Jonathan S. Marchant scite author profile

Inositol (1,4,5)-trisphosphate (IP 3 ) liberates intracellular Ca 2+ both as localized`puffs' and as repetitive waves that encode information in a frequency-dependent manner. Using video-rate confocal imaging, together with photorelease of IP 3 in Xenopus oocytes, we investigated the roles of puffs in determining the periodicity of global Ca 2+ waves. Wave frequency is not delimited solely by cyclical recovery of the cell's ability to support wave propagation, but further involves sensitization of Ca 2+ -induced Ca 2+ release by progressive increases in puff frequency and amplitude at numerous sites during the interwave period, and accumulation of pacemaker Ca 2+ , allowing a puff at à focal' site to trigger a subsequent wave. These speci®c focal' sites, distinguished by their higher sensitivity to IP 3 and close apposition to neighboring puff sites, preferentially entrain both the temporal frequency and spatial directionality of Ca 2+ waves. Although summation of activity from many stochastic puff sites promotes the generation of regularly periodic global Ca 2+ signals, the properties of individual Ca 2+ puffs control the kinetics of Ca 2+ spiking and the (higher) frequency of subcellular spikes in their local microdomain.

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Initiation of IP3-mediated Ca2+ waves in Xenopus oocytes

Marchant¹

1999

140

143

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Inositol (1,4,5)-trisphosphate (IP(3)) evokes Ca(2+) liberation in Xenopus oocytes as elementary events (Ca(2+) puffs) that become coupled to propagate Ca(2+) waves with increasing [IP(3)]. To investigate this transition between local and global Ca(2+) signaling, we developed an optical method for evoking rapid subcellular Ca(2+) elevations, while independently photoreleasing IP(3) and simultaneously recording confocal Ca(2+) images. Focal Ca(2+) elevations triggered waves within 100 ms of photoreleasing IP(3), compared with latencies of seconds following photorelease of IP(3) alone. Wave velocity varied with [IP(3)] but was independent of time after photorelease of IP(3), indicating that delayed wave initiation did not involve slow binding of IP(3) to its receptors. The amount of Ca(2+) required to trigger a wave was approximately 10-fold greater than the average size of puffs, and puffs showed no progressive increase in magnitude before waves initiated. Instead, Ca(2+) puffs contributed to a slow rise in basal free [Ca(2+)], which further increased puff frequency and sensitized IP(3) receptors so that individual events then triggered waves. Because the wave threshold is much greater than the size of the elementary puff, cells can employ both local and global signaling mechanisms, and the summation of stochastic behavior of elementary events allows generation of reproducible periodic waves.

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Genetic analysis of praziquantel response in schistosome parasites implicates a transient receptor potential channel

et al. 2021

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Mass treatment with praziquantel (PZQ) monotherapy is the mainstay for schistosome treatment. This drug shows imperfect cure rates in the field and parasites showing reduced response to PZQ can be selected in the laboratory, but the extent of resistance in Schistosoma mansoni populations is unknown. We examined the genetic basis of variation in PZQ response in a S. mansoni population (SmLE-PZQ-R) selected with PZQ in the laboratory: 35% of these worms survive high dose (73 µg/mL) PZQ treatment. We used genome wide association to map loci underlying PZQ response. The major chr. 3 peak shows recessive inheritance and contains a transient receptor potential (Sm.TRPMPZQ) channel (Smp_246790), activated by nanomoles of PZQ. Marker-assisted selection of parasites at a single Sm.TRPMPZQ SNP enriched populations of PZQ-R and PZQ-S parasites showing >377 fold difference in PZQ response. The PZQ-R parasites survived treatment in rodents better than PZQ-S. Resistant parasites show 2.25-fold lower expression of Sm.TRPMPZQ than sensitive parasites. Specific chemical blockers of Sm.TRPMPZQ enhanced PZQ resistance, while Sm.TRPMPZQ activators increased sensitivity. A single SNP in Sm.TRPMPZQ differentiated PZQ-ER and PZQ-ES lines, but mutagenesis showed this was not involved in PZQ-R, suggesting linked regulatory changes. We surveyed Sm.TRPMPZQ sequence variation in 259 individual parasites from the Newand Old World revealing one nonsense mutation, that results in a truncated protein with no PZQ binding site. Our results demonstrate that Sm.TRPMPZQ underlies variation in PZQ response in S. mansoni and provides an approach for monitoring emerging PZQ-resistance alleles in schistosome elimination programs..

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The Journey to Discovering a Flatworm Target of Praziquantel: A Long TRP

Park

Marchant

2020

Trends in Parasitology

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Infections caused by parasitic flatworms impose a considerable worldwide health burden. One of the most impactful is schistosomiasis, a disease caused by parasitic blood flukes. Treatment of schistosomiasis has relied on a single drug -praziquantel (PZQ) -for decades. The utility of PZQ as an essential medication is, however, intertwined with a stark gap in our knowledge as to how this drug works. No flatworm target has been identified that readily explains how PZQ paralyzes and damages schistosomes. Recently, a schistosome ion channel was discovered that is activated by PZQ and displays characteristics which mirror key features of PZQ action on schistosomes. Here, the journey to discovery of this target, properties of this ion channel, and remaining questions are reviewed.

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Nicotinic Acid Adenine Dinucleotide 2 -Phosphate (NAADP) Binding Proteins in T-Lymphocytes

Walseth¹,

Lin-Moshier²,

Weber³

et al. 2012

messenger

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Nicotinic acid adenine dinucleotide phosphate (NAADP) is a messenger that regulates calcium release from intracellular acidic stores. Although several channels, including two-pore channels (TPC), ryanodine receptor (RYR) and mucolipin (TRP-ML1) have been implicated in NAADP regulation of calcium signaling, the NAADP receptor has not been identified. In this study, the photoaffinity probe, [32P]–5-azido-NAADP ([32P]–5-N3-NAADP), was used to study NAADP binding proteins in extracts from NAADP responsive Jurkat T-lymphocytes. [32P]–5-N3-NAADP photolabeling of Jurkat S100 cytosolic fractions resulted in the labeling of at least ten distinct proteins. Several of these S100 proteins, including a doublet at 22/23 kDa and small protein at 15 kDa displayed selectivity for NAADP as the labeling was protected by inclusion of unlabeled NAADP, whereas the structurally similar NADP required much higher concentrations for protection. Interestingly, the labeling of several S100 proteins (60, 45, 33 and 28 kDa) was stimulated by low concentrations of unlabeled NAADP, but not by NADP. The effect of NAADP on the labeling of the 60 kDa protein was biphasic, peaking at 100 nM with a five-fold increase and displaying no change at 1 µM NAADP. Several proteins were also photolabeled when the P100 membrane fraction from Jurkat cells was examined. Similar to the results with S100, a 22/23 kDa doublet and a 15 kDa protein appeared to be selectively labeled. NAADP did not increase the labeling of any P100 proteins as it did in the S100 fraction. The photolabeled S100 and P100 proteins were successfully resolved by two-dimensional gel electrophoresis. [32P]–5-N3-NAADP photolabeling and two-dimensional electrophoresis should represent a suitable strategy in which to identify and characterize NAADP binding proteins.

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