Charles E. Ogburn

Accelerated loss of telomeric repeats may not explain accelerated replicative decline of Werner syndrome cells

The Werner syndrome (WS) is characterized by the premature onset and accelerated rate of development of major geriatric disorders, including atherosclerosis, diabetes mellitus, osteoporosis, ocular cataracts, and various neoplasms. Cultures of WS skin-fibroblastlike cells have been previously shown to undergo accelerated rates of decline of their replicative potentials and to exhibit variegated chromosomal translocations and deletions. Since the replicative decline of normal somatic cells is associated with a loss of telomeric repeats, we investigated the kinetics of telomeric repeat loss in WS cells. The mean length of telomere restriction fragments (TRF) from the earliest passages of WS cells studied was not shorter than those of controls, possibly reflecting selective pressure for subsets of cells with relatively high residual replicative capacity. Statistical evidence indicated an accelerated shortening of TRF length in serially passaged WS cultures, but the mean TRF lengths of WS cultures that had ceased replicating were significantly longer than those of senescent controls. Thus, while accelerated loss of telomeric repeats could potentially explain the rapid decline in proliferation of WS cells, it is possible that WS cells exit the cell cycle via mechanisms that differ from those of replicatively senescent cells from control subjects.

An apoptosis-inducing genotoxin differentiates heterozygotic carriers for Werner helicase mutations from wild-type and homozygous mutants

Abstract Immortalized B lymphocytes from Werner syndrome subjects are shown to be hypersensitive to 4-nitroquinoline-1-oxide (4NQO), supporting earlier work on T lymphocytes. We also show that B cell lines from clinically normal heterozygous carriers exhibit sensitivities to this genotoxic agent, which are intermediate to those of wild-type and homozygous mutants. 4NQO is shown to induce an apoptotic response. These data encourage research on DNA repair with such cell lines and raise the question of an enhanced sensitivity of the relatively prevalent heterozygous carriers to certain environmental genotoxic agents.

Transgenic mice over-expressing the C-99 fragment of βPP with an α-secretase site mutation develop a myopathy similar to human inclusion body myositis

Inclusion body myositis (IBM) is the most common muscle disease in the elderly. Amyloid-β protein (Aβ) has been shown to accumulate abnormally in the vacuolated fibers and to localize to amyloid-like fibrils in muscles from IBM patients. We studied the skeletal muscles from a line of transgenic mice over-expressing the carboxyl-terminal 99 amino acids (C99) of the β-amyloid precursor protein (βPP) with a substitution of lysine-612 to valine (K612V), intended to abolish α-secretase recognition and to preserve the Aβ domain of C99. The majority (87%) of the 24-month-old transgenic mice showed myopathic changes, and approximately one-third of them had degenerating fibers with sarcoplasmic vacuoles and thioflavin-S-positive deposits. Ultrastructurally, the inclusions were aggregates of short thin amyloid-like fibrils, 6 to 8 nm in diameter. These features are similar to those of human IBM. Immunocytochemistry using an antibody against Aβ showed membranous staining in most muscle fibers of transgenic mice, as well as granular or vacuolar cytoplasmic staining in the atrophic fibers. Western blots showed a high level of accumulation of carboxyl-terminal fragments of βPP in the muscles of the transgenic mice with the most severe IBM-like lesions. The expression of IBM-like lesions was age dependent. These transgenic mice provide a model for the study of IBM and for the peripheral expression of a key element in the pathogenesis of Alzheimer disease.

Polymorphisms at the Werner locus: II. 1074Leu/Phe, 1367Cys/Arg, longevity, and atherosclerosis

Werner syndrome (WS) is a progeroid syndrome caused by autosomal recessive null mutations at the WRN locus. The WRN gene encodes a nuclear protein of 180 kD that contains both exonuclease and helicase domains. WS patients develop various forms of arteriosclerosis, particularly atherosclerosis, and medial calcinosis. The most common cause of death in Caucasian subjects with WS is myocardial infarction. Previous studies have identified specific polymorphisms within WRN that may modulate the risk of atherosclerosis. Population studies of the 1074Leu/Phe and 1367Cys/Arg polymorphisms were undertaken to evaluate the role of WRN in atherogenesis. Frequencies of the 1074Leu/Phe polymorphisms in Finnish and Mexican populations revealed an age-dependent decline of 1074Phe/Phe genotype. In Mexican newborns, but not in Finnish newborns, the 1074Leu/Phe and 1367Cys/ Arg polymorphisms were in linkage disequilibrium. Among coronary artery disease subjects, there was a tendency for the 1074Phe allele to be associated with coronary stenosis in a gene dose-dependent manner. Furthermore, the 1367Arg/Arg genotype predicted a lower degree of coronary artery occlusion, as measured by NV50, when compared to the 1367Cys/Cys or 1367Cys/Arg genotypes. However, these tendencies did not achieve statistical significance. Samples from Mexican patients with ischemic stroke showed a trend of haplotype frequencies different from that in a control group of Mexican adults. These data support the hypothesis that WRN may mediate not only WS, but may also modulate more common age-related disorders and, perhaps, a basic aging process.

DNA double-strand breaks in mouse kidney cells with age

A Biojector device fitted with a CO2 cartridge was used to prepare single cellsuspensions from kidneys of 12-month-(middle-aged) and 24-month-old (old) C57Bl/6mice. Microgel electrophoresis of DNA fromthese cells revealed a modest but significant7.3% increase (P = 0.04) in DNA double-strand breaks in old mice. This increase is equivalent to the DNA damage induced by 0.1 Gray of X-rays (5 double-strand breaks) in kidney cells of 10-month-old mice, as determined by a standard calibration curve. Greater DNA damage with aging was also positively correlated with higher levels of pathology in the kidneys.

Increased Expression of β-Amyloid Protein Precursor and Microtubule-Associated Protein τ During the Differentiation of Murine Embryonal Carcinoma Cells

Abstract: Expression of the genes encoding the β/A4 amyloid protein precursor (APP) and microtubule‐associated protein τ was studied in an embryonal carcinoma cell line (P19) that differentiates in vitro into cholinergic neurons after treatment with retinoic acid. Expression of APP increased 34‐ (mRNA) and 50‐fold (protein) during neuronal differentiation; APP‐695 accounted for most of this increase. These remarkable increases in APP expression coincided with a proliferation of neuronal processes and with an increase in content of τ mRNA. Moreover, subsequent decreases in the levels of APP and τ mRNA coincided with the onset of the degeneration of the neuronal processes. Immunocytochemical staining suggested that >85% of the P19‐derived neurons are cholinergic and that APP is present in the neuronal processes and cell bodies. These results suggest that APP may play an important role in construction of neuronal networks and neuronal differentiation and also indicate that this embryonal carcinoma cell line provides an ideal model system to investigate biological functions of APP and the roles of APP and τ protein in development of Alzheimers disease in cholinergic neurons.

Overexpression of a C-Terminal Portion of the β-Amyloid Precursor Protein in Mouse Brains by Transplantation of Transformed Neuronal Cells

The role of beta-amyloid protein and its precursor protein is a central question in the pathogenesis of Alzheimers disease. We have established several transformants from a mouse embryonic carcinoma cell line, which overproduce a C-terminal region of the beta-amyloid precursor protein from the integrated DNA constructs. These stable transformants degenerated to varying extents when undergoing neural differentiation mediated by retinoic acid. To test the neurotoxicity and the amyloidogenicity of the transgene product and its proteolytic derivatives in vivo, two stable transformants were neuronally differentiated and transplanted into the hippocampal regions of syngeneic mice. Similarly, either a nontransformant or a transformant bearing a cDNA construct for yeast major apurinic endonuclease was transplanted to the contralateral regions of the same mice. Three weeks after transplantation, grafts were identified around needle tracts or in hippocampal regions. The regions where transformants overproducing the C-terminal region were grafted were highly reactive to antibodies raised against beta-amyloid protein and its precursor protein, in contrast to the contralateral regions. At 2 and 5 months after neurotransplantation, remarkable distortion and shrinkage characterized the hippocampus on the sides injected with the transformants overproducing the C-terminal region. This shrinkage was associated particularly with a loss of the hippocampal granule cells. beta-Amyloid protein immunoreactive granular deposits in the neuropil were also found in the same sides. Hippocampal blood vessel walls were also stained with the antibodies. These walls were surrounded by astrocytic processes, suggesting involvement of astroglial cells in vascular deposits of beta-amyloid protein. The results are consistent with the hypothesis that the C-terminal region or its derivatives are neurotoxic and amyloidogenic.

Levels of DNA damage are unaltered in mice overexpressing human catalase in nuclei.

Two types of transgenic mice were generated to evaluate the role of hydrogen peroxide in the formation of nuclear DNA damage. One set of lines overexpresses wild-type human catalase cDNA, which is localized to peroxisomes. The other set overexpresses a human catalase construct that is targeted to the nucleus. Expression of the wild-type human catalase transgene was found in liver, kidney, skeletal muscle, heart, spleen, and brain with muscle and heart exhibiting the highest levels. Animals containing the nuclear-targeted construct had a similar pattern of expression with the highest levels in muscle and heart, but with lower levels in liver and spleen. In these animals, immunofluorescence detected catalase present in the nuclei of kidney, muscle, heart, and brain. Both types of transgenic animals had significant increases of catalase activities compared to littermate controls in most tissues examined. Despite enhanced activities of catalase, and its presence in the nucleus, there were no changes in levels of 8OHdG, a marker of oxidative damage to DNA. Nor were there differences in mutant frequencies at a Lac Z reporter transgene. This result suggests that in vivo levels of H(2)O(2) may not generate 8OHdG or other types of DNA damage. Alternatively, antioxidant defenses may be optimized such that additional catalase is unable to further protect nuclear DNA against oxidative damage.

Cell fusion corrects the 4-nitroquinoline 1-oxide sensitivity of Werner syndrome fibroblast cell lines

We have shown that Werner syndrome (WRN) fibroblast cell lines are unusually sensitive to the DNA-damaging agent 4-nitroquinoline 1-oxide (4NQO), though not to gamma radiation or to hydrogen peroxide. The fusion of 4NQO-sensitive WRN and 4NQO-resistant control fibroblast cell lines generated proliferating WRN × control cell hybrids that expressed WRN protein and were 4NQO-resistant. These results establish the recessive nature of 4NQO sensitivity in WRN cell lines and provide a cellular assay for WRN protein function.

Senescence and Vascular Disease

It is with considerable humility that I approach my task of discussing some aspects of cell senescence as it pertains to vascular disease. First of all, the literature of arteriosclerosis and related subjects, if comprehensively and critically analyzed, would surely saturate my aging nervous system. I therefore apologize to all those scholars — living or dead — whom I offend by my restricted knowledge and special viewpoints. Secondly, I must emphasize that our own experimental work in this area is still quite preliminary. Our message is primarily to indicate some relatively simple approaches to the assessment of the replicative potentials of various cell types within and around blood vessels, how these may change as a function of age and what significance such changes may have for the pathogenesis of certain types of vascular disease.