Isolation of an active element from a high-copy-number family of retrotransposons in the sweetpotato genome.

A large number of plant retrotransposons have been characterized, but only three families ( Tnt1, Tto1 and Tos17) have been demonstrated to be transpositionally competent. We have used a novel approach to identify an active member of the Ty1- copia retrotransposon family with estimated 400 copies in the sweetpotato genome. Ty1- copia reverse transcriptase (RTase) sequences from the sweetpotato genome were analyzed, and a group of retrotransposon copies that probably arose by recent transposition events was identified and analyzed further. Transcripts containing long terminal repeats (LTRs) of this group were amplified from callus cDNA by the 3'RACE technique. Patterns of sequence-specific amplification polymorphism (S-SAP) of the LTR sequences in genomic DNA were compared between a normal plant and callus lines derived from it. In this way, a callus-specific S-SAP product was identified, which apparently resulted from the insertion of the retrotransposon detected by 3'RACE during cell culture. We conclude that our approach provides an effective way to identify active elements among the members of high-copy-number retrotransposon families.

Direct intracellular measurement of deoxygenated hemoglobin S solubility.

The solubility of deoxygenated hemoglobin S (HbS), which is the concentration of fully deoxygenated HbS in equilibrium with polymer (C(SAT)), is a factor that determines in vivo polymer formation. However, measurement of C(SAT) is usually performed under conditions that are far from physiological. In solution studies of HbS by Benesch et al, it was demonstrated that p50, the point at which hemoglobin is half-saturated with oxygen, is proportional to the amount of polymer formed and that it may be used to measure C(SAT). This method has been extended to measure C(SAT) in intact red cells by varying extracellular osmolarity, which, in turn, varies intracellular hemoglobin concentration. This method measures intracellular C(SAT) under physiological conditions with intact red cell contents and can be applied to human and transgenic mouse red cells. The principle is demonstrated by measuring p50 as a function of extracellular osmolarity for AA, SS, and AS red cells. (Blood. 2001;98:883-884)

K:Cl cotransport activity is inhibited by HCO3- in knockout mouse red cells expressing human HbC.

K:Cl cotransport (KCl) was examined in transgenic mice expressing exclusively human hemoglobin C. In contrast to previous studies in early transgenic mice expressing human alpha and beta(S) and residual mouse globins, we found significant volume and pH stimulation and sensitivity to. Exposure to physiological levels of also blocked a significant fraction of KCl cotransport.

Second generation knockout sickle mice: the effect of HbF.

Sickle transgenic mice expressing exclusively human globins are desirable for studying pathophysiology and testing gene therapy strategies, but they must have significant pathology and show evidence of amelioration by antisickling hemoglobins. Mice were generated that expressed exclusively human sickle hemoglobin with 3 levels of HbF using their previously described sickle constructs (cointegrated human miniLCRalpha2 and miniLCRbeta(S) [PNAS 89:12150, 1992]), mouse alpha- and beta-globin-knockouts, and 3 different human gamma-transgenes. It was found that, at all 3 levels of HbF expression, these mice have balanced chain synthesis, nearly normal mean corpuscular hemoglobin, and, in some cases, F cells. Mice with the least adult HbF expression were the most severe. Progressive increase in HbF from less than 3% to 20% to 40% correlated with progressive increase in hematocrit (22% to 34% to 40%) and progressive decrease in reticulocyte count (from 60% to 30% to 13%). Urine concentrating ability was normalized at high HbF, and tissue damage detected by histopathology and organ weight were ameliorated by increased HbF. The gamma-transgene that produces intermediate levels of HbF was introduced into knockout sickle mice described by Pàszty and coworkers that express the miniLCRalpha1(G)gamma(A)gammadeltabeta(S) transgene and have fetal but not adult expression of HbF. It was found that the level of HbF required to ameliorate low hematocrit and normalize urine concentrating defect was different for the miniLCRalpha2beta(S) and miniLCRalpha1(G)gamma(A)gammadeltabeta(S) mice. We conclude that knockout mice with the miniLCRalpha2beta(S) transgene and postnatal expression of HbF have sufficiently faithful sickle pathology to serve as a platform for testing antisickling interventions.

Hemoglobin C in transgenic mice: effect of HbC expression from founders to full mouse globin knockouts.

When present in the homozygous form, hemoglobin C (HbC, CC disease) increases red cell density, a feature that is the major factor underlying the pathology in patients with SC disease (Fabry et al., JCI 70, 1315, 1982). The basis for the increased red cell density has not yet been fully defined. We have generated a HbC mouse in which the most successful founder expresses 56% human alpha and 34% human beta(C). We introduced knockouts (KO) of mouse alpha- and beta-globins in various combinations. In contrast to many KO mice, all partial KOs have normal MCH. Full KOs that express exclusively HbC and no mouse globins have minimally reduced MCH (13. 7 +/- 0.3 pg/cell vs 14.5 +/- 1.0 for C57BL/6) and a ratio of beta- to alpha-globin chains of 0.88 determined by chain synthesis; hence, these mice are not thalassemic. Mice with beta(C) > 30% have increased MCHC, dense reticulocytes, and increased K:Cl cotransport. Red cell morphology studied by SEM is strikingly similar to that of human CC cells with bizarre folded cells. We conclude that red cells of these mice have many properties that closely parallel the pathology of human disease in which HbC is the major determinant of pathogenesis. These studies also establish the existence of the interactions with other gene products that are necessary for pleiotropic effects (red cell dehydration, elevated K:Cl cotransport, morphological changes) that are also present in these transgenic mice, validating their usefulness in the analysis of pathophysiological events induced by HbC in red cells.

Anti-beta s-ribozyme reduces beta s mRNA levels in transgenic mice: potential application to the gene therapy of sickle cell anemia.

Our current strategy for gene therapy of sickle cell anemia involves retroviral vectors capable of transducing "designer" globin genes that code for novel anti-sickling globins (while resisting digestion by a ribozyme), coupled with the expression of a hammerhead ribozyme that can selectively cleave the human beta s mRNA. In this report, we have tested in vivo an anti-beta s hammerhead ribozyme embedded within a cDNA coding for the luciferase reporter gene driven by the human beta-globin promoter and hyper-sensitive sites 3 and 4 of the locus control region. We have created mice transgenic for this luciferase-ribozyme construct and bred the ribozyme transgene into mice that were already transgenic for the human beta s gene. We then measured expression of the beta s transgene at the protein and RNA levels by HPLC and primer extension. The presence of the ribozyme was associated with a statistically significant reduction in the level of beta s mRNA in spleen stress reticulocytes (from 60.5 +/- 4.1% to 52.9 +/- 4.2%) and in the percentage of beta s globin chains in very young mice (from 44.5 +/- 0.6% to 40.8 +/- 0.7%). These results demonstrate that it is possible to decrease the concentration of beta s chains and mRNA with the help of a hammerhead ribozyme. While the enormous amount of globin mRNA in reticulocytes is a challenge for ribozyme technology, the exquisite dependence of the delay time for formation of Hb S nuclei on the concentration of Hb S in red blood cells suggests that even a modest reduction in Hb S concentration would have therapeutic value.

HbS-oman heterozygote: a new dominant sickle syndrome.

Hemoglobin (Hb) S-Oman has two mutations in the beta-chains. In addition to the classic betaS mutation (beta6 Glu --> Val), it contains a second mutation in the same chain (beta121 Glu --> Lys) identical to that of HbOARAB. We have studied a pedigree of heterozygous carriers of HbS-Oman that segregates into two types of patients: those expressing about 20% HbS-Oman and concomitant -/ thalassemia and those with about 14% of HbS-Oman and concomitant -/- thalassemia. The higher expressors of S-Oman have a sickle cell anemia (SS) clinical syndrome of moderate intensity, while the lower expressors have no clinical syndrome, and are comparable to the solitary case first described in Oman. In addition, the higher expressors exhibit a unique form of irreversibly sickled cell reminiscent of a "yarn and knitting needle" shape, in addition to folded and target cells. The CSAT of S-Oman is identical to that of S-Antilles, another supersickling hemoglobin, whose carriers express the abnormal hemoglobin at 40% to 50%, with a very similar clinical picture to HbS-Oman. Because the level of expression is so different and the clinical picture so similar, and based on the hemolysates CSAT's, we conclude that HbS-Oman produces pathology beyond its sickling tendencies. A clue for this additional pathogenesis is found in the fact that homozygous HbOARAB, which has the same second substitution as S-Oman, has a moderately severe hemolytic anemia; when HbOARAB is combined with HbS, it makes the phenotype of this double heterozygote as severe as SS. Properties of HbS-Oman red blood cells (RBCs) include reticulocytes that are much denser than normal (similar to those of SC and CC disease), a decrease in the Km for Ca2+ needed to activate the Gardos' channel (making this transporter more sensitive to Ca2+), increased association of HbS-Oman with the RBC membrane, the presence of dense cells by isopycnic gradient, the presence of folded cells, and abundant nidus of polymerization under the membrane. Other properties include a clear increase in volume and N-ethylmaleimide-stimulated K:Cl cotransport in RBCs expressing more than 20% HbS-Oman. We conclude that the pathology of heterozygous S-Oman is the product of the sickling properties of the beta6 Val mutation which are enhanced by the second mutation at beta121. In addition, the syndrome is further enhanced by a hemolytic anemia induced by the mutation at beta121. We speculate that this pathology results from the abnormal association of the highly positively charged HbS-Oman (3 charges different from normal hemoglobin) with the RBC membrane.

Nonperfusion of retina and choroid in transgenic mouse models of sickle cell disease.

PURPOSE: To determine if vascular occlusion and nonperfusion is associated with the outer retinal atrophy, retinopathy, and choroidopathy (chorioretinopathy) that occurs in the alpha H beta S[beta MDD] and alpha H beta S [alpha MD beta MDD] transgenic mouse models of sickle cell disease. METHODS: Mice from the alpha H beta S[beta MDD] and alpha H beta S[alpha MD beta MDD] transgenic mouse lines that express high levels of human beta S globin were anesthetized and administered horseradish peroxidase (HRP) intracardially. After 1 min, the animals were sacrificed, and the retina from one eye was excised, fixed, and developed in diaminobenzidine (DAB). The contralateral eye was fixed, embedded whole in glycol methacrylate, and HRP developed in 2.5 microns sections. RESULTS: HRP reaction product (HRP-RP) and stained erythrocytes (RBCs) (due to endogenous peroxidase) were diffusely distributed within all vascular lumens in flatmount retinas from control animals (littermates homozygous for the mouse Beta Major deletion not expressing the beta S transgene). In 42.5% of the transgenic mice expressing beta S without any proliferative retinopathy, many blood vessels contained RBC plugs and lacked lumenal HRP-RP. In addition to packed RBCs, fibrin was sometimes present at sites of occlusion. In sections from whole eyes of the same animals, foci of photoreceptor degeneration were associated with areas of choriocapillaris nonperfusion (lumen that lacked HRP-PR). In areas with normal photoreceptors, the choriocapillaris appeared perfused (HRP-RP was present). In animals with proliferative chorioretinopathy, some neovascular formations lacked luminal HRP-RP, suggesting autoinfarction. CONCLUSIONS: Nonperfused retinal and choroidal vessels were observed in mice from the alpha H beta S[beta MDD] and alpha H beta S[alpha MD beta MDD] lines without retinal and choroidal neovascularization, whereas, all mice with neovascularization had nonperfused areas. Furthermore, small foci of PR loss were associated with areas of nonperfused choriocapillaris. These results suggest that sickle cell-mediated vaso-occlusions are an initial event in the chorioretinopathy and outer retinal atrophy that occurs in these models.

Red blood cells of a transgenic mouse expressing high levels of human hemoglobin S exhibit deoxy-stimulated cation flux.

Deoxy-stimulated cation fluxes have been implicated in the generation of the dense and irreversibly sickled red blood cells (RBCs) in patients homozygous for hemoglobin S (SS). We now report on the effect of short term deoxygenation on K+ and Na+ transport in RBCs from control mice (C57Bl/6J) and a transgenic (alphaHbetaS[betaMDD]) mouse line that expresses high levels of human alphaH and betaS-chains and has a small percent dense cells but does not exhibit anemia. In transgenic mouse RBCs (n = 5) under oxygenated conditions, K+ efflux was 0.22 +/- 0.01 mmol/L cell x min and Na+ influx was 0.17 +/- 0.02 mmol/L cell x min. Both fluxes were stimulated by 10 min deoxygenation in transgenic but not in control mice. The deoxy-stimulated K+ efflux from transgenic mouse RBCs was about 55% inhibited by 5 nm charybdotoxin (CTX), a blocker of the calcium activated K+-channel. To compare the fluxes between human and mouse RBCs, we measured the area of mouse RBCs and normalized values to area per liter of cells. The deoxy-simulated CTX-sensitive K+ efflux was larger than the CTX-sensitive K+ efflux observed in RBCs from SS patients. These results suggest that in transgenic mice, deoxygenation increases cytosolic Ca2+ to levels which open Ca2+-activated K+ channels. The presence of these channels was confirmed in both control and transgenic mice by clamping intracellular Ca2+ at 10 microM with the ionophore A23187 and measuring Ca2+-activated K+ efflux. Both types of mouse had similar maximal rates of CTX-sensitive, Ca2+-activated K+ efflux that were similar to those in human SS cells. The capacity of the mouse red cell membrane to regulate cytosolic Ca2+ levels was examined by measurements of the maximal rate of calmodulin activated Ca2+-ATPase activity. This activity was 3-fold greater than that observed in human RBCs thus indicating that mouse RBC membranes have more capacity to regulate cytosolic Ca2+ levels. In summary, transgenic mouse RBCs exhibit larger values of deoxy-stimulated K+ efflux and Na+ influx when compared to human SS cells. They have a similar Ca2+-activated K+ channel activity to human SS cells while expressing a very high Ca2+ pump activity. These properties may contribute to the smaller percent of very dense cells and to the lack of adult anemia in this animal model.

K:Cl cotransport in red cells of transgenic mice expressing high levels of human hemoglobin S.

K:Cl cotransport is involved in generating dense red blood cells (RBCs) in homozygotes for HbS (SS). We report on the properties of this transport system in RBCs from control and transgenic mice expressing high levels of human alpha(H) and beta(S) chains. Unlike human SS RBCs, mouse RBCs incubated in isotonic media exhibited a Cl(-)-dependent K+ efflux and therefore have a different set-point for activation. This basal efflux was slightly stimulated by cell swelling to values five times smaller than that in human SS cells; in addition, the delay time for activation was shorter in transgenic than in control mice, but fourfold longer than that of human SS cells. These properties cast doubt on the physiological impact of the mouse K:Cl cotransporter on RBC volume regulation in the mouse and suggest that there are intrinsic differences between the human K:Cl cotransporter and the putative transporter in mice.

Properties of the mouse alpha-globin HS-26: relationship to HS-40, the major enhancer of human alpha-globin gene expression.

HS-26, the mouse homologue of HS-40, is the major regulatory element of the mouse alpha-globin gene locus. Like HS-40, HS-26 is located within an intron of a house-keeping gene; comparison of the nucleotide sequences of HS-26 and HS-40 reveals conservation of the sequences and positions of several DNA binding motifs in the 5' regions of both elements (3 GATA, 2 NFE-2, and 1 CACCC sites) and the absence in HS-26 of three CACCC sites and one GATA site that are present in the 3' region of HS-40, suggesting that the two elements might not be identical. We report here that when HS-26 is linked to a 1.5 kb Pstl human alpha-globin gene fragment, it has a weak enhancer activity in induced MEL cells and in transgenic embryos, and it does not have any detectable activity in adult transgenic mice. This suggests that HS-26 does not have Locus Control Region (LCR) activity but can act as an enhancer during the embryonic life when integrated at a permissive locus. To further test the importance of HS-26 at its natural locus, we have generated embryonic stem cells and chimeric animals in which 350 bp containing HS-26 have been replaced by a neomycin resistance gene by homologous recombination. The sizes of the chimeras' red cells were then estimated by measuring forward scattering on a FacsScan apparatus in hypotonic conditions. This revealed that a fraction of the chimeric animals' red cells were smaller than normal mouse red cells and were very similar to cells from mice heterozygous for alpha-thalassemia. Density gradient analysis also suggested the presence of thalassemic cells. These results indicated that despite its lack of LCR activity, HS-26 is important for the regulation of the mouse alpha-globin gene locus.

Roles of alpha 114 and beta 87 amino acid residues in the polymerization of hemoglobin S: implications for gene therapy.

Three novel recombinant mutants of sickle hemoglobin (Hb S, beta 6Glu-->Val) have been constructed to assess the role of proline at alpha 114 and threonine at beta 87 in the polymerization of deoxygenated Hb S. Using the hemoglobin expression system (pHE2) designed in our laboratory, four plasmids were expressed separately in Escherichia coli to produce the four recombinant hemoglobins: r Hb S (beta 6Glu-->Val); r Hb S-Chiapas (beta 6Glu-->Val, alpha 114Pro-->Arg); r Hb S-D-Ibadan (beta 6Glu-->Val, beta 87Thr-->Lys); and r Hb S-Chiapas-D-Ibadan (beta 6Glu-->Val, alpha 114Pro-->Arg, beta 87Thr-->Lys). The structural features of these four recombinant hemoglobins were analyzed by proton nuclear magnetic resonance spectroscopy, and were found to be similar to those of human normal adult hemoglobin (Hb A) under identical conditions. The recombinant hemoglobins were further investigated by measuring the oxygen-binding properties, which were found to be comparable to those of Hb A. Delay-time gelation studies of the three mutants of r Hb S were carried out in 1.8 M potassium phosphate (pH 7.34) by a temperature jump from 4 degrees C to 30 degrees C and an increase in delay time over that of r Hb S was observed, as well as an overall decrease in the polymerization of these three mutants of Hb S. A more detailed and quantitative investigation has also been carried out to determine the equilibrium solubility (Csat) in 0.1 M potassium phosphate (pH 7.35) at 25 degrees C of the three Hb S mutants as well as of mixtures of these mutants with Hb S versus mixtures of fetal hemoglobin (Hb F) and Hb A with Hb S. The inhibition of polymerization demonstrated in these experiments suggests that the interactions involving the two amino acid residues alpha 114Pro and beta 87Thr are very important to the formation of Hb S polymer, and modification of these amino acids results in an anti-sickling potential. Of particular interest is the inhibitory effect of alpha 114Pro-->Arg, which offers a novel opportunity to use an alpha-chain construct, in addition to a beta-chain construct in the same vector, in gene therapy for sickle cell anemia, with the objective of modifying a larger number of hemoglobin tetramers at a given level of expression.

Pulmonary entrapment of sickle cells: the role of regional alveolar hypoxia.

Pulmonary microvascular occlusion by abnormally adherent and/or nondeformable sickle red blood cells (SS cells) may contribute to the pathogenesis of acute chest syndrome of sickle cell disease. We hypothesized that regional alveolar hypoxia reduces SS cell deformability and, by causing regional vasoconstriction, slows regional perfusion, facilitating endothelial adhesion and mechanical entrapment of cells. In isolated rat lungs perfused at constant average flow with physiological salt solution, we separately ventilated the two lungs: one with 95% O2 and the other with 0, 2.5, 5, or 21% O2. We infused a bolus of 99mTc-labeled SS cells or normal human AA cells along with 113Sn-labeled 15-mu m microspheres as a perfusion marker, then sliced the lungs and counted 99mTc and 113Sn. Weight-normalized perfusion decreased with hypoxia (P < 0.02). Retention of AA cells (perfusion-normalized) averaged approximately 1% in lungs ventilated with 95% O2 and increased only twofold with 0% O2. In contrast, retention of SS cells averaged 3-fold higher than that of AA cells at 95 and 5% O2, 15-fold higher at 2.5% O2, and 25-fold higher at 0% O2 (P < 0.01). Histological examination demonstrated entrapment of individual SS cells in alveolar capillaries of hypoxic but not well-oxygenated lungs. Relief of hypoxia, but not increased perfusate flow, caused prompt efflux of most entrapped cells, which were primarily high-density (high mean corpuscular hemoglobin concentration) cells. Thus substantial retention of SS cells does not occur without hypoxia, but regional hypoxia and/or the resulting vasoconstriction causes extraordinary regional retention of dense SS cells, a phenomenon that appears to be due more to mechanical entrapment of nondeformable cells in capillaries than to endothelial adhesion.

A second generation transgenic mouse model expressing both hemoglobin S (HbS) and HbS-Antilles results in increased phenotypic severity.

We report on a second generation of transgenic mice produced by crossing a transgenic mouse line expressing high levels of human alpha and beta S chains (alpha H beta S [beta MDD]) with a line expressing human alpha and beta S-Antilles (beta SAnt). We hypothesized that mice expressing both hemoglobins (Hbs) would have a more severe phenotype because the reduced oxygen affinity and solubility of the beta S-Antilles might enhance the rate and extent of polymer formation. We obtained mice that expressed both beta S and beta S-Antilles. The doubly transgenic mice that are heterozygous for deletion of mouse beta Major (beta MD) occurred with reduced frequency and those that are homozygous for deletion of mouse beta Major (beta MDD) occurred at a much reduced frequency and suffered early mortality. Human alpha was 58% of all alpha globin for all animals, whereas beta S and beta S-Antilles were 34% and 28% of all beta globins for beta MD mice and 42% and 36% for beta MDD mice. Hematocrit, Hb, and mean corpuscular Hb were normal for all transgenic mice, but reticulocyte levels were higher for the doubly transgenic mice versus alpha H beta S [beta MDD] mice older than 30 days (10.0% +/- 1.0% v 4.3% +/- 0.4%; P < .001, mean +/- SE, n = 20 and n = 10, respectively) and control mice (3.9% +/- 0.4%). Reticulocytosis was more severe in mice less than 30 days old ( > 20% for alpha H beta S beta S-Ant[beta MDD] mice). The median mean corpuscular hemoglobin concentration of doubly transgenic mice was higher than that of alpha H beta S[beta MDD] mice with a variable number of very dense cells. Delay times for polymerization of Hb in red blood cells from alpha H beta S beta S-Ant[beta MDD] mice were shorter than those of alpha H beta S[beta MDD] mice, and there were fewer cells with delay times greater than 100 seconds. Urine-concentrating ability in control mice under ambient conditions is 2,846 +/- 294 mOsm and was reduced 30% to 1,958 +/- 240 mOsm, P < 4 x 10(-8) in all mice expressing both transgenes. We conclude that doubly transgenic mice have a more severe phenotype than either of the two parental lines. These mice may be suitable for validating therapeutic intervention in sickle cell disease.

High expression of human beta S- and alpha-globins in transgenic mice: hemoglobin composition and hematological consequences.

A line of transgenic mice (alpha H beta S-11; where alpha H is human alpha-globin) was created in which the human beta S and human alpha 2 globin genes, each linked to the beta-globin locus control region, were cointegrated into the mouse genome. On a normal genetic background, the transgenic mice produced 36% human beta S-globin chains with an alpha H/beta S ratio of 1.3. Higher levels of beta S were achieved by breeding the transgenic mice with mutant mice carrying a mouse beta major-globin gene deletion. Mice heterozygous for the beta major deletion (alpha H beta S[beta MD]; MD, mouse deletion) had 54% beta S with an alpha H/beta S ratio of 1.0; mice homozygous for the beta major deletion (alpha H beta S[beta MDD]) had 72.5% beta S and an alpha H/beta S ratio of 0.73. Because mouse alpha chains inhibit hemoglobin (Hb) S polymerization, we bred the mice to heterozygosity for a mouse alpha-globin deletion. These mice (alpha H beta S[alpha MD beta MDD]) had an increased alpha H/beta S ratio of 0.89 but expressed 65% beta S. Expression of the human genes cured the thalassemic phenotype associated with the murine beta major deletion. Transgenic alpha H beta S[beta MDD] mice had normal hematocrit and Hb and somewhat elevated reticulocytes (6% vs. 3% for control), whereas the mice carrying the alpha-globin deletion (alpha H beta S[alpha MD beta MDD]) had a normal hematocrit and Hb and more elevated reticulocytes (10.3 +/- 7.6% vs. 3.4 +/- 1.0%). Expression of the transgene restored a normal distribution of erythrocyte densities when compared to thalassemic mice; however, the average mean corpuscular Hb concentration of alpha H beta S[beta MDD] mice increased to 35.7 g/dl (vs. control 33.7 g/dl) whereas that of alpha H beta S[alpha MD beta MDD] mice was further elevated to 36.3 g/dl. The intrinsic oxygen affinity was increased in transgenic mouse erythrocytes at 280 milliosmolal, and the PO2 at midsaturation of alpha H beta S[alpha MD beta MDD] erythrocytes was higher than that of alpha H beta S[beta MDD] cells (37.4 +/- 2 vs. 33.5 +/- 1 mmHg). The higher values of the mean corpuscular Hb concentration and intrinsic PO2 at midsaturation, which favor in vivo sickling, may explain the slightly more severe hematological picture in alpha H beta S[alpha MD beta MDD] mice. We conclude that the transgenic mouse with high Hb S expression does not exhibit adult anemia but does have abnormal hematological features: increased erythrocyte density, high oxygen affinity, and reticulocytosis with increased stress reticulocytes.

High expression of human beta S- and alpha-globins in transgenic mice: erythrocyte abnormalities, organ damage, and the effect of hypoxia.

A line of transgenic mice with two cointegrated transgenes, the human beta S- and alpha 2-globin genes, linked to the beta-globin locus control region was produced and bred with mice carrying a deletion of the mouse beta major-globin gene. In transgenic mice homozygous for the beta major deletion (alpha H beta S[beta MDD]; where alpha H is human alpha-globin and MD is mouse deletion), 72.5 +/- 2.4% (mean +/- SD) of the beta-chains are beta S and the ratio of alpha H- to beta S-globin was 0.73. Introduction of a heterozygous mouse alpha-globin deletion into mice homozygous for the beta major deletion (alpha H beta S[alpha MD beta MDD]) resulted in 65.1 +/- 8.5% beta S and a human alpha/beta ratio of 0.89 +/- 0.2. Sickling occurs in 95% of erythrocytes from alpha H beta S[beta MDD] mice after slow deoxygenation. Transmission electron microscopy revealed polymer fiber formation but not fascicles of fiber. Increased organ weight was noted in lung, spleen, and kidney of transgenic mice vs. controls that may be due to hypertrophy or increased blood volume in the lungs and/or increased tissue water content. The hemoglobin content of lung, spleen, and kidney was also elevated in transgenic animals due to trapped hemoglobin and/or increased blood volume. When transgenic and control mice were examined by magnetic resonance imaging at 9.4 tesla, some transgenic animals had enlarged kidneys with prolonged relaxation time, consistent with increased organ weight and water content. The glomerular filtration rate was elevated in transgenic animals, which is characteristic of young sickle cell patients. Furthermore, exposure to hypoxia resulted in significantly decreased hematocrit, increased erythrocyte density, and induced a urine-concentrating defect. We conclude that the transgenic mouse line reported here has chronic organ damage and further hematological and organ dysfunction can be induced by hypoxia.

Rapid increase in red blood cell density driven by K:Cl cotransport in a subset of sickle cell anemia reticulocytes and discocytes.

We have previously demonstrated that young normal (AA) and sickle cell anemia (SS) red blood cells are capable of a volume regulatory decrease response (VRD) driven by a K:Cl cotransporter that is activated by low pH or hypotonic conditions. We now report on the characteristics of young SS cells (SS2, discocytes) capable of rapid increase in density in response to swelling. We have isolated cells with high VRD response (H-VRD) and low VRD response (L-VRD) cells by incubation and density-gradient centrifugation under hypotonic conditions. Comparison of these cells in patients homozygous for hemoglobin (Hb)S indicated that H-VRD cells have 91% more reticulocytes (P less than 9 x 10(-9) than L-VRD cells, 25% less HbF (P less than 5.5 x 10(-5), 106% more NEM (N-methylmaleimide)-stimulated K:Cl cotransport activity (P less than 2 x 10(-4), and 86% more volume-stimulated K:Cl cotransport activity (P less than 1.8 x 10(-3). H-VRD and L-VRD cells have similar G-6-PD and Na+/H+ antiport activity. In agreement with the reduced percent HbF in H-VRD cells, F cells (red blood cells that contain fetal Hb) are depleted from the H-VRD population; however, F reticulocytes are enriched in the H-VRD population to the same extent as non-F reticulocytes, which suggests that both F and non-F reticulocytes have a similar initial distribution of volume-sensitive K:Cl cotransport activity but that it may be more rapidly inactivated in F than in S reticulocytes. We find that H-VRD cells consist of 20% reticulocytes (or 79% of all reticulocytes in SS2) and 80% more mature cells. This study demonstrates the role of K:Cl cotransport in determining red blood cell density, the heterogeneity of K:Cl cotransport activity in reticulocytes, and the capacity for rapid change in the density of reticulocytes with high K:Cl cotransport activity. We speculate that the H-VRD population may be more susceptible to generation of dense and irreversibly sickled cells.

Na+/H+ exchange is increased in sickle cell anemia and young normal red cells.

Red cell volume regulation is important in sickle cell anemia because the rate and extent of HbS polymerization are strongly dependent on initial hemoglobin concentration. We have demonstrated that volume-sensitive K:Cl cotransport is highly active in SS whole blood and is capable of increasing MCHC. We now report that Na+/H+ exchange (Na/H EXC), which is capable of decreasing the MCHC of erythrocytes with pHi less than 7.2, is also very active in the blood of patients homozygous for HbS. The activity of Na/H EXC (maximum rate) was determined by measuring net Na+ influx (mmol/liter cell.hr = FU) driven by an outward H+ gradient in oxygenated, acid-loaded (pHi6.0), DIDS-treated SS cells. The Na/H EXC activity was 33 +/- 3 FU (mean +/- SE) (n = 19) in AA whites, 37 +/- 8 FU (n = 8) in AA blacks, and 85 +/- 15 FU (n = 14) in SS patients (P less than 0.005). Separation of SS cells into four density-defined fractions by density gradient revealed mean values of Na/H EXC four to five times higher in reticulocytes (SS1), discocytes (SS2) and dense discocytes (SS3), than in the fraction containing irreversibly sickled cells and dense discocytes (SS4). In contrast to K:Cl cotransport, which dramatically decreases after reticulocyte maturation, Na/H EXC persists well after reticulocyte maturation. In density-defined, normal AA red cells, Na/H EXC decreased monotonically as cell density increased. In SS and AA red cells, the magnitude of stimulation of Na/H EXC by cell shrinkage varied from individual to individual.(ABSTRACT TRUNCATED AT 250 WORDS)