THE FLORISTIC STUDY OF

HERBACEOUS GRASSES IN SULAWESI

MARTHEN THEOGIVES LASUT

DEPARTMENT OF BIOLOGY

THE GRADUATE SCHOOL

BOGOR AGRICULTURAL UNIVERSITY

BOGOR

STATEMENT OF RESEARCH ORIGINALITY AND

INFORMATION SOURCE

This is to verify that my dissertation entitled: The Floristic Study of Herbaceous Grasses in Sulawesi is my own work and never been submitted to any institution before. All of the incorporated data and information here are valid and stated clearly in the text, and listed in the references.

Bogor, November 2008 Marthen Theogives Lasut NRP G361030061

ABSTRACT

MARTHEN THEOGIVES LASUT. The Floristic Study of Herbaceous Grasses in Sulawesi. (Under direction of Dr. Sri S. Tjitrosoedirdjo, Prof. Dr. Edi Guhardja, Prof. Dr. Mien A. Rifai, and Dr. Jan F. Veldkamp).

Grasses is the one of the largest plant family in the world, it consist of about 657 genera comprising of 9379 species occur in the tropic region to the sub-tropic region. In Malesia there are about 150 genera; Papua New Guinea 130 genera; Malaysia 80 genera; Java 116 genera. Taxonomically, herbaceous grasses are very large, difficult and poorly known in Sulawesi. Therefore the floristic study of herbaceous in Sulawesi was conducted by using explorative and descriptive methods, to which the data was taken from morphological point of view. Based on gross morphological study on 764 number specimens, it was concluded that Sulawesi herbaceous grasses comprises of 17 tribes, 93 genera, 212 species, and four varieties. There are one endemic variety and seven endemic species in this area. One species is described as a new for science and one other species is proposed to be a new species. Twenty five new records are reported also in Sulawesi.

ABSTRAK

MARTHEN THEOGIVES LASUT. Kajian floristik rumput herba Sulawesi. (Dibimbing oleh Dr. Sri S. Tjitrosoedirdjo, Prof. Dr. Edi Guhardja, Prof. Dr. Mien A. Rifai, dan Dr. Jan F. Veldkamp).

Rumput herba adalah salah satu keluarga tumbuhan terbesar di dunia, anggotanya sekitar 657 marga dengan kurang lebih 9379 jenis yang tersebar di daerah tropis dan sub tropis. Kawasan Malesia memiliki 150 marga, Papua New Guinea 130 marga, Malaysia 80 marga, Jawa 116 marga. Secara taksonomi, rerumputan sangat besar, sulit dan kurang dipahami di Sulawesi. Karena itu maka kajian flora rumput Sulawesi dilakukan. Kajian ini menggunakan metode eksplorasi dan deskripsi dengan karakter morfologi sebagai cara identifikasinya. Berdasarkan pengamatan yang dilakukan pada 764 nomor koleksi spesimen rumput herba Sulawesi, ditemukan 17 puak, 93 marga, 212 jenis dan 4 varietas. Terdapat satu varitas endemik dan tujuh jenis endemic. Satu jenis rumput telah di pertelakan sebagai jenis baru dan satu lagi diusulkan sebagai jenis baru. Ditemukan pula dua puluh lima catatan baru rumput Sulawesi dalam kajian ini.

SUMMARY

MARTHEN THEOGIVES LASUT. The Floristic Study of Herbaceous Grasses in Sulawesi. (Under the supervision of Dr. Sri S. Tjitrosoedirdjo, Prof. Dr. Edi Guhardja, Prof. Dr. Mien A. Rifai, and Dr. Jan F. Veldkamp).

The grass family is one of the largest flowering plants next only to the Compositae, Orchidaceae, and Leguminosae. However, in terms of individual numbers, the grasses are most abundant and most widely distributed seed families. There are few habitats in which grasses do not occur naturally, and their range is only restricted by alpine or arctic cold on one hand and the intense shade of some tropical forests and drought of desert areas on the other. It is not surprising that the grass family has diversified into a rich array of variously modified and adapted forms. Grasses are so different from most other plants that special of terms have been devised to their vegetative and generative structures. The vegetative parts of the grass plant are superficially rather uniform. Moreover, within certain limits, the most obvious differences of size, colour, and hairiness are strongly influenced by environmental factors. As a result the use of vegetative characters for the identification of grasses is rather limited

The flowering parts (inflorescence) of the grass plant are a composite structure comprising various patterns of aggregation of the basic floral unit, the spikelet. Most commonly the inflorescence is a panicle of more or less open-branched structure. Less commonly the inflorescence is a spike (a single axis upon along which are borne sessile or stalkless spikelets). However, some panicles have their branches so reduced that they may appear to be spikes. Racemes (a single axis upon which are borne single pedicelled or stalked spikelets) are less common. However, a multitude of combinations of these various forms exists.

For Malesian area so far, no comprehensive floristic account is available. Partial floras have been published for Java (1968) by Backer and Bakhuizen, Papua New Guinea (1969) by Henty, and Malay Peninsula (1971) by Gilliland. Accordingly an attempt is made to undertaken floristic study of herbaceous grasses in Sulawesi.

Based on the notes on specimen kept in Herbarium Bogoriense, exploration of grasses in Sulawesi was began by the work of Koorders in 1895. The first grass collection in Sulawesi was made by him from Singkil – near Buha Manado, at 2 January 1895. After that, it followed by many other explorers and collectors from several areas.

Floristic is a study of floras, with the main objective to inventorize and to provide a tool to identify the grass from this study area. Description of taxa in this study include vegetative and reproductive features, place of growth or habit, and

distribution, along with pertinent synonymy used in others floras, and references to the taxonomy of the included taxa. All species of Sulawesi herbaceous grasses found in the wild – not cultivated are described and provides a source of information of those taxa.

The results of this study indicate that, there are 17 tribe with 93 genera from 212 species and 4 varieties of herbaceous grasses existing in Sulawesi island. The tribes are Andropogoneae, Aristideae, Arundineae, Arundinelleae, Aveneae, Brachypodieae,

Centotheceae, Cynodonteae, Ehrharteae, Eragrostideae, Eriachneae, Isachneae,

Oryzeae, Paniceae, Phareae, Poeae, and Thysanolaeneae.

Based on the size of taxa recognized in Sulawesi, the Andropogoneae is the largest one with 35% of genera, followed by the Paniceae 25%, Cynodonteae 8%,

Eragrostideae 6%, Aveneae and Poeae 3%, Arundineae, Arundinelleae, Centotheca,

Oryzeae, and Phareae 2%, the others tribes with 1%.

South Sulawesi exhibit the highest degree of endemic taxa if compared with the other parts of Sulawesi, apparently due to the considerable areas of high mountains. There are one endemic variety and five endemic species in this area –

Anthoxanthum horsfieldii (Kunth ex Bennet) Mez. var. celebicum Y. Schouten;

Hyparrhenia pratermissa Veldk., Ischaemum celebicum P. Jansen, Ischaemum veldkampii Lasut, Poa celebica Ohwi ex Veldk., and Rytidosperma bonthainicum (P. Jansen) Veldk. All endemic taxa above concentrated in Latimojong ridge (Mts. Rantemario) and Lompobatang mountain. North Sulawesi have only one endemic species – Eragrostis dyskritos Lasut, which is found in Mounts Soputan. This species is a new for science (in preparation to publish). Central Sulawesi also have one endemic species – Cymbopogon minutiflorus S. Dransf., found in Donggala area on the slopes of limestone hills.

This study found that about 11 percent species of herbaceous grasses in Sulawesi are new records to Sulawesi.

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THE FLORISTIC STUDY OF

HERBACEOUS GRASSES IN SULAWESI

MARTHEN THEOGIVES LASUT

A dissertation submitted to fulfill one of the requirements for the Doctorate Degree at the Study Program of Biology,

Graduate School, Bogor Agricultural University

DEPARTMENT OF BIOLOGY THE GRADUATE SCHOOL

BOGOR AGRICULTURAL UNIVERSITY BOGOR

EXTERNAL EXAMINERS

Examination I : Prof. Dr. Elizabeth A. Widjaja

Herbarium Bogoriense, Botany Division, Research Centre for Biologi, Indonesian Institute of Science Bogor, Indonesia.

Examination II : Prof. Dr. Johanis P. Mogea

Herbarium Bogoriense, Botany Division, Research Centre for Biologi, Indonesian Institute of Science Bogor, Indonesia.

Dr. Nunik Sri Ariyanti.

Department of Biology, Faculty of Mathematics and Science, Bogor Agricultural University, Indonesia.

Dissertation title : The Floristic Study of Herbaceous Grasses in Sulawesi Name of student : Marthen Theogives Lasut

Number of Student : G361030061 Study Program : Biology

Approved by Advisory Committee

Dr. Sri S. Tjitrosoedirdjo, MSc. Prof. Dr. Ir. Edi Guhardja, MSc.

(Chairman) (Member)

Prof. Dr. Mien A. Rifai Dr. Jan F. Veldkamp

(Member) (Member)

Head of Study Program of Biology Dean of Graduate School

Dr. Ir. Dedy Duryadi Solihin, DEA Prof. Dr. Ir. Khairil Anwar Notodiputro, MS

FOREWORD

Research on the herbaceous grasses in Sulawesi under the title “The Floristic Study of Herbaceous Grasses in Sulawesi” was conducted from 2004-2008. Field study was carried out at 35 localities in Sulawesi. Specimen examination was conducted at Herbarium Bogoriense (BO), Herbarium Leiden (L), BIOTROP (BIOT) and Herbarium Wallaceana (WALL).

Some part of this dissertation have been published under the title: “A New Species of Ischaemum from Sulawesi”, that published in Reinwardtia 12(3): 257-259 (2006); and “The List to Genera of Herbaceous Grasses in Sulawesi”, published in

Eugenia 14(4): 387-396 (2008).

I am greatly appreciate to all of my advisor: Dr. Sri S. Tjitrosoedirdjo, Prof. Dr. Edi Guhardja, Prof. Dr. Mien A. Rifai, and Dr. Jan F. Veldkamp, for their advice, guidance, and encouragements throughout this study. I would like to sincerely thank to Prof. Dr. Elizabeth A. Widjaja and Prof. Dr. Johanis P. Mogea for their advice and technical support in the fields. I am grateful to Dr. M.M.J. van Balgooy for discussion and support when I was studying grasses specimens in Leiden. My special thank to Dr. Arie Keim, Drs. Tahan Udji, Dra. Himmah Rustiami, M.Sc., Ir. Emil S., M.Si for fruitful discussion and technical support in the field. I also thank to Mr. Onong Sabintoe, Mr. Uping Papa, Mr. Kurniawan Syam, Mr. Reinjel Manitik, Mr. Christian Sumampouw, and Mr. Bueng Kananga for collecting and helping in the field. I am also grateful to Mr. Sobari for line drawing the new specimen. I also thank to Mr. Alex Sumadijaya for typing the preliminary grasses list of Sulawesi.

My sincerely thanks to the following institutes for allowing me to used their facilities: 1) Herbarium Bogoriense (BO), Botany Division, Research Centre for Biology – Indonesian Institute of Science, 2) Nationaal Herbarium Leiden (L), Leiden Universiteit Branch, 3) Herbarium Wallaceana (Wall), Department of Agronomy, Faculty of Agriculture, UNSRAT Manado, and 4) Herbarium Biotrop (BIOT).

My special thanks to the BPPS scholarship from Directorate General of Higher Education (DIKTI), Department of National Education Republic Indonesia and Masarang Foundation (“Yayasan Masarang”) Tomohon, Indonesia for financing the field works.

Last but not least, my grateful goes to my wife (Vemmy) and children (Lucky and Gisela), my dear father (Alexander N. Lasut who passed away on 19 October 2008) and mother (Carolina S. Mukuan who passed away on 22 August 2001), my brothers (Edwin and Travelly) and sister (Mercy) for their continuing support and deep understanding.

CURRICULUM VITAE

Marthen Theogives Lasut was born on 28 March 1963 in Tomohon, North Sulawesi, as the second son from four children from the late Alexander N. Lasut and the late Carolina S. Mukuan. He was graduated from Sam Ratulangi University (UNSRAT) Manado in 1987. Since 1989 he was employed as a lecture at Faculty of Agriculture, Sam Ratulangi University (Unsrat) Manado. In 15July 1995 was married with Dra. Hilda V. Oroh. In 23 Desember 1996 he admitted the degree of Magister Science at Bogor Agricultutal University (IPB).

In September 2003, he was awarded to continue his study at IPB for his Ph.D. This study was partly supported by BPPS – DIKTI and Masarang Foundation Tomohon.

CONTENTS

Page

TABLE ………...XII LIST OF FIGURES ……….XIII

HISTORICAL INTRODUCTION ...1

The Grass Plant ………..1

The Explorations of Grasses in Sulawesi ………..……….. .4

MATERIAL AND METHODS ...6

Procedure .………..6

Locations ...6

Description of taxa ………...7

RESULTS AND DISCUSSIONS ...8

THE CLASSIFICATION OF SULAWESI GRASSES ………...8

ENDEMIC TAXA AND THEIR DISTRIBUTION IN SULAWESI ...10

NEW RECORDS OF HERBACEOUS GRASSES IN SULAWESI …………..11

TAXONOMY ...12

POACEAE Barnhart ...12

Key to the tribes ...13

Tribe 1. ANDROPOGONEAE Dumort ...14

Key to the genera ...15

Genus description and key to the species ...17

5. APLUDA L. ...17

5.1. Apluda mutica L. ...18

7. ARTHRAXON P. Beauv. ...19

Key to the species ...20

7.1. Arthraxon hispidus (Thunb.) Makino ...20

7.2. Arthraxon lancifolius (Trin.) Hochst. ...21

9. ASTHENOCHLOA Buse ...22

9.1. Asthenochloa tenera Buse ...22

11. BOTHRIOCHLOA Kuntze ...23

11.1. Bothriochloa bladhii (Retz.) S.T. Blake ...24

14. CAPILLIPEDIUM Stapf. ...25

Key to the species ...26

14.1. Capillipedium assimile (Steud.) A. Camus ...26

14.2. Capillipedium parviflorum (R. Br.) Stapf. ...27

17. CHIONACHNE R. Br. ...28

17.1. Chionachne punctata (R. Br.) Jannink ...28

Key to the species ...31

19.1. Chrysopogon aciculatus (L.) Trin. ...31

19.2. Chrysopogon celebicus Veldk. ...32

20. COELORACHIS Brongn. ...33

20.1. Coelorachis glandulosa (Trin.) Stapf ex Ridl. 33 21. COIX L. ...34

21.1. Coix lachryma-jobi L. ...35

22. CYMBOPOGON Sprengel ...36

Key to the species ...37

22.1. Cymbopogon citratus (DC.) Stapf. ...38

22.2. Cymbopogon tortilis (J. Presl.) A. Camus ...39

22.3. Cymbopogon flexuosus (Nees ex Steudel) J.F. Watson ...40

22.4. Cymbopogon minutiflorus S. Dransf. ...41

22.5. Cymbopogon procerus (R. Br.) Domin. ...42

27. DICHANTIUM Willemet ...44

Key to the Species ...44

27.1. Dichantium annulatum (Forssk.) Stapf. ...44

27.2. Dichantium aristatum (Poir.) C.E. Hubb. ...46

27.3. Dichantium caricosum (L.) A. Camus ...47

28. DIECTOMIS Kunth. ...48

28.1. Diectomis fastigiata (Sw.) P. Beauv. ...48

30. DIMERIA R. Br. ...49

30.1. Dimeria ornithopoda Trin. ...50

37. EREMOCHLOA Buse. ...51

Key to the species ...51

37.1. Eremochloa ciliaris (L.) Merr. ...51

37.2. Eremochloa eriopoda C.E. Hubb. ...52

40. EULALIA Kunth. ………53

Key to the species ……….54

40.1. Eulalia leschenaultiana (Decne) Ohwi ……..54

40.2. Eulalia trispicata (Schult.) Henrard ………..55

44. HEMARTHRIA R. Br. ...56

44.1. Hemarthria vaginata Buse. ...56

45. HETEROPOGON Pers. ...57

Key to the species ...58

45.1. Heteropogon contortus (L.) P. Beauv. ex Roem. & Schult. ...58

45.2. Heteropogon triticeus ( R. Br.) Stapf ex Craib ...59

47. HYPARRHENIA Andersson ex E. Fourn. ...60

Key to the species ...61

47.1. Hyparrhenia diplandra (Hack.) Stapf ...61

47.2. Hyparrhenia praetermissa Veldk. …...62

Key to the species ...63

49.1. Imperata conferta (J. Presl) Ohwi ...64

49.2. Imperata cylindrica (L.) Raeusch ...64

51. ISCHAEMUM L. ...66

Key to the species ...66

51.1. Ischaemum aristatum L. ...67

51.2. Ischaemum barbatum Retz. ...68

51.3. Ischaemum beccarii Hack. ...70

51.4. Ischaemum celebicum P. Jansen ...70

51.5. Ischaemum ciliare Retz. ...71

51.6. Ischaemum digitatum Brongn. ...73

51.7. Ischaemum muticum L. ...74

51.8. Ischaemum rugosum Salisb. ...75

51.9. Ischaemum timorense Kunth. ...76

51.10. Ischaemum velkampii Lasut ...77

58. MICROSTEGIUM Nees. ...79

Key to the species ...79

58.1. Microstegium eucnemis (Nees ex Steud) A. Camus ………...79

58.2. Microstegium fasciculatum (L.) Henrard ..80

58.3 Microstegium glabratum A. Camus ...81

59. MISCANTHUS Anderss. ...82

80.1. Miscanthus floridulus (Labill.) Warb. ...83

60. MNESITHEA Kunth. ...84

Key to the species ...84

60.1. Mnesithea glandulosa (Trin.) de Koning & Sosef……….. 84

60.2. Mnesithea granularis (L.) de Koning & Sosef ...85

60.3. Mnesithea laevis (Retz) Kunth ...86

62. OPHIUROS Gaertn.f. ...87

62.1. Ophiuros exaltatus (L.) Kuntze ...87

72. POGONATHERUM P. Beauv. ...89

72.1. Pogonatherum paniceum (Lam.) Hack. ...89

73. POLYTOCA R. Br. ...90

73.1. Polytoca digitata (L.f.) Druce ...91

74. POLYTRIAS Hack. ……….92

Key to the species ………...92

74.1. Polytrias indica (Houtt.) Veldk. ……... ...92

77. ROTTBOELLIA L.f. ...93

77.1. Rottboellia cochinchinensis (Lour.) Clayton ...93

79. SACCHARUM L. ...94

Key to the species ...95

79.2. Saccharum barberi Jeswiet ...96

79.3. Saccharum fastigiatum Ness ex Steud. ...97

79.4. Saccharum spontaneum L. ...98

81. SCHIZACHYRIUM Nees. ...99

Key to the species ...99

81.1. Schizachyrium brevifolium (Sw.) Nees. ....100

81.2. Schizachyrium fragile (R. Br.) A. Camus ..100

81.3. Schizachyrium pseudelalia (Hosok.) S.T. Blake ...102

82. SEHIMA Forssk. ...103

82.1. Sehima nervosum (Rottl.) Stapf. ...103

85. SORGHUM Moench. ...104

Key to the species ...105

85.1. Sorghum bicolor (L.) Moench. ...105

85.2. Sorghum laxiflorum F.M. Bailey ...106

85.3. Sorghum nitidum (Vahl.) C.E. Hubb. ...107

85.4. Sorghum propinquum (Kunth) Hitchc. ...108

89. THEMEDA Forssk. ...109

Key to the species ...109

89.1. Themeda arguens (L.) Hack. ...110

89.2. Themeda caudata (Nees) A. Camus ...111

89.3. Themeda gigantea (Cav.) Hack. ...112

89.4. Themeda intermedia (Hack.) Bor ...113

89.5. Themeda triandra Forssk. ...114

89.6. Themeda villosa (Poir.) A. Camus ...115

Tribe 2. ARISTIDEAE C.E. Hubb. ...116

Genus description and key to the species ...116

6. ARISTIDA L. ...116

Key to the species ...117

6.1. Aristida chinensis Munro ...117

6.2. Aristida cumingiana Trin. & Rupr. ...117

Tribe 3. ARUNDINEAE Dumort. ...119

Key to the genera ...119

Genus description and key to the species ...120

70. PHRAGMITES Trin. ...120

70.1. Phragmites vallatoria (L.) Veldk. …...120

78. RYTIDOSPERMA Steud. ...121

Key to the species ...122

78.1. Rytidosperma bonthainicum (P. Jansen) Veldk. ...122

78.2. Rytidosperma oreoboloides (F. Muell.) H.P. Linder ...123

Tribe 4. ARUNDINELLEAE Stapf. ...123

Key to the genera ...124

Genus description and key to the species ...124

8. ARUNDINELLA Raddi. ...124

Key to the species ...124

8.1. Arundinella goeringii Steud. ...125

8.2. Arundinella pumila (Hochst. ex A. Rich.) Steud. ...126

8.3. Arundinella setosa Trin. ...127

43. GARNOTIA Brongn. ...128

Key to the species ...128

43.1. Garnotia patula (Munro) Benth. ...128

43.2. Garotia stricta Brongn. ...129

Tribe 5. AVENEAE Dumort. ...130

Key to the genera ...131

Genus description and the species ...131

2. AGROSTIS L. ...131

2.1. Agrostis infirma Buse. ...132

4. ANTHOXANTHUM L. ...132

4.1.1. Anthoxanthum horsfieldii (Kunth ex Bennet) Mez. var. celebicum Y. Schouten ...133

26. DEYEUXIA Clarion ex P. Beauv. ...133

26.1. Deyeuxia australis (Zoll. & Mor.) P. Jansen ...134

Tribe 6. BRACHYPODIEAE Harz. ...135

Genus description and species ...135

12. BRACHYPODIUM P. Beauv. ...135

12.1. Brachypodium sylvaticum (Huds.) P. Beauv. ...136

Tribe 7. CENTOTHECEAE Ridl. ...137

Key to the genera ...137

Genus description and the species ...137

16. CENTOTHECA Desv. ...137

16.1. Centotheca lappacea (L.) Desv. ...138

56. LOPHATERUM Brongn. ...139

56.1. Lophaterum gracile Brongn. ...140

Tribe 8. CYNODONTEAE Dumort. ...141

Key to the genera ...141

Genus description and key to the species ...142

18.1. Chloris barbata (L.) Sw. ...142

23. CYNODON L. C. Richard. ...144

Key to the species ...144

23.1.Cynodon dactylon (L.) Pers. ...145

23.2.Cynodon radiatus Roth. ...146

32. ECTROSIA R. Br. ...147

32.1. Ectrosia leporina R. Br. ...147

35. ENTEROPOGON Nees. ...148

35.1. Enteropogondolichostachyus (Lag.) Keng ……….148

41. EUSTACHYS Desv. ...149

41.1. Eustachys tenera (Presl) C.E. Hubb. ...150

55. LEPTURUS R. Br. ...151

55.1. Lepturus repens (Forst.) Beauv. ...151

69. PEROTIS Aiton. ...152

Key to the species ...152

69.1. Perotis indica (L.) Kuntze …………..153

69.2. Perotis hordeiformis Nees. ...153

93. ZOYSIA Willd. ...154

Key to the species ...155

93.1.Zoysia matrella (L.) Merr. ...155

93.2.Zoysia pasifica (Goudswaard) M. Hotta& Kuroki ...155

Tribe 9. EHRHARTEAE Nevski. ...156

Genus description and the variety ...156

33. EHRHARTA Thunb. ...156

33.1.1. Ehrharta diplaxvar. giulianettii (Stapf.) L.P.M. Willemse ...157

Tribe 10. ERAGROSTIDEAE Stapf. ...157

Key to the genera ...158

Genus description and key to the species ...158

25. DACTYLOCTENIUM Willd. ...158

25.1. Dactyloctenium aegyptium (L.) Willd. ....159

34. ELEUSINE Gaertn. . . ...160

Key to the species ...161

34.1.Eleusine coracana (L.) Gaertn. ...161

34.2.Eleusine indica (L.) Gaertn. ...162

36. ERAGROSTIS N.M. Wolf. ...163

Key to the species ...164

36.1.Eragrostis amabilis (L.) Wight & Arn. ex Nees ...165

36.2.Eragrostis atrovirens (Desf.) Trin. ex Steud. ...166

36.3.Eragrostis brownii (Kunth) Nees ex Steud

...167

36.4.Eragrostis cilianensis (Bellardi) Vignolo ex Janch. ...168

36.5.Eragrostis cumingii Steud. ...169

36.6.Eragrostis dyskrytos Lasut, sp. nov. ...170

36.7.Eragrostis japonica (Thunb.) Trin. ...172

36.8.Eragrostis lasioclada Merr. ...173

36.9.Eragrostis minor Host. ...174

36.10. Eragrostis pilosa (L.) P. Beauv. ...175

36.11. Eragrostis tenuifolia (A. Rich) Hochst. ex Steud. ...175

36.12. Eragrostis unioloides (Retz.) Nees ex Steud. ...176

36.13.Eragrostis warburgii Hack. ...177

54. LEPTOCHLOA P. Beauv. ...178

Key to the species ...178

54.1. Leptochloa chinensis (L.) Nees ...179

54.2. Leptochloa panicea (Retz.) Ohwi …...179

61. MUHLENBERGIA Schr. ...181

61.1. Muhlenbergia huegelii Trin... 181

87. SPOROBOLUS R. Br. ...182

Key to the species ...183

87.1. Sporobolus humilis J. Presl. ...183

87.2. Sporobolus indicus (L.) R. Br. ...183

87.3. Sporobolus tenuissimus (Mart. ex Schrank) Kuntze ...184

87.4. Sporobolus virginicus (L.) Kunth. ...185

Tribe 11. ERIACHNEAE (Ohwi) Eck-Boorsb ...186

Genus description and the species ...186

38. ERIACHNE R. Br. ...186

38.1. Eriachne pallescens R. Br. ...186

Tribe 12. ISACHNEAE Benth. ...187

Genus description and key to the species ...188

50. ISACHNE R. Br. ...188

Key to the species ...188

50.1. Isachne albens Trin. ...189

50.2. Isachne albomarginata P. Jansen ...190

50.3. Isachne brassii Hitch. ...191

50.4. Isachne confusa Ohwi ...191

50.5. Isachne globosa (Thunb.) Kuntze ...192

50.6. Isachne kunthiana (Wight & Arn. ex Steud Nees ex Miq. ...193

50.7. Isachne minutula (Gaudich.) Kunth ...194

50.8. Isachne myosotis Nees ...195

50.9. Isachne pulchella Roth ex Roem. ...196

50.10. Isachne pangerangensis Zoll. & Mor. ..197

50.11. Isachne stricta Elmer ...198

50.12. Isachne surgens P. Jansen ...198

Tribe 13. ORYZEAE Dumort. ...199

Key to the genera ...199

Genus description and the species and variety ...199

52. LEERSIA Sol. ex Swartz ...199

52.1. Leersia hexandra Swartz ...200

64. ORYZA L. ...201

64.1.1. Oryza minuta J. Presl. var. sylvatica (Camus) Veldk. …...201

Tribe 14. PANICEAE R. Br. ...202

Key to the genera ...202

Genus description and key to the species ...204

1. ACROCERAS Stapf. ...204

1.1. Acroceras munroanum (Balansa) Henrard ...205

3. ALLOTEROPSIS J. Presl. ...205

3.1. Alloteropsis semialata (R. Br.) Hitch. ...206

10. AXONOPUS P. Beauv. ………....207

10.1. Axonopus compressus (Sw.) P. Beauv. ………...208

15. CENCHRUS L. ...209

15.1. Cenchrus brownii Roem. & Schult. ...209

24. CYRTOCOCCUM Stapf. ...211

Key to the species ...211

24.1. Cyrtococcum accrescens (Trin.) Stapf. 211 24.2. Cyrtococcum oxyphyllum (Hochst.) Stapf. ...212

24.3. Cyrtococcum patens (L.) A. Camus ...213

29. DIGITARIA Haller. ...214

Key to the species ...215

29.1. Digitaria abludens (Roem. & Schult.) Veldk. …...216

29.2. Digitariabicornis (Lam.) Roem. & Schult ...217

29.3. Digitaria ciliaris (Retz.) Koeler ...218

29.4. Digitaria fuscescens (Presl.) Henrard ...219

29.5. Digitaria junghuhniana (Steud.) Henrard ...220

29.6. Digitaria longiflora (Retz.) Pers. ...220

29.7. Digitaria milanjiana (Rendle) Stapf. ...221

29.8. Digitaria radicosa (J. Presl) Miq. ...222

29.9. Digitaria sanguinalis (L.) Scop. ...223

29.10. Digitaria setigera Roem. & Schult. ....224

29.10.1. Digitaria setigera Roth. var. callible- pharata (Henrard) Veldk. …...225

29.11. Digitaria ternata (A. Rich.) Stapf. ...226

29.12. Digitaria violascens Link. ...227

31. ECHINOCHLOA P. Beauv. ...228

Key to the species ...229

31.1. Echinochloa colona (L.) Link. ...229

31.2. Echinochloa crus-galli (L.) P. Beauv. ..230

31.3. Echinochloa stagnina (Retz.) P. Beauv 231 39. ERIOCHLOA Kunth. ...233

39.1. Eriochloa procera (Retz.) C.E. Hubb. .233 46. HYMENACHNE P. Beauv. ...234

46.1. Hymenachne amplexicaulis (Rudge) Nees ...234

48. ICHNANTHUS P. Beauv. ...235

48.1.1. Ichnanthus pallens (Sw.) Munro ex Benth. ………...236

57. MELINIS P. Beauv. ...236

57.1. Melinis repens (Willd.) Zizka ...237

63. OPLISMENUS P. Beauv. ...238

Key to the species ...238

63.1. Oplismenus aemulus (R. Br.) Roem ex Schult. ...239

63.2. Oplismenus burmannii (Retz.) P. Beauv ...239

63.3. Oplismenuscompositus (L.) P. Beauv. 240 63.4. Oplismenus hirtellus (L.) P. Beauv. ....241

65. OTTOCHLOA Dandy ...242

65.1. Ottochloa nodosa (Kunth) Dandy ...242

66. PANICUM L. ...243

Key to the species ...244

66.1. Panicum auritum J. Presl. ex Nees ...244

66.2. Panicum bisulcatum Thunb. ...245

66.3. Panicum luzonense J. & C. Presl. ...246

66.4. Panicum notatum Retz. ...247

66.5. Panicum paludosum Roxb. ...247

66.6. Panicum repens L. ...248

66.7. Panicum sarmentosum Roxb. ...249

67. PASPALUM L. ...251 Key to the species ...252

67.1. Paspalum conjugatum P.J. Bergius ....252 67.2. Paspalum longifolium Roxb. ...253 67.3. Paspalum orbiculare G. Frost. ...254 67.4. Paspalum scrobiculatum L. ...254 67.5. Paspalum vaginatum Sw. ...255 68. PENNISETUM Rich. ...256 Key to the species ...257

68.1. Pennisetum ciliare (L.) Link. ...257 68.2. Pennisetum macrostachys (Brongn.)

Trin. ...258 68.3. Pennisetum purpureum Schum. ...259 75. PSEUDECHINOLAENA Stapf. ...260

75.1. Pseudechinolaena polystachya (Kunth) Stapf. ...260 76. PSEUDORAPHIS Griff. ...261 76.1. Pseudoraphisspinescens (R. Br.) Vickery

...261 80. SACCIOLEPIS Nash. ...262

Key to the species ...263 80.1. Sacciolepis indica (L.) Chase ...263 80.2. Sacciolepis myosuroides (R. Br.) Chase

...264 84. SETARIA P. Beauv. ...264 Key to the species ...265 84.1. Setaria barbata (Lam.) Kunth. ...265 84.2. Setaria clivalis (Ridl.) Veldk. ...266 84.3. Setaria flavida (Retz.) Veldk. …...267 84.4. Setaria palmifolia (J. Koenig) Stapf. ..268 84.5. Setaria parviflora (Poir.) Kergeulen ...269 84.6. Setaria punctata (Burm.f.) Veldk. …. 270 84.7. Setaria verticillata (L.) Beauv. ...271 86. SPINIFEX L. ...272 Key to the species ...272

86.1. Spinifex littoreus (Burm.f.) Merr. ...272 86.2. Spinifex longifolius R. Br. ...273

88. STENOTAPHRUM Trin. ...274 88.1. Stenotaphrum secundatum (Walt.)

Kuntze ...275 90. THUAREA Pers. ...275 90.1. Thuarea involuta (G. Forst.) Roem. &

Schult. ...276 92. UROCHLOA P. Beauv. ...277 Key to the species ...277

92.1. Urochloa glumaris (Trin.) Veldk. ….. 277 92.2. Urochloa maxima Jacq. ...278 92.3. Urochloa mutica (Forssk.) T.-Q Nguyen

...279 92.4. Urochloa reptans (L.) Stapf. ...280 92.5. Urochloa subquadripara (Trin.) R.D.

Webster ...281 Tribe 15. PHAREAE Stapf. ...282

Key to the genera ...282 Genus description and key to the species ...282 53. LEPTASPIS R. Br. ...282 Key to the species ...283

53.1. Leptaspis banksii R. Br. ...283 53.2. Leptaspis zeylanica Nees ex Steud. ...284 83. SCROTOCHLOA Judz. ...285 83.1. Scrotochloa urceolata (Roxb.) Judz. 286 Tribe 16. POEAE R. Br. ...287 Key to the genera ...288 Genus description and the species ...288 13. BRIZA L. ...288 13.1. Briza minor L. …...288 42. FESTUCA L. ...289 42.1. Festuca leptopogon Stapf. ...290 71. POA L. ...290 Key to the species ...291 71.1. Poa celebica Ohwi ex Veldk. …...291 71.2. Poa epileuca (Stapf.) Hitch. ...292 71.3. Poa papuana Stapf. ...293 Tribe 17. THYSANOLAENEAE C.E. Hubb. ...294 Genus description and the species ...294 91. THYSANOLAENA Nees ...294 91.1. Thysanolaena latifolia (Roxb. ex

Hornem) Honda ………...295 CONCLUSIONS ...297

TABLE

Page 1. The number of tribes, genera, species, and endemic species/variety

LIST OF FIGURES

page 1. Ischaemum veldkampii Lasut (Based on Lasut 994 BO) ...78 2. Eragrostis dyskritos Lasut (Based on Sabintoe 36 L) ...171

HISTORICAL INTRODUCTION

The grass family is one of the largest flowering plants next only to the Compositae, Orchidaceae, and Leguminosae (Brummitt, 1992). However, in terms of individual numbers, the grasses are most abundant and most widely distributed seed families (Keng, 1978). There are few habitats in which grasses do not occur naturally, and their range is only restricted by alpine or arctic cold on one hand and the intense shade of some tropical forests and drought of desert areas on the other. It is not surprising that the grass family has diversified into a rich array of variously modified and adapted forms (Tothill and Hacker, 1973).

According to Brummitt (1992), the grass family in the world consists of 657 genera. Almost all of these genera are widespread from the tropic region to the subtropic region. The Malesian Key Group (2004) have noted that in Malesia the family consists of about 150 grasses genera which occurred from sea level to alpine zone. For Malesian area so far, no comprehensive floristic account is available. Partial floras have been published for Java (1968) by Backer and Bakhuizen, Papua New Guinea (1969) by Henty, and Malay Peninsula (1971) by Gilliland. Accordingly an attempt is made to undertaken floristic study of herbaceous grasses in Sulawesi.

Based on present study – the preparation of the herbaceous grasses flora for Sulawesi, it is concluded that the grasses of Sulawesi should be accommodated in 93 genera with 212 species and 4 varieties. Sulawesi comprises of about 182.870 km2 of land (Keßler, et al., 2002) and fewer botanical specimen – 23 specimens each 100 km2 have been placed in herbaria whereas over 200 specimens each 100 km2 are known from Java (Whitten, et al., 1987). A density of 100 specimens each 100 km2 would be represents an adequately-known flora.

The Grass Plant

Grasses are so different from most other plants that special of terms have been devised to their vegetative and generative structures. The vegetative parts of the grass plant are superficially rather uniform. Moreover, within certain limits, the most obvious differences of size, color, and hairiness are strongly influenced by

environmental factors. As a result the use of vegetative characters for the identification of grasses is rather limited (Tothill and Hacker 1973). In ordinary flowering plants, the unit of floral structure is the flower – its sepals, petals, stamens and ovary. Such flowers are either borne singly, or more usually on special branches or branch-system known as inflorescences. Each flower is in the axil of leaf; and if the leaf is small, it is called a bract. Grasses also have inflorescences, but the units are not ordinary flowers. They are seen as little groups of small overlapping greenish, brownish or purplish bracts (sometimes hairy) from between which the stamens and stigmata emerge. Each group of bracts is separately stalked, and is called a spikelet, and they arranged very much in the same way as flowers are arranged in an ordinary inflorescence (Gilliland 1971).

The vegetative parts of a typical grass plant are comprising the following:

Culm: This is the elongated stalk which bears leaves and eventually at its apex, the inflorescense. It consists of a series of nodes and internodes, each node subtending a leaf alternately on either side of the culm. Nodes: In tufted grasses these only become apparent after the commencement of culm elongation when they are seen as small annular lumps or sometimes concavities, often pigmented and sometimes with a collar of hairs associated with them. Many grasses have creeping stems, called rhizomes if below ground or stolon if above, and on such stems nodes are apparent all the time.

The leaf is conveniently separated into three parts, the leaf sheath, ligule, and leaf blade. In the vegetative phase the leaf sheaths are telescoped one inside the other and are thus only fully apparent on the lowermost leaves. Leaf sheaths: This lower part of the leaf variously encloses the internodes above the node from which its originates. The internodes may or may not extend beyond the sheath. The sheaths may or may not be hairy, striate, or persistent at maturity, and show various modifications such as swollen bases and greater or lesser degrees of roundness in section or flattening and keeling along the mid-nerve. Frequently they enclose young axilarry shoots, although these may break through the sheath at its base. Generally axilarry shoots are formed only from lower nodes and hence in lower leaf sheaths, but the number of grasses also branch extensively or even predominantly from upper nodes.

Ligule: This structure lies at the point of junction of the sheath with the blade. It may be absent or present in various degrees as a collar of hairs or a membranous rim. Although it is of considerable value in separating broads groups of grass genera, it is rarely useful in distinguishing between different species of the same genus. The long membranous ligules is found predominantly in temperate grasses and is less often found in the predominantly tropical grasses. Leaf blade: This is generally a parallel-nerved, linear structure although in some very short-leaved species the blades may be relatively broad. The blade may be flat, folded, or rolled, hairy or hairless, rough or smooth, green or bluish, and of various shapes from narrow to broad in relation to length, parallel-sided or tapering, with points long and slender, abrupt or boat-shaped.

The flowering parts (inflorescence) of the grass plant are a composite structure comprising various patterns of aggregation of the basic floral unit, the spikelet. Most commonly the inflorescence is a panicle of more or less open-branched structure. Less commonly the inflorescence is a spike (a single axis upon along which are borne sessile or stalk-less spikelet). However, some panicles have their branches so reduced that they may appear to be spikes. Racemes (a single axis upon which are borne single pedicelled or stalked spikelets) are less common. However, a multitude of combinations of these various forms exists. The gross form of the inflorescence is popularly used in recognizing many different grass species or groups of species.

Spikelet: This is the basic floral unit which incorporates one or more flowers or florets. The one or more florets are partially enclosed by bract-like husks or glumes. Basically there are two glumes, which may be variously modified in size, shape, texture, nerve number, hairiness, and other elaborations, even to the extent of being variously absent, and they are very useful in identification. Although in many grasses different spikelet’s in the same inflorescence are all more or less similar, some of grasses have spikelets which differ in form and sex and are associated in pairs or, as a more extreme degree of specialization, the different spikelets may occur in different parts of the inflorescence. More rarely the different spikelet occurs on different inflorescence or different inflorescences or different plants. Floret: Each floret is enclosed by two more bract-like husks, the lemma with a variable number of nerves, and the palea,

usually with two nerves, though sometimes 1-nerved or nerveless, occasionally 3- or 4-nerved. These show much the same series of modifications as the glumes. When a spikelet basically contains more than one floret, the florets alternate along the axis in a continuous sequence above the glumes and may be relatively and variously modified in their sexual parts and also display a wide range of variation in the relative modifications of the lemmas and paleas. A fertile floret contains an ovary, which is best seen by the presence of stigmas, with or without male parts or anthers. A male floret is devoid of ovary and is reduced only to the male parts or anthers. In both cases the usual anther number is 3 but may occasionally be 1, 2, 4, or 6. A sterile floret is devoid of all sexual parts and both lemma and palea may be severely reduced and modified. Just as spikelets differ in form and function and are often characteristically associated in pairs, of dissimilar florets occur in the same spikelet, for example with a lower male or neuter floret and an upper female or bisexual floret, the florets being modified according to their differing functions. When this modification takes the form of extreme reduction or loss of paleas combined with the loss of one glume, care is needed in the identification of the various parts of the spikelet (Tothill and Hacker 1973).

The Explorations of Grasses in Sulawesi

Based on the notes on specimen kept in Herbarium Bogoriense, exploration of grasses in Sulawesi was began by the work of Koorders in 1895. After that, many other explorers and collectors from several areas. Notable among them are:

1. J. Elbert. Worked at South Sulawesi in 1909.

2. L. van Vurren & Noerkas. Worked at Pare-Pare in 1912. 3. W. M. van Leeuwen. Worked at “Seleier Island” in 1913. 4. V. M. A Beguin. Worked at Manado in 1920.

5. H.A.B. Bunnemeijer. Worked at Mts. Bonthain in 1921. 6. S. Leefmans. Worked at North Sulawesi in 1924.

7. H. J. Lam. Worked at Miangas, Sangir Talaud Islands in 1926. 8. G. K. Kjellberg. Worked at Enrekang in 1929.

9. O. Posthumus. Worked at Donggala, Palu, and Mt. Bonthain in 1930 10. A. Rant. Worked at Malino in 1931

11. L. J. Toxopeus. Worked at South Sulawesi in 1936

12. C. G. G. J. van Steenis. Worked at South Sulawesi in 1937. 13. P. J. Eyma. Worked at South Sulawesi in 1937.

14. S. Bloembergen. Worked at South Sulawesi in 1939. 15. A. H. G. Alston. Worked at Tomohon, Minahasa in 1954. 16. S. Soenarko. Worked at Maros in 1974.

17. W. Meijer. Worked at Palu in 1975.

18. E. A. Widjaja. Worked at Pare-pare in 1977.

19. M. M. J. van Balgooy and E. F. de Vogel. Worked at Central Celebes in 1979.

MATERIAL AND METHODS

This study was conducted from 2004 – 2008. The research materials are herbarium specimen, kept at the following herbaria: Herbarium Bogoriense (BO), Herbarium Leiden (L), Herbarium Wallaceana (WALL), Herbarium Biotrop (Biot), and collected fresh specimens from the field. The equipment used in collecting, preserving, and studying specimens are: scissors and scateurs, double flimsy (‘specimen folder’), press frames, press straps, corragurated sheets, paper or mesh bags, cardboard supports, plastic bottles, polytene bags, adhesive tape and string, alcohol, hand lens, compass, altimeter, fine mounted needles, fine forceps, sharp scalpel with fine point, small paint brush, and watch-glass or petridish (Forman and Bridson 1989).

Procedure

This research used explorative and descriptive method, according to the following steps: 1) collecting the specimens from the fields; 2) study of existing grasses already available in the herbaria; 3) identify and describe examined specimens; 4) defining the taxa accepted; 5) validation names and determined the status of taxon; 6) writing descriptions and illustrations; 7) and preparing the final draft flora.

Locations

The areas especially visited in: Tomohon and adjacent area (2004), including Mts. Mahawu (Alt. 1400 m), Mts. Masarang (Alt. 1300 m); Langoan and adjacent area, including Mts. Kawatak (Alt. 1450 m), Mts. Soputan (Alt. 1600 m); Tondano and adjacent area, including Mts. Lembean (Alt. 1290 m); Airmadidi and adjacent area, including Mts. Kalabat (Alt. 1990 m); Batu Putih and adjacent area, including

Tangkoko Nature Reserve; Modoinding and adjacent area, including Mts. Ambang (Alt. 1350 m).

Gorontalo (2005), Suwawa and adjacent areas, Pinogu enclave in Bogani Nani Wartabone National Park, including Mts. Gambuta (Alt. 1950 m); Paguyaman and adjacent area, including Nantu Adudu Nature Reserve.

Palu and adjacent areas (2005), including Mts. Nokilalaki (Alt. 2260 m); Toro and adjacent area; Doda valley and adjacent area, including Mts. Pohupaia (Alt. 1950 m).

Makassar and adjacent area (2005), including Bantimurung Bulusaraung National Park; Rantelemo and adjacent area, including Mts. Rantemario (Alt. 3465 m); Lembangbune and adjacent area, including Mts. Lompobatang (Alt. 2900 m).

Kendari and adjacent area (2005), including Rawa Aopa Watumohai National Park; Kolaka and adjacent area, including Mts. Mekongga (Alt. 2750 m).

Description of taxa

Floristic is a study of floras, with the main objective to inventorize and to provide a tool to identify the grass from this study area (Rifai 1976). Description of taxa in this study include vegetative and reproductive features, place of growth or habit, and distribution, along with pertinent synonymy used in others floras, and references to the taxonomy of the included taxa (Radford 1986). All species of Sulawesi herbaceous grasses found in the wild – not cultivated are described and provides a source of information of those taxa – current taxonomy statues, distribution, and habitat.

RESULTS AND DISCUSSIONS The classification of Sulawesi grasses

The results of this study indicates that, there are 17 tribes with 93 genera from 212 species and 4 varieties of herbaceous grasses existing in Sulawesi island (Table 1). The tribes are Andropogoneae, Aristideae, Arundineae, Arundinelleae, Aveneae,

Brachypodieae, Centotheceae, Cynodonteae, Ehrharteae, Eragrostideae, Eriachneae,

Isachneae, Oryzeae, Paniceae, Phareae, Poeae, and Thysanolaeneae. As a comparison the Malay Peninsula and Papua New Guinea have 13 tribes and 19 tribes; China, Taiwan, and Australia have 28, 27 and 26 tribes respectively.

Based on the size of taxa recognized in Sulawesi, the Andropogoneae is the largest one with 35% of genera, followed by the Paniceae 25%, Cynodonteae 8%,

Eragrostideae 6%, Aveneae and Poeae 3%, Arundineae, Arundinelleae, Centotheca,

Oryzeae, and Phareae 2%, the others tribes with 1%.

In the world there are 87 genera of the Andropogoneae, distribution throughout the tropics into warm regions. The largest tribes in Sulawesi is Andropogoneae, which is consists of 33 genera and 70 species.

The Paniceae consists of 86 genera, throughout the tropics, extending into warm temperate regions. This is the second largest tribe in Sulawesi with 24 genera and 60 species.

The Cynodonteae consists of c. 23 genera; worldwide distribution, and more predominant in tropical areas. It is a third largest tribe in Sulawesi with 8 genera and 11 species.

The Eragrostideae consists of c. 26 genera; throughout the tropics. The fourth largest tribe in Sulawesi with 6 genera and 23 species.

The Aveneae and Poeae, each has 3 genera, with 2 species and 1 variety in the first, and the second with 5 species and 1 variety. The Aveneae consists of 60 genera, temperate and cold regions of the worlds, extending to the mountains in the tropic. The Poeae consists of 50 genera, temperate and cold regions in the worlds, also found in tropical mountain.

Table 1. Number of tribes, genera, species, and endemic species/variety of herbaceous grasses in Sulawesi.

No Tribes Name of the Genera No. of Genus

No. of Species

Endemic Species * /Variety** 1 Andropogoneae Apluda, Arthraxon, Asthenochloa,

Bothriochloa, Capillipedium,

Chionachne, Chrysopogon, Coelorachis, Coix, Cymbopogon, Dichantium, Diectomis, Dimeria, Eremochloa, Eulalia, Hemarthria, Heteropogon, Hyparrhenia, Imperata, Ischaemum, Microstegium, Miscanthus, Mnesithea, Ophiuros, Pogonatherum, Polytoca, Polytrias, Rottboellia, Saccharum, Schizachyrium, Sehima, Sorghum, Themeda.

33 73 4*

2 Aristideae Aristida 1 2

3 Arundineae Phragmites, Rytidosperma 2 3 1*

4 Arundinelleae Arundinella, Garnotia 2 5

5 Aveneae Agrostis, Anthoxanthum, Deyeuxia 3 2 1**

6 Brachypodieae Brachypodium 1 1

7 Centotheceae Centotheca, Lophatherum 2 2

8 Cynodonteae Chloris, Cynodon, Ectrosia, Enteropogon, Eustachys, Lepturus, Perotis, Zoysia

8 11

9 Ehrharteae Ehrharta 1 1

10 Eragrostideae Dactyloctenium, Eleusine, Eragrostis,

Leptochloa, Sporobolus, Muhlenbergia 6 23 1*

Notes: * Endemic species and ** Endemic variety

The Arundineae, Arundinelleae, Centotheceae, Oryzeae, and Phareae are the tribes with 2 genera and have respectively 3, 5, 2, 2, and 3 species. The Arundineae

consists of 25 genera, is found as a tribe with cosmopolitan distribution; the

Arundinelleae consists of 9 genera, found in the tropics, often favouring infertile soils; the Centotheceae consists of 10 genera, mainly in the tropics, in shading places; the

Oryzeae consists of 7 genera, found in tropical and warm temperate region throughout the world; the Phareae consists of 2 genera, found on both hemisphere.

The Aristideae, Brachypodieae, Ehrharteae, Eriachneae, Isachneae, and

Thysanolaeneae are the tribes with only have 1 genera in Sulawesi. The Isachneae

have 12 species, the Eriachneae and Thysanolaeneae just have 1 species in Sulawesi. In the world Aristideae have 2 genera, found in tropic and subtropic, often in dry climate, or on poor soils; Brachypodieae have 1 genus, found in Europe and Asia, African highlands, and Central America; Ehrharteae have 3 genus, found on warm temperate regions of the Old World, mainly in Australia and South Africa; Eriachneae

have 2 genera, mainly in Australia, a few species extending into South and Southeast Asia; Isachneae have 5 genera, found in the tropics, mainly in Asia; Thysanolaeneae

have 1 genus, found in tropical Asia, including China.

12 Isachneae Isachne 1 12

13 Oryzeae Leersia, Oryza 2 1 1

14 Paniceae Acroceras, Alloteropsis, Axonopus, Cenchrus, Cyrtococcum, Digitaria, Echinochloa, Eriochloa, Hymenachne, Ichnanthus, Melinis, Oplismenus, Ottochloa, Panicum, Paspalum, Pennisetum, Psedechinolaena, Pseudoraphis, Sacciolepis, Setaria, Spinifex, Stenotaphrum, Thuarea, Urochloa

24 67 1

15 Phareae Leptaspis, Scrotochloa 2 3

16 Poeae Briza, Festuca, Poa 3 5 1*

17 Thysanolaeneae Thysanolaena 1 1

Endemic taxa and their distribution in Sulawesi

The Poaceae is one of the largest and most widespread of the families of flowering plants. There are only a few places or habitats in which grasses do not occur naturally, and their range is only restricted by alpine or arctic cold on the one hand and the intense shade of some tropical forests and drought of desert areas on the other (Tothill and Hacker 1973). It is hence not surprising that the grass family has diversified into a rich array of variously modified and adapted forms.

Based on 212 species and 4 varieties occurring in Sulawesi, there are 7 endemic species and 1 endemic variety. These mainly montane endemics belonging to the temperate genera, supporting the opinion of Steenis (1933) that in the tropics such as Malesia these are restricted to the mountains and represent only small offshoots from their generic centers. If compared with China, with 1795 species of grasses and 809 species are endemic, the number of endemic taxa in Sulawesi is very low, this is because of many endemics are confined to the temperate regions of the mountains in China (FOC 2006).

South Sulawesi exhibits the highest degree of endemic species if compared with the other parts of Sulawesi, apparently due to the considerable areas of high mountains. There are one endemic variety and five endemic species in this area –

Anthoxanthum horsfieldii (Kunth ex Bennet) Mez. var. celebicum Y. Schouten;

Hyparrhenia pratermissa Veldk., Ischaemum celebicum P. Jansen, Ischaemum veldkampii Lasut, Poa celebica Ohwi ex Veldk., and Rytidosperma bonthainicum (P. Jansen) Veldk. All endemic taxa above concentrated in Latimojong ridge (Mts. Rantemario) and Lompobatang Mountain.

North Sulawesi has only one endemic species – Eragrostis dyskritos Lasut, which is found in Mounts Soputan. This species is a new for science (in preparation to publish).

Central Sulawesi also has one endemic species – Cymbopogon minutiflorus S. Dransf., found in Donggala area on the slopes of limestone hills.

This study found that about 11 percent of herbaceous grasses in Sulawesi are new records to Sulawesi. From 212 species and 4 varieties found in this island, there are 25 species as new records to this island.

Ichnanthus pallens (Sw.) Munro ex Benth., found in North and Central Sulawesi at secondary forest and opened area. Usually found at more than 1000 m above sea level. This species is found in South America, North America, India, China, Vietnam, Thailand, Burma, Taiwan, Malaysia, Philippine, Papua New Guinea, Papua, and Java.

The Isachne have 4 species as a new records. Those are Isachne brassii Hitch.,

Isachne confusa Ohwi, Isachne kunthiana (Wight & Arn. ex Steud) Nees ex Miq., and

Isachne pangerangensis Zoll. & Mor. This genus found in Asia tropical.

The other new records of herbaceous grasses in Sulawesi are as following:

Oplismenus aemulus (R. Br.) Roem. ex Schult., this species found in America, Australia, New Guinea, Taiwan,and Malesia; Muhlenbergia huegelii Trin., found in India, China, Taiwan, Nepal, Japan, and Malesia, usually found at high altitude;

Panicum luzonense J. & C. Presl., and Panicum curviflorum Hornem, found in Malesia, Indo-China, Sri Lanka, India, China, Africa, and United states of America;

Paspalum orbiculare G. Frost, found from India, Australia, Hawaian islands, Taiwan, America, Borneo, and Sumatera; Perotis indica (L.) Kuntze, and Perotis hordeiformis

Nees, found in India, Nepal, Indo-China, China, Philippine, and Pakistan; Eragrostis minor Host, have a wide range of distribution, from Africa to Europe, and from Asia to America; Melinis repens (Willd.) Ziska, it is another widespread species, found in Africa, Asia, Australia, Caribean, and America; Setaria clivalis (Ridl.) Veldk., found in Christmas island, Java, Lesser Sunda Islands, Philippines, and Sumatra; Digitaria bicornis (Lam) Roem. & Schult., found in America, India, Australia, and Asia;

Polytrias indica (Houtt.) Veldk., found in Carribean, Colombia, Costa Rica, Guatemala, India, Timor, Java, Panama, Suriname, United States of America, Australia, China, and Africa; Saccharum fastigiatum Nees ex Steud., found in India, and Malesia; Sorghum laxiflorum F.M. Bailey, found in Australia, Papua New Guinea;

Spinifex longifolius R. Br., found in Australia, Malaysia, Papua New Guinea;

Carribean, and Paraguay; Cymbopogon procerus (R. Br.) Domin, found in Papuasia, and Australia; Cyrtococcum oxyphyllum (Hochst.) Stapf., found in Australia, Burma, India, Malaysia, Sri Lanka, Africa, China, Indo-China; Ectrosia leporina R. Br., found in Papua New Guinea, and Australia; and Microstegium eucnemis (Nees ex Steud.) A. Camus, found in Indo-China, and Burma.

Taxonomi

POACEAE Barnhart. nom. cons., Bull. Torrey Bot. Club 22: 7. 1895. nom. alt., Gramineae Juss, Based on Tribe Poeae R. Br. Voy. Terra Austr. 2: 582. 19 Jul

1814.

Annual or perennial herbs, sometimes with rhizomes or stolons. Culms erect, ascending, or creeping, usually branched at the base, in perennials with sterile shoots and flowering culms mixed, in annuals only the latter present; cylindrical, rarely flattened, jointed, usually hollow in the internodes; branches arises singly from nodes and subtended by a leaf sheath and 2-keeled prophyll. Leaves arranged alternately in 2 ranks, differentiated into sheath, blade and an adaxial erect appendage at sheath/blade junction – ligule; leaf sheath surrounding and supporting culm-internode, split to base or infrequently tubular partially or completely fused margins; leaf blades divergent, usually long, narrow and flat, but varying from inroled and filiform to ovate, nerves parallel; ligules membraneous, or a line of hairs. Inflorescence terminal or axillary, an open, contracted, or spikelike panicle, or composed of lax to spikelike racemes arranged along an elongate central axis, or digitate, paired, or occasionally solitary; axillary inflorescence often many, subtended by spatheoles and gathered into a leafy compound panicle. Spikelets composed of distichous bracts arranged along rachilla (a slender axis); typically 2 lowest bracts (glumes) empty, subtending 1 to many floret. Florets composed of 2 opposing bracts enclosing a single small flower, outer bract – lemma clasping the more delicate, usually 2-keeled inner bract – palea; base of floret often thickened prolongation articulated with articulated with rachilla – callus; lemma often with apical or dorsal bristle/awn, glumes sometimes awned. Flowers bisexual or unisexual; lodicules – small scales representing perianth 2, rarely 3 or absent, hyaline

or fleshy; stamens 3, rarely 1, 2, 6, hypogenous, filaments capillary, anthers versatile; ovary 1-celled, styles 1, or 2, rarely 3, free to united at the base, topped by feathery stigmas, exserted from sides or apex of floret. Fruit mostly caryopsis with a thin pericarp adnate to the seed, rarely with a free seed; caryopsis commonly combined with various parts of the spikelet, or less often the inflorescence, to form a false fruit; seed with starchy endosperm, an embryo at the base of the abaxial face, and a point or line – hilum on the base of adaxial face marking the connection between pericarp and seed.

Key to the tribes

1.a. Spikelets paired, sessile and pedicellate spikeletes………..2 b. Spikelets singly in panicles or racemes………4 2.a. Spikelets persistent ...4. Arundinelleae b. Spikelets deciduous ………...3 3.a. Glumes thinner than fertile floret; lower glumes short or suppressed; fertile floret

papery to crustaceous or leathery, without awn …………14. Paniceae

b. Glumes as long as spikelets, tougher and enclosing hyaline florets; fertile floret usually with geniculate awn ………...……….1. Andropogoneae

4.a. Spikelets with 2 or more fertile florets ………5 b. Spikelets with 1 fertile florets, sometimes with additional staminate or barren

florets ……….11 5.a. Inflorescence of one or more racemes ……….6 b. Inflorescence a panicle, open, contracted, dense, and spikelike ……….8 6.a. Ligule a line of hairs; lemmas 1-3-nerved ……….10. Eragrostideae b. Ligule membraneous; lemmas 5 or more nerved ………7 7.a. Spikelets placed broadside to rachis; both glumes present; ovary with hairy

apical appendage ……….6. Brachypodieae b. Spikelets placed edgeways to rachis; lower glume absent (except terminal

spikelet); ovary glabrous ………...16. Poeae 8.a. Spikelets with 2 florets, without rachilla extension ....………...9 b. Spikelets with several florets, with rachilla extension ………...10 9.a. Lemmas entire, without awn, glabrous or puberulous ………...12. Isachneae b. Lemmas bi-toothed, awn from sinus, densely hispid………...11. Eriachneae 10.a. Culms reed-like, usually tall; panicle large, plumose; blades articulated with with

sheath ……….………...3. Arundineae b. Culms mostly slender, if tall than not reed-like, panicle not large ………… ...7. Centotheceae 11.a. Glumes absent or both very short ………..12 b. Glumes well developed ……….13 12.a. Spikelets in umbellate cluster ………5. Aveneae b. Spikelets in panicle ………..13. Oryzeae

13.a. Spikelets unisexual; female spikelet inflated, shell- or urn-shaped …….…. ………...15. Phareae b. Spikelets bisexual ………..14

14.a. Blades with cross nerves, linear to ovate ………17. Thysanolaeneae b. Blades without cross nerves, narrow ……….15

15.a. Inflorescence composed of one or more racemes; rachis tough; glumes opposite ………...8. Cynodonteae

b. Inflorescence an opened, contracted, or spikelike panicle ………16 16.a. Spikelets with 1 to several floret; lemma with 3 awns …………2. Aristideae b. Spikelets with 3 florets; lower lemma enclosing fertile floret …9. Erharteae

Tribe 1. ANDROPOGONEAE Dumort. Observ. Gramin. Belg. 84, 90, 141. 1824. Type: Andropogon L. Sp. Pl. 2: 1045. 1753.

Coiceae Nakai. Ord. Fam. Prof. Nakai, Edita App. 223. 1943; Contr. U.S. Natl. Herb. 41: 7-8. 2003.

Imperateae Gren. & Godr. Fl. France Prosp. 3: 471. 1855.

Rottboellieae Kunth. Revis. Gramin. 1: 150. 1829.

Sacchareae Rchb. Consp. Regn. Veg. 48. 1828; Contr. U.S. Natl. Herb. 48: 12-14. 2003.

Plants annual, or perennial. Blades linear, rarely lanceolate or filiform. Ligule

membraneous, rarely ciliate. Inflorescence composed of fragile (infrequently tough) racemes, these arranged in a terminal panicle with elongate central axis, or more frequently sub-digitate, paired or solitary, often axillary, subtended by spathes and spatheoles and gathered into a compound panicle. Racemes usually bearing paired spikelets, rarely spikelets single or in threes, usually one spikelet of a pair sessile and the other pedicelled, infrequently both pedicelled. Rachis fracturing at maturity beneath each spikelet pair. Spikelets of a pair alike or more often dissimilar in shape and sex, when dissimilar sessile spikelet bisexual or female, pedicelled spikelet male or barren, rarely pedicelled spikelet vestigial or absent and sessile spikelet then apparently single; sometimes 1 or more of the lowermost pairs in raceme infertile, resembling pedicelled spikelets, persistent; rachis internodes and pedicels filiform, linear or thickened, sometimes very stout and partially enclosing spikelet, falling with adjacent sessile spikelet, pedicelled spikelet falling separately; callus at the base of sessile spikelet obtuse to pungent. Sessile spikelet with 2 florets, dorsally compressed; glumes enclosing florets, hardened; lower glumes facing outwards, variable, convex or

2-keeled; upper glume boat-shaped, fitting between internode and pedicel; lower floret male or barren, lower lemma hyaline, 2-keeled, lower palea suppressed when floret barren; upper floret fertile, upper lemma hyaline, narrow, entire or bi-toothed, awnless or bearing a geniculate awn with twisted column, upper palea short or absent.

Pedicelled spikelet usually lanceolate, papery, often smaller than pedicelled spikelet; pedicel resembling rachis internode, rarely absent or fused to internode.

Key to the Genera

1.a. Spikelets unisexual, separated in different inflorescences, or in parts of the same inflorescence ………...2

b. Spikelets bisexual, or at least the sessile spikelet of a pair, male and female not separated ………5

2.a. Annual; male and female spikelets mixed in the inflorescence ………...

………....28. Diectomis

b. Perennial; male and female spikelets in different parts of the same inflorescence ………3

3.a. Female spikelets enclosed in a beadlike, bony utricle ………....21. Coix b. Female spikelets not enclosed in a bony utricle ………..4 4.a. Female spikelets conspicuously transversely constricted; racemes solitary in

spatheate axillary clusters ………...17. Chionachne b. Female spikelets not conspicuously transversely constricted; racemes digitate in

spatheate axillary clusters ………73. Polytoca 5.a. Spikelets single, without an accompanying vestigial spikelet or pedicel ……6 b. Spikelets paired, but sometimes pedicelled spikelet vestigial or represented only

by the pedicel ………...7 c. Spikelets paired, or in three’s ...34 6.a. Racemes rachis tough; blades linear ……….30. Dimeria b. Racemes rachis fragile; blades lanceolate ………..7. Arthraxon 7.a. Rachis internodes and pedicels slender, filiform to linear, or if widened upward,

the upper lemma awned ………8

b. Rachis internodes and pedicels stout, angular, columnar, or widened upward; internodes and pedicel sometimes joined; the upper lemma awnless ………14 8.a. Spikelets of a pair similar in shape ………..9 b. Spikelets of a pair different in shape and sex ………19 9.a. Inflorescence with elongate central axis, longer than lowest raceme ………10 b. Inflorescence solitary or subdigitate racemes ………12 10.a. Racemes rachis fragile; 1 spikelet of the pair sessile ………..79. Saccharum b. Racemes rachis tough; all spikelets pedicelled ………..11 11.a. Panicle loose; glumes cartilaginous to leathery ………..59. Miscanthus b. Panicle contracted or spikelike; glumes membraneous………...49. Imperata 12.a. Inflorescence axillary, or spatheate ………...13 b. Inflorescence terminal ………...14 13.a. Glumes equal; lower glumes 7-nerved ………...………20. Coelorachis

b. Glumes subequal; lower glumes 3-5-nerved ……...……..72. Pogonatherum 14.a. Inflorescence terminal; raceme solitary, subdigitate, or spread along an elongate

axis ………..15

b. Inflorescence of racemes from the upper leaf axils ………...16 15.a. Sessile spikelet with pectinate, spinose margin, or tuberculate; racemes solitary

………37. Eremochloa

b. Sessile spikelets without pectinate margin; racemes solitary to many ……….. ………60. Mnesithea 16.a. Sessile spikelets alternating on raceme in 2 opposite rows; pedicelled spikelets

absent; pedicel joined to rachis internode ………62. Ophiuros

b. Sessile spikelets all on one side of racemes; pedicelled spikelets well developed to vestigial; pedicel free or partially or completely joined to rachis internode ………17

17.a. Spikelets of a pair similar; racemes tough or tardily disarticulating; rachis articulation line oblique without central peg ………..44. Hemarthria b. Spikelets of a pair different; racemes easily disarticulating ; rachis articulation

line straight with central peg ………..18

18.a. Lower floret of sessile spikelet staminate, its palea well developed; spikelets smooth ………..77. Rottboellia b. Lower floret of sessile spikelet barren, its palea reduced or absent; spikelets

grooves ……….……….60. Mnesithea 19.a. Pedicellate spikelet reduced to a minute pedicel and hidden in the callus hairs

………9. Asthenochloa b. Pedicellate spikelet not hidden in callus hairs ………...20 20.a. Racemes borne on an elongate central axis or its branches, axis longer than

lowest raceme, not supported by spathes ………...21 b. Racemes solitary , paired, or subdigitate, supported by spathes ………24 21.a. Rachis internodes and pedicels without a purple translucent median line …22 b. Rachis internodes and pedicels with a purple translucent median line …….23 22.a. Lower glume of sessile spikelet laterally compressed; racemes reduced to a triad

………..19. Chrysopogon

b. Lower glume of sessile spikelet dorsally compressed; raceme of several spikelet pairs below terminal triad ………..85. Sorghum

23.a. Racemes of 1-5 spikelet pairs ……….14. Capillipedium b. Racemes of more than 8 spikelets pairs ………11. Bothriochloa 24.a. Lower floret of sessile spikelet staminate, with well-developed palea ……..25 b. Lower floret of sessile spikelet barren, reduced to a lemma; palea absent …28 25.a. Ligule a line of hairs; raceme solitary; lower glume of sessile spikelet deeply

grooved, apex elongate, scarious ………...82. Sehima b. Ligule membraneous; racemes more than one; lower glume of sessile spikelet

not deeply grooved ………26 26.a. Sessile spikelet laterally compressed, smooth; raceme solitary, reduced to

b. Sessile spikelet dorsally compressed; racemes (1) 2- or more, terminal or axillary ………27

27.a. Rachis internodes and pedicels stoutly linear to thickly clavate; sessile spikelet rugose ……….51. Ischaemum

b. Rachis internodes and pedicels filiform to linear; sessile spikelet smooth, grooved along midline……….58. Microstegium 28.a. Awn arising from low down on lemma back; culms slender, trailing; blades

lanceolate ………7. Arthraxon b. Awn arising from apex of lemma, or from sinus of bi-lobed apex …………29 29.a. Lower glumes of sessile spikelet 2-keeled; callus inserted into hollowed

internode apex ………30 b. Lower glumes of sessile spikelet convexly rounded without keels; callus attached

obliquely ………..31

30.a. Racemes paired or digitate; leaves aromatic ………22. Cymbopogon b. Racemes solitary; leaves not aromatic ………..81. Schizachyrium 31.a. Upper lemma bi-toothed, awned from sinus ………47. Hyparrhenia b. Upper lemma entire, awned from apex ………..32 32.a. Raceme with 2 homogamous spikelet pairs at base, forming an involucre

……….89. Themeda b. Raceme with or without homogamous spikelet pairs, but not forming an

involucre ………33 33.a. Sessile spikelet with pungent callus ……….49. Heteropogon b. Sessile spikelet with obtuse callus ………27. Dicanthium 34.a. Spikelets in pairs or in three’s; upper glume 3-keeled ...40. Eulalia b. Spikelets in three’s; upper glume without keeled ...74. Polytrias Genus description and key to the species

5. APLUDA L. Type: Apluda mutica. Sp. Pl. 1: 82. 1753.

Calamina P. Beauv. Ess. Agrostogr. 128, 157. 1812.

From the Latin name apluda (appl-) ae for chaff or bran, alluding to the involucres, or to the spikelets.

One species, Saudi Arabia, Mauritus, through India to Southeast Asia, Australia and New Caledonia. Plants perennial, rambling, leafy, more or less glaucuos, often scrambling or decumbent and rooting at the base. Auricle absent. Sheath short.

Ligule an unfringed membrane. Blades linear-lanceolate and often falsely petiolate. Plants bisexual. Inflorescence racemose, large open terminal compound panicle, naviculate to boat-shape spathe. Raceme comprising 1 sessile and 2 pedicelled spikelets; central sessile branch composed of a fertile floret with a male floret below it,

sessile spikelets awned or not, pedicellate spikelets unawned; lower floret staminate; upper floret hermaphrodite. Glumes similar , and more or less leathery or thin.

Lemmas membraneous. Palea reduced to a membraneous scale. Lodicules 2, free and fleshy. Stamens 2-3. Ovary glabrous. Stigmas 2.

A good fodder when young suitable for all classes of animals, good hay and silage, stalks used for making hats, growing at the edge of woodlands and in hedges, thickets, on moist or dry stony soils, forest margins.

5.1. Apluda mutica L. Sp. Pl. 1: 82. 1753.

Apluda aristata L. Cent. Pl. II: 7. 1756.

Calamina gigantea P. Beauv. Ess. Agrostrgr. 128, 157. 1812.

Apluda gigantea (P. Beauv.) Spreng. Syst. Veg. 1: 290. 1825.

Calamina humilis J. Presl. Reliq. Haenk. 1(4-5): 344. 1830.

Apluda humilis (J. Presl.) Kunth. Revis. Gramin. 1: Suppl. XLI. 1830.

Apluda communis Nees. Gramineae 62. 1841.

Apluda inermis Regel. Trudy Glavn. Bot. Sada 7: 658. 1881.

Plants perennial. Culms 50-350 cm long, tufted, slender, straggling, creeping or scandent, base decumbent, rooting from lower nodes, branched in upper part. Sheaths

usually glabrous. Ligule 1-2 mm, a ciliolate membrane. Blades 8-30 cm by 2-20 mm, flat, apex attenuate to a setaceous. Synflorescence compound, paniculate, 5-35 cm long. Inflorescence a solitary raceme tightly embraced by a spatheole, terminal and axillary. Spatheole 3-9 cm long, ovate, membraneous. Racemes single, bearing a triad of spikelets. Rachis obsolete. Spikelets in threes: Fertile spikelets sessile; 1 in the cluster. Sterile spikelets: companion sterile spikelets rudimentary and well-developed, male, lanceolate, dorsally compressed, 2-5 mm long, as long as fertile spikeletes; glumes herbaceous, acute, muticous; lemmas 2, enclosed by glumes, muticous. Fertile spikelets comprising 1 basal sterile floret, 1 fertile florets, without rachilla extension, oblong, laterally compressed, 2-6 cm long. Glumes dissimilar, exceeding apex of florets, firmer than fertile lemma. Lower glume lanceolate, as long as spikelets, coriaceous, without keels, apex dentate, bifid. Upper glume primary nerve scaberulous, apex acute. Florets: basal sterile floret male, with palea. Lemma of lower sterile floret oblong, slightly shorter than spikelets, hyaline, 3-nerved, acute.

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