Novel permeability characteristics of red blood cells from sickle cell patients heterozygous for HbS and HbC (HbSC genotype).

Individuals heterozygous for HbS and HbC (HbSC) represent about 1/3(rd) of sickle cell disease (SCD) patients. Whilst HbSC disease is generally milder, there is considerable overlap in symptoms with HbSS disease. HbSC patients, as well as HbSS ones, present with the chronic anaemia and panoply of acute vaso-occlusive complications that characterize SCD. However, there are important clinical and haematological differences. Certain complications occur with greater frequency in HbSC patients (like proliferative retinopathy and osteonecrosis) whilst intravascular haemolysis is reduced. Patients with HbSC disease can be considered as a discrete subset of SCD cases. Although much work has been carried out on understanding the pathogenesis of SCD in HbSS homozygotes, including the contribution of altered red blood cell permeability, relatively little pertains directly to HbSC individuals. Results reported in the literature suggest that HbSC cells, and particularly certain subpopulations, present with similar permeability to HbSS cells but there are also important differences - these have not been well characterized. We hypothesise that their unique cell transport properties accounts for the different pattern of disease in HbSC patients and represents a potential chemotherapeutic target not shared in red blood cells from HbSS patients. The distinct pattern of clinical haematology in HbSC disease is emphasised here. We analyse some of the electrophysiological properties of single red blood cells from HbSC patients, comparing them with those from HbSS patients and normal HbAA individuals. We also use the isosmotic haemolysis technique to investigate the behaviour of total red blood cell populations. Whilst both HbSS and HbSC cells show increased monovalent and divalent (Ca(2+)) cation conductance further elevated upon deoxygenation, the distribution of current magnitudes differs, and outward rectification is greatest for HbSC cells. In addition, although Gd(3+) largely abolishes the cation conductance of both HbSS and HbSC cells, only in HbSS ones are currents inhibited by the aminoglycosides like streptomycin. This distinction is retained in isosmotic lysis experiments where both HbSS and HbSC cells undergo haemolysis in sucrose solutions but streptomycin significantly inhibits lysis only in HbSS cells. These findings emphasise similarities but also differences in the permeability properties of HbSS and HbSC cells, which may be important in pathogenesis.

Non-electrolyte permeability of deoxygenated sickle cells compared.

The passive permeability pathways of red cells are poorly defined, with the exception of the Gardos channel. Several cation and anion pathways can be induced by a variety of manoeuvres, however, including treatment with oxidants, low ionic strength (LIS), shrinkage, swelling and also infection with the intra-erythrocytic malaria parasite. Several of these stimuli (malaria, swelling, LIS), in addition, also activate a non-electrolyte this permeability. Sickle cells uniquely show a deoxygenation-induced pathway, which is termed P(sickle) and is usually considered to be a conductive cationic pathway. In this report, we explore further the extent to which this permeability pathway of deoxygenated sickle cells is available for non-electrolyte transport. We show that a number of solutes are permeable, with greater permeability to sugars (notably lactose and maltose) and smaller molecules, and less to charged or zwitterionic species. Red cells from heterozygous HbSC patients also showed deoxygenation-induced haemolysis in isosmotic sucrose solution, though to a slightly lesser extent than for red cells from homozygous sickle cell patients. In contrast to sickle cells, red cells from beta-thalassaemic patients did not show haemolysis in isosmotic sucrose solutions, regardless of the O(2) tension. Of the secondary cellular changes resulting from incubation in non-electrolyte solutions (which include imposition of a highly positive membrane potential, marked intracellular alkalinisation and cell shrinkage), none appear to correlate with activation of the non-electrolyte permeability. Rather, findings indicate that it is low ionic strength per se that is responsible. Normal red cells also show changes in ionic and non-electrolyte permeability in low ionic strength media, and these permeabilities are compared to those found in deoxygenated sickle cells. The extent to which these different permeabilities in normal and sickle red cells can be ascribed to one or more common pathways remains to be determined.

Prolactin delays hair regrowth in mice.

Mammalian hair growth is cyclic, with hair-producing follicles alternating between active (anagen) and quiescent (telogen) phases. The timing of hair cycles is advanced in prolactin receptor (PRLR) knockout mice, suggesting that prolactin has a role in regulating follicle cycling. In this study, the relationship between profiles of circulating prolactin and the first post-natal hair growth cycle was examined in female Balb/c mice. Prolactin was found to increase at 3 weeks of age, prior to the onset of anagen 1 week later. Expression of PRLR mRNA in skin increased fourfold during early anagen. This was followed by upregulation of prolactin mRNA, also expressed in the skin. Pharmacological suppression of pituitary prolactin advanced dorsal hair growth by 3.5 days. Normal hair cycling was restored by replacement with exogenous prolactin for 3 days. Increasing the duration of prolactin treatment further retarded entry into anagen. However, prolactin treatments, which began after follicles had entered anagen at 26 days of age, did not alter the subsequent progression of the hair cycle. Skin from PRLR-deficient mice grafted onto endocrine-normal hosts underwent more rapid hair cycling than comparable wild-type grafts, with reduced duration of the telogen phase. These experiments demonstrate that prolactin regulates the timing of hair growth cycles in mice via a direct effect on the skin, rather than solely via the modulation of other endocrine factors.

Identification of differentially expressed genes during a wool follicle growth cycle induced by prolactin.

The wool follicles of New Zealand Wiltshire sheep can be induced to undergo growth cycles by manipulating circulating prolactin levels. Altered patterns of gene expression through this cycle were examined using differential display, and nine sequence tags for differentially expressed genes were isolated. Four of these tags were identified as fragments of known genes, encoding a wool keratin, KRTAP3.2, a desmosome component, desmoglein 1, an epithelial cell marker, stratifin, and a protein kinase, Clk3. All four genes were shown to be downregulated in telogen skin compared with anagen. In situ hybridization showed that all had localization patterns which included cells that are absent in telogen. The stratifin tag was used to clone a cDNA that incorporated a complete open-reading frame for ovine stratifin. Ovine stratifin is similar to the human form, showing only six single residue differences in the predicted amino acid sequence. Stratifin probably acts as a regulator of other proteins involved in trichocyte cell cycling and differentiation. Clk3 is involved in regulating RNA splicing. KRTAP3.2 and Dsg1 both play structural roles in hair follicles. The other five tags, including two representing genes that were upregulated during catagen, could not be identified by homology. Differential display is an effective means of identifying genes involved in follicle function and, potentially, of genes controlling the growth cycle.

Prolactin signaling influences the timing mechanism of the hair follicle: analysis of hair growth cycles in prolactin receptor knockout mice.

Pituitary PRL regulates seasonal hair follicle growth cycles in many mammals. Here we present the first evidence implicating PRL in the nonseasonal, wave-like pelage replacement of laboratory mice. In this study we show that messenger RNA transcripts encoding the one long and two short forms of PRL receptor are present in the skin of adult and neonate mice. The receptor protein was immunolocalized to the hair follicle as well as the epidermis and sebaceous glands. Furthermore, PRL messenger RNA was detected within skin extracts, suggesting a possible autocrine/paracrine role. Analysis of the hair growth phenotype of PRL gene-disrupted mice (PRLR(-/-)) revealed a change in the timing of hair cycling events. Although no hair follicle development differences were noted in PRLR(-/-) neonates, observations of the second generation of hair growth revealed PRLR(-/-) mice molted earlier than wild types (PRLR(+/+)). The advance was greater in females (29 days) than in males (4 days), resulting in the elimination of the sexual dimorphism associated with murine hair replacement. Heterozygotes were intermediate between PRLR(-/-) and PRLR(+/+) mice in molt onset. Once initiated, the pattern and progression of the molt across the body were similar in all genotypes. Although all fiber types were present and appeared structurally normal, PRLR(-/-) mice had slightly longer and coarser hair than wild types. These findings demonstrate that PRL has an inhibitory effect on murine hair cycle events. The pituitary PRL regulation of hair follicle cycles observed in seasonally responsive mammals may be a result of pituitary PRL interacting with a local regulatory mechanism.

STAT5b is required for GH-induced liver IGF-I gene expression.

Although the increased expression of Igf-I in liver in response to GH is well characterized, the intracellular signaling pathways that mediate this effect have not been identified. Intracellular signaling molecules belonging to the Janus kinase-signal transducer and activator of transcription 5b (JAK2-STAT5b) pathway are activated by GH and have previously been shown to be required for sexually dimorphic body growth and the expression of liver cytochrome P450 proteins known to be regulated by the gender-specific temporal patterns of pituitary GH secretion. Here, we evaluate the role of STAT5b in GH activation of Igf-I by monitoring the induction of Igf-I mRNA in livers of wild-type and Stat5b(-/-)mice stimulated with exogenous pulses of GH. GH induced the expression of liver Igf-I mRNA in hypophysectomized male wild-type, but not in hypophysectomized male Stat5b(-/-) mice, although the Stat5b(-/-) mice exhibit both normal liver GH receptor expression and strong GH induction of Cytokine-inducible SH2 protein (Cis), which is believed to contribute to the down-regulation of GH-induced liver STAT5b signaling. Thus, STAT5b plays an important and specific role in liver Igf-I gene expression.

Structure and sequence of the bovine butyrophilin gene.

The complete sequence of the bovine butyrophilin gene (BTN) is described and compared with the mouse gene (Btn). Both genes contain seven exons separated by six introns, and the organisation of exons is closely associated with structural domains of the protein. Individual exons of BTN and Btn are 68-87% similar in sequence. There are no canonical TATA or CCAAT boxes associated with the transcription initiation sites in the genes of either species. However, a number of potential binding sites for transcription factors were identified in the 5'-flanking DNA, some of which may function in regulating expression of the gene in mammary tissue. Conservation of a 110-bp region in the promoters of BTN and Btn may have some functional significance. Cloning and sequencing of BTN provides an additional mammary-specific gene promoter that may be used for driving the expression of transgenes in the lactating mammary gland, and for determining the basis for tissue-specific gene expression. In addition, the sequence of BTN may be used to map intragenic polymorphisms and identify quantitative trait loci in commercial livestock.

Expression of alpha-lactalbumin, alpha-S1-casein, and lactoferrin genes is heterogeneous in sheep and cattle mammary tissue.

We used 35S-labeled cRNA probes to localize the sites of alpha-lactalbumin, alpha-S1-casein, and lactoferrin mRNA synthesis in sheep and forcibly weaned cattle mammary tissue. Expression of alpha-lactalbumin was absent in three of four "virgin" glands studied, present in some alveoli of "pregnant" glands but not in others, despite a similar histological appearance. In the early lactating gland, expression was high in those alveoli with few fat globules in their cells and lumen and was absent in alveoli with abundant fat globules. These observations suggest either that alpha-lactalbumin gene expression is linked to the long-term secretory activity of cells and falls once cells are resting or regressing, or that there are cyclical variations in expression, or that in the lactating gland some groups of epithelial cells are synthesizing alpha-lactalbumin and some are synthesizing fat. Expression patterns of alpha-S1-casein were similar to those of alpha-lactalbumin. Lactoferrin, in contrast, was expressed almost exclusively in the "fatty alveoli" of both species. Our results show that dramatic variations in milk gene expression can occur throughout the mammary gland of sheep and cattle and that at no stage of pregnancy, lactation, or involution can the gland be considered metabolically homogeneous.

STAT5b mediates the GH-induced expression of SOCS-2 and SOCS-3 mRNA in the liver.

Suppressor of cytokine signalling (SOCS) proteins act as part of a classical negative feedback loop regulating cytokine signal transduction. Expression of SOCS proteins is induced in response to cytokines and down-regulates the cytokine signal by inhibiting the JAK/STAT pathway. Growth hormone (GH) was previously shown to induce strong transient expression of SOCS-3 and to a lesser extent CIS, SOCS-1 and SOCS-2 in mouse liver (Adams, T.E., Hansen, J.A., Starr, R., Nicola, N.A., Hilton, D.J., Billestrup, N., 1998. Growth hormone preferentially induces the rapid, transient expression of SOCS-3, a novel inhibitor of cytokine receptor signalling. J. Biol. Chem. 273, 1285-1287.). In this work we have compared GH-induced SOCS gene expression in wild-type and STAT5b-deficient mice, and show that STAT5b is required for the induction of SOCS-2 and SOCS-3 in liver. In contrast, the absence of STAT5b has no effect on the GH-induced expression of CIS and SOCS-2 mRNA in the mammary gland. Suprisingly, there is no activation of SOCS-3 expression in mammary glands of wild-type and STAT5b mutant mice following GH administration. These results highlight both tissue- and factor-specific differences in the regulation of SOCS gene expression by STAT5a/b.

Detection of human papillomavirus DNA in cervical lesions by in-situ DNA hybridization.

Authors examined paraffin sections of 50 cervical specimens from 34 cases for the presence of human papillomavirus (HPV) type 6b, 11, 16, 18, 31 and 33 by in-situ hybridization using 35S-labelled HPV DNA probes. Specimens were classified according to the degree of dysplasia after histological examination. Viral nucleic acids were detected in 30 of 50 tissues (60%) in which 15 specimens had single, 10 double, 4 triple and 1 quadruple viral infections. In some cases, different viral nucleic acids were detected at separate sites in the same patient. Overall, no great variation in the frequency of each HPV was detected, but a pattern became apparent when the frequencies were compared with the grade of dysplasia. CIN II/III lesions contained one or more of the HPV types 16, 18, 31, 33 which are frequently associated with cervical carcinoma. In-situ hybridization offers sensitive means of investigating viral infection, gene expression and neoplastic transformation.

Identification of the specific sites of interaction between intercalating drugs and DNA.

A number of intercalating drugs have been found capable of causing site-specific inhibition of nick-translation in a DNA template of known sequence. Compounds of the 4'-(9-acridinylamino) methanesulphonanilide (AMSA) series cause selective inhibition in regions of G-C base pairs. Other intercalating drugs including ethidium bromide, adriamycin and actinomycin D also exhibited a G-C base pair preference although bisantrene-induced inhibition tended to be in regions of A-T base pairs. Diacridine compounds were more effective in inhibiting polymerase action as the linker chain was increased from 4 to 8 carbons. Results with mitonafide , anthracene derivatives, mithramycin and distamycin A are also presented. Inhibition caused by a given drug varied significantly from site to site in the DNA but apart from a preference for G-C or A-T rich regions, there seemed no preference for certain base sequences per se. Rather, it was felt that secondary structures, such as hairpins, in DNA might be of importance. The hypothesis is advanced that inhibition of polymerase action in this in vitro system may provide a useful and biologically relevant measure of the strength of drug binding at various DNA sites.

Failure of the intercalating agent 4'-(9-acridylamino)-methanesulphon-m -anisidide to induce DNA-repair replication in cultured human cells.

A search has been made for DNA-repair replication in cultured human cells treated with the DNA-intercalating agent 4'-(9-acridinylamino) methanesulphon--m-anisidide (m-AMSA). Previous reports had suggested that the transient appearance of protein-associated DNA-strand breaks in mammalian cells treated with m-AMSA might be indicative of a rapid DNA-repair process. The present experiments suggest that such a repair process is unlikely to occur as, even in cells treated with high concentrations of m-AMSA (50 microM) for 20 h, DNA repair replication could not be detected down to the limits of sensitivity (1 million nucleotides replaced per cell).

Photoreactivation of UV damage in Sminthopsis crassicaudata.

A comprehensive investigation has been made of photoreactivation of UV damage in cells cultured from the fat-tailed marsupial mouse, Sminthopsis crassicaudata. Maximal photoreversal of the lethal effects of germicidal UV radiation was obtained by exposure of cells to intense fluorescent black light at 37 degrees C. Dose-reduction factors of approximately 2 were obtained. This phenomenon was shown to be a true photoreactive not a photoprotective effect. Attempts to photoreverse the lethal effects of UV light by using white fluorescent light, or black lights at lower temperatures, proved ineffectual. Photoreactivation with black light at 37 degrees C for 30 min effectively photoreversed UV-induced pyrimidine dimers and also substantially reduced the levels of UV-induced DNA-repair replication. Sunlight was also found to be an effective source of photoreactivating light. Although a reasonable correlation was found between the lethal effects of UV light and the number of pyrimidine dimers persisting unrepaired in cellular DNA, some experiments did suggest that either a small subclass of dimers or some type of non-dimer damage contributed significantly to overall lethality. Two of the effects induced by UV light could not, however, be reversed by black light. These were sister-chromatid exchanges and the inhibition of DNA synthesis. The conclusion was reached that either these effects reflect non-dimer (non-photoreactivable damage) or that, under appropriate growth conditions, some damage rapidly disrupts the DNA, say within a replicon, in a manner which cannot be reversed even when the primary lesion has been subsequently removed.

Formaldehyde induced DNA-protein crosslinks in Escherichia Coli.

Exposure of Escherichia coli to low doses of formaldehyde induces interstrand cross-links in the cellular DNA, at least 50% of which involve protein "bridges" between the DNA strands. The biological importance of these cross-links is suggested by both the high yield of formation and by the inability of some sensitive repair deficient mutants to completely remove cross-links and bound protein from the DNA during post treatment incubation.

Effects of anti-GLUT antibodies on glucose transport into human erythrocyte ghosts.

We have studied the effects of anti-GLUT1 antibodies on the uptake of glucose into erythrocytes. Glucose transport into human erythrocyte ghosts was measured directly using 3H-2-deoxy-glucose, or indirectly by monitoring associated volume changes using light scattering. The uptake of glucose was significantly inhibited in ghosts resealed in solutions containing specific antibodies against GLUT1. Such an effect was not observed when an antibody against the oestrogen receptor, lacking specificity towards GLUT1, was employed instead. The antibodies were also without effect on the efflux of preloaded glucose from erythrocyte ghosts. The demonstration that anti-GLUT antibodies can inhibit glucose uptake is support for the hypothesis that they exaggerate the cytoplasmic barrier to glucose uptake created by endofacial segments of GLUT1.

Lactation-associated and prolactin-responsive changes in protein synthesis in mouse mammary cells.

Lactational function in the mammary epithelial cell is subject to complex regulation, most probably involving multiple extracellular and intracellular proteins that act at any of a number of levels. Although some of these proteins have been identified it is likely that additional controllers of lactation exist, but have yet to be discovered. In an effort to identify such proteins, a search was made for non-milk lactation-associated or prolactin-responsive proteins in primary mouse mammary epithelial cells and the mouse mammary epithelial cell line, COMMA-D using two-dimensional electrophoresis on large-format gels. These analyses revealed 12 proteins whose rate of synthesis was dependent on lactation state or on response to prolactin. Two of these (p77 and p63) were lactation-associated in primary cells and prolactin-responsive in COMMA-D cells. These two proteins were identified by amino acid sequencing as glucose-regulated protein 78 (GRP78) and protein disulphide isomerase (PDI). The localization of these proteins in the endoplasmic reticulum and their presence in other secretory cell types and tissues suggests that they have a function in the processing or secretion of milk proteins.

Chondrocyte regulation by mechanical load.

The effects of load on articular cartilage are complex. Dynamic loading of cartilage is associated with slight cell and tissue deformation as well as cyclical fluctuations in the hydrostatic pressure of cartilage and in fluid movement. Static loading results in expression of fluid from the tissue, concentrating extracellular matrix macromolecules and consequently increasing the concentrations of cations, reducing extracellular pH and increasing extracellular osmolarity. Each of these alterations is implicated in regulating the synthetic response of chondrocytes to load. However, the mechanisms by which these changes affect matrix turnover are poorly understood. In this review we consider how load may affect chondrocyte behaviour through its influence on membrane transport processes and thus on the intracellular environment.

Mechanisms involved in the increase in intracellular calcium following hypotonic shock in bovine articular chondrocytes.

The extracellular osmotic environment of chondrocytes fluctuates during joint loading as fluid is expressed from and reimbibed by the extracellular matrix. Matrix synthesis by chondrocytes is modulated by joint loading, possibly mediated by variations in intracellular composition. The present study has employed the Ca2+-sensitive fluoroprobe Fura-2 to determine the effects of hypotonic shock (HTS) on intracellular Ca2+ concentration ([Ca2+]i) and to characterise the mechanisms involved in the response for isolated bovine articular chondrocytes. In cells subjected to a 50% dilution, [Ca2+]i rapidly increased by approximately 250%, a sustained plateau being achieved within 300 s. The effect was inhibited by thapsigargin or by removal of extracellular Ca2+, indicating that the rise in [Ca2+]i reflects both influx from the extracellular medium and release from intracellular stores. Inhibition of the response by neomycin implicates activation of PLC and IP3 synthesis in the mobilisation of Ca2+ from intracellular stores. The rise was insensitive to inhibitors of L-type voltage-activated Ca2+ channels (LVACC) or reverse mode Na+/Ca2+ exchange (NCE) but could be significantly attenuated by ruthenium red, an inhibitor of transient receptor potential vanilloid (TRPV) channels and by Gd3+, a blocker of stretch-activated cation (SAC) channels. The HTS-induced rise in [Ca2+]i was almost completely absent in cells treated with Ni2+, a non-specific inhibitor of Ca2+ entry pathways. We conclude that in response to HTS the opening of SACC and a member of TRPV channel family leads to Ca2+ influx, simultaneously with the release from intracellular stores.

The effect of mechanical stress on cartilage energy metabolism.

Cartilage is routinely subjected to varying mechanical stresses which are known to affect matrix turnover by a variety of pathways. Here we show that mechanical loads which suppress sulphate incorporation or protein synthesis by articular chondrocytes, also inhibit rates of oxygen uptake and of lactate production. Although the mechanisms have not been definitively identified, it has been shown that high hydrostatic pressures reduce the activity of the glucose transporter GLUT. Furthermore, fluid expression consequent on static loading changes intracellular pH and ionic strength; intracellular changes which would reduce the activity of glycolytic enzymes. Both pathways would thus lead to a fall in rates of glycolysis and a reduction in intracellular ATP, and - since ATP concentrations directly affect sulphation of proteoglycans - a rapid fall in sulphate incorporation. Our results suggest that load-induced changes in matrix synthesis in cartilage can occur by means other than changes in gene expression.

The influence and interactions of hydrostatic and osmotic pressures on the intracellular milieu of chondrocytes.

The intracellular milieu of chondroctyes is regulated by an array of proteins in the cell membrane which operate as transport pathways, allowing ions and nutrients such as glucose and amino acids and metabolites such as lactate to cross the plasma membrane. Here we investigated the influence of hydrostatic pressure on intracellular calcium concentrations ([Ca(2+)](i)) in isolated bovine articular chondrocytes. We found that short applications of high hydrostatic pressures led to a significant increase in [Ca(2+)](i). The pressure-induced rise was abolished for long (240 sec) but not short (30 sec) pressure applications by removal of extracellular Ca(2+). The rise in pressure was also blocked by the inhibitors neomycin and thapsigargin confirming that pressure, by generating IP(3), led to an increase in [Ca(2+)](i) by mobilising the pool of Ca(2+) ions contained within intracellular stores. We also found that intracellular [Na(+)] was affected by a rise in osmotic pressure and further affected by application of hydrostatic pressure. The effect of hydrostatic pressure on sulphate incorporation depended strongly on extracellular osmolality. Since significant gradients in extracellular osmolality exist across intact cartilage, the results imply that responses of chondrocytes to the same pressure will vary depending on location in the joint. The results also indicate that hydrostatic pressures can affect several different transporter systems thus influencing the intracellular milieu and chondrocyte metabolism.