Cytometry of cyclin proteins

Cyclins are key components of the cell cycle progression machinery. They activate their partner cyclin-dependent kinases (CDKs) and possibly target them to respective substrate proteins within the cell. CDK-mediated phosphorylation of specific sets of proteins drives the cell through particular phases or checkpoints of the cell cycle. During unperturbed growth of normal cells, the timing of expression of several cyclins is discontinuous, occurring at discrete and well-defined periods of the cell cycle. Immunocytochemical detection of cyclins in relation to cell cycle position (DNA content) by multiparameter flow cytometry has provided a new approach to cell cycle studies. This approach, like no other method, can be used to detect the unscheduled expression of cyclins, namely, the presentation of G1 cyclins by cells in G2/M and of G2/M cyclins by G1 cells, without the need for cell synchronization. Such unscheduled expression of cyclins B1 and A was seen when cell cycle progression was halted, e.g., after synchronization at the G1/S boundary by inhibitors of DNA replication. The unscheduled expression of cyclins B1 or E, but not of A, was also observed in some tumor cell lines even when their growth was unperturbed. Likewise, whereas the expression of cyclins D1 or D3 in nontumor cells was restricted to an early section of G1, the presentation of these proteins in many tumor cell lines also was seen during S and G2/M. This suggests that the partner kinase CDK4 (which upon activation by D-type cyclins phosphorylates pRB committing the cell to enter S) is perpetually active throughout the cell cycle in these tumor lines. Expression of cyclin D also may serve to discriminate G0 vs. G1 cells and, as an activation marker, to identify the mitogenically stimulated cells entering the cell cycle. Differences in cyclin expression make it possible to discriminate between cells having the same DNA content but residing at different phases such as in G2 vs. M or G2/M of a lower DNA ploidy vs. G1 cells of a higher ploidy. The expression of cyclins D, E, A and B1 provides new cell cycle landmarks that can be used to subdivide the cell cycle into several distinct subcompartments. The point of cell cycle arrest by many antitumor agents can be estimated with better accuracy in relation to these compartments compared to the traditional subdivision into four cell cycle phases. The latter applications, however, pertain only to normal cells or to tumor cells whose phenotype is characterized by scheduled expression of cyclins. As sensitive and specific indicators of the cell's proliferative potential, the cyclins, in particular D-type cyclins, are expected to be key prognostic markers in neoplasia.

Tubing loops as a model for cardiopulmonary bypass circuits: both the biomaterial and the blood-gas phase interfaces induce complement activation in an in vitro model

We describe here a model for the study of blood/surface and blood/air interaction as encountered in cardiopulmonary bypass (CPB) circuits. Polyethylene tubing was filled with serum or blood and closed end to end into loops whereby the volume of the remaining air bubble was inversely varied with respect to that of the fluid. The loops were rotated vertically in a water bath at 37 degrees C. The profiles of C3a, iC3, and TCC generation were similar to those observed at surgery, involving CPB. Soluble heparin and heparan sulfate inhibited both C3a and TCC formation, but surface-conjugated heparin had only a minor effect. Binding of C3 and/or C3 fragments to the heparin surface was much reduced compared to the amine matrix to which heparin was linked, but compared with the polyethylene surface the effect was less pronounced. These data suggest that, in addition to the biomaterial surface, the blood-gas interface seems to play an important role in the activation of complement and that this activation is inhibitable by high concentrations of soluble glucose aminoglycans.

Unscheduled expression of cyclins D1 and D3 in human tumour cell lines

D-type cyclins are involved in regulation of cell traverse through G1 primarily by activating the cyclin-dependent kinase 4 (CDK4) and targeting it to the retinoblastoma tumour suppressor protein. There is a vast body of evidence that defective expression of D-type cyclins is associated with tumour development and/or progression. Immunocytochemical detection of D cyclins combined with multiparameter flow cytometry makes it possible to measure the expression of these proteins in individual cells in relation to their cell cycle position without the need for cell synchronization. This approach was used in the present study to compare the cell cycle phase specific expression of cyclins D3 and D1 in human normal proliferating lymphocytes and fibroblasts, respectively, with nine tumour cell lines of different lineage. During exponential, unperturbed growth, expression of cyclin D1 in fibroblasts from donors of different age, or cyclin D3 in lymphocytes, was limited to mid-G1 cells: Less than 7% of the cells entering S phase or progressing through S and G2 were cyclin D positive. In contrast, expression of either cyclin D1 or cyclin D3 in tumour cell lines of different lineage was not limited to G1 phase. Namely, over 80% of the cells in S and G2+M were cyclin D positive in eight of the nine cell lines studied. The data indicate that while expression of cyclin D1 or D3 in normal cells is discontinuous, occurring transiently in G1, these proteins are expressed in some tumour lines persistently throughout the cell cycle. This suggests that the partner kinase CDK4 is perpetually active throughout the cell cycle in these tumour lines.

Absence of a prominent Th2 cytokine response in human tuberculosis

Depressed Th1 responses are a prominent feature of human tuberculosis, but an enhanced Th2 response has not been detected in peripheral blood T cells stimulated in vitro with Mycobacterium tuberculosis. In disease due to Mycobacterium leprae, Th2 cells predominate in tissue lesions of patients with extensive disease but are absent from peripheral blood. To determine if Th2 cells are present in tissue lesions of tuberculosis patients, we evaluated patterns of cytokine expression in lymph nodes from tuberculosis patients with or without human immunodeficiency virus infection and in controls without tuberculosis. Gamma interferon and interleukin-10 (IL-10) mRNA expression in tuberculosis patients with or without human immunodeficiency virus infection was high, whereas IL-4 expression in the same patients was low. Immunolabeling studies showed that macrophage production of IL-12 was increased in lymph nodes from tuberculosis patients, that gamma interferon was produced by T cells, and that IL-10 was produced by macrophages rather than Th2 cells. These results indicate that Th2 responses are not enhanced either systemically or at the site of disease in human tuberculosis.

Effect of protease inhibitors on early events of apoptosis

Proteolysis is an early event of apoptosis which appears to be associated with activation of the endonuclease which is responsible for internucleosomal DNA cleavage. The present study was designed to reveal the possible role of proteolysis in other early events, such as chromatin condensation, nuclear breakdown, and destabilization of in situ DNA double-stranded structure. Apoptosis of human leukemic HL-60 cells and rat thymocytes was induced by different agents, including DNA topoisomerase inhibitors, an RNA antimetabolite, and the glucocorticosteroid, prednisolone. DNA degradation was evaluated by pulsed field and conventional gel electrophoresis and by the presence of in situ DNA strand breaks. DNA stability was estimated by the measure of its sensitivity in situ to denaturation. Chromatin condensation, nuclear breakdown, and other morphological changes were monitored by interference contrast and UV microscopy following cell staining with the DNA-specific fluorochrome 4',6-diamidino-2- phenylindole. Several irreversible or reversible serine protease inhibitors prevented internucleosomal DNA degradation, nuclear breakdown, and destabilization of DNA double-stranded structure. The effective inhibitors, however, did not prevent the onset of chromatin condensation, nor the loss of the fine structural framework, nor the initial step of DNA cleavage generating DNA fragments of >=50 kb in size. The data indicate that in both cell systems the activity of proteases sensitive to the inhibitors tested is needed for internucleosomal DNA cleavage to occur. The data also suggest that these proteases may be involved in dissolution of the nuclear envelope. Because nuclear matrix proteins and histones stabilize DNA in situ, and the decrease in DNA stability which occurs during apoptosis is precluded by the inhibitors, it is likely that serine proteases may degrade DNA stabilizing proteins. The activity of these proteases, however, appears needed neither for DNA cleavage to >=50-kb fragments nor for the onset of chromatin condensation which is associated with dissolution of the structural framework of the nucleus.

Growth imbalance and altered expression of cyclins B1, A, E, and D3 in MOLT-4 cells synchronized in the cell cycle by inhibitors of DNA replication

Expression of cyclins at the translational level is generally studied by immunoblotting lysates of cells synchronized in the cycle. Most methods used to synchronize transformed cells induce growth imbalance. The aim of the present study was to analyze levels of cyclins B1, A, E, and D3 in the respective phases of the cycle in synchronized human leukemic MOLT-4 cells, correlate them with total cellular protein content (reflecting growth imbalance), and compare the synchronized cells with cells from unperturbed, asynchronous cultures. Expression of cyclins detected immunocytochemically in individual permeabilized cells was analyzed by multiparameter flow cytometry, which made it possible to relate position of the cell in the cell cycle with cyclin expression. Cells synchronized at the G1-S boundary by thymidine, mimosine, or aphidicolin had about 40% increased total protein and 4-5 fold higher levels of cyclins E and B1 compared to their G1 counterparts from unperturbed cultures. Expression of cyclin A in synchronized cells was 2-fold higher, while expression of cyclin D3 was essentially unaltered. The synchronized cells traversing S phase after release from the block had elevated but decreasing levels of cyclins E, B1, and A. Although the cyclin expression of cells reentering G1 was similar to that of their counterparts from asynchronous cultures, the total protein content was still elevated by about 30%. The data indicate that due to different degrees of imbalance in total protein and individual cyclin content, levels of cyclins detected by immunoblotting of cell lysates from synchronized cultures may not be representative of their expression in unperturbed cells. The elevated level of cyclin B1 in the cells arrested at the G1-S boundary may reflect the increased half-life of this protein, stabilized as the result of the overexpression of cyclin E.

Discrimination of G2 and mitotic cells by flow cytometry based on different expression of cyclins A and B1

Cyclins, the regulatory subunits of their respective cyclin-dependent kinases, are the key components of the cell-cycle progression machinery. Some cyclins are expressed discontinuously during the cell cycle, their synthesis and degradation being strictly scheduled. The presence of these cyclins in the cell, therefore, provides landmarks of the cell cycle, in addition to DNA replication and mitosis. Cyclin A is expressed in late S and G2 phase and degraded during mitosis just prior to metaphase. Degradation of another "mitotic" cyclin, cyclin B1, occurs later, at the transition from metaphase to anaphase. Based on the difference in time of degradation of cyclin A versus cyclin B1 it was possible, in the present study, to discriminate between G2 and mitotic (postprophase) MOLT-4 leukemic cells, by multiparameter (cellular DNA content versus cyclin expression) flow cytometry. The cells arrested in metaphase by Vinblastine were cyclin A negative and had an elevated level of cyclin B1. The cells arrested in G2 by the DNA topoisomerase II inhibitor m-AMSA had a very high level of cyclin B1 expression and unchanged expression of cyclin A. During stathmokinesis induced by Vinblastine the percentage of mitotic cells estimated by analysis of cellular DNA content and cyclin A expression was identical to that estimated by the alternative method based on in situ DNA denaturation followed by staining with acridine orange. Thus, differences in expression of cyclins A and B1 make it possible to discriminate cells that have the same DNA content but reside in different phases of the cycle, such as DNA diploid cells in G2 versus tetraploid G1 cells or mitotic versus G2 cells.

T-cell cytokine responses in human infection with Mycobacterium tuberculosis

Compared with healthy tuberculin reactors, Mycobacterium tuberculosis-stimulated peripheral blood mononuclear cells from tuberculosis patients had diminished production and mRNA expression of the Th1 cytokines gamma interferon and interleukin 2 (IL-2), with no change in production and mRNA expression for the Th2 cytokines IL-4, IL-10, and IL-13. These results were confirmed by evaluation of T cells and CD4+ cells. At the level of systemic T cells, development of tuberculosis is associated with diminished Th1 but not enhanced Th2 responses.

Induction of apoptosis by 5-azacytidine: drug concentration-dependent differences in cell cycle specificity

There are conflicting data in the literature as to whether cytotoxicity of the cytidine antimetabolite 5'-azacytidine (AZC) is a consequence of its incorporation into RNA, DNA, or both. Because apoptosis appears to be the predominant mode of tumor cell death after treatment with most antitumor drugs, and in the case of some drugs, the proclivity of the cell to undergo apoptosis varies depending on the cell cycle position, this study was aimed toward elucidating whether induction of apoptosis by AZC is cell cycle phase specific. Human promyelocytic leukemic HL-60 cells were treated with varying concentrations of AZC, and flow cytometric methods that identify apoptotic cels and provide information about the cell cycle distribution of the apoptotic and nonapoptotic cell populations were used. At 2-6 microM concentrations of AZC, the cells in the G1 phase preferentially underwent apoptosis, whereas the cells in G2-M were particularly resistant. Although incorporation of bromouridine into RNA was suppressed at that low AZC concentration, the rate of 5'-bromo-2-deoxyuridine incorporation into DNA was not significantly affected. At an AZC concentration of 8-40 microM, no cell cycle phase specificity in induction of apoptosis was apparent, but both the rate of 5'-bromo-2-deoxyuridine incorporation into DNA and bromouridine into RNA were reduced in proportion to drug concentration. The data suggest that the mechanism of cell killing by AZC may be different, depending on its concentration. Namely, whereas incorporation of AZC into RNA may play a predominant role in the induction of cytotoxicity of G1 cells at low drug concentrations, the perturbation of both RNA and DNA metabolism may be responsible for triggering cell death in the G1 and S phases, as is seen at higher concentrations of this antimetabolite.

Autocrine transforming growth factor beta 1 modulates the expression of integrin alpha 5 beta 1 in human colon carcinoma FET cells

Transforming growth factor beta (TGF-beta) has been extensively studied as an exogenous agent that stimulates the expression of extracellular matrix proteins and their cell-surface integrin receptors in a variety of cell types. However, the recent demonstration of autocrine TGF-beta growth effects in a number of cell types suggests that the steady-state expression of extracellular matrix and integrin proteins and their biological activity may also be under autocrine TGF-beta control. Previously, we reported that repression of autocrine TGF-beta 1 activity by constitutive expression of a full-length TGF-beta 1 antisense cDNA led to abrogation of autocrine negative TGF-beta and, as a result, increased tumorigenicity and anchorage-independent growth of a poorly tumorigenic, well-differentiated colon carcinoma cell line designated FET (Wu, S., Theodorescu, D., Kerbel, R. S., Willson, J. K. V., Mulder, K. M., Humphrey, L. E., and Brattain, M. G. (1992) J. Cell Biol. 116, 187-196). Consequently, we have used this model system to study the effects of repression of autocrine TGF-beta 1 activity on the expression of integrin alpha 5 beta 1 and integrin alpha 5 beta 1-mediated cell adhesion to fibronectin. The expression of the integrin alpha 5 subunit was reduced in TGF-beta 1 antisense transfected FET cells at both mRNA and protein levels as determined by RNase protection assays and immunoprecipitation, respectively. Autocrine TGF-beta 1 had no effect on the transcription of integrin alpha 5 and beta 1 subunits, indicating that autocrine TGF-beta 1 may regulate integrin alpha 5 beta 1 expression at the post-transcriptional level. The diminished expression of integrin alpha 5 beta 1 on the cell surface led to the reduced adhesion of TGF-beta 1 antisense transfected cells to fibronectin. This phenomenon could be reversed by treatment with exogenous TGF-beta 1.

Shall red cell units stand upright, lie flat or be mixed during storage? In vitro studies of red cells collected in 0.5 CPD and stored in RAS2 (Erythrosol)

Red cells were prepared using a new anticoagulant with half the normal amount of citrate and a new additive solution (RAS2, Erythrosol) previously shown to give improved storage conditions, and stored in a highly gas permeable plastic container (PL 2209). Mixing daily and weekly resulted in lower PCO2, higher PO2 and more rapid oxygen saturation of the haemoglobin than storage unmixed in an upright position. Storage horizontally in a lying position unmixed resulted in similar blood gas values as with mixing. The haemolysis was lowest in units mixed once weekly: 0.21 +/- 0.09% after 28 days and 0.26 +/- 0.06% after 56 days. The morphology was better maintained in mixed than in unmixed units. Horizontal storage and mixing once per week seem to be optimal as judged from these in vitro studies.

Threshold expression of cyclin E but not D type cyclins characterizes normal and tumour cells entering S phase

Complexes of cyclin-dependent kinases (cdk) and their partner cyclins drive the cell through the cell cycle, each such complex phosphorylating a distinct set of proteins at a particular check-point or phase of the cycle. Immunocytochemical detection of cyclins combined with measurement of cellular DNA content by flow cytometry makes it possible to relate expression of each of these proteins with the actual cell cycle position, without the necessity of cell synchronization. In the present study, we have investigated expression of E and D type cyclins in G1 cells and in cells entering S phase, in eight different human hematopoietic and solid tumour cell lines (two leukaemias, a lymphoma, three breast carcinomas, a colon carcinoma and a bladder transitional cell carcinoma) during their exponential phase of growth, as well as in normal mitogen stimulated lymphocytes. In all the cell types studied, the average level of D type cyclin expression was invariable throughout the cell cycle. A great intercellular variability, in particular of the G1 cell subpopulations, and the presence of a large fraction of G1, S and G2 + M cells that were cyclin D negative (20-40% in tumour cell lines and about 80% among lymphocytes), were other characteristic features of D type cyclin expression. In contrast to D type cyclins, the expression of cyclin E was discontinuous during the cycle, peaking at the time of cell entrance to S. Also, a well defined threshold in expression of cyclin E characterized cells that were entering S phase, and virtually no cyclin E negative cells were seen during the early portion of S phase. The data indicate that while cell entrance to S phase is unrelated to expression of D type cyclins (at the time of entrance), accumulation of cyclin E up to critical level is a prerequisite for initiation of DNA replication. The great intercellular variability in expression of D type cyclins and their invariant average level across the cell cycle suggest that these cyclins, in addition to their acknowledged function in promoting cell progression through mid- to late-G1 may have other role(s), related or unrelated to the cell cycle progression. The presence of a large number of D type cyclin negative cells in all phases of the cycle suggests that during exponential growth the cells may not express this protein and yet may traverse the cycle, including G1 phase.

Expression of cyclins A, D2 and D3 in individual normal mitogen stimulated lymphocytes and in MOLT-4 leukemic cells analyzed by multiparameter flow cytometry

Cyclins are regulatory subunits of the cyclin dependent kinases (CDKs), the enzymes that drive the cell through the respective phases and check-points of the cell cycle. The expression of cyclins in non-tumor cells, regulated by timely induction of their synthesis and proteolysis, is scheduled, occurring at discrete periods of the cell cycle. Using multiparameter flow cytometry we have recently observed that expression of cyclins B1 and E in individual normal lymphocytes mitogenically stimulated by phytohemagglutinin (PHA) and lymphocytic leukemic MOLT-4 cells was similar, restricted to particular phases of the cycle: cyclin B1 was detected only in G2+M- and cyclin E in late G1 and early S-phase cells. In the present study we have measured the expression of cyclins A, D2 and D3 in these cells. The presence of cyclin A was restricted to late S and G2 phases, both in the case of lymphocytes and of MOLT-4 cells. Over 95% of the non-stimulated lymphocytes were both cyclin D2 and D3 negative. Mitogenic stimulation with PHA-induced expression of cyclins D2 and D3 in over 50% cells, which corresponds to the percentage of cells that respond to this mitogen in cultures. Expression of these proteins peaked between 8 and 24 h after addition of PHA, and then decreased at the time of cell entrance to S. During exponential growth (48-72 h after stimulation with PHA) expression of the D-type cyclins was diminished: only between 5-10% of the lymphocytes had levels of cyclin D3 as high as G1 cells between 8-24 h after PHA stimulation. Populations of proliferating lymphocytes and MOLT-4 cells were very heterogeneous in terms of expression of D-type cyclins by individual cells. While expression of cyclin D2 in exponentially growing MOLT-4 cells was similar to that of proliferating lymphocytes, the percent of cells expressing cyclin D3 as well as the degree of expression, was higher in MOLT-4 cells, regardless of the phase of the cycle. These results, with our earlier observations of the untimely expression of cyclins B1 and E in several other tumor lines, suggest that altered expression of cyclins may be a frequent feature of malignancy.

5-Aminolevulinate synthase and the first step of heme biosynthesis

5-Aminolevulinate synthase catalyzes the condensation of glycine and succinyl-CoA to yield 5-aminolevulinate. In animals, fungi, and some bacteria, 5-aminolevulinate synthase is the first enzyme of the heme biosynthetic pathway. Mutations on the human erythroid 5-aminolevulinate synthase, which is localized on the X-chromosome, have been associated with X-linked sideroblastic anemia. Recent biochemical and molecular biological developments provide important insights into the structure and function of this enzyme. In animals, two aminolevulinate synthase genes, one housekeeping and one erythroid-specific, have been identified. In addition, the isolation of 5-aminolevulinate synthase genomic and cDNA clones have permitted the development of expression systems, which have tremendously increased the yields of purified enzyme, facilitating structural and functional studies. A lysine residue has been identified as the residue involved in the Schiff base linkage of the pyridoxal 5'-phosphate cofactor, and the catalytic domain has been assigned to the C-terminus of the enzyme. A conserved glycine-rich motif, common to all aminolevulinate synthases, has been proposed to be at the pyridoxal 5'-phosphate-binding site. A heme-regulatory motif, present in the presequences of 5-aminolevulinate synthase precursors, has been shown to mediate the inhibition of the mitochondrial import of the precursor proteins in the presence of heme. Finally, the regulatory mechanisms, exerted by an iron-responsive element binding protein, during the translation of erythroid 5-aminolevulinate synthase mRNA, are discussed in relation to heme biosynthesis.

Aminolevulinate synthase: functionally important residues at a glycine loop, a putative pyridoxal phosphate cofactor-binding site

5-Aminolevulinate synthase catalyzes the first step of the heme biosynthetic pathway in nonplant higher eukaryotes. The enzyme functions as a homodimer and requires pyridoxal 5'-phosphate as its cofactor. Lysine-313 in murine erythroid aminolevulinate synthase has been identified as the residue involved in the Schiff base linkage with pyridoxal 5'-phosphate [Ferreira, G. C., Neame, P. J., & Dailey, H. A. (1993) Protein Sci. 2, 1959-1965]. However, other residues involved in binding and orienting the cofactor remain unknown. We studied the informational content of each residue within an 11 amino acid glycine-rich region, which we propose to be part of the phosphate-binding motif, based on amino acid sequence comparison with other pyridoxal 5'-phosphate-dependent enzymes and nucleotide-binding proteins. Partial random mutagenesis of this region in murine erythroid aminolevulinate synthase gene was followed by an efficient biological selection, using a hemA- Escherichia coli strain to recover functional unnatural enzymes. Among the total of 5444 variants produced, 283 were found to be functional. DNA sequencing results of 226 functional mutants indicated that most residues in this region contained a low informational content, being able to tolerate several other amino acid substitutions. However, three residues, namely, Arg-149, Gly-142, and Gly-144, were found to contain high informational content; Arg-149 was conserved in all of the functional mutants sequenced, while Gly-142 and Gly-144 could only tolerate alanine replacement. Two codon-specific random libraries of Arg-149, and Gly-142 and -144, respectively, were constructed to test further the stringency of these three positions.(ABSTRACT TRUNCATED AT 250 WORDS)

Aging and dietary modulation of elastase and interleukin-1 beta secretion

Aging is associated with diminished immune function that may stem from alterations in arachidonic acid metabolism and lipid peroxidation. This study sought to determine if dietary modification of fatty acids influenced neutrophil and monocyte secretion after an in vivo inflammatory stress in older human subjects. Volunteers participated in protocols that forced their quadriceps muscles to lengthen during tension development (eccentric stress). These protocols can cause inflammatory foci in the muscle as well as alterations in circulating leukocyte function. In this study, in vivo neutrophil degranulation was assessed by plasma elastase concentrations, and mononuclear cell function was assessed by interleukin-1 beta (IL-1 beta) secretion in vitro. In response to eccentric stress, older subjects (> 60 yr old) taking a placebo had no apparent elastase response, whereas those taking fish oil supplements responded with a 142% increase in plasma elastase (P = 0.011), similar to responses of younger reference subjects (< 33 yr old) taking no supplement. Overall, elastase responses correlated with individual plasma arachidonic acid-to-eicosapentaenoic acid ratios (r = -0.881, P = 0.004). Thus apparent age-related differences in elastase release were reconciled by individual differences in fatty acid nutriture. No significant temporal changes in urinary lipid peroxide excretion or IL-1 beta secretion were observed; however, age-associated differences were found.

T cell cytokine responses in persons with tuberculosis and human immunodeficiency virus infection

Tuberculosis causes more extensive and life-threatening disease in patients with HIV infection than in immunocompetent persons. To investigate the hypothesis that these severe manifestations of tuberculosis may be due to alterations in cytokine production, we evaluated cytokine patterns in HIV-infected tuberculosis patients. Upon stimulation with Mycobacterium tuberculosis in vitro, PBMC from HIV-infected tuberculosis patients had reduced proliferative and type 1 responses, compared with HIV-seronegative tuberculosis patients. The reduction in proliferative responses was independent of the CD4 cell count, but the reduced type 1 response was a direct result of CD4 cell depletion. There was no enhancement of type 2 cytokine production in HIV-infected patients, although production of IL-10 was prominent in all tuberculosis patients. In HIV-infected tuberculosis patients, M. tuberculosis-induced proliferative responses were significantly enhanced by neutralizing antibodies to IL-10 but not by antibodies to IL-4 or by recombinant IL-12. The M. tuberculosis-induced type 1 response was augmented both by antibodies to IL-10 and by recombinant IL-12. Tuberculosis in the context of HIV infection is characterized by diminished type 1 responses, probably induced by immunosuppressive cytokines produced by macrophages/monocytes, rather than by type 2 cells.

Studies of one invasive and two noninvasive methods for detection of bacterial contamination of platelet concentrates

Recently, a new method for noninvasive detection of bacterial contamination of platelet concentrates was described [Arpi et al.: Vox Sang 1993;65:335-336]. A CO2-sensitive label is applied on the outer surface of the plastic container of the platelet concentrate. When any contaminating bacteria have increased the pCO2 to a certain level the label changes color, indicating bacterial growth. We have studied this technique and applied such sensitive labels both directly onto PCs and onto plastic bags with culture medium into which platelet contents have been transferred. However, in both cases the sensitivity of the technique was found insufficient for practical quality control of PCs. There seem to be two problems with this principle: (1) platelets produce CO2 and (2) a considerable amount of the gas passes beside the detection label, in this way decreasing the sensitivity of detection by the label. This noninvasive technique was compared with an invasive method using automated bacterial culture, which was found sensitive and rapid.

Unscheduled expression of cyclin B1 and cyclin E in several leukemic and solid tumor cell lines

Normal, nontumorous cells express cyclin proteins in an orderly, scheduled fashion, at a given phase of the cell cycle. Thus, cyclin B1 is synthesized during G2 and abruptly degraded during mitosis. The onset of cyclin E synthesis takes place in mid-G1, its maximal expression is at the time of cell entrance to S, and its degradation occurs during cell progression through S phase. In the present study, multiparameter flow cytometry was used to correlate expression of cyclin B1 or cyclin E with cell cycle position (estimated by cellular DNA content) in normal human proliferating lymphocytes as well as in T-cell MOLT-4 leukemia; promyelocytic HL-60 leukemia; histiocytic U937 lymphoma; MCF-7, T-47D, and Hs 587T breast carcinoma; Colo 320DM colon carcinoma; and the T-24 transitional cell carcinoma cell line. The scheduled expression of both cyclins, namely of cyclin B1 restricted to G2 + M cells and of cyclin E restricted to late G1 and early S cells, was observed only in normal lymphocytes and MOLT-4 cells. The cells of HL-60, U937, T-47D, and Hs 587T lines expressed both cyclins in an unscheduled ("ectopic") fashion, i.e., unrelated to cell cycle position. Colo 320DM cells showed unscheduled expression of cyclin E (i.e., during G2) but expression of cyclin B1 in this line was generally restricted to G2 + M cells. There were relatively few (10-12%) cells in MCF-7 and T-24 cell lines that expressed cyclin B1 or E in an unscheduled manner. It may be expected that the unscheduled expression of cyclins in tumor cells may lead to a loss of the regulatory mechanisms of cell cycle progression and that such feature of the tumor may be of prognostic value. There is a need, therefore, to conduct similar studies in primary tumor cells.

Staurosporine blocks cell progression through G1 between the cyclin D and cyclin E restriction points

The protein kinase inhibitor staurosporine (SSP) stops progression of normal nontransformed cells in the G1 phase of the cell cycle. This implies that at least one of the cell cycle associated kinases, essential for cell transit through G1, is sensitive to SSP. Using multivariate flow cytometry to correlate the expression of cyclin E or cyclin D with cellular DNA content (i.e., cell cycle position), we have presently characterized the point of action of SSP in relation to the expression of these cyclins. During stimulation of normal human lymphocytes by phytohemagglutinin, cyclin D was expressed early, peaking at 8-14 h, while cyclin E appeared later, reaching a maximum at the time of cell entrance to S phase (24 h). Addition of SSP at the time of cell stimulation, while markedly suppressing the expression of cyclin E, had a rather modest effect on the expression of cyclin D. The data indicate that the SSP sensitive kinase(s) involved in cell progression through G1 operate beyond the restriction point of cyclin D but prior to that of cyclin E. Thus, the target(s) of SSP is (are) either the p33cdk/cyclin E complex itself or other protein kinase(s), activated subsequent to the cyclin D but prior to the cyclin E restriction point, the activity of which is essential for cell transit through G1.

A selective procedure for DNA extraction from apoptotic cells applicable for gel electrophoresis and flow cytometry

In cells undergoing apoptosis (programmed cell death), a fraction of nuclear DNA is fragmented to the size equivalent of DNA in mono- or oligonucleosomes. When such DNA is analyzed by agarose gel electrophoresis it generates the characteristic "ladder" pattern of discontinuous DNA fragments. Such a pattern of DNA degradation generally serves as a marker of the apoptotic mode of cell death. We developed a simple, rapid, and selective procedure for extraction of the degraded, low-molecular-weight DNA from apoptotic cells. The cells are prefixed in 70% ethanol, DNA is extracted with 0.2 M phosphate-citrate buffer at pH 7.8, and the extract is sequentially treated with RNase A and proteinase K and then subjected to electrophoresis. The ladder pattern was detected from DNA extracted from 1-2 x 10(6) HL-60 cells, of which as few as 8% were apoptotic, by flow cytometric criteria, as well as from blood and bone marrow samples from leukemic patients undergoing chemotherapy. The method is rapid and uses nontoxic reagents (no phenol, chloroform, etc.). This approach permits the analysis of DNA extracted from the very same cell population that is subjected to measurements by flow cytometry to estimate DNA ploidy, the cell cycle distribution of nonapoptotic cells, the percentage of apoptotic cells, or other parameters. Furthermore, the cells may be stored in 70% ethanol for at least several weeks before analysis without any significant DNA degradation. Treatment with ethanol also inactivates several pathogens, thereby increasing the safety of sample handling. The method is applicable to clinical samples, which can be fixed in ethanol and then stored and/or safety transported prior to analysis.