Kaposi's sarcoma-associated herpesvirus can productively infect primary human keratinocytes and alter their growth properties.

Previous studies have shown the presence of Kaposi's sarcoma-associated herpesvirus (KSHV/HHV8) DNA in endothelial cells, in keratinocytes in the basal layer of the epidermis overlying plaque-stage nodular lesions of cutaneous Kaposi's sarcoma (KS), and in the epithelial cells of eccrine glands within KS lesions. We infected primary cell cultures of human keratinocytes with KSHV/HHV8. At 6 days post infection, transcription of viral genes was detected by reverse transcriptase PCR (RT-PCR), and protein expression was documented by an immunofluorescence assay with an anti-LANA monoclonal antibody. To determine whether the viral lytic cycle was inducible by chemical treatment, KSHV/HHV8-infected keratinocytes were treated with 12-O-tetradecanoylphorbol-13-acetate (TPA) and RT-PCR was performed to confirm the transcription of lytic genes such as open reading frame 26, (which encodes a capsid protein). Finally, to assess infectious viral production, other primary human cells (human umbilical vein endothelial cells), were infected with concentrated supernatant of KSHV-infected, TPA-induced keratinocytes and the presence of viral transcripts was confirmed by RT-PCR. The uninfected keratinocytes senesced 3 to 5 weeks after mock infection, while the KSHV/HHV8-infected keratinocytes continued to proliferate and to date are still in culture. However, 8 weeks after infection, viral genomes were no longer detectable by nested PCR. Although the previously KSHV/HHV8-infected keratinocytes still expressed epithelial markers, they acquired new characteristics such as contact inhibition loss, telomerase activity, anchorage-independent growth, and changes in cytokine production. These results show that KSHV/HHV8, like other herpesviruses, can infect and replicate in epithelial cells in vitro and suggest that in vivo these cells may play a significant role in the establishment of KSHV/HHV8 infection and viral transmission.

Early exposure to restraint stress enhances chemical carcinogenesis in rat liver.

This study examines the effect of a stress-associated condition on chemical hepatocarcinogenesis in the rat. Rats were given diethylnitrosamine (200 mg/kg. b.w., i.p.), followed, 1 week later, by three cycles of immobilization at room temperature. Two weeks after the last cycle they were treated according to the resistant hepatocyte protocol. At 4 weeks after selection, mean size of glutathione-S-transferase 7-7 positive foci/nodules was increased in the immobilized group (0.82+/-0.22 vs. 0.25+/-0.04 mm(2) in controls). Furthermore, at the end of 1 year 10/13 animals (77%) developed hepatocellular carcinoma in the former group, while only 6/14 (43%) incidence of cancer was found in controls. These results indicate that exposure to restraint stress early during carcinogenesis enhances the development of chemically-induced hepatocellular carcinoma in the rat.

Liver regeneration in response to partial hepatectomy in rats treated with retrorsine: a kinetic study.

BACKGROUND/AIM: We have designed an experimental model in which transplantation of normal hepatocytes into rats previously treated with retrorsine (a naturally-occurring pyrrolizidine alkaloid) results in near-complete replacement of the recipient liver by donor-derived cells. Two/thirds partial hepatectomy was found to be essential for this process to occur. To probe this finding, in the present study we describe the kinetics of liver regeneration in response to partial hepatectomy in rats given retrorsine. METHODS: Six-weeks-old male Fisher 344 rats received retrorsine (2 injections of 30 mg/kg each, i.p., 2 weeks apart), or the vehicle. Four weeks after the last injection, partial hepatectomy was performed and rats were killed at 1, 2, 3, 6, and 15 days thereafter. RESULTS: At time zero, i.e. prior to partial hepatectomy, liver weight and total liver DNA content were significantly lower in retrorsine-treated animals compared to controls (DNA content: 19.2+/-1.7 vs. 25.7+/-1.1 mg/liver). Diffuse megalocytosis (enlarged hepatocytes) was present in the group exposed to retrorsine. By day 3 post-partial hepatectomy liver DNA content in control animals had more than doubled compared to day 1 values (20.2+/-1.5 vs. 8.8+/-1.2), while very little increase was seen in retrorsine-treated rats at the same time points (7.6+/-0.4 vs. 6.1+/-0.2). At 2 weeks after partial hepatectomy, total DNA content returned close to normal levels in the control group (26.9+/-1.0 mg/liver); however, the value was still very low in animals receiving retrorsine (9.1+/-0.7). Data on BrdU labeling were consistent with this pattern and indicated that DNA synthesis following partial hepatectomy was largely inhibited in the retrorsine group. Similarly, no mitotic response was observed in hepatocytes following partial hepatectomy in animals exposed to retrorsine. CONCLUSIONS: These results clearly indicate that retrorsine exerts a strong and persistent cell cycle block on hepatocyte proliferation. Further, these results are in agreement with the hypothesis that selective proliferation of transplanted hepatocytes in retrorsine-treated animals is dependent, at least in part, on the persistent cell cycle block imposed by the alkaloid on endogenous parenchymal cells.

Direct hyperplasia does not enhance the kinetics of liver repopulation in a new model of hepatocyte transplantation in the rat.

BACKGROUND/AIMS: We have recently developed a new model of extensive liver repopulation by transplanted hepatocytes following exposure to pyrrolizidine alkaloids. In the present study, the effect of 2/3 partial hepatectomy (PH) and that of a potent direct liver mitogen, lead nitrate, were compared in their ability to modulate the kinetics of liver repopulation. METHODS: Fischer 344 rats deficient in enzymatic activity for dipeptidyl-peptidase IV (DPPIV-) were used as cell transplantation recipients. They were given 2 doses of the pyrrolizidine alkaloid retrorsine (30 mg/kg, i.p.), 2 weeks apart, followed 2 weeks later by transplantation of 2 x 10(6) hepatocytes (via the portal vein), freshly isolated from a normal congeneic DPPIV+ donor. PH was carried out or a single injection of lead nitrate (100 micromol/kg, i.v.) was administered 2 weeks post-transplantation. Liver samples obtained at different time points post-treatment were processed histochemically for DPPIV activity. RESULTS: The percent of liver sections occupied by DPPIV+ hepatocytes was <1% at the time of PH or lead nitrate administration. In animals which underwent PH, it increased to 33.4+/-5.7% at 2 weeks and to 55.6+/-8.5% at 1 month. However, in animals receiving lead nitrate, these percentages were only 3.3+/-1.3% at 2 weeks and 16.2+/-3.9% at 1 month. Repeated injections of lead nitrate had no additional effect. Further experiments indicated that an acute mitogenic response to lead nitrate was present in transplanted cells, while resident hepatocytes were inhibited by retrorsine. CONCLUSIONS: These results indicate that direct mitogenic signals (such as those induced by lead nitrate), and compensatory signals (such as those elicited by PH), are not equally effective on kinetics of liver repopulation in this system. The possible reasons for these differential effects are discussed.