Complete chloroplast genome sequence of holoparasite Cistanche deserticola (Orobanchaceae) reveals gene loss and horizontal gene transfer from its host Haloxylon ammodendron (Chenopodiaceae)

doi:10.1371/journal.pone.0058747

. 2013;8(3):e58747.

doi: 10.1371/journal.pone.0058747. Epub 2013 Mar 15.

Complete chloroplast genome sequence of holoparasite Cistanche deserticola (Orobanchaceae) reveals gene loss and horizontal gene transfer from its host Haloxylon ammodendron (Chenopodiaceae)

Xi Li¹, Ti-Cao Zhang, Qin Qiao, Zhumei Ren, Jiayuan Zhao, Takahiro Yonezawa, Masami Hasegawa, M James C Crabbe, Jianqiang Li, Yang Zhong

Affiliations

PMID: 23554920
PMCID: PMC3598846
DOI: 10.1371/journal.pone.0058747

Complete chloroplast genome sequence of holoparasite Cistanche deserticola (Orobanchaceae) reveals gene loss and horizontal gene transfer from its host Haloxylon ammodendron (Chenopodiaceae)

Xi Li et al. PLoS One. 2013.

. 2013;8(3):e58747.

doi: 10.1371/journal.pone.0058747. Epub 2013 Mar 15.

Authors

Xi Li¹, Ti-Cao Zhang, Qin Qiao, Zhumei Ren, Jiayuan Zhao, Takahiro Yonezawa, Masami Hasegawa, M James C Crabbe, Jianqiang Li, Yang Zhong

Affiliation

¹ Ministry of Education Key Laboratory for Biodiversity Science and Ecological Engineering, School of Life Sciences, Fudan University, Shanghai, China.

PMID: 23554920
PMCID: PMC3598846
DOI: 10.1371/journal.pone.0058747

Abstract

The central function of chloroplasts is to carry out photosynthesis, and its gene content and structure are highly conserved across land plants. Parasitic plants, which have reduced photosynthetic ability, suffer gene losses from the chloroplast (cp) genome accompanied by the relaxation of selective constraints. Compared with the rapid rise in the number of cp genome sequences of photosynthetic organisms, there are limited data sets from parasitic plants. PRINCIPAL FINDINGS/SIGNIFICANCE: Here we report the complete sequence of the cp genome of Cistanche deserticola, a holoparasitic desert species belonging to the family Orobanchaceae. The cp genome of C. deserticola is greatly reduced both in size (102,657 bp) and in gene content, indicating that all genes required for photosynthesis suffer from gene loss and pseudogenization, except for psbM. The striking difference from other holoparasitic plants is that it retains almost a full set of tRNA genes, and it has lower dN/dS for most genes than another close holoparasitic plant, E. virginiana, suggesting that Cistanche deserticola has undergone fewer losses, either due to a reduced level of holoparasitism, or to a recent switch to this life history. We also found that the rpoC2 gene was present in two copies within C. deserticola. Its own copy has much shortened and turned out to be a pseudogene. Another copy, which was not located in its cp genome, was a homolog of the host plant, Haloxylon ammodendron (Chenopodiaceae), suggesting that it was acquired from its host via a horizontal gene transfer.

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Conflict of interest statement

Competing Interests: The authors have declared that no competing interests exist.

Figures

**Figure 1. Gene Maps of the plastid chromosomes of *C. deserticola*.**
Genes shown inside the circle are transcribed clockwise, those outside the circle are transcribed counterclockwise. The large single copy region (LSC) and the small single copy region (SSC) are separated by two inverted repeats (IRa and IRb). Asterisks indicate intron containing genes. Pseudogenes are marked by Ψ.

**Figure 2. Pairwise dN/dS value of *C. deserticola* (Cd), *E. virginiana* (Ev) and *N. tabacum* (Nt) vs. *O. europaea* (Oe) for all shared protein-coding genes.**
*indicates gene lost, ^#indicates the absence of non synonymous substitutions, ^$indicates the absence of synonymous substitutions.

Figure 3. Phylogenetic evidence for horizontal gene transfer of the plastid rpoC2 from *Haloxylon ammodendron* to *Cistanche deserticola.*
Lamiales are coloured in red, and Caryophyllales are coloured in blue. While the ten *C. deserticola* sequences involved in horizontal gene transfer are coloured in red. Numbers at nodes are posterior probabilities >0.60 and maximum likelihood bootstrap values >60. The Genebank number: *Oryza nivara*, NC_005973; *Antirrhinum indicum*, GQ997028; *Sesamum indicum*, NC_016433; *Boea hygrometrica*, NC_016468; *Jasminum nudiflorum*, NC_008407; Olea europaea, NC_013707; *Basella alba*, HQ843359; *Opuntia microdasys*, HQ843375; *Pereskia aculeata*, HQ843376; *Portulaca oleracea*, HQ843380; Mollugo verticillata, HQ843373; *Bougainvillea glabra*, HQ843360; *Mirabilis jalapa*, HQ843372; *Phytolacca americana*, HQ843378; *Celosia cristata*, HQ843361; *Spinacia oleracea*, NC_002202; *Silene conica*, NC_016729; *Stellaria media*, HQ843386; *Cistanche deserticola* (HGT), KC543998.

**Figure 4. Position of inserted cytosine within the transferred rpoC2 gene.**
(A) Alignment of the nucleotide sequences of transferred rpoC2 gene amplified from parasite and host with intact open reading frames of other related species. The inserted cytosine was labeled with colored vertical lines. (B) Inserted cytosine resulted in followed premature termination codon in the transferred rpoC2 in *Cistanche deserticola*.

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References

1. Raubeson LA, Jansen RK (2005) Chloroplast genomes of plants. In: Plant diversity and evolution: genotypic and phenotypic variation in higher plants. Henry RJ (Ed.). CABI Publishing, London.
1. Krause K (2012) Plastid genomes of parasitic plants: a trail of reductions and losses. In: Organelle genetics. Bullerwell C (Ed.). Springer, Berlin.
1. Jansen RK, Ruhlman TA (2012) Plastid Genomes of Seed Plants. In: Genomics of Chloroplasts and Mitochondria, Advances in Photosynthesis and Respiration. Bock R, Knoop V (Eds.). Springer, Berlin.
1. Barkman TJ, McNeal JR, Lim SH, Coat G, Croom HB, et al. (2007) Mitochondrial DNA suggests at least 11 origins of parasitism in angiosperms and reveals genomic chimerism in parasitic plants. BMC Evol Biol 7: 248. - PMC - PubMed
1. Wolfe KH, Morden CW, Palmer JD (1992) Function and evolution of a minimal plastid genome from a nonphotosynthetic parasitic plant. Proc Nat Acad Sci USA 89: 10648–10652. - PMC - PubMed

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Grants and funding

This work is supported by the National Science Foundation of China [30925004, 91131901 to Zhong Y; 31070197 to Li JQ]; and China Postdoctoral Science Foundation [20100480550, 2011M500538 to Zhang TC and Qiao Q]. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

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[1] Raubeson LA, Jansen RK (2005) Chloroplast genomes of plants. In: Plant diversity and evolution: genotypic and phenotypic variation in higher plants. Henry RJ (Ed.). CABI Publishing, London.

[2] Raubeson LA, Jansen RK (2005) Chloroplast genomes of plants. In: Plant diversity and evolution: genotypic and phenotypic variation in higher plants. Henry RJ (Ed.). CABI Publishing, London.

[3] Krause K (2012) Plastid genomes of parasitic plants: a trail of reductions and losses. In: Organelle genetics. Bullerwell C (Ed.). Springer, Berlin.

[4] Krause K (2012) Plastid genomes of parasitic plants: a trail of reductions and losses. In: Organelle genetics. Bullerwell C (Ed.). Springer, Berlin.

[5] Jansen RK, Ruhlman TA (2012) Plastid Genomes of Seed Plants. In: Genomics of Chloroplasts and Mitochondria, Advances in Photosynthesis and Respiration. Bock R, Knoop V (Eds.). Springer, Berlin.

[6] Jansen RK, Ruhlman TA (2012) Plastid Genomes of Seed Plants. In: Genomics of Chloroplasts and Mitochondria, Advances in Photosynthesis and Respiration. Bock R, Knoop V (Eds.). Springer, Berlin.

[7] Barkman TJ, McNeal JR, Lim SH, Coat G, Croom HB, et al. (2007) Mitochondrial DNA suggests at least 11 origins of parasitism in angiosperms and reveals genomic chimerism in parasitic plants. BMC Evol Biol 7: 248. - PMC - PubMed

[8] Barkman TJ, McNeal JR, Lim SH, Coat G, Croom HB, et al. (2007) Mitochondrial DNA suggests at least 11 origins of parasitism in angiosperms and reveals genomic chimerism in parasitic plants. BMC Evol Biol 7: 248. - PMC - PubMed

[9] Wolfe KH, Morden CW, Palmer JD (1992) Function and evolution of a minimal plastid genome from a nonphotosynthetic parasitic plant. Proc Nat Acad Sci USA 89: 10648–10652. - PMC - PubMed

[10] Wolfe KH, Morden CW, Palmer JD (1992) Function and evolution of a minimal plastid genome from a nonphotosynthetic parasitic plant. Proc Nat Acad Sci USA 89: 10648–10652. - PMC - PubMed

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Complete chloroplast genome sequence of holoparasite Cistanche deserticola (Orobanchaceae) reveals gene loss and horizontal gene transfer from its host Haloxylon ammodendron (Chenopodiaceae)

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Complete chloroplast genome sequence of holoparasite Cistanche deserticola (Orobanchaceae) reveals gene loss and horizontal gene transfer from its host Haloxylon ammodendron (Chenopodiaceae)

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