Active and passive cation transport and L antigen hertogeneity in low potassium sheep red cells

Several lines of experimental evidence are presented suggesting that the L antigens in low potassium (LK) sheep red cells are associated with separate Na(+)K(+) pump flux is distinct from the action of anti-L(l) on K(+) leak flux, implying that K(+) leak transport sites may not be converted into active pumps by the L antiserum. Treatment of LK red cells with trypsin completely abolished both the stimulation of K(+) pump flux and the enhancement of the rate of ouabain binding brought about by anti- L. That this effect is due to a total destruction of the L(p) determinant associated with the LK pump was evident from the complete failure of anti-L(p) to bind to trypsinized LK red cells. The L(p) antigen can be effectively protected against the trypsin attack by prior incubation with anti-L, indicating that the sites for antibody binding and trypsin action may be closely adjacent at the structural level. Trypsin treatment, however, did not interfere with anti-L(l) reducing ouabain insensitive K(+) leak influx, nor did it prevent binding of anti-L(ly), the hemolytically active L antibody which is probably identical with anti-L(l). The functional independence of the L(p) and L(l) sites was documented by the observation that anti-L(l) still reduced K(+) leak influx in LK cells with experimentally induced high potassium concentrations, at which K(+) pump flux is fully suppressed, whether or not anti-L(p) was binding to the L(p) antigen associated with the LK pump.     

LK sheep reticulocytosis: effect of anti-L on K influx and in vitro maturation

After massive hemorrhage, adult sheep with genotypically low potassium (LK) red cells temporarily produce high potassium (HK) cells with ouabain-sensitive K+ pump fluxes equivalent to mature HK red cells. In light of recent reports of different red cell volume populations accompanying the HK-LK transition also occurring in newborn LK sheep and the unresolved controversy over the effect of anti-L on K+ transport in these immature red cells, we have reexamined the K+ transport changes and the effect of anti-L in the newly formed HK cells at various times after anemic stress and under in vitro conditions. We found that approximately 7 d after bleeding, maximum reticulocytosis occurred in the peripheral blood. After separation by density centrifugation, the top 10% cell fraction contained 100% reticulocytes, with a mean cell volume 2.5 times larger than that of mature erythrocytes. These immature red cells were of HK type, and their K+ pump and leak fluxes were 30 and 10 times higher, respectively, than those found in mature LK cells. The new cells may possess HK- and LK- type pumps because K+ pump influx was significantly stimulated by anti- L. When separated by density centrifugation on days 9, 17, and 23 after bleeding, some of the cells apparently maintained their large size while gaining higher density. Large cells from day 9, kept in vitro for 22 h, showed anti-L-sensitive K+ pump and leak fluxes that declined within hours, paralleling the behavior of these cells in vivo, whereas cellular K+ levels changed much less. It is concluded that the newly formed red cells may belong to a stress-induced macrocytic cell population that does not acquire all of the characteristics of adult LK cells.     

Different red cell populations in newborn, genetically low potassium sheep: relation to hematopoietic, immunologic and physiologic differentiation

Three red cell populations have been distinguished in genotypically low potassium (LK) newborn sheep by an improved electrical sizing method and were best approximated by a logarithmic normal distribution. Labeling studies with ⁵¹Cr and ⁵⁹Fe exclude transformation of the three red cell populations into each other. Population I, consisting of large red cells (mean volume 36 μm³), with a comparatively slow electrophoretic mobility is present at birth and disappears within three to four weeks from circulation. These cells possess a high potassium (HK) steady state concentration, a K⁺ pump influx activity at least 5-fold greater than observed in adult LK red cells, very low amounts of the L antigens generally associated with the LK property, and do not respond to the stimulatory action of the L antibody. The first population is gradually replaced by population II comprising small red cells (mean volume 28 μm³) of intermediate electrophoretic mobility and with a peak production around day 20 after birth. The potassium concentration, [K⁺]_c, in these cells appears to be lower than in the cells of population I but the L antigen content is increased. Formation of population III (mean volume 30 μm³ and comparatively fast electrophoretic mobility) follows closely that of population II and is preceded by a sharp increase in reticulocytosis. The red cells of population III exhibit parameters characteristic for adult LK cells: low [K⁺]_c and K⁺ pump activity, fully developed L antigen content, and an almost maximal response to the K⁺ pump stimulating effect of anti-L. In L and M antigen positive LK red cells of newborn sheep, the development of the M antigen parallels that of the L antigen. The data are consistent with the hypothesis that cellular replacement and not maturation is the major factor in controlling the HK-LK transition in newborn sheep.     

L-antigen and active potassium transport in HK and LK red cells of Barbary sheep (Ammotragus lervia)

1. The potassium concentration in red cells of 21 Barbary sheep showed a bimodal distribution, with five animals of LK type (K+ conc. 30-45 mM) and 16 of HK type (K+ conc. 80-95 mM). 2. Evidence is presented that both Lp and Ll antigens are present on LK Barbary sheep red cells. 3. Active K+ transport in LK Barbary sheep red cells was stimulated 3-5 fold by sheep and goat anti-L. 4. Active K+ transport in HK Barbary sheep red cells was higher than in LK red cells. Five out of six HK animals tested showed no stimulation of active K+ transport with anti-L. One HK animal (2BA2) showed some stimulation of active K+ transport, and also absorbed some anti-L from antisera, suggesting that Lp antigen is present on these red cells. 5. Ouabain-sensitive ATPase in membranes from HK and LK Barbary sheep red cells showed kinetics characteristic of HK and LK membranes of domestic goats and sheep; the ATPase of LK Barbary sheep membranes sensitized with anti-L was stimulated 2-fold due to an alteration in the internal sodium and potassium affinities in favour of sodium.     

Binding characteristics of M and L isoantibodies to high and low potassium sheep red cells.

Binding of highly purified 125I labeled M and L antibodies, both belonging to the immunoglobulin G class, was studied in high potassium (HK) and low potassium (LK) sheep red cells. Anti-M and anti-L bound specifically to M and L antigen positive HK and LK red cells, respectively. Nonspecific binding was higher for anti-L to HK cells than for anti-M to LK cells. Once bound, the M and L antibodies were capable of inducing complement dependent immune hemolysis. Only 75-100 and 500-750 molecules of anti-M and anti-L immunoglobulins were required to hemolyze 50% of HK (MM) and LK (LL) red cells, respectively, suggesting that the M and L antigens may be clustered on the surfaces of these cells. Equilibrium binding studies revealed that the maximum number of M sites is 3-6 x 10(3) in HK (MM) and 1.5-4 x 10(3) in LK (LM) cells, respectively. In comparison, the number of L antigens is slightly lower in LK cells, about 1.2-1.8 x 10(3) in LL and less in LM(LK) red cells. The number of M and L antigens, therefore, is more than an order of magnitude larger than that of the Na+K+ pumps measured previously in these cells by 3H-ouabain binding, thus precluding a quantitative correlation between M and L antigens and the Na+K+ pumps different in the three genetic types of sheep red cells. The binding affinities of both anti-M and anti-L could not be described by a single equilibrium dissociation constant indicating heterogeneous antibody populations and /or variability in the antigenic sets of individual HK or LK cells. The pronounced heterogeneity of antigens and/or antibodies in both the M and L systems was reflected in the antibody association kinetics, which also exhibited a remarkable temperature dependence. The data suggest that the correlation between the M and L antigens and the Na+K+ pump molecules is more complex than that in goat red cells previously reported by others.     

GENETIC VARIATION IN THE SHEEP RED BLOOD CELL

1. There are 7 well-established red-cell antigen (blood group) loci. The R-O system has 3 phenotypes, R, O and i, identified by the ‘naturally occurring’ antibodies, anti-R and anti-O. The R and O substances are also present in soluble form in some body secretions. The expression of R and O is controlled by a dominant gene I, epistatic in effect, at an independent locus from that of R. The systems, A, C, M-L, B, D and X-2 are identified by means of ‘immune-type’ antibodies, and several of the loci have multiple alleles. An isoenzymic form of serum alkaline phosphatase is associated with the R-O system. The frequency for the genes at the various loci has been determined in a limited number of breeds. 2. Some sheep red cells have high K+ and low Na+ concentrations (HK type, or Key), others have low K+ and high Na⁺ concentrations (LK type or Kea). Two other rare forms exist; Key type which is HK but with lower than normal K+ values, and Kep type which has approximately equal Na⁺ and K⁺ concentrations. The red cells of foetuses and newborn lambs have high K+ levels irrespective of their potassium genotype. HK cells have 3–4 times greater (Na+-K+)-activated ATPase activity, a 3–4 times increased rate of active K+ transport and a larger number of ouabain-binding sites than LK cells. Antigen M is present on homozygous HK and heterozygous LK red cells, and antigen L is present on homozygous and heterozygous LK red cells. Sensitization of LK cells with anti-L stimulates active K+ transport and ATPase activity and exposes a larger number of ouabain-binding sites in these cells. Anti-M has no effect. The red cells of newborn lambs only show weak L and M antigen activity. It is postulated that L antigen inhibits cation transport in LK cells by masking the pump sites on the membrane. Immature red cells in LK-type sheep have a high rate of active K+ transport and yet have L antigen present. No satisfactory explanation for this has yet been advanced. There is no conclusive evidence that the potassium types have any significance from the point of view of adaptation or sheep breeding. The potassium-gene frequencies are known for a large number of breeds. 3. Two allelic genes, Hb⁴ and Hb^B control 3 haemoglobin phenotypes, A, AB, and B. Foetal haemoglobin (HbF) is present in foetuses and newborn lambs. Sheep with HbA also synthesize small amounts of another haemoglobin (HbC) and under conditions of severe anaemia, synthesis of HbC takes over from that of HbA. No change in HbB is observed in anaemia. A rare haemoglobin (HbD) has been found in 3 Yugoslavian sheep. Hbs A, B, C and F differ in their physicochemical properties; they share the same alpha chains but their non-alpha chains differ in a number of amino acids. HbD differs from HbA in one amino acid in the alpha chain. Certain genetic aspects are discussed. There is some evidence that sheep with HbA are less fertile than those with HbB. The gene frequencies for Hb are known for a large number of breeds. 4. Two isoenzymic forms of carbonic anhydrase are found in red-cell lysates and these are controlled by a pair of allelic autosomal genes, producing 3 phenotypes, CAF, CAFS and CAS. Only a few breeds have been studied but CA^F is apparently quite rare. 5. An unidentified protein, designated ‘X’ is present in electrophoretic separations of haemolysates from some sheep. Its presence is dominant to its absence. Polymorphism at this locus is present in all breeds so far studied. 6. A deficiency of reduced glutathione (GSH) in red cells is found in some sheep and is inherited as an autosomal recessive disorder. Sheep with this deficiency have lower red-cell K+ and Na^f concentrations than normal and it is suggested that the HK GSH-deficient sheep may be Ked type sheep. This deficiency has so far only been found with certainty in one breed of sheep. 7. In sheep twin chimeras, admixture of red-cell antigens, haemoglobin and ‘X’ protein types has been found. Various aspects of chimerism, which occurs only rarely in sheep, are discussed. 8. The significance of the genetic variation is discussed in the light of the physiology and immunology of the red cell and of the sheep itself.     

The effect of anti-L on ouabain binding to sheep erythrocytes.

Binding of 3H-ouabain was studied in high potassium (HK) and low potassium (LK) sheep red cells. In particular, we investigated the effect of anti-L, an antibody raised in HK sheep against L-positive LK sheep red cells, on 3H-oubain binding and its relation to K+ -pump flux inhibition in LK cells. HK cells were found to have about twice as many 3H-ouabain binding sites and a higher association rate for 3H-ouabain than homozygous LL-type LK cells. The number of 3H-ouabain molecules bound to heterozygous LM-type LK cells is lower than that on LL cells, but the rate of ouabain binding is between that of HK and LL red cells. A close correlation was observed between the rates of 3H-oubain binding and fraction K+-pump inhibition. Exposure of LM and LL cells to anti-L did not affect the number of 3H-ouabain molecules bound at saturation, but increased the rates of glycoside binding and K+ -pump inhibition proportionately, so that for LK cells in the presence of anti-L, the rates of the two processes approximate those of HK cells. These data exclude the possibility that anti-L generates entirely new pump sites in LK sheep cells, but suggest that the antibody increases the affinity of the existing -a+ -K+ pumps for the glycoside.     

Binding characteristics of M and L isoantibodies to high and low potassium sheep red cells

Summary Binding of highly purified¹²⁵I labeled M and L antibodies, both belonging to the immunoglobulin G class, was studied in high potassium (HK) and low potassium (LK) sheep red cells. Anti-M and anti-L bound specifically to M and L antigen positive HK and LK red cells, respectively. Nonspecific binding was higher for anti-L to HK cells than for anti-M to LK cells. Once bound, the M and L antibodies were capable of inducing complement dependent immune hemolysis. Only 75–100 and 500–750 molecules of anti-M and anti-L immunoglobulins were required to hemolyze 50% of HK (MM) and LK (LL) red cells, respectively, suggesting that the M and L antigens may be clustered on the surfaces of these cells. Equilibrium binding studies revealed that the maximum number of M sites is 3–6×10³ in HK (MM) and 1.5–4×10³ in LM (LM) cells, respectively. In comparison, the number of L antigens is slightly lower in LK cells, about 1.2–1.8×10³ in LL and less in LM (LK) red cells. The number of M and L antigens, therefore, is more than an order of magnitude larger than that of the Na⁺K⁺ pumps measured previously in these cells by³H-ouabain binding, thus precluding a quantitative correlation between M and L antigens and the Na⁺K⁺ pumps different in the three genetic types of sheep red cells. The binding affinities of both anti-M and anti-L could not be described by a single equilibrium dissociation constant indicating heterogeneous antibody populations and/or variability in the antigenic sets of individual HK or LK cells. The pronounced heterogeneity of antigens and/or antibodies in both the M and L systems was reflected in the antibody association kinetics which also exhibited a remarkable temperature dependence. The data suggest that the correlation between the M and L antigens and the Na⁺K⁺ pump molecules is more complex than that in goat red cells previously reported by others.     

Properties of a goat anti-L antibody: further evidence for heterogeneity of the L antigen.

The preparation and properties of an antibody (anti-L) against low potassium type (LK) goat red cells raised in a high potassium type (HK) goat are described. This reagent stimulated active potassium transport, but showed only weak serological activity against low potassium type (LK) sheep and goat red cells. The results are discussed in relation to the hypothesis that anti-L antibody has two specificities--a sodium pump-stimulating activity (anti-Lp) and a serological activity (anti-L1y).     

Regulation of Cell Volume by Active Cation Transport in High and Low Potassium Sheep Red Cells

A model cell which controls its cation composition and volume by the action of a K-Na exchange pump and leaks for both ions working in parallel is presented. Equations are formulated which describe the behavior of this model in terms of three membrane parameters. From these equations and the steady state concentrations of Na, K, and Cl, values for these parameters in high potassium (HK) and low potassium (LK) sheep red cells are calculated. Kinetic experiments designed to measure the membrane parameters directly in the two types of sheep red cells are also reported. The values of the parameters obtained in these experiments agreed well with those calculated from the steady state concentrations of ions and the theoretical equations. It is concluded that both HK and LK sheep red cells control their cation composition and volume in a manner consistent with the model cell. Both have a cation pump which exchanges one sodium ion from inside the cell with one potassium ion from outside the cell but the pump is working approximately four times faster in the HK cell. The characteristics of the cation leak in the two cell types are also very different since the HK cells are relatively more leaky to sodium as compared with potassium than is the case in the LK cells. Both cell types show appreciable sodium exchange diffusion but this process is more rapid in the LK than in the HK cells.     

Properties of a goat anti-L antibody Further evidence for heterogeneity of the L antigen

The preparation and properties of an antibody (anti-L) against low potassium type (LK) goat red cells raised in a high potassium type (HK) goat are described. This reagent stimulated active potassium transport, but showed only weak serological activity against low potassium type (LK) sheep and goat red cells. The results are discussed in relation to the hypothesis that anti-L anti-body has two specificities — a sodium pump-stimulating activity (anti-Lp) and a serological activity (anti-L_ly.     

The M-L blood group system and its influence on red cell potassium levels in sheep

Five phenotypes within the M-L blood group system of sheep were identified with three reagents: anti-L(m), anti-M and anti-M'. Factor M' only occurred in combination with M. The serological properties were studied and the potassium concentrations in the red cells of the various phenotypes were compared. Like M, the L antigen was only weakly developed on the red cells of newborn lambs, and it was only when adult low potassium levels were established that full L activity was reached. These results support the hypothesis that antigen L is acting as an inhibitor of active potassium transport.     

Interaction of HK and LK Goat Red Blood Cells with Ouabain

The characteristics of the interaction of Na-K pumps of high potassium (HK) and low potassium (LK) goat red blood cells with ouabain have been determined. The rate of inhibition by ouabain of the pump of HK cells is greater than the rate of inhibition of the pumps of LK cells. Treatment of LK cells with an antibody (anti-L) raised in HK sheep by injecting LK sheep red cells increases the rate of inhibition of the LK pumps by ouabain to that characteristic of HK pumps; reduction of intracellular K (K_c) in LK cells increases the rate at which ouabain inhibits their pumps and exposure of these low K_c cells to anti-L does not affect the rate of inhibition. There is considerable heterogeneity in the pumps of both HK and LK cells in the rate at which they interact with ouabain or the rate at which they pump or both. LK pumps which are sensitive to stimulation by anti-L bind ouabain less rapidly than the remainder of the LK pumps and exposure to antibody increases the rate at which ouabain binds to the sensitive pumps; the difference between the two types of pumps disappears if intracellular K is very low. The calculated number of ouabain molecules bound at 100% inhibition of the pump is about the same for HK and LK cells. Although exposure to anti-L increases the apparent number of ouabain binding sites in LK cells at normal K_c, it does not alter the apparent number of sites in LK cells when K_c has been reduced.     

Na+ K+ pump and passive K+ transport in large and small red cell populations of anemic high and low K+ sheep

Reticulocytes, isolated by centrifugal elutriation from massively bled sheep and identified by cytometric techniques, were analyzed with respect to their cation transport properties. In sheep with genetically high K+ (HK) or low K+ (LK) red cells, two reticulocyte types were distinguished by conventional or fluorescence-staining techniques 5-6 days after hemorrhage: Large reticulocytes as part of a newly formed macrocytic (M) erythrocyte population, and small reticulocytes present among the adult red cell population (volume population III of normal sheep blood, Valet et al., 1978). Although cellular reticulin disappeared within a few days, the M-cell population persisted throughout weeks in the peripheral circulation permitting a transport study of in vivo maturation. At all times, M cells of LK sheep had lower K+ and higher Na+ contents than M cells of HK sheep. Regardless of the sheep genotypes, M cells apparently reduced their volume during their first days in circulation; however, throughout the observation period, they did not attain that characteristic for adult red cells. Both ouabain-sensitive K+ pump and ouabain-insensitive K+ leak fluxes were elevated in M cells of both HK and LK sheep. The increased K+ pump flux was mainly due to higher K+ pump turnover rather than to the modestly increased number of pumps as measured by [3H]ouabain binding. In contrast, small reticulocytes enriched from separated volume population III cells by a Percoll-density gradient exhibited transport parameters close to their prospective mature HK or LK red cells. The data support the concept that the M cells derived from emergency reticulocytes while the small reticulocytes represented precursors of normal red cell maturation. The Na+ and K+ composition found in M cells of HK and LK sheep, respectively, suggest development of the LK steady state at or prior to the reticulocyte state, a finding consistent with that of Lee and Kirk (1982) on low K+ dog red cells.     

Red blood cell potassium types of angora goats (Capra hircus)

Two distinct K phenotypes with normal frequency distribution curves were found and identified as low (LK) and high (HK) potassium types in the red blood cells of 748 Angora goats. The division between the two types was arbitrarily assigned at 24.9 meq/l. Of the two KRBC level types; the LK type was predominating, its curve showed evidence of leptokurtosis and was negatively skewed. The HK type had a curve slightly mesokurtic and the population was normal with respect to skewness.     

Passive potassium transport in LK sheep red cells. Effects of anti-L antibody and intracellular potassium

The passive K influx in low K(LK) red blood cells of sheep saturates with increasing external K concentration, indicating that this mode of transport is mediated by membrane-associated sites. The passive K influx, iMLK, is inhibited by external Na. Isoimmune anti-L serum, known to stimulate active K transport in LK sheep red cells, inhibits iMLK about twofold. iMLK is affected by changes in intracellular K concentration, [K]i, in a complex fashion: increasing [K]i from near zero stimulates iMLK, while further increases in [K]i, above 3 mmol/liter cells, inhibit iMLK. The passive K influx is not mediated by K-K exchange diffusion. The effects of anti-L antibody and [K]i on passive cation transport are specific for K: neither factor affects passive Na transport. The common characteristics of passive and active K influx suggest that iMLK is mediated by inactive Na-K pump sites, and that the inability to translocate Na characterizes the inactive pumps. Anti-L antibody stimulates the K pump in reticulocytes of LK sheep. However, anti-L has no effect on iMLK in these cells, apparently because reticulocytes do not have the inactive pump sites which, in mature LK cells, are a consequence of the process of maturation of circulating LK cells. The results also indicate that anti-L alters the maximum velocity of both active and passive K fluxes by converting pumps sites from a form mediating passive K influx to an actively transporting form.     

The effect of sheep anti-L and certain cattle S-system reagents on active potassium transport in sheep and cattle red blood cells

Certain anti-sheep L antisera stimulated active potassium transport in cattle red cells. All cattle red cells tested (red cells from 21 Jersey cows) which had an internal K level of less than 70 mmol/1 were stimulated but those with more than 75 mmol/1 of K (red cells from 7 Jersey cows) were not stimulated. Cattle S-system reagents and isoimmune cattle sera produced by injecting red cells of low-potassium type into cows with cells of high-potassium type failed to stimulate active potassium transport in either cattle or sheep red cells.     

Immature Blood Vessels in Rheumatoid Synovium Are Selectively Depleted in Response to Anti-TNF Therapy

Background

Angiogenesis is considered an important factor in the pathogenesis of Rheumatoid Arthritis (RA) where it has been proposed as a therapeutic target. In other settings, active angiogenesis is characterized by pathologic, immature vessels that lack periendothelial cells. We searched for the presence of immature vessels in RA synovium and analyzed the dynamics of synovial vasculature along the course of the disease, particularly after therapeutic response to TNF antagonists.

Methodology/Principal Findings

Synovial arthroscopic biopsies from RA, osteoarthritis (OA) and normal controls were analyzed by double labeling of endothelium and pericytes/smooth muscle mural cells to identify and quantify mature/immature blood vessels. To analyze clinicopathological correlations, a cross-sectional study on 82 synovial biopsies from RA patients with variable disease duration and severity was performed. A longitudinal analysis was performed in 25 patients with active disease rebiopsied after anti-TNF-α therapy. We found that most RA synovial tissues contained a significant fraction of immature blood vessels lacking periendothelial coverage, whereas they were rare in OA, and inexistent in normal synovial tissues. Immature vessels were observed from the earliest phases of the disease but their presence or density was significantly increased in patients with longer disease duration, higher activity and severity, and stronger inflammatory cell infiltration. In patients that responded to anti-TNF-α therapy, immature vessels were selectively depleted. The mature vasculature was similarly expanded in early or late disease and unchanged by therapy.

Conclusion/Significance

RA synovium contains a significant fraction of neoangiogenic, immature blood vessels. Progression of the disease increases the presence and density of immature but not mature vessels and only immature vessels are depleted in response to anti-TNFα therapy. The different dynamics of the mature and immature vascular fractions has important implications for the development of anti-angiogenic interventions in RA.     

Identification of a 25 kDa polypeptide associated with the L antigen in low potassium-type sheep red cells

Antisera to the L blood group antigen have been used, following radioiodination of low potassium-type sheep red cells and subsequent immunoprecipitation, to identify a polypeptide of the L antigen. Only LK, and not HK, cells express this 25 kDa component which is present in very low copy number.     

Developmental regulation of K accumulation in pollen, anthers, and papillae: are anther dehiscence, papillae hydration, and pollen swelling leading to pollination and fertilization in barley (Hordeum vulgare L.) regulated by changes in K concentration?

The presence of potassium (K) in pollen, anthers and papillaefrom barley (Hordeum vulgare L.) flowers with different levelsof developmental stages starting from boot stage to fully matureflower, was studied by using the K-sensitive fluorescent dyePBFI (potassium-binding benzofuran isophthalate) and confocallaser scanning microscopy. The presence of heavy K fluorescencewas detected only at the aperture area of the mature pollen.Similarly, the presence of K increased with the progressionfrom immature to mature anther and papillae. In addition, ahigher concentration of K was observed only at the stomium area(the place of anther dehiscence) of mature anthers. Keepingin view the role of K as an active osmoticum and the consistentand synchronized appearance of K in mature pollen, anthers,and papillae, it was concluded that K may regulate anther dehiscence,pollen imbibition, and papillae hydration leading to pollinationand fertilization. Key words: Anther, confocal microscopy, papillae, PBFI, pollen, potassium