Steven D. Tanksley

Last updated

Steven Tanksley
Dr steven tanksley.jpg
Tanksley in 2011
Born
Steven Dale Tanksley

(1954-04-07) April 7, 1954 (age 69)
NationalityAmerican
Alma mater Colorado State University (BA)
University of California, Davis (PhD)
Awards
Scientific career
Fields Plant Breeding
Genetics
Institutions Cornell University
College of Agriculture and Life Sciences
Thesis Inheritance, developmental expression, and polymorphism of three glycolytic enzymes in species of Lycopersicon  (1979)
Doctoral students Susan McCouch
Website plbrgen.cals.cornell.edu/people/steven-d-tanksley/ OOjs UI icon edit-ltr-progressive.svg

Steven Dale Tanksley (born April 7, 1954) is the Chief Technology Officer of Nature Source Improved Plants. Prior to founding Nature Source Improved Plants, Tanksley served as the Liberty Hyde Bailey professor of plant breeding and biometry and chair of the Genomics Initiative Task Force at Cornell University College of Agriculture and Life Sciences. He is currently[ when? ] a Professor Emeritus at Cornell University.

Contents

Education

Tanksley received a bachelor's degree in agronomy from Colorado State University in 1976 and a doctorate in genetics from the University of California, Davis in 1979.

Career and research

Tanksley joined the faculty at Cornell in 1985 as an associate professor of plant breeding, and became full professor in 1994. He led the development of the first molecular maps of tomato [1] and rice. [2] In 1993, Tanksley was the head of a Cornell research group that isolated and subsequently cloned a disease-resistance gene in tomato plants. The research is believed to be the first successful DNA map-based cloning in a major crop plant. [3]

Much of Tanksley's work focused on identifying alleles from wild relatives of crops that could be useful in improving cultivated varieties, for example fruit size and shape in tomato, [4] using the technology Marker-assisted selection (MAS). He led work developing the advanced backcross Quantitative Trait Loci (QTL) method, facilitating the introgression of new alleles into cultivated breeding lines. [5] His team also spearheaded using genetic markers in comparative mapping among Solanaceae species [6] and others. [7] [8]

Tanksley has co-authored more than 200 scientific publications[ citation needed ] and has mentored dozens of graduate students[ citation needed ] including Susan McCouch.

In 2006, Tanksley co-founded Nature Source Genetics, a company based in Ithaca, NY, conceived to work on creating new computer algorithms to improve the efficiency of using natural genetic diversity in crop improvement. In 2016, Nature Source Genetics merged with the In Vitro division of Agromod, a Mexican company specializing in plant propagation, to form Nature Source Improved Plants, LLC, [9] a US-based company dedicated to the genetic improvement, propagation, and sales of high performing plant materials. [10] The company has one division in Ithaca, NY and one in Tapachula, Mexico.

Awards and honors

Tanksley was elected a member of the National Academy of Sciences (NAS) in 1995. [11] He has received the Alexander von Humboldt Foundation Award, [12] the Martin Gibbs Medal of the American Society of Plant Biologists, [13] and the Wolf Prize in Agriculture. [14] Tanksley was also awarded the Kumho International Science Award in 2005 for his work in molecular genetics. [15] In 2016, he won the Japan Prize. [16] He was elected a Foreign Member of the Royal Society (ForMemRS) of London in 2009. [17]

Related Research Articles

Genetic linkage is the tendency of DNA sequences that are close together on a chromosome to be inherited together during the meiosis phase of sexual reproduction. Two genetic markers that are physically near to each other are unlikely to be separated onto different chromatids during chromosomal crossover, and are therefore said to be more linked than markers that are far apart. In other words, the nearer two genes are on a chromosome, the lower the chance of recombination between them, and the more likely they are to be inherited together. Markers on different chromosomes are perfectly unlinked, although the penetrance of potentially deleterious alleles may be influenced by the presence of other alleles, and these other alleles may be located on other chromosomes than that on which a particular potentially deleterious allele is located.

A quantitative trait locus (QTL) is a locus that correlates with variation of a quantitative trait in the phenotype of a population of organisms. QTLs are mapped by identifying which molecular markers correlate with an observed trait. This is often an early step in identifying the actual genes that cause the trait variation.

<i>Oryza sativa</i> Species of plant

Oryza sativa, also known as rice, is the plant species most commonly referred to in English as rice. It is the type of farmed rice whose cultivars are most common globally, and was first domesticated in the Yangtze River basin in China 13,500 to 8,200 years ago.

<span class="mw-page-title-main">Synteny</span>

In genetics, the term synteny refers to two related concepts:

<span class="mw-page-title-main">Introgression</span> Transfer of genetic material from one species to another

Introgression, also known as introgressive hybridization, in genetics is the transfer of genetic material from one species into the gene pool of another by the repeated backcrossing of an interspecific hybrid with one of its parent species. Introgression is a long-term process, even when artificial; it may take many hybrid generations before significant backcrossing occurs. This process is distinct from most forms of gene flow in that it occurs between two populations of different species, rather than two populations of the same species.

A molecular marker is a molecule, sampled from some source, that gives information about its source. For example, DNA is a molecular marker that gives information about the organism from which it was taken. For another example, some proteins can be molecular markers of Alzheimer's disease in a person from which they are taken. Molecular markers may be non-biological. Non-biological markers are often used in environmental studies.

Marker assisted selection or marker aided selection (MAS) is an indirect selection process where a trait of interest is selected based on a marker linked to a trait of interest, rather than on the trait itself. This process has been extensively researched and proposed for plant- and animal- breeding.

A doubled haploid (DH) is a genotype formed when haploid cells undergo chromosome doubling. Artificial production of doubled haploids is important in plant breeding.

Expression quantitative trait loci (eQTLs) are genomic loci that explain variation in expression levels of mRNAs.

In genetics, association mapping, also known as "linkage disequilibrium mapping", is a method of mapping quantitative trait loci (QTLs) that takes advantage of historic linkage disequilibrium to link phenotypes to genotypes, uncovering genetic associations.

Nested association mapping (NAM) is a technique designed by the labs of Edward Buckler, James Holland, and Michael McMullen for identifying and dissecting the genetic architecture of complex traits in corn. It is important to note that nested association mapping is a specific technique that cannot be performed outside of a specifically designed population such as the Maize NAM population, the details of which are described below.

In statistical genetics, inclusive composite interval mapping (ICIM) has been proposed as an approach to QTL mapping for populations derived from bi-parental crosses. QTL mapping is based on genetic linkage map and phenotypic data to attempt to locate individual genetic factors on chromosomes and to estimate their genetic effects.

Quantitative trait loci mapping or QTL mapping is the process of identifying genomic regions that potentially contain genes responsible for important economic, health or environmental characters. Mapping QTLs is an important activity that plant breeders and geneticists routinely use to associate potential causal genes with phenotypes of interest. Family-based QTL mapping is a variant of QTL mapping where multiple-families are used.

Molecular breeding is the application of molecular biology tools, often in plant breeding and animal breeding. In the broad sense, molecular breeding can be defined as the use of genetic manipulation performed at the level of DNA to improve traits of interest in plants and animals, and it may also include genetic engineering or gene manipulation, molecular marker-assisted selection, and genomic selection. More often, however, molecular breeding implies molecular marker-assisted breeding (MAB) and is defined as the application of molecular biotechnologies, specifically molecular markers, in combination with linkage maps and genomics, to alter and improve plant or animal traits on the basis of genotypic assays.

A sequence related amplified polymorphism (SRAP) is a molecular technique, developed by G. Li and C. F. Quiros in 2001, for detecting genetic variation in the open reading frames (ORFs) of genomes of plants and related organisms.

<span class="mw-page-title-main">Michael Goddard</span>

Michael Edward "Mike" Goddard is a professorial fellow in animal genetics at the University of Melbourne, Australia.

A plant genome assembly represents the complete genomic sequence of a plant species, which is assembled into chromosomes and other organelles by using DNA fragments that are obtained from different types of sequencing technology.

Susan Rutherford McCouch is an American geneticist specializing in the genetics of rice. She is the Barbara McClintock Professor of Plant Breeding and Genetics at Cornell University, and since 2018 a member of the National Academy of Sciences. In 2012, she was awarded the Chancellor's Award for Excellence in Scholarship and Creative Activities.

SoyBase is a database created by the United States Department of Agriculture. It contains genetic information about soybeans. It includes genetic maps, information about Mendelian genetics and molecular data regarding genes and sequences. It was started in 1990 and is freely available to individuals and organizations worldwide.

Amanda M. Hulse-Kemp is a computational biologist with the United States Department of Agriculture – Agricultural Research Service. She works in the Genomics and Bioinformatics Research Unit and is stationed on the North Carolina State University campus in Raleigh, North Carolina.

References

  1. Tanksley SD, Ganal MW, Prince JP, de Vicente MC, Bonierbale MW, Broun P, Fulton TM, Giovannoni JJ, Grandillo S, Martin GB, Messeguer R, Miller JC, Paterson AH, Pineda O, Roder MS, Wing RA, Wu W, and Young ND (1992). "High Density Molecular Linkage Maps of the Tomato and Potato Genomes". Genetics. 132 (4): 1141–1160. doi:10.1093/genetics/132.4.1141. PMC   1205235 . PMID   1360934.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  2. Tanksley, S., M. Causse, T. Fulton, N. Ahn, Z. Wang, K. Wu, J. Xiao, P. Ronald, Z. Yu, G. Second, and S. McCouch (1992). "A high density molecular map of the rice genome". Rice Genetics Newsletter. 9.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  3. Fisher, Lawrence M. (1993). "Tomato Gene That Resists Disease Is Cloned". The New York Times . p. A25.
  4. Tanksley, S. D. (2004). "The Genetic, Developmental, and Molecular Bases of Fruit Size and Shape Variation in Tomato". The Plant Cell Online. 16 (suppl_1): S181–S189. doi:10.1105/tpc.018119. JSTOR   3872310. PMC   2643388 . PMID   15131251.
  5. Tanksley, S.D. and J.C. Nelson (1996). "Advanced backcross QTL analysis: a method for the simultaneous discovery and transfer of valuable QTLs from unadapted germplasm into elite breeding lines". Theor. Appl. Genet. 92 (2): 191–203. doi:10.1007/BF00223376. PMID   24166168. S2CID   24001863.
  6. Doganlar, S., A. Frary, M-C. Daunay, R. N. Lester, and S. D. Tanksley (2002). "A comparative genetic linkage map of eggplant (Solanum melongena) and its implications for genome evolution in the solanaceae". Genetics. 161 (4): 1697–711. doi:10.1093/genetics/161.4.1697. PMC   1462225 . PMID   12196412.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  7. Fulton, T. M., R. van der Hoeven, N.T. Eannetta, S.D. Tanksley (2002). "Identification, Analysis and Utilization of Conserved Ortholog Set (COS) Markers for Comparative Genomics in Higher Plants". The Plant Cell Online. 14 (7): 1457–1467. doi:10.1105/tpc.010479. PMC   150699 . PMID   12119367.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  8. Ahn, S. and S.D. Tanksley (1993). "Comparative linkage maps of rice and maize genomes". Proc. Natl. Acad. Sci. USA. 90 (17): 7980–7984. Bibcode:1993PNAS...90.7980A. doi: 10.1073/pnas.90.17.7980 . PMC   47271 . PMID   8103599.
  9. "Nature Source Improved Plants | Home". nsiplants.com.
  10. "Nature Source Genetics LLC and Agromod's In Vitro Division have merged to form Nature Source Improved Plants LLC" (PDF).
  11. "Steven D. Tanksley". National Academy of Sciences. Retrieved October 7, 2019.
  12. Friedlander, Blaine (October 24, 1998). "Cornell's Tanksley wins prestigious 1998 Humboldt Award for his 'significant contribution' to agriculture". Cornell University. Retrieved October 7, 2019.
  13. "Steven Tanksley – Lecture Series Biography" . Retrieved October 7, 2019.
  14. Lang, Susan S. (January 22, 2004). "Cornell plant breeder Steven Tanksley is a co-recipient of the international Wolf Foundation Prize in Agriculture". Cornell Chronicle. Retrieved October 7, 2019.
  15. "Cornell geneticist to be honored by foundation". Korea JoongAng Daily . May 29, 2005. Retrieved October 7, 2019.
  16. Steven D. Tanksley, Ph.D. japanprize.jp. Retrieved October 7, 2019.
  17. "Steven Tanksley | Royal Society". royalsociety.org.
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