Increased metabolic rate and insulin sensitivity in male mice lacking the carcino-embryonic antigen-related cell adhesion molecule 2.

AIMS/HYPOTHESIS: The carcino-embryonic antigen-related cell adhesion molecule (CEACAM)2 is produced in many feeding control centres in the brain, but not in peripheral insulin-targeted tissues. Global Ceacam2 null mutation causes insulin resistance and obesity resulting from hyperphagia and hypometabolism in female Ceacam2 homozygous null mutant mice (Cc2 [also known as Ceacam2](-/-)) mice. Because male mice are not obese, the current study examined their metabolic phenotype. METHODS: The phenotype of male Cc2(-/-) mice was characterised by body fat composition, indirect calorimetry, hyperinsulinaemic-euglycaemic clamp analysis and direct recording of sympathetic nerve activity. RESULTS: Despite hyperphagia, total fat mass was reduced, owing to the hypermetabolic state in male Cc2(-/-) mice. In contrast to females, male mice also exhibited insulin sensitivity with elevated ß-oxidation in skeletal muscle, which is likely to offset the effects of increased food intake. Males and females had increased brown adipogenesis. However, only males had increased activation of sympathetic tone regulation of adipose tissue and increased spontaneous activity. The mechanisms underlying sexual dimorphism in energy balance with the loss of Ceacam2 remain unknown. CONCLUSIONS/INTERPRETATION: These studies identified a novel role for CEACAM2 in the regulation of metabolic rate and insulin sensitivity via effects on brown adipogenesis, sympathetic nervous outflow to brown adipose tissue, spontaneous activity and energy expenditure in skeletal muscle.

Negative transcriptional regulation of human interleukin 2 (IL-2) gene by glucocorticoids through interference with nuclear transcription factors AP-1 and NF-AT.

IL-2 gene transcription is affected by several nuclear proteins. We asked whether dexamethasone (Dex) and cyclosporin A (CsA) inhibit IL-2 gene transcription by interfering with the activity of nuclear proteins that bind to the IL-2 promoter. Nuclear extracts from primary human T lymphocytes were analyzed by electrophoretic DNA mobility shift assays. Both Dex and CsA inhibited the binding of transcription factors AP-1 and NF-AT, but not of NF-kB and OCT-1/OAF, to their corresponding sites on the IL-2 gene promoter. To correlate changes in nuclear factor binding in vitro with transcriptional activity in vivo and define the structural requirements for IL-2 promoter repression, we used transient DNA transfections. Jurkat cells were transfected with plasmids containing either the intact IL-2 promoter or its AP-1, NF-AT, and NF-kB motifs. Dex inhibited the IL-2 promoter and the AP-1, but not the NF-AT and NF-kB plasmids. In contrast, CsA inhibited the IL-2 promoter and the NF-AT, but not the AP-1 and NF-kB plasmids. These results suggest that in human T lymphocytes both Dex and CsA inhibited IL-2 gene transcription through interference with transcription factors AP-1 and NF-AT. We propose that, while maximum inhibition may involve interaction with both transcription factors, AP-1 is the primary target of Dex.

The differential effects of pp120 (Ceacam 1) on the mitogenic action of insulin and insulin-like growth factor 1 are regulated by the nonconserved tyrosine 1316 in the insulin receptor.

pp120 (Ceacam 1) undergoes ligand-stimulated phosphorylation by the insulin receptor, but not by the insulin-like growth factor 1 receptor (IGF-1R). This differential phosphorylation is regulated by the C terminus of the beta-subunit of the insulin receptor, the least conserved domain of the two receptors. In the present studies, deletion and site-directed mutagenesis in stably transfected hepatocytes derived from insulin receptor knockout mice (IR(-/-)) revealed that Tyr(1316), which is replaced by the nonphosphorylatable phenylalanine in IGF-1R, regulated the differential phosphorylation of pp120 by the insulin receptor. Similarly, the nonconserved Tyr(1316) residue also regulated the differential effect of pp120 on IGF-1 and insulin mitogenesis, with pp120 downregulating the growth-promoting action of insulin, but not that of IGF-1. Thus, it appears that pp120 phosphorylation by the insulin receptor is required and sufficient to mediate its downregulatory effect on the mitogenic action of insulin. Furthermore, the current studies revealed that the C terminus of the beta-subunit of the insulin receptor contains elements that suppress the mitogenic action of insulin. Because IR(-/-) hepatocytes are derived from liver, an insulin-targeted tissue, our observations have finally resolved the controversy about the role of the least-conserved domain of insulin and IGF-1Rs in mediating the difference in the mitogenic action of their ligands, with IGF-1 being more mitogenic than insulin.

Persistent expression of foreign genes in cultured hepatocytes: expression vectors.

We have optimized a liposome-based transfection method that mediated highly efficient stable expression of foreign genes in hepatocytes. Moreover, we have observed that the metallothionein 1 promoter in the bovine papilloma virus-based expression vector drove the highest expression of foreign genes in hepatocytes as compared with the cytomegalovirus and the human polypeptide chain elongation factor 1alpha (EF-1alpha) promoters in the pcDNA 3-based expression vector. The cytomegalovirus promoter failed to yield significant expression in these cells. Furthermore, expression of foreign genes persisted up to at least 15 passages when expression was under the control of either the EF-1alpha or the metallothionein 1 promoter. Thus, these two promoters led to comparable stability of foreign genes in hepatocytes, with the metallothionein 1 promoter yielding a higher level of expression of foreign genes in these cells.

Androgen regulation of the cell-cell adhesion molecule-1 (Ceacam1) gene.

Previous studies have established that the cell-cell adhesion molecule-1 (CEACAM1, previously known as C-CAM1) functions as a tumor suppressor in prostate cancer and is involved in the regulation of prostate growth and differentiation. However, the molecular mechanism that modulates CEACAM1 expression in the prostate is not well defined. Since the growth of prostate epithelial cells is androgen-regulated, we investigated the effects of androgen and the androgen receptor (AR) on CEACAM1 expression. Transient transfection experiments showed that the AR can enhance the Ceacam1 promoter activity in a ligand-dependent manner and that the regulatory element resides within a relatively short (-249 to -194 bp) segment of the 5'-flanking region of the Ceacam1 gene. This androgen regulation is likely through direct AR-promoter binding because a mutant AR defective in DNA binding failed to upregulate reporter gene expression. Furthermore, electrophoretic mobility shift assays demonstrated that the AR specifically binds to this sequence, and mutation analysis of the potential ARE sequences revealed a region within the sequence that was required for the AR to activate the Ceacam1 gene. Therefore, the regulation of Ceacam1 gene expression by androgen may be one of the mechanisms by which androgen regulates prostatic function.

Myocardial ischemic effects of isometric, dynamic and combined exercise in coronary artery disease.

The electrocardiographic effects isometric (handgrip) and combined isometric-dynamic (treadmill-plus-brief-case) exercise were evaluated and compared to a submaximal treadmill stress test in 140 patients with known or suspected coronary artery disease. Only 3 of 90 patients developed ischemic ST changes during handgrip, as opposed to 25 positive treadmill tests (p less than 0.01). Of 19 of 50 patients who were positive during the standard treadmill test, only 17 showed positive findings during the combined treadmill-briefcase test. Analysis of hemodynamic responses showed significant (p less than 0.01) differences between the handgrip and treadmill tests in terms of heart rate response (control 83 plus or minus beats/minute, handgrip 105 plus or minus 4, treadmill 151 plus or minus 6), diastolic blood pressure (control 80 plus or minus 2 mm Hg, isometric 93 plus or minus 3, treadmill 81 plus or minus 3) and heart rate-systolic pressure product (control 9940 plus or minus 564 units, handgrip 15022 plus or minus 779, treadmill 22270 plus or minus 1147). In comparing treadmill and combined treadmill-briefcase tests, significant differences were seen in systolic blood pressure (control 114 plus or minus 2 mm Hg, treadmill 143 plus or minus 3, briefcase 155 plus or minus 3), diastolic blood pressure (control 83 plus or minus 2 mm Hg, treadmill 82 plus or minus 2, briefcase 89 plus or minus 2) and rate-pressure product (control 10134 plus or minus 373, treadmill 19624 plus or minus 777, briefcase 21201 plus or minus 798). Isometric exercise alone is much less likely to produce myocardial ischemia than vigorous dynamic exercise. Higher arterial diastolic (coronary perfusion) pressure may retard the development of myocardial ischemia during isometric or combined isometricdynamic exercise in coronary patients.

Altered intestinal and renal brush border amino-oligopeptidase structure in diabetes and metabolic acidosis: normal and biobreed (BB) rats.

Amino-oligopeptidase (AOP, aminopeptidase N), a major glycoprotein hydrolase in intestinal and kidney brush border membranes, plays a crucial role in digesting peptide nutrients and salvaging filtered peptides. The molecular structure of rat intestinal and kidney AOP was compared for normal Wistar and congenitally diabetic BB Wistar (BBd) rats. Brush border membranes were isolated, solubilized with Triton X-100, and the AOP specifically immunoprecipitated with polyvalent rabbit antiserum and analyzed on 7% sodium dodecyl sulfate (SDS)-acrylamide electrophoresis. While the specific hydrolytic activity was maintained, BBd rats displayed an altered migration of AOP on SDS gels. Intestinal AOP migrated as a smaller species (130 kd) in the BBd than in the normal Wistar (135 to 140 kd). In some BBd rats, additional intestinal AOP species were observed (a 130- to 135-kd doublet or a 125-, 130-, or 135-kd triplet). Kidney AOP migrated as a broader band (125 to 140 kd) than intestine for all rat groups, probably due to carbohydrate chain heterogeneity, and was approximately 5 kd smaller in the BBd rat than in the normal Wistar. In contrast, no mass change was found in diabetes induced by streptozotocin (STZ). The altered intestinal AOP in the BBd rat was present when first inserted into the brush border membrane (6 hours after intraperitoneal [35S]methionine labeling), and hence was not due to nonenzymatic glycosylation (NEG). Abnormal intestinal and kidney AOP structure appeared in early diabetes, irrespective of high plasma glucose levels or ketoacidosis, and was reversed following evolution of the diabetes under prolonged (21 to 120 days) insulin treatment.(ABSTRACT TRUNCATED AT 250 WORDS)

Frequency of tracheobronchial foreign bodies in children and adolescents.

OBJECTIVE: The problem of foreign body aspiration in the community has been studied and compared with other reports. METHODS: We have retrospectively studied patients who had bronchoscopy for suspected foreign bodies in the tracheobronchial tree, attending or referred to Al-Noor Specialist Hospital, Makkah over a period of 3 years from May 1996 to May 1999. RESULTS: The total number of patients was 94 (62 male and 32 female). Ages ranged from 4 months to 45 years(mean age 3.77 years), 85% of children being under the age of 5 years. One hundred bronchoscopies (6 repeat bronchoscopies) and one thoracotomy were carried out. Foreign bodies were removed from 60 patients (64%). Six (10%) did not have any definite history, while 15 patients (21%) with definite history of foreign body aspiration had negative bronchoscopy. An aspirated Fis-Fis (Alfalfa, Lucerne) seed accounted for more than one-third of all foreign bodies. The most frequent symptoms, signs, radiological findings and site of foreign body lodgement in the tracheobronchial tree are discussed. CONCLUSION: We conclude that a negative history, clinical examination and chest x-ray do not necessarily exclude aspirated foreign body material. Bronchoscopy is the most effective diagnostic and therapeutic modality to prevent complications related to neglected foreign body aspiration. In addition to children, teenagers and adolescents are also not immune to this problem. We recommend early referral to an appropriate hospital on suspicion or if symptoms persist. However, preventive measures, remain the best means of protecting these children.

Decreased osteoclastogenesis and high bone mass in mice with impaired insulin clearance due to liver-specific inactivation to CEACAM1.

Type 2 diabetes is associated with normal-to-higher bone mineral density (BMD) and increased rate of fracture. Hyperinsulinemia and hyperglycemia may affect bone mass and quality in the diabetic skeleton. In order to dissect the effect of hyperinsulinemia from the hyperglycemic impact on bone homeostasis, we have analyzed L-SACC1 mice, a murine model of impaired insulin clearance in liver causing hyperinsulinemia and insulin resistance without fasting hyperglycemia. Adult L-SACC1 mice exhibit significantly higher trabecular and cortical bone mass, attenuated bone formation as measured by dynamic histomorphometry, and reduced number of osteoclasts. Serum levels of bone formation (BALP) and bone resorption markers (TRAP5b and CTX) are decreased by approximately 50%. The L-SACC1 mutation in the liver affects myeloid cell lineage allocation in the bone marrow: the (CD3(-)CD11b(-)CD45R(-)) population of osteoclast progenitors is decreased by 40% and the number of (CD3(-)CD11b(-)CD45R(+)) B-cell progenitors is increased by 60%. L-SACC1 osteoclasts express lower levels of c-fos and RANK and their differentiation is impaired. In vitro analysis corroborated a negative effect of insulin on osteoclast recruitment, maturation and the expression levels of c-fos and RANK transcripts. Although bone formation is decreased in L-SACC1 mice, the differentiation potential and expression of the osteoblast-specific gene markers in L-SACC1-derived mesenchymal stem cells (MSC) remain unchanged as compared to the WT. Interestingly, however, MSC from L-SACC1 mice exhibit increased PPARgamma2 and decreased IGF-1 transcript levels. These data suggest that high bone mass in L-SACC1 animals results, at least in part, from a negative regulatory effect of insulin on bone resorption and formation, which leads to decreased bone turnover. Because low bone turnover contributes to decreased bone quality and an increased incidence of fractures, studies on L-SACC1 mice may advance our understanding of altered bone homeostasis in type 2 diabetes.

pp120, a substrate of the insulin receptor tyrosine kinase, is associated with phosphatase activity.

pp120, a plasma membrane glycoprotein, is phosphorylated on Tyr488 by the insulin receptor tyrosine kinase. This requires basal phosphorylation on Ser503 by cAMP-dependent serine kinase. Phe513, the other tyrosine residue in the intracellular domain, does not undergo insulin-stimulated phosphorylation. Phe488 mutation abolished basal and insulin-stimulated phosphorylation, whereas, Phe513 plus Phe488 mutation markedly decreased the effect of insulin on pp120 phosphorylation without altering basal phosphorylation in intact cells. To investigate whether basal phosphorylation of pp120 is regulated by a phosphatase activity that requires Tyr513, in vitro phosphorylation assays using partially purified glycoproteins from stably transfected NIH 3T3 cells were performed in the absence of phosphatase inhibitors. Wild-type pp120 was promptly dephosphorylated, whereas, Y513F pp120 was not. Decreasing pp120 expression by antisense cDNA transfection proportionally decreased phosphatase activity in H4-II-E hepatoma cells measured by the p-nitrophenyl phosphate assay. This suggests that pp120 is associated with phosphatase activity that requires an intact Tyr513 residue.

Differential effect of pp120 on insulin endocytosis by two variant insulin receptor isoforms.

The insulin receptor is expressed as two variably spliced isoforms that differ by the absence (isoform A) or presence (isoform B) of a 12-amino acid sequence encoded by exon 11 at the carboxy terminus of the alpha-subunit. Coexpression of the A isoform and pp120, a substrate of the insulin receptor tyrosine kinase, in NIH 3T3 fibroblasts increased receptor A-mediated insulin endocytosis and degradation by two- to threefold compared with cells expressing receptors alone. Because B is the predominant isoform in the liver and binds insulin with lower affinity than A, we have examined the effect of pp120 on receptor B-mediated endocytosis. In contrast to isoform A, the effect of pp120 on isoform B-mediated insulin internalization and degradation in stably transfected NIH 3T3 cells was minimal.

Intestinal aminooligopeptidase in diabetic BioBreed rat: altered posttranslational processing and trafficking.

The structure of aminooligopeptidase (AOP), an intestinal brush-border digestive hydrolase, is abnormal in human diabetes and in the congenitally diabetic BioBreed Wistar (BB(d)) rat. Its assembly in the BB(d) rat was examined. After normal initial synthesis and assembly of immature AOP precursor (AOP(i)) with high-mannose N-linked chains in the endoplasmic reticulum (ER), processing of N-linked glycans in Golgi yielded a smaller than normal mature AOP precursor (AOP(m)) with persistence of some high-mannose N-linked chains. Deglycosylation analyses suggested that the mass difference could be attributed to a lower mass of N-linked with unaltered O-linked glycans in AOP(m) of the diabetic rat. Intrajejunal pulse-chase experiments revealed that the conversion of AOP(i) to AOP(m) occurred at 30 min of chase in normal rats but at 60-90 min in diabetic rats, reflecting delay in ER-to-Golgi transport or a slower processing of high-mannose chains. Once maximal transport to Golgi was achieved, the residence time in Golgi was shortened in diabetes. This altered processing of the precursor accounted for the altered structure of AOP in diabetes.

Sucrase-alpha-dextrinase in diabetic BioBreed rats: reversible alteration of subunit structure.

BioBreed (BB) Wistar rats develop diabetes mellitus, which closely resembles the human disease, in 50% of progeny. Intestinal sucrase-alpha-dextrinase, a glycoprotein hydrolase of the enterocyte's brush border consisting of 140-kDa alpha-dextrinase and 125-kDa sucrase subunits, is essential for surface digestion of carbohydrate nutrients. Although its catalytic characteristics were found to be maintained in the diabetic state, the structure of the subunits, as compared with normal Wistar rats, was altered in the BB rat within 2 days of the onset of diabetes. Its capacity to react in a solid-phase immunoassay was reduced by 50%; when examined by 6% acrylamide electrophoresis, the sucrase subunit was increased in mass by 5 kDa and, in some BB rats, the dextrinase subunit was reduced by 5 kDa. Intact rats labeled intraintestinally with [35S]methionine displayed the alteration within 6 h of synthesis, indicating that nonenzymatic glycosylation could not account for the structural change. This mass change was not seen in streptozotocin-induced diabetes and was independent of the plasma glucose concentration or the degree of acidosis. Deglycosylation with peptide N-glycosidase indicated that the N-linked chains of the normal dextrinase subunit (11 kDa) have twice the mass of those in the BB rat (6 kDa) and that the sucrase subunit may have an increased mass of O-linked chains. Overall, these experiments point to changes in glycosylation as a mechanism of structural alteration in congenital diabetes. Despite persistence of the insulin-dependent diabetes, the subunit pattern eventually became indistinguishable from normal, but at differential rates (21 days and 35 days, respectively, for sucrase and dextrinase subunits).

pp120/ecto-ATPase, an endogenous substrate of the insulin receptor tyrosine kinase, is expressed as two variably spliced isoforms.

The insulin receptor possesses tyrosine kinase activity which is thought to mediate the biological effects of insulin upon target cells. pp120 is a liver-specific glycoprotein of apparent molecular size of 120 kDa that is phosphorylated on tyrosine residues by the receptors for insulin, insulin-like growth factor-I, and epidermal growth factor. Previously, we demonstrated that pp120 is identical to a liver-specific ecto-ATPase. In the present study, we have cloned the rat gene encoding pp120/ecto-ATPase. The gene is contained within approximately 15 kilobases of genomic DNA, and consists of nine exons interrupted by eight introns. Using the reverse transcriptase/polymerase chain reaction, we isolated cDNA clones complementary to rat liver mRNA encoding pp120/ecto-ATPase. Sequence analysis indicated the presence of two populations of cDNA's that differ by the presence or absence of a 53-base pair (bp) fragment encoding the juxta-membrane region of the cytoplasmic domain. By cloning the corresponding region of the ecto-ATPase gene, we demonstrated that the 53-bp represents exon 7 of the gene. This 53-bp exon undergoes alternative splicing, thereby giving rise to two mRNA variants. Deletion of this 53-bp cassette exon introduces a frameshift, and results in a premature chain termination codon that truncates the cytoplasmic domain. The truncated cytoplasmic domain contains 10 rather than 71 amino acid residues. Because the short isoform of ecto-ATPase lacks the putative sites for tyrosine- and serine-specific phosphorylation, this alternative splicing may have a major effect upon the physiological function of the enzyme.

Metabolic regulation of Na(+)/P(i)-cotransporter-1 gene expression in H4IIE cells.

We showed that the rat Na(+)/P(i) cotransporter-1 (RNaPi-1) gene was regulated by insulin and glucose in rat hepatocytes. The aim of this work was to elucidate signaling pathways of insulin-mediated metabolic regulation of the RNaPi-1 gene in H4IIE cells. Insulin increased RNaPi-1 mRNA abundance in the presence of glucose and decreased RNaPi-1 mRNA in the absence of glucose, clearly establishing an involvement of metabolic signals for insulin-induced upregulation of the RNaPi-1 gene. Pyruvate and insulin increased RNaPi-1 expression but downregulated L-pyruvate kinase, indicating the existence of gene-specific metabolic signals. Although fructose, glycerol, and lactate could support insulin-induced upregulation of the RNaPi-1 gene, compounds entering metabolism beyond pyruvate oxidation, such as acetate and citrate, could not, suggesting that RNaPi-1-specific metabolic signals are generated at or above pyruvate oxidation. Wortmannin, LY-294002, and rapamycin abolished the insulin effect on the RNaPi-1 gene, whereas expression of dominant negative Asn(17) Ras and mitogen-activating protein kinase (MAPK) kinase (MEK) inhibitor PD-98059 exhibited no effect. Thus we herein propose that metabolic regulation of RNaPi-1 expression by insulin is mediated through the phosphatidylinositol 3-kinase/p70 ribosomal S6 kinase pathways, but not the Ras/MAPK pathway.

Cell adhesion properties and effects on receptor-mediated insulin endocytosis are independent properties of pp120, a substrate of the insulin receptor tyrosine kinase.

pp120 undergoes phosphorylation by the tyrosine kinase of the insulin, not the insulin-like growth factor 1 (IGF-1), receptor. Moreover, pp120 stimulates receptor-mediated insulin, but not IGF-1, endocytosis, suggesting that pp120 phosphorylation underlies its effect on insulin endocytosis. pp120 phosphorylation also underlies its bile acid transport and tumor suppression functions. In addition to depending on the intracellular tail, the cell adhesion property of pp120 depends on Arg98 in the N-terminal IgV-like ectoplasmic domain. To investigate whether this domain mediates the effect of pp120 on insulin endocytosis, we mutated Arg98 to Ala and examined whether this mutation altered pp120 phosphorylation and its effect on ligand endocytosis in transfected NIH 3T3 cells. This mutation did not modify either pp120 phosphorylation or its effect on receptor-mediated ligand endocytosis. These findings support the hypothesis that stimulation of insulin endocytosis by pp120 is not mediated by Arg98 in the N-terminal IgV-like ectoplasmic domain of pp120.

Effect of pp120 on receptor-mediated insulin endocytosis is regulated by the juxtamembrane domain of the insulin receptor.

pp120, a substrate of the insulin receptor tyrosine kinase, does not undergo ligand-stimulated phosphorylation by the insulin-like growth factor-1 (IGF-1) receptor. However, replacement of the C-terminal domain of the IGF-1 receptor beta-subunit with the corresponding segment of the insulin receptor restored pp120 phosphorylation by the chimeric receptor. Since pp120 stimulates receptor-mediated insulin endocytosis when it is phosphorylated, we examined whether pp120 regulates IGF-1 receptor endocytosis in transfected NIH 3T3 cells. pp120 failed to alter IGF-1 receptor endocytosis via either wild-type or chimeric IGF-1 receptors. Thus, the effect of pp120 on hormone endocytosis is specific to insulin, and the C-terminal domain of the beta-subunit of the insulin receptor does not regulate the effect of pp120 on insulin endocytosis. Mutation of Tyr960 in the juxtamembrane domain of the insulin receptor abolished the effect of pp120 to stimulate receptor endocytosis, without affecting pp120 phosphorylation by the insulin receptor. These findings suggest that pp120 interacts with two separate domains of the insulin receptor as follows: a C-terminal domain required for pp120 phosphorylation and a juxtamembrane domain required for internalization. We propose that the interaction of pp120 with the juxtamembrane domain is indirect and requires one or more substrates that bind to Tyr960 in the insulin receptor.

Modifications of RNA processing modulate the expression of hemoglobin genes.

The developmental changes in hemoglobin gene expression known as "switching" involve both the sequential activation and silencing of the individual globin genes. We postulated that in addition to changes in transcription, posttranscriptional mechanisms may be involved in modulating globin gene expression. We studied globin RNA transcripts in human adult erythroid cells (hAEC to analyze the mechanism of silencing of the embryonic epsilon-globin gene in the adult stage and in K562 erythroleukemic cells to analyze the inactive state of their adult beta-globin genes. In hAEC, which express primarily the beta-globin gene, quantitative PCR analysis shows that beta-mRNA exon levels are high and comparable among the three exons; the RNA transcripts corresponding to exons of the gamma-globin gene are low, with slight differences among the three exons. Although epsilon-globin is not expressed, epsilon-globin RNA transcripts are detected, with exon I levels comparable to that of gamma-globin exon I and much higher than epsilon-exons II and III. As expected, in K562 cells that express high levels of epsilon- and gamma-globin, epsilon- and gamma-mRNA levels are high, with comparable levels of exons I, II, and III. In K562 cells beta-mRNA levels are very low but beta-exon I levels are much higher than that of exons II or III. Moreover, all or most of the globin transcripts for the highly expressed globin genes in both cell types (gamma and beta in hAEC, epsilon and gamma in K562 cells) found in the cytoplasm or nucleus are correctly processed. The globin transcripts that are detected both in the cytoplasm and nucleus of cells without expression of the corresponding protein are largely unspliced (containing one or two intervening sequences). These studies suggest that in addition to changes in transcription rates, changes in completion or processing of globin RNA transcripts may contribute to the developmental regulation of the hemoglobin phenotype.