Raman tweezers provide the fingerprint of cells supporting the late stages of KSHV reactivation

Kaposi's sarcoma-associated herpesvirus (KSHV) has both latent and lytic phases of replication. The molecular switch that triggers a reactivation is still unclear. Cells from S phase of cell cycle provide apt conditions for an active reactivation. In order to specifically delineate the Raman spectra of cells supporting KSHV reactivation, we followed a novel approach where cells were sorted based on the state of infection (latent Vs lytic) by a flow cytometer and then analyzed by the Raman tweezers. The Raman bands at 785, 813, 830, 1095, and 1128 cm-1 are specifically altered in cells supporting KSHV reactivation. These 5 peaks make up the Raman fingerprint of cells supporting KSHV reactivation. The physiological relevance of the changes in these peaks with respect to KSHV reactivation is discussed in the following report. Originally published Journal of Cellular and Molecular Medicine, Vol. 13, No. 8b, Aug 200

XXVII. — Coleoptera (Lagriidae) from Northern Sarawak

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Apolipoprotein H, a new mediator in the inflammatory changes ensuing in jeopardised human myocardium

Aim—To investigate the presence of membrane "flip flop" in ischaemic human myocardium, we assessed depositions of apolipoprotein H (apoH; ß2-glycoprotein 1) in ischaemic myocardium. Serum protein apoH can bind to negatively charged phospholipids and can also inhibit blood coagulation in vitro. We hypothesised that, because of its affinity for phosphatidyl serine, apoH might bind to "flip flopped" cells and would therefore be useful as a marker for membrane flip flop in vivo. Methods—Myocardial tissue specimens were obtained from patients who had died within 14 days of acute myocardial infarction. Results—Immunohistochemical analysis of these specimens revealed that apoH was selectively deposited in infarcted areas of human myocardium of at least one day's duration. Depositions of apoH were not found in non-ischaemic myocardial tissue samples obtained from patients who died from other (extracardial) causes. In vitro experiments with the human leukaemia T cell line Jurkat, subjected to apoptosis by etoposide, showed that apoH was bound to the membrane of apoptotic cells. However, these experiments also indicated that flip flop itself is not sufficient for apoH binding. In addition, Jurkat cells that bound apoH were positive for activated complement complexes, as was also found in the human heart. Conclusions—These results suggest that apoH is involved in the inflammatory processes that occur in ischaemic myocardium. Key Words: myocardium • apolipoprotein H • inflammation • complemen