Three distinct stages of lens opacification in transgenic mice expressing the HIV-1 protease.

Scanning electron microscopy of the lenses from transgenic mice (TG(72)) containing the HIV-1 protease linked to the lens alphaA-crystallin promoter showed structural changes around postnatal day 16. Frank opacification of the lens was observed at day 24. To relate the biochemical and biophysical changes that occur during the process of cataract development, high-resolution two-dimensional gel electrophoresis (2D), quantitative image analysis and ion measurements were carried out on lenses from postnatal day 10 and on days 15-24. The phase separation temperature (Tc), a measure of molecular interactions between proteins, was also determined for normal and transgenic lenses. A comparison of the transgenic and normal lenses on day 10 revealed no significant differences in any of the measured parameters. However, starting around day 16 or the first stage of observed structural changes, the TG(72)crystallin profiles of the alphaA- alphaB-, betaA3-, betaA4-, betaB3 and one gamma-crystallin began to deviate from the normal. By postnatal day 20, a second stage was initiated with an influx of calcium and sodium ions that was accompanied by modifications of betaB1- and betaB2-crystallin. In the third and final stage of the cataract process, a large increase in the proteolysis of crystallins was accompanied by the appearance of the frank cataract on day 24. The Tc initially increased in all of the mouse lenses until just prior to eyelid opening. After that time, the Tc decreased in all lenses. Although the Tc continued to decrease in the normal lenses with age, for the homozygous transgenic mice it exhibited a dramatic increase that began on day 20. Thus, in the TG(72)transgenic mouse, cataract formation occurs in a three-stage process. Tc and other biophysical parameters previously measured appeared to be insensitive to the modifications that occur during stage 1. However, during the second stage of cataract formation, there was a correspondence between abnormal Tc and the abnormal interactions between cellular constituents apparently resulting from lens hydration, the loss of ion homeostasis and continued proteolysis. The last stage of cataract formation results in a total loss of lens transparency and leakage of lens proteins.

Tracking pathology with proteomics: identification of in vivo degradation products of alphaB-crystallin.

Soemmerring's ring is one form of "after cataract" that can occur following cataract surgery. The ring structure is formed by adherence of the anterior lens capsule to the posterior lens capsule. Epithelial cells remaining after surgery differentiate into lens fiber cells but the resulting tissue mass does not remain transparent. The protein in normal lens and in Soemmerring's rings from four individuals was analyzed using two-dimensional (2-D) gel electrophoresis, matrix assisted laser desorption/ionization-time of-flight-mass spectrometry (MALDI-TOF-MS) and image analysis with Phoretix software. The 2-D protein patterns of the Soemmerring's rings were generally similar to that of cortical fiber cells of normal human lens with some notable exceptions. Several post-translationally modified forms of alphaB-crystallin(1-175) were identified. Two degradation products, alphaB-crystallin(1-170) and alphaB-crystallin(1-174), each make up 9.5-27% of the total alphaB-crystallin in the Soemmerring's rings and less than 1% in the normal lenses. Other modified forms of alphaB-crystallin are aberrant in the fiber cells of the Soemmerring rings relative to normal lens.

An atypical form of alphaB-crystallin is present in high concentration in some human cataractous lenses. Identification and characterization of aberrant N- and C-terminal processing.

Two unique polypeptides, 22.4 and 16.4 kDa, were prominent in some human cataracts. Both proteins were identified as modified forms of the small heat shock protein, alphaB-crystallin. The concentration of total alphaB-crystallin in most of these cataracts was significantly increased. The 22.4-kDa protein was subsequently designated as alphaB(g). Mass spectrometric analyses of tryptic and Asp-N digests showed alphaB(g) is alphaB-crystallin minus the C-terminal lysine. alphaB(g) constituted 10-90% of the total alphaB-crystallin in these cataracts and was preferentially phosphorylated over the typical form of alphaB-crystallin. Human alphaB(g) and alphaB-crystallin were cloned and expressed in Escherichia coli. The differences in electrophoretic mobility and the large difference in native pI values suggest some structural differences exist. The chaperone-like activity of recombinant human alphaB(g) was comparable to that of recombinant human alphaB-crystallin in preventing the aggregation of lactalbumin induced by dithiothreitol. The mechanism involved in generating alphaB(g) is not known, but a premature termination of the alphaB-crystallin gene was ruled out by sequencing the polymerase chain reaction products of the last exon for the alphaB-crystallin gene from lenses containing alphaB(g). The 16.4-kDa protein was an N-terminally truncated fragment of alphaB(g). The high concentration of alphaB-crystallin in these cataracts is the first observation of this kind in human lenses.

Targeted disruption of the mouse alpha A-crystallin gene induces cataract and cytoplasmic inclusion bodies containing the small heat shock protein alpha B-crystallin.

alpha A-crystallin (alpha A) and alpha B-crystallin (alpha B) are among the predominant proteins of the vertebrate eye lens. In vitro, the alpha-crystallins, which are isolated together as a high molecular mass aggregate, exhibit a number of properties, the most interesting of which is their ability to function as molecular chaperones for other proteins. Here we begin to examine the in vivo functions of alpha-crystallin by generating mice with a targeted disruption of the alpha A gene. Mice that are homozygous for the disrupted allele produce no detectable alpha A in their lenses, based on protein gel electrophoresis and immunoblot analysis. Initially, the alpha A-deficient lenses appear structurally normal, but they are smaller than the lenses of wild-type littermates. alpha A-/- lenses develop an opacification that starts in the nucleus and progresses to a general opacification with age. Light and transmission electron microscopy reveal the presence of dense inclusion bodies in the central lens fiber cells. The inclusions react strongly with antibodies to alpha B but not significantly with antibodies to beta- or gamma-crystallins. In addition, immunoblot analyses demonstrate that a significant portion of the alpha B in alpha A-/- lenses shifts into the insoluble fraction. These studies suggest that alpha A is essential for maintaining lens transparency, possibly by ensuring that alpha B or proteins closely associated with this small heat shock protein remain soluble.

Hierarchy of lens proteins requiring protection against heat-induced precipitation by the alpha crystallin chaperone.

Gel filtration of the water-soluble extract from bovine lens yields a group of proteins, emerging between the peaks of beta H and beta L crystallins, which show a considerably greater sensitivity to heat-induced aggregation/precipitation than the far more abundant beta and gamma crystallins. However, the small heat shock protein: alpha crystallin was effective in protecting these trace constituents of the lens from precipitating out of solution at 55 degrees C (measured under the standard conditions in a pH 7.5 buffer containing 50 mM sodium phosphate, 100 mM NaCl, 1 mM EDTA and 0.05% NaN3). Prominent components of the precipitate, formed in the absence of a recombinant alpha B crystallin chaperone could be resolved by one- and two-dimensional electrophoresis. Identification by amino acid sequencing revealed that the heat-sensitive group of lens proteins comprised glyceraldehyde-3-phosphate dehydrogenase (M(r) approximately 39 kDa), enolase (approximately 48 kDa), leucine aminopeptidase (approximately 52 kDa) and aldehyde dehydrogenase (approximately 53 kDa). These findings indicate for the first time that the aggregation of such minor lens constituents could possibly contribute to initiating the process of opacification in the development of cataracts.

The nucleus of the human lens: demonstration of a highly characteristic protein pattern by two-dimensional electrophoresis and introduction of a new method of lens dissection.

A practical method for dissection of human lenses is described. The method utilizes the suture patterns as a guide to identify the developmental stage in which fiber cells were formed. Lenses were separated into cortex and adult, infantile, fetal and embryonic nuclear regions. Analysis of the proteins in each of these regions in adult lenses shows that the lens nucleus has a highly characteristic two-dimensional protein pattern distinct from that of the cortex. Each of the nuclear regions has essentially the same protein pattern. The data suggest that the conversion of cortical fibers to mature nuclear fibers involves well controlled processes.