are known regulators of the cell cycle; however, Cdk5 expression previously has been described in terminally differentiated cells of the brain. The present evidence of an association between Cdk5 and microfilaments of Sertoli cells and meiotic metaphase germ cells suggests a role of Cdk5 in both seminiferous tubule function and meiosis.

Recombinant TIGR/MYOC increases outflow resistance in the human anterior segment.

PURPOSE: To determine the effect of human recombinant TIGR/myocilin (MYOC) protein on outflow resistance in the human anterior segment. METHODS: A cDNA for MYOC was inserted into a bacterial expression system and purified with nickel ion affinity chromatography. The anterior segments of 12 pairs of human eyes were placed in perfusion organ culture. One eye received an anterior chamber exchange with partially purified recombinant MYOC (25 microgram), whereas the other eye received either heat-denatured recombinant MYOC (25 microgram), partially purified ss-galactosidase (25 or 250 microgram), or partially purified control proteins isolated from a null expression lysate (25 microgram). Eyes were fixed up to 72 hours after infusion, and immunohistochemistry was performed using anti-MYOC polyclonal antibody. RESULTS: Recombinant MYOC caused an increase in IOP over 12 hours, increasing outflow resistance 94%, whereas the fellow eye infused with null expression sample increased 12% (n = 7; P = 0.0005). When compared with recombinant MYOC, neither heat-denatured MYOC, recombinant ss-galactosidase, bovine serum albumin, nor fetal calf serum caused an increase in outflow resistance. MYOC IOP remained above baseline levels for 48 to 72 hours. Immunohistochemistry results confirmed the presence of recombinant MYOC in the trabecular meshwork. CONCLUSIONS: Recombinant MYOC increased outflow resistance in human anterior segments, whereas control proteins did not. MYOC may increase outflow resistance by specific interactions within the trabecular meshwork.

TGFbeta-inducible early gene (TIEG) also codes for early growth response alpha (EGRalpha): evidence of multiple transcripts from alternate promoters.

TGFbeta-inducible early gene (TIEG) and early growth response alpha (EGRalpha) are putative transcription factors based on homology to known zinc finger proteins SP1, EGR1, BTEB, and Wilm tumor. Here we report that TIEG and EGRalpha are expressed from alternative promoters of the same gene. The TIEG/EGRalpha gene spans 8 kb and contains five exons. Use of alternative first exons results in TIEG having 12 unique amino acids on its N-terminus. Computer analysis of the 5' upstream regions of either TIEG (exon 1a) or EGRalpha (exon 1b) does not identify a TATA box or initiator sequencebut shows consensus sequence similarities to binding sites for several transcription factors including SP1,JunB, and aromatic hydrocarbon/receptor-ligand complexes. Analysis of constructs containing 5'-flanking regions show that both the TIEG and the EGRalpha promoters have significant activity in human fetal osteoblast cells. Northern analysis of mRNA from various human tissues and several cell lines reveals that TIEG is the predominant transcript produced and regulated by growth factors from the TIEG/EGRalpha gene.

Production of SVP-1/-3/-4 in guinea pig testis. Characterization of novel transcripts containing long 5'-untranslated regions and multiple upstream AUG codons.

The GP1G gene of the guinea pig codes for three of the four abundant seminal vesicle secretory proteins produced in this species. This gene is expressed at highest efficiency in the seminal vesicle (SV) from a promoter that contains a canonical TATA box and CCAAT box. However, GP1G gene transcripts and proteins have also been identified in other tissues. To investigate the structure of GP1G transcripts produced in the testis, cDNA clones were isolated by screening a testis library. Three unique cDNAs (TSM1-3) were isolated. Each of these clones contained a 3'-untranslated region (UTR) and coding region identical to that of the seminal vesicle transcript. However, the 5'-UTRs of the testis transcripts were significantly longer than that found on the SV mRNA (416-646 nucleotides compared with only 23 nucleotides for the SV). Each of these alternatively spliced 5'-UTRs incorporated the SV promoter elements into transcribed sequence, and each contained multiple upstream AUG codons predicted to abolish translation of the major open reading frame. Nevertheless, each of the testis transcripts was capable of directing the synthesis of GP1G-related proteins in vitro. Analysis of the translation products suggests that the extended 5'-UTR of the testis transcripts regulate both the choice of translation start site and the efficiency of translation in this system. Western blot analysis of testis proteins revealed that the protein products of GP1G are also synthesized by the testis in vivo.

Exons lost and found. Unusual evolution of a seminal vesicle transglutaminase substrate.

The GP1G gene codes for three of the four abundant androgen-regulated secretory proteins produced by the guinea pig seminal vesicle. Sequencing of the entire 6.3-kilobase gene and comparison with other mammalian seminal vesicle secretory protein genes reveals a common three-exon, two-intron organization. However, significant sequence similarity between this group of genes is largely limited to their 5'-flanking regions and first exons, which code almost exclusively for signal peptides in each case. The first intron of GP1G does contain a region with high similarity to the coding exon of a human seminal vesicle secretory protein gene, semenogelin II. The 3' half of the GP1G gene appears to share a common ancestry with the human SKALP/elafin gene. Sequences related to the elafin promoter, coding, untranslated regions, and introns are clearly identifiable within the GP1G sequence. The elafin gene codes for a serine protease inhibitor and is expressed in a variety of different human tissues. To determine if the GP1G gene was also active outside of the seminal vesicle, RNA from a variety of guinea pig tissues was hybridized to a GP1G cDNA probe. At least three novel RNA bands hybridizing to the GP1G probe were detected in testis RNA samples, and GP1G-related mRNAs were also found in other tissues. These data suggest that these seminal vesicle secretory proteins may have functional roles outside the reproductive system.

Recombinant human proteinase 3, the Wegener's autoantigen, expressed in HMC-1 cells is enzymatically active and recognized by c-ANCA.

We developed a stable expression system for conformationally intact recombinant human PR3 (rPR3) using the human mast cell line HMC-1. Like in U937 cells, the rPR3 is processed from a 34 kDa precursor to the 29 kDa mature form, primarily as the result of oligosaccharide trimming. The rPR3 binds [3H]DFP and hydrolyzes the substrate N-methoxysuccinyl-Ala-Ala-Pro-Val-pNA. The enzymatic activity is inhibited by greater than 95% by alpha 1-PI. The rPR3 and the enzymatically inactive mutant rPR3-S176A are both packaged in granules. Thus, proteolytic autoprocessing is not required for PR3's targeting to granules. This rPR3 is the first to be recognized by most c-ANCA from WG patients and all anti-PR3 ANCA that were detected by standard anti-PR3 specific ELISA. This expression system for rPR3 represents a versatile tool for the analysis of its intracellular processing, structure-function relationships and interaction with autoantibodies.

Differential regulation of p34cdc2 and p33cdk2 by transforming growth factor-beta 1 in murine mammary epithelial cells.

Cyclin-dependent kinases (cdks) are a family of proteins whose function plays a critical role in cell cycle traverse. Transforming growth factor-beta 1 (TGF-beta 1) is a potent growth inhibitor of epithelial cells. Since cdks have been suggested as possible biochemical markers for TGF-beta growth inhibition, we investigated the effect of TGF-beta 1 on cdc2 and cdk2 in a normal mouse mammary epithelial cell line (MME) and a TGF-beta-resistant MME cell line (BG18.2). TGF-beta 1 decreases newly synthesized cdc2 protein levels within 6 h after addition. Coincident with this decrease in newly synthesized cdc2 protein was a marked reduction in its ability to phosphorylate histone H1. This decrease in kinase activity is not due to a change in steady-state levels of cdc2 protein, since mRNA and total protein levels of cdc2 are not reduced until 12 h after TGF-beta 1 addition. This suggests that the kinase activity of cdc2 is dependent on newly synthesized cdc2 protein. Moreover, the protein synthesis of another cyclin-dependent kinase, cdk2, is not effected by TGF-beta 1 addition, but its kinase activity is substantially reduced. Thus, it appears that TGF-beta decreases the kinase activity of both cdc2 and cdk2 by distinct mechanisms.

Conditional binding to and cell cycle-regulated inhibition of cyclin-dependent kinase complexes by p27Kip1.

Mammalian cultures primarily regulate cell cycle traverse during G1. For progression through G1 and commitment to DNA synthesis, the activity of a family of proteins, the cyclin-dependent kinases (cdks), is required. There are two primary regulatory portions of G1: (a) the G0-G1 transition, which allows entry into G1; and (b) the G1-S transition, promoting entry to DNA synthesis and commitment to cell division. In the present manuscript, we provide evidence for cross-talk between these two cell cycle transitions. Extracts prepared from quiescent mouse mammary epithelial cells are shown to act in a dominant manner to specifically inhibit the histone H1 kinase activity of preformed/active cdk2, cdk4, cyclin A, or cyclin E complexes from G1-S cell extracts. The inhibitory activity arises as cells enter quiescence and decreases once cultures are stimulated to begin G1 traverse and endogenous cdk activity becomes evident. This activity is associated with the regulated binding of the cdk inhibitor p27Kip1 to cyclin A/cdk2 kinase complexes upon mixing of the extracts. Removal of p27Kip1 from the quiescent cell extract specifically abolishes the inhibitory effect. The inhibitory activity and p27Kip1 binding in vitro depend on incubation of the extracts at physiological temperature or the presence of a reducing agent. The results suggest an interplay between the acquisition of quiescence, cdk activity, and G1 traverse.

Dissociation of p34cdc2 complex formation from phosphorylation and histone H1 kinase activity.

The cell cycle inhibitor mimosine was used to examine the activation of the p34cdc2 protein kinase in S phase of the cell cycle. Addition of mimosine to cycling epithelial cells halted cell cycle traverse in S phase, coincident with an inhibition of p34cdc2 histone H1 kinase activity. Mimosine treatment did not alter p34cdc2 synthesis or turnover; however, overall phosphorylation of p34cdc2 was decreased to near undetectable levels. Although activity of p34cdc2 was inhibited, the ability of the protein to form high molecular weight complexes, a phenomenon associated with kinase activation in vivo, was not affected. These results indicate that p34cdc2 complex formation can occur in the absence of phosphorylation and that phosphorylation of p34cdc2 is then required to activate these preformed complexes.

Cell cycle-dependent inhibition of p34cdc2 synthesis by transforming growth factor beta 1 in cycling epithelial cells.

Cycling epithelial cells were shown to reversibly arrest in late G1 phase following treatment with transforming growth factor beta 1. Associated with this G1-S phase arrest was a decrease in the synthesis and histone H1 kinase activity of p34cdc2. Transforming growth factor beta 1 did not reduce p34cdc2 levels by modulating the turnover of newly synthesized p34cdc2. The decrease in p34cdc2 synthesis preceded any detectable effect on DNA synthesis. Moreover, the action of transforming growth factor beta 1 was regulated in a cell cycle-specific manner; epithelial cells were sensitive to transforming growth factor beta 1 only during the G1 phase. The results suggest that p34cdc2 might be a useful biochemical marker for investigating the mechanism(s) of transforming growth factor beta 1 signaling.

Conservation of coding and transcriptional control sequences within the snRNP E protein gene.

The snRNP E protein is one of several proteins associated with the U family of small nuclear RNAs that are involved in RNA processing. Isolation and characterization of the snRNP E protein cDNA sequences from mouse and chicken revealed a 100% conservation of the predicted amino acid sequence when compared to that of the human homologue. Further characterization of a genomic clone for the mouse snRNP E protein gene revealed that the 5' untranslated region and the immediate 5' upstream region have also been highly conserved: 72 and 70%, respectively. Conserved 5' regions include multiple copies of the CTTCCG hexamer sequence which are involved in regulating transcription of the human snRNP E protein gene. Mobility shift assays using corresponding DNA fragments from both human and mouse reveal that both fragments can compete for binding of at least one common transcription factor. These studies demonstrate that along with the amino acid sequence conservation between human and mouse, the snRNP E protein gene has also maintained a high DNA sequence conservation within its basal promoter structure.

Transcriptional regulation of the small nuclear ribonucleoprotein E protein gene. Identification of cis-acting sequences with homology to genes encoding ribosomal proteins.

The 5'-upstream region of the small nuclear ribonucleoprotein E protein (snRNP E) gene has multiple sequence similarities to elements found to be integral in the transcriptional regulation of some mouse ribosomal protein genes (G + C block, CTTCCG motifs) as well as U1 snRNA genes (U1 "B," U1 "D," and SPH enhancers). Furthermore, the immediate upstream region of the snRNP E protein gene lacks typical TATA and CAAT sequence motifs but contains one copy of a GC box characteristic of a housekeeping promoter. By transfection of constructs containing various amounts of the 5'-upstream region of the snRNP E protein gene linked to the bacterial gene for chloramphenicol acetyl transferase (CAT), we determined that the 5' boundary of sequence needed for transcription was within the first 153 nucleotides upstream of the transcription start site. Further deletions to within 51 base pairs reduced CAT expression by 2.5-fold. Mutational analysis within this 51-base pair region revealed that direct repeats of the hexamer CTTCCG were essential for CAT expression. Gel shift assays and DNase I footprinting experiments confirmed this conclusion by demonstrating specific binding of proteins to the CTTCCG motifs. This suggests that the direct repeats of the CTTCCG hexamer sequence play a key role in transcriptional regulation of the snRNP E protein gene.