MEASUREMENT OF THE KINETIC STATUS OF BONE MARROW PRECURSOR CELLS: THREE CAUTIONARY TALES

Measurements to determine the kinetic status of the morphologically unrecognizable haemopoietic precursor cells in the bone marrow are frequently carried out using techniques which inhibit or destroy cells in the DNA-synthetic (S) phase of the cell cycle. For example, tritiated thymidine (³H-TdR) has for many years been recognized as a highly specific label for DNA synthesis and, as such, administration of large doses of ³H-TdR has often been used, both in vitro and in vivo, to kill cells in S. Assay of the surviving cells has then given a measure of the proportion of the total cells which are in the S-phase of the generation cycle. Other compounds which have been used for the same purpose are: ¹²⁵Iodo-deoxyuridine (¹²⁵I-UdR), another S-phase specific label, or hydroxyurea (HU) which prevents entry of cells into S and inhibits or kills cells already in S (Sinclair, 1965). For a variety of reasons, different laboratories tend to make different choices of the agent to be used for this purpose. As a result, it has sometimes proved difficult to marry data obtained from different sources. In the course of using ³H-TdR, tritiated uridine (³H-Ur), ¹²⁵I-UdR and HU in attempts toevaluate the kinetic status of bone marrow stem cells, it has become clear that their use is not straightforward and this paper presents data which illustrate some of the pitfalls associated with their use.     

CELL LOSS FROM SEVERAL TYPES OF SOLID MURTNE TUMOUR: COMPARISON OF 125I-IODODEOXYURIDINE AND TRITIATED THYMIDINE METHODS

The method of measuring tumour cell loss rates in situ following radioactivity loss after a single injection of ¹²⁵I-iododeoxyurudine (¹²⁵I-UdR) was tested for its accuracy in five different types of murine tumour. To achieve this the method was compared with two others: (1) using ¹²⁵I-UdR, but excising tumours before the radioactivity determinations, with or without extracting DNA; (2) using tritiated thymidine and autoradiography. A third method was used on three of the tumours, in which ¹²⁵I-UdR-labelled tumours were grown in unlabelled hosts, followed by whole body counting of the tumour-bearing mice. In two of the tumours an increase was observed in total tumour radioactivity with time after ¹²⁵I-UdR injection. This prevented the estimation of cell loss parameters in these tumours. Approximately half the increase was due to reutilization of ¹²⁵I-UdR supplied from tissues within the mouse; approximately a third to an influx of labelled inflammatory cells (probably in response to infection accompanying ulceration of overlying skin); and the remainder to an increase in non-DNA radioactivity. In these tumours cell loss rates could be obtained from the whole body counting technique in which influxes of labelled cells and reutilizable radioactivity were eliminated. A comparison of either ¹²⁵I-UdR technique with the ³H-TdR technique showed good agreement of the cell loss factors for the low cell loss tumours. However, for tumours with high cell loss factors the ¹²⁵I-UdR technique gave lower values for cell loss. This implied that reutilization of ¹²⁵I-UdR within the tumour (i.e. from internal, not external sources) occurred in the high cell loss tumours. It is concluded that equating radioactivity loss with cell loss after an injection of ¹²⁵I-UdR is reasonable for some tumours, but will result in significant underestimates in others. For high cell loss tumours the ³H-TdR technique will give the     

STUDY OF CELL DEATH IN FRIEND LEUKAEMIA

Cell death of splenic Friend leukaemic cells has been studied in vivo, using ¹²⁵I-UdR and ³H-TdR pulse labelling. The evolution of the splenic specific activity has been measured by autoradiography and external counting during 40 hr after injection of the labelled precursor. These two techniques show the existence of a large reutilization of ³H-TdR (50%), which is measurable as soon as 7 hr after the injection. The DNA turnover rate is rapid, 83-8 % of the splenic cellular DNA being renewed per day. These results confirm that most of the cells produced in the Friend leukaemic spleen are rapidly lost; they also demonstrate that this cell loss is mainly due to a massive death, which occurs in proerythroblastic and erythroblastic compartments after one or two cell divisions. Friend leukaemic cells, which are characterized by a limited capacity of proliferation and a short lifespan, do not appear to be malignant.     

POLYMETHACRYLIC ACID: INDUCTION OF LYMPHOCYTOSIS AND TISSUE DISTRIBUTION

Polymethacrylic acid (PMAA) induces up to a three-fold increase in the lymphocyte population of peripheral blood in rats, goats and calves after intravenous administration. Other routes of administration are less effective. A maximum lymphocytosis is achieved after 3 hr with all doses in excess of 30 mg PMAA/kg body weight; over the next few hours the lymphocyte level declines to normal. Granulocytes increase steadily for the first 7 hr before declining. Multiple doses of PMAA 2 hr apart failed to maintain or significantly alter the lymphocytosis. PMAA was labelled with ¹²⁵I and ¹⁴C, and was traced to various sites in the rat. The greatest accumulation of radioactivity was in the spleen, lungs, liver, kidney, adrenals and mesenteric lymph nodes (with ¹⁴C-PMAA). The accumulation appeared more specific for spleen and lymph nodes since there was only a small loss of activity following removal of blood by whole body perfusion. This supports previous findings indicating that these two tissues play a major role in the development of lymphocytosis. Accumulation in the bone marrow may be indicative of stem cell mobilization. The results are discussed in terms of the lymphocytosis-inducing mechanism and the site of action of PMAA and the possible clinical application to ECIB therapy is considered.     

KINETICS OF ERYTHROPOIETIN STIMULATED PROLIFERATION OF ERYTHROID PROGENITORS IN THE SPLEEN

The effect of RBC transfusion and erythropoietin (EPO) on the proliferation of immature erythrocyte progenitors was studied in the spleens of RBC transfused, lethally irradiated mice injected with bone marrow. Transfusion decreased expansion of the progenitors and slowed their proliferation: the mean cycle time as measured by per cent labelled mitosis (PLM) on the third day after injection of bone marrow was 10.7 hr in transfused as compared to 5.6 hr in non-transfused mice. One injection of five units of erythropoietin on day 2 decreased the mean cycle time to 7.3 hr in transfused mice and increased expansion of the progenitor cells. The effects of erythropoietin on cell proliferation were prompt: a significant increase of incorporation of ³H-TdR into DNA occurred within 2 hr of injection. Erythroblasts were absent from the spleens of transfused, irradiated bone marrow injected mice; however, erythroblasts appeared by 72 hr and 48 hr following EPO injection either 2 days or 5 days after transplantation respectively. Increased uptake of radioactive iron in spleen after erythropoietin injection preceded the appearance of erythroblasts by 2 and 1 days when erythropoietin was injected either 2 or 5 days after marrow transplantation respectively. The increase in cellular proliferation induced by erythropoietin in transfused irradiated mice injected with bone marrow equivalent to 0.35 femoral shaft was manifested as an increase of the total DNA content in the spleen by 119 μg (11.9 × 10⁶ cells) within 48 hr of injection. The cellular increment produced by EPO injection on day 5 to mice given 0.05 femoral shaft consisted mainly of undifferentiated mononuclear cells, most of which were labelled, with erythroblasts comprising only one quarter of the increment. Erythropoietin inactivated by mild acid hydrolysis failed to increase cellular proliferation.     

A TECHNIQUE FOR DETERMINING THE PROPORTION OF THE CLONOGENIC CELLS IN S PHASE IN EMT6 CELL CULTURES AND TUMORS

The survival of cultured EMT6 cells was examined after treatment with hydroxyurea (HU) or high specific activity tritiated thymidine (³H-TdR). The concentrations of the agents, duration of exposure to the agents, and post-exposure treatment of the cultures were found to influence the cell survival; the effects of these factors are reported. Conditions were defined under which the proportions of cells killed by HU and by ³H-TdR were the same and were also the same as the proportion of labeled cells seen on autoradiographs of cultures labeled with small doses of ³H-TdR. Under these conditions, either ³H-TdR or HU could be used to determine the proportion of the clonogenic cells in S phase. Single cell suspensions prepared from solid EMT6 tumors were treated in vitro with HU or ³H-TdR, using the conditions found optimal for each agent with cultured cells. The proportion of the tumor cells killed by treatment with HU in vitro was the same as the proportion killed by HU in vivo and as the proportion labeled by ³H-TdR in vivo, and incubation of tumor cell suspensions with HU in vitro appeared to provide a valid measurement of the proportion of clonogenic tumor cells in S phase. Incubation of tumor cell suspensions with ³H-TdR in vitro proved difficult to perform and the results were relatively unreliable because of severe problems with reutilization of ³H-TdR during the incubation for colony formation.     

FATE OF THYMOCYTES: STUDIES WITH 125I-IODODEOXYURIDINE AND 3H-THYMIDINE IN MICE

Cortical thymocytes of young adult mice were labeled in situ with radioactive DNA precursors. As a result of cell emigration and cell death, total thymic radioactivity decreased within 8 days to 10% or less of that present on day 1. Accumulation of thymic migrants in peripheral lymphoid organs was estimated by computing the net thymus-derived radioactivity in these tissues. Thymic cell death was assessed by comparing values obtained with ¹²⁵I-UdR to those acquired with ³H-TdR. The results indicate that cortical thymocytes migrate to the spleen, mesenteric lymph node, femurs and intestine; nevertheless, only a small fraction of the activity originally present in the thymus was recovered in these organs; the vast majority of newly formed cortical thymocytes apparently die after a relatively short life span. Exclusive of the fraction which dies in situ, evidence for thymocyte death is seen in bone marrow; however, most migrants appear to terminate in the intestine.     

The Effect of X-Irradiation On Cell Loss In Five Solid Murine Tumours, As Determined By the 125Iudr Method

The rate of cell loss in irradiated RIF-1, EMT6, KHJJ, B16 and KHT tumours was studied using the ¹²⁵IUdR loss technique. Administration of ¹²⁵IUdR preceded localized tumour irradiation by 2 days. Loss of tumour radioactivity was measured for 6–8 days after irradiation. the blood flow to some tumours was occluded during, and for 30 min following, injection of the label to measure the amount of radioactivity entering the tumour as a result of reutilization of label from the gut epithelia and influx of labelled host cells. Irradiation did not significantly alter the amount of radioactivity entering these clamped tumours during the 8–10 days after injection of ¹²⁵IUdR. This permitted comparison of irradiated and control groups based on the loss of radioactivity from the non-occluded tumours. Irradiation of RIF-1, EMT6, KHJJ or B16 tumours with doses of 600, 1400, 2400 or 4400 rads produced no significant increase in the rate of loss of tumour radioactivity. This suggested that, in the population of labelled cells, cell lysis following irradiation proceeded slowly. In contrast, KHT tumours showed a significant increase in loss rate following each radiation dose, although the increase was dose-independent. In all tumour systems, the constant rate of cell loss after radiation appeared to coincide with published reports of tumour growth responses after irradiation. the present data suggest that the manner of expression of radiation-induced cell killing results from the cellular proliferative status, i.e. whether a cell is cycling or non-cycling.     

Bone Marrow Response to Damage Induced By Hydroxyurea Or Colchicine

The extent of bone marrow damage caused by the administration of single or repeated doses of either hydroxyurea (1000 mg/kg b.w.) or colchicine (1 mg/kg b.w.) are comparable. This conclusion is based on serial studies of bone marrow cellularity and of the CFUc numbers in the bone marrow. the proliferation response of the pluripotential haemopoietic stem cells, determined by the cells forming colonies in the spleen of lethally irradiated mice (CFUs) markedly differs if the bone marrow damage is caused by hydroxyurea or colchicine. While hydroxyurea administration stimulates a large proportion of the resting G₀ cells into the cell cycle, the damage induced by colchicine is followed by only a mild increase in the CFUs proliferation rate. The seeding efficiency of the spleen colony technique has been determined after both hydroxyurea and colchicine administration. This parameter, important for the estimation of the number of the pluripotential haemopoietic stem cells in blood forming organs, is significantly affected by hydroxyurea administration, but also by repeated injections of colchicine. Following a single dose of hydroxyurea, the time-course of the CFUs numbers, which were corrected for the change in the seeding efficiency, shows an overshoot occurring after 18–20 hr. At the other time periods, the number of pluripotential haemopoietic stem cells is little affected by a single hydroxyurea injection. This poses a question about the nature of the stimulus, which after hydroxyurea administration triggers the CFUs from the resting G₀ state into the cell cycle. There is evidence that this stimulus is probably not represented by the damage caused to the various intensively proliferating cell populations of the bone marrow. This evidence is based on experiments which show that colchicine induced damage, of a degree similar to that after hydroxyurea, does not stimulate the CFUs proliferation rate to an extent comparable to hydroxyurea. The possibility that colchicine could block CFUs in the G₀ state or that it could interfere with the progress of CFUs through the G₁ and S phases of the cell cycle have been ruled out by experiments which demonstrated that colchicine (1 mg/kg b.w.), administered 10 min before hydroxyurea, does not reduce the number of CFUs triggered into the cell cycle as the consequence of hydroxyurea administration.     

MIGRATION OF SMALL LYMPHOCYTES IN ADULT MICE DEMONSTRATED BY PARABIOSIS

Parabiotic BALB/C mice were used to study the traffic of small lymphocytes in immunological mature but unchallenged mice. By giving ³H-thymidine (³H-TdR) injections to only one member (A) of a pair by preventing the escape of the radioactive isotope to the other member (B), the kinetics of newly-formed cells was followed. Less than 10% labelled small lymphocytes were found in the peripheral lymphoid tissues of both A and B members, while the thymusses and bone marrows of A members showed labelling percentages up to 70% in this period. Hardly any labelled cells gained entrance into the thymus while a detectable number was found in the bone marrows of B members. Results from pairs set up to follow migration of long-lived lymphocytes revealed that labelled cells detected 4–5 weeks after injections were equilibrated between the peripheral tissues and the bone marrows of the partners. Very few labelled cells were seen in the thymic medulla and none were observed in the thymic cortex, germinal centres or medullary cords of lymph nodes from any B member. It was concluded that short-lived small lymphocytes are formed primarily in the thymus and bone marrow and the migration of these cells is limited in adult animals. Furthermore, the vast majority of long-lived small lymphocytes are freely recirculating, and these cells gain entrance to and are normal residents in the bone marrow.     

DIFFERENCES IN REUTILIZATION OF THYMIDINE IN HEMOPOIETIC AND LYMPHOPOIETIC TISSUES OF THE NORMAL MOUSE

Swiss Albino mice received a single i.v. injection of ³H-thymidine (TdR) or of ¹²⁵I-deoxyuridine (IUdR). Bone marrow, thymus, spleen and mesenteric lymph node were examined for the efficiency of precursor incorporation into DNA, and for DNA renewal from day 1 to day 8.
TdR is 5–8 times more efficiently incorporated by the different organs in vivo and in vitro than is IUdR. This indicates that the discrimination against IUdR occurs at the level of DNA synthesizing cells.
A diminished DNA turnover rate measured with ³H-TdR in comparison with ¹²⁵I-UdR is interpreted to indicate reutilization of TdR.
TdR reutilization was observed in bone marrow and spleen from at least day 1 on, and in the thymus from day 3 on, following pulse labeling of DNA synthesizing cells. The degree of TdR reutilization appears higher in the thymus (67%) than the bone marrow (43%) and spleen (38%). The mesenteric lymph node indicates either no, or a very low efficiency of TdR reutilization. The data are also consistent with a reutilization equally efficient for TdR and IUdR.
It is suggested that the TdR salvage pathway in hemopoietic tissues is largely localized to single organs which have immediate access to TdR made available by catabolism of DNA. The contribution of TdR from systemic reutilization to the organs studied falls within the limits of error of measurements. Moreover, the TdR salvage pathway especially in the lymph node may involve other DNA breakdown products than nucleosides.     

THE ROLE OF ERYTHROPOIETIN IN REGULATION OF POPULATION SIZE AND CELL CYCLING OF EARLY AND LATE ERYTHROID PRECURSORS IN MOUSE BONE MARROW

This study was designed to determine the stage in haemopoietic cell differentiation from multipotential stem cells at which erythropoietin becomes physiologically important. The responses of haemopoietic precursor cells were monitored in the bone marrow of mice under conditions of high (after bleeding) and low (after hypertransfusion) ambient erythropoietin levels. The number of relatively mature erythroid precursors (CFU-E), detected by erythroid colony formation after 2 days of culture, increased three-fold in marrow by the fourth day after bleeding, and decreased three-fold after hypertransfusion. Assessed by sensitivity to killing by a brief exposure to tritiated thymidine (³H-TdR) in vitro, the proliferative activity of CFU-E was high (75% kill) in untreated and bled animals, and was slightly lower (60% kill) after hypertransfusion. The responses of more primitive erythroid progenitors (BFU-E), detected by erythroid colony formation after 10 days in culture, presented a contrasting pattern. After hypertransfusion they increased slightly, while little change was noted until the fourth day after bleeding, when they decreased in the marrow. The same response pattern was observed for the progenitors (CFU-C) detected by granulocyte/macrophage colony formation in culture. The sensitivity of BFU-E to ³H-TdR was normally 30%, and neither increased after bleeding nor decreased after hypertransfusion. However, in regenerating marrow the ³H-TdR sensitivity of BFU-E increased to 63%, and this increase was not affected by hypertransfusion. These results are interpreted as indicating (1) that physiological levels of erythropoietin do not influence the decision by multipotential haemopoietic stem cells to differentiate along the erythroid pathway as opposed to the granulocyte/macrophage pathway; (2) that early erythroid-committed progenitors themselves do not respond to these levels of erythropoietin, but rather are subject to regulation by erythropoietin-independent mechanisms; and (3) that physiological regulation by erythropoietin commences in cells at a stage of maturation intermediate between BFU-E and CFU-E.     

Validation of bromodeoxyuridine immunohistochemistry for localization of S-phase cells in decalcified tissues. A comparative study with tritiated thymidine autoradiography

Summary Immunohistochemical detection of the thymidine analogue 5-bromo-2-deoxyuridine (BrdUrd), which is incorporated by S-phase cells, offers a convenient way of studying the proliferation kinetics of cells in normal skeletal tissues and in bone containing/derived tumours. To assess the validity of using this approach on decalcified, paraffin embedded tissues, the BrdUrd method was compared with tritiated thymidine (³H-TdR) autoradiography, using rat tibiae labelled with both³H-TdR and BrdUrd, fixed in Carnoy's fluid and decalcified in EDTA, prior to routine paraffin embedding. The distribution of BrdUrd-labelled cells correlated with the sites of cell proliferation in the growing rat tibia.Independent studies with each method on paired serial sections of double-labelled tissue, showed a highly significant correlation (r=0.81, p<0.0003) in the numbers of labelled cells seen in autoradiographs and immunostained sections from the proximal tibial growth plate. Combined BrdUrd immunohistochemistry and³H-TdR autoradiography showed that the majority of labelled cells in cartilage, bone marrow, and fibrous perichondrium and periosteum had incorporated both labels. These results show that BrdUrd immunohistochemistry is a valid technique for the study of dividing cells in mineralized tissues after decalcification.     

Disposition of fucose in brain

Abstract— Labelled fucose administered to rats in vivo was rapidly incorporated into brain glycoproteins, but not into any other brain constituents, including glycolipids and acid mucopolysaccharides. Maximum incorporation of tritium-labelled fucose into brain glyco-proteins occurred 3–6 h after intraperitoneal injection in young or adult rats, and the half-time for the turnover of glycoprotein-fucose in young rats was approximately 2 weeks. Within 3 h after the administration of either [1-³H]fucose or fucose generally labelled with tritium, 75 per cent of the total acid-soluble radioactivity in plasma and brain was found to be volatile, and by 24 h after injection more than 90 per cent of the acid-soluble radioactivity was volatile. The tritium in labelled fiicose appears to undergo arapid exchange reaction with hydrogen atoms in body water, although the tritium in fucose glycosidically- linked to glycoproteins is biologically stable. The rapid disappearance of labelled free fucose from the plasma and tissues of the rat precludes the possibility of any significant degree of reutilization of labelled precursor, and provides support for other data indicating that the turnover of fucose in brain glycoproteins is relatively slow in comparison to that of hexosamine and sialic acid. Activities of α-L-fucosidase in rat brain, with pH optima at 40 and 6.0, had essentially the same K_m (4 × 10^?4 M and 3.2 × 10^?4 M, respectively) with p-nitrophenyl-α-L-fucopyranoside as substrate. Activities of both were competitively inhibited by L-fucose. However, the K_t measured at pH 4 (1.9 × 10^?2) was almost ten times greater than that measured at pH 6 (1.5 × 10^?4).     

Study of cell death in Friend leukaemia.

Cell death of splenic Friend leukaemic cells has been studied in vivo, using 125I-UdR and 3H-TdR pulse labelling. The evolution of the splenic specific activity has been measured by autoradiography and external counting during 40 hr after injection of the labelled precursor. These two techniques show the existence of a large reutilization of 3H-TdR (50%), which is measurable as soon as 7 hr after the injection. The DNA turnover rate is rapid, 83-8% of the splenic cellular DNA being renewed per day. Those results confirm that most of the cells produced in the Friend leukaemic spleen are rapidly lost; they also demonstrate that this cell loss is mainly due to a massive death, which occurs in proerythroblastic and erythroblastic compartments after one or two cell divisions. Friend leukaemic cells, which are characterized by a limited capacity of proliferation and a short lifespan, do not appear to be malignant.     

THYMIDINE SUICIDE IN VIVO AND IN VITRO OF SPLEEN COLONY FORMING AND AGAR COLONY FORMING CELLS OF MOUSE BONE MARROW

The ‘thymidine suicide’technique for indicating differences in the proliferation rate of early haemopoietic progenitor cells (spleen colony forming and agar colony forming cells) in C57BL mice has been evaluated. Special care was taken to use the same bone marrow cell suspension for the two progenitor cell assays. Both the in vivo and the in vitro techniques were employed. Following ³H-TdR in vivo, about 20% of both types of progenitor cell are killed in normal mice; however, after incubation in vitro with ³H-TdR, 35% of agar colony forming cells but only 4% of spleen colony forming cells are killed. Reasons for the difference between the in vivo and the in vitro results are discussed. With bone marrow from continuously irradiated animals, the thymidine suicide for both agar colony forming and spleen colony forming cells is in the range 42–50%, and there is no difference between in vivo and in vitro suicide. The in vivo results support the conclusion, based on the effect of proliferation dependent cytotoxic agents, that in C57BL mice agar colony forming and spleen colony forming cells are proliferating at the same rate in normal animals, and are speeded up to the same extent by continuous γ-irradiation. It is considered that in normal C57BL mice the in vitro method does not give a correct estimate of the proliferation rate of these progenitor cells. It would seem that the similarity in the proliferation rate of agar colony forming and spleen colony forming cells in C57BL mice is not true for other strains of mice: indeed using normal CBA and in vivo suicide, we have shown a significantly greater thymidine suicide for agar colony forming cells compared to spleen colony forming cells.     

PROLIFERATION OF ERYTHROID AND GRANULOCYTE PROGENITORS IN THE SPLEEN AS A FUNCTION OF STEM CELL DOSE

A study of the kinetics of cellular proliferation, in the morphologically unrecognizable haemopoietic progenitor cell compartment, as a function of injected CFU-S dose has been carried out in the spleens of lethally X-irradiated mice using ³H-TdR labelling. Amplification in this proliferating cell compartment was observed to decline as CFU-S dose increased. The number of divisions in the differentiated line arising from CFU-S up to the first appearance of recognizable erythroid precursors were calculated to be 9.2, 12.5, 15 and 17 for the 2, 0.35, 0.05 and 0.007 femur equivalent doses respectively. The growth of cell populations arising from CFU-S was biphasic, with a rapid initial phase having a doubling time of about 6.3 hr, and a slow phase of doubling time around 1 day. Analysis of the rapid phase by the FLM method gave a cycle time of 5.6 hr. Recognizable labelled erythroid precursors were detected at the same time as, or just after, the change in slope of the growth curve. Significant numbers of proliferating (labelled) granulocytes only appeared in the spleens of animals receiving the higher marrow doses (2 and 0.35 femur). The erythroid to granulocyte ratio was also a decreasing function of marrow dose.     

Rapidly metabolized glycoproteins in a neuroplastoma cell line

The metabolism of neuroblastoma cell glycoproteins was examined using l-[³H]fucose. Incubation of monolayer cultures with [³H]fucose resulted in a rapid uptake of the radioactive precursor and its incorporation into acid-insoluble macromolecules. Less than 3% of the [³H]fucose that was isolated from neuroblastoma cells by trichloroacetic acid precipitation was associated with glycolipids. The metabolism of fucosylated macromolecules was studied in cells which were labelled to a steady state, and then reincubated under conditions which limited reutilization of the radioactive precursor (40 mM unlabelled fucose). During reincubation of the cells, we observed a rapid metabolism (27% by 2 h)_ of the prelabelled macromolecules which stabilized within a cell generation time to give an overall rate of turnover of 9%. This rapid loss of radioactivity from the cells was not due to exocytosis since less than 4% of the [³H]-fucose was lost into the media as macromolecules during a 5 h reincubation period. The presence of 40 mM fucose in the media did not affect cell growth until after 24 h of incubation or cellular synthesis until after 15 h of incubation. When the metabolism of neuroblastoma cell glycoproteins was measured in the presence of 1.8 · 10^?4 M cycloheximide, there appeared to be a less rapid decrease in cell-associated specific activity, and an increased reutilization of [³H]fucose. Although the major proportion of the radioactivity remained as [³H]fucose, extensive incubation of neuroblastoma cells with this radioactive precursor led to increased amounts of tritium associated with other cellular components. However, a rapid rate of glycoprotein metabolism could also be demonstrated with cells incubated with [⁴C]fucose. This eliminated the possibility that the above results were restricted to the tritiated precursor and merely a reflection of hydrogen-tritium exchange.     

Plasma clearance and endocytosis of mitochondrial malate dehydrogenase in the rat.

1. Pig mitochondrial malate dehydrogenase was labelled with 125I and intravenously injected into rats. Enzyme activity and radioactivity were cleared from plasma identically, with first-order kinetics, with a half-life of only 7 min. 2. Radioactivity accumulated in liver, spleen, bone (marrow) and kidneys, reaching maxima of 3 1, 4, 6 and 9% of the injected dose respectively, at 10 min after injection. 3. Our data allow us to calculate that in the long run 59, 5, 11 and 13% of the injected dose is taken up and subsequently broken down by liver, spleen, bone and kidneys respectively. 4. Differential fractionation of liver showed that the acid-precipitable radioactivity was mainly present in the lysosomal and microsomal fractions, suggesting that the endocytosed protein is transported via endosomes to lysosomes, where it is degraded. 5. Radioautography of liver and spleen suggested that the labelled protein was taken up by macrophages of the reticuloendothelial system. 6. Mitochondrial malate dehydrogenase is probably internalized in liver, spleen and bone marrow by adsorptive endocytosis, since uptake of the enzyme of these tissues is saturable.     

CELL LOSS AND INFLUX OF LABELED HOST CELLS IN THREE TRANSPLANTABLE MOUSE TUMORS USING [125I]UdR RELEASE

The [¹²⁵I]UdR loss technique was used to estimate cell loss from RIF-1, EMT6 and KHJJ tumors in order to determine the length of the delay between labeling and the beginning of the loss of labeled cells, and also to calculate a value for ø, the cell loss factor. To determine the importance of reutilization of label released from the gut and/or the influx of labeled host cells, the blood flow to some tumors was occluded during and for 30 min after injection of the label. Relatively small amounts of radioactivity entered occluded RIF-1 tumors during 9 days after injection of [¹²⁵I]UdR, indicating that reutilization of systemic label and influx of labeled host cells are not significant in this system. In contrast, substantial amounts of radioactivity entered occluded EMT6 and KHJJ tumors, reaching 40% of the total activity in non-occluded tumors during 6 days following injection. After corrections were made for this influx of label, the [¹²⁵I]UdR loss curves from RIF-1 and EMT6 tumors were essentially exponential from the first day following injection of label. This was interpreted as indicating the loss of proliferating as well as non-proliferating cells from both tumors. The cell loss factor derived from the [¹²⁵I]UdR loss curves corrected for influx appeared to agree well with published values derived from analysis of percent labeled mitoses curves. In contrast, the corrected [¹²⁵I]UdR loss curves from KHJJ tumors showed that loss of activity began three days after injection of label, indicating that primarily nonproliferating cells are lost from this tumor.