Table_12_Transcriptome and Proteomics Analysis of Wheat Seedling Roots Reveals That Increasing NH4+/NO3– Ratio Induced Root Lignification and Reduced Nitrogen Utilization.xls by Dongqing Yang (675454)

“…However, the mechanisms underlying the response of wheat seedling roots to changes in NH₄⁺/NO₃^– ratio remain unclear. In this study, we investigated wheat growth, transcriptome, and proteome profiles of roots in response to increasing NH₄⁺/NO₃^– ratios (N_a: 100/0; N_r1: 75/25, N_r2: 50/50, N_r3: 25/75, and N_n: 0/100). …”

Table_6_Transcriptome and Proteomics Analysis of Wheat Seedling Roots Reveals That Increasing NH4+/NO3– Ratio Induced Root Lignification and Reduced Nitrogen Utilization.xlsx by Dongqing Yang (675454)

“…However, the mechanisms underlying the response of wheat seedling roots to changes in NH₄⁺/NO₃^– ratio remain unclear. In this study, we investigated wheat growth, transcriptome, and proteome profiles of roots in response to increasing NH₄⁺/NO₃^– ratios (N_a: 100/0; N_r1: 75/25, N_r2: 50/50, N_r3: 25/75, and N_n: 0/100). …”

Table_3_Transcriptome and Proteomics Analysis of Wheat Seedling Roots Reveals That Increasing NH4+/NO3– Ratio Induced Root Lignification and Reduced Nitrogen Utilization.xlsx by Dongqing Yang (675454)

“…However, the mechanisms underlying the response of wheat seedling roots to changes in NH₄⁺/NO₃^– ratio remain unclear. In this study, we investigated wheat growth, transcriptome, and proteome profiles of roots in response to increasing NH₄⁺/NO₃^– ratios (N_a: 100/0; N_r1: 75/25, N_r2: 50/50, N_r3: 25/75, and N_n: 0/100). …”

Table_5_Transcriptome and Proteomics Analysis of Wheat Seedling Roots Reveals That Increasing NH4+/NO3– Ratio Induced Root Lignification and Reduced Nitrogen Utilization.xlsx by Dongqing Yang (675454)

“…However, the mechanisms underlying the response of wheat seedling roots to changes in NH₄⁺/NO₃^– ratio remain unclear. In this study, we investigated wheat growth, transcriptome, and proteome profiles of roots in response to increasing NH₄⁺/NO₃^– ratios (N_a: 100/0; N_r1: 75/25, N_r2: 50/50, N_r3: 25/75, and N_n: 0/100). …”

Table_2_Transcriptome and Proteomics Analysis of Wheat Seedling Roots Reveals That Increasing NH4+/NO3– Ratio Induced Root Lignification and Reduced Nitrogen Utilization.xlsx by Dongqing Yang (675454)

“…However, the mechanisms underlying the response of wheat seedling roots to changes in NH₄⁺/NO₃^– ratio remain unclear. In this study, we investigated wheat growth, transcriptome, and proteome profiles of roots in response to increasing NH₄⁺/NO₃^– ratios (N_a: 100/0; N_r1: 75/25, N_r2: 50/50, N_r3: 25/75, and N_n: 0/100). …”

Table_9_Transcriptome and Proteomics Analysis of Wheat Seedling Roots Reveals That Increasing NH4+/NO3– Ratio Induced Root Lignification and Reduced Nitrogen Utilization.xlsx by Dongqing Yang (675454)

“…However, the mechanisms underlying the response of wheat seedling roots to changes in NH₄⁺/NO₃^– ratio remain unclear. In this study, we investigated wheat growth, transcriptome, and proteome profiles of roots in response to increasing NH₄⁺/NO₃^– ratios (N_a: 100/0; N_r1: 75/25, N_r2: 50/50, N_r3: 25/75, and N_n: 0/100). …”

Table_11_Transcriptome and Proteomics Analysis of Wheat Seedling Roots Reveals That Increasing NH4+/NO3– Ratio Induced Root Lignification and Reduced Nitrogen Utilization.xlsx by Dongqing Yang (675454)

“…However, the mechanisms underlying the response of wheat seedling roots to changes in NH₄⁺/NO₃^– ratio remain unclear. In this study, we investigated wheat growth, transcriptome, and proteome profiles of roots in response to increasing NH₄⁺/NO₃^– ratios (N_a: 100/0; N_r1: 75/25, N_r2: 50/50, N_r3: 25/75, and N_n: 0/100). …”

Table_7_Transcriptome and Proteomics Analysis of Wheat Seedling Roots Reveals That Increasing NH4+/NO3– Ratio Induced Root Lignification and Reduced Nitrogen Utilization.xls by Dongqing Yang (675454)

“…However, the mechanisms underlying the response of wheat seedling roots to changes in NH₄⁺/NO₃^– ratio remain unclear. In this study, we investigated wheat growth, transcriptome, and proteome profiles of roots in response to increasing NH₄⁺/NO₃^– ratios (N_a: 100/0; N_r1: 75/25, N_r2: 50/50, N_r3: 25/75, and N_n: 0/100). …”

Table_4_Transcriptome and Proteomics Analysis of Wheat Seedling Roots Reveals That Increasing NH4+/NO3– Ratio Induced Root Lignification and Reduced Nitrogen Utilization.xlsx by Dongqing Yang (675454)

“…However, the mechanisms underlying the response of wheat seedling roots to changes in NH₄⁺/NO₃^– ratio remain unclear. In this study, we investigated wheat growth, transcriptome, and proteome profiles of roots in response to increasing NH₄⁺/NO₃^– ratios (N_a: 100/0; N_r1: 75/25, N_r2: 50/50, N_r3: 25/75, and N_n: 0/100). …”

Table_1_Transcriptome and Proteomics Analysis of Wheat Seedling Roots Reveals That Increasing NH4+/NO3– Ratio Induced Root Lignification and Reduced Nitrogen Utilization.docx by Dongqing Yang (675454)

“…However, the mechanisms underlying the response of wheat seedling roots to changes in NH₄⁺/NO₃^– ratio remain unclear. In this study, we investigated wheat growth, transcriptome, and proteome profiles of roots in response to increasing NH₄⁺/NO₃^– ratios (N_a: 100/0; N_r1: 75/25, N_r2: 50/50, N_r3: 25/75, and N_n: 0/100). …”

Table_10_Transcriptome and Proteomics Analysis of Wheat Seedling Roots Reveals That Increasing NH4+/NO3– Ratio Induced Root Lignification and Reduced Nitrogen Utilization.xls by Dongqing Yang (675454)

“…However, the mechanisms underlying the response of wheat seedling roots to changes in NH₄⁺/NO₃^– ratio remain unclear. In this study, we investigated wheat growth, transcriptome, and proteome profiles of roots in response to increasing NH₄⁺/NO₃^– ratios (N_a: 100/0; N_r1: 75/25, N_r2: 50/50, N_r3: 25/75, and N_n: 0/100). …”

Table_8_Transcriptome and Proteomics Analysis of Wheat Seedling Roots Reveals That Increasing NH4+/NO3– Ratio Induced Root Lignification and Reduced Nitrogen Utilization.xlsx by Dongqing Yang (675454)

“…However, the mechanisms underlying the response of wheat seedling roots to changes in NH₄⁺/NO₃^– ratio remain unclear. In this study, we investigated wheat growth, transcriptome, and proteome profiles of roots in response to increasing NH₄⁺/NO₃^– ratios (N_a: 100/0; N_r1: 75/25, N_r2: 50/50, N_r3: 25/75, and N_n: 0/100). …”

data-raw.xls by Jinlei Zhu (19952964)

“…Sap flow velocity and daily sap flow accumulation increased at 50% stumping but decreased at 75% and 100% stumping. …”

Table1_The long-term effect of biochar application to Vitis vinifera L. reduces fibrous and pioneer root production and increases their turnover rate in the upper soil layers.docx by Peter Beatrice (12859252)

“…Our findings demonstrate that in the long term, biochar application significantly increased soil pH, nutrient availability, and water-holding capacity causing a decrease in the production of fibrous and pioneer roots which is reflected in a reduction of the root web characterized though by a higher turnover rate. …”

Table1_The long-term effect of biochar application to Vitis vinifera L. reduces fibrous and pioneer root production and increases their turnover rate in the upper soil layers.docx by Peter Beatrice (12859252)

“…Our findings demonstrate that in the long term, biochar application significantly increased soil pH, nutrient availability, and water-holding capacity causing a decrease in the production of fibrous and pioneer roots which is reflected in a reduction of the root web characterized though by a higher turnover rate. …”

Deterministic sensitivity analysis. by Katharina Wahedi (7136459)

“…Bars on the right indicate an increase of ICER, bars on the left show a decrease of ICER. Changes resulting from increasing the parameters are represented by green bars while those resulting from a decrease of parameters are shown in red.…”

Static difference-in-differences estimates. by Wei Yang Tham (15360970)

“…However, there can be delays during the renewal process. Over a period beginning three months before and ending one year after these delays, I find that interrupted labs reduce overall spending by 50% but over 90% in the month with the largest decrease. …”

Effects of HAI-1 and HAI-2 overexpression and downregulation on cell proliferation in NPCs. by Raili Koivuniemi (280720)

“…(<b>C</b>) Immunoblot of the cell cycle regulator, CyclinD1. ß-actin was used as a control. Quantification below shows a decrease in CyclinD1 after HAI-1 and HAI-2 expression. …”

Loss of specific subpopulations of interneurons seen within various regions of the hippocampus. by Jeremy P. Morgan (479017)

Cell counts in the GCL. by Antonio Piras (347544)

“…Retinal thickness is markedly reduced, compared to the control (A), after injury (B), mainly due to decrease in IPL thickness and number of GCL-neurons; these effects are partially prevented by 3-MA treatment (C). …”