Your search keyword '"Pushpanjali Soppina"' showing total 8 results

1. Kinesin-3 motors are fine-tuned at the molecular level to endow distinct mechanical outputs

Author

Pushpanjali Soppina, Nishaben Patel, Dipeshwari J. Shewale, Ashim Rai, Sivaraj Sivaramakrishnan, Pradeep K. Naik, and Virupakshi Soppina

Subjects

Adenosine Triphosphatases, Mammals, Physiology, Kinesins, Cell Biology, Plant Science, Microtubules, General Biochemistry, Genetics and Molecular Biology, Adenosine Triphosphate, Structural Biology, Animals, General Agricultural and Biological Sciences, Ecology, Evolution, Behavior and Systematics, Developmental Biology, Biotechnology, Protein Binding

Abstract

Background Kinesin-3 family motors drive diverse cellular processes and have significant clinical importance. The ATPase cycle is integral to the processive motility of kinesin motors to drive long-distance intracellular transport. Our previous work has demonstrated that kinesin-3 motors are fast and superprocessive with high microtubule affinity. However, chemomechanics of these motors remain poorly understood. Results We purified kinesin-3 motors using the Sf9-baculovirus expression system and demonstrated that their motility properties are on par with the motors expressed in mammalian cells. Using biochemical analysis, we show for the first time that kinesin-3 motors exhibited high ATP turnover rates, which is 1.3- to threefold higher compared to the well-studied kinesin-1 motor. Remarkably, these ATPase rates correlate to their stepping rate, suggesting a tight coupling between chemical and mechanical cycles. Intriguingly, kinesin-3 velocities (KIF1A > KIF13A > KIF13B > KIF16B) show an inverse correlation with their microtubule-binding affinities (KIF1A Conclusions Together, we propose that a fine balance between the rate of ATP hydrolysis and microtubule affinity endows kinesin-3 motors with distinct mechanical outputs. The K-loop, a positively charged insert in the loop12 of the kinesin-3 motor domain promotes microtubule bending, an interesting phenomenon often observed in cells, which requires further investigation to understand its cellular and physiological significance.

Published

2022

2. Regulation of longevity by depolarization-induced activation of PLC-β–IP 3 R signaling in neurons

Author

Morgan A. Rousseau, Kartik Venkatachalam, Nicholas E. Karagas, Yufang Chao, Qiaochu Wang, Jewon Jung, John F. Hancock, Yong Zhou, Catherine A. Collins, Ching On Wong, Michael X. Zhu, Ryan Insolera, and Pushpanjali Soppina

Subjects

Membrane potential, Glutamatergic, Multidisciplinary, Hyperactivation, ATP synthase, biology, Chemistry, Endoplasmic reticulum, Regulator, biology.protein, Depolarization, Inositol trisphosphate receptor, Cell biology

Abstract

Mitochondrial ATP production is a well-known regulator of neuronal excitability. The reciprocal influence of plasma-membrane potential on ATP production, however, remains poorly understood. Here, we describe a mechanism by which depolarized neurons elevate the somatic ATP/ADP ratio in Drosophila glutamatergic neurons. We show that depolarization increased phospholipase-Cβ (PLC-β) activity by promoting the association of the enzyme with its phosphoinositide substrate. Augmented PLC-β activity led to greater release of endoplasmic reticulum Ca2+ via the inositol trisphosphate receptor (IP3R), increased mitochondrial Ca2+ uptake, and promoted ATP synthesis. Perturbations that decoupled membrane potential from this mode of ATP synthesis led to untrammeled PLC-β–IP3R activation and a dramatic shortening of Drosophila lifespan. Upon investigating the underlying mechanisms, we found that increased sequestration of Ca2+ into endolysosomes was an intermediary in the regulation of lifespan by IP3Rs. Manipulations that either lowered PLC-β/IP3R abundance or attenuated endolysosomal Ca2+ overload restored animal longevity. Collectively, our findings demonstrate that depolarization-dependent regulation of PLC-β–IP3R signaling is required for modulation of the ATP/ADP ratio in healthy glutamatergic neurons, whereas hyperactivation of this axis in chronically depolarized glutamatergic neurons shortens animal lifespan by promoting endolysosomal Ca2+ overload.

Published

2021

3. Effect of Binding-Affinity and ATPase Activity on the Velocities of Kinesins Using Ratchet Models

Author

Rupsha Mukherjee, Pushpanjali Soppina, Nishaben M. Patel, Virupakshi Soppina, and Kaustubh Rane

Subjects

Adenosine Triphosphatases, Biophysics, Kinesins, Cell Biology, General Medicine, Biochemistry, Dimerization, Microtubules, Protein Binding

Abstract

We use two-state ratchet models containing single and coupled Brownian motors to understand the role of motor-microtubule binding, ATPase reaction rate and dimerisation on the translational velocities of Kinesin motors. We use model parameters derived from the experimental measurements on KIF1A, KIF13A, KIF13B, and KIF16B motors to compute velocities in μm/s. We observe that both the models show the same trend in velocities (KIF1A KIF13A KIF13B KIF16B) as the experimental results. However, the models significantly underpredict the velocities when compared with the experiments. The predictions of the coupled-motor model are closer to the experiments than those of the single-motor model. Our results indicate that the variation of ATPase reaction rate governs the trend in velocities for the above four motors. The variation of motor-microtubule binding affinity and the coupling strength between the motor domains may only have a secondary effect. More rigorous models that incorporate the power-stroke mechanism are necessary for better quantitative compliance with the experiments.

Published

2021

4. Engineered kinesin motor proteins amenable to small-molecule inhibition

Author

William O. Hancock, Pushpanjali Soppina, T. Lynne Blasius, Michael Winding, Yang Yue, Shankar Shastry, Martin F. Engelke, Kristen J. Verhey, Federico Teloni, Vladimir I. Gelfand, and Sanjay Reddy

Subjects

0301 basic medicine, Cell division, Science, Dynein, Kinesin 13, Gene Expression, Kinesins, General Physics and Astronomy, macromolecular substances, Myosins, Biology, Protein Engineering, Transfection, Microtubules, Article, General Biochemistry, Genetics and Molecular Biology, Cell Line, Small Molecule Libraries, Motor protein, Mice, 03 medical and health sciences, Cell Movement, Microtubule, Chlorocebus aethiops, Animals, Humans, Kinesin 8, Multidisciplinary, fungi, Dyneins, food and beverages, General Chemistry, Protein engineering, Recombinant Proteins, Tubulin Modulators, Molecular Imaging, Cell biology, Protein Transport, Drosophila melanogaster, 030104 developmental biology, COS Cells, Kinesin, Plasmids

Abstract

The human genome encodes 45 kinesin motor proteins that drive cell division, cell motility, intracellular trafficking and ciliary function. Determining the cellular function of each kinesin would benefit from specific small-molecule inhibitors. However, screens have yielded only a few specific inhibitors. Here we present a novel chemical-genetic approach to engineer kinesin motors that can carry out the function of the wild-type motor yet can also be efficiently inhibited by small, cell-permeable molecules. Using kinesin-1 as a prototype, we develop two independent strategies to generate inhibitable motors, and characterize the resulting inhibition in single-molecule assays and in cells. We further apply these two strategies to create analogously inhibitable kinesin-3 motors. These inhibitable motors will be of great utility to study the functions of specific kinesins in a dynamic manner in cells and animals. Furthermore, these strategies can be used to generate inhibitable versions of any motor protein of interest., The use of specific small molecule inhibitors can contribute to the study of kinesins' cellular functions. Here the authors develop a chemical-genetic approach to engineer kinesin motors that can be efficiently inhibited upon addition of cell-permeable molecules.

Published

2016

5. Restraint of presynaptic protein levels by Wnd/DLK signaling mediates synaptic defects associated with the kinesin-3 motor Unc-104

Author

Doychin T. Stanchev, Jiaxing Li, Pushpanjali Soppina, Susan Klinedinst, Richard I. Hume, Yao V. Zhang, Tobias M. Rasse, Catherine A. Collins, Elham Asghari Adib, Xin Xiong, and Thomas R. Jahn

Subjects

0301 basic medicine, QH301-705.5, Science, Neuromuscular Junction, Kinesins, Biology, kinesin, General Biochemistry, Genetics and Molecular Biology, Synapse, 03 medical and health sciences, synapse, medicine, Animals, Drosophila Proteins, Biology (General), Axon, KIF1A, D. melanogaster, General Immunology and Microbiology, Synaptic pharmacology, General Neuroscience, fungi, Cell Biology, stress response, General Medicine, Anatomy, MAP Kinase Kinase Kinases, Protein Transport, 030104 developmental biology, medicine.anatomical_structure, nervous system, Axoplasmic transport, Medicine, Kinesin, Drosophila, Neuron, axonal transport, Signal transduction, signaling, Neuroscience, Research Article, Signal Transduction

Abstract

The kinesin-3 family member Unc-104/KIF1A is required for axonal transport of many presynaptic components to synapses, and mutation of this gene results in synaptic dysfunction in mice, flies and worms. Our studies at the Drosophila neuromuscular junction indicate that many synaptic defects in unc-104-null mutants are mediated independently of Unc-104’s transport function, via the Wallenda (Wnd)/DLK MAP kinase axonal damage signaling pathway. Wnd signaling becomes activated when Unc-104’s function is disrupted, and leads to impairment of synaptic structure and function by restraining the expression level of active zone (AZ) and synaptic vesicle (SV) components. This action concomitantly suppresses the buildup of synaptic proteins in neuronal cell bodies, hence may play an adaptive role to stresses that impair axonal transport. Wnd signaling also becomes activated when pre-synaptic proteins are over-expressed, suggesting the existence of a feedback circuit to match synaptic protein levels to the transport capacity of the axon., eLife digest Each nerve cell, or neuron, has a long nerve fiber – called an axon – that forms specialized sites for information exchange – called synapses – with other cells. Many molecules work at synapses to coordinate the exchange of information. These molecules are largely made in the central part of the neuron – known as the cell body – and are then transported along the axon to the synapses. The transport of these molecules is carried out by proteins known as molecular motors. One molecular motor, called KIF1A in humans and Unc-104 in fruit flies, is thought to be a major transporter of synaptic molecules. Mutations that hinder this molecular motor result in neurons failing to form synapses and, instead, synaptic components accumulate in the cell body. However, it was not clearif Unc-104 does actually carry all of the components needed to assemble synapses along axons, or if it influences synapse formation in another way. Now, Li, Zhang et al. report new evidence that supports the second of these two hypotheses. The experiments made use of fruit flies in which the gene for Unc-104 had been deleted, and revealed that inhibiting enzymes in a specific signaling pathway could reverse the synaptic problems caused by the loss of Unc-104. The signaling pathway, which is conserved between flies and humans, involves an enzyme that is called Wnd in flies and DLK in humans. The Wnd/DLK signaling pathway was previously known to regulate how neurons respond when their axons are damaged (either by growing new axons or dying, depending on the context). Further investigation by Li, Zhang et al. revealed that signaling via the Wnd enzyme becomes triggered whenever the Unc-104 molecular motor is impaired. This activation correlates with the build-up of synaptic proteins in the cell body. Once activated, the pathway then reduces the total amount of synaptic proteins that the cell makes. This reduction matches the neuron’s reduced ability to transport them along the axon, and may help the neuron to adapt when axonal transport is impaired. However, the reduction in synaptic proteins also impaired the exchange of information at the synapses. These findings suggest how DLK could be behind problems with synapses in diseases in which transport along axons is impaired. These diseases include hereditary spastic paraplegia, which has been linked to mutations in human KIF1A, and may also include ALS and Alzheimer’s disease, which have recently been linked to DLK. DLK has received recent attention as a candidate drug target because it contributes to the deterioration of damaged neurons. These new findings further expand that interest by suggesting that inhibiting DLK may help neurons to maintain working synapses, which is more useful than simply preventing damaged neurons from dying.

Published

2017

6. Author response: Restraint of presynaptic protein levels by Wnd/DLK signaling mediates synaptic defects associated with the kinesin-3 motor Unc-104

Author

Pushpanjali Soppina, Catherine A. Collins, Susan Klinedinst, Yao V. Zhang, Elham Asghari Adib, Tobias M. Rasse, Jiaxing Li, Thomas R. Jahn, Doychin T. Stanchev, Xin Xiong, and Richard I. Hume

Subjects

Kinesin, Biology, Cell biology

Published

2017

7. Engineered kinesin motor proteins amenable to small molecule inhibition

Author

Martin F. Engelke, William O. Hancock, Shankar Shastry, Kristen J. Verhey, Pushpanjali Soppina, Sanjay Reddy, Vladimir I. Gelfand, T. Lynne Blasius, Michael Winding, Yang Yue, and Federico Teloni

Subjects

0303 health sciences, Cell division, Chemistry, 030302 biochemistry & molecular biology, Motility, macromolecular substances, Small molecule, Cell biology, Motor protein, 03 medical and health sciences, Microtubule, Kinesin, Function (biology), Intracellular, 030304 developmental biology

Abstract

The human genome encodes 45 kinesins that drive cell division, cell motility, intracellular trafficking, and ciliary function. Determining the cellular function of each kinesin would be greatly facilitated by specific small molecule inhibitors, but screens have yielded inhibitors that are specific to only a small number of kinesins, likely due to the high conservation of the kinesin motor domain across the superfamily. Here we present a chemical-genetic approach to engineer kinesin motors that retain microtubule-dependent motility in the absence of inhibitor yet can be efficiently inhibited by small, cell-permeable molecules. Using kinesin-1 as a prototype, we tested two independent strategies to design inhibitable motors. First, we inserted the six amino acid tetracysteine tag into surface loops of the motor domain such that binding of biarsenic dyes allosterically inhibits processive motility. Second, we fused DmrB dimerization domains to the motor heads such that addition of B/B homodimerizer cross-links the two motor domains and inhibits motor stepping. We show, using cellular assays that the engineered kinesin-1 motors are able to transport artificial and natural kinesin-1 cargoes, but are efficiently inhibited by the addition of the relevant small molecule. Single-molecule imaging in vitro revealed that inhibitor addition reduces the number of processively moving motors on the microtubule, with minor effects on motor run length and velocity. It is likely that these inhibition strategies can be successfully applied to other members of the kinesin superfamily due to the high conservation of the kinesin motor domain. The described engineered motors will be of great utility to dynamically and specifically study kinesin function in cells and animals.

Published

2016

8. The Highwire Ubiquitin Ligase Promotes Axonal Degeneration by Tuning Levels of Nmnat Protein

Author

Xia Li, Jiaxing Li, Kan Sun, Yan Hao, Chunlai Wu, Richard I. Hume, Catherine A. Collins, Xin Xiong, Pushpanjali Soppina, and Bibhudatta Mishra

Subjects

Wallerian degeneration, medicine.disease_cause, Mice, Ubiquitin, Neurobiology of Disease and Regeneration, Drosophila Proteins, Nicotinamide-Nucleotide Adenylyltransferase, Biology (General), Motor Neurons, Mutation, Neuronal Morphology, biology, Kinase, General Neuroscience, MAP Kinase Kinase Kinases, Axon Guidance, Ubiquitin ligase, Cell biology, Drosophila melanogaster, Phenotype, General Agricultural and Biological Sciences, Research Article, QH301-705.5, Ubiquitin-Protein Ligases, Neuromuscular Junction, Neurophysiology, Down-Regulation, Nerve Tissue Proteins, Signaling Pathways, General Biochemistry, Genetics and Molecular Biology, Developmental Neuroscience, medicine, Animals, Biology, General Immunology and Microbiology, Nicotinamide-nucleotide adenylyltransferase, MAP kinase kinase kinase, Ubiquitination, medicine.disease, Molecular biology, Axons, nervous system, Cellular Neuroscience, Synapses, biology.protein, NAD+ kinase, Molecular Neuroscience, Wallerian Degeneration, Neuroscience, Synaptic Plasticity

Abstract

Highwire, a conserved axonal E3 ubiquitin ligase, regulates the initiation of axonal degeneration after injury in Drosophila by regulating the levels of the NAD+ biosynthetic enzyme, Nmnat, and the Wnd kinase., Axonal degeneration is a hallmark of many neuropathies, neurodegenerative diseases, and injuries. Here, using a Drosophila injury model, we have identified a highly conserved E3 ubiquitin ligase, Highwire (Hiw), as an important regulator of axonal and synaptic degeneration. Mutations in hiw strongly inhibit Wallerian degeneration in multiple neuron types and developmental stages. This new phenotype is mediated by a new downstream target of Hiw: the NAD+ biosynthetic enzyme nicotinamide mononucleotide adenyltransferase (Nmnat), which acts in parallel to a previously known target of Hiw, the Wallenda dileucine zipper kinase (Wnd/DLK) MAPKKK. Hiw promotes a rapid disappearance of Nmnat protein in the distal stump after injury. An increased level of Nmnat protein in hiw mutants is both required and sufficient to inhibit degeneration. Ectopically expressed mouse Nmnat2 is also subject to regulation by Hiw in distal axons and synapses. These findings implicate an important role for endogenous Nmnat and its regulation, via a conserved mechanism, in the initiation of axonal degeneration. Through independent regulation of Wnd/DLK, whose function is required for proximal axons to regenerate, Hiw plays a central role in coordinating both regenerative and degenerative responses to axonal injury., Author Summary Axons degenerate after injury and during neurodegenerative diseases, but we are still searching for the cellular mechanism responsible for this degeneration. Here, using a nerve crush injury assay in the fruit fly Drosophila, we have identified a role for a conserved molecule named Highwire (Hiw) in the initiation of axonal degeneration. Hiw is an E3 ubiquitin ligase thought to regulate the levels of specific downstream proteins by targeting their destruction. We show that Hiw promotes axonal degeneration by regulating two independent downstream targets: the Wallenda (Wnd) kinase, and the NAD+ biosynthetic enzyme nicotinamide mononucleotide adenyltransferase (Nmnat). Interestingly, Nmnat has previously been implicated in a protective role in neurons. Our findings indicate that Nmnat protein is down-regulated in axons by Hiw and that this regulation plays a critical role in the degeneration of axons and synapses. The other target, the Wnd kinase, was previously known for its role in promoting new axonal growth after injury. We propose that Hiw coordinates multiple responses to regenerate damaged neuronal circuits after injury: degeneration of the distal axon via Nmnat, and new growth of the proximal axon via Wnd.

Published

2012