# Platelet Factor 4 and heparins in NETosis and Sepsis

> **NIH NIH P01** · UNIVERSITY OF PENNSYLVANIA · 2022 · $590,776

## Abstract

ABSTRACT
Sepsis is a multi-organ, dysfunctional response to infection. PROJECT 4 focuses on the role of released
neutrophil extracellular traps (NETs), its ability to entrap microbes, and NET-degradation products (NDPs, e.g.,
cell-free DNA and histones) in organ damage, and on the interactions of the cationic chemokine, platelet factor
4 (PF4) and the polyanion heparin with NETs. On presentation, many septic patients have an overwhelming
amount of released NETs so that preventing NET release (NETosis) by blocking peptidylarginine deiminase 4
or accelerating NET lysis would be ineffective in preventing morbidity and mortality. We propose that in sepsis
NET stabilization, enhanced microbe entrapment, and/or NDP sequestration would be protective. Our studies
have defined three related strategies that can achieve one or more of these goals. We propose to better
understand the underlying mechanism(s) of these strategies, hemostatic/thrombotic implications, and their
potential therapeutic efficacy. Specific Aim (SA) #1: Understanding small, positive protein effects on
NETs. PF4 and other small, positive proteins (e.g., protamine sulfate (ProSO4)) compact NETs, decreasing
their lysis by DNases. PF4, but not ProSO4, prevents NDP release, an important difference between these
cationic proteins that will be explored to understand the impact of compacting NETs in sepsis. PF4 enhances
microbe entrapment and protects the endothelium from NET injury. Whether ProSO4 similarly effects NET
biology given that it releases NDPs will be pursued in a microfluidic system and in murine endotoxic/sepsis
models. Both cationic proteins will be compared to or in conjunction with other NET-directed therapeutic
options. The side-effects of these cations, especially on hemostasis, will be explored. Pilot trials of canine and
human (h) PF4s will be infused in dogs with spontaneous peritonitis with the long-term goal of a clinical trial in
this large animal sepsis setting. SA#2: Studies on enhancing the effect of PF4 on NETs. We have found
that a monoclonal antibody KKO that enhances PF4 binding to NETs further increases DNase resistance. An
Fc-modified KKO variant protects against NET deleterious effects in vitro and in mice models of sepsis. The
underlying mechanism(s) of how KKO, and other anti-PF4 antibodies effect NET biology will be defined. KKO
infusion studies will be pursued in mice expressing hPF4 looking at efficacy and thrombotic complications and
in pilot studies of co-infused KKO and hPF4 in septic dogs. SA#3: Understanding ODSH effects on NETs in
sepsis. We have previously shown that the desulfated heparin ODSH, which has markedly lower anticoagulant
effects than heparin, is protective in a histone infusion murine model and will explore its mechanistic basis in
vitro and in murine sepsis models as in SA#1. We will continue a dose escalation study on the efficacy of
ODSH in dogs with spontaneous peritonitis to define maximal tolerated dose for an eventual clinical ...

## Key facts

- **NIH application ID:** 10434812
- **Project number:** 5P01HL146373-03
- **Recipient organization:** UNIVERSITY OF PENNSYLVANIA
- **Principal Investigator:** Mortimer Poncz
- **Activity code:** P01 (R01, R21, SBIR, etc.)
- **Funding institute:** NIH
- **Fiscal year:** 2022
- **Award amount:** $590,776
- **Award type:** 5
- **Project period:** 2020-05-10 → 2025-04-30

## Primary source

NIH RePORTER: https://reporter.nih.gov/project-details/10434812

## Citation

> US National Institutes of Health, RePORTER application 10434812, Platelet Factor 4 and heparins in NETosis and Sepsis (5P01HL146373-03). Retrieved via AI Analytics 2026-05-22 from https://api.ai-analytics.org/grant/nih/10434812. Licensed CC0.

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