The Institute of Soil Genomics for Healthy Community Forestry

The Institute of Soil Genomics for Healthy Community Forestry

Community Development and Urban Planning

Kansas City, Missouri 281 followers

We help you grow trees, not just plant them.

About us

🌱 Welcome to the Institute of Soil Genomics for Healthy Community Forestry! 🌳 🔬 Unleashing the Secrets of Soil Genomics for Greener Tomorrow 🔬 At the forefront of innovation in community forestry, our institute stands as a beacon of transformation and sustainability. We are not your typical organization; we are an independent, non-profit entity with a vision that reaches far beyond the horizon of conventional forestry practices. 🌿 Why Are We Unique? 🌿 Our roots run deep in pursuing excellence, driven by a collaborative spirit that binds us with diverse partners, collaborators, and stakeholders. The Institute of Soil Genomics for Healthy Community Forestry thrives on a shared mission to unlock the extraordinary potential hidden beneath the Earth's surface. 💡 What Sets Us Apart? 💡 Drawing from a wellspring of expertise, our institute is an industry-facing powerhouse. Our exceptional team combines cutting-edge research and development services with a passion for real-world impact. Our commitment to applied knowledge sets us apart, empowering us to solve the challenges that define urban forestry in the 21st century. 🌍 Join the Green Revolution 🌍 We invite professionals, enthusiasts, and visionaries to connect with us and dive into the world of Soil Genomics and Urban Forestry. Curiosity is the key that unlocks the door to a brighter, greener future. Together, we will shape landscapes, promote sustainability, and create a healthier environment for future generations. 🤝 Connect with Us Today! 🤝 If you're ready to explore the uncharted territories of Soil Genomics, discover groundbreaking solutions, and make a tangible difference, join our vibrant community. Let's sow the seeds of change and cultivate a thriving ecosystem for a more sustainable and resilient world. 🌿 Let's Grow Together! 🌿

Industry
Community Development and Urban Planning
Company size
2-10 employees
Headquarters
Kansas City, Missouri
Type
Nonprofit
Founded
2023
Specialties
Urban Forestry, Genomic Soil Analysis, Water Management, Biological Inputs, and Urban Development & Planning

Locations

Employees at The Institute of Soil Genomics for Healthy Community Forestry

Updates

  • We will have two Urban Forest Soil Genomics Workshops scheduled for September: September 20th: St Louis MO, sign up here: https://cvent.me/gD318Z September 24th: Austin TX, sign up here: https://cvent.me/x0o0A2 Urban trees play a critical role in sustaining the living quality of urban dwellers. However, the built environment is quite different from the natural environments where trees evolved over millions of years. That is why urban trees struggle. The reason is that the building process destroys the soil by stripping off topsoil, compaction, impervious pavement, deicing salt and other pollutants, heat island, over- and under-watering, and depleting organic matter and soil microbiome. How can trees survive and thrive under these conditions? This workshop will address most of the common problems we found in urban soils. What is the real limiting factor? Does green stormwater infrastructures work? We will provide insight into the soil microbiome with genomics testing. For example, how do deicing salts affect soil aeration and soil microbiome? We will also introduce techniques on how to build back the healthy soil required by healthy trees. CEUs/PDHs:(* CEU's Pending) Credits: LACES 3, ISA 3, PGMS 3, NALP 3, NRPA 3 The Austin Tx workshop will offer a bonus topic: (1 LACES PDH & 1 ISA CEU ): How to keep trees hydrated during drought and water restrictions?

    • No alternative text description for this image
    • No alternative text description for this image
  • Urban Forest Soil Genomics Workshop Boston MA (In-Person) on August 28, 2024 at Franklin Park Zoo in Boston. Urban trees play a critical role in sustaining the living quality of urban dwellers. However, the built environment is quite different from the natural environments where trees evolved over millions of years. That is why urban trees struggle. The reason is that the building process destroys the soil by stripping off topsoil, compaction, impervious pavement, deicing salt and other pollutants, heat island, over- and under-watering, and depleting organic matter and soil microbiome. How can trees survive and thrive under these conditions? This workshop will address most of the common problems we found in urban soils. What is the real limiting factor? Does green stormwater infrastructures work? We will provide insight into the soil microbiome with genomics testing. For example, how do deicing salts affect soil aeration and soil microbiome? We will also introduce techniques on how to build back the healthy soil required by healthy trees. learn more and register here: https://cvent.me/VV310M This workshop is right after the MNLA's Plant Geek Day event (https://lnkd.in/e5vJ8xj6). Separate registrations required CEUs/PDHs:(* CEU's Pending) Credits: LACES 3, ISA 3, PGMS 3, NALP 3, MCH 3*, NRPA 3

    • No alternative text description for this image
  • This is our kind of guy. We always say don’t just plant a tree; focus on growing a tree and in this case saving a tree for future growth.

    View profile for Chetan Singh Solanki, graphic

    Professor at IIT Bombay, Founder of Energy Swaraj Foundation, Brand Ambassador of Solar Energy, Govt of MP, Google search "Solar Man of India"

    When you truly love nature, you will do everything in your power to protect it. Protecting #nature is ultimately protecting ourselves. Salute to the person in this video. Let us all strive to protect every aspect of our natural world: the #air, water, soil, trees, glaciers, #forest and oceans. Halting the rise in global temperatures and mitigating climate change must be our highest priority in these critical times. #EnergySwaraj

  • Urban Forest Soil Genomics Workshop, Episode II We have an in-person one and a virtual one. The in-person one will be held in Ashland Va. Check out the event pages here: In-person event: https://cvent.me/nM81Yr Virtual event: https://cvent.me/X9kOwo Note: The programs are slightly different for the in-person one and the virtual one. The In-person Event is fine-tuned to be more suitable for eastern United States situations. The Virtual Event is suitable for all urban forest audiences.

    • No alternative text description for this image
    • No alternative text description for this image
  • Artificial intelligence helps scientists engineer plants to fight climate change

    View profile for L. Dean Alberty, graphic

    Director of Strategic Planning at The Institute of Soil Genomics for Healthy Community Forestry and the new 2024 President of MoGIA (Missouri Green Industry Alliance).

    The Intergovernmental Panel on Climate Change (IPCC) has declared that removing carbon from the atmosphere is now essential to fighting climate change and limiting the rise in global temperature. To support these efforts, Salk Institute scientists are harnessing plants' natural ability to draw carbon dioxide out of the air by optimizing their root systems to store more carbon for a longer period of time.To design these climate-saving plants, scientists in Salk's Harnessing Plants Initiative are using a sophisticated new research tool called SLEAP—an easy-to-use artificial intelligence (AI) software that tracks multiple features of root growth. Created by Salk Fellow Talmo Pereira, SLEAP was initially designed to track animal movement in the lab. Now, Pereira has teamed up with plant scientist and Salk colleague Professor Wolfgang Busch to apply SLEAP to plants. In a study published in Plant Phenomics, Busch and Pereira debut a new protocol for using SLEAP to analyze plant root phenotypes—how deep and wide they grow, how massive their root systems become, and other physical qualities that—prior to SLEAP—were tedious to measure. The application of SLEAP to plants has already enabled researchers to establish the most extensive catalog of plant root system phenotypes to date. Together with massive genome sequencing efforts for elucidating the genotype data in large numbers of crop varieties, these phenotypic data, such as a plant's root system growing especially deep in soil, can be extrapolated to understand the genes responsible for creating that especially deep root system. This step—connecting phenotype and genotype—is crucial in Salk's mission to create plants that hold on to more carbon and for longer, as those plants will need root systems designed to be deeper and more robust. Implementing this accurate and efficient software will allow the Harnessing Plants Initiative to connect desirable phenotypes to targetable genes with groundbreaking ease and speed. Our organization is planning ahead by increasing the number of urban soil samples for genomics reports, to contribute to a better environment.

    • No alternative text description for this image
  • The ingredients for a tastier, stronger tea could be in the soil

    View profile for L. Dean Alberty, graphic

    Director of Strategic Planning at The Institute of Soil Genomics for Healthy Community Forestry and the new 2024 President of MoGIA (Missouri Green Industry Alliance).

    The ingredients for a tastier, stronger tea could be in the soil From the strength of black and Earl Grey teas to the soothing and light flavors of herbal and green teas, the little plants brewed in this millennia-old beverage have endless variety. However, the complexity and quality of their flavor could depend on something even smaller than the leaves themselves. A study published February 15 in the journal Current Biology found that the microbes at the tea’s roots may make high-quality tea even better.  Some previous studies noted that the soil microbes living at the roots of plants affect the way that nutrients are absorbed and used by the plant to grow and flourish. However, improving the quality of tea leaves in the lab by genetically altering the plants is challenging and difficult to achieve in the lab. According to the team from this study, there is a vested interest in finding other ways to modify and enhance tea, potentially with microbial agents. "Our previous discussions have emphasized that regardless of whether you're growing tea or trees, the key lies in the soil. Perhaps we should delve deeper into the genomics of soil and dedicate more time and effort towards restoring our planet. Happy Earth Day!".

    • No alternative text description for this image
  • The anthropogenic salt cycle is why your soil's health matters.

    View profile for L. Dean Alberty, graphic

    Director of Strategic Planning at The Institute of Soil Genomics for Healthy Community Forestry and the new 2024 President of MoGIA (Missouri Green Industry Alliance).

    Increasing salt production and use is shifting the natural balances of salt ions across Earth systems, causing interrelated effects across biophysical systems collectively known as freshwater salinization syndrome The natural salt cycle and synthesize increasing global trends of salt production and riverine salt concentrations and fluxes. The natural salt cycle is primarily driven by relatively slow geologic and hydrologic processes that bring different salts to the surface of the Earth. Anthropogenic activities have accelerated the processes, timescales and magnitudes of salt fluxes and altered their directionality, creating an anthropogenic salt cycle. Global salt production has increased rapidly over the past century for different salts, with approximately 300 Mt of NaCl produced per year. Street trees are often affected by the road salt that is pushed closer to them. This increases the stress factor in the soil, which can set off an imbalance in the biome around the trees. There have been many discussions about this issue, and efforts are being made to change the course of action. A salt budget for the USA suggests that salt fluxes in rivers can be within similar orders of magnitude as anthropogenic salt fluxes, and there can be substantial accumulation of salt in watersheds. Excess salt propagates along the anthropogenic salt cycle, causing freshwater salinization syndrome to extend beyond freshwater supplies and affect food and energy production, air quality, human health and infrastructure. There is a need to identify environmental limits and thresholds for salt ions and reduce salinization before planetary boundaries are exceeded, causing serious or irreversible damage across Earth systems. To learn about your city's soil information and assess the soil's genomics health, start a conversation with our team.. Diver deeper into this topic in multiple ways with the following TreeDiaper ( Dr. Wei Zhang) educational online and to the following individuals who suported this article. Sujay S. Kaushal, Gene E. Likens, Paul M. Mayer, Ruth R. Shatkay, Sydney A. Shelton, Stanley B. Grant, Ryan M. Utz, Alexis M. Yaculak, Carly M. Maas, Jenna E. Reimer, Shantanu V. Bhide, Joseph T. Malin & Megan A. Rippy Kaushal, S.S., Likens, G.E., Mayer, P.M. et al. The anthropogenic salt cycle. Nat Rev Earth Environ 4, 770–784 (2023). https://lnkd.in/gujhwS39

    • No alternative text description for this image
  • Fixing nitrogen

    View profile for L. Dean Alberty, graphic

    Director of Strategic Planning at The Institute of Soil Genomics for Healthy Community Forestry and the new 2024 President of MoGIA (Missouri Green Industry Alliance).

    Azotobacter vinelandi is a Gram-negative diazotroph, which means it can fix nitrogen while growing aerobically. A. vinelandi is a free-living nitrogen fixer that produces many phytohormones and vitamins in soils. It also produces fluorescent pyoverdine pigments. The nitrogenase holoenzyme of A. vinelandi has been characterized by X-ray crystallography in both ADP tetrafluoroaluminate-bound and Mg ATP-bound states. The enzyme possesses molybdenum iron-sulfido cluster cofactors (FeMoco) as active sites, each bearing two pseudocubic iron-sulfido structures. A. vinelandi is a genetically tractable system that is used to study nitrogen fixation. Genetically engineered strains can produce significantly higher amounts of ammonia. Appropriate ammonia emissions can provide crops with the ammonia they need without excess amounts that can pollute lakes and oceans. A. vinelandi also produces significant amounts of alginate. In the nitrogen cycle, A. vinelandi plays a fundamental role in nitrogen fixation, a pivotal step in converting atmospheric nitrogen into forms usable by plants and, subsequently, other organisms. Unlike some other nitrogen-fixing bacteria that form symbiotic relationships with plants, A. vinelandi operates independently, contributing to the nitrogen cycle in non-symbiotic environments. In agriculture, the role of A. vinelandi in nitrogen fixation is particularly significant. By converting atmospheric nitrogen into a form usable by plants, this bacterium contributes to soil fertility. Arborist can leverage the natural nitrogen-fixing abilities of A. vinelandi to reduce the reliance on synthetic fertilizers, promoting sustainable and eco-friendly agricultural practices. Next-generation companies are using this formation in products that cities and urban communities can obtain, helping generate a healthier soil complex. To learn more about this or obtain the products, contact solublesciences.com.

    • No alternative text description for this image

Similar pages