Title page for ETD etd-08202011-082956


Type of Document Master's Thesis
Author Wadlington, William Herring
URN etd-08202011-082956
Title Three genes from Solanum chacoense coding for squalene synthase
Degree Master of Science
Department Horticulture
Advisory Committee
Advisor Name Title
Collakova, Eva Committee Member
Okumoto, Sakiko Committee Member
Tokuhisa, James G. Committee Member
Veilleux, Richard E. Committee Member
Keywords
  • squalene synthases
  • Solanum chacoense
  • gene family
Date of Defense 2011-05-04
Availability unrestricted
Abstract
Squalene synthase (EC 2.5.1.2.1; SQS) is located at a branch point in the isoprenoid pathway and catalyzes the condensation of two molecules of farnesyl diphosphate to form squalene. SQS activity contributes to the formation of triterpenes and sterols, including phytosterols, brassinosteroids, cholesterol, and in potato plants, steroidal glycoalkaloids (SGAs). These compounds have diverse functions in the plant. SGAs are defense compounds that deter feeding by potato pests. The wild potato Solanum chacoense accumulates higher amounts of SGAs than cultivated potato and some of its accessions produce leptines, a rare class of SGAs that is toxic to Colorado potato beetle. Unlike most eukaryotes, higher plants have more than one gene coding for SQS. Three sqs gene homologs were isolated from S. chacoense, sqs1Sc, sqs2Sc, and sqs4Sc, that have 74 to 83% identity at the amino acid level. Some of the amino acid differences between sqs isoforms are likely to affect enzyme activity. Each of the three genes contained an intron in the 3’UTR. This feature may have a role in the nonsense-mediated decay of incomplete sqs mRNAs. A partial SQS polypeptide retaining catalytic activity but lacking the membrane anchoring domain could adversely affect a cell with the randomly distributed accumulation of squalene. The mRNA of sqs1Sc and sqs2Sc was detected in all tissues whereas sqs4Sc transcript was limited to bud tissue. The sqs2Sc transcript was less uniformly distributed in the plant than sqs1Sc and accumulated most abundantly in floral tissue. The results demonstrate that the three sqs genes have different patterns of gene expression and encode proteins with different primary structures indicating distinct roles in plant squalene metabolism.
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