Loading content, please wait..
loading..
Logo
Version 3.22
login
or
register

Report for Polypogon monspeliensis (L.) Desf.

updated: Nov 24th 2020, 6:38 am see all updates
Changed fields since previous approved record are highlighted


Family Poaceae
Genus Polypogon
Species monspeliensis
Author (L.) Desf.
Infraspecific subsp.
Infraspecfic Author
Pictures
Plant type
  • psammophile
Life form
  • Annual
Previously was:
  • Perennial grass
    • Ecotypes Yes
    Max. salinity
    		 400 mMAtia, A., A. Smaoui, Z. Barhoumi, C. Abdelly and A. Debez (2011) Differential response to salinity and water deficit stress in Polypogon monspeliensis (L.) Desf. provenances during germinationKuhn, NL; Zedler, JB (1997) Differential effects of salinity and soil saturation on native and exotic plants of a coastal salt marshOuni, Y; Mateos-Naranjo, E; Abdelly, C; Lakhdar, A (2016) Interactive effect of salinity and zinc stress on growth and photosynthetic responses of the perennial grass, Polypogon monspeliensisPARTRIDGE, TR; WILSON, JB (1987) SALT TOLERANCE OF SALT-MARSH PLANTS OF OTAGO, NEW-ZEALAND
    Previously was: empty
    Germination YesAtia, A., A. Smaoui, Z. Barhoumi, C. Abdelly and A. Debez (2011) Differential response to salinity and water deficit stress in Polypogon monspeliensis (L.) Desf. provenances during germinationMahmood, K; Malik, KA; Lodhi, MAK; Sheikh, KH (1996) Seed germination and salinity tolerance in plant species growing on saline wastelandsNoe, G. B. and J. B. Zedler (2000) Differential effects of four abiotic factors on the germination of salt marsh annualsPARTRIDGE, TR; WILSON, JB (1987) GERMINATION IN RELATION TO SALINITY IN SOME PLANTS OF SALT MARSHES IN OTAGO, NEW-ZEALAND
    Salt glands and bladders unknown
    Photosynthesis Pathway unknown
    Molecular data
    Microbial interactions and mycorrhizal status YesCanfora, L; Lo Papa, G; Antisari, LV; Bazan, G; Dazzi, C; Benedetti, A (2015) Spatial microbial community structure and biodiversity analysis in Ouni, Y., A. Lakhdar, R. Scelza, R. Scotti, C. Abdelly, Z. Barhoumi and M. A. Rao (2013) Effects of two composts and two grasses on microbial biomass and biological activity in a salt-affected soilde Souza, MP; Huang, CPA; Chee, N; Terry, N (1999) Rhizosphere bacteria enhance the accumulation of selenium and mercury in wetland plants
    Previously was: unknown
    Bioremediation YesGao, S; Tanji, KK; Lin, ZQ; Terry, N; Peters, DW (2003) Selenium removal and mass balance in a constructed flow-through wetland system
    Previously was: unknown
    antioxidants
    Secondary Metabolites
    Compatible Solutes
    • ProlineTipirdamaz, R., D. Gagneul, C. Duhaze, A. Ainouche, C. Monnier, D. Ozkum and F. Larher (2006) Clustering of halophytes from an inland salt marsh in Turkey according to their ability to accumulate sodium and nitrogenous osmolytes
    Habitat
    • C1.5 Permanent inland saline and brackish lakes, ponds and poolsQasem, Jamal R. (2015) PROSPECTS OF WILD MEDICINAL AND INDUSTRIAL PLANTS OF SALINE HABITATS IN THE JORDAN VALLEYRosen, David J.; Caskey, Amber D.; Conway, Warren C; Haukos, David A. (2013) VASCULAR FLORA OF SALINE LAKES IN THE SOUTHERN HIGH PLAINS OF TEXAS AND EASTERN NEW MEXICO
    • A2.5 Coastal saltmarshes and saline reedbedsNoe, G. B. and J. B. Zedler (2000) Differential effects of four abiotic factors on the germination of salt marsh annualsPARTRIDGE, TR; WILSON, JB (1987) GERMINATION IN RELATION TO SALINITY IN SOME PLANTS OF SALT MARSHES IN OTAGO, NEW-ZEALAND
    Previously was:
  • C1.5 Permanent inland saline and brackish lakes, ponds and poolsQasem, Jamal R. (2015) PROSPECTS OF WILD MEDICINAL AND INDUSTRIAL PLANTS OF SALINE HABITATS IN THE JORDAN VALLEY
    • Economic use
    Distribution
    Distribution (text)
    • Mediterranean region
    • Africa - northOuni, Y; Mateos-Naranjo, E; Abdelly, C; Lakhdar, A (2016) Interactive effect of salinity and zinc stress on growth and photosynthetic responses of the perennial grass, Polypogon monspeliensis
    • 75 km parallel to the Jordan River and the Dead Sea, and varies in width from 10 km at Wadi Hisban and Wadi Zarqa to about 2-3 km in Zara,JordanQasem, Jamal R. (2015) PROSPECTS OF WILD MEDICINAL AND INDUSTRIAL PLANTS OF SALINE HABITATS IN THE JORDAN VALLEY
    • Southern ScicilyCanfora, L; Lo Papa, G; Antisari, LV; Bazan, G; Dazzi, C; Benedetti, A (2015) Spatial microbial community structure and biodiversity analysis in
    • Tesas and New MexicoRosen, David J.; Caskey, Amber D.; Conway, Warren C; Haukos, David A. (2013) VASCULAR FLORA OF SALINE LAKES IN THE SOUTHERN HIGH PLAINS OF TEXAS AND EASTERN NEW MEXICO
    • California, USANoe, G. B. and J. B. Zedler (2000) Differential effects of four abiotic factors on the germination of salt marsh annuals
    • 0tago, New ZealandPARTRIDGE, TR; WILSON, JB (1987) GERMINATION IN RELATION TO SALINITY IN SOME PLANTS OF SALT MARSHES IN OTAGO, NEW-ZEALAND
    Previously was:
  • Mediterranean region
  • Africa - north
  • 75 km parallel to the Jordan River and the Dead Sea, and varies in width from 10 km at Wadi Hisban and Wadi Zarqa to about 2-3 km in Zara,JordanQasem, Jamal R. (2015) PROSPECTS OF WILD MEDICINAL AND INDUSTRIAL PLANTS OF SALINE HABITATS IN THE JORDAN VALLEY
    • Miscellaneous notes
    References

    Last Records approved
    Atriplex lindleyi subsp. inflata (F.Muell.) Paul G.Wilson
    Submitted by T J Flowers
    Jan 21st 2022, 5:49 am
    Approved by T J Flowers
    Jan 21st 2022, 5:49 am
    Atriplex leucoclada Boiss.
    Submitted by T J Flowers
    Jan 21st 2022, 5:42 am
    Approved by T J Flowers
    Jan 21st 2022, 5:42 am
    Atriplex lentiformis (Torr.) S.Watson
    Submitted by T J Flowers
    Jan 21st 2022, 5:35 am
    Approved by T J Flowers
    Jan 21st 2022, 5:36 am
    Atriplex lampa (Moq.) Gillies ex D.Dietr.
    Submitted by T J Flowers
    Jan 21st 2022, 5:22 am
    Approved by T J Flowers
    Jan 21st 2022, 5:22 am
    Atriplex laciniata L.
    Submitted by T J Flowers
    Jan 21st 2022, 5:09 am
    Approved by T J Flowers
    Jan 21st 2022, 5:09 am
    LEGAL NOTICES — This website is protected by Copyright © The University of Sussex, 2012, 2013, 2014, 2015, 2016, 2017, 2018, 2019, 2020, 2021, 2022. The eHALOPH database is protected by Database Right and Copyright © The University of Sussex and other contributors, 2006, 2012, 2013, 2014, 2015, 2016, 2017, 2018, 2019, 2020, 2021, 2022. This database is based on an earlier work by James Aronson.
    THIS WEBSITE AND THIS DATABASE ARE PROVIDED ON AN "AS IS" BASIS, AND YOU USE THEM AND RELY ON THEM AT YOUR OWN RISK.

    Contact email: halophytes@sussex.ac.uk
    Credits – Tim Flowers, Joaquim Santos, Moritz Jahns, Brian Warburton, Peter Reed