Registration of Large, Erect Pensacola Bahiagrass Germplasm Lines T18 and T23

doi:10.3198/jpr2007.03.0168crg

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Registration of Large, Erect Pensacola Bahiagrass Germplasm Lines T18 and T23

G. W. Burton and W. F. Anderson^*

USDA-ARS, Crop Genetics and Breeding Research Unit, P.O. Box 748, Tifton, GA 31793

^* Corresponding author (bill.anderson{at}ars.usda.gov).

‘Pensacola’ bahiagrass (Paspalum notatum Flügge)germplasm lines T18 (Reg. No. GP-3, PI 648217) and T23 (Reg.No. GP-4, PI 648218) were jointly released by the AgriculturalResearch Service, United States Department of Agriculture andthe University of Georgia College of Agricultural and EnvironmentalSciences, Coastal Plain Experiment Station in Tifton in 2007.T18 and T23 bahiagrass germplasm lines have larger, more erectplants and higher individual plant yields, than Pensacola. Theyhave value as parents in development of high-yielding bahiagrasscultivars for pasture and hay production.

T18 and T23 are a result of 18 and 23 cycles of recurrent restrictedphenotypic selection (RRPS), respectively, for individual plantsize and yield from ‘Pensacola’ (Burton 1974; 1982).For each cycle, 20% of 1000 space-planted selections from theprevious cycle were selected based on above-ground herbage accumulation.In December, 125 seeds of each entry were planted in rows inflats of soil in the greenhouse. In February, the seven mostvigorous seedlings were transplanted to 5-cm clay pots in thegreenhouse. In April, land was prepared in the field by fumigatingwith methyl bromide and the six most vigorous plants of the166 best (largest and best established) entries were plantedon 6-m centers in six blocks. In July, five plants having inflorescencesand having the longest leaves within each 5 x 5 block were selected.Three culms from each selection were labeled and placed togetherin a common vessel filled with water in isolation. Inflorescenceswere shaken each morning to ensure inter-pollination. Harvestedseed produced were used for the next cycle in the greenhouseand transplanted to the field for selection the following spring.

To evaluate the change in individual plant characteristics ofthe ninth (T9), eighteenth (T18), and twenty-third (T23) cyclesof selection from Pensacola, spaced seedlings were planted on6 May 1998 in the field at Tifton, GA with Pensacola and fiveother entries (total nine entries). Two tests were planted witheach having 18 plants from each entry. Plants were spaced at17.6 cm and 26.4 cm in the two tests in a ‘Design 3’orientation. A Design 3 randomizes the nine entries in a 3 x3 arrangement to form a lattice square block and nine blocks(replications) are then arranged 3 x 3 similar to a ‘Sudoku’puzzle orientation. Two Design 3 patterns were aligned end toend to constitute the 18 replications for each spaced planttest. Individual plant dry matter yield, plant height, and plantdiameter were measured on 8 October for the 17.6 cm spacingtest and on 13 October for the 26.4 cm spacing test.

Individual plant phenotype data was recorded on 100 plants eachof Tifton 9, T18, and T23 in 2005. Seeds were started in thegreenhouse and transplanted to 2-cm clay pots. The culm numberwas counted four weeks after germination (17 May 2005) and plantswere then transplanted to the field. Plants of each entry werespace planted 26.4 cm apart in a single bed at Tifton, GA. Culmangle as measured as degrees from ground (ground level = 0,completely erect = 90) of the lowest culm to the ground, plantheight (ground to base of terminal culm), leaf length (thirdleaf from culm terminal), and leaf width (third leaf from culmterminal) were recorded on 30 June 2005. Raceme number (averageof three inflorescences) and raceme length (average of longestraceme on three inflorescences) were measured on July 15, 2005.

Plant dry matter yield, plant height and plant diameter of T23was significantly greater (p = 0.05) than Pensacola and T9 bahiagrasswhile T18 was intermediate in both tests (Tables 1 and 2 )which supports previous data (Pedreira and Brown, 1996; Werner and Burton, 1991).Plants of T18 and T23 had a more erect plant phenotype thanPensacola or Tifton 9 (Burton, 1989) bahiagrasses.

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Table 1. Dry matter yield, plant height, and plant diameter of individual plants of bahiagrass spaced 17.6 cm apart in as Design 3 randomized plot arrangement with 18 replications planted 6 May 1998 and harvested 8–9 October 1998.

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Table 2. Dry matter yield, plant height, and plant diameter of individual plants of bahiagrass spaced 26.4 cm apart in randomized Design 3 plot arrangement with 18 replications planted 6 May 1998 and harvested 13–14 October 1998.

Mature plants of T18 and T23 had significantly fewer culms (8.1and 6.3, respectively) than Tifton 9 (9.2) in field comparisonsof 100 individual spaced plants in 2005 (Table 3 ). Culm anglesfrom horizontal were significantly greater for T18 (46°)and T23 (55°) than for Tifton 9 (34^o) indicating more erectplant types. Plant heights and leaf lengths were greater forT18 and T23 than Tifton 9; however, leaf width of the germplasmlines were less than Tifton 9. Inflorescences had generallythree racemes. Raceme lengths of T18 and Tifton 9 were similar,whereas T23 racemes were shorter (Table 3).

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Table 3. Comparative means for morphological traits between Tifton 9, T 18, and T 23 on 100 individual spaced plants in field Tifton, GA 2005.

Seeds of T18 and T23 will be deposited in the USDA-ARS NationalPlant Germplasm System. Breeder seed will be maintained by USDA-ARSCrop Genetics and Breeding Research Unit at Tifton. Small quantitiesof seed may be obtained from W. F. Anderson at the USDA/ARSlocation in Tifton (Requests made to P.O. Box 748, Tifton, GA31793).

Footnotes

All rights reserved. No part of this periodical may be reproducedor transmitted in any form or by any means, electronic or mechanical,including photocopying, recording, or any information storageand retrieval system, without permission in writing from thepublisher. Permission for printing and for reprinting the materialcontained herein has been obtained by the publisher.

Received for publication March 23, 2007.

References

Burton, G.W. 1974. Recurrent restricted phenotypic selection increases forage yields of Pensacola bahiagrass. Crop Sci. 14:831–835.[Abstract/Free Full Text]

Burton, G.W. 1982. Improved recurrent restricted phenotypic selection increases bahiagrass forage yields. Crop Sci. 22:1058–1061.[Abstract/Free Full Text]

Burton, G.W. 1989. Registration of ‘Tifton 9’ Pensacola bahiagrass. Crop Sci. 29:1326.[Free Full Text]

Pedreira, C.G.S., and R.H. Brown. 1996. Physiology, morphology, and growth of individual plants of selected and unselected bahiagrass populations. Crop Sci. 36:138–142.[Abstract/Free Full Text]

Werner, B.K., and G.W. Burton. 1991. Changes in morphology and yield of Pensacola bahiagrass due to recurrent restricted phenoyptic selection for yield. Crop Sci. 31:48–50.[Abstract/Free Full Text]

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