NOTICE: You are viewing a page of the openwetware wiki. Our "dewikify" feature makes a wiki page appear as a normal web page. On September 22nd 2017, this feature will GO AWAY and this URL will redirect to the source URL on our wiki. We're sorry for the inconvenience.


Room 2115
Section of Plant Biology
1002 Life Sciences, One Shields Ave.
University of California Davis
Davis, CA 95616


Home      Research      Publications      Protocols      Resources      Announcements      Lab Safety     

Jose M Jimenez-Gomez, PhD.


The information contained in this website may be outdated.
Please use my this website instead: Jimenez Gomez Lab.

Starting in October 2010, I am a Junior Group Leader in the Department of Plant Breeding and Genetics at the Max Planck Institute for Plant Breeding in Cologne. I worked as a Postdoctoral fellow in Julin Maloof's lab in the Section of Plant Biology at the University of California Davis.

In 2005, I completed my PhD. in JM Martinez-Zapater's lab at the CNB (National Center for Biotechnology) in Madrid, Spain, where I performed a quantitative genetic analysis of flowering time in tomato [1].

My main interests are based on the application of modern genetic and bioinformatic techniques to the study of plant natural variation, evolution and domestication. To do this I survey different plant species and populations presenting variation in interesting characteristics, and analyze the responsible molecular mechanism. Here is an small description of some of my recent work in the Maloof lab:

QTL and Network analysis of the shade avoidance response in Arabidopsis

It is well known that plants from different light environments exhibit different degrees of responsiveness to similar light stimulus. For example, plants accommodated to sunny environments detect foliar shade from neighboring vegetation and respond increasing their petioles/stems and reducing the time to reproduction, a phenomenon called the "shade avoidance response". On the other hand, plants adapted to live under dense canopies are less sensitive to the shade and have a reduced shade avoidance response. To identify the molecular mechanisms underlying this differences we are performing QTL analysis using a previously developed, well characterized Recombinant Inbred Line set descent from two different natural populations of Arabidopsis thaliana: Bayreuth, originary from the German low altitude fallow lands, and Shahdara, from the high mountains of Tadjikistan [2].
We grew replicated individual RILs in environments simulating shade and sun conditions and characterized them on a number of traits associated with the shade avoidance response syndrome. For the QTL analysis we calculated a shade avoidance response index fitting fixed effect models to the phenotipic data, and used an available genetic map for the population that includes more than 500 Single Feature Polymorphism (SFP) markers [3].

LOD score graph for several of the traits measured

We focused in a chromosomal region containing close to 400 genes to fine map and identify the gene responsible for the differences found in the response to shade in the Bay-0 x Sha population. To do this we employed traditional genetic approaches as well as genomic and network analysis. This network analysis is based on coexpression of the candidate genes with other genes across microarray experiments [4], colocalization with expression QTLs [5], functional categorization [6] and presence of polymorphisms between the parental lines [7]. The use of this bioinformatic approach allowed us to identify ELF3 as the candidate gene for the shade avoidance QTL, which was then confirmed by traditional fine mapping and cloning.

Fragment of a gene network

In the publication of this work, ELF3 alleles of Bay-0 and Sha are shown to differentially affect the shade avoidance response in flowering time and circadian rhtyhms [8]

Expresion profiling and Single Nuncleotide Polymorphism discovery in cultivated tomato and its wild relatives

Tomato is a specially interesting species because of its natural history, phenotypic diversity among its wild relatives and economic importance. To study the genomic variation among the wild tomato species, we first mined the numerous tomato EST sequences available in the databases in search of polymorphisms. In this dataset, we estimated divergence rates among genes from selected species, and obtained a new set of molecular markers useful in natural variation studies. We performed functional and evolutionary pre-genomic analyses, which gave us an idea of which gene families evolve more rapidly/slowly and have been important during tomato domestication. The results from this work were published [9] and are available to the community here. Now, we are using RNAseq to sequence the transcriptome of four tomato species grown in sun and shade: S. lycopersicum var M82, S. pennellii, S. pimpinellifollium and S. habrochaites. We developed bioinformatic pipelines to analyze the more than 400 million reads obtained fronm different tissues, species and conditions. The pipeline include scripts that filter and map the reads, detect polymorphisms, calculte their effect on the proteins, perform evolutionary analyses and calculate genome-wide expression levels. Using this methods we identified more than 500.000 polymorphisms in these four speceies and calculated expression differences between species, tissues and environmental conditions.

Molecular evolution of PHYTOCHROME B

PHYTOCHROME B (PHYB) is the main plant photoreceptor involved in the shade avoidance response. This gene has been reported to be under selective pressure, suggesting that plants with different shade avoidance responses may have different functional alleles of PHYB. Under these presumptions we are sequencing and cloning PHYB genes from a number of species with diverse shade avoidance behaviors. We will soon test if the variation in light responses between these plants are due to particular amino-acid changes in this photoreceptor.

amino-acid changes in a fragment of the PHYB gene in 8 species, red and black bars indicate non-conserved/conserved amino-acid changes respectively


Error fetching PMID 17502904:
Error fetching PMID 12582628:
Error fetching PMID 16702412:
Error fetching PMID 17179097:
Error fetching PMID 17641193:
Error fetching PMID 10802651:
Error fetching PMID 19575805:
Error fetching PMID 20838594:
  1. Error fetching PMID 17502904: [Jimenez-Gomez07]
  2. Error fetching PMID 12582628: [Loudet02]
  3. Error fetching PMID 16702412: [West06]
  4. Riken


  5. Error fetching PMID 17179097: [West07]
  6. Error fetching PMID 10802651: [GO_Classification]
  7. Error fetching PMID 17641193: [Clark07]
  8. Error fetching PMID 20838594: [Jimenez-Gomez10]
  9. Error fetching PMID 19575805: [Jimenez-Gomez09]
All Medline abstracts: PubMed HubMed