Near Infrared Spectroscopic Evaluation of Starch Properties of Diverse Sorghum Populations

Kamaranga H S Peiris,Tesfaye Tesso,Brent Bean,S V Krishna Jagadish,Mayra Perez-Fajardo,Xiaorong Wu,Melinda K Yerka,Ramasamy Perumal,Chad Hayes,William L Rooney,Troy Ostmeyer,Scott R Bean,Mitchell A Kent,Fadi M Aramouni

doi:10.3390/pr9111942

Abstract

Starch, mainly composed of amylose and amylopectin, is the major nutrient in grain sorghum. Amylose and amylopectin composition affects the starch properties of sorghum flour which in turn determine the suitability of sorghum grains for various end uses. Partial least squares regression models on near infrared (NIR) spectra were developed to estimate starch and amylose contents in intact grain sorghum samples. Sorghum starch calibration model with a coefficient of determination (R2) = 0.87, root mean square error of cross validation (RMSECV) = 1.57% and slope = 0.89 predicted the starch content of validation set with R2 = 0.76, root mean square error of prediction (RMSEP) = 2.13%, slope = 0.93 and bias = 0.20%. Amylose calibration model with R2 = 0.84, RMSECV = 2.96% and slope = 0.86 predicted the amylose content in validation samples with R2 = 0.76, RMSEP = 2.60%, slope = 0.98 and bias = −0.44%. Final starch and amylose cross validated calibration models were constructed combining respective calibration and validation sets and used to predict starch and amylose contents in 1337 grain samples from two diverse sorghum populations. Protein and moisture contents of the samples were determined using previously tested NIR spectroscopy models. The distribution of starch and protein contents in the samples of low amylose (<5%) and normal amylose (>15%) and the overall relationship between starch and protein contents of the sorghum populations were investigated. Percent starch and protein were negatively correlated, low amylose lines tended to have lower starch and higher protein contents than lines with high amylose. The results showed that NIR spectroscopy of whole grain can be used as a high throughput pre-screening method to identify sorghum germplasm with specific starch quality traits to develop hybrids for various end uses.

Highlights

Sorghum (Sorghum bicolor (L.) Moench) ranks fifth in global cereal grain production after maize (Zea mays (L.)), wheat (Triticum aestivum (L.)), rice (Oryza sativa (L.)) and barley (Hordeum vulgare (L.)) with 57.9 million megagrams (Mg) of grain sorghum harvested from 40.1 million ha in 2019 with an average yield of 1.44 Mg/ha
Samples for the amylose calibrations were selected from four different populations distinct from SP1–5 consisting of hybrids, inbreds, and segregating early F2 generation plant selections grown in Kansas and Texas
Raw spectral data of the starch and amylose datasets were subjected to principal component analysis to investigate similarity/diversity of spectra among sample populations

Summary

Introduction

Sorghum (Sorghum bicolor (L.) Moench) ranks fifth in global cereal grain production after maize (Zea mays (L.)), wheat (Triticum aestivum (L.)), rice (Oryza sativa (L.)) and barley (Hordeum vulgare (L.)) with 57.9 million megagrams (Mg) of grain sorghum harvested from 40.1 million ha in 2019 with an average yield of 1.44 Mg/ha. Mg of grain sorghum harvested from 1.9 million ha with an average yield of 4.6 Mg/ha in. Grain sorghum is used as food, feed, fodder and as a feedstock for bioethanol production [1,2,3,4,5]. Starch comprises two types of macromolecules, the relatively small (up to 106 Da) and linear amylose with few long branches and the large (107 –109 Da) and highly-branched amylopectin with many short branches. These macromolecules form starch granules with alternative crystalline and amorphous layers [11,12]. Starch content and starch properties, especially the amount of amylose content in sorghum starch, influence the suitability of sorghum cultivars for specific end uses [13,14,15]

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