Platelets are currently stored at room temperature before transfusion to maximize circulation time. This approach has numerous downsides, including limited storage duration, bacterial growth risk, and increased costs. Cold storage could alleviate these problems. However, the functional consequences of cold exposure for platelets are poorly understood. In the present study, we compared the function of cold-stored platelets (CSP) and room temperature-stored platelets (RSP) in vitro, in vivo, and post-transfusion. CSP formed larger aggregates under in vitro shear while generating similar contractile forces compared to RSP. We found significantly reduced GPVI levels after cold exposure of 5-7 days. After transfusion in humans, CSP were mostly equivalent to RSP yet aggregated significantly less to the GPVI agonist collagen. In a mouse model of platelet transfusion, we found a significantly lower response to the GPVI-dependent agonist convulxin and significantly lower GPVI levels on the surface of transfused platelets after cold storage. In summary, our data support an immediate but short-lived benefit of CSP and highlight the need for thorough investigations of this product. (NCT03787927)
(De)form and Function: Measuring Cellular Forces with Deformable Materials and Deformable Structures
The ability for biological cells to produce mechanical forces is important for the development, function, and homeostasis of tissue. The measurement of cellular forces is not a straightforward task because individual cells are microscopic in size and the forces they produce are at the nanonewton scale. Consequently, studies in cell mechanics rely on advanced biomaterials or flexible structures that permit one to infer these forces by the deformation they impart on the material or structure. Herein, the scientific progression on the use of deformable materials and deformable structures to measure cellular forces are reviewed. The findings and insights made possible with these approaches in the field of cell mechanics are summarized.
The deep-branching eukaryote Giardia lamblia is an extracellular parasite that attaches to the host intestine via a microtubule-based structure called the ventral disc. Control of attachment is mediated in part by the movement of two regions of the ventral disc that either permit or exclude the passage of fluid under the disc. Several known disc-associated proteins (DAPs) contribute to disc structure and function, but no force-generating protein has been identified among them. We recently identified several Giardia actin (GlActin) interacting proteins at the ventral disc, which could potentially employ actin polymerization for force generation and disc conformational changes. One of these proteins, Disc and Actin Associated Protein 1 (DAAP1), is highly enriched at the two regions of the disc previously shown to be important for fluid flow during attachment. In this study, we investigate the role of both GlActin and DAAP1 in ventral disc morphology and function. We confirmed interaction between GlActin and DAAP1 through coimmunoprecipitation, and used immunofluorescence to localize both proteins throughout the cell cycle and during trophozoite attachment. Similar to other DAPs, the association of DAAP1 with the disc is stable, except during cell division when the disc disassembles. Depletion of GlActin by translation-blocking antisense morpholinos resulted in both impaired attachment and defects in the ventral disc, indicating that GlActin contributes to disc-mediated attachment.Depletion of DAAP1 through CRISPR interference resulted in intact discs but impaired attachment, gating, and flow under the disc. As attachment is essential for infection, elucidation of these and other molecular mediators is a promising area for development of new therapeutics against a ubiquitous parasite.Author SummaryGiardia lamblia is a single-celled organism and one of the most common gastrointestinal parasites worldwide. In developing countries, recurrent Giardia infections are common, due to lack of access to clean water. Giardia infections can lead to diarrhea, vomiting, dehydration, disruption of the intestinal microbiome, and chronic infections can lead to colitis and irritable bowel syndrome. Because existing drug treatments have side effects and Giardia’s resistance to drugs is increasing, new treatment strategies are needed. The parasite’s attachment to the host’s intestine is mediated by a Giardia-specific structure that resembles a suction cup and is called the ventral adhesive disc. We previously identified DAAP1, a protein which interacts with Giardia actin and localizes to the ventral disc. Here, we explore the relationship between these two proteins and investigate their role in disc-based attachment. Most disc proteins, including DAAP1, are unrelated to any human proteins, making them appealing drug targets to inhibit parasite attachment and infection.
Disc and Actin Associated Protein 1 influences attachment in the intestinal parasite Giardia lamblia
The deep-branching eukaryote Giardia lamblia is an extracellular parasite that attaches to the host intestine via a microtubule-based structure called the ventral disc. Control of attachment is mediated in part by the movement of two regions of the ventral disc that either permit or exclude the passage of fluid under the disc. Several known disc-associated proteins (DAPs) contribute to disc structure and function, but no force-generating protein has been identified among them. We recently identified several Giardia actin (GlActin) interacting proteins at the ventral disc, which could potentially employ actin polymerization for force generation and disc conformational changes. One of these proteins, Disc and Actin Associated Protein 1 (DAAP1), is highly enriched at the two regions of the disc previously shown to be important for fluid flow during attachment. In this study, we investigate the role of both GlActin and DAAP1 in ventral disc morphology and function. We confirmed interaction between GlActin and DAAP1 through coimmunoprecipitation, and used immunofluorescence to localize both proteins throughout the cell cycle and during trophozoite attachment. Similar to other DAPs, the association of DAAP1 with the disc is stable, except during cell division when the disc disassembles. Depletion of GlActin by translation-blocking antisense morpholinos resulted in both impaired attachment and defects in the ventral disc, indicating that GlActin contributes to disc-mediated attachment. Depletion of DAAP1 through CRISPR interference resulted in intact discs but impaired attachment, gating, and flow under the disc. As attachment is essential for infection, elucidation of these and other molecular mediators is a promising area for development of new therapeutics against a ubiquitous parasite.
Background: Platelets (PLTs) are currently stored at 22°C (RT, room temperature) for clinical purposes. This approach ensures long circulation time but has numerous downsides, including limited storage time due to the risk of bacterial growth and increased costs due to bacterial testing or pathogen reduction processing. PLTs stored at 4°C were the standard of care in the 1960s and 1970s. In our previous study with healthy volunteers, we showed that humans who received cold-stored PLTs have a significantly weaker response to collagen (an agonist that acts predominantly via GPVI) compared to RT-stored PLTs. If and how cold-stored PLTs recover their function in vivo is poorly understood. Methods: We obtained human PLTs by an apheresis collection and sampled either at baseline (fresh) or after five days at RT or 4°C. To test the response to GPVI-dependent agonists, we stimulated platelet-rich plasma or washed PLTs with collagen and the GPVI-specific agonist convulxin (CVX) and tested for activated integrin and α-degranulation by flow cytometry. Platelet aggregation, in response to GPVI-dependent agonists, was tested by aggregometry. We checked for GPVI expression levels by flow cytometry and for signaling events downstream of GPVI by immunoblotting. To allow for recovery of function in vitro, we incubated either 4°C-stored, or RT-stored PLTs with fresh, platelet-depleted blood for 15min, and perfused the reconstituted whole blood through a microfluidic block and post device to quantify the contractile forces of platelet aggregates. Additionally, we performed platelet force measurements at the single cell level using a traction force microscopy approach. To validate a murine model of platelet storage and transfusion, we replicated functional studies in vitro by testing mouse PLTs for integrin activation and α-degranulation by flow cytometry. Platelet aggregation in response to collagen, CVX, and the GPVI-specific antibody JAQ-1 with crosslinking anti-IgG was also tested. To evaluate the platelet function after transfusion, we obtained whole blood from UbiC-GFP mice and isolated platelet-rich plasma followed by storage for 24 hours at either 4°C or RT. To allow tracking of stored PLTs in vivo, we transfused the UbiC-GFP PLTs into wild-type C57BL/6J mice and tested for integrin activation of endogenous and transfused PLTs. Results: In human PLTs, we found a significantly increased integrin response in 4°C-stored PLTs stimulated with collagen in flow cytometry studies in vitro. Similarly, the aggregation response of 4°C-stored PLTs to collagen was significantly increased compared to RT-stored PLTs in vitro. In line with these findings, we observed more PLCγ2 phosphorylation and Syk phosphorylation at baseline in 4°C-stored PLTs compared to RT-stored PLTs, suggesting more pre-activation downstream of GPVI. However, no differences in PLCγ2 phosphorylation or Syk-phosphorylation were found between RT and 4°C-stored PLTs after stimulation with CVX, and no significant differences in surface expression levels of GPVI were detected between RT and 4°C. Stored platelets in plasma showed superior function after 4°C-storage in aggregation and flow cytometry assays. In contrast, we found similar contractile forces of platelet aggregates when RT-stored or 4°C-stored PLTs were added to platelet-depleted fresh blood. Additionally, at the single cell level, we found a similar magnitude of platelet forces in RT-stored and 4°C-stored PLTs. Similar to human PLTs, mouse PLTs showed significantly more integrin activation, P-selectin exposure, and aggregation in 4°C-stored PLTs compared to RT. To test the recovery of function of stored mouse platelets in vivo, we transfused GFP-positive PLTs into GFP-negative wild-type mice. Contrary to our pre-transfusion results, we found a significantly lower integrin activation response to CVX in 4°C-stored platelets after transfusion, consistent with our previous results in healthy human volunteers. Summary: The in vivo recovery of function of stored PLTs is an underappreciated phenomenon in platelet storage biology, and most studies are solely based on functional in vitro data. Based on our post-transfusion results, storage temperature affects the ability to recover function in vivo significantly in human and mouse platelets. Whether these differences lead to differences in clinical outcomes needs to be investigated in clinical trials. Disclosures Sniadecki: Stasys Medical Corporation: Current equity holder in private company, Other: Co-founder; Curi Bio: Current equity holder in publicly-traded company, Membership on an entity's Board of Directors or advisory committees.
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