Chan:Research: Difference between revisions

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[http://www-plb.ucdavis.edu/index.html Department of Plant Biology] at [http://www.ucdavis.edu/ UC Davis]
[http://www-plb.ucdavis.edu/ Department of Plant Biology], [http://www.ucdavis.edu/ UC Davis] and [http://www.hhmi.org HHMI]
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[[Chan:Bioinformatics Sites|Bioinformatics]]
[[Chan:Bioinformatics Sites|Bioinformatics]]
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[[Chan:Resources|Resources]]
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[[Chan:Teaching|Teaching]]
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[[Chan:Contact|Contact]]
[[Chan:Contact|Contact]]
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'''Overview'''<br>
'''Centromeres: Controllers of Inheritance'''<br>
All organisms must pass an intact genome onto their progeny, so we are interested how chromosomes are faithfully inherited when cells divide. The centromere is the position on a chromosome where it attaches to the mitotic spindle, facilitating correct segregation. The protein complex that creates a microtubule binding site at the centromere is termed the kinetochore. We study chromosome properties that specify centromere location and function using the model plant ''Arabidopsis thaliana''. ''Arabidopsis'' has key advantages for studying centromeres:<br>
<br>
<br>
- facile genetics<br>
(You can also read about our research at the [http://www.hhmi.org/research/hhmi-gbmf/chans.html HHMI website])<br>
- centromere DNA structure that is similar to most plants and animals (megabases of short tandem repeats)<br>
- simple karyotype (haploid # = 5), allowing us to visualize individual kinetochores easily<br>
<br>
<br>
'''Specific Projects'''<br>
We study the fundamental biology of genetic inheritance, and aim to manipulate it for practical benefit. Centromeres control chromosome segregation during cell division, because they are the loci at which chromosomes attach to spindle microtubules via the kinetochore protein complex. Centromere DNA in most plants and animals consists of megabases of simple tandem repeats. These sequences can be dispensable for centromere function. Instead, the centromere is epigenetically specified by CENH3, a centromere-specific histone H3 variant that replaces conventional H3 in centromeric nucleosomes, and is essential for recruiting other kinetochore proteins.<br>
<br>
<br>
We are studying the following chromosome features that distinguish centromeres:<br>
The plant ''Arabidopsis thaliana'' is ideal for studying chromosome segregation, because it combines facile genetics and cytology with large centromeres that are similar to those vertebrate cells (by contrast, laboratory yeasts have very small centromeres).<br>
<br>
<br>
1. The centromere-specific histone CENH3<br>
We have discovered that centromere differences between two parents can cause massive chromosome segregation errors when their genomes meet in the fertilized zygote. When ''Arabidopsis'' plants expressing altered CENH3 proteins are crossed to wild type, chromosomes from the mutant parent can be completely eliminated, yielding haploid progeny. Major research projects in the lab are listed below.<br>
Centromeres in many eukaryotes are marked epigenetically by a centromere-specific version of histone H3 (CENH3), which replaces conventional H3 in centromeric nucleosomes. In several cases, centromere tandem repeat DNA is dispensable for centromere function, providing that CENH3 nucleates a functional centromere. We are developing new methods for quantifying CENH3 nucleosomes at centromeres. CENH3 evolves much more rapidly than conventional H3, and we are investigating the functional consequences of this rapid evolution.<br>
<br>
<br>
2. Centromeric heterochromatin<br>
[[Image:haploid_production.jpg|500 px]]<br>
Centromeres are typically embedded in repeat- and transposon-rich chromosome regions with extensive transcriptional silencing i.e. heterochromatin. ''Arabidopsis'' heterochromatin mutants are well-characterized, and we are using these resources to study how changes in gene silencing and in chromatin modifications affect centromere function.<br>
<br>
<br>
3. Centromere DNA<br>
'''1) Mechanism of genome elimination'''<br>
In most plants and animals, centromere DNA is composed of megabases of short tandem repeats. Like the centromere-specific histone, these sequences evolve very rapidly. The size of the repeat array and high degree of similarity between repeats make centromere DNA difficult to study with conventional genetic tools. In collaboration with [http://korflab.ucdavis.edu/ Ian Korf] and [http://agronomy.cfans.umn.edu/STUPAR_ROBERT_M.html Bob Stupar], we are using bioinformatics, shotgun sequencing and cytogenetics to characterize centromere DNA from a very wide range of eukaryotes. By comparing centromere DNAs from many genomes, we hope to discover principles that govern their function and evolution.<br>
<br>
<br>
Chromosome spread from metaphase II photographed by [[Chan:Ravi_Maruthachalam|Ravi]]. DNA is stained with DAPI, and five pairs of sister chromatids can be seen in each cell.<br>
We are using genetic and cytological methods to investigate chromosome missegregation caused by parental centromere differences. Crosses between ''cenh3'' mutants and wild-type feature a high amount of seed abortion, and produce a mixture of diploid, aneuploid and haploid progeny. We are working to understand the mechanistic basis of these observations.<br>
[[Image:metaII.jpg|600px]]
<br>
 
'''2) Centromere evolution'''<br>
<br>
Despite the essential nature of centromeres, their DNA sequence and the CENH3 protein evolve rapidly. To study the functional consequences of rapid centromere evolution, we are manipulating CENH3 and centromere DNA in ''Arabidopsis'' and in other plants. In collaboration with [http://korflab.ucdavis.edu/ Ian Korf], we are also using comparative genomics to study how centromere DNA evolution has been constrained by functional demands.<br>
<br>
'''3) Chromosome engineering to create new plant breeding technologies'''<br>
<br>
Haploid plants that are converted back into diploids can greatly [http://www.formula1.com/ accelerate] plant breeding. Such “doubled haploids” produce instant homozygous lines from heterozygous F1s, a process that normally takes 8-10 generations of inbreeding. As described above, we have discovered a simple method for producing haploid plants through seed by manipulating CENH3.  Haploids are easily converted to diploids, so ''Arabidopsis'' geneticists can produce large recombinant populations in a single step, or rapidly generate multiple mutants (e.g. 1 out of 256 haploid progeny will contain eight unlinked mutations if one starts with a octuple heterozygote). A detailed protocol for generating ''Arabidopsis'' haploids is available at [http://tinyurl.com/ArabidopsisHaploidProtocol http://tinyurl.com/ArabidopsisHaploidProtocol]<br>
<br>
Our method has key advantages over current procedures that often require tissue culture and are limited to specific species or genotypes. As CENH3 is found in all eukaryotes, the procedure should theoretically work in any plant species. To learn more about our technology, please see this [http://techtransfer.universityofcalifornia.edu/NCD/19877.html website].<br>
<br>
We are also interested in developing new plant breeding methods through chromosome engineering. Hybrid vigour is the basis of many high-yielding agricultural varieties, but it is impossible to propagate a heterozygous genotype through sexual reproduction. In collaboration with Imran Siddiqi and Raphael Mercier's labs, we have recently shown that hybrid ''Arabidopsis'' can be crossed to a cenh3 mutant to create clonal progeny that preserve their heterozygous genotype (see [[Chan:Publications|Publications]] for details).
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Latest revision as of 15:40, 25 November 2011


Chan Lab
Department of Plant Biology, UC Davis and HHMI


Centromeres: Controllers of Inheritance

(You can also read about our research at the HHMI website)

We study the fundamental biology of genetic inheritance, and aim to manipulate it for practical benefit. Centromeres control chromosome segregation during cell division, because they are the loci at which chromosomes attach to spindle microtubules via the kinetochore protein complex. Centromere DNA in most plants and animals consists of megabases of simple tandem repeats. These sequences can be dispensable for centromere function. Instead, the centromere is epigenetically specified by CENH3, a centromere-specific histone H3 variant that replaces conventional H3 in centromeric nucleosomes, and is essential for recruiting other kinetochore proteins.

The plant Arabidopsis thaliana is ideal for studying chromosome segregation, because it combines facile genetics and cytology with large centromeres that are similar to those vertebrate cells (by contrast, laboratory yeasts have very small centromeres).

We have discovered that centromere differences between two parents can cause massive chromosome segregation errors when their genomes meet in the fertilized zygote. When Arabidopsis plants expressing altered CENH3 proteins are crossed to wild type, chromosomes from the mutant parent can be completely eliminated, yielding haploid progeny. Major research projects in the lab are listed below.



1) Mechanism of genome elimination

We are using genetic and cytological methods to investigate chromosome missegregation caused by parental centromere differences. Crosses between cenh3 mutants and wild-type feature a high amount of seed abortion, and produce a mixture of diploid, aneuploid and haploid progeny. We are working to understand the mechanistic basis of these observations.

2) Centromere evolution

Despite the essential nature of centromeres, their DNA sequence and the CENH3 protein evolve rapidly. To study the functional consequences of rapid centromere evolution, we are manipulating CENH3 and centromere DNA in Arabidopsis and in other plants. In collaboration with Ian Korf, we are also using comparative genomics to study how centromere DNA evolution has been constrained by functional demands.

3) Chromosome engineering to create new plant breeding technologies

Haploid plants that are converted back into diploids can greatly accelerate plant breeding. Such “doubled haploids” produce instant homozygous lines from heterozygous F1s, a process that normally takes 8-10 generations of inbreeding. As described above, we have discovered a simple method for producing haploid plants through seed by manipulating CENH3. Haploids are easily converted to diploids, so Arabidopsis geneticists can produce large recombinant populations in a single step, or rapidly generate multiple mutants (e.g. 1 out of 256 haploid progeny will contain eight unlinked mutations if one starts with a octuple heterozygote). A detailed protocol for generating Arabidopsis haploids is available at http://tinyurl.com/ArabidopsisHaploidProtocol

Our method has key advantages over current procedures that often require tissue culture and are limited to specific species or genotypes. As CENH3 is found in all eukaryotes, the procedure should theoretically work in any plant species. To learn more about our technology, please see this website.

We are also interested in developing new plant breeding methods through chromosome engineering. Hybrid vigour is the basis of many high-yielding agricultural varieties, but it is impossible to propagate a heterozygous genotype through sexual reproduction. In collaboration with Imran Siddiqi and Raphael Mercier's labs, we have recently shown that hybrid Arabidopsis can be crossed to a cenh3 mutant to create clonal progeny that preserve their heterozygous genotype (see Publications for details).

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