An anti-angiogenic state in mice and humans with retinal photoreceptor cell degeneration

Abnormal angiogenesis accompanies many pathological conditions including cancer, inflammation, and eye diseases. Proliferative retinopathy because of retinal neovascularization is a leading cause of blindness in developed countries. Another major cause of irreversible vision loss is retinitis pigmentosa, a group of diseases characterized by progressive photoreceptor cell degeneration. Interestingly, anecdotal evidence has long suggested that proliferative diabetic retinopathy is rarely associated clinically with retinitis pigmentosa. Here we show that neonatal mice with classic inherited retinal degeneration (Pdeb(rd1)/Pdeb(rd1)) fail to mount reactive retinal neovascularization in a mouse model of oxygen-induced proliferative retinopathy. We also present a comparable human paradigm: spontaneous regression of retinal neovascularization associated with long-standing diabetes mellitus occurs when retinitis pigmentosa becomes clinically evident. Both mouse and human data indicate that reactive retinal neovascularization either fails to develop or regresses when the number of photoreceptor cells is markedly reduced. Our findings support the hypothesis that a functional mechanism underlying this anti-angiogenic state is failure of the predicted up-regulation of vascular endothelial growth factor, although other growth factors may also be involved. Preventive and therapeutic strategies against both proliferative and degenerative retinopathies may emerge from this work.

Neurochemical and morphological consequences of axon terminal degeneration in cerebellar deep nuclei of mice with inherited Purkinje cell degeneration

The concentrations of free amino acids and the activities of transmitter-related enzymes, glutamic acid decarboxylase (GAD), choline acetylase (ChAC) and GABA-transaminase (GABA-t) were measured in cerebellar cortex and deep cerebellar nuclei from the mouse mutant Purkinje cell degeneration (pcd) at various times before and after Purkinje cell loss. Axosomatic synapses on target cells in pcd deep nuclei were quantified by electron microscopy during and after degeneration. The concentration of GABA (nmol/mg wet weight), the Purkinje cell transmitter, was normal in pcd cerebellar cortex and deep nuclei before onset of Purkinje cell degeneration on postnatal day 15. Just after the major period of Purkinje cell loss in cerebellar cortex, GABA concentration was unchanged in the cortical layers but fell to 50% of normal values in the deep nuclei of pcd animals killed either by decapitation or by microwave irradiation. No other measured free amino acid decreased. There were no long-term increases following Purkinje cell degeneration in the concentration of any transmitter amino acids or related enzymes, GAD, ChAC or GABA-t, and thus no indication of axonal sprouting reactions. Progressive losses occurred in wet weight and protein and in activity of GABA-t in both the cerebellar cortex and the deep nuclei of pcd animals. Electron microscopic analysis indicated that Purkinje cell axon terminals contact 30% or more of the somatic surface of principal neurons of the lateral nucleus of the normal cerebellum, but only about 2% of the corresponding sites in the pcd cerebellum. Glial leaflets, rather than other synaptic terminals take their place. Axon terminals may degenerate earlier than Purkinje somata in the pcd disease.

Long lives for homozygous trembler mutant mice despite virtual absence of peripheral nerve myelin

Nervous system functions are dependent on point-to-point communication of signals along neuronal axons, and axonal insulation by myelin is thought to speed such conduction. Loss of previously formed myelin or lack of myelin formation can have serious, even fatal, consequences. Mice homozygous for the trembler mutation make virtually no peripheral nervous system myelin, yet have long and functional lives. This result calls into question the view that peripheral nervous system myelin plays a vital role, at least in this species.

Early cortical histogenesis in the primary olfactory cortex of the mouse

The primary olfactory cortex of mouse embryos varying in age from the 13th to the 15th day of gestation is investigated with the aid of several techniques: Nissl and Golgi preparations, autoradiography and electron microscopy. It is observed that the earliest cells to complete their migrations are diffusely scattered at all levels of the emerging cortical plate. The dendrites of these cells are predominantly tangentially aligned. Subsequently these early formed cells are subdivided into two groups. One group remains superficial in close relation to the lateral olfactory tract while the second is displaced to the deepest level of the cortex. The dendrites of many cells which remain at superficial cortical levels become realigned in a radially upward direction. "Maculae adherens diminutae" are abundant at points of apposition of membranes of cells of all classes at superficial cortical levels. It is suggested that these serve to stabilize cell position and that the upward dendritic realignment is an expression of radially directed stresses. Synapses appear relatively late and probably play no role as determinants of cell position.

Parasagittal organization of the olivocerebellar projection in the mouse

The inferior olivocerebellar projection of the normal inbred C57BL/6J mouse was visualized after anterograde transport of horseradish peroxidase conjugated to the lectin wheat germ agglutinin (HRP-WGA conjugate). Following injections of HRP-WGA conjugate which filled the entire inferior olivary nucleus on one side, olivocerebellar fibers were followed across the midline of the medulla and into the contralateral cerebellar cortex via the inferior cerebellar peduncle. The molecular layer was heavily but nonuniformly labeled in all cortical lobules. Labeled olivocerebellar fibers within the contralateral cerebellar molecular layer were grouped into distinct bands separated by regions of molecular layer containing no labeled fibers. The bands of olivocerebellar terminals in the molecular layer were in turn organized into distinct sets of bands oriented in parasagittal planes. The organizational basis for this banding pattern, previously recognized by other workers in other mammalian and avian species, remains unknown.

Vibrator (vb): a spinocerebellar system degeneration with autosomal recessive inheritance in mice

Vibrator (gene symbol vb), an autosomal recessive mutation, occurred spontaneously in the DBA/2J strain of mice, was rescued by a single cross to C57BL/6J and subsequent brother X sister mating, and has been mapped near shaker-2 (sh-2) and vestigial tail (vt) on chromosome 11. The name emphasizes the unusually rapid (18-20 Hz) postural action tremor expressed in juvenile homozygotes. Selected neurons in spinal cord, and later in brainstem and cerebellum, show progressive degenerative changes featuring dilated cisternae of endoplasmic reticulum in cell bodies, dendrites and axons, with eventual severe intracellular vacuolation and some cell death.

Shiverer gene maps near the distal end of chromosome 18 in the house mouse

Several mouse mutations cause unstable locomotion, tremor, seizures, and a reduced lifespan because of deficient myelin formation in the central nervous system. Mutant alleles at the shiverer (shi) locus are the only ones in this series with a selective molecular defect, namely, in myelin basic proteins (MBPs), which are virtually absent in shi homozygotes and 50% reduced in heterozygotes. In the present study, backcross and intercross matings indicate recombination of 21.2 +/- 3.3% between myelin deficient, shimld, and fused phalanges, syfp, a marker near the middle of chromosome 18. Recombination of shimld with twirler (Tw), a marker near the centromere, is 45.7 +/- 4.9%. Thus, the shi locus maps near the distal end of mouse chromosome 18 and is the first available marker for this region. Given the evidence of other workers that an MBP locus maps to the same mouse chromosome, and that part of this chromosome may be syntenic with an MBP-PEPA region on human chromosome 18, it is likely that shi is in or near an MBP gene.

X-ray diffraction study of myelin structure in immature and mutant mice

X-ray diffraction patterns were obtained from freshly dissected central and peripheral nerves of quaking, myelin synthesis deficiency (msd), and trembler mutants, as well as immature and adult normal mice. The patterns were compared with respect to strength of myelin diffraction, background scatter level, repeat period, and intensity and linewidth of Bragg reflections. The deficiency of myelin in optic nerves was found to be (in decreasing severity): quaking greater immature greater trembler approximately normal adult; and in sciatic nerves: trembler greater immature greater quaking greater msd approximately normal adult. Repeat periods about 3 A less than that for normal adult sciatic myelin were detected in corresponding nerves from immature, quaking, and trembler mice. In some trembler sciatic nerves a second phase having a 190-200 A period and accounting for about 60% of the total ordered myelin was also evident. Comparison of electron density profiles of membrane units calculated from the repeat periods and diffracted intensities for sciatic myelins indicate structural differences at the molecular level. The main findings are: (1) quaking myelin shows a significant elevation of density in the external protein-water layer between membrane bilayers; (2) the membrane bilayer of immature myelin is approximately equal to 2 A thinner than that for normal adult; (3) the membrane bilayer of the more compact phase in trembler myelin is approximately equal to 5 A thinner than for normal; and (4) the difference in repeat periods for the two phases present in some of the trembler nerves can be accounted for predominantly by distinct membrane bilayer separations at the external boundary.

Cribriform degeneration (cri): a new recessive neurological mutation in the mouse

The mutation cribriform degeneration (cri) occurred in the DBA/2J strain; it is in linkage group VIII, 31 recombination units from b. Homozygotes show severe vacuolar degeneration in white and gray matter of the spinal cord and brainstem, normocytic anemia at birth which decreases in severity with age, and abnormalities of electrolyte distribution.

Growth and development of the mouse retinal pigment epithelium. II. Cell patterning in experimental chimaeras and mosaics

The retinal pigment epithelium (PE), with pigmentation as a cell-autonomous marker, was analyzed in three types of mice: congenic pigmented----albino chimaeras, X-inactivation mosaics (Cattanach's translocation), and mosaics homozygous for the pink-eyed unstable mutation, which contain rare fully pigmented cells. In 10 chimaeric and 34 X-inactivation eyes, the proportionate mix in the right and left eyes of an individual animal was similar, the mix was approximately constant in all parts of a given eye, average patch size was larger toward the periphery of the PE, and peripheral patches tended to be elongated in the radial dimension. In all 44 whole mounts from pink-eyed unstable mutants, patches of 1-12 pigmented cells, each representing a single clone, were scattered throughout the PE; they tended to be larger with increasing distance from the optic nerve head. The collective data are consistent with significant cell mixing prior to specification of the two eye fields, during early organ-forming stages, and during later development of the PE. The tendency of peripheral patches to orient radially reflects the edge-biased pattern of cell proliferation in the PE. Cell mixing appears to be more prominent posteriorly in the PE sheet; growth proceeds anteriorly for more generations.

Persistent hypersynchronization of neocortical neurons in the mocha mutant of mouse

A recessive mutation in the mouse at the mocha locus (mh, chromosome 10) modulates the synchronous synaptic activation of neocortical neurons, resulting in a constant 6-7 Hz (theta) wave pattern in the electrocorticogram. The gene-linked brain rhythm is unaffected by motor behavior and cannot be desynchronized by sensory stimuli. This exemplary neurological mutation affecting cortical excitability is the first to reveal clearly that the predominance of a specific pattern of spontaneous brain wave activity can be inherited as a recessive trait.

Nontoxic nerve guide tubes support neovascular growth in transected rat optic nerve

Nontoxic, bioresorbable "nerve guide" tubes were used to bridge the transected optic nerves of adult rats. Nerve guides were fabricated as polymers of synthetic poly D,L-lactates with 2% triethyl citrate added as a plasticizer. The local environment was manipulated further by the addition of the proteins collagen, fibrinogen, and anti-Thy-1 antibody to the nerve guide lumens at the time of operation. Neovascular growth through the nerve guide lumens was quantified with the aid of a computer-controlled microscope. Neovascular growth was greater in the nerve guides to which proteins had been added, compared with initially empty nerve guides. These experiments demonstrated the effectiveness of these nerve guide tubes in supporting and directing neovascular growth in the mammalian central nervous system, and suggested that specific alterations of the local environment within the nerve guide lumen can affect the extent of neovascular growth.

Paranodal dysmyelination and increase in tetrodotoxin binding sites in the sciatic nerve of the motor end-plate disease (med/med) mouse during postnatal development

Motor end-plate disease (med), in the mouse, is a hereditary neuromuscular defect, caused by a single gene mutation and characterized by a progressive muscle weakness. +Med/+med mice die 21-23 days after birth and the neurobiological abnormalities already reported are nerve terminal sprouting and swelling and neurotransmission failures. We studied +med/+med mice at preclinical (9-11 days after birth) as well as at clinically recognized stages of the disease. The nonmyelinated gaps of the nodes of Ranvier in the +med/+med sciatic nerve are found to be significantly widened in +med/+med animals compared to control littermates, even in the preclinical stage, although the nodes of Ranvier are not yet ultrastructurally mature. The maximal binding capacity for [3H]ethylene-diamine tetrodotoxin, expressed in femtomoles per milligram of protein, is significantly increased in +med/+med sciatic nerves. Thus, Na+ channels, which are known to be located mainly at the nodes of Ranvier in normal myelinated axons, are increased in number in +med/+med mice even before the disease becomes clinically established. Both the ultrastructural and biochemical developmental abnormalities of the node of Ranvier rapidly approach their maximal expression as the behavioral signs develop. Such nerve abnormalities may be closely related to the physiological impairment of nerve impulse conduction which leads to the pathophysiological expression of motor end-plate disease.

Benzo(a)pyrene and X-rays induce reversions of the pink-eyed unstable mutation in the retinal pigment epithelium of mice

The pink-eyed unstable (p(un)) mutation is the result of a 70kb tandem duplication within the murine p gene. Homologous deletion/recombination of the locus to wild-type occurs spontaneously in embryos and results in pigmented spots in the fur and eye that persist for life. Such deletion events are also inducible by a variety of DNA damaging agents, as we have observed previously with the fur spot assay. Here, we describe the use of the retinal pigment epithelium (RPE) of the eye to detect reversion events induced with two differently acting agents. Benzo(a)pyrene (B(a)P) induces a high frequency, and X-ray exposure a more modest increase, of p(un) reversion in both the fur and the eye. The eye-spot assay requires fewer mice for significant results than the fur spot assay. Previous work had elucidated the cell proliferation pattern in the RPE and a position effect variegation phenotype in the pattern of p(un) reversions, which we have confirmed. Acute exposure to B(a)P or X-rays resulted in an increased frequency of reversion events. The majority of the spontaneous reversions lie toward the periphery of the RPE whereas induced events are found more centrally, closer to the optic nerve head. The induced distribution corresponds to the major sites of cell proliferation in the RPE at the time of exposure, and further advocates the proposal that dividing cells are at highest risk to develop deletions.

Identification and mapping of a mouse gene influencing cerebellar folial pattern

Little is known about the role of inheritance in the pattern of cerebral and cerebellar cortical folding, or the causes of individual variation. Inouye and Oda (J. Comp. Neurol., 190 (1980) 357-362) found that the cerebellar folial pattern varies markedly between inbred strains of mice and between individuals in a closed (non-inbred) colony, but shows little variation between individuals within a given inbred strain. They concluded that strain-specific variation in cerebellar folial pattern is under genetic control. In the present study, the folial pattern was examined in crosses between the C57BL/6J and DBA/2J inbred strains of mice, which differ in the presence or absence of a single cerebellar fissure, and in recombinant inbred strains derived from a cross between the same strains. We found that variation is discrete, that neither phenotype is dominant, and that the strain difference is due predominantly to allelic differences at a single locus (Cfp-1) on chromosome 4. Incomplete penetrance of the simpler pattern suggests that this genetic locus interacts in a probabilistic manner with epigenetic mechanisms involved in morphogenesis of the cerebellum.

Cross-linked collagen surface for cell culture that is stable, uniform, and optically superior to conventional surfaces

A new type of collagen surface for use with cultures of peripheral nervous system cells is described. Collagen is derivatized to plastic culture dishes by a cross-linking reagent, l-cyclohexyl-3-(2-morpholinoethyl)-carbodiimide-metho-p-toluene sulfonate (carbodiimide), to form a uniform and durable surface for cell attachment and growth that allows dry storage, long-term culture, and improved microscopy. Surfaces of collagen derivatized to plastic were compared to surfaces of adsorbed or ammonia-polymerized collagen in terms of collagen binding and detachment, growth by dorsal root ganglion cells, and electron microscopy appearances. Derivatized collagen surfaces retained more collagen and showed much less evidence of degradation and cellular damage over periods of many weeks than did conventional adsorbed surfaces. Long-term survival of cells on derivatized collagen was far superior to that on the other surfaces, with almost 90% of cultures still viable after 10 wk. Transmission electron microscopy showed an organized layer of single fibrils that supported cell growth well, and scanning electron microscopy demonstrated an increased uniformity of derivatized collagen surfaces compared to ammoniated collagen surfaces. Applications for this improved substrate surface are discussed.