Distinct Kinetic Properties Research Articles

Abstract: P695 LEMON FLAVONOIDS REDUCE HOMOCYSTEINE-INDUCED MONOCYTE INFLAMMATION

This review article provides an overview of recent studies of nicotine dependence and withdrawal that used genetically engineered mice. Major progress has been made in recent years with mutant mice that have knockout and gain-of-function of specific neuronal nicotinic acetylcholine receptor (nAChR) subunit genes. Nicotine exerts its actions by binding to neuronal nAChRs that consist of five subunits. The different nAChR subunits that combine to compose a receptor determine the distinct pharmacological and kinetic properties of the specific nAChR. Recent findings in genetically engineered mice have indicated that while α4-containing and β2-containing nAChRs are involved in the acquisition of nicotine self-administration and initial stages of nicotine dependence, α7 homomeric nAChRs appear to be involved in the later stages of nicotine dependence. In the medial habenula, α5-containing, α3-containing, and β4-containing nAChRs were shown to be crucially important in the regulation of the aversive aspects of nicotine. Studies of the involvement of α6 nAChR subunits in nicotine dependence have only recently emerged. The use of genetically engineered mice continues to vastly improve our understanding of the neurobiology of nicotine dependence and withdrawal.

Differential regulation of sphingosine kinases 1 and 2 in lung injury

Two mammalian sphingosine kinase (SphK) isoforms, SphK1 and SphK2, possess identical kinase domains but have distinct kinetic properties and subcellular localizations, suggesting each has one or more specific roles in sphingosine-1-phosphate (S1P) generation. Although both kinases use sphingosine as a substrate to generate S1P, the mechanisms controlling SphK activation and subsequent S1P generation during lung injury are not fully understood. In this study, we established a murine lung injury model to investigate LPS-induced lung injury in SphK1 knockout (SphK1(-/-)) and wild-type (WT) mice. We found that SphK1(-/-) mice were much more susceptible to LPS-induced lung injury compared with their WT counterparts, quantified by multiple parameters including cytokine induction. Intriguingly, overexpression of WT SphK1 delivered by adenoviral vector to the lungs protected SphK1(-/-) mice from lung injury and attenuated the severity of the response to LPS. However, adenoviral overexpression of a SphK1 kinase-dead mutant (SphKKD) in SphK1(-/-) mouse lungs further exacerbated the response to LPS as well as the extent of lung injury. WT SphK2 adenoviral overexpression also failed to provide protection and, in fact, augmented the degree of LPS-induced lung injury. This suggested that, in vascular injury, S1P generated by SphK2 activation plays a distinctly separate role compared with SphK1-dependent S1P generation and survival signaling. Microarray and real-time RT-PCR analysis of SphK1 and SphK2 expression levels during lung injury revealed that, in WT mice, LPS treatment caused significantly enhanced SphK1 expression ( approximately 5x) levels within 6 h, which declined back to baseline levels by 24 h posttreatment. In contrast, expression of SphK2 was gradually induced following LPS treatment and was elevated within 24 h. Collectively, our results for the first time demonstrate distinct functional roles of the two SphK isoforms in the regulation of LPS-induced lung injury.

An Essential DnaB Helicase ofBacillus anthracis: Identification, Characterization, and Mechanism of Action

We have described a novel essential replicative DNA helicase from Bacillus anthracis, the identification of its gene, and the elucidation of its enzymatic characteristics. Anthrax DnaB helicase (DnaB(BA)) is a 453-amino-acid, 50-kDa polypeptide with ATPase and DNA helicase activities. DnaB(BA) displayed distinct enzymatic and kinetic properties. DnaB(BA) has low single-stranded DNA (ssDNA)-dependent ATPase activity but possesses a strong 5'-->3' DNA helicase activity. The stimulation of ATPase activity appeared to be a function of the length of the ssDNA template rather than of ssDNA binding alone. The highest specific activity was observed with M13mp19 ssDNA. The results presented here indicated that the ATPase activity of DnaB(BA) was coupled to its migration on an ssDNA template rather than to DNA binding alone. It did not require nucleotide to bind ssDNA. DnaB(BA) demonstrated a strong DNA helicase activity that required ATP or dATP. Therefore, DnaB(BA) has an attenuated ATPase activity and a highly active DNA helicase activity. Based on the ratio of DNA helicase and ATPase activities, DnaB(BA) is highly efficient in DNA unwinding and its coupling to ATP consumption.

AMPA Receptor Subunit-Specific Regulation by a Distinct Family of Type II TARPs

AMPA-type glutamate receptors (GluRs) play major roles in excitatory synaptic transmission. Neuronal AMPA receptors comprise GluR subunits and transmembrane AMPA receptor regulatory proteins (TARPs). Previous studies identified five mammalian TARPs, gamma-2 (or stargazin), gamma-3, gamma-4, gamma-7, and gamma-8, that enhance AMPA receptor function. Here, we classify gamma-5 as a distinct class of TARP that modulates specific GluR2-containing AMPA receptors and displays properties entirely dissimilar from canonical TARPs. Gamma-5 increases peak currents and decreases the steady-state currents selectively from GluR2-containing AMPA receptors. Furthermore, gamma-5 increases rates of GluR2 deactivation and desensitization and decreases glutamate potency. Remarkably, all effects of gamma-5 require editing of GluR2 mRNA. Unlike other TARPs, gamma-5 modulates GluR2 without promoting receptor trafficking. We also find that gamma-7 regulation of GluR2 is dictated by mRNA editing. These data establish gamma-5 and gamma-7 as a separate family of "type II TARPs" that impart distinct physiological features to specific AMPA receptors.

MiXED Messages in Ion Channel Modulation

Ion channels are modulated by multiple molecular mechanisms. In this issue of Neuron, Pietrzykowski et al. expand the mechanistic repertoire by demonstrating that ethanol-induced microRNA can modulate the pattern of mRNA splice variants from which BK potassium channels are constructed. Because BK channels are important targets of ethanol, this finding has implications for mechanisms of ethanol sensitivity and tolerance.

Chromatin Remodeling Complexes Interact Dynamically with a Glucocorticoid Receptor–regulated Promoter

Brahma (BRM) and Brahma-related gene 1 (BRG1) are the ATP-dependent catalytic subunits of the SWI/SNF family of chromatin-remodeling complexes. These complexes are involved in essential processes such as cell cycle, growth, differentiation, and cancer. Using imaging approaches in a cell line that harbors tandem repeats of stably integrated copies of the steroid responsive MMTV-LTR (mouse mammary tumor virus-long terminal repeat), we show that BRG1 and BRM are recruited to the MMTV promoter in a hormone-dependent manner. The recruitment of BRG1 and BRM resulted in chromatin remodeling and decondensation of the MMTV repeat as demonstrated by an increase in the restriction enzyme accessibility and in the size of DNA fluorescence in situ hybridization (FISH) signals. This chromatin remodeling event was concomitant with an increased occupancy of RNA polymerase II and transcriptional activation at the MMTV promoter. The expression of ATPase-deficient forms of BRG1 (BRG1-K-R) or BRM (BRM-K-R) inhibited the remodeling of local and higher order MMTV chromatin structure and resulted in the attenuation of transcription. In vivo photobleaching experiments provided direct evidence that BRG1, BRG1-K-R, and BRM chromatin-remodeling complexes have distinct kinetic properties on the MMTV array, and they dynamically associate with and dissociate from MMTV chromatin in a manner dependent on hormone and a functional ATPase domain. Our data provide a kinetic and mechanistic basis for the BRG1 and BRM chromatin-remodeling complexes in regulating gene expression at a steroid hormone inducible promoter.

Evolution of C4 phosphoenolpyruvate carboxylase in Flaveria: determinants for high tolerance towards the inhibitor L‐malate

During the evolution of angiosperms, C4 phosphoenolpyruvate carboxylases have evolved several times independently from ancestral non-photosynthetic isoforms. They show distinct kinetic and regulatory properties when compared with the C3 isozymes. To identify the evolutionary alterations which are responsible for C4-specific properties, particularly the increased tolerance towards the allosteric inhibitor L-malate, the photosynthetic phosphoenolpyruvate carboxylase of Flaveria trinervia Mohr C4 and its ortholog from the closely related C3 plant Flaveria pringlei Gand. were examined using reciprocal enzyme chimeras. The main determinants for a high tolerance towards L-malate were located in the C-terminal region of the C4 enzyme. The effect of interchanging the region between amino acids 296 and 437 was strongly dependent upon the activation of the enzyme by glucose-6-phosphate. This confirms earlier observations that this region is important for the regulation of the enzyme by glucose-6-phosphate and that it harbours determinants for the different response of the C3 and the C4 enzyme towards this allosteric activator. In addition, it was possible to demonstrate that the only C4-specific amino acid, a serine in the C-terminal part of the enzyme, is not involved in conferring an increased L-malate tolerance to the C4 enzyme.

Arabidopsis thaliana NADP-malic enzyme isoforms: high degree of identity but clearly distinct properties

The Arabidopsis thaliana genome contains four NADP-malic enzymes genes (NADP-ME1-4). NADP-ME4 is localized to plastids whereas the other isoforms are cytosolic. NADP-ME2 and 4 are constitutively expressed, while NADP-ME1 is restricted to secondary roots and NADP-ME3 to trichomes and pollen. Although the four isoforms share remarkably high degree of identity (75-90%), recombinant NADP-ME1 through 4 show distinct kinetic properties, both in the forward (malate oxidative decarboxylation) and reverse (pyruvate reductive carboxylation) reactions. The four isoforms behave differently in terms of reversibility, with NADP-ME2 presenting the highest reverse catalytic efficiency. When analyzing the activity of each isoform in the presence of metabolic effectors, NADP-ME2 was the most highly regulated isoform, especially in its activation by certain effectors. Several metabolites modulate both the forward and reverse reactions, exhibiting dual effects in some cases. Therefore, pyruvate reductive carboxylation may be relevant in vivo, especially in some cellular compartments and conditions. In order to identify residues or segments of the NADP-ME primary structure that could be involved in the differences among the isoforms, NADP-ME2 mutants and deletions were analysed. The results obtained show that Arg115 is involved in fumarate activation, while the amino-terminal part is critical for aspartate and CoA activation, as well as for the reverse reaction. As a whole, these studies show that minimal changes in the primary structure are responsible for the different kinetic behaviour of each AtNADP-ME isoform. In this way, the co-expression of some isoforms in the same cellular compartment would not imply redundancy but represents specificity of function.

Distinct kinetic and mechanical properties govern ALCAM-mediated interactions as shown by single-molecule force spectroscopy

The activated leukocyte cell adhesion molecule (ALCAM) mediates dynamic homotypic and heterotypic cellular interactions. Whereas homotypic ALCAM-ALCAM interactions have been implicated in the development and maintenance of tissue architecture and tumor progression, heterotypic ALCAM-CD6 interactions act to initiate and stabilize T-cell-dendritic-cell interactions affecting T-cell activation. The ability to resist the forces acting on the individual bonds during these highly dynamic cellular contacts is thought to be crucial for the (patho)physiology of ALCAM-mediated cell adhesion. Here, we used atomic force microscopy to characterize the relationship between affinity, avidity and the stability of ALCAM-mediated interactions under external loading, at the single-molecule level. Disruption of the actin cytoskeleton resulted in enhanced ALCAM binding avidity, without affecting the tensile strength of the individual bonds. Force spectroscopy revealed that the ALCAM-CD6 bond displayed a significantly higher tensile strength, a smaller reactive compliance and an up to 100-fold lower dissociation rate in the physiological force window in comparison to the homotypic interaction. These results indicate that homotypic and heterotypic ALCAM-mediated adhesion are governed by significantly distinct kinetic and mechanical properties, providing novel insight into the role of ALCAM during highly dynamic cellular interactions.

Synaptotagmins I and IX function redundantly in regulated exocytosis but not endocytosis in PC12 cells

Synaptotagmin I is considered to be a Ca2+ sensor for fast vesicle exocytosis. Because Ca2+-dependent vesicle exocytosis persists in synaptotagmin I mutants, there must be additional Ca2+ sensors. Multiple synaptotagmin isoforms co-reside on vesicles, which suggests that other isoforms complement synaptotagmin I function. We found that full downregulation of synaptotagmins I and IX, which co-reside on vesicles in PC12 cells, completely abolished Ca2+-dependent vesicle exocytosis. By contrast, Ca2+-dependent exocytosis persisted in cells expressing only synaptotagmin I or only synaptotagmin IX, which indicated a redundancy in function for these isoforms. Although either isoform was sufficient to confer Ca2+ regulation on vesicle exocytosis, synaptotagmins I and IX conferred faster and slower release rates, respectively, indicating that individual isoforms impart distinct kinetic properties to vesicle exocytosis. The downregulation of synaptotagmin I but not synaptotagmin IX impaired compensatory vesicle endocytosis, which revealed a lack of isoform redundancy and functional specialization of synaptotagmin I for endocytic retrieval.

XRCC1 and PCNA are loading platforms with distinct kinetic properties and different capacities to respond to multiple DNA lesions

BackgroundGenome integrity is constantly challenged and requires the coordinated recruitment of multiple enzyme activities to ensure efficient repair of DNA lesions. We investigated the dynamics of XRCC1 and PCNA that act as molecular loading platforms and play a central role in this coordination.ResultsLocal DNA damage was introduced by laser microirradation and the recruitment of fluorescent XRCC1 and PCNA fusion proteins was monitored by live cell microscopy. We found an immediate and fast recruitment of XRCC1 preceding the slow and continuous recruitment of PCNA. Fluorescence bleaching experiments (FRAP and FLIP) revealed a stable association of PCNA with DNA repair sites, contrasting the high turnover of XRCC1. When cells were repeatedly challenged with multiple DNA lesions we observed a gradual depletion of the nuclear pool of PCNA, while XRCC1 dynamically redistributed even to lesions inflicted last.ConclusionThese results show that PCNA and XRCC1 have distinct kinetic properties with functional consequences for their capacity to respond to successive DNA damage events.

Caenorhabditis elegans has two genes encoding functional d‐aspartate oxidases

Four cDNA clones that were annotated in the database as encoding d-amino acid oxidase (DAAO) or d-aspartate oxidase (DASPO) were isolated by RT-PCR from Caenorhabditis elegans RNA. The proteins (Y69Ap, C47Ap, F18Ep, and F20Hp) encoded by the cloned cDNAs were expressed in Escherichia coli as recombinant proteins with an N-terminal His-tag. All proteins except F20Hp were recovered in the soluble fractions. The recombinant Y69Ap has functional DAAO activity, as it can deaminate neutral and basic d-amino acids, whereas the recombinants C47Ap and F18Ep have functional DASPO activities, as they can deaminate acidic d-amino acids. Additional experiments using purified recombinant proteins revealed that Y69Ap deaminates d-Arg more efficiently than d-Ala and d-Met, and that C47Ap and F18Ep show distinct kinetic properties against d-Asp, d-Glu, and N-methyl-d-Asp. This is the first time that cDNA cloning of invertebrate DAAO and DASPO genes has been reported. In addition, our study reveals for the first time that C. elegans has at least two genes encoding functional DASPOs and one gene encoding DAAO, although it had previously been thought that organisms only bear one copy each of these genes. The two C. elegans DASPOs differ in their substrate specificities and possibly also in their subcellular localization.

Structure and Inhibition of a Quorum Sensing Target from Streptococcus pneumoniae

Streptococcus pneumoniae 5'-methylthioadenosine/S-adenosylhomocysteine hydrolase (MTAN) catalyzes the hydrolytic deadenylation of its substrates to form adenine and 5-methylthioribose or S-ribosylhomocysteine (SRH). MTAN is not found in mammals but is involved in bacterial quorum sensing. MTAN gene disruption affects the growth and pathogenicity of bacteria, making it a target for antibiotic design. Kinetic isotope effects and computational studies have established a dissociative S(N)1 transition state for Escherichia coli MTAN, and transition state analogues resembling the transition state are powerful inhibitors of the enzyme [Singh, V., Lee, J. L., Núñez, S., Howell, P. L., and Schramm, V. L. (2005) Biochemistry 44, 11647-11659]. The sequence of MTAN from S. pneumoniae is 40% identical to that of E. coli MTAN, but S. pneumoniae MTAN exhibits remarkably distinct kinetic and inhibitory properties. 5'-Methylthio-Immucillin-A (MT-ImmA) is a transition state analogue resembling an early S(N)1 transition state. It is a weak inhibitor of S. pneumoniae MTAN with a K(i) of 1.0 microM. The X-ray structure of S. pneumoniae MTAN with MT-ImmA indicates a dimer with the methylthio group in a flexible hydrophobic pocket. Replacing the methyl group with phenyl (PhT-ImmA), tolyl (p-TolT-ImmA), or ethyl (EtT-ImmA) groups increases the affinity to give K(i) values of 335, 60, and 40 nM, respectively. DADMe-Immucillins are geometric and electrostatic mimics of a fully dissociated transition state and bind more tightly than Immucillins. MT-DADMe-Immucillin-A inhibits with a K(i) value of 24 nM, and replacing the 5'-methyl group with p-Cl-phenyl (p-Cl-PhT-DADMe-ImmA) gave a K(i) value of 0.36 nM. The inhibitory potential of DADMe-Immucillins relative to the Immucillins supports a fully dissociated transition state structure for S. pneumoniae MTAN. Comparison of active site contacts in the X-ray crystal structures of E. coli and S. pneumoniae MTAN with MT-ImmA would predict equal binding, yet most analogues bind 10(3)-10(4)-fold more tightly to the E. coli enzyme. Catalytic site efficiency is primarily responsible for this difference since k(cat)/K(m) for S. pneumoniae MTAN is decreased 845-fold relative to that of E. coli MTAN.

Species having C4 single-cell-type photosynthesis in the Chenopodiaceae family evolved a photosynthetic phosphoenolpyruvate carboxylase like that of Kranz-type C4 species.

Spatial and temporal regulation of phosphoenolpyruvate carboxylase (PEPC) is critical to the function of C(4) photosynthesis. The photosynthetic isoform of PEPC in the cytosol of mesophyll cells in Kranz-type C(4) photosynthesis has distinctive kinetic and regulatory properties. Some species in the Chenopodiaceae family perform C(4) photosynthesis without Kranz anatomy by spatial separation of initial fixation of atmospheric CO(2) via PEPC from C(4) acid decarboxylation and CO(2) donation to Rubisco within individual chlorenchyma cells. We studied molecular and functional features of PEPC in two single-cell functioning C(4) species (Bienertia sinuspersici, Suaeda aralocaspica) as compared to Kranz type (Haloxylon persicum, Salsola richteri, Suaeda eltonica) and C(3) (Suaeda linifolia) chenopods. It was found that PEPC from both types of C(4) chenopods displays higher specific activity than that of the C(3) species and shows kinetic and regulatory characteristics similar to those of C(4) species in other families in that they are subject to light/dark regulation by phosphorylation and display differential malate sensitivity. Also, the deduced amino acid sequence from leaf cDNA indicates that the single-cell functioning C(4) species possesses a Kranz-type C(4) isoform with a Ser in the amino terminal. A phylogeny of PEPC shows that isoforms in the two single-cell functioning C(4) species are in a clade with the C(3) and Kranz C(4) Suaeda spp. with high sequence homology. Overall, this study indicates that B. sinuspersici and S. aralocaspica have a C(4)-type PEPC similar to that in Kranz C(4) plants, which likely is required for effective function of C(4) photosynthesis.

Compound‐specific Na+ channel pore conformational changes induced by local anaesthetics

Upon prolonged depolarizations, voltage-dependent Na+ channels open and subsequently inactivate, occupying fast and slow inactivated conformational states. Like C-type inactivation in K+ channels, slow inactivation is thought to be accompanied by rearrangement of the channel pore. Cysteine-labelling studies have shown that lidocaine, a local anaesthetic (LA) that elicits depolarization-dependent ('use-dependent') Na+ channel block, does not slow recovery from fast inactivation, but modulates the kinetics of slow inactivated states. While these observations suggest LA-induced stabilization of slow inactivation could be partly responsible for use dependence, a more stringent test would require that slow inactivation gating track the distinct use-dependent kinetic properties of diverse LA compounds, such as lidocaine and bupivacaine. For this purpose, we assayed the slow inactivation-dependent accessibility of cysteines engineered into domain III, P-segment (mu1: F1236C, K1237C) to sulfhydryl (MTSEA) modification using a high-speed solution exchange system. As expected, we found that bupivacaine, like lidocaine, protected cysteine residues from MTSEA modification in a depolarization-dependent manner. However, under pulse-train conditions where bupivacaine block of Na+ channels was extensive (due to ultra-slow recovery), but lidocaine block of Na+ channels was not, P-segment cysteines were protected from MTSEA modification. Here we show that conformational changes associated with slow inactivation track the vastly different rates of recovery from use-dependent block for bupivacaine and lidocaine. Our findings suggest that LA compounds may produce their kinetically distinct voltage-dependent behaviour by modulating slow inactivation gating to varying degrees.

Over-expression, Purification, and Characterization of Recombinant Human Arylamine N-Acetyltransferase 1

Human arylamine N-acetyltransferase 1 (NAT1) has been overexpressed in E. coli as a mutant dihydrofolic acid reductase (DHFR) fusion protein with a thrombin sensitive linker. An initial DEAE anion-exchange chromatography resulted in partial purification of the fusion protein. The fusion protein was cleaved with thrombin, and human rNAT1 was purified with a second DEAE column. A total of 8 mg of human rNAT1 from 2 1 of cell culture was purified to homogeneity with this methodology. Arylamine substrate specificities were determined for human rNATI and hamster rNAT2. With both NATs, the second order rate constants (k(cat)/ Kmb) for p-aminobenzoic acid (PABA) and 2-aminofluorene (2-AF) were several thousand-fold higher than those for procainamide (PA), consistent with the expected substrate specificities of the enzymes. However, p-aminosalicylic acid (PAS), previously reported to be a human NAT1 and hamster NAT2 selective substrate, exhibits 20-fold higher specificity for hamster rNAT2 (k(cat)/Kmb 3410 microM(-1) s(-1)) than for human rNAT1 (k(cat)/Kmb 169.4 microM(-1) s(-1)). p-aminobenzoyl-glutamic acid (pABglu) was acetylated 10-fold more efficiently by human rNAT1 than by hamster rNAT2. Inhibition studies of human rNAT1 and hamster rNAT2 revealed that folic acid and methotrexate (MTX) are competitive inhibitors of both the unacetylated and acetylated forms of the enzymes, with K(I) values in 50 - 300 micro range. Dihydrofolic acid (DHF) was a much poorer inhibitor of human rNAT1 than of hamster rNAT2. The combined results demonstrate that human rNAT1 and hamster rNAT2 have similar but distinct kinetic properties with certain substrates, and suggest that folic acid, at least in the non-polyglutamate form, may not have an effect on human NAT1 activity in vivo.

Glutathione S-transferase in the insect Apis mellifera macedonica: Kinetic characteristics and effect of stress on the expression of GST isoenzymes in the adult worker bee

The glutathione S-transferase present in the adult worker bee Apis mellifera macedonica was purified and analyzed for its physicochemical and kinetic properties. The enzyme is heterodimeric with subunit molecular masses of 29 and 25 kDa, respectively. Two main isoenzymes with distinct kinetic properties are present, with isoelectric points of 7.40 for the alkaline and 4.58 for the acidic forms, respectively. The two enzymes are induced independently by factors such as insecticide treatments and environmental conditions, including low temperatures or starvation.

Glutathione S-transferase in the insect Apis mellifera macedonicaKinetic characteristics and effect of stress on the expression of GST isoenzymes in the adult worker bee

The glutathione S -transferase present in the adult worker bee Apis mellifera macedonica was purified and analyzed for its physicochemical and kinetic properties. The enzyme is heterodimeric with subunit molecular masses of 29 and 25 kDa, respectively. Two main isoenzymes with distinct kinetic properties are present, with isoelectric points of 7.40 for the alkaline and 4.58 for the acidic forms, respectively. The two enzymes are induced independently by factors such as insecticide treatments and environmental conditions, including low temperatures or starvation.

Plant sulphate transporters: co-ordination of uptake, intracellular and long-distance transport.

Proton/sulphate co-transport in the plasma membrane of root cells is the first step for the uptake of sulphate from the environment by plants. Further intracellular, cell-to-cell and long-distance transport must fulfil the requirements for sulphate assimilation and source/sink demands within the plant. A gene family of sulphate transporters, which may be subdivided into five groups, has been identified with examples from many different plant species. For at least two groups, proton/sulphate co-transport activity has been confirmed. It appears that each group represents sulphate transporters with distinct kinetic properties, patterns of expression, and cell/tissue specificity related to specific roles in the uptake and allocation of sulphate. High-affinity sulphate uptake and low-affinity vascular transport, as well as vacuolar efflux, are controlled by the nutritional status of the plant. Most notably there is an apparent increase in capacity for cellular sulphate uptake and vacuolar efflux when sulphur supply is limiting. Within the groups, the individual sulphate transporters may be further subdivided by differences in temporal, cellular and tissue expression. Many of the transporters are regulated by the nutritional status of the individual tissues, to optimize sulphate movement within and between sink and source organs.

Distinct kinetic and mechanical properties govern selectin-leukocyte interactions.

Leukocytes are recruited from the bloodstream to sites of inflammation by the selectin family of adhesion receptors. In vivo and in vitro studies reveal distinctive rolling velocities of polymorphonuclear leukocytes over E-, P- and L-selectin substrates. The kinetic and mechanical properties of the selectin-ligand bonds responsible for these differences at the single-molecule level are not well understood. Using single-molecule force spectroscopy, we probe in situ the rupture force, unstressed off-rate and reactive compliance of single selectin receptors to single ligands on whole human polymorphonuclear leukocytes (PMNs) under conditions that preserve the proper orientation and post-translational modifications of the selectin ligands. Single L-selectin bonds to PMNs were more labile than either E- or P-selectin in the presence of an applied force. This outcome, along with a higher unstressed off-rate and a higher reactive compliance, explain the faster L-selectin-mediated rolling. By quantifying binding frequency in the presence of a specific blocking monoclonal antibody or following enzyme treatment, we determined that P-selectin glycoprotein ligand-1 is a high-affinity ligand for E-selectin on PMNs under force. The rupture force spectra and corresponding unstressed off-rate and reactive compliance of selectin-ligand bonds provide mechanistic insights that might help to explain the variable rolling of leukocytes over different selectin substrates.