Tag: funding

Phase Genomics Announces Funding to Accelerate Discovery of New Lysin-Based Precision Antimicrobials

 

SEATTLE (March, 4, 2024) – Phase Genomics, Inc., a leading innovator at the forefront of genomics technology development, today announced $1.5MM in new funding from the Bill & Melinda Gates Foundation to fuel a new antimicrobial discovery platform. Leveraging the power of lysins, phage-derived proteins that selectively kill specific bacteria and archaea, the program aims to address two immediate threats that will shape the next century: a growing global antibiotic resistance crisis and the challenge of reducing global greenhouse gas emissions. The foundation of this effort rests on Phase Genomics’ proprietary global phage atlas, developed with support from the Gates Foundation. Under this project, Phase Genomics will deploy its platform to develop antimicrobial agents that bypass resistance against Campylobacter infections and methanogenic archaea in ruminants that drive global methane emissions.

“Our work at the frontier of microbiome research has unlocked a wealth of new insights on phages, the viruses that infect bacteria. Now, with support from the Gates Foundation, we’re harnessing our global phage database with the goal of improving human and environmental health and providing a critical alternative to traditional antibiotics,” said Ivan Liachko, PhD, founder and CEO of Phase Genomics. “The need for breakthrough therapeutics to combat the growing AMR crisis is urgent. We’ve built the right technology to identify and engineer lysin candidates primed to combat microbes both in environmental settings as well as emerging AMR biothreats and help overcome the industry-wide inertia facing novel antibiotic development.”

Derived from bacteriophage (or simply, phage) genomes, lysins are highly specific lytic proteins that kill bacteria by dismantling the cell wall structure, sparing off-target healthy microbes that are often collateral damage in traditional, systemic antibiotic treatment. Lysin-based antibiotics are well-suited for rapid, scalable biomanufacturing and deployment. Targeted bacteria are also much less likely to develop resistance to lysins than both traditional antibiotics and intact phages, providing a sustainable and durable framework to counter the accelerating antibiotic resistance threat. 

The new platform will build on data from Phase Genomics’ bacteriophage discovery engine which holds one of the world’s largest and most comprehensive collections of phage-microbe interactions containing hundreds of thousands of new host-resolved phage genomes. This continuously-growing phage interactome atlas is primed for the rapid discovery of wide-ranging classes of antimicrobial lysins derived from phages. The platform is superior to other approaches in both scale and accuracy, simultaneously resolving both microbial targets and the phages that infect them, with each pair containing a potential target-specific lysin candidate. Phase Genomics’ ProxiMeta™-powered phage atlas forms a deep well of target bacterial pathogens and new candidate biologics to tackle emerging drug-resistant pathogens and environmental biothreats.

This year-long project also marks a first-of-its-kind collaboration between Phase Genomics and Seattle-based Lumen Bioscience, who will assess lysin bioactivity in their robust and scalable microbial expression system.

Follow Phase Genomics on X and LinkedIn for the latest news and information.

 

About Phase Genomics 

Phase Genomics applies proprietary proximity ligation technology to enable chromosome-scale genome assembly, microbiome discovery, as well as analysis of genomic variation and genome architecture. In addition to a comprehensive portfolio of laboratory and computational services and products, including kits for plants, animals, microbes, and human samples, they also offer an industry-leading genome and metagenome assembly and analysis software.

Based in Seattle, WA, the company was founded in 2015 by a team of genome scientists, software engineers, and entrepreneurs. The company’s mission is to empower scientists with genomic tools that accelerate breakthrough discoveries.

 

Contact

Eric Schudiske

eric@s2spr.com

Bacterial pathogens have their own nemesis, and mimicking it can help solve the global AMR crisis

image of the globe surrounded by images of plants and viruses

 

Decades of antibiotic use – and abuse – are triggering a global rise in antibiotic resistance and limiting the usefulness of these life-saving drugs. In a nod to the adage, “The enemy of my enemy is my friend,” a solution may lie with bacteria’s oldest adversary: phages, the viruses that prey upon them. Our team at Phase Genomics is harnessing groundbreaking new metagenomic data and AI to tap into the evolutionary innovations of phages – and to eradicate dangerous microbial pathogens with surgical precision.

 

The need could not be greater. Fewer new antibiotics are hitting the market. The UN estimates that by 2050, worldwide deaths from antibiotic-resistant “superbugs” will overtake deaths from cancer.  Early 20th century scientists explored deploying phages to cure bacterial infections, an idea that has been recently resurrected. Phages are a staggeringly diverse class of bacteria-killers. By one estimate there are 1031 of them on this planet right now, vastly more than all living organisms combined. But using phages to cure infections has its own drawbacks: Mass production is difficult since phages only grow in bacteria, which can be difficult to culture, and it turns out bacteria have a barrage of defenses against intact viruses, imparting resistance against them.

 

While phages present one opportunity to help us stave off a return to the pre-penicillin past, we can also use their anti-bacterial weapons to launch a new arsenal rooted in synthetic biology. Phages produce proteins called lysins to destroy their hosts’ cell walls. These proteins have evolved over millennia to specifically target the phages’ hosts. They can be purified and used as precision antimicrobials, molecules that specifically kill the target bacteria without the collateral damage and resistance brought about by traditional wide-spectrum antibiotics.

 

Our team has used our unique genome sequencing technology to build the world’s largest catalog of the genomes of phages and the microbes that they attack – including the sequences of lysin proteins that they make. We’re harnessing this catalog to design, synthesize, and perfect lysin-based therapeutics that can attack bacterial pathogens safely, effectively, and with a surgical precision that today’s antibiotics lack.

 

Lysins hold tremendous advantages over traditional antibiotics. Antibiotics take out swathes of bacteria in our microbiomes that are essential for good health, leaving us more vulnerable to future infections – like the dreaded C. difficile – as well as to immune dysregulation. Yet most lysins target only the phage’s host species and its close relatives. And though antibiotic resistance spreads rapidly via plasmids, bacteria struggle to evolve resistance to exogenously introduced lysins.

 

Our collective knowledge of lysins to date comes largely from isolated experiments on phages or small-scale genomic studies. To deploy lysins as a life-saving solution, we need detailed knowledge of the intricate and intimate interactions between phages and bacteria. Phase Genomics has led this effort by building a vast catalog containing hundreds of thousands of phage genomes from different microbial environments. Our proprietary ProxiMeta technology employed for these experiments preserves unique information about essential ecological interactions in these microbiomes, including the host bacterial species that specific phages target. Thanks to this large and growing catalog of phage-microbe interactions, for many pathogenic bacteria, we can find specific lysins that could turn its cell walls into Swiss cheese.

 

We are using this foundational knowledge to build the first foundry for lysins. With support from the Bill and Melinda Gates Foundation, Phase Genomics is collaborating with Lumen Bioscience to design, grow, and purify lysins identified by our catalog. This proving ground will serve as the foundation for a future pipeline for lysin design – augmented by machine learning to hone target specificity, perfect performance and even create entirely new lysins with a desired target specificity. To make a custom-designed lysin against almost any bacteria, we would need to find a phage – and its lysin – that attacks it. This approach to lysin research and discovery has applications even beyond medicine, such as critically needed environmental remediation.

 

Our goal to develop therapeutic lysins would upend the existing paradigm for treating bacterial infections. Today, medical professionals have a shrinking pool of imperfect antibiotics that cut a swathe through our microbiomes to take out the bacterial bad guys. With lysins on the shelf as an option, we would be taking away this machete, and replacing it with a scalpel.

 

Funding the Future of Cancer Research

Genome Startup Day Spring 2022

Stories from Startup Founders and an Insider’s Advice on SBIR Grants 

 

Some of tomorrow’s biggest breakthroughs in cancer treatment are in the works today in startup labs across the US. On March 30th, we brought together CEOs and leaders in the cancer startup industry for a behind-the-scenes look at how emerging technologies are taking aim at one of the deadliest diseases in our world, and how these startup leaders are carving successful careers in the cancer tech landscape. Watch the replay of the event to hear their advice on deciding when to commercialize, how to scale up, and who to hire. 

 

 

Getting Started with SBIR

One of the struggles of starting a new company is the constant pressure to find funding. However, there are many options for various stage startup companies that are outside of Venture Capital. While VC funds are a great way to raise money to embark on your journey to commercialization, programs such as the Small Business Innovation Research (SBIR) Fund offer resources that allow founders to obtain funding without losing equity. The SBIR program’s goal is to create jobs in the U.S. by supporting commercially-directed, for-profit, small businesses. Submitting an SBIR proposal may be a daunting process, but during our fireside chat, Greg Evans – Program Director at the National Cancer Institute, SBIR – shared some helpful tips for those looking to take advantage of this resource. 

 

Common Mistakes

1. Not talking to the program officers in advance 

Evans emphasized, “Part of our job is to serve [as] a “help desk” function” – to be available to help people strategize on grant submissions and how to be competitive.” Program officers can help you construct the proper proposal, advise you on how much money to apply for, and direct you towards the right grants to pursue. Get in contact with them to plan out your proposal before submitting.

 

2. Applying for multiple grants

While your instincts may lead you to hedge your bets and apply for grants across several topics, Evans notes that the best proposals are the ones that have identified the scope of their project, and have committed to a market sector. Instead of sending in three proposals, pick your best proposal based on the data you have, competition in the market, strengths of people in your company, and make the business decision to focus your efforts.

 

3. Only applying for “priority areas”

The NIH does list Research Topics of Interest; however, this does not discourage companies from applying for grants outside of these topics. Evans notes that the burden is on the small business to have a product that is better than current competing products, regardless of if it is in a NCI “priority area.”

 

For more helpful tips on applying for an SBIR grant, including which letters of support you will need, watch the full Fireside Chat with Ivan Liachko and Greg Evans.

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