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Journal of the Australian Rangeland Society
RESEARCH ARTICLE

Genetic differentiation of the dominant perennial grass Cenchrus ciliaris L. contributes to response to water deficit in arid lands

Amina Kharrat-Souissi A C , Alex Baumel B , Franck Torre B and Mohamed Chaieb A
+ Author Affiliations
- Author Affiliations

A Université de Sfax, Faculté des Sciences de Sfax, Laboratoire de Biologie et d’Ecophysiologie des végétaux en milieu aride, Route de Sokra, Km 3.5, BP 1171-3000, Sfax, Tunisia.

B Institut Méditerranéen de la Biodiversité et d’Ecologie marine et continentale, UMR CNRS 7263-IRD 237, Université d’Aix-Marseille, Campus de l’Etoile, Saint Jérôme, case 421, 13397 Marseille Cedex 20, France.

C Corresponding author. Email: kharratsouissi@yahoo.fr

The Rangeland Journal 34(1) 55-62 https://doi.org/10.1071/RJ11034
Submitted: 6 June 2011  Accepted: 28 September 2011   Published: 29 February 2012

Abstract

Perennial herbaceous plants are a key element of the vegetation cover in arid lands, during a long period of the year, but their persistence depends on their ability to cope with acute drought. This characteristic could become very important with the predicted climatic changes in arid lands because the persistence of perennial plants will be a key element countering the process of desertification. The aim of the present study was to compare experimentally the response to water deficit of different genotypes of the perennial grass Cenchrus ciliaris L. (buffelgrass). We analysed the impact of water deficit on productivity, time span of the vegetative growth and leaf traits. Overall, there was highly heritable variation in the responses to applied water deficit for the measured attributes, and five different groups of genotypes responded differently to water deficit. These groups of genotypes differently invested their energy to alter their phenotype in response to water deficit. Consequently, some genotypes were more strongly affected by the water deficit and their aboveground biomass showed the largest decrease. The group of genotypes which showed the smallest decrease of their aboveground biomass was characterised by less increase of leaf hairiness, a strong decrease of leaf area and also the strongest decrease of stomatal density on the abaxial epidermis. The current study provides evidence that the capacity of C. ciliaris to regulate its growth as an adaptive mechanism under water deficit is dependent on strong genetic variation that could affect its productivity and in consequence the vegetation cover of arid ecosystems.

Additional keywords: adaptation, experimental water stress, phenotypic response, Poaceae, variability.


References

Arriaga, L., Castellanos, A. E., Moreno, E., and Alarcocon, J. (2004). Potential ecological distribution of alien invasive species and risk assessment: a case study of buffel grass in arid regions of Mexico. Conservation Biology 18, 1504–1514.
Potential ecological distribution of alien invasive species and risk assessment: a case study of buffel grass in arid regions of Mexico.Crossref | GoogleScholarGoogle Scholar |

Arshad, M., Ashraf, M. Y., Ahmad, M., and Zaman, F. (2007). Morpho-genetic variability potential of Cenchrus ciliaris L. from Cholistan desert, Pakistan. Pakistan Journal of Botany 39, 1481–1488.

Boujnah, D. (1997). Morphological, anatomical and ecophysiological variations, in relation to drought stress resistance of the olive tree (Olea europaea L.). PhD Thesis, University of Gand, Belgium. [In French].

Boussaid, M., Ben Fadhel, N., Zaouali, Y., Ben Salah, A., and Abdelkefi, A. (2004). Pastoral plants in the North African arid areas. Cahiers Options Méditerranéennes 62, 55–59. [In French with English summary].

Chaieb, M., Henchi, B., and Boukhris, M. (1996). Impact of clipping on root systems of 3 grass species in Tunisia. Journal of Range Management 49, 336–339.
Impact of clipping on root systems of 3 grass species in Tunisia.Crossref | GoogleScholarGoogle Scholar |

Cuénod, A., Pottier-Alapetite, G., and Labbe, A. (1954). ‘Analytical and Synoptic Flora of Tunisia. Vascular Cryptogams, Gymnosperms and Monocotyledons.’ (SEFAN: Tunis, Tunisia.) [In French].

Emberger, L. (1954). A biogeograpic classification of climates. Researches and Developments in Montpellier Botanical Laboratory. Faculty of Sciences of Montpellier Série Botanique 7, 3–43.

Farooq, M., Wahid, A., Kobayashi, N., Fujita, D., and Basra, S. M. A. (2009). Plant drought stress: effects, mechanisms and management. Agronomy for Sustainable Development 29, 185–212.
Plant drought stress: effects, mechanisms and management.Crossref | GoogleScholarGoogle Scholar |

Hanselka, C. W. (1984). Grazing management strategies for buffel grass (Cenchrus ciliaris). In: ‘Buffelgrass, Adaptation, Management and Forage Quality Symposium’. (Eds E. C. A. Runge and J. L. Schuster.) pp. 53–65. (The Texas Agricultural Experiment Station, Bull. MP: College Station, TX.)

Kharrat-Souissi, A., Baumel, A., Mseddi, K., Torre, F., and Chaieb, M. (2010). Polymorphism of Cenchrus ciliaris a perennial grass of arid zones. African Journal of Ecology 49, 209–220.
Polymorphism of Cenchrus ciliaris a perennial grass of arid zones.Crossref | GoogleScholarGoogle Scholar |

Kharrat-Souissi, A., Baumel, A., Torre, F., Juin, M., Siljak-Yakovlev, S., Roig, A., and Chaieb, M. (2011). New insights into the polyploid complex Cenchrus ciliaris L. (Poaceae) show its capacity for gene flow and recombination processes despite its apomictic nature. Australian Journal of Botany 59, 543–553.
New insights into the polyploid complex Cenchrus ciliaris L. (Poaceae) show its capacity for gene flow and recombination processes despite its apomictic nature.Crossref | GoogleScholarGoogle Scholar |

Lazaridou, M., and Koutroubas, S. D. (2004). Drought effect on water efficiency of berseem clover at various growth stages. In: ‘New Directions for a Diverse Planet. Proceeding for 4th International Crop Science Congress’. Brisbane, Qld, 26 Sept.–1 Oct. 2004. (Ed. R. A. Fischer.) (The Regional Institute Ltd, Online Community Publishing: Australia) Available at: www.cropscience.org.au (accessed 1 October 2011).

Lazaridou, M., and Noitsakis, B. (2003). The effect of water deficit on yield and water use efficiency of lucerne. In: ‘Grassland Science in Europe. Vol. 8’. (Eds A. Kirilov, N. Todorov and I. Katerov.) pp. 344–347. (Bulgarian Association for Grassland and Forage Production (BAGFP): Pleven.)

Le Houérou, H. N. (1959). ‘Ecological Research and Floristic Vegetation of Southern Tunisia.’ (Institute of Research on the Sahara: Algeria.) [In French].

Le Houérou, H. N. (2000). Restoration and rehabilitation of arid and semi-arid Mediterranean ecosystems in North Africa and West Asia: a review. Arid Soil Research and Rehabilitation 14, 3–14.
Restoration and rehabilitation of arid and semi-arid Mediterranean ecosystems in North Africa and West Asia: a review.Crossref | GoogleScholarGoogle Scholar |

M’Seddi, K., Visser, M., Neffati, M., Reheul, D., and Chaieb, M. (2002). Seed and spike traits from remnant populations of Cenchrus ciliaris L. in South Tunisia: high distinctiveness, no ecotypes. Journal of Arid Environments 50, 309–324.
Seed and spike traits from remnant populations of Cenchrus ciliaris L. in South Tunisia: high distinctiveness, no ecotypes.Crossref | GoogleScholarGoogle Scholar |

M’Seddi, K., Mnif, L., Chaieb, M., Neffati, M., and Roux, M. (2004). Aboveground phytomass productivity and morphologic variability of Tunisian accessions of Cenchrus ciliaris. African Journal of Range and Forage Science 19, 13–20.

Mansoor, U., Mansoor, H., Wahid, A., and Rao, A. R. (2002). Ecotypic variability for drought resistance in Cenchrus ciliaris L. germplasm from Cholistan Desert in Pakistan. International Journal of Agriculture and Biology 4, 392–397.

Mnif, L., and Chaieb, M. (2010). Net photosynthesis and leaf water potential of buffel grass (Cenchrus ciliaris L.) accessions growing in the arid zone of Tunisia. Journal of Biological Research-Thessalon 14, 231–238.
| 1:CAS:528:DC%2BC3cXhtVygurzL&md5=26ebd5855a22428b9feeb2c05d159c8eCAS |

Parkhurst, D. F., and Loucks, O. J. (1972). Optimal leaf size in relation to the environment. Journal of Ecology 60, 505–537.
Optimal leaf size in relation to the environment.Crossref | GoogleScholarGoogle Scholar |

Parmesan, C. (2006). Ecological and evolutionary responses to recent climate change. Annual Review of Ecology and Systematics 37, 637–669.
Ecological and evolutionary responses to recent climate change.Crossref | GoogleScholarGoogle Scholar |

R Development Core Team (2009). ‘R: A Language and Environment for Statistical Computing.’ (R Foundation for Statistical Computing: Vienna, Austria.) Available at: www.R-project.org (accessed 1 October 2011).

Taiz, L., and Zeiger, E. (2002). ‘Plant Physiology.’ (Sunderland: Redwood City.)

Visser, M., M’seddi, K., Chaïeb, M., and Neffati, M. (2008). Assessing yield and yield stability of remnant populations of Cenchrus ciliaris L. in arid Tunisia: developing a blueprint for initiating native seed production. Grass and Forage Science 63, 301–313.
Assessing yield and yield stability of remnant populations of Cenchrus ciliaris L. in arid Tunisia: developing a blueprint for initiating native seed production.Crossref | GoogleScholarGoogle Scholar |

WorldClim Dataset (2011). WorldClim – Global Climate Data. Available at: www.worldclim.org (accessed 1 October 2011).

Zouari, K., Bouzid, J., Bousnina, A., Chaied, M., Karray, N., and Bradai, N. (1996). ‘Implications of Climate Changes for the Sfax Coastal Area (Tunisia).’ MAP Technical Reports Series No. 99. (UNEP: Athens.) [In French].