Research Project: Development of High-Yielding, Stress Tolerant Sugarcane Cultivars Using Agronomic, Genetic, and Molecular Approaches

Location: Sugarcane Field Station

2018 Annual Report

Objectives
1. Develop sugarcane breeding populations with high quality seed for use in Florida and Louisiana, and select and advance elite clones to produce and release improved sugarcane cultivars for sustainable production in Florida. 2. Characterize abiotic and biotic stress tolerance of sugarcane breeding populations to determine agronomic, physiological, and genetic relationships, and use the information in breeding programs to improve efficiency of selection methodologies. 2.A. Develop physiological and agronomic methodologies to screen yield components of sugarcane clones for tolerance to flowering characteristics. 2.B. Compare and determine methodologies that improve selection efficiency and maximize genetic gains in the Canal Point sugarcane breeding programs. 2.C. Develop and compare physiological testing and genetic x environmental interactions for sugarcane and its relatives, to determine abiotic tolerance and yield potentials that can be used for both sugarcane and biomass yield advancement. 3. Elucidate the molecular and genetic bases of disease resistance, low temperature stress, high sucrose content, and high biomass yield, develop molecular markers, and use molecular markers to screen germplasm and progenies for stress tolerance, yield, and quality. 3.A. Develop and test genomic prediction models for clonal and parental selection for disease resistance, biomass yield, and sucrose content. 3.B. Identify and screen sugarcane and its relative germplasm for freeze damage and cold tolerance. Utilize genotypic sequencing and phenotypic screening to ascertain putative associative markers linking abiotic tolerance and yield response with specific genetic loci. 3.C. Develop molecular markers for sugarcane disease resistance and high sucrose concentration. 3.D. Development and utilization of 100K single nucleotide polymorphism (SNP) array in Saccharum Spp.

Approach
The primary goal of this project is to improve yields and profits of Florida sugarcane growers by developing more productive and profitable cultivars with improved resistance and tolerance to biotic and abiotic stresses. Most research in genetics, agronomy, crop physiology, and molecular biology focuses on improving the breeding and selection of cultivars to yield more on muck and sand soils and have tolerance or durable resistance to diseases and abiotic stresses. This process will be enhanced through improved knowledge of classic and molecular genetics, identification of important traits for selection, and selection methodologies. A portion of the research aims to improve yields through modified agronomic practices. Specific efforts may focus on developing improved cultivars with disease resistance and high sucrose concentration using different approaches, especially our new sand-soil program and this may include the pursuit of links between traditional efforts to breed for increased sucrose yields and newer programs that use sugarcane and related species for cellulosic ethanol and enhanced evaluations of the genotypes. The scientists at Canal Point are expected to interact with each other and with colleagues at the University of Florida in Gainesville and its Everglades Research and Education Center in Belle Glade, and with other public and private industry scientists in Florida and Louisiana, Texas, and other areas. Over the next 5 years, we will focus on our specific objectives.

Progress Report
This new project replaces project 6030-21000-005-00D. Development of molecular markers for sugarcane orange rust resistance. Sugarcane orange rust appeared in Western hemisphere in 2007 and negatively impacted the Florida sugarcane industry as well as the Canal Point (CP) cultivar development programs. ARS scientists at Canal Point, Florida, and in University of Florida worked closely from molecular approach to develop molecular markers for improving the rust resistance efficiency. The phenotypic disease data obtained from the segregating population have been used for marker development. Quantitative trait loci associated with orange rust resistance has been identified. Diagnostic markers have been developed for orange rust resistance and will be further tested for potential use in the CP sugarcane cultivar development programs.

Accomplishments
1. Sugarcane growers in Florida are facing the challenge of sugarcane orange rust and brown rust diseases. The rusts recently cause considerable yield losses and an increase in input costs of fungicide applications. Therefore, development of new cultivars with disease resistance, high yields, and high profits using different approaches, such as genetics, genomics, agronomy, physiology, and molecular biology, is our priority of the Canal Point (CP) sugarcane breeding and cultivar development programs. ARS researchers at Canal Point, Florida, collaborated with the University of Florida and Florida Sugar Cane League, and released six new high-yielding sugarcane cultivars (CP 10-1620, CP 10-1716, CP 10-2195, CP 11-1314, CP 11-1956, and CP 11-2248) in June 2018 for growers to use in Florida. These new released cultivars are resistant/tolerant to major diseases. Of these six new cultivars, the first three are for Florida sand soils and the last three are for Florida muck soils. The new cultivars will mitigate negative effects of brown and orange rusts and other stresses on sugar yield and profits in Florida.

Review Publications
McCord, P.H., Comstock, J.C., Zhao, D., Gordon, V.S., Sood, S.G., McCorkle, K.M., Davidson, R.W., Baltazar, M., Singh, M., Sandhu, H.S. 2018. Registration of ‘CP 07-2320’ Sugarcane. Journal of Plant Registrations. 12:52-59. doi:10.3198/jpr2016.09.0047crc.
Islam, M.S., Yang, X., Sood, S.G., Comstock, J.C., Wang, J. 2018. Molecular characterization of genetic basis of Sugarcane Yellow Leaf Virus (SCYLV) resistance in Saccharum spp. hybrid. Plant Breeding. 137(4):598-604. doi:org/10.1111/pbr.12614.
Yang, X., Sood, S.G., Glynn, N., Islam, M.S., Comstock, J.C., Wang, J. 2017. Constructing high-density genetic maps for polypoid sugarcane (Saccharum spp.) and identifying quantitative trait loci controlling brown rust resistance. Molecular Breeding. 37:116. doi:10.1007/s11032-017-0716-7.
Rott, P., Kaye, C., Naranjo, M., Shine, J., Sood, S.G., Comstock, J.C., Raid, R. 2018. Controlling sugarcane diseases in Florida: a challenge in constant evolution. International Sugar Journal. 2:274-279.
Yang, X., Islam, M.S., Sood, S.G., Maya, S., Hanson, E.A., Comstock, J.C., Wang, J. 2018. Identifying quantitative trait loci (QTLs) and developing diagnostic markers linked to oragne rust resistance in sugarcane (Saccharum spp.). Frontiers in Plant Science. doi:10.1111/pbr.12614.
Sandhu, H., McCord, P.H., Zhao, D., Comstock, J.C., Singh, M.P., Davidson, W.R., Gordon, V.S., Sood, S.G., Baltazar, M., McCorkle, K.M. 2018. Registration of ‘CP 09-1822’ Sugarcane. Journal of Plant Registrations. 12:333-339. https://doi.org/10.3198/jpr2017.11.0078crc.