绿帽换妻

• Help prepare students for the science/technology workforce of tomorrow
• Empower students as collaborators and potential co-authors of research
• Focus on topics that are somehow of social significance, whatever the field of science or technology
• Apply research to problems that span multiple disciplines, thus mirroring the current integration of fields of science/technology and their methodologies
• Demonstrate your willingness to share the (modest) funding with other applicants by asking for the absolute minimum needed
• Involve collaborators from other departments, and universities, or companies, research laboratories or agencies
• Demonstrate that they are creatively drawing support from other resources as well
• For example, Cal State East Bay’s Center for Student Research Scholar’s Program might also be used to provide support for student collaborators

• A scientist with lots of outside support should not apply, to add a little more money to the pot
• Someone contemplating development of a whole new research direction for which they have not developed and tested their methodology
• Someone wishing to pay students who would only help out with the investigator’s own obscure or isolated research program
• A researcher wanting to receive a stipend for themselves.

Metabolomic Analysis of Salinity Stressed Pistachios
Principal Investigators:
Department of Chemistry and Biochemistry, CSU East Bay
Abstract: With climate change non-saline water will become a scarce but necessary resource to maintain agriculture and therefore our food supply. Some plants, including pistachio trees, are able to withstand irrigation with saline water as in brackish but not ocean water. Shifting agricultural practices to more salt-tolerant plants could preserve freshwater resources. This project aims to elucidate the biochemical response of pistachio trees to salinity stress. My collaboration partners are Dr. Gary Baňuelos from the US Department of Agriculture – Agricultural Research Service (USDA-ARS), faculty and students at Fresno State, and five undergraduate research students at 绿帽换妻. This collaboration is already well established. With the help of this grant, I seek to add a new research component in the form of a paid metabolomic pilot study. This pilot study will focus on phenolic compounds. In our previous work, we observed an increase in phenolic compounds in leaves of pistachio trees subjected to saline irrigation.Phenolic compounds serve as antioxidants and protect the plant tissue from radical oxygen species (ROS). An increase in ROS is a known consequence of salt-induced plant stress. With the help of the services from the Metabolomics Core Facility at UC Riverside we can find out which of the many plant phenolic compounds change in concentration as a response to salt stress. This pilot study will provide an excellent opportunity to train my research students in metabolomics (e.g.; how to obtain and evaluate data encompassing the many individual metabolites of an organism). We will use the data of the pilot study to design new experiments. We will quantify specific phenolic compounds selected from the metabolomic study and inspect the activity of enzymes involved in the transformation of these compounds. As my collaboration partners and I are moving forward with our study on the salt-tolerance of pistachio trees, we will apply for more funding. If this pilot study turns out to be successful, we will include metabolomic investigations for phenolics and other types of metabolites (e.g.; sugars, amino acids, lipids) in our next grant applications.

Progress Update:

This collaborative research award enabled me and my research team to conduct a metabolomic pilot study with pistachio leaf samples. The pistachio leaf samples stem from a salinity tolerance study  conducted at the Agricultural Research Service - US Department of Agriculture (ARS-USDA) in Parlier, CA. My main collaborator, Dr. Gary Baňuelos, and his team planted pistachio trees into a research field site  and irrigated these trees with water at different salinity levels. The goal of this study is to find a  threshold for saline irrigation, so that pistachio growers can use low quality water (for example brackish  water) for irrigation without damaging their pistachio orchards. Dr. Baňuelos’ team is sending pistachio  leaf and nut samples to my research group at CSU East Bay for biochemical analysis. We aim to find  biomarkers which are molecules that change in their concentration levels in response to salinity stress.  A better molecular understanding of the plant’s stress response will enable us to better define the  salinity threshold. Our preliminary results indicated that phenolic compounds might serve as  biomarkers for salinity stress. To obtain more detailed information on individual phenolic compounds  we decided to use the services of a metabolomic facility. Metabolomic facilities have instrumentation  (liquid chromatography paired with mass spectrometry) and the expertise to survey large classes of  smaller molecules, for example amino acids, lipids, sugars, and phenolic compounds, that make up the  metabolism of an organism.  

I obtained the collaborative research award in the middle of the Fall semester 2022. In Fall 2022 my  undergraduate research team consisted of four students (Ryan Luu (CSR scholar), Michael Rivera,  Esiason Rodriguez, and Quierra Shugart). By Spring 2023, I was able to recruit three additional students  (Feliza Dao, Sabbu Shrestha, and Manmeet Kaur). In addition to sample preparation, my students  learned about metabolomics and performed additional experiments to determine total antioxidant  capacity and total concentration of phenolic compounds, photopigments, and soluble sugars.  

The metabolomic study was carried out at the Metabolomic Facility of UC Riverside in April 2022. Dr.  Amancio de Souza was my main point of contact. We sent 24 lyophilized pistachio leaf samples to the  metabolomic facility. Lyophilization is used to preserve biological samples via a freeze-drying procedure.  This sample treatment was recommended by Dr. Souza. An apparatus with a vacuum pump and cooling  compartment was available in the research laboratory of my colleague Dr. Michael Groziak (Chemistry  and Biochemistry Department, 绿帽换妻). The metabolomic analysis conducted at UC Riverside resulted in  the detection of 20 different phenolic compounds. Six of these compounds showed a weak dependency  on salinity treatment. These compounds were myricetin 3-galactoside, myricetin 3-rutinoside,  pinocembrin, naringenin, naringenin chalcone, and catechin.  

My research group and I are currently conducting our own HPLC-based identification and quantification  of phenolic compounds. HPLC stands for high-performance liquid chromatography. Since we do not  have the same instrumentation as a metabolomics facility we can only detect phenolic compounds in  our samples for which we have standards. A standard is a purchased pure compound that the  experimenter is trying to detect and to quantify in the sample of interest. I used the remaining money  from this award and funding provided by the Chemistry Department to purchase individual phenolic  compounds. We leveraged the results of the metabolomic pilot study and consulted the scientific 

literature to select our HPLC standards. This Fall semester (Fall 2022) my research team currently  consists of four students (Takudzwa Chirenje (CSR scholar), Manmeet Kaur, Rebecca Chavez, Viral  Chhaganbhai (graduate student)). We were able to corroborate the presence of catechin in the pistachio  leaf samples. We discovered a significant catechin concentration increase in young pistachio leaves  (leaves collected from the tip of a branch) of PG1 rootstocks irrigated with saline water. Older leaves of  the same PG1 rootstock that were collected closer to the stem did not show any significant change of  catechin concentration as a function of saline irrigation. This part of the research project is still ongoing.  We are currently screening approximately 30 different phenolic compounds. In addition to the leaf  samples that were sent to the metabolomic facility we are also investigating pistachio nut extracts and  we will soon receive a new set of leaf samples from Dr. Baňuelos’ team.  

I am happy to report that our HPLC-based work on phenolic compounds led to a new collaboration with  my colleague Dr. Stephanie Zaleski (Chemistry and Biochemistry Department, 绿帽换妻). Her group is  using surface enhanced Raman spectroscopy (abbreviated SERS) to detect and quantify phenolic  compounds. We are now sharing our reagents and results with each other. We already had one joint  research group meeting and will host more so that our students can learn from each other. Dr. Zaleski’s  group will apply the SERS technique to our pistachio leaf extracts. My research group already  investigated the same extracts with HPLC. We will compare and contrast the advantages and limitations  of both techniques with each other. 

Read the article:

Investigator: Michael P. Groziak, Chemistry and Biochemistry
Project Title: Synthesis and Antibacterial Assay of New Boron Heterocycles
Collaborator: H. Howard Xu, Department of Biological Sciences, CSU Los Angeles

The proposed work is a drug discovery effort that seeks to continue a fruitful collaboration between a synthetic organic chemist and a bacteria-specializing biologist, with compounds prepared at 绿帽换妻 being sent down to CSULA for testing. Joint publications featuring student co-authors are the primary to be expected from this project. Our collaborative work began in 2010 and was supported by a Sieber Interdisciplinary Research Award. The Groziak and Xu Groups have examined more than 4 dozen compounds, found 6 new compounds with good antibacterial activity, and published 7 papers describing various aspects of their joint efforts (list at end). The first Sieber award, some Faculty Support Grants, and a 2018 Collaborative Research Award that enabled these accomplishments. With continuing College of Science Collaborative Research Award funding, targets will be synthesized, purified, characterized, and tested for antibacterial properties. These are analogs of a known antibacterial 4-toluenesulfonylated boron heterocycle (first compound shown below). A comparison of some of our past targets to this lead reveals a close structural resemblance. Our central hypothesis in the proposed work is that an acyl substituent can serve as a suitable replacement for the sulfonyl one, maintaining or even enhancing the enzyme inhibition known to be the mechanism of action of the known bactericidal boron heterocycle benchmark compound.The goal of this program is to help develop new anti-TB drugs which are becoming sorely needed due to the rise of multidrug-resistant strains of TB.