Lianqing Yang

Telomere shortening and decline in replicative potential as a function of donor age in human adrenocortical cells

Telomere shortening is the cause of replicative senescence of mammalian cells in culture and may be a cause of cellular aging in vivo. Some tissues clearly show telomere shortening during aging in humans, but the relationship between replication history and telomere length is obscured by complex relationships between stem cells and more differentiated cell types. Previous experiments on the adrenal cortex and human adrenocortical cells in culture indicate that the proliferative biology of this tissue is relatively simple; cell division occurs continuously throughout life, without evidence for a distinct stem cell compartment. In this tissue we investigated the relationship between telomere biology and replicative senescence by measuring replicative capacity and telomere length as a function of donor age. Cells cultured from adrenal tissue from donors of different ages showed a strong age-related decline in total replicative capacity, falling from about 50 population doublings for fetal cells to an almost total lack of division in culture for cells from older donors. Telomere restriction fragment (TRF) length was analyzed in the same sets of cells and decreased from a value of about 12 kb in fetal cells to approximately 7 kb in cells from older donors. The latter value is consistent with that in fibroblasts which have reached replicative senescence. Furthermore, there was a good correlation in individual donor samples between TRF length and replicative capacity in culture. To confirm the relationship between telomere length, telomerase, and replicative capacity, we measured telomere length in cells before and after infection with a retrovirus encoding hTERT, the catalytic component of human telomerase. The adult adrenal cortex does not have telomerase activity; cells after transduction with the hTERT retrovirus had high telomerase activity. Whereas control cells underwent a replication-dependent shortening in telomeres during long-term growth in culture, hTERT-modified cells maintained telomere length and are probably immortalized. Symmetric cell division in human adrenocortical cells, occurring slowly over the life span, is associated with progressive telomere shortening and may result in proliferative defects in vivo in old age, which could partly account for the age-related changes in the structure and function of the human adrenal cortex.

Expression of p21(WAF1/CIP1/SDI1) and p53 in apoptotic cells in the adrenal cortex and induction by ischemia/reperfusion injury.

p21(WAF1/CIP1/SDI1), an inhibitor of cyclin-dependent kinases, is expressed at varying levels in human adrenal glands removed during surgery or organ recovery. In glands with p21 mRNA, nuclear p21 immunoreactivity, which was occasionally extensive, colocalized with p53 immunoreactivity and DNA damage, as evidenced by in situ end-labeling. Many cells showed morphological features of apoptosis when observed by fluorescent DNA dye staining and electron microscopy. This pattern was also associated with high levels of cytoplasmic heat shock protein 70. To address the question of the origin of p21 expression in some human adrenal glands, rat adrenal glands were subjected to 30 min of ischemia followed by 8 h of reperfusion. Cells with nuclear p21 and p53 appeared in the adrenal cortex together with DNA damage detected by in situ end-labeling. Nuclear p21 immunoreactivity was also produced in adrenal tissue fragments incubated at 37 degrees C in vitro. However, in this case, p21 expression was confined to the cut edge of the tissue. In contrast, p21 in human adrenal glands, as in ischemic rat glands, was within the inner regions of the cortex, supporting an origin of the protein in vivo rather than postmortem. The p53/p21 pathway of reaction to cellular injury, potentially leading to apoptosis, may play a role in tissue damage such as that resulting from ischemia/reperfusion. In the human adrenal cortex this process may be a precursor of adrenal failure.

Differentially expressed genes in zona reticularis cells of the human adrenal cortex

The zona reticularis (ZR) cell in the human adrenal cortex is responsible for the secretion of dehydroepiandrosterone, but its biology, origin, and putative decrease in number during aging are poorly understood. In the present experiments, we investigated to what extent ZR and zona fasciculata (ZF) cells differ in patterns of gene expression. Both cell types were purified by microdissection from adult adrenal cortex specimens. After a brief period in culture, RNA was harvested from the cells and used to prepare radioactively labeled probes following amplification by PCR. Probes were used in hybridizations of arrays of cDNAs on nylon membranes (PCR products or plasmids obtained from an adrenal cDNA library). Analysis of hybridization intensities showed that 17 of the 750 genes studied differed in expression by more than 2-fold. Several genes expressed at higher levels in ZR cells encode components of the major histocompatibility complex or enzymes involved in peroxide metabolism. Members of the tubulin gene family were expressed at higher levels in ZF cells. Differential expression of four of the genes was confirmed by Northern blotting. These differences show that although ZR and ZF cells are similar in gene expression, ZR cells have a gene expression pattern related to the unique biology of this cell type.

DNA damage and p21WAF1/CIP1/SDI1 in experimental injury of the rat adrenal cortex and trauma-associated damage of the human adrenal cortex

In vivo models are needed to study the reactions of tissues to DNA damage, such as the induction of the cyclin‐dependent kinase inhibitor p21, indicating potential repair of the damage, versus apoptosis, indicating the elimination of the damaged cells. Damage to DNA occurs in tissues during shock, sepsis, and other critical medical conditions. Previous studies have found evidence of damage to the cortex of adrenal glands from organ donors who had undergone severe trauma prior to death. The present experiment studied rats under experimental interventions of clinical relevance to patients with conditions that put them at risk for damage to the adrenal glands. These interventions comprised ischaemia and reperfusion injury, sepsis following caecal ligation and puncture, acute pancreatitis, and administration of chemical agents (zymosan and acrylonitrile). All the interventions caused an increase in p21 mRNA as assessed by northern blotting and in situ hybridization. Increased nuclear p21 protein was shown by immunohistochemistry. All the interventions caused damage to DNA, as shown by labelling of available 3′ termini of single‐strand breaks with terminal transferase. The number of cells undergoing apoptosis, visualized by ligation of a hairpin oligonucleotide probe to double‐strand breaks in DNA, was much lower. In rat adrenal glands, apoptotic cells were infrequent under all the conditions studied. They were more abundant in human organ donor adrenal glands that were previously shown to have extensive DNA damage accompanied by induction of p21. The similarity of the effects of a wide variety of surgical interventions and chemical agents suggest a common pathophysiological mechanism which is not specific to the initiating injury. Experimental injury of the rat adrenal cortex provides a model for investigating the role of organ DNA damage and of mediators of the response to DNA damage, such as p21. Copyright

CYP21 pseudogene transcripts are much less abundant than those from the active gene in normal human adrenocortical cells under various conditions in culture

The human steroid 21-hydroxylase pseudogene (CYP21P, also termed CYP21A) is transcribed in the adrenal cortex, but the relative abundance of transcripts from CYP21P and from the active CYP21 gene (also termed CYP21B) is not well established. In the present experiments we cultured primary human adrenocortical cells in defined medium and used RNase protection assays to examine whether there might be a selective increase in the relative abundance of CYP21P transcripts under any of the various regulatory factors known to affect expression of 21-hydroxylase. Differences between the sequences of intron 2 in CYP21P and CYP21 allowed the synthesis of gene-specific probes spanning exon 3 and parts of the adjacent introns. CYP21- and CYP21P-specific probes spanning the site of the start of transcription were also synthesized. CYP21 transcripts were readily detectable. In agreement with previous observations on 21-hydroxylase mRNA and enzyme activity in primary cultures of human adrenocortical cells, the abundance of CYP21 transcripts was increased by cyclic AMP analogues (N6-monobutyryl cyclic AMP and 8-bromo cyclic AMP), insulin, IGF-I and tetradecanoyl phorbol acetate (TPA). However, CYP21P transcripts were not detected in the presence of any of the various regulatory factors known to affect expression of 21-hydroxylase.

Transplantation of normal and genetically modified adrenocortical cells.

Cell transplantation techniques have been applied to the study of the biology of the adrenal cortex and to adrenocortical cell proliferation, differentiation, and senescence. Primary bovine adrenocortical cells, primary human adrenocortical cells and genetically modified bovine adrenocortical cells have been transplanted. Successful methods include transplantation of cells beneath the kidney capsule and several subcutaneous cell transplantation procedures. In successful transplants the cells form a functional vascularized tissue structure that allows the host animals to survive adrenalectomy. We show here that subcutaneous cell transplantation does not depend on embedding cells in collagen get before introduction into the host animal. Subcutaneous transplants secrete both cortisol and aldosterone. However, the variability of plasma aldosterone levels indicates that the factors that determine glomerulosa-type and fasciculata-type cell function in transplant tissues are not well understood.

Adrenocortical cell proliferation in a cell transplantation model: The role of SV40 T antigen

Bovine adrenocortical cells immortalized by human telomerase reverse transcriptase (hTERT) are capable of forming functional vascularized tissue structures when transplanted in immunodeficient mice. These tissues maintain the life of adrenalectomized animals, show normal cell proliferation rates, and maintain a constant tissue size. These experiments were performed by co-transfection of an hTERT-encoding plasmid with an SV40 T antigen-encoding plasmid, but in tissues formed from clones derived in this way SV40 T Ag was not expressed. However, when tissues were formed from nonclonal heterogeneous populations of transfected cells, nodules of SV40 TAg-expressing cells arose that showed a high proliferation rate. These structures resembled nodules formed from transplanted bovine adrenocortical cells in which SV40 TAg was introduced by retroviral transduction rather than transfection. The reasons for these phenomena are discussed; in a nonclonal mixed population of cells, some may have much higher levels of SV40 TAg, which perturbs the normal histology and behavior of tissues formed from hTERT-immortalized adrenocortical cells.