diff --git a/JSchnable.tex b/JSchnable.tex index 2696963d3288a2d209f82c9e8018e7ec549f8a47..31d2e099762ba3143a852964dc889649b0766c62 100644 --- a/JSchnable.tex +++ b/JSchnable.tex @@ -2,11 +2,11 @@ %https://github.com/rossibarra/CV \documentclass[letterpaper]{article} -\usepackage{CJKutf8} +%\usepackage{CJKutf8} \usepackage{hyperref} \usepackage{geometry} \usepackage{etaremune} -\usepackage{fixltx2e} +%\usepackage{fixltx2e} \usepackage{pgf} \usepackage{float} \usepackage{textcomp} @@ -86,7 +86,7 @@ \vspace{0.25in} \centerline{\huge \textsc{\name}} %Updated transliteration of Schnable, thanks to Zhikai Liang -\centerline{\begin{CJK*}{UTF8}{gbsn}詹姆斯 . 施耐博\end{CJK*}} +%\centerline{\begin{CJK*}{UTF8}{gbsn}詹姆斯 . 施耐博\end{CJK*}} % Alternatively, print name centered and bold: %\centerline{\huge \bf \name} @@ -130,11 +130,11 @@ \\Associate Professor, Department of Agronomy and Horticulture \hfill 2019-2022 \\Assistant Professor, Department of Agronomy and Horticulture \hfill 2014-2019 \item Alphabet, Google, X\\ -Interim Technology Lead \hfill 2022 -\item Chinese Academy of Agricultural Sciences\\ -NSF PGRP Fellowship Supported Visiting Scholar \hfill 2014 -\item Donald Danforth Plant Science Center\\ -NSF PGRP Fellowship Supported Postdoctoral Researcher \hfill 2013 +Technology Lead \textit{(Interim)} \hfill 2022 +\item Danforth Plant Science Center \& Chinese Academy of Agricultural Sciences\\ +NSF PGRP Fellowship Supported Visiting Scholar \hfill 2013-2014 +%\item Donald Danforth Plant Science Center\\ +%NSF PGRP Fellowship Supported Postdoctoral Researcher \hfill 2013 \end{itemize} %EDUCATION @@ -177,7 +177,7 @@ NSF PGRP Fellowship Supported Postdoctoral Researcher \hfill 2013 \item ARPA-E ``\href{https://arpa-e.energy.gov/?q=news-item/arpa-e-announces-165-million-technologies-supporting-biofuels-supply-chain}{Soil Organic Carbon Networked Measurement System (SOCNET)}'' (co-PI) 2020-2023 \$1.9M \item NSF ``\href{https://www.nsf.gov/awardsearch/showAward?AWD_ID=1826781}{RII Track-2 FEC: Functional analysis of nitrogen responsive networks in Sorghum.}'' (co-PI) 2018-2023. \$4M \item FFAR ``\href{http://www.ncsa.illinois.edu/news/story/crops_in_silico_project_awarded_5_million}{Crops in silico: Increasing crop production by connecting models from the microscale to the macroscale.}'' (co-PI) 2019-2023. \$5M -\item NSF ``AI Institute for Resilient Agriculture'' (Investigator) 2021-2026 \$20M +\item NSF ``\href{https://aiira.iastate.edu/}{AI Institute for Resilient Agriculture}'' (Investigator) 2021-2026 \$20M %\item DOE-JGI Community Sequencing Program ``Expanding grass genome comparators.'' \end{itemize} @@ -218,13 +218,14 @@ NSF PGRP Fellowship Supported Postdoctoral Researcher \hfill 2013 \textit{Designs, manufactures, and deploys low-cost, instant readout, high-performance, field-based nutrient sensors for crops, soil, and water, improving agronomic management practices, increasing grower profitability and reducing the environmental footprint of agriculture.} \item Founder, \href{http://www.drylandgenetics.com/}{Dryland Genetics LLC}\hfill2014-Present\\ \textit{Using high throughput quantitative genetics and field phenotyping techologies to develop and commericialize higher yielding cultivars of crops already naturally adapted to using little water and growing arid regions where conventional agriculture fails in the absence of irrigation.} -\item Co-Founder, \href{https://www.data2bio.com/}{Data2Bio LLC} (USA) \& \begin{CJK*}{UTF8}{gbsn}DATA生物科技(北京)有限公司\end{CJK*} (China) \hfill2010-Present\\ +%\item Co-Founder, \href{https://www.data2bio.com/}{Data2Bio LLC} (USA) \& \begin{CJK*}{UTF8}{gbsn}DATA生物科技(北京)有限公司\end{CJK*} (China) \hfill2010-Present\\ +\item Co-Founder, \href{https://www.data2bio.com/}{Data2Bio LLC} \hfill2010-Present\\ \textit{Providing patented tGBS genotyping and genomic selection services to public and private sector plant and animal breeders in the USA and China.} \end{itemize} \subsection*{Entrepreneurship-Related Funding} \begin{itemize} -\item NSF (to EnGeniousAg) ``SBIR Phase II: Low-cost in-planta nitrate sensor'' 2023-2025 \$1M +%\item NSF (to EnGeniousAg) ``SBIR Phase II: Low-cost in-planta nitrate sensor'' 2023-2025 \$1M \item NSF (to EnGeniousAg) ``SBIR Phase I: Low-cost in-planta nitrate sensor'' 2019-2022 \$225k \item USDA (to EnGeniousAg) ``SBIR Phase I: Low-cost field-deployable sensors to monitor nitrate in soil and water.'' 2019-2021 \$100k \end{itemize} @@ -240,16 +241,16 @@ NSF PGRP Fellowship Supported Postdoctoral Researcher \hfill 2013 \section*{Advising} \begin{itemize} \item \textbf{Current Graduate Advisees:} -Hongyu Jin (PhD, Complex Biosystems), Michael Tross (PhD, Complex Biosystems), Nikee Shrestha (PhD, Complex Biosystems), Waqar Ali (PhD, Complex Biosystems), Ramesh Kanna Mathivanan (PhD, Agronomy and Horticulture), -Nate Korth (co-advised, PhD, Food Science), +Hongyu Jin (co-advised, PhD, Complex Biosystems), Fangyi Li (co-advised, PhD, Complex Biosystems), +Amany Gomma (co-advised, PhD, Plant Pathology), %Kahheetah Barnoskie (co-advised MS, Agronomy \& Horticulture), Kyle Linders (co-advised MS, Agronomy \& Horticulture) -\item \textbf{Thesis Committees:} +%\item \textbf{Thesis Committees:} %Abbas Atefi (PhD, Biological Systems Engineering), %Yen Ning Chai (PhD, Agronomy \& Horticulture), %Waseen Huassain (PhD, Agronomy \& Horticulture), @@ -264,16 +265,17 @@ Kyle Linders (co-advised MS, Agronomy \& Horticulture) %Rituaj Khound (PhD, Agronomy \& Horticulture), %Sergio Manuel Gabriel Peralta (PhD, Plant Pathology), %Shimin Chen (PhD, Food Science), -Zachery Shomo (PhD, Biochemistry), -Jared Haupt (PhD, Biochemistry), +%Zachery Shomo (PhD, Biochemistry), +%Jared Haupt (PhD, Biochemistry), %Sairam Behera (PhD, Computer Science), -Sarah Johnson (PhD, Agronomy \& Horticulture), +%Sarah Johnson (PhD, Agronomy \& Horticulture), %Michael Meier (PhD, Agronomy \& Horticulture), %Semra Palali (PhD, Agronomy \& Horticulture) \item \textbf{Graduated Advisees:} Daniel Carvalho (PhD, Agronomy \& Horticulture), Zhikai Liang (PhD, Agronomy \& Horticulture), Chenyong Miao (PhD, Agronomy \& Horticulture), +Nate Korth (co-advised, PhD, Food Science), Preston Hurst (MS, Agronomy \& Horticulture), Xianjun Lai (PhD, Sichuan Agriculture University), Xiuru Dai (PhD, Shandong Agriculture University), @@ -324,18 +326,21 @@ Lab members in \textbf{bold}, $^*$authors contributed equally, $^\ddagger$underg \begin{etaremune} \subsection*{Faculty Publications} -\item \textbf{Sun G}, Yu H, Wang P, Lopez-Guerrero MG, \textbf{Mural RV}, \textbf{Mizero ON}, \textbf{Grzybowski M}, Song B, van Dijk K, Schachtman DP, Zhang C, \textbf{Schnable JC}$^\S$ (2023) A role for heritable transcriptomic variation in maize adaptation to temperate environments. \textsc{bioRxiv} doi: \href{https://doi.org/10.1101/2022.01.28.478212}{10.1101/2022.01.28.478212}\\ +\item \textbf{Sun G}, Yu H, Wang P, Lopez-Guerrero MG, \textbf{Mural RV}, \textbf{Mizero ON}$^\ddagger$, \textbf{Grzybowski M}, Song B, van Dijk K, Schachtman DP, Zhang C, \textbf{Schnable JC}$^\S$ (2023) A role for heritable transcriptomic variation in maize adaptation to temperate environments. \textsc{bioRxiv} doi: \href{https://doi.org/10.1101/2022.01.28.478212}{10.1101/2022.01.28.478212} \item Gaillard M, Benes B, \textbf{Tross MC}, \textbf{Schnable JC} (2023) Multi-view triangulation without correspondences. \textsc{Computers and Electronics in Agriculture} doi: \href{https://doi.org/10.1016/j.compag.2023.107688}{10.1016/j.compag.2023.107688} -\item \textbf{Grzybowski M}$^\S$, \textbf{Mural RV}, Xu G, \textbf{Turkus, J}, Yang Jinliang, \textbf{Schnable JC} (2023) A common resequencing-based genetic marker dataset for global maize diversity. \textsc{The Plant Journal} doi: \href{https://doi.org/10.1111/tpj.16123}{10.1111/tpj.16123} +\item \textbf{Grzybowski M}$^\S$, \textbf{Mural RV}, Xu G, \textbf{Turkus, J}, Yang Jinliang, \textbf{Schnable JC} (2023) A common resequencing-based genetic marker dataset for global maize diversity. \textsc{The Plant Journal} doi: \href{https://doi.org/10.1111/tpj.16123}{10.1111/tpj.16123}\\ +\textbf{\textit{Cover Article, March 2023}} \textbf{\textit{"Research Highlight"}} doi: \href{https://doi.org/10.1111/tpj.16123}{10.1111/tpj.16123} -\item \textbf{Sun G}, Wase N, Shu S, Jenkins J, Zhou B, Chen C, Sandor L, Plott C, Yoshinga Y, Daum C, Qi P, Barry K, Lipzen A, Berry L, Gottilla T, \textbf{Foltz A}, Yu H, O'Malley R, Zhang C, Devos KM, \textbf{Sigmon B}, Yu B, Obata T, Schmutz J$^\S$, \textbf{Schnable JC}$^\S$ (2023) Genome of \textit{Paspalum vaginatum} and the role of trehalose mediated autophagy in increasing maize biomass. \textsc{Nature Communications} doi: \href{https://doi.org/10.1038/s41467-022-35507-8}{10.1038/s41467-022-35507-8} \textsc{bioRxiv} doi: \href{https://doi.org/10.1101/2021.08.18.456832}{10.1101/2021.08.18.456832}\\ +\item \textbf{Sun G}, Wase N, Shu S, Jenkins J, Zhou B, Chen C, Sandor L, Plott C, Yoshinga Y, Daum C, Qi P, Barry K, Lipzen A, Berry L, Gottilla T, \textbf{Foltz A}$^\ddagger$, Yu H, O'Malley R, Zhang C, Devos KM, \textbf{Sigmon B}, Yu B, Obata T, Schmutz J$^\S$, \textbf{Schnable JC}$^\S$ (2023) Genome of \textit{Paspalum vaginatum} and the role of trehalose mediated autophagy in increasing maize biomass. \textsc{Nature Communications} doi: \href{https://doi.org/10.1038/s41467-022-35507-8}{10.1038/s41467-022-35507-8} \textsc{bioRxiv} doi: \href{https://doi.org/10.1101/2021.08.18.456832}{10.1101/2021.08.18.456832}\\ \textbf{\textit{"Research Highlight" in Nature Plants}} doi: \href{https://doi.org/10.1038/s41477-023-01343-x}{10.1038/s41477-023-01343-x} \item \textbf{Grzybowski M}$^\S$, \textbf{Zweiner M}, \textbf{Jin H}, Wijewardane NK, Atefi A, Naldrett MJ, Alverez S, Ge Y, \textbf{Schnable JC} (2022) Variation in morpho-physiological and metabolic responses to low nitrogen stress across the sorghum association panel. \textsc{BMC Plant Biology} doi: \href{https://doi.org/10.1186/s12870-022-03823-2}{10.1186/s12870-022-03823-2} \textsc{bioRxiv} doi: \href{https://doi.org/10.1101/2022.06.08.495271}{10.1101/2022.06.08.495271} -\item Yang Q, Van Haute M, \textbf{Korth N}, Sattler S, Toy J, Rose D, \textbf{Schnable JC}, Benson A (2022) Genetic analysis of seed traits in Sorghum bicolor that affect the human gut microbiome. \textsc{Nature Communications} doi: \href{https://doi.org/10.1038/s41467-022-33419-1}{10.1038/s41467-022-33419-1} +\item Yang Q, Van Haute M, \textbf{Korth N}, Sattler S, Toy J, Rose D, \textbf{Schnable JC}, Benson A (2022) Genetic analysis of seed traits in Sorghum bicolor that affect the human gut microbiome. \textsc{Nature Communications} doi: \href{https://doi.org/10.1038/s41467-022-33419-1}{10.1038/s41467-022-33419-1}\\ +\textbf{\textit{"In Brief" in Nature Reviews Genetics}} doi: \href{https://doi.org/10.1038/s41576-022-00543-z}{10.1038/s41576-022-00543-z}\\ +\textbf{\textit{"Genome Watch" in Nature Reviews Microbiology}} doi: \href{https://doi.org/10.1038/s41579-022-00850-6}{10.1038/s41579-022-00850-6} \item Li D, Bai D, Tian Y, Li Y, Zhao C, Wang Q, Gou S, Gu Y, Luan X, Wang R, Yang J, Hawkesford MJ, \textbf{Schnable JC}, Jin X, Qiu L (2022) Time series canopy phenotyping enables the identification of genetic variants controlling dynamic phenotypes in soybean. \textsc{Journal of Integrative Plant Biology} doi: \href{https://doi.org/10.1111/jipb.13380}{10.1111/jipb.13380}