Degradation of nicotinamide adenine dinucleotide in cell suspension cultures

Metabolites of [carbonyl-¹⁴C]-NAD in cell suspension cultures of mung bean, soybean and garbanzo bean are trigonelline and compounds of the pyridine nucleotide cycle. Degradation of nicotinate does not occur. In parsley cell cultures nicotinate degradation and formation of nicotinic acid N-α-l-arabinoside were observed. These conjugates are alternative reservoir forms of nicotinic acid. The adenine moiety of NAD is degraded in cell cultures via hypoxanthine-xanthine-allantoin-allantoic acid, with accumulation of the latter two compounds.     

The fate of corticosterone and 11-deoxycorticosterone in C57BL/6 and BALB/c strains of mice: distribution and oxidative metabolism

The distribution kinetics and oxidative metabolism of [4-C14] corticosterone (B) and 11-deoxy-[1,2-3H] corticosterone (DOC) were compared in C57BL/6 (B6) and BALB/c (C) mice. Statistically important differences in the distribution of [14C]B and [3H]DOC occurred that were independent of strain, while other differences were strain dependent. Intestinal excretion of metabolites of B and DOC was greater in B6 mice than in C mice, and kidney excretion was greater in C mice than B6 mice. In both C and B6 mice, 3H was cleared from liver faster than 14C, with no strain differences. DOC metabolite levels exceeded B metabolite levels in small intestine and gall bladder of both strains. In most other organs, B metabolites exceeded DOC metabolites. Time average strain differences in accumulation of B and its metabolites favoring B6 were found in pancreas, brain, lung, heart, muscles, adrenals, spleen, mesentery and small intestine. Except for the organs of excretion, no strain differences were found for [3H]DOC metabolites. Sixty minutes after steroid administration, 45% of B metabolites and a third of DOC metabolites were 20-hydroxy-21-oic acids. In the intestine, accumulation of acids derived from either B or DOC was greater for B6 than C strain mice, reflecting the greater proportion of total steroid excreted in the B6 strain.     

Metabolism of cholecalciferol in land snails.

1. Radioactively labelled cholecalciferol was injected into the land snails Levantina hiersolyma and Theba pisana. Three metabolites (C, D and E), more polar than cholecalciferol, were found. 2. Metabolite C was found to be identical with 25-hydroxycholecalciferol. On injection of 25-hydroxy[26,27-3H]cholecalciferol, metabolite E was predominantly formed. Metabolite D was predominantly formed from cholecalciferol. Metabolites D and E differ from any known cholecalciferol metabolites. 3. The intestine was found to be the tissue capable of carrying out the transformation of 25-hydroxycholecalciferol into metabolite E. 4. 25-Hydroxycholecalciferol and metabolite E were localized in the digestive gland of the snail, the tissue responsible for the absorption of Ca2+ and its storage. Metabolite D was not localized in any specific tissue.     

Rapid hepatic metabolism of 7-ketocholesterol in vivo: implications for dietary oxysterols.

7-Ketocholesterol is a major dietary oxysterol and the predominant non-enzymically formed oxysterol in human atherosclerotic plaque. We tested the hypothesis that 7-ketocholesterol is preferentially retained by tissues relative to cholesterol in vivo. To ensure rapid tissue uptake, acetylated low density lipoprotein, labeled with esters of [(14)C]-7-ketocholesterol and [(3)H]cholesterol, was injected into rats via a jugular catheter. At timed intervals (2 min to 24 h) rats (n = 48 total) were exsanguinated and tissues were dissected and assayed for radioactivity. In two experiments the majority of both radiolabels appeared in the liver after 2 min. In all tissues, (14)C appeared transiently and did not accumulate. Rather, it was metabolized in the liver and excreted into the intestine mainly as aqueous-soluble metabolites (presumably bile acids). By 9 h, (14)C in the liver had decreased to 10% of the injected dose while 36% was present in the intestine. In contrast, at 9 h 38% of (3)H was evident in the liver while only 5% was found in the intestine. Unlike [(3)H]cholesterol, little (14)C was found to re-enter the circulation, indicating that enterohepatic recycling of 7-ketocholesterol was negligible.This is the first report of the distribution of an oxysterol relative to cholesterol, administered simultaneously, in a whole animal model. The finding that [(14)C]-7-ketocholesterol is rapidly metabolized and excreted by the liver suggests that diet may not be a major source of oxysterols in atherosclerotic plaque, and that perhaps dietary oxysterols make little or no contribution to atherogenesis.     

Cholinergic stimulation of arachidonic acid and phosphatidic acid metabolism in C62B glioma cells

Glioma C62B cells were incubated for 18 h with [1-14C]arachidonic acid. Most (80%) of the added [1-14C] arachidonic acid was taken into the intracellular pool; less than 1% of the intracellular [1-14C]arachidonic acid remained unesterified; the rest was present in glycerophospholipids. Acetylcholine stimulation of the prelabeled cells resulted in the rapid accumulation of free [1-14C]arachidonic acid, presumably liberated by hydrolysis from phospholipids. Labeled unesterified [1-14C]arachidonic acid peaked by 90 s and returned to basal levels by 5 min. Paralleling the transient increase of unesterified [1-14C]arachidonic acid were increases in level of radioactivity in an unidentified lipoxygenase metabolite of arachidonic acid and of radioactive phosphatidic acid. The release of arachidonic acid induced by acetylcholine or carbachol was blocked by muscarinic but not nicotinic receptor antagonists; adrenergic or histaminergic receptor agonists were ineffective at stimulating arachidonic acid liberation. In contrast to the transient effects of stimulation with cholinergic agonists, stimulation with the divalent cation ionophore A23187 resulted in a linear increase in the accumulation of liberated arachidonic acid for at least 1 h. Furthermore, the pattern of metabolites synthesized from arachidonic acid in response to ionophore stimulation was more complex than that observed following cholinergic stimulation and included also several metabolites derived from cyclooxygenase activity. We conclude that muscarinic receptor agonists rapidly induce specific changes in arachidonic acid and phosphatidic acid metabolism in a glioma cell line and suggest that similar responses may occur in glial cells and play a physiologically significant role in neural metabolism.     

Extrahepatic sites of metabolism of carbon tetrachloride in rats

Rats were injected i.v. and i.p. with [14C]carbon tetrachloride and the localization and binding of metabolites in the tissues were studied by autoradiography. Based on the autoradiographic findings, various tissues were tested for their capacity to form 14CO2 from [14C]carbon tetrachloride in vitro. Autoradiography in vitro was used to localize the sites of [14C]carbon tetrachloride metabolism under in vitro conditions. The results showed that several tissues accumulating metabolites in vivo had an ability to form 14CO2 in vitro, and accumulation of metabolites was observed also under the in vitro conditions. These results indicate that carbon tetrachloride is metabolized in many extrahepatic tissues in vivo. The structures identified to have a marked carbon tetrachloride-metabolizing capacity were, besides the liver, the mucosa of the bronchial tree, the tracheal mucosa, the olfactory and respiratory nasal mucosa, the oesophageal mucosa, the mucosa of the larynx, the tongue and the cheeks, the lateral nasal gland and the kidney cortex. It is well established that the degradation of carbon tetrachloride involves the cytochrome P-450 system, and the metabolism of the substance in the mentioned tissues is probably correlated to high concentrations of cytochrome P-450. The nasal olfactory mucosa was found to be the tissue with the highest capacity to form 14CO2 from the [14C]carbon tetrachloride and microautoradiography indicated that in this tissue the cells of the subepithelial glands of the lamina propria mucosae are most actively engaged in the metabolism. It was also shown that cytochrome P-450 is present in the nasal olfactory mucosa.     

Metabolism of sialic acids from exogenously administered sialyllactose and mucin in mouse and rat

A mixture of N-acetyl-[4,5,6,7,8,9-14C]neuraminosyl-alpha (2-3(6]-galactosyl-beta (1-4-glucose[( 14C]sialyl-lactose) and N-acetylneuraminosyl-alpha (2-3(6]-galactosyl-beta(1-4)-glucit-1-[3H]ol(sialyl-[3H]lactitol) as well as porcine submandibular gland mucin labeled with N-acetyl- and N-glycoloyl-[9-(3)H]neuraminic acid were administered orally to mice. The distribution of the different isotopes was followed in blood, tissues and excretion products of the animals. One half of the [14C]sialyl-lactose/sialyl-[3H]lactitol mixture given orally was excreted unchanged in the urine. The other half was hydrolysed by sialidase and partly metabolized further, followed by the excretion of 30% of the 14C-radioactivity as free N-acetyl-[4,5,6,7,8,9-14C]neuraminic acid and 60% of this radioactivity in the form of non-anionic compounds including expired 14CO2 within 24 h. The 14C-radioactivity derived from the [14C]sialyl-lactose/sialyl-[3H]lactitol mixture which remained in the bodies of fasted mice after 24 h was less than 1%. In the case of well-fed mice, a higher amount of the sialic acid residues was metabolized. The bulk of radioactivity of the mucin was resorbed within 24 h. About 40% of the radioactivity administered was excreted by the urine within 48 h; 30% of this radioactivity represented sialic acid and 70% other anionic and non-anionic metabolic products. 60% of the radioactivity administered remained in the body, and bound 3H-labeled sialic acids were isolated from liver. Sialyl-alpha (2-3)-[3H]lactitol was injected intravenously into rats; the substance was rapidly excreted in the urine without decomposition. These studies show that part of the sialic acids bound to oligosaccharides and glycoproteins can be hydrolysed in intestine by sialidase and be resorbed. This is followed either by excretion as free sialic acid or by metabolization at variable degrees, which apparently depends on the compound fed and on the retention time in the digestive tract.     

Biosynthesis of trigonelline from nicotinate mononucleotide in mungbean seedlings

To determine the biosynthetic pathway to trigonelline, the metabolism of [carboxyl-(14)C]nicotinate mononucleotide (NaMN) and [carboxyl-(14)C]nicotinate riboside (NaR) in protein extracts and tissues of embryonic axes from germinating mungbeans (Phaseolus aureus) was investigated. In crude cell-free protein extracts, in the presence of S-adenosyl-L-methionine, radioactivity from [(14)C]NaMN was incorporated into NaR, nicotinate and trigonelline. Activities of NaMN nucleotidase, NaR nucleosidase and trigonelline synthase were also observed in the extracts. Exogenously supplied [(14)C]NaR, taken up by embryonic axes segments, was readily converted to nicotinate and trigonelline. It is concluded that the NaMN-->NaR-->nicotinate-->trigonelline pathway is operative in the embryonic axes of mungbean seedlings. This result suggests that trigonelline is synthesised not only from NAD but also via the de novo biosynthetic pathway of pyridine nucleotides.     

The formation of radiolabeled N1- and N8-acetylspermidine in various rat organs following [14C]spermidine administration

To detect the in vivo formation of acetylspermidine, three female Sprague-Dawley rats were injected intravenously with 20 muCi of [14C]spermidine. Twenty-four hours after the injection of the radiolabel, the kidneys, liver, lungs, pancreas, small intestine, spleen, stomach and thymus were removed under Halothane anesthesia. High performance liquid chromatography (HPLC) of the pooled radiolabeled extracts from each tissue demonstrated the presence of a 14C-labeled material which co-chromatographed with an acetylspermidine standard. Thin layer chromatography (TLC) of the HPLC eluent demonstrated the presence of both radiolabeled N1- and N8-acetylspermidine in the tissues. Concentrations of labeled acetylspermidine ranged from 0.27 to 1.9% of the total tissue radiolabel. The N1-to N8-acetylspermidine ratio in tissues ranged from approx. 5 to 1 in the thymus to 1.5 to 1 in the liver.     

Studies on the distribution and metabolism of N-[14C]nitrosopyrrolidine in mice.

Pretreatments with pyrazole, ethanol, nialamide or diethyldithiocarbamate were found to strongly depress the exhalation of 14CO2 and the incorporation of radioactivity in the acid-insoluble fraction of the liver in mice injected with N-[14C]nitrosopyrrolidine. Whole-body autoradiography performed with hemisections of mice at -80 degrees C (to prevent evaporation of the volatile N-nitrosopyrrolidine) and with dry tape-sections (to localize the non-volatile metabolites), using pretreated and non-pretreated mice, indicated a uniform distribution of the non-metabolized N-nitrosopyrrolidine in the tissues. At the shortest survival intervals (1 and 5 min), a high level of metabolites were found in the liver, the tracheo-bronchial and nasal mucosa and Harder's gland, indicating a local formation of metabolits in these tissues. At later survival intervals (0.5--24 h) metabolites were in addition found in tissues with a rapid cell turnover and a high rate of protein synthesis and in brown fat, which probably reflects incorporation of metabolites via normal biosynthetic pathways. Autoradiography of N-[14C]nitrosopyrrolidine in mice given the substance orally resulted in distribution pictures similar to those obtained after i.v. injections.     

Time-course of utilization of [stearic or lignoceric acid]sphingomyelin from high-density lipoprotein by rat tissues

Utilization of stearic and lignoceric acids supplied by high-density lipoprotein (HDL) sphingomyelin to different tissues was followed for 24 h after rats were injected with HDL containing [[1-14C]stearic (18:0) or [1-14C]lignoceric (24:0) acid [Me-3H]choline]sphingomyelin. Both isotopes reached a maximum in tissue lipids 3-12 h after injection and were recovered mainly in the liver (30%) and small intestine (3%), whereas the other tissues contained approx. 1% or less of the injected dose. All the tissues were able to take up some intact sphingomyelin from HDL and hydrolyze it. In the lung and erythrocytes, the 3H:14C ratio of sphingomyelin remained unchanged throughout the studied period, while an increase in the isotopic ratio was observed in the kidney due to the 3H choline moiety re-used for synthesis of new sphingomyelin. Conversely, the isotopic ratio of sphingomyelin decreased in the liver, indicating a saving of the 14C-labelled fatty acids, especially 24:0. Furthermore, [24:0]ceramide in the liver remained at a high level (6% of the injected dose), whereas [18:0]ceramide decreased to 1%. When the tissues were examined 24 h after injection, the proportion of the 14C linked to sphingomyelin in the total 14C was always higher for both kinds of sphingomyelin than the molar proportion of sphingomyelin in the whole of lipid classes. However, in the majority of the extra-hepatic tissues, more [14C]18:0 than [14C]24:0 was recovered in sphingomyelin, and more 14C radioactivity from 18:0 than from 24:0 was redistributed in the other lipids. The choline moiety from both kinds of sphingomyelin was re-used to synthesize phosphatidylcholine, especially in the liver (up to 20% of the injected dose). All these results show that utilization of sphingomyelin from HDL by tissues normally occurs in vivo and that this phenomenon should be taken into account in the study of the phospholipid turnover of cell membranes. They also show that metabolism of sphingomyelin from HDL in the liver and other tissues is dependent on the sphingomyelin acyl moiety.     

Tissue sites of degradation of native and reductively methylated [14C]sucrose-labeled low density lipoprotein in rats. Contribution of receptor-dependent and receptor-independent pathways

Low density lipoprotein (LDL) is catabolized by both receptor-dependent and receptor-independent pathways; methylated LDL (MeLDL) is catabolized only by receptor-independent mechanisms. Rats were injected with either LDL or MeLDL labeled with [14C]sucrose and the tissue sites of degradation were determined 24 h later. On degradation, the 14C-labeled ligand remains trapped intracellularly as a cumulative measure of degradation. The fractional catabolic rate (FCR) of [14C]sucrose-MeLDL was lower than that of [14C]sucrose-LDL (0.056 +/- 0.015 versus 0.118 +/- 0.025 h-1, p less than 0.01). Liver was the predominant site of catabolism of both LDL and MeLDL; more than 85% of catabolism was attributable to parenchymal cells in both cases. The fraction of the plasma LDL pool "cleared" per tissue weight per unit of time was determined for individual tissues. The differences in these rates for LDL and MeLDL are an approximation of receptor-mediated uptake of LDL. According to this method, 67.4% of hepatic uptake was attributable to receptors, as was 69.5% of adrenal, 65.4% of ovarian, 52.4% of intestinal, and 44.2% of renal uptake. In other studies, rats were continuously infused with LDL to down-regulate and saturate receptor prior to injection of labeled LDL or MeLDL. Rats infused with LDL exhibited a lower FCR for [14C]sucrose-LDL compared to controls (0.077 versus 0.120 h-1); the FCR for sucrose-MeLDL was unchanged by LDL infusion. The fractional degradation rate of [14C]sucrose-LDL by individual tissues was lowered by LDL infusion in liver, adrenal, ovary, and intestine (41.4, 57.3, 23.1, and 32.4% lower than controls, respectively). The determination of receptor dependency by this independent approach supports the conclusions reached using [14C]sucrose-LDL and [14C]sucrose-MeLDL in normolipemic animals.     

omega-Oxidation of fatty acids and the acetylation p-aminobenzoic acid.

p-Aminobenzoic acid was fed to normal and alloxan-induced diabetic rats injected with [omega-14C]labeled and [2-14C]labeled fatty acids. The p-acetamidobenzoic acid that was excreted was hydrolyzed to yield acetate which was degraded. The distribution of 14C in the acetates formed when an [omega-14C]labeled fatty acid was injected was similar to that when a [2-14C]labeled fatty acid was injected. This contrasts with the finding that in acetates from 2-acetamido-4-phenylbutyric acid excreted when 2-amino-4-phenylbutyric acid was fed, there was a difference in the distributions of 14C, a difference attributable to omega-oxidation of the fatty acid. Acetylation of p-aminobenzoic acid is then concluded to occur in a different cellular environment than that of 2-amino-4-phenylbutyric acid, one in which omega-oxidation is not functional. When 2-amino-4-phenylbutyric acid was fed and [6-14C]palmitic acid injected, rather than [16-14C]palmitic acid, the distribution of 14C in acetate was the same as when [2-14C]palmitic acid was injected. This indicates that the dicarboxylic acid formed on omega-oxidation of palmitic acid does not undergo beta-oxidation to form succinyl-CoA. Thus, glucose is not formed via omega-oxidation of long-chain fatty acid.     

In vitro metabolism and biological activity of all-trans-retinoic acid and its metabolites in hamster trachea

The in vitro metabolism of all-trans-[11,12-3h]retinoic acid to several more polar compounds has been demonstrated in a hamster tracheal organ culture system. The production of these metabolites is dependent on the presence of tissue. The physiological significance of these compounds is shown by the cochromatography of several of the in vitro formed metabolites synthesized from [carboxy-14C]retinoic acid with metabolites isolated from the intestine and urine of hamsters previously injected with 0.1 to 1.5 microgram of [3H]retinoic acid. One of the metabolites shows about one-tenth the biological activity of all-trans-retinoic acid when tested in a hamster tracheal organ culture assay. This biologically active metabolite is converted by the hamster trachea in vitro to a biologically inactive metabolite.     

Ineffectiveness of dimethyl sulfoxide in altering the permeability of the blood-brain barrier

The failure of DMSO to alter the permeability of the blood-brain barrier has been studied using several polar, nonpolar, hydrophilic, and hydrophobic compounds labeled with selected radioactive isotopes. The metabolites were Na¹³¹I, ¹³¹I-iodinated human serum albumin, l-[³⁵S]methionine, dl-[ring-2-¹⁴C]tryptophan, [U-¹⁴C]sucrose, d-[6-¹⁴C]glucose, and [4-¹⁴C]cholesterol. DMSO was injected intraperitoneally at a dose of 1 g/kg followed after 1 hr by the intracarotid injection of the labeled metabolite. An appropriate volume of saline was substituted for the DMSO in control animals. The brain and one gastrocnemius muscle were removed at selected intervals up to 30 min and the uptake into these tissues was measured.It was found that the permeability of neither the blood-brain barrier nor skeletal muscle was altered by this concentration of DMSO. This dose of DMSO, administered intravenously, frequently caused death and, intraperitoneally, caused muscular twitching, lethargy, and hematuria.     

Uptake and metabolism of catecholamines in the awake dog

The contributions of uptake, metabolism and excretion to the removal of circulating dopamine (D) have been studied in comparison to those of adrenaline (A) and noradrenaline (NA). In two experiments radioactive catecholamines were infused during 80 min in an awake dog. In the first experiment [14C]D and D, L-[3H]A was used and in the second experiment these catecholamines were infused together with D, L-[14C]NA. Renal excretion of 14C-radioactivity was almost equal in both experiments, as was the case with the accumulation of 14C-components in plasma, demonstrating that the uptake of D was comparable to that of NA. The removal of [14C]D, [14C]NA and [3H]A, by uptake was 50, 50 and 13.5% respectively after 1 h. The conversion by metabolism was 46, 46 and 81%. Renal excretion was 3.5, 2 and 0.5%. Thus only 0.5, 2 and 5% was left in the extracellular fluid (ECF). In a report on similar experiments in anaesthetized dogs much higher levels of unchanged NA in plasma were measured. Probably this is due to anaesthesia inhibiting uptake. In the pulmonary circulation 14C-radioactivity was extracted at a constant rate during infusion which can mainly be attributed to extraneuronal uptake of [14C]D and to neuronal uptake of [14C]NA. Besides extraneuronal uptake of [3H]A in the lung expiration of [3H]water may contribute to the pulmonary extraction.     

Nicotinate, quinolinate and nicotinamide as precursors in the biosynthesis of nicotinamide–adenine dinucleotide in barley

1. The relative efficiencies of nicotinate, quinolinate and nicotinamide as precursors of NAD(+) were measured in the first leaf of barley seedlings. 2. In small amounts, both [(14)C]nicotinate and [(14)C]quinolinate were quickly and efficiently incorporated into NAD(+) and some evidence is presented suggesting that NAD(+) is formed from each via nicotinic acid mononucleotide and deamido-NAD. 3. [(14)C]Nicotinamide served equally well as a precursor of NAD(+) and although significant amounts of [(14)C]NMN were detected, most of the [(14)C]NAD(+) was derived from nicotinate intermediates formed by deamination of [(14)C]nicotinamide. 4. Radioactive NMN was also a product of the metabolism of [(14)C]nicotinate and [(14)C]quinolinate but most probably it arose from the breakdown of [(14)C]NAD(+). 5. In barley leaves where the concentration of NAD(+) is markedly increased by infection with Erysiphe graminis, the pathways of NAD(+) biosynthesis did not appear to be altered after infection. A comparison of the rates of [(14)C]NAD(+) formation in infected and non-infected leaves indicated that the increase in NAD(+) content was not due to an increased rate of synthesis.     

Uptake and incorporation of 14C-labelled carbohydrates in the tissues of the reproductive system of the female fowl

The in vivo incorporation of radioactivity from [14C]GlcN, [14C]GalN, [14C]Glc and [14C]Gal, for different time intervals between 1 and 240 hr into whole tissues, acetone extracted tissues and MPS-P of the different parts of the reproductive system of the female fowl was studied. The incorporation of radioactivity was much more extensive when [14C]GlcN was injected than when [14C]GalN was injected. The incorporation of radioactivity was much more extensive when [14C]HexN was injected than when the corresponding [14C]Hex was injected. This difference of incorporation was greater in the MPS-P than in the fresh or acetone extracted tissues. A comparison was undertaken in the extent that radioactivity was incorporated among the different parts of the reproductive system of the fowl when [14C]HexN and 14C[Hex] were administered.     

Dependence of ADP-ribosylation of histones of chicken liver nuclei on the intranuclear content of NAD

The dependence of ADP-ribosylation of chicken liver nuclear histones on NAD concentration in the nuclei was studied under conditions of stimulation of coenzyme synthesis by the nicotinamide and nicotinic acid as well as upon addition of various concentrations of the [Ado-U-14C]NAD nuclei to the incubation mixture. In the first case, the rate of [Ado-U-14C]NAD incorporation into the histones was decreased due to the dilution of the label by the de novo synthesized NAD. The amount of the latter formed under effects of nicotinic acid and nicotinamide increased, correspondingly, from 2,2 X 10(-5) mmol up to 4.1 X 10(-5) and 7.0 X 10(-5) mmol per mg of nuclear protein. The incorporation of [Ado-U-14C]NAD into the histones decreased from 12.0 X 10(-8) mmol after incubation of liver slides with nicotinic acid and nicotinamide down to 8.0 X 10(-8) and 7.0 X 10(-8) mmol, respectively. With a rise in the concentration of exogenous [Ado-U-14C]NAD, the level of ADP-ribosylation of nuclear histones increased, the plot [14C]NAD incorporation at the labeled coenzyme concentration of 25 X 10(-7) mM/mg of histone had a plateau. Changes in the labeled substrate concentration brought about corresponding changes in the average length of the histone-linked poly-(ADP-ribose) chain.     

Migratory patterns of B lymphocytes. IV. Effect of anti-Ig on follicular localization of radioactively labeled murine spleen and bone marrow cells.

A study was made of the localization of nylon-wool-adherent (AD) and nonadherent (NA) murine spleen cells in lymphoid tissue of irradiated syngeneic recipients. Cells were labeled in vitro with [³H]uridine or ⁵¹Cr and injected intravenously. Localization in recipient tissues was expressed as percent of injected radioactivity. NA and AD [³H]uridine labeled cells gave spleen to lymph node (S:LN) ratios of 1.0 and 2.7, respectively. After treatment of AD cells with rabbit anti-mouse Fab + C at 37 °C, localization in S decreased markedly.NA cells primarily localized in LN paracortex and splenic periarteriolar sheaths. Untreated and NRS-treated AD cells localized in lymphoid follicles, whereas anti-Fab-treated AD cells did not. When ⁵¹Cr-labeled AD cells were treated with anti-Fab at 4 °C without C, there was a transient decrease in splenic localization at 24 hr followed by a recovery to the normal pattern at 48 hr after transfer. [³H]uridine-labeled bone marrow (BM) cells showed less localization in lymphoid tissue than did S cells. Some BM cells were seen in LN follicles, particularly at 48 hr after transfer, but this localization was not affected by prior treatment with anti-Fab + C. The possible role of surface Ig in the determination of follicular localization of B lymphocytes is discussed.